[Federal Register Volume 74, Number 117 (Friday, June 19, 2009)]
[Rules and Regulations]
[Pages 29344-29387]
From the Federal Register Online via the Government Publishing Office [www.gpo.gov]
[FR Doc No: E9-14269]
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Part III
Department of the Interior
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Fish and Wildlife Service
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Department of Commerce
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National Oceanic and Atmospheric Administration
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50 CFR Parts 17 and 224
Endangered and Threatened Species; Determination of Endangered Status
for the Gulf of Maine Distinct Population Segment of Atlantic Salmon;
Final Rule
��Federal Register / Vol. 74, No. 117 / Friday, June 19, 2009 / Rules
and Regulations��
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DEPARTMENT OF INTERIOR
Fish and Wildlife Service
50 CFR Part 17
DEPARTMENT OF COMMERCE
National Oceanic and Atmospheric Administration
50 CFR Part 224
[Docket No. 0808191116-9709-02]
RIN 0648-XJ93
Endangered and Threatened Species; Determination of Endangered
Status for the Gulf of Maine Distinct Population Segment of Atlantic
Salmon
AGENCY: National Marine Fisheries Service (NMFS), National Oceanic and
Atmospheric Administration (NOAA), Commerce; United States Fish and
Wildlife Service (USFWS), Interior.
ACTION: Final rule.
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SUMMARY: We (NMFS and USFWS, collectively referred to as the Services)
have determined that naturally spawned and conservation hatchery
populations of anadromous Atlantic salmon (Salmo salar) whose
freshwater range occurs in the watersheds from the Androscoggin River
northward along the Maine coast to the Dennys River, including those
that were already listed in November 2000, constitute a distinct
population segment (DPS) and hence a ``species'' for listing. We have
determined that the Gulf of Maine (GOM) DPS warrants listing as
endangered under the Endangered Species Act (ESA). Critical habitat for
the GOM DPS will be designated in a subsequent Federal Register notice.
DATES: This rule is effective July 20, 2009.
ADDRESSES: Comments and materials received, as well as supporting
scientific information used in the preparation of this rule, will be
available for public inspection, by appointment, during normal business
hours at: National Marine Fisheries Service, Northeast Regional Office,
55 Great Republic Drive, Gloucester MA 01930. An electronic copy of
this final rule is available at: http://www.nero.noaa.gov/prot_res/altsalmon/. Public comments received can be viewed at http://www.regulations.gov.
FOR FURTHER INFORMATION CONTACT: Rory Saunders, NMFS, at (207) 866-
4049; Jessica Pruden, NMFS, at (978) 282-8482; Marta Nammack, NMFS, at
(301) 713-1401; Lori Nordstrom, USFWS, at (207) 827-5938 ext. 13.
Persons who use a Telecommunications device for the deaf (TDD) may call
the Federal Information Relay Service (FIRS) at 1-800-877-8339, 24
hours a day, 7 days a week.
SUPPLEMENTARY INFORMATION:
Background
We issued a final rule listing the GOM DPS of Atlantic salmon as
endangered on November 17, 2000 (65 FR 69469). The GOM DPS was defined
as all naturally reproducing wild populations and those river-specific
hatchery populations of Atlantic salmon having historical, river-
specific characteristics found north of and including tributaries of
the lower Kennebec River to, but not including, the mouth of the St.
Croix River at the U.S.-Canada border. In the final rule listing the
GOM DPS, we did not include fish that inhabit the mainstem and
tributaries of the Penobscot River above the site of the former Bangor
Dam, the upper Kennebec River, or the Androscoggin River within the GOM
DPS (65 FR 69469; November 17, 2000).
In late 2003, we assembled the 2005 Biological Review Team (BRT)
composed of biologists from the Maine Atlantic Salmon Commission (now
the Maine Department of Marine Resources Bureau of Sea-run Fisheries
and Habitat (MDMR)), the Penobscot Indian Nation, and both Services.
The 2005 BRT was charged with reviewing and evaluating all relevant
scientific information relating to the current DPS delineation
(including a detailed genetic characterization of the Penobscot
population and data relevant to the appropriateness of including the
upper Kennebec and Androscoggin rivers as part of the DPS), determining
the conservation status of the populations not included in GOM DPS
listed in 2000, and assessing their relationship to the GOM DPS as it
was listed in 2000. The findings of the 2005 BRT, which are detailed in
the 2006 Status Review for Anadromous Atlantic Salmon in the United
States (Fay et al., 2006), addressed: the DPS delineation, including
whether populations that were not included in the 2000 listing should
be included in the GOM DPS; the extinction risks to the species; and
the threats to the species. The 2006 Status Review (Fay et al., 2006)
underwent peer review by experts in the fields of Atlantic salmon
biology and genetics to ensure that it was based on the best available
science. Each peer reviewer independently affirmed the major
conclusions presented in Fay et al. (2006).
Policies for Delineating Species Under the ESA
Section 3 of the ESA defines ``species'' as including ``any
subspecies of fish or wildlife or plants, and any distinct population
segment of any species of vertebrate fish or wildlife which interbreeds
when mature.'' The term ``distinct population segment'' is not
recognized in the scientific literature. Therefore, the Services
adopted a joint policy for recognizing DPSs under the ESA (DPS Policy;
61 FR 4722) on February 7, 1996. The DPS policy requires the
consideration of two elements when evaluating whether a vertebrate
population segment may be considered a DPS under the ESA: (1) The
discreteness of the population segment in relation to the remainder of
the species or subspecies to which it belongs; and (2) the significance
of the population segment to the species or subspecies to which it
belongs.
A population segment of a vertebrate species may be considered
discrete if it satisfies either one of the following conditions: (1) It
is markedly separated from other populations of the same taxon (an
organism or group of organisms) as a consequence of physical,
physiological, ecological, or behavioral factors. Quantitative measures
of genetic or morphological discontinuity may provide evidence of this
separation; or (2) it is delimited by international governmental
boundaries within which differences in control of exploitation,
management of habitat, conservation status, or regulatory mechanisms
exist that are significant in light of section 4(a)(1)(D) of the ESA
(i.e., inadequate regulatory mechanisms).
If a population segment is found to be discrete under one or more
of the above conditions, its biological and ecological significance to
the taxon to which it belongs is evaluated. This consideration may
include, but is not limited to: (1) Persistence of the discrete
population segment in an ecological setting unusual or unique for the
taxon; (2) evidence that the loss of the discrete population segment
would result in a significant gap in the range of a taxon; (3) evidence
that the discrete population segment represents the only surviving
natural occurrence of a taxon that may be more abundant elsewhere as an
introduced population outside its historic range; and (4) evidence that
the discrete population segment differs markedly from other populations
of the species in its genetic characteristics.
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Listing Determinations Under the ESA
The ESA defines an endangered species as one that is in danger of
extinction throughout all or a significant portion of its range, and a
threatened species as one that is likely to become endangered in the
foreseeable future throughout all or a significant portion of its range
(sections 3(6) and 3(20), respectively). The statute requires us to
determine whether any species is endangered or threatened because of
any of the following five factors: (1) The present or threatened
destruction, modification, or curtailment of its habitat or range; (2)
overutilization for commercial, recreational, scientific, or
educational purposes; (3) disease or predation; (4) the inadequacy of
existing regulatory mechanisms; or (5) other natural or manmade factors
affecting its continued existence (section 4(a)(1)(A-E)). We are to
make this determination based solely on the best available scientific
and commercial data available after conducting a review of the status
of the species and taking into account any efforts being made by states
or foreign governments to protect the species.
Atlantic Salmon Life History
Anadromous Atlantic salmon are a wide ranging species with a
complex life history. The historic range of Atlantic salmon occurred on
both sides of the North Atlantic: from Connecticut to Ungava Bay in the
western Atlantic and from Portugal to Russia's White Sea in the Eastern
Atlantic, including the Baltic Sea.
For Atlantic salmon in the United States, juveniles typically spend
2 years rearing in freshwater. Freshwater ecosystems provide spawning
habitat and thermal refuge for adult Atlantic salmon; overwintering and
rearing areas for eggs, fry, and parr; and migration corridors for
smolts and adults (Bardonnet and Bagliniere, 2000). Adult Atlantic
salmon typically spawn in early November. During spawning, the female
uses its tail to scour or dig a series of nests in the gravel where the
eggs are deposited; this series of nests is called a redd. The eggs
remain in the redd until they hatch in late March or April. At this
stage, they are referred to as alevin or sac fry. Alevins remain in the
redd for about 6 more weeks and are nourished by their yolk sac until
they emerge from the gravel in mid-May. At this time, they begin active
feeding and are termed fry. Within days, the fry enter the parr stage,
indicated by vertical bars (parr marks) on their sides that act as
camouflage. Atlantic salmon parr are territorial; thus, most juvenile
mortality is thought to be density dependent and mediated by habitat
limitation (Gee et al., 1978; Legault, 2005). In particular, suitable
overwintering habitat may limit the abundance of large parr prior to
smoltification (Cunjak et al., 1998). Smoltification (the physiological
and behavioral changes required for the transition to salt water)
usually occurs at age 2 for most Atlantic salmon in Maine. The smolt
emigration period is rather short and lasts only 2 to 3 weeks for each
individual. During this brief emigration window, smolts must contend
with rapidly changing osmoregulatory requirements (McCormick et al.,
1998) and predator assemblages (Mather, 1998). The freshwater stages in
the life cycle of the Atlantic salmon have been well studied; however,
much less information is available on Atlantic salmon at sea (Klemetsen
et al., 2003).
Gulf of Maine Atlantic salmon migrate vast distances in the open
ocean to reach feeding areas in the Davis Strait between Labrador and
Greenland, a distance over 4,000 km from their natal rivers (Danie et
al., 1984; Meister, 1984). During their time at sea, Atlantic salmon
undergo a period of rapid growth until they reach maturity and return
to their natal river. Most Atlantic salmon (about 90 percent) from the
Gulf of Maine return after spending 2 winters at sea; usually less than
ten percent return after spending 1 winter at sea; roughly one percent
of returning salmon are either repeat spawners or have spent 3 winters
at sea (3 sea winter, or 3SW salmon) (Baum, 1997).
In addition to anadromous Atlantic salmon, landlocked Atlantic
salmon have been introduced to many lakes and rivers in Maine, though
they are only native to four watersheds in the State: The Union,
including Green Lake in Hancock County; the St. Croix, including West
Grand Lake in Washington County; the Presumpscot, including Sebago Lake
in Cumberland County; and the Penobscot, including Sebec Lake in
Piscataquis County (Warner and Havey, 1985). There are certain lakes
and rivers in Maine where landlocked salmon and anadromous salmon co-
exist. Recent genetic surveys have confirmed that little genetic
exchange occurs between these two life history types (Spidle et al.,
2003; NMFS unpublished data).
Delineation of the Gulf of Maine Distinct Population Segment
Fay et al. (2006) concluded that the DPS delineation that resulted
in the 2000 listing designation (65 FR 69469; November 17, 2000) was
largely appropriate, except in the case of large rivers that were
excluded in the previous listing determination (Section 6.2.4 of Fay et
al., 2006). As described below in the analyses of discreteness and
significance of the population segment, Fay et al. (2006) concluded
that the salmon currently inhabiting the larger rivers (Androscoggin,
Kennebec, and Penobscot) are genetically similar to the rivers included
in the GOM DPS as listed in 2000 (Spidle et al., 2003), have similar
life history characteristics, and occur in the same zoogeographic
region (section 6.3 of Fay et al., 2006). Further, the salmon
populations inhabiting the large and small rivers from the Androscoggin
River northward to the Dennys River differ genetically and in important
life history characteristics from Atlantic salmon in adjacent portions
of Canada (Spidle et al., 2003; Fay et al., 2006). Thus, Fay et al.
(2006) (section 6.3.1.4 and 6.3.2.4) concluded that this group of
populations (population segment) met both the discreteness and
significance criteria of the DPS Policy and, therefore should be
considered a DPS. Fay et al. (2006) recommended that the new GOM DPS
include all anadromous Atlantic salmon whose freshwater range occurs in
the watersheds from the Androscoggin River northward along the Maine
coast to the Dennys River, including all associated conservation
hatchery populations used to supplement these natural populations;
currently, such conservation hatchery populations are maintained at
Green Lake National Fish Hatchery (GLNFH) and Craig Brook National Fish
Hatchery (CBNFH).
Delineating Geographic Boundaries
Determining the precise boundary of the GOM DPS is difficult. In
the case of the GOM DPS, we use a wide array of independent sources of
information to make this determination. These sources of information
include recent genetic analyses, life history, and zoogeography, among
others. Recent genetic analyses, in particular, have clarified these
distinctions, and we rely on them heavily in the following analysis.
When using genetic data to make these delineations, it is important to
note that extant populations must exist in order to make meaningful
comparisons. In the case of determining the northern boundary of the
GOM DPS, extant populations were used in genetic analyses and thus
inform the determination. However, in the case of the determination of
the southern boundary of the GOM DPS, many populations south of the
Androscoggin are extirpated, and thus there are no genetic data
available to make these
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comparisons. For this reason we rely on additional information to
delineate the southern boundary of the GOM DPS below.
We relied on genetic data to inform our determination on the
northern terminus of the GOM DPS. At a broad scale, it is clear that
there are substantial differences in genetic structure between U.S. and
Canadian populations of Atlantic salmon (Spidle et al., 2003). However,
there are no genetic data on the wild salmon that once occurred in the
St. Croix watershed along the U.S.-Canada border. As listed in 2000,
the northern terminus of the GOM DPS was the U.S.-Canada border at the
St. Croix River, but as described on page 54 of Fay et al. (2006), the
best available science suggests that the St. Croix groups with other
Canadian rivers. Genetic analyses found that salmon in the Dennys River
are more similar to populations in the United States than to Canadian
salmon populations that are geographically proximate to the Dennys
(Spidle et al., 2003). Therefore, we find that the northern terminus of
the GOM DPS is the Dennys River watershed, rather than the St. Croix.
We determined the southern terminus of the GOM DPS to be the
Androscoggin River based on zoogeography rather than genetics because
there are extremely few Atlantic salmon in the rivers on which to base
genetic analyses as one moves southward. Due to the combination of low
numbers of Atlantic salmon in some rivers (e.g., Androscoggin) and the
complete extirpation of the native stock in other rivers to the south
(e.g., Merrimack), complete genetic data are not and may never be
available for the Services to be able to genetically characterize these
populations. In the absence of clear genetic data, we used ecological
factors to define the southern boundary of the GOM DPS. The
Androscoggin River lies within the Penobscot-Kennebec-Androscoggin
Ecological Drainage Unit (EDU) (Olivero, 2003) and the Laurentian Mixed
Forest Province (Bailey, 1995), which separates it from more southern
rivers that were historically occupied by Atlantic salmon. EDUs are
aggregations of watersheds with similar zoogeographic history,
physiographic conditions, climatic characteristics, and basic geography
(Olivero, 2003). The substantial changes in physiographic conditions
south of the Androscoggin drainage are reflected in the southern
terminus of both the Laurentian Mixed Forest Province and the
Penobscot--Kennebec--Androscoggin EDU occurring in that area. Basin
geography, climate, groundwater temperatures, hydrography, and
zoogeographic differences between the Penobscot--Kennebec--Androscoggin
EDU and the EDUs to the south (e.g., Saco-Merrimack-Charles, Lower
Connecticut, Middle Connecticut, and Upper Connecticut) likely had a
strong effect upon Atlantic salmon ecology and production. These
differences would influence the structure and function of aquatic
ecosystems (Vannote et al., 1980; Cushing et al., 1983; Minshall et
al., 1983; Cummins et al., 1984; Minshall et al., 1985; Waters, 1995)
and create a different environment for the development of local
adaptations than rivers, such as the Saco and Merrimack, to the south.
In the proposed rule, we proposed to include the entire
Androscoggin, Kennebec, and Penobscot Watersheds within the GOM DPS
boundary. Some comments from the public appropriately highlighted
several impassable falls that limited the upstream extent to which
anadromous salmon inhabited the rivers of Maine. NMFS also evaluated
historical occupancy at the watershed scale for the process of
proposing critical habitat for the GOM DPS. There is also considerable
information provided in the 2006 Status Review pertaining to impassable
falls as well. We are, therefore, using these information sources (and
others cited therein) to delimit the upstream extent of anadromy for
GOM salmon in this final rule.
We have identified seven impassable falls that substantially
limited the upstream extent of the freshwater range of GOM salmon.
These include Rumford Falls in the town of Rumford on the Androscoggin
River, Snow Falls in the town of West Paris on the Little Androscoggin
River, Grand Falls in Township 3 Range 4 BKP WKR, on the Dead River in
the Kennebec Basin; the un-named falls (impounded by Indian Pond Dam)
immediately above the Kennebec River Gorge in the town of Indian Stream
Township on the Kennebec River; Big Niagara Falls on Nesowadnehunk
Stream in Township 3 Range 10 WELS in the Penobscot Basin; Grand Pitch
Falls on Webster Brook in Trout Brook Township in the Penobscot Basin;
and Grand Falls on the Passadumkeag River in Grand Falls Township in
the Penobscot Basin (Table 1).
Table 1--Impassable Falls That Limit the Upstream Extent of the Freshwater Range of GOM Salmon
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Name of falls Town River Basin
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Rumford Falls....................... Rumford................ Androscoggin River.... Androscoggin.
Snow Falls.......................... West Paris............. Little Androscoggin Androscoggin.
River.
Grand Falls......................... Township 3 Range 4 BKP Dead River............ Kennebec.
WKR.
Un-named............................ Indian Stream Township. Kennebec River........ Kennebec.
Big Niagara Falls................... Township 3 Range 10 Nesowadnehunk Stream.. Penobscot.
WELS.
Grand Pitch......................... Trout Brook Township... Webster Brook......... Penobscot.
Grand Falls......................... Grand Falls Township... Passadumkeag River.... Penobscot.
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As a result, we have modified the geographic boundaries of the
freshwater range of GOM salmon in the Androscoggin, Kennebec, and
Penobscot Basins in the following ways: all freshwater bodies in the
Androscoggin Basin are included up to Rumford Falls on the Androscoggin
River and up to Snow Falls on the Little Androscoggin River; all
freshwater bodies in the Kennebec Basin are included up to Grand Falls
on the Dead River and the unnamed falls (currently impounded by Indian
Pond Dam) immediately above the Kennebec River Gorge; and all
freshwater bodies in the Penobscot Basin are included up to Big Niagara
Falls on Nesowadnehunk Stream, Grand Pitch on Webster Brook, and Grand
Falls on the Passadumkeag River.
We recognize that many other potentially impassable waterfalls
exist throughout the range of GOM salmon. While other impassable falls
may exist throughout the range, we did not exclude any other areas
(other than the areas above the seven falls mentioned above) for the
following reasons: (1) Their occurrence is typically in headwater areas
that preclude access from relatively small portions of a given
watershed; (2) identifying every impassable falls is impractical given
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current information; and (3) no other impassable falls were brought to
our attention during the public comment period.
In addition, we recognize that within every watershed, there is an
upstream extent of anadromy. However, it is impossible to define that
specific point in every watershed. The upstream extent of anadromy is
ultimately limited by the incremental narrowing of a given river or
stream. While a stream may be too small for an adult salmon to swim up
any further, juveniles may ascend further than that point in search of
suitable rearing habitat. In fact, upstream movement of even fry can be
quite substantial. As such, we include all the freshwater bodies as
part of the freshwater range of GOM salmon unless above one of the
impassable falls mentioned in the text above.
Discreteness and Significance of the GOM DPS
With respect to the ``discreteness'' of this population segment,
section 6.3.1 of Fay et al. (2006) considered ecological, behavioral,
and genetic factors under the first discreteness criterion of the DPS
Policy to examine the degree to which it is separate from other
Atlantic salmon populations. Gulf of Maine salmon are behaviorally and
physiologically discrete from other members of the taxon because they
return to their natal GOM rivers to spawn (a process called homing),
which leads to the separation in stocks that has been observed between
the Gulf of Maine and other segments of the taxon. River-specific
adaptation is an important mechanism that allows anadromous salmon to
occupy diverse environments throughout their range. River-specific
adaptation is facilitated by homing and is characteristic of all other
anadromous salmonids (Klemetsen et al., 2003; Utter et al., 2004). Baum
and Spencer (1990) found that roughly 98 percent of all tagged salmon
returned to their natal rivers to spawn. As described below, these
strong homing tendencies have led to the formation and maintenance of
river-specific adaptations for GOM salmon as well.
Ecologically, GOM salmon are discrete from other members of the
taxon. The core of the riverine habitat of this population segment lies
within the Penobscot-Kennebec-Androscoggin EDU (Olivero, 2003) and the
Laurentian Mixed Forest Province (Bailey, 1995). These environmental
conditions have shaped life history characteristics of GOM salmon. In
particular, GOM salmon life history strategies are dominated by age 2
smolts and 2SW adults, whereas populations to the north of this
population segment are generally dominated by age 3 or older smolts and
1SW adults (called grilse). Smolt age reflects growth rate (Klemetsen
et al., 2003), with faster growing parr emigrating as smolts earlier
than slower growing ones (Metcalfe et al., 1990). Smolt age is largely
influenced by temperature (Symons, 1979; Forseth et al., 2001) and can
therefore be used to compare and contrast growing conditions across
rivers (Metcalfe and Thorpe, 1990). For GOM populations, smolt ages are
quite similar across rivers with naturally-reared (result of either
wild spawning or fry stocking) returning adults predominantly
emigrating at river age 2 (88 to 100 percent) with the remainder
emigrating at river age 3 (Fay et al., 2006). Smolt ages from
naturally-reared returning adults in rivers south of the Penobscot-
Kennebec-Androscoggin EDU are also dominated by river age 2 smolts with
some emigrating at river age 3, but a substantial proportion of river
age 1 smolts are also present (See Table 6.3.1.1 in Fay et al., 2006).
The strongest evidence that GOM salmon are discrete from other
members of the taxon is genetic. Fay et al. (2006) described genetic
structure of this population segment and other stocks in detail in
section 6.3.1.3. In summary, three primary genetic groups of North
American populations (Spidle et al., 2003; Spidle et al., 2004;
Verspoor et al., 2005) are evident. These include the anadromous GOM
populations (including salmon in the Kennebec and Penobscot Rivers)
(Spidle et al., 2003), non-anadromous Maine populations (Spidle et al.,
2003), and Canadian populations (Verspoor et al., 2005). Because of
these behavioral, physiological, ecological and genetic factors, we
conclude that the GOM anadromous population is discrete from other
Atlantic salmon populations under the provisions of the DPS Policy.
With respect to the ``significance'' of this population segment,
Fay et al. (2006) found that there are three attributes which are
described as evidence for ``significance'' in the DPS policy that are
applicable to the GOM DPS (section 6.3.2 of Fay et al., 2006). Fay et
al. (2006) (section 6.3.2.1) concluded that this population segment has
persisted in an ecological setting unusual or unique to the taxon for
several reasons. First, GOM salmon live in and migrate through a unique
marine environment. The marine migration corridor for GOM salmon begins
in the GOM that is known for unique circulation patterns, thermal
regimes, and predator assemblages (Townsend et al., 2006). Gulf of
Maine salmon undertake extremely long marine migrations to feeding
grounds off the West Coast of Greenland because the riverine habitat
they occupy is at the southern extreme of the current North American
range. While such vast marine migrations are more common for stocks on
the northeast side of the Atlantic, the combination of the long
migration distances and the unique setting of the GOM, described above,
make the oceanic life history of the GOM DPS quite different from those
of other stocks (ICES, 2008). In addition, the core of the riverine
habitat of this population segment lies within the Penobscot-Kennebec-
Androscoggin EDU (Olivero, 2003) and the Laurentian Mixed Forest
Province (Bailey, 1995). The importance of this setting is evidenced by
the tremendous production potential of its juvenile nursery habitat
that allows production of proportionately younger smolts than Canadian
rivers to the north (Myers, 1986; Baum, 1997; Hutchings and Jones,
1998). Thus, the combination of the unique rearing conditions in the
freshwater portion of its range combined with the unique marine
migration corridor led Fay et al. (2006) to conclude that this
population segment has persisted in an ecological setting unusual or
unique to the taxon.
Fay et al. (2006) also concluded that the loss of this population
segment would result in a significant gap or constriction in the range
of the taxon (Section 6.3.2.2 of Fay et al., 2006). The extirpation of
this population segment would represent a significant range reduction
for the entire taxon Salmo salar because this population segment
represents the southernmost native Atlantic salmon population in the
western Atlantic. The temperature regimes in these southern rivers made
possible the tremendous growth and production potential which resulted
in the historically very large populations in these areas. Historic
attempts to enhance salmon populations (in GOM rivers) using Canadian-
origin fish failed. This further illustrates the importance of
conserving native, river-specific populations and the difficulties of
restoration if they are lost.
Fay et al. (2006) concluded that this population segment differs
markedly from other populations of the species in its genetic
characteristics (Section 6.3.2.3 of Fay et al., 2006). While genetic
differences were used to examine the ``discreteness'' of this
population segment, Fay et al. (2006) suggested that the
``significance'' of these observed genetic differences is that they
provide evidence of local adaptation. That is, low returns of exogenous
smolts (i.e., Canadian-origin
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smolts stocked in Maine) and lower survival of smolts from these Maine
rivers stocked outside their native geographic range (e.g., into the
Merrimack River) indicate that this population segment is adapted to
its native environment. Based on this information related to
significance, Fay et al. (2006) concluded that this population segment
is significant to the Atlantic salmon species, and therefore, qualifies
as a DPS (the new GOM DPS) under the provisions of the DPS Policy.
Fay et al. (2006) (section 6.3.4) explicitly considered whether to
include hatchery populations in the GOM DPS and concluded that all
conservation hatchery populations (currently maintained at GLNFH and
CBNFH) should be included in the GOM DPS. This determination was based
on the fact that there is a low level of genetic divergence between
conservation hatchery populations and the rest of the GOM DPS because:
(1) The river-specific hatchery programs collect wild parr or sea-run
adults annually (when possible) for inclusion into the broodstock
programs; (2) broodstocks are used to stock fry and other life stages
into the river of origin, and, in some instances, hatchery-origin
individuals represent the primary origin of Atlantic salmon due to low
adult returns; (3) there is little evidence of introgression from
Canadian-origin populations; and (4) there is minimal introgression
from aquaculture fish because of a rigorous genetic screening program
in the hatchery. Because the level of divergence is minimal, in Section
6.3.4 Fay et al. (2006) suggested that hatchery populations should be
considered part of the GOM DPS. However, Fay et al. (2006) also noted
the dangers of reliance on hatcheries. In short, genetic risks from
hatcheries include artificial selection, inbreeding depression, and
outbreeding depression, in addition to other risks such as the
potential for disease outbreaks, loss of funding, or other catastrophic
failure at one or more hatcheries. The reader is directed to
``Population Status of the GOM DPS'' section of this final rule and
Section 8.5.1 of Fay et al. (2006) for an in depth discussion of these
risks.
For the reasons described in Section 6 of Fay et al. (2006), we
conclude that the GOM DPS as described above warrants delineation as a
DPS (i.e., it is discrete and significant). Specifically, we conclude
that the GOM DPS is comprised of all anadromous Atlantic salmon whose
freshwater range occurs in the watersheds from the Androscoggin River
northward along the Maine coast to the Dennys River, including all
associated conservation hatchery populations used to supplement these
natural populations; currently, such populations are maintained at
GLNFH and CBNFH. We consider the conservation hatchery populations that
are maintained at CBNFH and GLNFH essential for recovery of the GOM DPS
because the hatchery populations contain a high proportion of the
genetic diversity remaining in the GOM DPS (Bartron et al., 2006).
Excluded are those salmon raised in commercial hatcheries for
aquaculture and landlocked salmon because they are genetically
distinguishable from the GOM DPS. The marine range of the GOM DPS
extends from the Gulf of Maine to feeding grounds off Greenland. The
freshwater range of the GOM DPS includes all freshwater bodies in the
watersheds from the Androscoggin to the Dennys, except those watersheds
excluded because of natural barrier falls as described in the
``Delineating Geographic Boundaries'' section of this final rule. The
most substantial difference between the GOM DPS as listed in 2000 and
the GOM DPS described in this final rule is the inclusion of the
majority of the Androscoggin, Kennebec, and Penobscot Basins as well as
the associated conservation hatchery population at GLNFH.
Several rivers outside the range of the GOM DPS in Long Island
Sound and Central New England contain Atlantic salmon (Fay et al.,
2006; section 6.4). The native Atlantic salmon of these areas south of
the GOM DPS were extirpated in the 1800s (Fay et al., 2006). Efforts to
restore Atlantic salmon to these areas (e.g., Connecticut, Merrimack,
and Saco Rivers) involve stocking Atlantic salmon that were originally
derived from the GOM DPS. Atlantic salmon whose freshwater range occurs
outside the range of GOM DPS do not interbreed with salmon within the
GOM DPS, are not considered a part of the GOM DPS, and are not
protected under the ESA.
Population Status of the GOM DPS
In evaluating the status of Atlantic salmon, we considered four
basic attributes that contribute to a viable population: abundance,
productivity, genetic diversity, and spatial distribution. The
importance of considering each of these factors is briefly described
below. However, it is important to note that our ability to conduct
such analyses for Atlantic salmon is often limited by the availability
of sufficient data. It is also important to note that the most recent
data available at the time of writing of this final rule was from 2007.
We consider the U.S. Atlantic Salmon Assessment Committee (USASAC)
reports to be the data of record with respect to Atlantic salmon
counts. USASAC reports are generally not available until several weeks
after their annual meeting in March. Thus, 2008 data are considered
only preliminary at the time of writing this final rule.
Considering abundance levels of a given species is critical to
evaluating extinction risks. All else being equal, small populations
are at greater risk of extinction than larger populations because,
generally, larger populations are better able to withstand the effects
of environmental variation, genetic processes, demographic
stochasticity, ecological feedback, and catastrophes (Shaffer, 1981).
Population growth rate (productivity) provides information
regarding how a population is performing in the habitat it occupies. In
evaluating extinction risks, we ideally measure average productivity at
different life stages and estimates of variance to describe the level
of uncertainty inherent in the measurements. An example of life stage-
specific data could be smolt emigration estimates which represent: (a)
The population's potential to increase or (b) the population's ability
to weather periods of poor marine conditions. Measuring productivity
rates over time is quite difficult and resource intensive. Therefore,
simple measures such as spawner population size and replacement rates
may be used to provide more rapid detection of changes in conditions
affecting population growth rates.
For small populations, spatial distribution is important to reduce
extinction risks from genetic risks and demographic stochasticity. A
population's spatial distribution depends on habitat quality (including
accessibility), population dynamics, and dispersal characteristics of
individuals in the population. Analysis of spatial distribution focuses
primarily on spawning group distribution (even though spatial
distribution is important at all life stages) and connectivity of
populations. Since freshwater habitat is often quite heterogeneous,
spawning habitat may be distributed as discrete patches. Straying is an
important component contributing to spatial distribution and,
typically, straying rates are higher at smaller scales (e.g., occurring
within subpopulations rather than between populations (Quinn, 1997)).
Genetic diversity allows species to adapt to a variety of
environments that provide for the needs of the species and
[[Page 29349]]
protects against short-term environmental change while also providing
the raw genetic material necessary to survive long-term environmental
change. Natural demographic and evolutionary processes (patterns of
mutation, selection, drift, recombination, migration, etc.) are
important to maintaining a species' genetic diversity.
The influence of hatcheries on the GOM DPS must be carefully
considered in evaluating the status of the species. The influence of
hatcheries can be both positive and negative; we describe these effects
in some detail below in this section of this final rule. It is
important, however, to first describe the general operation of
conservation hatcheries in Maine.
The USFWS operates two hatcheries in support of Atlantic salmon
recovery efforts in Maine. Together, Green Lake National Fish Hatchery
(GLNFH) and Craig Brook National Fish Hatchery (CBNFH) raise and stock
over 600,000 smolts and 3.5 million fry annually within the range of
the GOM Atlantic salmon DPS. The primary focus of the conservation
hatchery program for the GOM Atlantic salmon DPS is to conserve the
genetic legacy of Atlantic salmon in Maine until habitats can support
natural, self-sustaining populations (Bartron et al., 2006). As such, a
great deal of consideration is given to broodstock collection, spawning
protocols, genetic screening for aquaculture escapees, and other
considerations as outlined by Bartron et al. (2006). The current
program started in 1992, when a river-specific broodstock and stocking
program was implemented for rivers in Maine (Bartron et al., 2006).
This strategy complies with the North Atlantic Salmon Conservation
Organization (NASCO) guidelines for stock rebuilding (USASAC, 2005).
The stocking program was initiated for two reasons: (1) Runs were
declining in every river in Maine, and numerous studies indicated that
restocking efforts are more successful when the donor population comes
from the river to be stocked (Moring et al., 1995); and (2) the numbers
of returning adult Atlantic salmon to the rivers were very low, and
artificial propagation had the potential to increase the number of
juvenile fish in the river through fry and other early life stage
stocking.
Current practices of fry, parr, and smolt stocking as well as
recovery of parr for hatchery rearing are designed to ensure that
river-specific brood stock is available for future production. Atlantic
salmon from the Narraguagus, Pleasant, Sheepscot, Machias, East
Machias, and Dennys populations are maintained at CBNFH in East Orland,
Maine. These populations are augmented by annual collections of parr
from their respective natal river; this program is described in detail
by Bartron et al. (2006). Additionally, returning adult Atlantic salmon
are trapped at the Veazie Dam on the Penobscot River throughout the
duration of the run, transferred to CBNFH, and held until spawning in
the fall of each year. In addition, domestic adults (i.e., offspring of
the sea-run adults representing all sea-run spawned families) from the
Penobscot River are maintained at GLNFH in the event that insufficient
sea-run adults return to the Veazie trap or in the event of a fish loss
at CBNFH. Adult Atlantic salmon (with the exception of the Penobscot
River) are maintained in one of six river-specific broodstock rooms at
CBNFH. Within each broodstock room, adults are maintained separately by
capture year. Capture year is defined as the year parr were collected
from a river. Each capture year may represent one to two year classes.
In addition, fully captive lines, or ``pedigree lines,'' are
implemented when the recovery of parr from the river environment is
expected to be too low to ensure future spawning stock is available
(Bartron et al., 2006). Pedigree lines are established at the time of
stocking, where a proportional representation of each family from a
particular river-specific broodstock is retained in the hatchery while
the rest of the fry are stocked into the river. If parr are recovered
from the fry stocking for the pedigree lines, individuals are screened
to determine origin and familial representation and are integrated into
the pedigree line to maintain some component of natural selection while
maintaining a broad representation of the genetic diversity observed in
the broodstock.
The goals of the captive propagation program include maintenance of
the unique genetic characteristics of each river-specific broodstock
and maintenance of genetic diversity within each broodstock (Bartron et
al., 2006). Evaluation of estimates of genetic diversity within captive
populations, such as average heterozygosity, relatedness, and allelic
richness are monitored within the hatchery broodstocks according to the
CBNFH Broodstock Management Plan (Bartron et al., 2006). Estimates of
allelic richness within each broodstock have thus far, revealed
consistent estimates over the brief time series available (generally
1994 to 2004; Bartron et al., 2007). Information from genetic
monitoring is used to evaluate management practices to reduce the
potential for artificially reducing overall genetic diversity. Further
details of annual genetic monitoring are described by Bartron et al.
(2007).
The current low abundance of adult returns, integration of the
majority of adult returns into the hatchery for the Penobscot, and
recapture of parr from the wild for broodstock makes the wild and
hatchery populations interwoven. In the following sections of this
final rule, we describe the four population attributes of interest
(abundance, productivity, spatial structure, and genetic diversity) and
attempt to apply them first to the wild population and then discuss the
impact the hatchery has on that attribute. For the reasons noted above,
however, it is rarely possible to completely separate the wild and
hatchery population in this analysis.
Abundance
The abundance of Atlantic salmon within the range of the GOM DPS
has been generally declining since the 1800s (Fay et al., 2006). Data
sets tracking adult abundance are not available throughout this entire
time period; however, Fay et al. (2006) in Figure 7.3.1 present a
comprehensive time series of adult returns to the GOM DPS dating back
to 1967. It is important to note that contemporary abundance levels of
Atlantic salmon within the GOM DPS are several orders of magnitude
lower than historical abundance estimates. For example, Foster and
Atkins (1869) estimated that roughly 100,000 adult salmon returned to
the Penobscot River alone before the river was dammed, whereas
contemporary estimates of abundance for the entire GOM DPS have rarely
exceeded 5,000 individuals in any given year since 1967 (Fay et al.,
2006).
Contemporary abundance estimates are informative in considering the
conservation status of the GOM DPS today. After a period of population
growth in the 1970s, adult returns of salmon in the GOM DPS have been
steadily declining since the early 1980s and appear to have stabilized
at low levels since 2000 (Figure 1). The population growth observed in
the 1970s is likely attributable to favorable marine survival and
increases in hatchery capacity, particularly at GLNFH, which was
constructed in 1974. Marine survival remained relatively high
throughout the 1980s, and salmon populations in the GOM DPS remained
relatively stable until the early 1990s when marine survival rates
decreased, leading to the declining trend in adult abundance observed
in the early 1990s.
[[Page 29350]]
[GRAPHIC] [TIFF OMITTED] TR19JN09.002
Adult returns to the GOM DPS have been very low for many years and
remain extremely low in terms of adult abundance in the wild. Further,
the majority of all adults return to a single river, the Penobscot,
which accounted for 91 percent of all adult returns to the GOM DPS in
2007 (Table 2). As illustrated by Table 3, of the 925 adult returns to
the Penobscot in 2007, 802 were the result of smolt stocking and only
the remaining 123 were naturally-reared. The term ``naturally-reared''
includes fish originating from natural spawning and hatchery fry
(USASAC, 2008). Hatchery fry are included because hatchery fry are not
marked; therefore, they cannot be distinguished from fish produced from
natural spawning. Because of the extensive amount of fry stocking that
takes place in an effort to recover the GOM DPS, it is likely that a
substantial number of fish counted as naturally-reared were actually
stocked as fry. The term ``hatchery-origin'' includes those fish
stocked as either parr or smolt from either CBNFH or GLNFH.
The proportion of naturally reared fish that is attributed to fry
stocking cannot be determined. Preliminary adult return data for 2008
(http://www.maine.gov/dmr/searunfish/trapcounts.html) indicated higher
returns than in previous years, but remain well below conservation
spawning escapement (CSE) goals that are widely used (e.g., ICES, 2005)
to describe the status of individual Atlantic salmon populations. When
CSE goals are met, Atlantic salmon populations are generally self-
sustaining. When CSE goals are not met (i.e., less than 100 percent),
populations are not reaching full potential, and this can be indicative
of a population decline. For all rivers in Maine, current Atlantic
salmon populations (including hatchery contributions) are well below
CSE levels required to sustain themselves (Fay et al., 2006) (section
7.1), which is further indication of their poor population status.
Furthermore, calculation of returns relative to CSE for Atlantic salmon
include salmon of fry-stocked origin; because these fish are not
spawned in the wild, displaying returns as a percentage of CSE
overestimates the degree to which the population is achieving self-
sustainability.
Table 2--Adult Returns to the Small Coastal Rivers, the Penobscot River, the Kennebec River, and the Androscoggin River From 2001 to 2007. These Data
are Summarized From Table 3.2.1.2 and Table 16 in the United States Atlantic Salmon Assessment Committee Report (USASAC, 2008)
--------------------------------------------------------------------------------------------------------------------------------------------------------
Small coastal Penobscot River Kennebec River Androscoggin Total known
Year rivers trap count trap count \a\ River trap count returns
--------------------------------------------------------------------------------------------------------------------------------------------------------
2001.......................................................... 103 785 ................ 5 893
2002.......................................................... 37 780 ................ 2 819
2003.......................................................... 76 1112 ................ 3 1191
2004.......................................................... 82 1323 ................ 11 1416
2005.......................................................... 71 985 ................ 10 1066
2006.......................................................... 79 1044 15 6 1144
[[Page 29351]]
2007.......................................................... 53 925 16 20 1014
--------------------------------------------------------------------------------------------------------------------------------------------------------
a Counts not conducted on the Kennebec until 2006.
Table 3--Adult Returns to Rivers Within the Freshwater Range of the GOM DPS by Origin in 2007. These Data Are
Summarized From Table 1 in the United States Atlantic Salmon Assessment Committee Report (USASAC, 2008)
----------------------------------------------------------------------------------------------------------------
River Hatchery-origin Naturally-reared Total
----------------------------------------------------------------------------------------------------------------
Androscoggin.............................................. 17 3 20
Kennebec.................................................. 9 7 16
Dennys.................................................... 2 1 3
Narraguagus............................................... 0 11 11
Other GOM DPS............................................. 0 39 39
Penobscot................................................. 802 123 925
-----------------------------------------------------
Total................................................. 830 184 1014
----------------------------------------------------------------------------------------------------------------
Declines in both hatchery-origin and naturally reared salmon are
evident in the Penobscot River (Table 4). Declines in hatchery-origin
adult returns are less sharp because of the effects of hatcheries. In
short, hatchery supplementation over this time period has been
relatively constant, generally fluctuating around 550,000 smolts per
year (USASAC, 2008). In contrast, the number of naturally-reared smolts
emigrating each year is likely to decline following poor returns of
adults. Although it is impossible to distinguish truly wild salmon from
those stocked as fry, it is likely that some portion of naturally
reared adults are wild. Thus, wild smolt production would suffer 3
years after there were low adult returns, because the progeny of adult
returns typically emigrate 3 years after their parents return. The
relatively constant inputs from smolt stocking coupled with the
declining trend of naturally reared adults result in the apparent
stabilization of hatchery-origin salmon and the decline of naturally
reared components of the GOM DPS observed over the last 2 decades.
Table 4--Adult returns, by origin (hatchery-origin and naturally reared) and age (1sw Indicates the Individual Spent One Winter at Sea; 2sw Indicates
the Individual Spent Two Winters at Sea; 3sw Indicates the Individual Spent Three Winters at Sea; and Repeat Indicates the Individual was a Repeat
Spawner) to the Penobscot River from 1996 to 2007
--------------------------------------------------------------------------------------------------------------------------------------------------------
Hatchery-origin Naturally reared
Year -------------------------------------------------------------------------------- Total
1sw 2sw 3sw Repeat 1sw 2sw 3sw Repeat
--------------------------------------------------------------------------------------------------------------------------------------------------------
1996.......................................................... 484 1,218 6 18 11 303 3 1 2,044
1997.......................................................... 243 934 4 14 4 153 2 1 1,355
1998.......................................................... 238 793 0 10 31 133 1 4 1,210
1999.......................................................... 223 568 0 11 49 108 0 9 968
2000.......................................................... 167 265 0 15 16 69 0 2 534
2001.......................................................... 195 466 0 3 21 98 2 0 785
2002.......................................................... 363 344 0 15 14 41 1 2 780
2003.......................................................... 196 847 1 4 6 56 0 2 1,112
2004.......................................................... 276 952 10 16 5 59 3 2 1,323
2005.......................................................... 269 678 0 8 6 22 0 2 985
2006.......................................................... 338 653 1 4 15 33 0 0 1,044
2007.......................................................... 226 575 0 1 35 88 0 0 925
--------------------------------------------------------------------------------------------------------------------------------------------------------
The influence of CBNFH and GLNFH on abundance of the GOM DPS is
positive, thus reducing short-term extinction risks to the GOM DPS.
Below, we briefly describe the three mechanisms by which the
conservation hatchery programs positively affect the abundance of the
GOM DPS:
1. Stocking of large numbers of smolts (Penobscot beginning in
1974, Dennys beginning in 2001, and Narraguagus beginning in 2008)
increases adult returns, thus reducing demographic risks (i.e.,
extinction risks) to populations that would otherwise be smaller.
2. Stocking large numbers of smolts also reduces the risks of
catastrophic loss because at least one cohort is always at sea and
could be collected as broodstock in case of a catastrophic event in
freshwater (e.g., a large contaminant spill) or in a hatchery (e.g.,
disease outbreak).
3. Rivers without large scale fry stocking efforts have even fewer
adult returns than those rivers with large scale stocking efforts.
Further, rivers that lack significant hatchery contributions (fry
stocking) have not experienced stable
[[Page 29352]]
levels of adult returns since the decline in marine survival in the
early 1990s. For example, redd counts in the Ducktrap River (a river
which is not stocked) have been steadily declining since the 1990s to a
point where no redds were found in the Ducktrap River in 2007, a year
with favorable conditions for redd counting and over 90 percent of
spawning habitat surveyed (USASAC, 2008).
As illustrated by the above data, the abundance of Atlantic salmon
in the GOM DPS is low and either stable or declining. The proportion of
fish that are of natural origin is very small (approximately 10
percent) and is continuing to decline. The conservation hatchery has
assisted in slowing the decline and helped stabilize populations at low
levels, but has not contributed to an increase in the overall abundance
of salmon and has not been able to halt the decline of the naturally-
reared component of the GOM DPS.
Productivity
The historic productivity of the GOM DPS is unknown. Over long time
frames, it is expected that productivity fluctuated widely according to
a diverse range of biotic factors such as food availability and abiotic
factors such as temperature regime and sea level.
Contemporary productivity rates for the GOM DPS can be inferred
from replacement rates. In short, populations with a replacement rate
of 1.0 or higher are stable or increasing while populations with a
replacement rate less than 1.0 are declining. The USASAC has estimated
the replacement rate for the GOM DPS (as listed in 2000) over the last
several years. Replacement rate for the GOM DPS (as listed in 2000) had
been below 1.0 for several generations until 2007, when replacement
rate for the 2002 spawning cohort was 1.47. This translates to on
average, every adult returning in 2002 replacing itself with 1.47
adults in 2007. While this increase is promising, it only represents 1
year; thus, it is premature to conclude that this is indicative of an
increasing trend.
Replacement rate is a fairly imprecise measurement of productivity
for several reasons. First, tracking adult to adult return rates of
naturally reared fish necessarily includes those fish that result from
stocking. Thus, it is not true replacement of fish in the wild because
each river with substantial returns of adults is stocked with fry, or
smolts as in the case of the Penobscot, Narraguagus, and Dennys Rivers.
This situation results in an overestimation of productivity (because it
does not account for the contribution that stocking makes to adult
returns) and also emphasizes the importance of hatcheries to the
security of the GOM DPS. Without stocking of hatchery fry and smolts,
adult returns would presumably be lower and would result in even lower
replacement rates.
The influence of hatcheries on productivity is not known with
certainty, but overall productivity (even with hatchery
supplementation) is quite low. The first goal of the captive broodstock
program is to facilitate the recovery of the natural populations and
minimize the risk of further decline or loss of individual populations
(Bartron et al., 2006). Over time, more adult returns should
successfully spawn in the wild and result in replacement rates above
1.0. However, insufficient data exist to determine whether adult
returns from hatchery contributions result in more spawners and
ultimately more truly wild-origin adult returns. The National Research
Council (NRC, 2004) and the Sustainable Ecosystems Institute (SEI,
2007) identified this as a key limitation in available data on the
recovery efforts for salmon in Maine. Without this information, it is
impossible to estimate, with any certainty, the effect of hatcheries on
this key population attribute (productivity). Overall, however,
replacement rates less than 1.0 (as has been the case most years since
the early 1990s) are indicative of low productivity.
As illustrated by the above, productivity of the GOM DPS is low and
has not consistently had a replacement rate above 1.0 such that
population growth would be expected. There is no current evidence that
hatcheries have increased or will increase productivity in the wild.
Spatial Distribution
The historic distribution of Atlantic salmon in Maine has been
described extensively by Baum (1997) and Beland (1984), among others.
In short, substantial populations of Atlantic salmon existed in nearly
every river that was large enough to maintain a spawning population.
The upstream extent of anadromy extended far into the headwaters of
even the largest rivers. For example, Atlantic salmon were found
throughout the West Branch of the Penobscot River as far as Penobscot
Brook, a distance over 350 river km inland (Atkins, 1870). In the
Kennebec River, Atlantic salmon ranged as far inland as the Kennebec
River Gorge and Grand Falls on the Dead River, 235 km inland (Foster
and Atkins, 1867; Atkins, 1887).
Today, the spatial structure of Atlantic salmon is limited by
obstructions to passage and also by low abundance levels. Fish passage
obstructions caused the decline of many salmon populations (Moring,
2005). Within the range of the GOM DPS, the Kennebec, Androscoggin,
Union, and Penobscot Rivers contain dams that severely limit passage of
salmon to significant amounts of spawning and rearing habitat.
In addition, the low abundance of salmon within the range of the
GOM DPS serves to concurrently limit spatial distribution through two
mechanisms: (1) Lack of sufficient source populations, and (2) hatchery
limitations. First, in properly functioning salmon populations, some
areas have relatively abundant salmon populations such that they may
serve as ``source'' populations. Fish from source populations may seek
out areas with fewer or no competitors. This is an important dispersal
mechanism for all anadromous salmonids. Over evolutionary timescales,
this process led to the colonization of nearly every river in Maine by
Atlantic salmon. Because the abundance of salmon is so low today, this
dispersal mechanism is likely not operating and will likely not operate
until trends in productivity and abundance are reversed. Second,
spatial distribution is limited today by hatchery capacity. The
Penobscot River alone would require 12.5 million fry in order to
properly seed all presently accessible rearing habitat (Trial, 2006),
while GLNFH and CBNFH can only produce roughly 3.5 million fry annually
(Barton et al., 2006). Thus, hundreds of thousands of otherwise
suitable habitat units are currently unoccupied (NMFS, 2008). The
Sheepscot, Narraguagus, Dennys, Machias, East Machias, and Pleasant
Rivers are usually stocked with as many fry as are needed to properly
seed the habitat, although no stocking occurs within a 50-meter buffer
around areas known to have spawning activity the previous year in order
to reduce competition between potentially wild and hatchery fry
(described in detail by Trial, 2006). Hatchery space for the Penobscot
population is limited by hatchery capacity, such that only 2.5 million
fry are typically allocated and stocked into the Penobscot River
annually. Other rivers within the freshwater range of the GOM DPS have
been stocked to a very limited degree in some years, usually with
Penobscot-origin fry (see section 5 of Fay et al., 2006, for a detailed
review).
The influence of hatcheries on spatial structure of the GOM DPS is
positive. Without hatchery contributions, fewer juveniles would inhabit
the rivers of Maine. In section 7.2., Fay et al. (2006)
[[Page 29353]]
examined recent MDMR electrofishing data, which demonstrated that
rivers with large scale stocking efforts have much higher juvenile
densities compared to those rivers without large scale stocking
efforts. The hatchery, therefore, has allowed for maintenance of the
current spatial structure of the GOM DPS. Without the hatcheries, there
likely would have been a greater reduction in spatial distribution. In
summary, spatial distribution of the GOM DPS is positively influenced
by the Atlantic salmon conservation hatchery supplementation program in
the following ways:
1. The use of captive broodstock from seven separate populations
reduces the risks of random environmental and demographic events;
2. Stocking maintains the spatial distribution of the GOM DPS;
3. Stocking has been used to repopulate unoccupied areas, when
determined to be an appropriate management action.
As illustrated above, the spatial distribution of the GOM DPS has
been significantly reduced from historic levels and is currently
limited by low abundance of Atlantic salmon. However, we conclude that
spatial distribution would have experienced even greater reductions
without the influence of hatcheries.
Genetic Diversity
In general, large populations have higher levels of genetic
diversity than small populations. As population sizes decrease, and the
potential for mating related individuals increases, the threat of
inbreeding in a population also increases. Inbreeding has been
documented to decrease overall fitness of a population (Spielman et
al., 2004; Lynch and O'Hely, 2001), reducing the long-term population
viability. Thus, maintaining sufficient levels of genetic variability
and structure is of utmost importance to endangered and threatened
species.
Historical salmon populations within the range of the GOM DPS were
several orders of magnitude higher than they are today and occupied a
greater diversity of habitats. As such, genetic diversity levels of the
GOM DPS are likely to have been higher historically as well. Lage and
Kornfield (2006) demonstrated significant reductions in diversity and
effective population size in the Dennys River from 1963 to 2001. This
raises concern that diversity levels today are lower than historical
levels.
However, results from genetic surveys conducted by the USFWS
suggest that, overall, the GOM DPS is not currently suffering
significant negative effects due to inbreeding. Estimates of genetic
diversity (e.g., average heterozygosity, relatedness coefficients, and
allelic diversity and frequency) within captive populations are
evaluated within the hatchery broodstocks according to the CBNFH
Broodstock Management Plan (Bartron et al., 2006). Broodstock
management is evaluated annually and is revised as needed to minimize
the potential for inbreeding and maintain genetic diversity (Bartron et
al., 2006).
The effects of hatcheries on genetic diversity of the GOM DPS are
both positive and negative; however, the positive effects outweigh the
negative effects at this time. Below, we describe the positive and
negative effects of hatcheries on diversity levels of the GOM DPS.
Genetic diversity of the GOM DPS is positively influenced by the
Atlantic salmon conservation hatchery supplementation program in the
following ways:
1. A rigorous genetic screening program reduces the risks of
outbreeding depression that may otherwise result from aquaculture
escapees or their progeny being integrated into the hatchery program;
2. The effective use of spawning protocols preserves genetic
variation inherent in each of the genetically unique river populations
maintained at CBNFH, ensures the long-term maintenance of genetic
variation, and minimizes the potential for inbreeding or domestication
selection and associated reductions in fitness in the wild;
3. The use of pedigree lines for those populations most at risk
reduces the chance of catastrophic loss of an entire population;
4. Stocking of juveniles into rivers significantly reduces the
risks of catastrophic loss at CBNFH. That is, if a catastrophic loss of
one or more captive broodstock lines occurred at CBNFH, a component of
the genetic variability lost could be recovered by collecting parr for
broodstock.
There are significant risks associated with the current reliance on
hatcheries for the persistence of the GOM DPS. As mentioned previously,
these risks include artificial selection, inbreeding depression, and
outbreeding depression.
Over the long term, artificial selection for the hatchery
environment is considered a threat to survival. If parr are not
recovered in numbers sufficient for broodstock and spawning
requirements, it becomes necessary to establish pedigree lines, which
means that natural selection from fry to parr stage may no longer be
incorporated into the life cycle (details of pedigree line management
are in Fay et al., 2006, and Bartron et al., 2006). Establishment of
pedigree lines is only resorted to in instances when one of the
following criteria is met:
1. The number of broodstock for a particular population is low
(less than collection target);
2. There is a threat of few or no hatchery or wild spawned parr
being recovered; or
3. Loss of family variation through general parr collection
practices is projected to cause appreciable losses in local population
diversity in the near future.
In recent years, pedigree lines have been established for
broodstock from the Pleasant River (due to insufficient parr
collection) and the Dennys River (due to a large aquaculture escape
event). Over time, this process could result in a population that is
well adapted to the artificial environment and poorly adapted to the
natural environment; this form of artificial selection is widely known
as domestication selection (Hey et al., 2005).
Both inbreeding depression and outbreeding depression are widely
accepted as potential risks in artificial propagation programs. As
population sizes decrease, and the potential for mating related
individuals increases, the threat of inbreeding in a population also
increases. Inbreeding may also decrease overall fitness of a population
(Spielman et al., 2004; Lynch and O'Hely, 2001), reducing the long-term
population viability and, therefore, inhibiting the success of
restoration and recovery efforts. Of similar concern is the threat of
outbreeding depression and decreased fitness resulting from the mating
of individuals from populations with significantly different genetic
composition.
Over time, these risks will increase and more negative effects may
appear. At this time, however, results from USFWS genetic screening
programs suggest that domestication, inbreeding depression, and
outbreeding depression do not appear to be negatively impacting the GOM
DPS.
Summary
In summary, all available metrics of abundance, productivity,
spatial distribution, and genetic diversity are cause for concern for
the GOM Atlantic salmon DPS. Contemporary abundance estimates of adult
spawners are several orders of magnitude lower than historical
abundance. Estimates of productivity are well below those required to
sustain a viable population over the long term. The spatial
distribution of the GOM DPS has been severely reduced relative to
historical
[[Page 29354]]
distribution patterns. Genetic diversity levels, though apparently
stable, are likely much lower than they were historically (Lage and
Kornfield, 2006) and lower than more abundant populations in Canada
(Spidle et al., 2003). Finally, while conservation hatcheries
positively influence several of these metrics, they have not yet been
able to reverse the observed declines in wild adult spawners. In the
following sections of this final rule, we use this information combined
with recent population viability analyses to analyze the current
conservation status of the GOM DPS.
Population Viability Analyses
Statistical methods can be used to quantitatively estimate
population growth, and more importantly, extinction probabilities for a
species. The simplest type of model to perform this can be referred to
as a simple Population Viability Analysis (PVA). A simple PVA
quantitatively estimates population growth and extinction probabilities
for a single population (Dennis et al., 1991). A simple PVA is a
stochastic exponential growth model of population size. These types of
models are best used with census data where the sampling variability is
small compared to the population or environmental variability (Dennis
et al., 1991).
More complex versions of PVAs have been developed where life
history characteristics, such as the age distribution within abundance
measures, are accounted for within the model. In addition, a modified
approach has been developed where different life history processes are
compartmentalized within the model allowing for the incorporation of
such things as juvenile survival rates, adult survival rates, habitat
limitations/degradation, age-specific fecundity, or migration rates
(Brook et al., 1999; Marmontel, 1997; Ratner et al., 1997; Zhang and
Wang, 1999). Other complex PVAs have been developed to help managers
decide between competing management regimes, whereby population growth
(or conversely extinction probability) can be predicted based on
changes to survival at one or more life stages. Thus, PVA models can
vary widely in complexity.
Some general caveats are associated with the use and interpretation
of PVAs. It is particularly important to recognize that PVAs are merely
projections about what might happen in the future based on the data
used to compile the model and assumptions made to address uncertainties
(Ralls et al., 2002; Legault, 2005). Because PVAs do not account for
all potential sources of future environmental variation and because of
the uncertainty inherent in predicting future conditions, especially
over longer timeframes, we use PVA results cautiously and consider them
as just one of the pieces of information we evaluate in determining a
species' conservation status.
For the purpose of considering the risks of extinction for Atlantic
salmon, we have two PVAs to consider: the simple PVA conducted by Fay
et al. (2006), and the SalmonPVA (Legault, 2004; Legault, 2005). Both
are instructive in considering the relative extinction risks to the GOM
DPS. They also help clarify the importance of marine survival and
hatchery supplementation in considering extinction risks. It is
important to note that the Services look at estimates of how extinction
probability changes over multiple timeframes and not at only a single
estimate of the extinction probability for a single time period. This
is consistent with the cautions noted by Fay et al. (2006) and Legault
(2005).
Fay et al. (2006) used a simple PVA to assess the extinction risk
to the GOM DPS as defined in this final rule. This PVA examined a
number of different scenarios and provided a wide range of alternative
outputs. In particular, it included three different endpoints: 1
individual, 50 individuals, and 100 individuals. An endpoint greater
than zero, referred to as a quasi-extinction threshold or QET, reflects
the point at which the population is considered to be functionally
extinct, that is, non-recoverable due to loss of fitness of
individuals, inability of individuals to carry out essential population
functions, or other problems. Compared with use of an extinction
threshold of zero, use of a QET would produce a higher probability of
extinction over the same time period or the same probability of
extinction over a shorter time period. An extinction threshold of one
individual, which recognizes that there is no longer a population to
model, is not typically referred to as a QET; compared to a threshold
of zero individuals, it will not materially affect a model's results.
Although a model's results using different extinction thresholds are
not directly comparable, they do provide useful information about the
condition of the population over time.
Fay et al. (2006) presented a range of estimated extinction risks
for a variety of time horizons (0 to 100 years, with 20-year
intervals). This analysis used adult return data from two time series
(1980-2004 and 1991-2004) to estimate population growth and extinction
probabilities for the GOM DPS. The two time series were separated
because of the regime shift in marine survival observed for Atlantic
salmon throughout the North Atlantic that began in 1991 (ICES, 2005).
This regime shift represents a change in productivity and marine
survival of Atlantic salmon in the Northwest Atlantic that has
persisted to date. In short, projections for the time period 1980 to
2004 are more ``optimistic'' because those data include roughly 10
years of higher marine survival; projections for the time period 1991
to 2004 are more ``pessimistic'' because they only include observations
during the recent period of lower marine survival. Using this method,
Fay et al. (2006) provided a wide range of extinction risks, but all
scenarios considered clearly trended toward extinction. Comparing the
two time series clearly shows the importance of marine survival;
extinction risks are more severe for the 1991 to 2004 time series
(Figure 3) compared to the 1980 to 2004 time series (Figure 2).
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The results of the Fay et al. (2006) PVA are based solely on the
dynamics of the population during the timeframes examined (1980 to
2004) and are dependent on the following assumptions: (1) Hatchery
supplementation continues into the future for up to 100 years at
current levels with similar survival rates, and (2) similar threats to
the species remain operative into the future (i.e., environmental
conditions remain unchanged). The Fay et al. (2006) PVA does not
include the risk of disruptions to hatchery operations (e.g., due to
disease outbreak) or the risk of genetic effects (such as inbreeding
and domestication selection described above) of hatchery
supplementation.
The SalmonPVA (Legault, 2004) was developed for the GOM DPS of
Atlantic salmon as listed in 2000 and does not include the Penobscot
population. Given that smaller initial population sizes exacerbate the
extinction process (Holmes, 2001), the probability of extinction for
any given time period for the GOM DPS as defined in this final rule,
which includes the Penobscot population, might be lower than the
estimates produced by the model for the GOM DPS as listed in 2000.
However, the Penobscot population is also in decline and subject to
many of the same, as well as additional, environmental stressors. Thus,
the model results are still generally instructive for this analysis.
The SalmonPVA model was developed to aid in the formation of delisting
criteria for the GOM DPS as listed in 2000 and to assess the efficacy
of different management strategies towards this delisting goal.
The SalmonPVA (Legault, 2004, 2005) incorporates all salmon life
stages, different survival rates for each stage, four different marine
survival scenarios, freshwater habitat capacity, harvest, straying
rates, and hatchery stocking as inputs into the model. Extinction in
the SalmonPVA was defined as no fish alive at any life stage; this
model, unlike the Fay et al. (2006) PVA, does not use QETs (i.e., it
does not identify an earlier point in decline at which the population
would become functionally extinct).
The SalmonPVA (Legault, 2004, 2005) demonstrates that current
levels of hatchery supplementation may reduce extinction risk to the
GOM DPS as listed in 2000 depending on the rate of marine survival. In
simulations where current low marine survival estimates increased to
the mean of the last 30 years, the SalmonPVA estimated that the
extinction risk in the next 100 years (for the GOM DPS as listed in
2000) was approximately 1 percent in simulations where hatchery
supplementation continued for 50 years, 72 percent if continued
hatchery supplementation was reduced from 50 years to 30 years, and
near 100 percent if hatchery supplementation ceased in 10 years.
Furthermore, in simulations using a constant low marine survival
scenario representing the current environment, there was a 100 percent
chance of extinction within 100 years regardless of the number of years
of stocking, and extinction occurred within 20 years of the last
stocking event.
Like the results of the Fay et al. (2006) PVA, the results of the
SalmonPVA (Legault 2004, 2005) are dependent on assumptions about
future conditions remaining the same. These assumptions include the
level of hatchery supplementation (i.e., number of fish stocked),
freshwater survival, freshwater carrying capacity, and straying rates
of adult fish among rivers. Also like the Fay et al. (2006) PVA, the
SalmonPVA (Legault 2004, 2005) does not include the risk of disruptions
to hatchery operations (e.g., due to disease outbreak) or the genetic
risks (such as inbreeding and domestication selection described above)
of hatchery supplementation. It is expected that extinction would
proceed much faster than indicated by the model's simulation results if
and when these effects become operative in the GOM DPS. The SalmonPVA
does include scenarios where hatchery operations cease (without
attributing that to a cause which could be lack of funding, disease
outbreak or evidence of significant genetic risks), and those scenarios
illustrate that declines rapidly follow the elimination of the
hatchery.
Both the Fay et al. (2006) and Legault (2004, 2005) PVAs assumed
that hatchery supplementation would continue at its present level even
when there were 100 or fewer returning adults in the Penobscot.
However, hatchery supplementation (in particular, smolt stocking) could
not continue at the same level in the future if returning adults fell
below 150 because that is the number of adults necessary to make full
use of the current conservation hatchery capacity for the smolt
stocking program that currently sustains the Penobscot population
(section 5.2.1 of Fay et al., 2006). Smolt stocking increases the
number of returning adults, so if the full number of smolts could not
be produced and stocked, there would be fewer adults returning which
would result in an even smaller population. Adult returns to the
Penobscot constitute a substantial proportion of the total returns to
the GOM DPS (Table 2).
Additional problems would arise if there were 150 or fewer adult
returns to the Penobscot. If there were only 150 adult returns, it is
likely all of their production would be used for smolt production (M.
Bartron, USFWS, pers. comm., 2009). Fry production for the Penobscot
would have to come from domestic broodstocks. If the domestic
broodstocks (at GLNFH and other sources) were not able to be sustained
because all the adult production was being used for smolt production,
then there would be no fry production for the Penobscot. If the total
production from 150 fish were used to produce smolts, and not to
replenish domestic broodstocks, then those backup broodstocks for the
Penobscot would no longer exist (M. Bartron, USFWS, pers. comm., 2009).
Fry production in the other rivers (those maintained at CBNFH) would
continue.
If there were 150 or fewer adults in the Penobscot, or if smolt
stocking and fry stocking was curtailed, there would be an increased
risk of genetic problems because the rate of loss of genetic diversity
(and the potential for inbreeding) is inversely proportional to the
effective population size (number of individuals reproducing). As the
number of individuals reproducing decreases, the rate of loss of
genetic diversity increases, as does the potential for inbreeding. The
potential for loss of genetic diversity further increases when
populations remain low for extended periods of time. A faster
population decline and genetic impacts would increase the probability
of extinction beyond the predictions of the two PVAs.
In addition to providing estimates of extinction probability, the
Fay et al. (2006) and Legault (2004, 2005) PVAs also provide useful
projections regarding the condition of the population over time. For
example, the results of the Legault (2004, 2005) PVA demonstrate that,
while the estimated extinction probability may be low under certain
scenarios of long-term hatchery supplementation and improved marine
survival, the population can continue to decline to extinction. For the
model scenario producing an extinction probability estimate of 1
percent in 100 years if marine survival increased to the 30-year
average and hatchery supplementation continued for 50 years, the
replacement rate was still less than 1, indicating the simulated GOM
DPS was still in decline. Also under this scenario, the model predicted
that three of the eight river populations would be extirpated.
In summary, PVA results must be interpreted carefully. The two PVAs
considered here do not include risks associated with other sources of
environmental variation (e.g., aquaculture escapement and disease
[[Page 29357]]
outbreak in the wild) identified in the Summary of Factors Affecting
the Species section. Because these PVAs do not account for all
potential sources of future environmental variation, and because of the
uncertainty inherent in predicting future conditions, especially over
longer timeframes, we do not consider the numerical estimates of
extinction probabilities in the PVA of Fay et al. (2006) and the
SalmonPVA (Legault 2004, 2005) to be the actual extinction
probabilities of the newly defined GOM DPS.
We have no information to indicate that marine survival will
significantly improve. We find that, based on the available trend
information, it is most reasonable to assume that marine survival will
continue at approximately its current low level. Therefore, we conclude
that the results of the Fay et al. (2006) PVA and the Legault (2004,
2005) PVA that are based on marine survival values above the current
low level are unrealistic.
Also, based on information on diseases (see Factor C in the Factors
Affecting the Species section of this final rule), or concerns such as
catastrophic loss to water supply or feed contamination (P. Santavy,
USFWS, pers. comm., January 23, 2009), there is a risk of disruptions
to hatchery operations. Based on the information on long-term hatchery
operations (NRC, 2004; Fay et al., 2006, at section 8.5.1; SEI, 2007),
there is a risk of genetic problems from hatchery supplementation. At
present, these risks are not quantifiable, and are therefore not
accounted for in either PVA. However, we find that these risks are
substantial in the long term because of the dependence on the
conservation hatchery program.
Because the models do not include the risk of disruptions to
hatchery operations, the risk of genetic effects of hatchery
supplementation, and risks associated with other sources of
environmental variation, we conclude that all of the results of the Fay
et al. (2006) PVA and the Legault (2004, 2005) PVA may considerably
underestimate the probability of extinction. Nevertheless, the Fay et
al. (2006) PVA and the Legault (2004, 2005) SalmonPVA do tell us much
about certain factors affecting the status of the GOM DPS as defined in
this rule, especially the significance of hatchery supplementation and
marine survival, and we use this information to provide important
context for evaluating threats in the following sections of this rule.
Previous Federal Actions
In 1991, the FWS designated Atlantic salmon in five rivers in
Downeast Maine (the Narraguagus, Pleasant, Machias, East Machias, and
Dennys Rivers) as Category 2 candidate species under the ESA (56 FR
58804; November 21, 1991). Both Services received identical petitions
in October and November of 1993 to list the Atlantic salmon (Salmo
salar) throughout its historic range in the contiguous United States
under the ESA. On January 20, 1994, the Services found that the
petition presented substantial scientific information indicating that
the petitioned action may be warranted (59 FR 3067).
The Services conducted a joint review of the species in January
1995, and found that the available biological information indicated
that the species described in the petition, Atlantic salmon throughout
its range in the United States, did not meet the definition of
``species'' under the ESA. Therefore, the Services concluded that the
petitioned action to list Atlantic salmon throughout its historical
United States range was not warranted (60 FR 14410; March 17, 1995). In
the same notice, the Services determined that a DPS consisting of
populations in seven rivers (the Dennys, East Machias, Machias,
Pleasant, Narraguagus, Ducktrap, and Sheepscot Rivers) did warrant
listing under the ESA. On September 29, 1995, after reviewing the
information in the status review, as well as state and foreign efforts
to protect the species, the Services proposed to list the seven rivers
DPS as a threatened species under the ESA (60 FR 50530; September 29,
1995). The proposed rule contained a special rule under section 4(d) of
the ESA which would have allowed for a State plan, approved by the
Services, to define the manner in which certain activities could be
conducted without violating the ESA. In response to that special
provision in the proposed rule, the Governor of Maine convened a task
force that developed a Conservation Plan for Atlantic Salmon in the
seven rivers. That Conservation Plan was submitted to the Services in
March 1997.
The Services reviewed information submitted from the public,
current information on population levels, and assessed the adequacy of
the Maine Atlantic Salmon Conservation Plan, and, on December 18, 1997,
withdrew the proposed rule to list the seven rivers DPS of Atlantic
salmon as threatened under the ESA (62 FR 66325). In that withdrawal
notice, the Services redefined the species under analysis as the GOM
DPS to acknowledge the possibility that other populations of Atlantic
salmon could be added to the DPS if they were found to be naturally
reproducing and to have wild stock characteristics. NMFS maintained the
GOM DPS as a candidate species to acknowledge ongoing concern over the
species' status. In the 1997 withdrawal notice, the Services outlined
three circumstances under which the process for listing the GOM DPS of
Atlantic salmon under the ESA would be reinitiated: (1) An emergency
which poses a significant risk to the well-being of the GOM DPS is
identified and not immediately and adequately addressed; (2) the
biological status of the GOM DPS is such that the DPS is in danger of
extinction throughout all or a significant portion of its range; or (3)
the biological status of the GOM DPS is such that the DPS is likely to
become endangered in the foreseeable future throughout all or a
significant portion of its range.
The Services received the State of Maine 1998 Annual Progress
Report on implementation of the Conservation Plan in January 1999. On
January 20, 1999, the Services invited comment from the public on the
first annual report and other information on protective measures and
the status of the species. The comment period remained open until March
8, 1999 (64 FR 3067). The Services reviewed all comments submitted by
the public and provided a summary of those, along with their own
comments, to the State of Maine in March 1999. The State of Maine
responded to the Services' comments on April 13, 1999.
In order to conduct a comprehensive review of the protective
measures in place and the status of the species, as was committed to in
the 1997 withdrawal notice, the BRT was reconvened to update the
January 1995 Status Review for Atlantic salmon. The 1999 Status Review
was made available on October 19, 1999 (64 FR 56297). On November 17,
1999, the Services published a proposed rule to list as endangered the
GOM Atlantic salmon DPS, which was defined to include all naturally
reproducing remnant populations of Atlantic salmon from the Kennebec
River downstream of the former Edwards Dam site northward to the mouth
of the St. Croix River at the United States-Canada border. At that
time, the Services stated that, to date, they had determined that these
populations were found in the Dennys, East Machias, Machias, Pleasant,
Narraguagus, Sheepscot, and Ducktrap Rivers and in Cove Brook, all in
eastern Maine. On November 17, 2000 (65 FR 69459), the Services
published a final rule listing the GOM Atlantic salmon
[[Page 29358]]
DPS as endangered. In that final rule, we noted that a determination as
to the appropriateness of adding the mainstem and upper tributaries of
the Penobscot River to the DPS would be made upon completion of genetic
analyses.
The 2006 Status Review for Anadromous Atlantic Salmon (Salmo salar)
in the United States (Fay et al., 2006) assessed genetic and life
history information and concluded that the GOM DPS as defined in 2000
should be redefined to encompass the Penobscot, Kennebec, and
Androscoggin Rivers.
We received a petition to list the ``Kennebec River population of
anadromous Atlantic salmon'' as an endangered species under the ESA on
May 11, 2005. NMFS published a notice in the Federal Register on
November 14, 2006 (71 FR 66298), concluding that the petitioners
(Timothy Watts, Douglas Watts, the Friends of Merrymeeting Bay, and the
Maine Toxics Action Coalition) presented substantial scientific
information indicating that the petitioned action may be warranted.
On September 3, 2008 (73 FR 51415), we proposed to revise the
extent of the GOM DPS and list the DPS as endangered; we also announced
our 12-month finding that listing was warranted for the petition to
list Atlantic salmon in the Kennebec River as endangered. On September
5, 2008 (73 FR 51747), NMFS proposed to designate critical habitat for
the revised GOM DPS of Atlantic salmon.
The Services jointly administer the ESA as it applies to anadromous
Atlantic salmon. In 2006, the USFWS Region 5 and NMFS Northeast Region
entered into a Statement of Cooperation to divide responsibility for
ESA implementation with respect to Atlantic salmon in order to enhance
efficiency and effectiveness. Experience implementing this agreement,
changes in structure of the recovery program, and anticipated increases
in workload associated with this listing action caused the Services to
revisit the 2006 agreement. A new Statement of Cooperation has been
signed which clarifies roles and responsibilities between the Services.
The Statement of Cooperation assigns the following responsibilities to
NMFS: critical habitat designation; section 7 consultations (for both
the species and critical habitat) on activities within estuaries and
marine waters; ESA activities and actions to address dams; assessment
activities in the estuary and marine environment; and international
science and management. The Statement of Cooperation assigns the
following responsibilities to USFWS: Administrative lead for
development of a new recovery plan; section 10 recovery permits;
section 10 habitat conservation plans (for all activities except dams);
section 7 consultations (for both the species and critical habitat) on
activities in freshwater (except dams); and the conservation hatchery
program.
Summary of Comments
With the publication of the proposed listing determination for the
GOM DPS on September 3, 2008, we announced a 90-day public comment
period extending through December 2, 2008. We held two public hearings
at two different locations to provide additional opportunities and
formats to receive public input as announced on October 21, 2008 (73 FR
62459). A joint NMFS/FWS policy requires us to solicit independent
expert review from at least three qualified specialists, concurrent
with the public comment period (59 FR 34270; July 1, 1994). In December
2004, the Office of Management and Budget (OMB) issued a Final
Information Quality Bulletin for Peer Review establishing minimum peer
review standards, a transparent process for public disclosure, and
opportunities for public input. The OMB Peer Review Bulletin,
implemented under the Information Quality Act (Pub. L. 106-554), is
intended to provide public oversight on the quality of agency
information, analyses, and regulatory activities, and applies to
information disseminated on or after June 16, 2005. We solicited
technical review of the proposed listing determination from four
independent experts, and received reviews from two of these experts.
The independent expert review under the joint NMFS/FWS peer review
policy collectively satisfies the requirements of the OMB Peer Review
Bulletin and the joint NMFS/FWS peer review policy.
Comments were submitted from interested individuals; state, Federal
and tribal agencies; fishing groups; environmental organizations;
industry groups; and peer reviewers with scientific expertise. The
summary of comments and our responses below are organized into seven
general categories: (1) Tribal comments (2) peer review comments; (3)
comments on the delineation of the GOM DPS; (4) comments on the
conservation status of the GOM DPS; (5) comments on the Services'
identification and consideration of specific threats; (6) comments on
the consideration of conservation efforts in general as well as in
relation to the conservation status of the GOM DPS; and (7) comments on
the Federal management of the GOM DPS.
During the public comment period, the Services met with a number of
groups to address specific concerns and questions on the proposed
listing decision. The hydropower industry, agriculture industry, and
various state agencies were among the groups with which the Services
met. These discussions focused on clarification of information in the
proposed rule and the potential implications of the listing decision on
Atlantic salmon management and the ongoing operations of industry.
These meetings were not held to solicit or receive comments on the
proposed rule, but rather to provide clarification. Meeting
participants were instructed to submit comments on the proposed rule
through the regular means, and those are identified and addressed in
the comments section of this rule. The Services also met with
representatives from some of the Maine Tribes, including the Penobscot
Indian Nation, The Houlton Band of Maliseets, the Aroostook Band of
Micmacs, and the Passamaquoddy Tribe. The Services appreciate the
importance of our Federal trust responsibilities and the spirit of
government-to-government consultation embodied in Secretarial Order
3206 (American Indian Tribal Rights, Federal-Tribal Trust
Responsibilities, and the Endangered Species Act) and Executive Order
13175 (Consultation and Coordination with Indian Tribal Governments).
The focus of the government-to-government consultation was on the
implications of the listing decision on Atlantic salmon management and
exploring options to further enhance our cooperation on Atlantic salmon
recovery.
Tribal Comments
Comment 1: The Penobscot Indian Nation commented that it maintains
its right to directly take Atlantic salmon for sustenance purposes.
Penobscot Indian Nation members have not lethally taken an Atlantic
salmon since 1988 at which time two Atlantic salmon were harvested for
ceremonial purposes. The Penobscot Indian Nation has not exercised its
right to take any Atlantic salmon for traditional purposes since that
time based upon concerns about the health of the Penobscot Atlantic
salmon population. The Penobscot Indian Nation stated that it will
continue to abstain from taking any Atlantic salmon until the status of
the Penobscot population is healthy enough to be able to sustain some
level of harvest.
Response: The Services appreciate the importance of Atlantic salmon
to the Penobscot Indian Nation in particular as well as other Maine
Tribes. The Services recognize both the Penobscot Indian
[[Page 29359]]
Nation's tribal rights and the Services' responsibility to implement
the ESA. Given that Penobscot Indian Nation has not exercised its right
to take Atlantic salmon since 1988 on a voluntary basis, the Services
believe that there is no conflict provided the Penobscot Indian Nation
continues to voluntarily abstain from taking based upon continued
concerns about the conservation status of the Penobscot population.
Comment 2: The Penobscot Indian Nation commented that it would not
take any position on whether the species should be listed as threatened
or endangered. The Penobscot Indian Nation defers to the Services'
expertise to make that determination.
Response: The Services have provided justification for the listing
decision in this final rule.
Peer Review Comments
Comment 3: Both reviewers agreed with the delineation of the GOM
DPS of Atlantic salmon. However, both reviewers felt there were parts
of the text that could be further clarified, specifically consideration
of available genetic data for the northern and southern boundaries in
relation to the zoogeographic information used.
Response: The Services received comments from both peer reviewers
and the general public regarding necessary clarification of the data
used to support the southern boundary delineation in particular. The
Services have clarified the text in the DPS delineation section of this
final rule.
Comment 4: One of the peer reviewers stated that the discussion of
the population PVA was perhaps overemphasized and could be simplified
while still communicating extinction risk. The reviewer notes that
there are simpler deterministic equilibrium models that could have been
used to more simply state extinction risk.
Response: The Services have clarified the text of the rule
addressing PVAs and the projections. The Services acknowledge that
there are a number of different types of models that could have been
used to project extinction risk or demonstrate the conservation status
of the species. The Services chose the PVA models because they are
useful in assessing extinction risks. Further, the Atlantic salmon
conservation and management community in Maine are more familiar with
them than with other models, given the public's previous exposure to
them during the recovery planning process and the development of the
2006 Status Review. We agree with the peer reviewer that the PVA is
just one piece of information considered in the listing determination;
in the text of this final rule, we have clarified our findings with
respect to the PVAs and how they factor into the biological status of
the species.
Comment 5: Both reviewers noted that the proposed rule lacked
necessary description for how threats were categorized as either
primary or secondary threats. Neither felt that this was an incorrect
way to communicate the magnitude of the threat; rather, the basis for
this determination should be better explained and supported in the
text.
Response: The Services agree that the description of threats as
primary or secondary could have been better explained in the proposed
rule. Upon review, the Services decided to take a different approach to
describing the magnitude of the threat and its influence on the
conservation status of the GOM DPS under the ESA. Rather than comparing
the magnitude of the threats to each other, we have identified the
relative impact of each of the threats on the species and its habitat.
The text has been modified accordingly.
Comment 6: One of the reviewers had concerns about the discussion
of artificial propagation under Factor E (Other Natural or Manmade
Factors Affecting its Continued Existence). While the reviewer agrees
with the Services' conclusion that the conservation hatchery program is
reducing the risk of extinction of the GOM DPS, he highlighted areas
where the text should be clarified. Specifically, the short- and long-
term goals of the conservation hatchery program should be better
described in relation to how the program is currently being conducted.
Response: Upon closer review and in response to the peer review,
the Services have changed the way in which artificial propagation and
specifically the conservation hatchery program are described and
considered. While there are both positive and negative effects
resulting from any artificial propagation program, the Services have
determined that it would be more appropriate to move the discussion of
the role of the conservation hatchery program and its influence on the
current status of the species and recovery to the section of the rule
describing the status of the species rather than describing it in the
section pertaining to the threats. The Services have also revised the
description of the program and its role in recovery of the GOM DPS in
response to comments received from both peer reviewers and the general
public.
Comment 7: One reviewer recommended minor clarifications to the
text in Factor E addressing diadromous fish communities, marine
survival, and competition.
Response: The Services have clarified the text in these sections to
be responsive to comments from both peer reviewers and the general
public.
Comment 8: Both reviewers commented that the section applying the
Policy for Evaluation of Conservation Efforts when making Listing
Decisions (PECE) to conservation actions was unclear and seemed
incomplete. They questioned the analysis of only one conservation
initiative, the Penobscot River Restoration Project (PRRP).
Response: The Services agree that analysis of conservation efforts
under PECE is more transparent if a complete analysis of a variety of
efforts is included in the rule. We have revised the section addressing
analysis of conservation actions.
Comment 9: Both reviewers commented that the determination to list
the GOM DPS of Atlantic salmon as endangered was sound and only
suggested minor clarifications to the text.
Response: The Services have made minor changes and clarified the
text in this section.
Public Comments
Comment 10: Many commenters believe that certain river systems,
particularly the Androscoggin and the Union, should not be included
within the GOM DPS boundaries. They argue that we erred in using
different criteria (zoogeographic and genetic) to delineate the
southern and northern boundaries of the DPS and that we should delay
the decision to include the Androscoggin in the DPS until the naturally
reared population in Androscoggin can be genetically characterized.
Commenters also suggest that river systems where the species has been
extirpated, such as the Union, should not be included within the DPS
range.
Response: The 1996 Interagency Policy Regarding the Recognition of
Distinct Vertebrate Populations Under the Endangered Species Act (61 FR
4722) (DPS Policy) states that a population segment may be considered
discrete in relation to the remainder of the species to which it
belongs if ``it is markedly separated from other populations of the
same taxon as a consequence of physical, physiological, ecological or
behavioral factors. Quantitative measures of genetic or morphological
discontinuity may provide evidence of this separation.'' The DPS Policy
does not restrict the Services to using only one measure to
[[Page 29360]]
define discreteness of a population segment. In fact, the introduction
to the second element (significance) that must be met in evaluating
whether a population qualifies as a DPS says that a population segment
may be considered discrete based on ``one or more'' of the discreteness
conditions.
As more thoroughly described in the ``Review of Species
Delineation'' section of this final rule, genetic data were available
for us to delineate the northern boundary of the GOM DPS. These data
show clear genetic differentiation between populations inhabiting
rivers in Maine and rivers in New Brunswick, with the Dennys River
population clustering more closely with the Maine population and the
St. Croix River population clustering more closely with populations in
New Brunswick. Therefore, we used the Dennys watershed as the northern
boundary of the DPS. However, because of the combination of low numbers
of Atlantic salmon in some rivers (e.g., only three naturally reared
adult returns to the Androscoggin River (Table 3)) and the complete
extirpation of the native stock in other rivers (e.g., Merrimack
River), complete genetic data are not, and may never be, available for
us to genetically characterize these populations.
In the absence of clear genetic information to define the southern
boundary of the GOM DPS, we used ecological factors in addition to the
genetic factors described above. In particular, we used the
zoogeographic boundary (the Penobscot-Kennebec-Androscoggin EDU and the
Laurentian Mixed Forest Province) that ecologically separates the
Androscoggin watershed from watersheds to the south (e.g., Saco,
Merrimack, and Connecticut watersheds). EDUs, defined by Olivero
(2003), are aggregations of watersheds with similar zoogeographic
history, physiographic conditions, climatic characteristics, and basin
geography. EDUs generally have similar physiographic and climatic
conditions (Higgins et al., 2005). These differences would influence
the structure and function of aquatic ecosystems (Vannote et al.,1980;
Cushing et al., 1983; Minshall et al., 1983; Cummins et al., 1984;
Minshall et al., 1985; Waters, 1995) and create a different environment
for the development of local adaptations than rivers to the south.
Therefore, we believe this zoogeographic boundary sufficiently
satisfies the criteria to define discreteness for the southern edge of
the GOM DPS.
In listing the GOM DPS, our goal is ultimately to recover the
species so it no longer requires the protection of the ESA. Therefore,
we have delineated boundaries for the GOM DPS that include all the
areas of current and historical occupation of Atlantic salmon where
those salmon would be identified as belonging to the GOM DPS. During
recovery planning, we will further evaluate the recovery needs of the
GOM DPS. It is likely that different levels of attention will be paid
to the recovery of the DPS in different watersheds, based in part on
the threats within a particular watershed and the habitat potential
within a watershed. Delineating the entire GOM DPS conserves this
ecosystem for Atlantic salmon survival and recovery, in addition to
supporting straying, providing refugia, and buffering against
catastrophic events.
Comment 11: Some commenters suggest that the boundaries of the DPS
delineation should not extend into watersheds that were historically
unoccupied by Atlantic salmon because they are upstream of historical,
natural barriers (e.g., waterfalls).
Response: Based on the comments received, analyses by NMFS (2008),
and information contained in the 2006 Status Review, we delimited the
freshwater range of the GOM DPS to include only those areas downstream
of substantial barrier falls. For this final rule, we have modified the
geographic boundaries of the freshwater range of the GOM DPS in the
Androscoggin, Kennebec, and Penobscot Basins in the following ways: All
freshwater bodies in the Androscoggin Basin are included up to Rumford
Falls on the Androscoggin River and up to Snow Falls on the Little
Androscoggin River; all freshwater bodies in the Kennebec Basin are
included up to Grand Falls on the Dead River and the un-named falls
(currently impounded by Indian Pond Dam) immediately above the Kennebec
River Gorge; and all freshwater bodies in the Penobscot Basin are
included up to Big Niagara Falls on Nesowadnehunk Stream, Grand Pitch
on Webster Brook, and Grand Falls on the Passadumkeag River. See the
``Delineating Geographic Boundaries'' section of this final rule.
Comment 12: Many commenters stated that the Services did not
accurately determine the conservation status of the GOM DPS. These
commenters disagreed with the Services' proposal that the GOM DPS
should be listed as endangered under the ESA. Instead, they argued that
a threatened listing determination was more appropriate. The definition
of endangered is ``in danger of extinction throughout all or a
significant portion of its range.'' Several commenters argued the
results of the PVA conducted by Legault (2004, 2005) demonstrated that
the GOM DPS had a less than one percent chance of extinction provided
that hatchery supplementation continued into the future. Thus, some
commenters felt that the definition of threatened, ``likely to become
endangered * * *'' was more appropriate given the role of hatcheries in
preventing extinction. Commenters also cited the success of the
conservation hatchery program as evidenced by the status of rivers
within the 2000 GOM DPS that were supported by hatchery supplementation
versus those that were not. The replacement rate reported by the USASAC
was also cited as evidence of the positive contribution of the hatchery
program to returns within the GOM DPS.
Response: We agree that the conservation hatcheries (CBNFH and
GLNFH) provide a buffer against short-term extinction risks. Without
these facilities in place, the status of the GOM DPS would be even more
dire. However, as described in the ``Population Status of the GOM DPS''
section of this final rule, only three of the four population
attributes of interest (abundance, spatial structure, and genetic
diversity) are enhanced by the conservation hatcheries. In particular,
the lack of any evidence that hatchery fish have the potential to
result in wild returns over successive generations remains a
significant concern. While the increase in replacement rate reported in
2007 by the USASAC is a positive sign, the overall trend remains
negative when taken together. Further, 1 year of positive population
growth is insufficient to justify threatened status.
The extended timeframes for extinction (provided that hatchery
supplementation continues) projected by Legault (2005) are further
evidence of the buffering effect of hatcheries. However, these
projections do not include any consideration of the negative effects of
reliance on hatcheries over successive generations. Recent evidence
suggests that the negative effects of domestication, inbreeding
depression, and outbreeding depression can accrue over just a few
generations (Araki et al., 2007). While we do not believe these
negative effects are substantially reducing the long-term viability of
the GOM DPS at this time, each successive generation will likely have
higher risks of reduced fitness because of these effects. These
additive risks over time are not modeled or otherwise accounted for in
the extinction risks scenarios described by Legault (2005). The PVA
results of Legault demonstrate that extinction occurs quickly when the
conservation hatchery is eliminated. This provides
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further evidence that the wild population is currently in danger of
extinction.
Finally, the SalmonPVA (Legault 2005) showed that at the constant
low marine survival scenario representing the current environment,
there was a 100 percent chance of extinction within 100 years
regardless of the number of years of stocking, and extinction occurred
within 20 years of the last stocking event. Legault (2005) demonstrated
that an increase in marine survival substantially decreased the
extinction probabilities. The scenario in which Legault found there to
be a 1 percent chance of extinction assumed an increase in marine
survival to the high of the previous 30 years. Unfortunately, we have
no information to indicate that marine survival will significantly
improve; therefore, there is no scientifically sound basis for assuming
there is only a one percent chance of the GOM DPS going extinct.
Comment 13: One commenter felt that both hatchery-origin and
naturally reared Atlantic salmon should be equally weighted in terms of
their population contribution to the GOM DPS. This commenter felt that
the inclusion of both hatchery-origin and naturally reared Atlantic
salmon in the GOM DPS was inconsistent with the way in which the
Services weighted the relative contribution of each group to recovery.
The Services' determination of the conservation status of the GOM DPS
placed a higher weight on naturally reared fish in terms of their
contribution to recovery versus hatchery origin fish (fish stocked as
parr, smolts, or adults).
Response: The stated purpose of the ESA is ``to provide a means
whereby the ecosystems upon which endangered species and threatened
species depend may be conserved'' (16 U.S.C. Sec. 1531(b)). Using
captive propagation as a recovery tool is clearly warranted when
necessary, as in the case of the GOM DPS. However, the intent of the
ESA is quite clear: the ultimate goal of species recovery efforts
should be recovery in the wild, free from human intervention. While
CBNFH and GLNFH clearly reduce the immediate risk of extinction of the
GOM DPS, they have not been shown to substantially contribute to
recovery in the wild. The influence of hatcheries on productivity is
not known with certainty, but overall productivity (even with hatchery
supplementation) is quite low. Hatchery fish are included in the GOM
DPS because they are essential to recovery, and the sole purpose of the
conservation hatchery is recovery. But, recovery means recovery in the
wild, so the goal of the hatchery is to, over time, increase the
percentage of returns that are of wild origin to the point that the GOM
DPS becomes self-sustaining and is no longer dependent on the hatchery.
Over time, more adult returns should successfully spawn in the wild,
resulting in replacement rates above 1.0. However, the idea that adult
returns from hatchery contributions result in more spawners and,
ultimately, more truly wild-origin adult returns, remains an untested
hypothesis. The National Research Council (NRC, 2004) and the
Sustainable Ecosystems Institute (SEI, 2007) identified this as a key
limitation in available data on the recovery efforts of salmon in
Maine. Without this information, it is impossible to estimate, with any
certainty, the effect of hatcheries on this key population attribute
(productivity). The conservation hatchery has assisted in slowing the
decline and helped stabilize populations at low levels, but has not
contributed to an increase in the overall abundance of wild salmon.
Comment 14: Several commenters felt that the Services' listing
determination placed too much emphasis on the potential for a
catastrophic failure at the conservation hatchery facilities.
Commenters acknowledged that this may have been an issue when the
Services initially listed the GOM DPS in 2000, given that all
broodstock were held at CBNFH. However, the expansion of the GOM DPS to
include the Penobscot and other rivers means that there are now several
facilities that house broodstock (e.g., GLNFH, the USDA facility, and
the Cooke Facility on the Kennebec). Thus, loss of all broodstock due
to a catastrophic failure is highly unlikely.
Response: The Services agree that the loss of all potential
broodstock would be extremely unlikely. However, it would not take the
loss of all broodstock to significantly jeopardize the long-term
viability of the GOM DPS. Catastrophic broodstock loss or a
catastrophic loss of fry, parr, or smolt cohorts would result in a
decrease in effective population size, loss of genetic diversity, and a
multi-year lag while life stages rebuild, during which time there would
be limited or no hatchery production or stocking.
Domestic broodstock for the Penobscot is currently maintained at
facilities in addition to GLNFH. These domestic broodstocks should be
viewed as backups. These sources are meant to be replenished annually
(i.e., new domestic broodstock lines are created each year) for GLNFH
to reduce long-term selection to the hatchery environment. If there was
a situation where the numbers of adult returns were reduced to 150 or
less, then all production would go toward smolt production and not to
fry stocking or to replenish domestic broodstocks. These backup
broodstocks would no longer exist (M. Bartron, USFWS, pers. comm.,
2009). If these domestic broodstocks were used to propagate future
domestic broodstocks, there would be greater concerns about the
decreased fitness of their offspring in the wild from successive
generations of selection to captivity.
The Services have concluded that the conservation hatcheries
significantly contribute to the maintenance of the genetic diversity of
the GOM DPS. However, there are both long-term and short-term risks of
reliance on hatcheries that have been considered above in the
``Population Status of the GOM DPS'' section of this final rule. In
addition, recent events provide additional evidence of the potential
for catastrophic events to further exacerbate extinction risks. In
January 2009, significant mortality occurred to eggs of Penobscot
origin at CBNFH. Low egg survival rates in the Penobscot population
required the use of the domestic line for smolt production (50,000) for
the first time ever. The relative fitness rate of the sea-run line has
not been compared to the domestic line, so the demographic effects are
unpredictable. The cause for the low egg survival rate is unknown, but
is being investigated at the time of writing of this rule.
Comment 15: Several commenters felt that by increasing the
geographic scope of the GOM DPS to include additional populations, one
being the Penobscot, which has the highest returns to the DPS, the
extinction risk is substantially reduced. Therefore, these commenters
felt that a threatened listing determination is warranted.
Response: All things being equal, larger populations do have lower
extinction risks. However, the inclusion of the Penobscot population in
the GOM DPS does not alter the trends in abundance, which are pointing
toward extinction. The addition of the Penobscot population does
provide some measure of security from immediate extinction risks, but
does not reverse the long-term trend which is toward extinction.
Comment 16: At least one commenter argued that a threatened listing
determination could be justified based upon the returns to both the
Penobscot and Downeast Salmon Habitat Recovery Units (SHRU). These two
SHRUs, according to the commenter, satisfy the minimum recovery
criteria by having at
[[Page 29362]]
least 500 (naturally reared and hatchery origin) salmon within each
SHRU.
Response: In developing its draft recovery criteria for use in the
critical habitat designation process, NMFS specifically noted that in
order to be eligible for recovery, SHRUs would not only need to meet a
minimum population size of 500 individuals, but also show a positive
population growth rate for at least two generations (10 years).
Further, only wild-origin salmon are included in these measures because
the goal of recovery is to achieve a self-sustaining population; a
population that relies on hatchery stocking is not self-sustaining and
therefore does not contribute to achievement of the recovery criteria.
These criteria have clearly not been met in either case given the long-
term downward trends in abundance and preponderance of hatchery-origin
salmon composing the GOM DPS as described throughout this final rule.
NMFS' draft recovery guidelines (2008) also state that in order to
delist the GOM DPS, the threats identified at the time of listing must
be addressed.
Comment 17: Many commenters argued that the PVA results of Legault
(2004, 2005) and Fay et al. (2006), coupled with low returns and poor
marine survival, demonstrate that the Services are correct in their
proposal to list the GOM DPS as endangered under the ESA. These
commenters felt that the intent behind the ESA is to recover wild
populations and that hatchery origin fish are only a temporary option
until the wild population recovers.
Response: We concur. We also recognize the long-term risks of
reliance on hatcheries that are not accounted for in either PVA.
Therefore, we are issuing this final rule to list the GOM DPS of
Atlantic salmon as endangered.
Comment 18: A small number of commenters argued against listing the
expanded GOM DPS at all. They argued that the rivers included in the
expansion are heavily stocked and do not represent self-sustaining
populations. They also stated that existing regulatory mechanisms are
sufficiently protective, and thus, listing under the ESA is not
necessary.
Response: Many endangered species are currently not self-
sustaining. In fact, this is a key factor in determining whether a
species should be listed; self-sustaining populations are generally
less likely to need the protection of the ESA, depending on the threats
facing the species. The Services do recognize the long history of
stocking to support Atlantic salmon recovery in Maine. We describe both
the positive and negative effects of hatchery supplementation in the
``Population Status of the GOM DPS'' section of this final rule. The
weight of the available genetic, life history, and ecological data
clearly indicates that the GOM DPS (including conservation hatchery
populations used to supplement natural populations) satisfies both the
discreteness and significance criteria of the DPS Policy, and
therefore, is a DPS. The fact that the GOM DPS is not self-sustaining
with the existing regulatory mechanisms and is trending toward
extinction indicates it warrants the protection of the ESA.
Comment 19: Several commenters felt that the threat posed by dams
was overstated. Specifically, they disagree with the Services'
assertion that current fish passage technology results in a high level
of mortality and that dams contribute to significant changes in fish
assemblages and predation. One commenter stated that in focusing on the
threat posed by dams, the Services failed to recognize hydropower as a
clean source of energy production.
Response: The Services disagree that the threat posed by dams is
overstated. The National Research Council stated in 2004 that the
greatest impediment to self-sustaining Atlantic salmon populations in
Maine is obstructed fish passage and degraded habitat caused by dams.
There are many studies that support this conclusion that are reviewed
and cited in Section 8 of Fay et al. (2006). Dams result in direct loss
of production habitat, alteration of hydrology and geomorphology,
interruption of natural sediment and debris transport, and changes in
temperature regimes (Wheaton et al., 2004). Riverine areas above
impoundments are typically replaced by lacustrine habitat following
construction. Dramatic changes to both upstream and downstream habitat
directly result in changes in the composition of aquatic communities,
predator/prey assemblages, and species composition (NRC, 2004; Fay et
al., 2006; Holbrook, 2007). Upstream changes in habitat are known to
create conditions that are ideal for known predators of Atlantic salmon
such as chain pickerel, smallmouth bass, and avian predators like
double crested comorants (Fay et al., 2006). Furthermore, dams not only
change predator-prey assemblages, but dam passage also negatively
affects predator detection and avoidance in salmonids (Raymond, 1979;
Mesa, 1994). Adults may also be susceptible to predation when they are
attempting to locate and pass an upstream passage facility at a dam
when stressed by higher summer temperatures (Power and McCleave, 1980).
Even highly effective passage facilities cause Atlantic salmon
mortality. Passage inefficiency and delays occur at biologically
significant levels, resulting in incremental losses of pre-spawn
adults, smolts, and kelts (a life stage after Atlantic salmon spawn).
Dams are known to typically injure or kill between 10 and 30 percent of
all fish entrained at turbines (EPRI, 1992). With rivers containing
multiple hydropower dams, these cumulative losses could compromise
entire year classes of Atlantic salmon. Studies in the Columbia River
system have shown that fish generally take longer to pass a dam on a
second attempt after fallback compared to the first (Bjornn et al.,
1999). Thus, cumulative losses at passage facilities can be significant
and are an important consideration.
The Services do recognize that hydropower does not contribute to
air pollution as do many other energy sources. However, dams remain a
direct and significant threat to Atlantic salmon.
Comment 20: Several commenters stated that existing recreational
fishing regulations in the State of Maine are sufficiently protective
of Atlantic salmon. Specifically, minimum and maximum length limits are
cited for landlocked salmon and brown trout, as well as gear
restrictions, area closures, and outreach programs to educate anglers
on identification and mandatory regulations. Several of these
commenters highlighted the importance of the support of the angling
community to the conservation and recovery effort. They encouraged the
Services to coordinate with the angling community prior to enacting
regulations to ensure that unnecessary regulations are not enacted and
that angling opportunities are made available when biologically
appropriate and that any changes are consistent with the 1996 Policy
for Conserving Species Listed or Proposed for Listing Under the ESA
While Providing and Enhancing Recreational Fishing Opportunities.
Several commenters directly stated that the health of the Penobscot
population could indeed support a directed catch and release fishery.
Response: There are a number of minimum and maximum length limits
that help reduce the threat of take of juvenile and adult anadromous
Atlantic salmon. Similarly, closures have been enforced in certain
areas where anadromous Atlantic salmon may be particularly susceptible
to take. However, the Services believe that many of these regulations
are still not sufficiently protective of outmigrating smolts and of
adults. Minimum and
[[Page 29363]]
maximum length limits should be adjusted to be more protective,
specifically, the maximum length limit of 25 inches (63.5 cm) for
landlocked salmon should be decreased to 16 inches (40.6 cm) in certain
areas. Closures should be prompted by the presence of adult Atlantic
salmon in certain areas such as thermal refugia, overwintering areas,
and holding pools. Some closures mandated by the State have been the
result of emergency action following the lethal take of Atlantic
salmon. A proactive approach to closures and regulation implementation
will be more effective in terms of salmon recovery.
The Services recognize that the angling community has lent
significant support to the conservation and recovery of Atlantic salmon
in the GOM DPS. We believe that we have been very inclusive and
transparent with respect to the angling community and issues of
concern. We invited representatives of angler organizations to
participate as members of the Atlantic Salmon Recovery Team and have
been engaged and participated in critical discussions in other forums
such as the Maine Atlantic Salmon Technical Advisory Committee and
NASCO. We will continue to coordinate and collaborate with the angling
community as we move forward with recovery and management of the GOM
DPS. We believe that we have been consistent with the 1996 Policy for
Conserving Species Listed or Proposed for Listing Under the ESA while
Providing and Enhancing Recreational Fishing Opportunities in our
communication and coordination with the angling community, and we will
continue to be consistent in the future.
It is not biologically appropriate, at this time, to allow a
directed catch and release fishery on the Penobscot River. The Atlantic
salmon population in the Penobscot River is highly dependent on
hatchery stocking; broodstock goals have not been met in most recent
years; and the population is less than 10 percent of its spawning
escapement target. Given these low numbers, it is important to meet
broodstock goals and also to allow some returning adults to spawn
naturally in the river. Decreasing the chances of reaching both of
these goals by allowing targeted fishing on returning adults does not
further the conservation of the species. There also are legal
restrictions on targeted fishing for a listed species.
Comment 21: Maine's Department of Inland Fish and Wildlife (MIFW)
stocks a variety of fish species to provide angling opportunities to
Maine citizens. The bulk of the comments on MIFW stocking programs were
submitted as comments on Factor B (Overutilization for Commercial,
Recreational, Scientific and Educational Purposes). While stocking
programs do cause take of Atlantic salmon due to angling, they also can
have a negative impact on Atlantic salmon due to competition,
particularly from non-native species. Factor E (Other Natural or
Manmade Factors Affecting Its Continued Existence) addresses the issue
of competition. Thus, comments related to stocking and potential
competition issues are addressed in the section of the response to
comments under Factor E.
Comments that were directly related to the impact of stocking
programs on Atlantic salmon as a result of the expansion or increase in
angling opportunities cite coordination with the MDMR as evidence that
measures are taken to minimize any harmful effects of stocking
practices on Atlantic salmon. Commenters also stated that in some areas
where the habitat is not fully seeded with Atlantic salmon, informal
agreements between MDMR and MIFW have been reached to allow for a
certain level of fish stocking to enhance angling opportunities without
creating a significant threat to salmon that may be in the area. One
commenter also cited guidelines that are in the process of being
finalized that will be used to manage rainbow trout stocking. Several
commenters disagree with the Services' conclusion that these stocking
programs are harmful to Atlantic salmon.
Response: MIFW stocking practices that create more angling
opportunities in areas occupied or used by Atlantic salmon contribute
to the potential for take to occur as a result of misidentification,
bycatch, or poaching. MIFW stocking programs are not directed to
Atlantic salmon recovery or ecosystem restoration. They are intended to
create and enhance angling opportunities, and, where these overlap with
salmon, there is increased risk to salmon. MIFW currently stocks
landlocked Atlantic salmon, brown trout, brook trout, rainbow trout,
and splake in Atlantic salmon drainages, posing a threat to Atlantic
salmon in the GOM DPS (Fay et al., 2006). The information presented by
commenters with respect to angling regulations and stocking program
management does not change our conclusion that angling and stocking
programs associated with increased angling opportunities pose an
ongoing threat to Atlantic salmon in the GOM DPS. While coordination
may reduce or minimize exposure of Atlantic salmon to increased angling
pressure, the fact remains that angling pressure is higher than it
would be in the absence of these stocking programs.
Comment 22: One commenter was concerned that the text on the threat
of disease did not reflect the State of Maine's effort to attain Class
A fish health ratings for the hatcheries managed by MIFW.
Response: The text has been changed to reflect the effort on behalf
of the State of Maine to achieve the Class A fish health rating. With
this effort, disease issues still pose a threat to Atlantic salmon as
described in Factor C below.
Comment 23: One commenter felt that the text in the predation
threat analysis did not acknowledge the restoration efforts of the
State of Maine, specifically the Penobscot River Multi-species
Management Plan and the Penobscot Interagency Technical Committee.
Response: The Services believe that these two conservation actions
are more appropriately described and evaluated in the analysis of
conservation efforts under the Policy for Evaluating Conservation
Efforts. We have revised that analysis to incorporate information on
both of these efforts.
Comment 24: Many commenters disagree with the Services' conclusion
that the regulatory mechanisms to address the threat posed by dams are
inadequate. These commenters stated that a number of laws directly
(e.g., Federal Power Act (FPA)) and indirectly (e.g., ESA, National
Environmental Policy Act) allow Federal resource agencies to influence
passage issues and hydropower agreements. They state that the Federal
Energy Regulatory Commission (FERC) process is very transparent and
allows for public involvement. For non-FERC dams, commenters cited the
oversight of the State of Maine Department of Environmental Protection
(MDEP) in addressing fish passage, flow regimes, and water quality.
Response: Notwithstanding the ESA, the current state and Federal
regulatory mechanisms in place to address operation of dams were not
designed to address survival or recovery of endangered species. The
Services recognize that there are a number of laws that create a
process whereby industry, Federal resource agencies, the public, state
agencies and other groups are involved in relicensing, brokering
settlement agreements, or prescribing fish passage. However, as
described in the section of this rule that addresses Factor D, there
are substantial shortcomings associated with these processes. First,
most of these processes require a ``balancing'' of energy and
environmental resources. Under the ESA, deference is given to the
species.
[[Page 29364]]
The FERC process is extremely lengthy, and any contentious fishway
prescriptions could potentially take years to agree on and implement.
Furthermore, neither upstream nor downstream fish passage measures are
100 percent efficient. Their limitations contribute to juvenile and
adult injury and mortality, as well as habitat alterations that affect
the health and survival of all life stages of Atlantic salmon. Sections
10(a) and 10(j) of the FPA could be used by the Services to address the
impact of dams on habitat; however, these regulatory mechanisms are
often discretionary and not necessarily required by FERC (Fay et al.,
2006). Section 4(e) of the FPA may also be used to recommend fisheries
enhancements; however, this section is only applicable to certain
Federal lands which are a rare occurrence in Maine (Fay et al., 2006).
It is also important to recognize that, while settlement agreements
can be a very useful tool to address passage issues, they are not
necessarily removing the issue of passage mortality or in some cases,
even ensuring passage facilities. For example, the Kennebec Hydro
Developers Accord uses biological triggers to establish sequential
upstream passage. If these biological triggers are not met, upstream
passage could be suspended further into the future.
The majority of dams within the GOM DPS range do not require a FERC
license or water quality certificate from the MDEP. These non-
jurisdictional dams are usually small, non-generating dams that were
historically used for flood control, water storage, and other purposes.
Virtually none of these dams have fish passage facilities, and almost
all of them are impacting historical salmon habitat. While there is a
process whereby the public can petition the State of Maine to set
minimum flows and water levels, the State has no authority to prescribe
fishery enhancements without public request or petition. To our
knowledge, no fishways have ever been installed at any dam in the State
of Maine using the fishway petition process outlined pursuant to 12
Maine Revised Statutes Annotated (MRSA) Sec. 12760. Therefore,
significant issues are ongoing with respect to the current mechanisms
in place to address the threat of both FERC and non-FERC licensed dams.
While regulations exist, these regulations have not proven
effective in preventing impacts or quickly responding to remove
impacts. In fact, the most progress on fish passage issues has been
accomplished by working outside of these regulatory mechanisms in the
negotiation of fish passage agreements. Aspects of the current
regulations we find inadequate include the time delays experienced,
extensive resource requirements, and inability to prescribe a solution
which eliminates the impacts from dams.
Comment 25: Some commenters stated that Maine's existing water
quality standards and criteria and its antidegradation policy under the
Clean Water Act (CWA) as administered by the State of Maine (Maine
Pollutant Discharge Elimination System (MPDES)) are sufficiently
protective of all life stages of Atlantic salmon. Furthermore,
commenters state that lack of requests by the Services to condition
permits to avoid substantial impairment to Atlantic salmon is evidence
that the present standards and criteria are protective of Atlantic
salmon.
Response: Maine's water classification program, of which the
State's antidegradation policy is a part, provides for different water
quality standards for different classes of waters (e.g., there are four
classes for freshwater rivers, all of which are found within the GOM
DPS range). Some portions of the GOM DPS are in the highest water
quality classification where water quality standards are the most
stringent. These standards become progressively less stringent with
each lower water classification. These standards were not defined
specifically for Atlantic salmon. Additionally, permits allow an area
of initial dilution or mixing zone where water quality requirements are
reduced. Salmon in or passing through such zones would be exposed to
discharges below water quality standards.
Even where water quality standards are believed to be sufficiently
protective when met, there are circumstances and conditions where
discharges do not meet water quality standards. There are documented
cases where minimum dissolved oxygen standards were not met in class C
waters (MDEP, 2008). Adequate dissolved oxygen concentrations are
necessary for fish health (Decola, 1970). The observed incidents of low
dissolved oxygen were potentially harmful to any salmon present.
The fact that the Services have not requested that permits be
conditioned to protect Atlantic salmon does not mean that water quality
standards are sufficiently protective of Atlantic salmon. Currently,
the Services review only permits that may affect salmon where listed in
2000, and the number of permits issued in this area has been relatively
small. Expansion of the DPS as a result of this final rule will
encompass rivers for which there are many more activities requiring
Maine Pollutant Discharge Elimination System (MPDES) permits, and where
water classifications and associated water quality standards are lower,
which causes us to be concerned about potential impacts to salmon. See
Factors A and D, below, for our analysis of the impact of water quality
on the GOM DPS.
Comment 26: Some commenters stated that we inaccurately emphasized
the effects of Overboard Discharges (OBD) on Atlantic salmon. They
explain that the number of OBDs, the volume of discharge, and the
treatment requirements result in a negligible effect on water quality
within the range of the GOM DPS.
Response: In the proposed rule, we stated that we were concerned
about the potential negative impacts of OBDs on water quality and
identified OBDs as a threat to the GOM DPS. While we remain concerned
about the potential for OBDs to impact Atlantic salmon, we have
determined that we have insufficient information to determine whether
OBDs are currently causing or will cause harm to the GOM DPS.
Therefore, we have removed OBDs as an identified stressor under Factors
A and D below.
Comment 27: Commenters emphasized the importance of Maine's water
rule (MDEP Chapter 587 Rule) in protecting in-stream flows and habitat
for aquatic life.
Response: We agree that the Water Rule represents substantial
progress toward limiting negative impacts on in-stream flows due to
water withdrawals, particularly for class AA waters. However, there are
aspects of the water rule that are not sufficiently protective of
Atlantic salmon. Because the flow standards for class A, B, and C
waters are based on the seasonal base flow (the average flow over an
entire season), withdrawals would be allowed that maintain flow above
the seasonal base flow but reduce flow below the median monthly flow.
During times when flows are naturally low, allowing withdrawals to
reduce flows further, to levels below the median monthly flow, would
negatively impact Atlantic salmon. See Factors A and D, below, for our
analysis of the impacts of water withdrawals under Maine's water rule
on the GOM DPS.
Comment 28: Some commenters noted Maine's forestry-related
regulations and standards that are protective of Atlantic salmon.
Response: We concur that activities conducted in compliance with
the Shoreland Zoning Act, Maine Forest
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Practices Act, Natural Resource Protection Act, Protection and
Improvement of Waters Act, Erosion and Sedimentation Control Law, and
the Statewide Standards for Timber Harvesting and Related Activities in
Shoreland Areas reduce threats to Atlantic salmon from sedimentation
and other impacts related to forestry activities. The State's
compliance monitoring and enforcement of these regulations and
standards will assist in evaluating and confirming that forestry-
related impacts to salmon are minimized. We discuss forestry activities
and other potential non-point sources of pollution under Factors A and
D below.
Comment 29: Several commenters indicated that the threat of poor
marine survival was understated. They felt that considering that poor
marine survival was characterized as one of the primary threats to the
GOM DPS, the Services have failed to adequately address it in either
the proposed rule or the 2006 Status Review.
Response: The Services agree and have incorporated additional
information on marine survival into the final rule to properly reflect
the significance of the threat of poor marine survival to the recovery
of the GOM DPS. Marine survival and climate change are both addressed
through analysis of the five factors specified in section 4(a)(1) of
the ESA.
Comment 30: One commenter disagreed with the identification of
depleted diadromous fish communities as a threat to the GOM DPS. The
commenter felt that the State of Maine is making strides in
implementing management actions aimed at restoration of diadromous fish
communities. These programs will need time to achieve success; however,
the commenter argues that the threat need not be considered given that
there are programs in place to address diadromous fish restoration.
Response: The Services acknowledge the efforts by the State of
Maine at diadromous species restoration in the analysis of State
protective efforts. While the goal of these efforts is to restore the
full suite of diadromous fishes, that goal is far from being realized.
Further, there is not a high level of certainty that these actions will
be implemented and effective. It is very encouraging that the role of
restored diadromous fish communities is recognized; however,
significant coordination, effort, and commitment are necessary to
achieve the goal. Thus, the threat of depleted diadromous fish
communities remains. The PECE analysis section of this rule contains
the Services' evaluation of these programs as well as other
conservation efforts.
Comment 31: One commenter disagreed that MIFW sport fish stocking
programs pose a threat to Atlantic salmon. These comments were
submitted under Factor B, but in large part were directed at the way
the Services characterized the threat of competition due to stocking
under Factor E. The commenter stated that coordination between MIFW and
MDMR is evidence that measures are taken to minimize any harmful
effects of stocking practices on Atlantic salmon. In some areas where
the habitat is not fully seeded with Atlantic salmon, informal
agreements allow for a certain level of stocking without adversely
affecting Atlantic salmon. The commenter also cited guidelines that are
in the process of being finalized that will be used to manage rainbow
trout stocking.
Response: The Services disagree with the commenter that the threat
posed by MIFW stocking programs is adequately addressed by the current
stocking management program. Text has been added to the section of the
rule that discusses competition to provide additional detail to clarify
the negative impact current stocking programs have in terms of
contributing to the threat of competition between other species and
Atlantic salmon. The Services do recognize that a Memorandum of
Understanding (MOU) exists between MDMR and MIFW that establishes a
process for the management and stocking of freshwater salmonid fish
species in Atlantic salmon river systems in Maine to ``reduce the
effects of competing finfish species on Atlantic salmon populations.''
The MOU states that on an annual basis, at the very least, before April
each year, biologists from MDMR and the MIFW will meet as a joint
committee to: (1) Identify all current stocking programs for all
finfish in identified Atlantic salmon river systems; (2) according to
the best available scientific information on species interactions,
assess the possible interactions between Atlantic salmon and inland
fisheries management proposals; (3) identify and evaluate areas of
concern and assess ways to minimize impacts; (4) implement agreed upon
management actions or changes (no fish stocking or changes in
management programs on these rivers shall take place other than in
accordance with this agreement); and lastly, (5) develop
recommendations for the Commissioner of Inland Fisheries & Wildlife and
the other members of the Board of the Atlantic Salmon Commission for
areas of concern that cannot be resolved by the joint committee. While
this MOU does provide a process for managing stocking practices, it
does not address all of the threats posed by the State's stocking
practices. Some of the issues this process does not address include,
but are not limited to, the following: (1) Cumulative effects of
repeated stockings and multi-species stocking on Atlantic salmon; (2)
competition for suitable over-wintering areas; (3) threats from
introduction of parasites or disease from stocking; (4) the threats
posed by Atlantic salmon/brown trout hybrids; and (5) management of
other fish species (smallmouth bass, chain pickerel, etc.). Because
these and other issues still have not been addressed fully, state
stocking programs continue to pose a threat to the GOM DPS as is
described in this rule.
Comment 32: Several commenters felt that the Services did not give
enough consideration to ongoing conservation efforts in the GOM DPS.
Commenters used specific examples, including, but not limited to, the
Penobscot River Restoration Project, the Kennebec Hydro Agreement, and
Project SHARE (Salmon Habitat and River Enhancement). Many commenters
felt that the PECE was not appropriately applied. Commenters suggested
that the Services may need to use the PECE to reevaluate projects like
the Penobscot River Restoration Project for which funding and certainty
of implementation may have changed since publication of the proposed
rule.
Response: The Services agree that analysis of conservation efforts
under PECE is more transparent if a more complete analysis of major
efforts is included in the rule. We have revised the section addressing
analysis of conservation efforts.
Comment 33: Some commenters are concerned that having two Federal
agencies (NMFS and USFWS) share jurisdiction of Atlantic salmon is
inefficient, which is detrimental to the overall conservation of
Atlantic salmon. As a result, some recommended that NMFS be assigned
the lead Federal agency for management of Atlantic salmon.
Response: Joint jurisdiction of Atlantic salmon was first
established in 1994, when the Services worked together jointly to
respond to a listing petition for Atlantic salmon. While we acknowledge
that sharing jurisdiction for an endangered species is challenging, we
believe that both agencies can contribute positively to recovery.
Therefore, we will continue to share jurisdiction for Atlantic salmon.
The goal of both agencies is the recovery of Atlantic salmon; to that
end we will
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strive to work cooperatively and effectively to conserve Atlantic
salmon. To clarify roles and responsibilities of each agency and help
resolve potential differences, we have developed a Statement of
Cooperation (NMFS and USFWS, 2009). The preamble to this rule
identifies how roles and responsibilities have been divided between the
two agencies.
Comment 34: Some commenters were concerned about the lack of
resources to fulfill the requirements of the ESA for Federal agencies,
the State, Tribes, or the regulated community as will be required by
listing the Atlantic salmon in a larger area.
Response: As required by section 4(b)(1)(A) of the ESA, listing
decisions are to be made solely on the basis of the best scientific and
commercial data available. We fully recognize that resources are
limited and intend, through our collaborative partnership with the
State and Tribes, to make most efficient use of our collective
resources to conserve and recover Atlantic salmon. The challenge of
addressing high workload with limited resources is one of the reasons
the Services have divided responsibility for ESA implementation by
activity as noted in the response above. We will work within the ESA's
flexible framework to achieve the regulatory requirements of the ESA.
Comment 35: Several commenters suggested that listing
determinations should consider the likelihood of future cooperation and
collaboration toward recovery.
Response: Under the ESA, the Services must make each listing
determination solely on the best available data on the status of the
species, the five factors specified in section 4(a)(1) of the ESA, and
the efforts being made to protect the species. The possibility of
enhanced cooperation in future recovery actions is not one of the five
statutory factors. While we recognize the importance of cooperation in
achieving recovery, it is not one of the factors identified by the ESA
for making listing determinations. Therefore, we have not considered it
in this determination.
Summary of Factors Affecting the GOM DPS
Section 4 of the ESA (16 U.S.C. 1533) and implementing regulations
at 50 CFR part 424 set forth procedures for adding species to the
Federal List of Endangered and Threatened Species. Under section 4(a)
of the ESA, we must determine if a species is threatened or endangered
because of any of the following five factors: (A) The present or
threatened destruction, modification, or curtailment of its habitat or
range; (B) overutilization for commercial, recreational, scientific, or
educational purposes; (C) disease or predation; (D) the inadequacy of
existing regulatory mechanisms; or (E) other natural or manmade factors
affecting its continued existence.
We have described the effects of various factors leading to the
decline of Atlantic salmon in previous listing determinations (60 FR
50530, September 29, 1995; 64 FR 62627, November 17, 1999; 65 FR 69459,
November 17, 2000) and supporting documents (NMFS and USFWS, 1999; NMFS
and USFWS, 2005). The reader is directed to section 8 of Fay et al.
(2006) for a more detailed discussion of the factors affecting the GOM
DPS. In making this finding, information regarding the status of the
GOM DPS of Atlantic salmon is considered in relation to the five
factors specified in section 4(a)(1) of the ESA.
In making this evaluation, we have carefully considered the
relative demographic effects of each threat to the GOM DPS. In
particular, there are large distinctions between marine survival and
freshwater survival that are important to characterize the current
status of the GOM DPS. From a demographic viewpoint, incremental
increases in marine survival have a much greater impact on the
population than do increases in freshwater survival; although,
increases in marine survival may be more difficult to achieve. It is
important to note that marine survival is calculated from the last time
smolts are counted in a river until adults return to spawn. Thus,
marine survival estimates may include some portion of freshwater,
estuarine, and near-shore mortality in addition to open ocean
mortality.
The historical range of freshwater survival for U.S. populations is
estimated to be approximately 0.13 to 6.09 percent (Legault, 2005).
These estimates are based on numerous studies on different life stages
of the freshwater phase across a wide spatial and temporal scale.
Current marine survival (smolt to adult) for U.S. populations is
estimated to range from 0.09 to 1.02 percent based on total smolt
cohort return rates for the Penobscot (hatchery smolt returns, 1995 to
2004) and Narraguagus Rivers (naturally reared smolt returns, 1997 to
2004) (ICES, 2008). For the reasons mentioned above, marine survival
estimates of hatchery smolts in the Penobscot also include dam-related
mortality.
Improvements in these survival rates are necessary to reach the
point where each fish is replacing itself and to eventually result in
population growth toward recovery. Increases in freshwater survival
will enhance the probability of recovery; however, improvements in
marine survival are necessary to achieve stability and growth. While
numerous natural and anthropogenic factors during the freshwater phase
influence Atlantic salmon populations (Baum et al., 1983; McCormick et
al., 1998; Parrish et al., 1998), the effects of marine survival are
thought to have a greater influence on population levels (Friedland et
al., 2003; Jonsson and Jonsson, 2004; Chadwick, 1987) in part because
the annual variation in marine survival is nearly four times greater
than that in freshwater (Bley, 1987; Reddin et al., 1988). Thus, marine
survival has a significant impact on adult production. As a result,
marine survival must improve in order to recover the GOM DPS (Legault,
2005), and, thus, low marine survival is one of the most important
threats contributing to the poor status of the species. Other factors
affecting the freshwater stages of salmon within the range of the GOM
DPS can be quite pervasive (e.g., poor connectivity due to improperly
sized culverts). Below, these factors are described as stressors that
collectively contribute to the poor status of the GOM DPS; however,
those factors that affect later life stages (typically considered as
marine survival) have the greatest demographic effect.
Factor A. The Present or Threatened Destruction, Modification, or
Curtailment of Its Habitat or Range
Changes to the GOM DPS's natural environment are ubiquitous. Both
contemporary and historic land and water use practices such as damming
of rivers, forestry, agriculture, urbanization, and water withdrawal
have substantially altered Atlantic salmon habitat by: (1) Eliminating
and degrading spawning and rearing habitat, (2) reducing habitat
complexity and connectivity, (3) degrading water quality, and (4)
altering water temperatures. These impacts and their effects on salmon
are described in detail by Fay et al. (2006). Here, we summarize the
stressors that are having the greatest impact on the GOM DPS.
Dams
Dams are among the leading causes of both historical declines and
contemporary low abundance of the GOM DPS of Atlantic salmon (NRC,
2004). Dams directly limit access to otherwise suitable habitat. Prior
to the construction of mainstem dams in the early 1800s, the upstream
migrations of salmon extended well into headwaters
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of large and small rivers alike, unless a naturally impassable
waterfall existed. For example, Atlantic salmon were found throughout
the West Branch of the Penobscot River (roughly 350 km inland) and as
far as Grand Falls (roughly 235 km inland) on the Dead River in the
Kennebec Drainage (Foster and Atkins, 1867; Atkins, 1870). Today,
however, upstream passage for salmon on the West Branch of the
Penobscot is nonexistent and on the Kennebec is limited to trapping and
trucking salmon above the first mainstem dam. Dams also change
hydraulic characteristics of rivers. These changes, combined with
reduced, non-existent, or poor fish passage, influence fish community
structure. Specifically, dams create slow-moving impoundments in
formerly free-flowing reaches. Not only are these altered habitats less
suitable for spawning and rearing of Atlantic salmon, they may also
favor nonnative competitors such as smallmouth bass (Micropterus
dolomieu) over native species such as brook trout (Salvelinus
fontinalis) and American shad (Alosa sapidissima). Fish passage
inefficiency also leads to direct mortality of Atlantic salmon,
including both smolts and adults; these later life stages are
particularly important from a demographic perspective as described
above. Upstream passage effectiveness for anadromous fish species never
reaches 100 percent, and substantial mortality and migration delays
occur during downstream passage through screen impingement and turbine
entrainment. The cumulative losses of smolts incrementally diminish the
productive capacity of all freshwater rearing habitat above
hydroelectric dams. The demographic consequences of low marine survival
(described above) are similar to those of the cumulative losses of
adults at dams. Comprehensive discussions of the impacts of dams are
presented in sections 8.1, 8.3, and 8.5.4 of Fay et al. (2006) and NRC
(2004).
In short, dams directly and substantially reduce survival rates of
salmon through the following ways:
1. Dams directly limit access to otherwise suitable habitat. This
has reduced spatial distribution of the GOM DPS over the last 200
years.
2. Dams also directly kill and injure a significant number of
salmon on both upstream and downstream migrations. Injury and mortality
due to dams occurs at the smolt and adult life stages. These older life
stages are particularly important from a demographic perspective
(similar to marine survival) since slight changes in survival rates at
older life stages can drive demographic trends.
3. Dams also degrade the productive capacity of habitats upstream
by inundating formerly free-flowing rivers, reducing water quality, and
changing fish communities.
Dams are also one of three primary factors that led to the
declining abundance trends that began in the 1800s. The other two
factors (pollution and overfishing), though still operative, have been
greatly reduced in severity (Moring, 2005). Dams, however, represent a
significant threat during the current period of decline (1800s to
present) and are generally more pervasive (over 300 within the
freshwater range of the GOM DPS today) over that same time period.
These effects have led to a situation where salmon abundance and
distribution have been greatly reduced, and thus, the species is more
vulnerable to extinction through processes such as demographic and
environmental stochasticity, natural catastrophes, and genetic drift
inherent in all small populations (Shaffer, 1981).
As stated above, dams directly limit access to otherwise suitable
habitat, directly kill and injure a significant number of salmon during
both upstream and downstream migration, and degrade the productive
capacity of habitats upstream by inundating formerly free-flowing
rivers, reducing water quality, and changing fish communities. Dams
affect multiple life stages in multiple ways, particularly by
preventing or impeding access to spawning habitat for returning adult
salmon; impacts at this late life stage have the greatest demographic
effect. Therefore, dams represent a significant threat to the survival
and recovery of the GOM DPS.
Habitat Complexity
Some forest, agricultural, and other land use practices have
reduced habitat complexity within the range of the GOM DPS of Atlantic
salmon. Large woody debris (LWD) and large boulders are currently
lacking from many rivers because of historical timber harvest
practices. When present, LWD and large boulders create and maintain a
diverse variety of habitat types. Large trees were harvested from
riparian areas; this reduced the supply of LWD to channels. In
addition, any LWD and large boulders that were in river channels were
often removed in order to facilitate log drives. Historical forestry
and agricultural practices were likely the cause of currently altered
channel characteristics, such as width-to-depth ratios (i.e., channels
are wider and shallower today than they were historically). Channels
with large width-to-depth ratios tend to experience more rapid water
temperature fluctuations, which are stressful for salmon, particularly
in the summer when temperatures are warmer. Further discussions of the
impacts of reduced habitat complexity are presented in section 8.1.2 of
Fay et al. (2006). Reduced habitat complexity acts as a stressor on the
GOM DPS by reducing spaces for hiding from predators and increasing
water temperature.
Habitat Connectivity
Over the last 200 years, habitat connectivity within the freshwater
range of the GOM DPS has been reduced because of dams and poorly
designed road crossings. Further discussions of the impacts of reduced
habitat connectivity are presented in section 8.1.2 of Fay et al.
(2006). As a highly migratory species, Atlantic salmon require a
diverse array of well-connected habitat types in order to complete
their life history. Impediments to movement between habitat types can
limit access to potential habitat and, therefore, directly reduce
survival in freshwater. In some instances, barriers to migration may
also impede recovery of other diadromous fishes as well. For example,
alewives (Alosa pseudoharengus) require free access to lakes to
complete their life history. To the extent that salmon require other
native diadromous fishes to complete their life history (see ``Depleted
Diadromous Communities'' in ``Factor E'' of this final rule), limited
connectivity of freshwater habitat types may limit the abundance of
salmon through diminished nutrient cycling, and a reduction in the
availability of co-evolved diadromous fish species that provide an
alternative prey source and serve as prey for GOM DPS Atlantic salmon.
Restoration efforts in the Machias, East Machias, and Narraguagus
Rivers have improved passage at road crossings by replacing poorly-
sized and poorly-positioned culverts. However, many barriers of this
type remain throughout the range of the GOM DPS. Reduced habitat
connectivity is a stressor to the GOM DPS because it prevents salmon
from fully using substantial amounts of freshwater habitat and changes
fish community structure by preventing access for other native fish.
Water Quantity
Water withdrawals can directly impact salmon spawning and rearing
habitat (Fay et al., 2006). Survival of eggs, fry, and juveniles is
also mediated by stream flow. Low flows constrain available habitat and
limit populations.
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Water quantity can be affected by the withdrawal of water for
irrigation or other consumptive water uses as described in section
8.1.1.2 of Fay et al. (2006). The potential for water withdrawals
reducing in-stream flows to levels that may impact Atlantic salmon is a
concern in rivers classified under Maine's ``In-stream flow and water
level standards'' as class A, B, or C. The flow standards for class A,
B, and C waters are based on seasonal base flows (the average flow over
an entire season) rather than median monthly flows. Because these flow
standards are based on the seasonal base flow, withdrawals would be
allowed that, while not reducing flow below the seasonal base flow,
reduce flow below the median monthly flow. In some months, flows are
naturally low (e.g., late summer months), which is stressful to fish
because habitat is more limited, water temperature increases, and
dissolved oxygen decreases. During times when flows are naturally low,
allowing withdrawals to reduce flows further, to levels below the
median monthly flow, would negatively impact Atlantic salmon.
Therefore, water withdrawal that reduces the instream flow below the
median monthly flow is a stressor on the GOM DPS because it may reduce
habitat, increase water temperature, and decrease dissolved oxygen
during the months of naturally low flow.
Water Quality
Atlantic salmon likely are impacted by degraded water quality
caused by point and non-point source discharges. The MDEP administers
the National Pollutant Discharge Elimination System (NPDES) program
under the CWA and issues permits for point source discharges from
freshwater hatcheries, municipal facilities, and other industrial
facilities. Maine's water classification system provides for different
water quality standards for different classes of waters (e.g., there
are four classes for freshwater rivers, all of which are found within
the GOM DPS range); however, these standards were not developed
specifically for Atlantic salmon. Some portions of the GOM DPS are in
areas with the highest water quality classification where water quality
standards are the most stringent. These standards become progressively
less stringent with each lower water classification. Additionally,
permits allow an area of initial dilution or mixing zone where water
quality requirements are reduced. Salmon in or passing through such
zones would be exposed to discharges below water quality standards. The
impacts to salmon passing through these zones are unknown. We are
concerned that water quality standards for Class A, B, and C waters and
mixing zones may not be sufficiently protective of all life stages of
Atlantic salmon, particularly the more sensitive salmon life stages
(e.g., smolts).
Even where water quality standards are believed to be sufficiently
protective, there are circumstances and conditions where discharges do
not meet water quality standards. For example, there are documented
cases in class C waters where dissolved oxygen standards (the lower
bound of which is 5.0 ppm) were not met. This occurred in portions of
the mainstem Androscoggin River, and in the East Branch of the
Sebasticook River and Sabattus River (MDEP, 2008). When dissolved
oxygen concentrations are less than 5.0 ppm, adult salmon breathing
functions become impaired, embryonic development is delayed, and parr
growth and health are impacted; conditions become lethal for salmon at
dissolved oxygen concentrations less than 2.0 ppm (Decola, 1970). When
water quality reaches levels that are harmful to salmon, it is a
stressor to the GOM DPS.
Non-point source discharges such as elevated sedimentation from
forestry, agriculture, urbanization, and roads can reduce survival at
several life stages, especially the egg stage. Sedimentation can alter
in-stream habitat and habitat use patterns by filling interstitial
spaces in spawning gravels, and adversely affect aquatic invertebrate
populations that are an important food source for salmon. Acid rain
reduces pH in surface waters with low buffering capacity, and reduced
pH impairs osmoregulatory abilities and seawater tolerance of Atlantic
salmon smolts. A variety of pesticides, herbicides, trace elements such
as mercury, and other contaminants are found at varying levels
throughout the range of the GOM DPS. The effects of chronic exposure of
Atlantic salmon, particularly during sensitive life stages such as fry
emergence and smoltification, to many contaminants is not well
understood. Fay et al. (2006) provide a discussion of water quality
concerns in section 8.1.3. For these reasons, non-point source
pollution, particularly sedimentation and acid rain, is a stressor to
the GOM DPS.
In summary, we have determined that degraded water quality is a
stressor on the GOM DPS because of the known situations when water
quality did not meet standards and was at levels that negatively impact
salmon and because of the impacts of non-point source pollution,
particularly sedimentation and acid rain.
Factor B. Overutilization for Commercial, Recreational, Scientific, or
Educational Purposes
The GOM DPS of Atlantic salmon has supported important tribal,
recreational, and commercial fisheries. In the past, these fisheries
have been conducted throughout nearly all of the GOM DPS' habitats,
including in-river, estuarine, and off-shore (section 8.2 of Fay et al.
(2006)).
Atlantic salmon are an integral part of the history of Native
American tribes in Maine, particularly the Penobscot Indian Nation. The
species represents both an important resource for food, and perhaps
more importantly, a cultural symbol of the deeply engrained connection
between the Penobscot Indian Nation and the Penobscot River. In
accordance with the Maine Indian Land Claims Settlement Act, the
Penobscot Indian Nation retains the right of its members to harvest
Atlantic salmon for sustenance purposes, and to self-regulate that
harvest. The Penobscot Indian Nation harvested two salmon under these
provisions in 1988, and has voluntarily chosen not to harvest any
Atlantic salmon since then because of the depleted status of the
species (Francis, Penobscot Indian Nation in litt., 2009).
Recreational fisheries for Atlantic salmon in Maine date back to
the early to mid-1800s. Since 1880, over 25,000 Atlantic salmon have
been landed in Maine rivers, roughly 14,000 in the Penobscot River
alone (Baum, 1997). Historically, Atlantic salmon sport anglers
practiced very little catch and release. Beginning in the 1980s as runs
decreased, the Maine Atlantic Sea Run Salmon Commission imposed
increasingly restrictive regulations on the recreational harvesting of
Atlantic salmon in Maine. The allowable annual harvest per angler was
reduced from 10 salmon in the 1980s to one grilse in 1994. Angling was
closed on the Pleasant River from 1986 to 1989. In 1990, a one-year
catch and release fishery was allowed on the Pleasant River. In 1995,
regulations were promulgated for catch and release fishing for sea-run
Atlantic salmon throughout all other Maine salmon rivers, closing the
last remaining recreational harvest opportunities for sea run Atlantic
salmon in the United States. In 2000, all directed recreational
fisheries for sea run Atlantic salmon in Maine were closed until 2006
when a short experimental catch and release fishery was opened on the
Penobscot River below Veazie Dam. The 30-day
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angling season began on September 15, 2006, and resulted in one
Atlantic salmon being caught and released on September 20, 2006. This
fishery was opened again on September 15, 2007. In 2008, the Maine
Atlantic Salmon Commission Board authorized a 30-day catch and release
fishery for the spring of 2008. This fishery poses a risk to returning
sea-run Atlantic salmon because it occurs at a time of year before
broodstock have been collected; broodstock are essential to maintaining
current levels of conservation hatchery supplementation, and lack of
broodstock would further reduce the likelihood of achieving the
scientifically sound and mutually-agreed goals set forth in the
Broodstock Management Plan (P. Kurkul, NOAA, in litt. February 1,
2008).
Poaching and incidental capture remain concerns to the status of
Atlantic salmon in Maine. Incidental capture of parr and smolts,
primarily by trout anglers, and of adult salmon, primarily by striped
bass anglers, has been documented. Targeted poaching for adult salmon
occurs at low levels as well. Low returns of adult salmon to Maine
rivers highlight the importance of continuing to reduce any source of
mortality, particularly at later life stages. While current state
regulations for recreational angling do include minimum and maximum
size limits for certain species (e.g., landlocked salmon), area
closures, and outreach and education programs, there is still a threat
of take of Atlantic salmon from recreational angling.
Commercial fishing for Maine Atlantic salmon historically occurred
in rivers, estuaries, and on the high seas. While most directed
commercial fisheries for Atlantic salmon have ceased, the impacts from
past fisheries are important in explaining the present low abundance of
the GOM DPS. Also, the continuation of offshore fisheries for Atlantic
salmon, albeit at reduced levels, influences the current status of the
GOM DPS.
Nearshore fisheries for Atlantic salmon in Maine were quite common
in the late 1800s. In 1888, roughly 90 metric tons (mt) of salmon were
harvested in the Penobscot River alone. As stocks continued to decline
through the early 1900s, the Maine Atlantic Sea Run Salmon Commission
closed the nearshore commercial fishery for Atlantic salmon after the
1947 season when only 40 fish (0.2 mt) were caught. Any future
opportunities for directed fisheries for Atlantic salmon in U.S.
territorial waters were further limited by regulations implementing the
Atlantic Salmon Fishery Management Plan (FMP) in 1987 (NEFMC, 1987).
These regulations prohibit possession of Atlantic salmon in the U.S.
Exclusive Economic Zone. While nearshore fisheries for Atlantic salmon
have ceased, the impacts from past fisheries are important in
explaining the present low abundance of the GOM DPS.
Directed fishing for other species has the potential to intercept
salmon as by-catch. Beland (1984) reported that fewer than 100 salmon
per year were caught incidental to other commercial fisheries in the
coastal waters of Maine. Recent investigations also suggest that by-
catch of Atlantic salmon in herring fisheries is not a significant
source of mortality for U.S. stocks of salmon (ICES, 2004).
Offshore, directed fisheries for Atlantic salmon continue to affect
the GOM DPS, though these fisheries have been substantially reduced in
recent years. The combined harvest of 1SW Atlantic salmon of U.S.
origin in the fisheries off West Greenland and Canada averaged 5,060
fish, and returns to U.S. rivers averaged 2,884 fish from 1968 to 1989
(ICES, 1993). We estimate that roughly 87 percent of all U.S. adult
returns during the time period 1968 to 1989 originated from the GOM DPS
as defined in this rule, and thus, roughly 2,519 of the 2,884 U.S.
returns were GOM DPS fish. ICES (1993) estimated that adult returns to
U.S. rivers could have potentially been increased by 2.5 times in the
absence of the West Greenland commercial fishery (closed in 2001) and
Labrador fisheries (closed in 1998) during that time period. The United
States joined with other North Atlantic nations in 1982 to form NASCO
for the purpose of managing salmon through a cooperative program of
conservation, restoration, and enhancement of North Atlantic stocks.
NASCO achieves its goals by managing the exploitation by member nations
of Atlantic salmon that originated within the territory of other member
nations. The United States' interest in NASCO stemmed from its desire
to ensure that intercept fisheries of U.S. origin fish did not
compromise the long-term commitment by the states and Federal
government to rehabilitate and restore New England Atlantic salmon
stocks. Since the establishment of NASCO in 1982, commercial quotas for
the West Greenland fishery have steadily declined, as has the abundance
of most stocks that make up this mixed stock fishery (including the GOM
DPS). The West Greenland fishery has been restricted to an internal use
fishery (i.e., no fish were exported) in the following years: 1998-
2000; 2003-2008. From 2002 to 2005, the internal-use fishery harvested
between 19 and 25 mt (reported and estimated unreported catch)
annually. Genetic analysis performed on samples obtained from the 2002
to 2004 fisheries estimated the North American contribution at 64-73
percent, with the U.S. contributing between 0.1 and 0.8 percent of the
total. The 90 percent confidence interval for the U.S. estimates are 0
to 141 salmon in 2002, 5 to 132 salmon in 2003, and 0 to 64 salmon in
2004 (ICES, 2006).
In addition, a small commercial fishery occurs off St. Pierre et
Miquelon, a French territory south of Newfoundland. Historically, the
fishery was very limited (2 to 3 mt per year). There is great interest
by the United States and Canada in sampling this catch to gain more
information on stock composition. In recent years, there has been a
reported small increase in the number of fishermen participating in
this fishery. A small sampling program was initiated in 2003 to obtain
biological data and samples from the catch. Genetic analysis on 134
samples collected in 2004 indicated that all samples originated from
North America, and approximately 1.9 percent were of U.S. origin. The
90-percent confidence interval around this estimate was 0-77 U.S.-
origin salmon (ICES, 2006), and since roughly 87 percent of all U.S.
returns originated from the GOM DPS (as defined in this rule) in 2004
(USASAC, 2005), we estimate that up to 67 fish harvested in this
fishery originated from the GOM DPS. Efforts to continue and increase
the scope of this sampling program are ongoing through NASCO. These
data are essential to understanding the impact of this fishery on the
GOM DPS.
A multi-year conservation agreement was established in 2002 between
the North Atlantic Salmon Fund and the Organization of Hunters and
Fishermen in Greenland, effectively buying out the commercial fishery
for Atlantic salmon for a 5-year period. The internal-use fishery was
not included in the agreement. In June 2007, the agreement was extended
and revised to cover the 2007 fishing season. The agreement may
continue to be extended on an annual basis through 2013.
In summary, overutilization for recreational and commercial
purposes was a factor that contributed to the historical declines of
GOM DPS. Intercept fisheries in West Greenland and St Pierre et
Miquelon, bycatch in recreational fisheries, and poaching act as
stressors on the GOM DPS because they result in direct mortality or
cause stress reducing reproductive success and survival.
[[Page 29370]]
Factor C. Disease or Predation
Disease
Fish diseases have always represented a source of mortality to
Atlantic salmon in the wild (for a more thorough discussion see section
8.3.2 of Fay et al. (2006)). Atlantic salmon are susceptible to
numerous bacterial, viral, and fungal diseases. Bacterial diseases
common to New England waters include Bacterial Kidney Disease (BKD),
Enteric Redmouth Disease (ERM), Cold Water Disease (CWD), and Vibriosis
(Mills, 1971; Gaston, 1988; Olafsen and Roberts, 1993; Egusa, 1992). To
reduce the likelihood of disease outbreaks or epizootic events,
cultured salmon used for aquaculture purposes routinely receive
vaccinations for these pathogens prior to stocking into marine sites.
Fungal diseases such as furunculosis can affect all life stages of
salmon in both fresh and salt water, and the causative agent
(Saprolignia spp.) is ubiquitous to most water bodies. The risk of an
epizootic occurring during fish culture operations is greater because
of the increased numbers of host animals reared at much higher
densities than would be found in the wild. In addition, stressors
associated with intensive fish culture operations (i.e., handling,
stocking, tagging, and sea-lice loads) may increase susceptibility to
infections. Disease from fish culture operations may be spread to wild
salmon directly through effluent discharge or indirectly from either
escapes of cultured salmon, or through smolts and returning adults
passing through embayments where pathogen loads are increased to a
level such that infection occurs and diseases may be transferred.
A number of viral diseases that could affect wild populations have
occurred during the culture of Atlantic salmon, such as Infectious
Pancreatic Necrosis, Salmon Swimbladder Sarcoma Virus, Infectious
Salmon Anemia (ISA), and Salmon Papilloma (Olafsen and Roberts, 1993).
In 2007, the Infectious Pancreatic Necrosis virus was isolated in sea
run fish in the Connecticut River program. These fish most likely
contracted the disease during their time at sea, and it was detected in
the hatchery due to the rigorous fish health monitoring and assessment
protocols. ISA is of particular concern for the GOM DPS because of the
nature of the pathogen and the high mortality rates associated with the
disease. Most notably, a 2001 outbreak of ISA in Cobscook Bay led to an
emergency depopulation of all commercially cultured salmon in the Bay.
In addition to complete depopulation of all cultured salmon, the MDMR
ordered all cages be thoroughly cleaned and disinfected, all sites be
fallowed for 3 months, and subsequent re-stocking of cages occur at
lower densities with only a single year class. These measures were
initially successful; however, subsequent testing for ISA revealed
additional detections of the virus in Cobscook Bay (Maine) sites in
2003, 2004, 2005, and 2006.
In summary, the MIFW, MDMR, and the federally managed conservation
hatcheries all must adhere to rigorous disease prevention and
management regulations and protocols; despite these protocols there
remains a risk of disease outbreaks. Additionally, there is a risk of a
disease outbreak in the wild. While disease(s) can have devastating
population-wide effects when they occur, there are efforts in place to
prevent and manage disease outbreaks in conservation hatcheries and
aquaculture facilities. Disease is not presently impacting the GOM DPS.
However, the efforts in place to manage this risk cannot completely
eliminate the potential for disease outbreak. Further, if a large
outbreak were to occur, it could have significant impacts on the GOM
DPS.
Predation
Predation is a natural and necessary process in properly
functioning aquatic ecosystems (for a comprehensive discussion see
section 8.3.1 of Fay et al. (2006)). Native freshwater fishes known to
prey on Atlantic salmon include brook trout, burbot, American eel,
fallfish, and common shiners. In estuarine and marine environments
Atlantic salmon are prey to striped bass, Atlantic cod, pollock,
porbeagle shark, Greenland shark, Atlantic halibut, and many other
species. Many species of birds, mink, and several species of seal also
prey on Atlantic salmon. Thus, predation levels may contribute to the
low marine survival regimes currently experienced by the GOM DPS.
Atlantic salmon have evolved a suite of strategies that allow them
to co-exist with the numerous predators they encounter throughout their
life cycle. However, natural predator-prey relationships in aquatic
ecosystems in Maine have been substantially altered through the spread
of nonnative fish species (e.g., smallmouth bass); habitat alterations;
site specific and cumulative delay, injury, or stress experienced
during migration and passage over/through dams; and the decline of
other diadromous species that would otherwise serve as an alternative
prey source for fish that feed on Atlantic salmon smolts and adults.
For example, in the estuarine environment, cormorants are an important
predator of outmigrating smolts. However, the abundance of alternative
prey sources such as alewives likely minimized the impact of cormorant
predation on the GOM DPS historically. Similarly, changes in fish
assemblages due to stocking of non-native species have resulted in
predator species inhabiting many of the same areas used by Atlantic
salmon. This is particularly true of smallmouth bass and brown trout
(van de Ende, 1993; MASC and MIFW, 2002). The threat posed by these
predator species is simply compounded in areas where Atlantic salmon
are experiencing physiological stress due to obstructions to passage
(Raymond, 1979; Mesa, 1994; Blackwell et al., 1997) and poor habitat
quality and complexity (Cunjak, 1996; Blackwell and Krohn, 1997;
Larinier, 2000).
In summary, the impact of predation on the GOM DPS of Atlantic
salmon is important because of the imbalance between the very low
numbers of adults returning to spawn and the increase in population
levels of some native predators such as double-crested cormorants,
striped bass, and several species of seals as well as non-native
predators, such as smallmouth bass. Predation acts as a stressor on the
GOM DPS because of high levels of predators and low numbers of Atlantic
salmon.
Factor D. Inadequacy of Existing Regulatory Mechanisms
A variety of state and Federal statutes and regulations directly or
indirectly address potential threats to Atlantic salmon and their
habitat. These laws are complemented by international actions under
NASCO and many interagency agreements and state-Federal cooperative
efforts specifically designed to protect Atlantic salmon.
Implementation and enforcement of these laws and regulations could be
strengthened to further protect Atlantic salmon.
Dams
As stated previously, Atlantic salmon require a diverse array of
well connected habitat types in order to complete their life history.
Present conditions within the range of the GOM DPS only allow salmon to
access a fraction of the habitat that was historically accessible. Even
where salmon can presently access suitable habitat, they must often
pass several dams to reach their natal spawning habitat.
Hydroelectric dams: Hydroelectric dams in the GOM DPS are licensed
by the FERC under the FPA. Currently, within the historical range of
Atlantic
[[Page 29371]]
salmon in the GOM DPS there are 19 hydroelectric dams in the
Androscoggin watershed, 18 in the Kennebec watershed, and 23 in the
Penobscot watershed. In the Androscoggin watershed 16 hydroelectric
dams within the range of the GOM DPS are impassable due to the lack of
fishways. In the Kennebec watershed, 15 dams are impassable, along with
12 dams in the Penobscot watershed. Presently, 15 dams in the
Androscoggin, 7 dams in the Kennebec, and 9 dams in the Penobscot are
FERC-licensed without any specific fish passage requirements.
1. Mechanisms Available at Hydroelectric Dams Outside of FERC
(Re)licensing
Several mechanisms exist within the framework of the FPA that could
potentially be used to address impacts of dams. However, many of these
mechanisms are only available in relicensing. Of the 70 dams licensed
by FERC in Maine, 3 are currently in relicensing, 3 are covered by the
Penobscot River Restoration Project with plans to remove them before
expiration of their licenses, and 8 will be up for relicensing in the
2010s, 22 in the 2020s, 19 in the 2030s, 11 in the 2040s, and 4 in the
2050s. Thus, the bulk of these projects will not be up for relicensing
for 10 to 20 years or more. The current licenses for many, though by no
means all, of these projects contain reservations of FPA section 18
authority that could allow fishways to be prescribed by the Services
(16 U.S.C. 811). However, exercise of that authority requires
administrative proceedings before the FERC and the Services which could
themselves take several years, and the outcome is far from certain. As
to the remainder of the projects whose licenses contain no reserved
authority, reopening of these licenses may be dependent upon the
success of a petition to the FERC to exercise its own reserved
authority. This is not a dependable recourse as the decision to even
consider such a petition is subject to FERC's discretion. Additional
avenues may be available, consistent with the Interagency Task Force
Report on Improving Coordination of ESA Section 7 Consultation with the
FERC Licensing Process, but these remain largely untested.
Furthermore, lack of fish passage is not the only threat to salmon
caused by hydroelectric dams. The effects of habitat degradation and
the altered environmental features that favor nonnative species pose an
equal or even greater impediment to Atlantic salmon recovery via
reduction in production capacity of freshwater rearing areas above
dams. These threats may not be addressed by the Services' reserved
authority under Section 18 of the FPA; the only mechanism available
outside of relicensing is a petition to FERC to exercise its own
discretionary authority.
2. Mechanisms Available at Hydroelectric Projects in FERC (Re)licensing
Even in relicensing, the regulatory mechanisms for protection of
salmon are inadequate to remove the significant threat to the survival
of the species posed by dams. First, fish passage may be addressed by
the Services in relicensing pursuant to their mandatory authority under
Section 18 of the FPA (16 U.S.C. 811). However, as noted above, this
requires a lengthy administrative proceeding before the Services and
FERC, and the outcome is not certain. Moreover, the result is a FERC
license containing a requirement to construct and operate fish passage.
However, a substantial amount of mortality and passage inefficiency may
occur even with fishways in place, given that fish passage facilities
are never 100 percent efficient. Further, enforcement of FERC licenses
can be done only by FERC, is subject to administrative processes with
uncertain outcome, and has frequently, in the Services' view, been less
than prompt where fish passage or fish habitat issues have been at
stake.
The other threats posed by dams to Atlantic salmon, besides lack of
fish passage, may also be addressed in relicensing by the Services, via
Sections 10(a) and 10(j) of the FPA (16 U.S.C. sections 797 and 803).
However, these are mechanisms for making recommendations to the FERC,
which factors them into the balancing of factors in its public interest
determination under Section 10(a) of the FPA. There is no guarantee
that species protection would be a controlling factor in the FERC's
decision. In practice, such recommendations are often not required by
the FERC (Black et al., 1998).
The Services recognize that they and the FERC are not the only
authorities with a role to play in protecting fish in hydropower
relicensing. For a hydropower project to be relicensed by the FERC, the
State of Maine must first certify that continued operation of the
project will comply with Maine's water quality standards pursuant to
Section 401 of the CWA. The MDEP is the certifying agency for all
hydropower project licensing and relicensing in the State of Maine,
except for projects in unorganized territories subject to permitting by
the Land Use Regulation Commission (LURC). Through the water quality
certification process, the State of Maine can require fish passage and
habitat enhancements at FERC licensed hydroelectric projects (See S.D.
Warren v. Maine Board of Environmental Protection 547 U.S. 370, 126
S.Ct. 1843 (2006)). As with Section 18 authority, though section 401
authority is binding on the FERC, it requires administrative
proceedings with uncertain outcomes. Also, it is not clear that this
mechanism is available except in relicensing, or where MDEP has
specifically reserved authority to alter the terms of its prior
certification. Authority under section 401 of the CWA permits the
certifying state to certify that the discharge will comply with the
terms of the CWA, including any state water quality standards. It is
not clear that section 401 permits regulation of conditions in the
reservoirs above dams, except indirectly where the water quality of the
reservoir is controlled by the quality of discharges from an upstream
dam.
Finally, in other parts of the country, mandatory conditioning
authority under section 4(e) of the FPA is often used by the Services
in relicensing to recommend fisheries enhancements. However, this
authority is only available to a Federal agency where there are Federal
lands under its jurisdiction within the project boundary, and acts as a
mechanism to protect the ``reservation.'' Federal lands where Section
4(e) could be applied are rare in Maine, and 4(e) does not provide an
adequate mechanism for protection of Atlantic salmon throughout the GOM
DPS.
Non-hydroelectric dams: The vast majority of dams within the range
of the GOM DPS do not require either a FERC license or MDEP water
quality certificate. These dams are typically small dams historically
used for a variety of purposes, including flood control, storage, and
process water (for industries such as blueberry harvesting). Because
they do not generate electricity, they are not subject to the
jurisdiction of the FERC under the FPA. Practically none of these dams
within the range of the GOM DPS have fish passage facilities, and all
impact historical Atlantic salmon habitat. Many of these non-
jurisdictional dams are no longer used for their intended purposes;
however, many smaller dams maintain water levels in lakes and ponds.
Lack of fish passage and other impacts to salmon may currently be
addressed only through the mechanisms of State law.
Fish passage may be required by the State of Maine under 12 M.R.S.A
section 12760. However, this requires an administrative process and a
hearing, if one is requested by the dam owner. An
[[Page 29372]]
order to construct fish passage under this statute requires a finding
that fish can be restored ``in substantial numbers'' and that habitat
above the dam ``is sufficient and suitable to support a substantial
commercial or recreational fishery.'' These are very different
considerations from the ESA's focus on prevention of extinction.
Furthermore, this statute has never been used to require fish passage
at any dam in Maine, and, despite the one hearing ongoing at this time,
the statute remains untested in the courts and at the administrative
level. Nor, of course, does it address threats beyond lack of fish
passage.
Finally, although the MDEP can be petitioned by the public to set
minimum flows and water levels at the dams not under FERC jurisdiction,
the MDEP has no direct statutory authority under Maine law to require
fisheries related enhancements without public request or petition.
Removal of non-hydropower generating dams in Maine may require a permit
under the Maine Natural Resources Protection Act or the Maine Waterway
Development and Conservation Act. Owners of non-hydroelectric dams can
petition the MDEP to be released from ownership; however, the MDEP does
not have the authority to require dam removal without the consent of
the owner.
In summary, the inadequacy of existing regulatory mechanisms for
dams significantly affects the GOM DPS because dams pose a significant
threat. Existing regulatory mechanisms do not provide a timely and
dependable means to eliminate the effects of dams on salmon and their
habitat.
Water Withdrawals
The State of Maine has made substantial progress in regulating
water withdrawals. In 2007, it finalized a new rule (Chapter 587 of the
Code of Maine Rules ``In-stream flow and water level standards'') that
establishes river and stream flows and lake and pond water levels to
protect aquatic life and other designated uses in Maine's waters. The
new standards are based on maintaining natural variation of flows and
water levels, but allow variances if water use will still be protective
of applicable state and Federal water quality classifications. The flow
standards are based on seasonal aquatic base flows. We believe that the
water rules for class AA waters will be protective of Atlantic salmon
because the flow standards are based on natural flows, and exceptions
are allowed only under clearly defined limits. However, the flow
standards for class A, B, and C waters are based on seasonal base
flows, which allow withdrawals when flow is at or below median monthly
flow. These standards are not sufficiently protective of Atlantic
salmon because they allow reduced in-stream flows that reduce habitat,
increase water temperature, and decrease dissolved oxygen (as described
in Factor A, above).
Water withdrawals that reduce flow below the median monthly flow
are a stressor on the GOM DPS (see Factor A). These withdrawals are
allowed under the Maine flow standards; therefore, the existing
regulatory mechanisms for water quantity are inadequate.
Water Quality
As described above in Factor A, the MDEP administers the NPDES
program under the CWA (known as the MPDES program). MDEP issues permits
for point source discharges from freshwater hatcheries, municipal
facilities, and other industrial facilities. Maine's water
classification system provides for different water quality standards
for different classes of waters (e.g., there are four classes for
freshwater rivers all of which are found within the GOM DPS range).
However, these standards are not based on water quality requirements of
Atlantic salmon. Also, as described under Factor A above, there have
been cases when water quality did not meet standards and was at levels
that negatively impact salmon. Therefore, we are concerned that water
quality standards may not be sufficiently protective of Atlantic salmon
and that lack of compliance with existing standards may continue to
harm salmon.
Factor A also describes concerns we have regarding non-point source
discharges. Sedimentation and other non-point source discharges related
to forestry activities are regulated by the Shoreland Zoning Act, Maine
Forest Practices Act, Natural Resource Protection Act, Protection and
Improvement of Waters Act, Erosion and Sedimentation Control Law, and
the Statewide Standards for Timber Harvesting and Related Activities in
Shoreland Areas. Non-compliance with these regulatory mechanisms has
resulted in impacts to Atlantic salmon habitat and continues to pose a
risk to the GOM DPS (Fay et al., 2006, page 83).
In summary, the MPDES program and the associated water quality
standards do not regulate all potential water quality problems for
salmon. We have determined that lack of compliance with existing water
quality standards and with regulations to reduce sedimentation from
forestry activities may continue to impact Atlantic salmon. Therefore,
we find that inadequacy of existing regulatory mechanisms for water
quality is a stressor to the GOM DPS.
Factor E. Other Natural or Manmade Factors Affecting Its Continued
Existence
Artificial Propagation
In the proposed rule we included a discussion of artificial
propagation under Factor E. However, because of the essential role of
conservation hatcheries in currently sustaining the GOM DPS of Atlantic
salmon, in this final rule we evaluated the positive and negative
effects of hatcheries in the status of the species section. We find
that, in the short-term, conservation hatcheries are a benefit to the
GOM DPS. The role of the conservation hatchery program is discussed
above in the ``Status of the GOM DPS'' section.
Aquaculture
Atlantic salmon that escape from farms and commercial hatcheries
pose a threat to native Atlantic salmon populations (Naylor et al.,
2005) because captive-reared fish are selectively bred to promote
behavioral and physiological attributes desirable in captivity (Hindar
et al., 1991; Utter et al., 1993; Hard et al., 2000); for further
discussion of the threat of aquaculture see section 8.5.2 in Fay et al.
(2006)). Experimental tests of genetic divergence between farmed and
wild salmon indicate that farming generates rapid genetic change as a
result of both intentional and unintentional selection in culture and
those changes alter important fitness-related traits (McGinnity et al.,
1997; Gross, 1998). Consequently, aquaculture fish are often less fit
in the wild than naturally produced salmon (Fleming et al., 2000).
Annual invasions of escaped adult aquaculture salmon can disrupt local
adaptations and reduce genetic diversity of wild populations (Fleming
et al., 2000). Bursts of immigration also disrupt genetic
differentiation among wild Atlantic salmon stocks, especially when wild
populations are small (Mork, 1991). Natural selection may be able to
purge wild populations of maladaptive traits but may be less able to if
the intrusions occur year after year. Under this scenario, population
fitness is likely to decrease as the selection from the artificial
culture operation overrides wild selection (Hindar et al., 1991;
Fleming and Einum, 1997), a process called outbreeding depression. The
threat of outbreeding depression is likely to be greater in North
America where aquaculture salmon have been based, in part, on European
strain. To
[[Page 29373]]
minimize these risks, the use of non-North American strains of salmon
has been phased out in the United States.
In addition to genetic effects, escaped farmed salmon can disrupt
redds of wild salmon, compete with wild salmon for food and habitat,
transfer disease or parasites to wild salmon, and degrade benthic
habitat (Windsor and Hutchinson, 1990; Saunders, 1991; Youngson et al.,
1993; Webb et al., 1993; Clifford et al., 1997). Farmed salmon have
been documented to spawn successfully, but not always at the same time
as wild salmon (Lura and Saegrov, 1991; Jonsson et al., 1991; Webb et
al., 1991; Fleming et al., 1996). Late spawning aquaculture fish could
limit wild spawning success through redd superimposition. There has
also been recent concern over potential interactions when wild adult
salmon migrate past closely spaced cages, creating the potential for
behavioral interactions, disease transfer, or interactions with
predators (Lura and Saegrov, 1991; Crozier, 1993; Skaala and Hindar,
1997; Carr et al., 1997; DFO, 1999). In Canada, the survival of wild
postsmolts moving from Passamaquoddy Bay to the Bay of Fundy was
inversely related to the density of aquaculture cages (DFO, 1999).
Atlantic salmon aquaculture has developed and expanded in the North
Atlantic since the early 1970s. Production of farmed Atlantic salmon in
2007 was estimated at over 1.27 million metric tonnes worldwide,
859,103 metric tonnes in the North Atlantic, and 8.16 metric tonnes in
Maine (ICES, 2008). The Maine Atlantic salmon aquaculture industry is
concentrated in Cobscook Bay near Eastport, Maine. The industry in
Canada, just across the border, is approximately twice the size of the
Maine industry. Five freshwater commercial hatcheries in the United
States have provided smolts to the sea cages and produce up to four
million smolts per year.
Three primary broodstock lines have been used for farm production.
The lines include fish from the Penobscot River, St. John River, and
historically an industry strain from Scotland. The Scottish strain was
imported into the United States in the early 1990s and is composed
primarily of Norwegian strains, frequently referred to as Landcatch.
Milt of Norwegian origin was also imported by the industry from Iceland
(Baum, 1998). However, placement of reproductively viable non-North
American origin Atlantic salmon into marine cages in the United States
has been eliminated.
Escaped farmed salmon are known to enter Maine rivers. For example,
at least 17 percent (14 of 83 fish) of the rod catch in the East
Machias River were captive-reared adults in 1990. In addition to the
frequency and magnitude of escape events that drive annual variability,
returns of captive-reared adults to Maine rivers are influenced by the
amount of production and proximity of rearing sites in adjacent bays.
About 60 percent of commercial salmon production in Maine occurs at
sites on Cobscook and Passamaquoddy Bays, into which the Dennys River
flows; 35 percent on Machias Bay and the estuary of the Little River,
within 11.26 kilometers of the Machias and East Machias Rivers; and the
remainder on the estuaries of the Pleasant and Narraguagus Rivers, or
adjacent to Blue Hill Bay. The percentage of captive-reared fish in
adult returns is highest in the St. Croix (not a part of the GOM DPS)
and Dennys Rivers and lowest in the Penobscot River (less than 0.01
percent in the years 1994 to 2001), with the Narraguagus runs having
low and sporadic proportions of captive-reared salmon.
A large escape event occurred in 2005 when four marine salmon
aquaculture sites in Western New Brunswick, Canada, were vandalized
from early May through November 2005, resulting in approximately
136,000 escaped farmed salmon. Most escapees were unmarked 1SW salmon
of similar size (2 to 5 kg). Escaped aquaculture-origin salmon from
these vandalism events entered the Dennys River and possibly other
Eastern Maine rivers in 2005. The Services and MDMR cooperated to
implement a program to minimize genetic and ecological risks from this
escape (Bean et al., 2006).
Aquaculture escapees and resultant interactions with native stocks
are expected to continue to occur within the range of the GOM DPS given
the continued operation of farms. While recent containment protocols
have greatly decreased the incidence of losses from hatcheries and
pens, the risk of large escapes occurring is still significant. Escaped
farmed fish are of great concern in Maine because, even at low numbers,
they can represent a substantial portion of the returns to some rivers.
Wild populations at low levels are particularly vulnerable to genetic
intrusion or other disturbance caused by escapees (Hutchings, 1991;
DFO, 1999).
Despite the concerns with aquaculture described above, recent
advances in containment and marking of aquaculture fish limit the
negative impacts of aquaculture fish on the GOM DPS. Permits issued by
the Army Corps of Engineers (ACOE) and MDEP require: genetic screening
to ensure that only North American strain salmon are used in commercial
aquaculture; marking to facilitate tracing fish back to the source and
cause of the escape; containment management plans and audits; and
rigorous disease screening.
In summary, aquaculture is a stressor to the GOM DPS. If the
current regulatory measures were no longer in place, were less
protective, or less effective, the threat from aquaculture would be
much greater.
Low Marine Survival
As noted previously, Atlantic salmon leave Maine rivers as smolts,
and the majority spend 2 years at sea before returning to spawn.
Survival during the time at sea directly influences the number of
adults that return to spawn. During this extensive marine migration,
U.S. Atlantic salmon can be affected directly and indirectly by
commercial fisheries (discussed in Factor B) and natural mortality.
Given significant reductions in commercial intercept fisheries, the
continued low marine survival rates indicate that natural mortality is
having a significant impact. Natural mortality in the marine
environment can be attributed to four general sources: predation
(Factor C), starvation, disease/parasites (Factor C), and abiotic
factors (e.g., ocean conditions). While our understanding of the marine
ecology of Atlantic salmon has increased substantially in the past
decade, the specific role or contribution of the four sources
identified above remains unclear.
In general, return rates for Atlantic salmon across North America
have declined over the last 30 years (ICES, 1998). Chaput et al. (2005)
reported on the possibility of a phase (or regime) shift of
productivity for Atlantic salmon in the Northwest Atlantic. A phase or
regime shift refers to a large and sudden change in abundance (Beamish
et al., 1999). Evidence is presented that the productivity of North
American Atlantic salmon in the Northwest Atlantic Ocean has decreased
since the early 1990s, likely the result of reduced marine survival
(Chaput et al., 2005). Specifically, there has been a decrease in the
recruit-per-spawner relationship for these populations, which likely
occurred over several years in the late 1980s into the early 1990s.
This has resulted in a similar number of lagged spawners (index of the
parental stock that produced the pre-fishery abundance) resulting in a
2-3 fold decrease in the number of pre-fishery abundance fish (number
of North
[[Page 29374]]
American 2SW salmon in the ocean at a specific time) when comparing
pre-early 1990s to post-early 1990s. The concept of phase shift has
previously been documented and discussed for Pacific salmon populations
(Beamish et al., 1999). Chaput et al. (2005) did not speculate on the
causes of the reduced marine survival.
The phase shift described above resulting in lower survival of
salmon in the Northwest Atlantic beginning in the 1990s is supported by
documented low marine survival rates since 1991 for U.S. stocks of
Atlantic salmon, (see section 8.5.3 of Fay et al. (2006)). For the
period 2003 to 2007, 2SW return rates for wild Narraguagus River smolts
ranged from 0.54 to 0.94 percent. Return rates for this same period for
2SW hatchery Penobscot River smolts ranged from 0.11 to 0.17 percent
(ICES, 2008). Data for 2007, which is based on the 2005 and 2006 smolt
cohorts, showed that 1SW and 2SW adult returns for hatchery and wild
populations in many rivers in Newfoundland, Quebec, Scotia-Fundy, and
the United States were the lowest in the available time series (1971-
2000) (ICES, 2008).
North American stocks have experienced greater declines than
European stocks, and southern stocks have experienced greater declines
than northern stocks. Bley and Moring (1988) have suggested that
Atlantic salmon with longer migration routes typically suffer from
lower marine survival rates. Stock abundances and management regimes
are highly variable throughout the range. The synchronous population
declines on both sides of the North Atlantic despite diverse management
regimes suggests that large scale processes in the common marine
environment are affecting Atlantic salmon in the ocean and are at least
partially responsible for the negative trends in abundance (Friedland
et al., 2003; Jonsson and Jonsson, 2004; Friedland et al., 2005; Spares
et al., 2007). Furthermore, sonic telemetry studies of emigrating
smolts in southern European and North American rivers suggest that
smolt mortality in estuaries, though variable, is broadly similar in
both regions (ICES, 2008). Numerous ultrasonic tracking studies have
begun to provide estimates of nearshore mortality for a number of
different populations (Dieperink et al., 2002; Lacroix et al., 2005;
Kocik et al., 2008), and it has been suggested that nearshore survival
has a particularly large influence on overall marine survival (Ritter,
1989; Dieperink et al., 2002; Potter et al., 2003). These and other
studies demonstrate that poor marine survival is being experienced
throughout the Atlantic Ocean and is heavily influenced by nearshore
survival in addition to open ocean survival and that patterns of
decline are most evident in southern stocks (ICES, 2008). Higher
freshwater productivity in southern populations may offset poorer
marine survival; however, as mentioned above, marine survival is much
more variable and has a highly significant impact on adult production
regardless of freshwater production.
Efforts to understand marine survival are being undertaken at
national and international levels. NMFS is specifically engaged in
activities at the national level (e.g., smolt trapping and telemetry
studies, and post-smolt trawl surveys) in an effort to understand
migration/survival dynamics of smolts, survival estimates by ecological
zone, smolt health and behavior during transition to the marine
environment, and environmental conditions/ecosystem health during smolt
migration. Data collected from these studies inform salmon management
at the national levelands contribute to international efforts. As
stated previously, the United States is a member of NASCO, an
international treaty organization. Through NASCO, the United States
participates in high seas sampling, marine research, and the sampling
program for the West Greenland fishery. NMFS is also currently
participating in an effort supported by NASCO called Salmon At Sea
(SALSEA), an initiative to develop international scientific
collaboration to understand marine survival issues. SALSEA is geared
towards understanding marine survival issues on the high seas. Ongoing
SALSEA work includes, but is not limited to, efforts to merge genetics
and ecology data to try and understand marine migration and
distribution patterns, trawl surveys, and fishery sampling.
Marine survival is thus critical to shaping recruitment patterns in
Atlantic salmon, with low marine survival causing the low abundance of
adult salmon; however, the mechanisms of the observed persistent
decline in marine survival remain unknown. It is clear that marine
survival has to improve dramatically in the future in order to reverse
the GOM DPS decline.
It is important to note that the above discussion focuses primarily
on survival at sea, beyond the territorial waters of any one country.
Mortality of outmigrating smolts in the estuaries and bays of the GOM
DPS is also affecting the population. Tagging and tracking studies
conducted by NMFS indicate that approximately half of the smolts
leaving our rivers do not enter the open ocean. Improvements in
survival in this transition zone could ultimately result in
improvements in marine survival. It is also likely that if we are able
to identify the factors affecting survival of outmigrating smolts in
our estuaries and bays, we will have a greater chance of influencing
those factors than the factors that may be affecting salmon survival at
sea. In summary, the observed, persistent decline in marine survival is
directly responsible for the low abundance of adult salmon. Low marine
survival poses a significant threat to the GOM DPS because it is
driving population status and projections for recovery. Recovery of the
species is dependent on increases in marine survival. The mechanisms
driving low marine survival remain unknown.
Depleted Diadromous Communities
The ecological setting in which Maine Atlantic salmon evolved is
considerably different than what exists today. Ecological changes that
have occurred over the last 200 years are ubiquitous and span a wide
array of spatial and temporal scales. Of particular concern for
Atlantic salmon recovery efforts within the range of the GOM DPS is the
dramatic decline observed in the diadromous fish community. At historic
abundance levels, Fay et al. (2006) and Saunders et al. (2006)
hypothesized that several of the co-evolved diadromous fishes may have
provided substantial benefits to Atlantic salmon through at least four
mechanisms: serving as an alternative prey source for salmon predators;
serving as prey for salmon directly; depositing marine-derived
nutrients in freshwater; and increasing substrate diversity of rivers.
A brief description of each mechanism is provided below.
Fay et al. (2006) and Saunders et al. (2006) hypothesized that the
historically large populations of clupeids (i.e., members of the family
Clupeidae, such as alewives, blueback herring, and American shad)
likely provided a robust alternative forage resource (or prey buffer)
for opportunistic native predators of salmon during a variety of events
in the salmon's life history. First, pre-spawn adult alewives likely
served as a prey buffer for migrating Atlantic salmon smolts. Evidence
for this relationship includes significant spatial and temporal overlap
of migrations, similar body size, numbers of alewives that exceeded
salmon smolt populations by several orders of magnitude (Smith, 1898;
Collette and Klein-MacPhee, 2002), and a higher caloric content per
individual (Schulze, 1996). Thus, alewives were likely a substantial
[[Page 29375]]
alternative prey resource (i.e., prey buffer) that protected salmon
smolts from native predators such as cormorants, otters, ospreys, and
bald eagles within sympatric migratory corridors (Mather, 1998; USASAC,
2004). Second, adult American shad likely provided a similar prey
buffer to potential predation on Atlantic salmon adults by otters and
seals. Pre-spawn adult shad would enter these same rivers and begin
their upstream spawning migration at approximately the same time as
adult salmon. Historically, shad runs were considerably larger than
salmon runs (Atkins and Foster, 1869; Stevenson, 1898). Thus, native
predators of medium to large size fish in the estuarine and lower river
zones could have preyed on these 1.5 to 2.5 kg size fish readily.
Third, juvenile shad and blueback herring may have represented a
substantial prey buffer from potential predation on Atlantic salmon fry
and parr by native opportunistic predators such as mergansers, herons,
mink, and fallfish. Large populations of juvenile shad (and blueback
herring, with similar life history and habitat preferences to shad)
would have occupied mainstem and larger tributary river reaches through
much of the summer and early fall. Juvenile shad and herring would
ultimately emigrate to the ocean, along with juvenile alewives from
adjacent lacustrine habitats, in the late summer and fall. Recognizing
that the range and migratory corridors of these juvenile clupeids would
not be precisely sympatric with juvenile salmon habitat, there
nonetheless would have been a substantial spatial overlap amongst the
habitats and populations of these various juvenile fish stocks. Even in
reaches where sympatric occupation by juvenile salmon and juvenile
clupeids may have been low or absent, factors such as predator mobility
and instinct driven energetic efficiency (i.e., optimal foraging
theory) need to be considered since the opportunity for prey switching
would have been much greater than today, and the opportunity for prey
switching may produce stable predator-prey systems with coexistence of
both prey and predator populations (Krivan, 1996).
At historical abundance levels, other diadromous species also
represented significant supplemental foraging resources for salmon in
sympatric habitats. In particular, anadromous rainbow smelt are known
to be a favored spring prey item of Atlantic salmon kelts (Cunjak et
al. 1998). A 1995 radio tag study found that Miramichi River (New
Brunswick, Canada) kelts showed a net upstream movement shortly after
ice break-up (Komadina-Douthwright et al., 1997). This movement was
concurrent with the onset of upstream migrations of rainbow smelt
(Komadina-Douthwright et al., 1997). In addition, Moore et al. (1995)
suggested that the general availability of forage fishes shortly after
ice break-up in the Miramichi could be critical to the rejuvenation and
ultimate survival of kelts as they prepared to return to sea. Kelts
surviving to become repeat spawners are especially important, from a
demographic perspective, due to higher fecundity (Baum, 1997; NRC,
2004). The historical availability of anadromous rainbow smelt as
potential kelt forage in lower river zones may have been important in
sustaining the viability of this salmon life stage. Conversely, the
broad declines in rainbow smelt populations may be partially
responsible for the declining occurrence of repeat spawners in Maine's
salmon rivers.
Historically, the upstream migrations of large populations of adult
clupeids, sea lamprey, and salmon themselves, provided a conduit for
the import and deposition of biomass and nutrients of marine origin
into freshwater environments. Mechanisms of direct deposition included
discharge of urea, discharge of gametes on the spawning grounds, and
deposition of adult carcasses (Durbin et al., 1979). Migrations and
other movements of mobile predators and scavengers of adult carcasses
likely resulted in further distribution of imported nutrients
throughout the freshwater ecosystem. Conversely, juvenile outmigrants
of these sea-run species represented a massive annual outflux of forage
resources for Gulf of Maine predators, while also completing the cycle
of exporting base nutrients back to the ocean environment. These types
of diffuse mutualism are only recently being recognized (Hay et al.,
2004). Sea lampreys also likely played a role in nutrient cycling.
Lampreys prefer spawning habitat that is very similar (location and
physical characteristics) to that used by spawning Atlantic salmon
(Kircheis, 2004). Adult lampreys spawn in late spring, range in weight
from 1 to 2 kg, and experience 100 percent post-spawning mortality on
spawning grounds (semelparous). This results in the deposition of
marine-origin nutrients at about the same time that salmon fry would be
emerging from redds and beginning to occupy adjacent juvenile
production habitats. These nutrients would likely have enhanced the
primary production capability of these habitats for weeks or even
months after initial deposition, and would gradually be transferred
throughout the trophic structure of the ecosystem, including those
components most important to juvenile salmon (e.g., macroinvertebrate
production).
Sea lampreys likely provide an additional benefit to Atlantic
salmon spawning activity in sympatric reaches. In constructing their
nests, lamprey carry stones from other locations and deposit them
centrally in a loose pile within riffle habitat and further utilize
body scouring to clean silt off stones already at the site (Kircheis,
2004). Ultimately, a pile of silt-free stones as deep as 25 cm and as
long as a meter is formed (Leim and Scott, 1966; Scott and Scott,
1988), into which the lamprey deposit their gametes. The stones
preferred by lampreys are generally in the same size range as those
preferred by spawning Atlantic salmon. Thus, lamprey nests can be
attractive spawning sites for Atlantic salmon (Kircheis, 2004).
Kircheis (2004) also notes the lamprey's silt-cleaning activities
during nest construction that may improve the ``quality'' of the
surrounding environment with respect to potential diversity and
abundance of macroinvertebrates, a primary food item of juvenile
salmon.
Depleted diadromous fish communities are a stressor to the GOM DPS.
Because diadromous fish populations have been significantly reduced,
ecological benefits from marine derived nutrient deposition, prey
buffering, and alternative sources of food for Atlantic salmon are
likely significantly lower today compared to historical conditions.
These impacts may be contributing, at some undetermined level, to
decreased marine survival through the reduction of prey for
reconditioning kelts, through increased predation risks for smolts in
lower river and estuarine areas, and through increased predation risks
to adults in estuarine and lower river areas. Although these impacts do
not occur in the open ocean, the demographic impact to the species
occurs after smolt emigration, and is thus a component of the marine
survival regime.
Competition
Prior to 1800, the resident riverine fish communities in Maine were
relatively simple, consisting of brook trout, cusk (burbot), white
sucker, and a number of minnow species. Today, Atlantic salmon co-exist
with a diverse array of nonnative resident fishes, including brown
trout, largemouth bass, smallmouth bass, and northern pike
[[Page 29376]]
(MIFW, 2002). The range expansion of nonnative fishes is important,
given evidence that niche shifts may follow the addition or removal of
other competing species (Fausch, 1998). For example, in Newfoundland,
Canada, where fish communities are simple, Atlantic salmon inhabit
pools and lakes that are generally considered atypical habitats in
systems where there are more complex fish communities (Gibson, 1993).
Use of lacustrine (or lake) habitat, in particular, can increase smolt
production (Matthews et al., 1997). Conversely, if salmon are excluded
from these habitats through competitive interactions, smolt production
may suffer (Ryan, 1993). Even if salmon are not completely excluded
from a given habitat type, they may select different, presumably sub-
optimal, habitats in the presence of certain competitors (Fausch,
1998). Thus, competitive interactions may limit Atlantic salmon
production through niche constriction (Hearn, 1987).
The range expansion of nonnative species (e.g., smallmouth bass,
brown trout, and rainbow trout) is of particular concern since these
species often require similar resources as salmon and are, therefore,
expected to be competitors for food and space. MIFW currently stocks
landlocked Atlantic salmon, brown trout, brook trout, rainbow trout and
splake in Atlantic salmon river drainages, posing a threat to Atlantic
salmon in the GOM DPS (Fay et al., 2006). The range of northern pike
has also been expanded through stocking, and they now exist in at least
16 lakes within the Kennebec and Androscoggin drainages as well as
Pushaw Lake that drains into Lower Penobscot River (MIFW, 2001). Yellow
perch, white perch, and chain pickerel were historically native to
Maine, though their range has been expanded by stocking and subsequent
colonization (MIFW, 2002).
Brown trout, rainbow trout, and splake are all non-native species
known to prey on Atlantic salmon and have been stocked throughout the
range of the GOM DPS by the MIFW (Fay et al., 2006). The species most
likely to compete for food and habitat with Atlantic salmon in the GOM
DPS include brown trout, land locked Atlantic salmon, brook trout, and
smallmouth bass (Fay et al., 2006). Atlantic salmon and rainbow trout
juveniles require similar resources; therefore, competition is expected
to be significant in areas of overlap (Fay et al., 2006). Rainbow trout
would be important competitors if they overlapped with Atlantic salmon
to a greater extent (Fay et al., 2006). Rainbow trout are present in at
least three reaches of the Kennebec River and in the Androscoggin (Fay
et al., 2006). Illegal introductions and legal stocking programs
continue to expand their range (Pellerin, 2002). Atlantic salmon and
rainbow trout juveniles require similar resources; therefore,
competition is expected to be significant in areas of overlap (Fay et
al., 2006).
There are some areas within the range of the GOM DPS where
landlocked Atlantic salmon spawn successfully and rear in sympatry with
anadromous Atlantic salmon (Fay et al., 2006). For these populations,
competitive interactions for food and habitat are expected to be very
high given the nearly identical early life history requirements of the
two ecotypes (Fay et al., 2006). Competition between brown trout and
Atlantic salmon is expected to be significant in areas where they co-
occur given similarities in their life history requirements (Fay et
al., 2006). Brown trout currently inhabit the Androscoggin, Kennebec
Rivers, and the Piscataquis River in the upper Penobscot watershed, as
well as many lakes and ponds (Boland, 2001; MIFW, 2002). Most evidence
suggests that brown trout will displace or otherwise outcompete
Atlantic salmon from pool habitats in both summer and winter (Kennedy
and Strange, 1986; Harwood et al., 2001). The ability of brown trout to
outcompete Atlantic salmon has significant negative effects on Atlantic
salmon, including changes in habitat use and behavior that may limit
salmon production through niche constriction when the two species co-
occur (Hearn, 1987; Fausch, 1988). In summary, competition is a
stressor to the GOM DPS because it can exclude salmon from preferred
habitats, reduce food availability, and increase predation.
Climate Change
Since the 1970s there has been a historically significant change in
climate (Greene et al., 2008). Climate warming has resulted in
increased precipitation, river discharge, and glacial and sea-ice
melting (Greene et al., 2008). The past 3 decades have witnessed major
changes in ocean circulation patterns in the Arctic, and these were
accompanied by climate associated changes as well (Greene et al.,
2008). Shifts in atmospheric conditions have altered Arctic ocean
circulation patterns and the export of freshwater to the North Atlantic
(Greene et al., 2008; IPCC, 2006). With respect specifically to the
North Atlantic Oscillation (NAO), changes in salinity and temperature
are thought to be the result of changes in the earth's atmosphere
caused by anthropogenic forces (IPCC, 2006). The NAO impacts climate
variability throughout the northern hemisphere (IPCC, 2006). Data from
the 1960s through the present show that the NAO index has increased
from minimum values in the 1960s to strongly positive index values in
the 1990s and somewhat declined since (IPCC, 2006). This warming
extends over 1000 m deep and is deeper than anywhere in the world
oceans and is particularly evident under the Gulf Stream/North Atlantic
Current system (IPCC, 2006). On a global scale, large discharges of
freshwater into the North Atlantic subarctic seas can lead to intense
stratification of the upper water column and a disruption of North
Atlantic Deepwater (NADW) formation (Greene et al., 2008; IPCC, 2006).
There is evidence that the NADW has already freshened significantly
(IPCC, 2006). This in turn can lead to a slowing down of the global
ocean thermohaline (large-scale circulation in the ocean that
transforms low-density upper ocean waters to higher density
intermediate and deep waters and returns those waters back to the upper
ocean), which can have climatic ramifications for the whole earth
system (Greene et al., 2008).
The changes in freshwater export and circulation patterns have
resulted in significant salinity changes (IPCC, 2006), leading to two
main ecological shifts (Pershing et al., 2005; Greene and Pershing
2007; Greene et al., 2008). The first major ecological shift is the
biogeographic range expansion by Boreal Plankton, including trans-
Arctic exchanges of Pacific species with the Atlantic (Greene et al.,
2008). The second ecological shift had mainly affected the Northwest
Atlantic where, during the early 1990s, a dramatic shift in shelf
ecosystems occurred (Pershing et al., 2005; Greene and Pershing, 2007;
Greene et al., 2008). The major shifts observed specifically in the GOM
and Scotian shelf ecosystems in the early 1990s are specifically linked
to these changes in salinity and lower trophic level communities
(Pershing et al., 2005; Greene and Pershing, 2007; Greene et al.,
2008). These changes may be related to changes in higher trophic level
consumer populations as well (Greene et al., 2008). Shifts in
ecological communities in the Northwest Atlantic include commercially
harvested fish and crustacean populations, both of which underwent
large changes in abundance during the 1990s (Frank et al., 2005;
Pershing et al., 2005; Vilhjalmsson et al., 2005). While overfishing
was the predominant cause
[[Page 29377]]
of the collapse of cod in particular, the cold, low-salinity Arctic
waters entering the northern portion of the range of cod, seem to have
hampered their subsequent recovery (Rose et al., 2000; Vilhjalmsson et
al., 2005). Other species, such as shrimp and snow crab, have increased
in abundance in the absence of cod predation (Frank et al., 2005).
With respect to the GOM DPS, Greene et al. (2008) describe that
changes in salinity can result in more localized effects on ocean
circulation patterns and climate that are confined to the North
Atlantic basin and the adjacent landmasses. For example, these changes
specifically affect thermal regimes within the range of the GOM DPS
(see section 8.1.4 of Fay et al. (2006)). Within the range of the GOM
DPS, the spring runoff occurs earlier; water content in snow pack for
March and April has decreased; and the duration of river ice has been
reduced (Dudley and Hodgkins, 2002). Several studies indicate that
small thermal changes may substantially alter reproductive performance,
smolt development, species distribution limits, and community structure
of fish populations (Van Der Kraak and Pankhurst, 1997; McCormick et
al., 1997; Keleher and Rahel, 1996; McCarthy and Houlihan, 1997; Welch
et al., 1998; Schindler, 2001). For Atlantic salmon specifically,
Juanes et al. (2004) suggest that observed changes in adult run timing
may be a response to global climate change. Friedland et al. (2005)
summarized numerous studies that suggest that climate mediates marine
survival for Atlantic salmon as well as other fish species. Recent
analyses of bottom water temperatures found that negative NAO years are
warmer in the north and cooler in the Gulf of Maine (Petrie, 2007).
Positive NAO years are warmer in Gulf of Maine and colder in the north
(north of 45[deg] N) (Petrie, 2007). Strength of NAO is related to
annual changes in diversity of potential predators: at southern
latitudes, there are more species during positive NAO years (Fisher et
al., 2008). The effect is system-wide where 133 species showed at least
a 20 percent difference in frequency of occurrence in years with
opposing NAO states (Fisher et al., 2008).
This is currently leading to different hypotheses regarding the
effect these changes may be having on Atlantic salmon. One hypothesis
is that salmon migrating during positive NAO years confront a steeper
gradient of cooler to warmer water. This gradient may be resulting in
changes in the composition of species as Atlantic salmon undertake
their marine migration, potentially increasing the vulnerability of
Atlantic salmon to predators (Gibson, 2006; NMFS Nearshore Workshop
2, 2009). Other hypotheses being explored relate to potential
linkages between ocean climate and effects on wind velocities and
nearshore wind driven currents and adverse impacts on post smolt
migration, as well as the potential influence of air temperatures and
sea surface temperature and potential impacts on migration cues (NMFS
Nearshore Workshop 2, 2009). These current efforts to
understand changes in ocean productivity are focused on whether
environmental changes could be contributing, whether there are any
other species where similar shifts in productivity have had negative
effects, and whether there are correlations between this particular
phase shift and population dynamics of other species.
While some physiological changes at the individual level are quite
predictable when changes in temperature are known, we do not understand
how or to what degree climate change may affect the freshwater and
marine environment of the GOM DPS. At this time, we do not have enough
information to determine whether the GOM DPS is threatened or
endangered because of the effects of climate change.
Efforts Being Made To Protect the Species
Section 4(b)(1)(A) of the ESA requires the Secretary of Commerce to
make listing determinations solely on the basis of the best scientific
and commercial data available after taking into account efforts being
made to protect a species. Therefore, in making a listing
determination, we first assess a species' level of extinction risk and
identify factors that have led to its decline. We then assess existing
efforts being made to protect the species to determine if these
conservation efforts improve the status of the species such that it
does not meet the ESA's definition of a threatened or endangered
species.
In judging the efficacy of existing protective efforts, we rely on
the Services' joint ``Policy for Evaluation of Conservation Efforts
When Making Listing Decisions'' (``PECE;'' 68 FR 15100; March 28,
2003). PECE provides direction for the consideration of protective
efforts identified in conservation agreements, conservation plans,
management plans, or similar documents (developed by Federal agencies,
state and local governments, tribal governments, businesses,
organizations, and individuals) that have not yet been implemented, or
have been implemented but have not yet demonstrated effectiveness. The
policy articulates several criteria for evaluating the certainty of
implementation and effectiveness of protective efforts to aid in
determining whether a species should be listed as threatened or
endangered. Evaluation of the certainty that an effort will be
implemented includes whether: (1) The conservation effort, the
party(ies) to the agreement or plan that will implement the effort, and
the staffing, funding level, funding source, and other resources
necessary to implement the effort are identified; (2) the legal
authority of the party(ies) to the agreement or plan to implement the
formalized conservation effort, and the commitment to proceed with the
conservation effort are described; (3) the legal procedural
requirements (e.g. environmental review) necessary to implement the
effort are described, and information is provided indicating that
fulfillment of these requirements does not preclude commitment to the
effort; (4) authorizations (e.g., permits, landowner permission)
necessary to implement the conservation effort are identified, and a
high level of certainty is provided that the party(ies) to the
agreement or plan that will implement the effort will obtain these
authorizations; (5) the type and level of voluntary participation
(e.g., number of landowners allowing entry to their land, or number of
participants agreeing to change timber management practices and acreage
involved) necessary to implement the conservation effort is identified,
and a high level of certainty is provided that the party(ies) to the
agreement or plan that will implement the conservation effort will
obtain that level of voluntary participation (e.g., an explanation of
how incentives to be provided will result in the necessary level of
voluntary participation); (6) regulatory mechanisms (e.g., laws,
regulations, ordinances) necessary to implement the conservation effort
are in place; (7) a high level of certainty is provided that the
party(ies) to the agreement or plan that will implement the
conservation effort will obtain the necessary funding; (8) an
implementation schedule (including incremental completion dates) for
the conservation effort is provided; and (9) the conservation agreement
or plan that includes the conservation effort is approved by all
parties to the agreement or plan. The evaluation of the certainty of an
effort's effectiveness is made on the basis of whether the effort or
plan meets the following elements: (1) The nature and extent of threats
being
[[Page 29378]]
addressed by the conservation effort are described, and how the
conservation effort reduces the threats is described; (2) explicit
incremental objectives for the conservation effort and dates for
achieving them are stated; (3) the steps necessary to implement the
conservation effort are identified in detail; (4) quantifiable,
scientifically valid parameters that will demonstrate achievement of
objectives, and standards for these parameters by which progress will
be measured, are identified; (5) provisions for monitoring and
reporting progress on implementation (based on compliance with the
implementation schedule) and effectiveness (based on evaluation of
quantifiable parameters) of the conservation effort are provided; and
(6) principles of adaptive management are incorporated.
PECE also notes several important caveats. Satisfaction of the
above mentioned criteria for implementation and effectiveness
establishes a given protective effort as a candidate for consideration,
but does not mean that an effort will ultimately change the risk
assessment for the species. The policy stresses that, just as listing
determinations must be based on the viability of the species at the
time of review, so they must be based on the state of protective
efforts at the time of the listing determination. PECE does not provide
explicit guidance on how protective efforts affecting only a portion of
a species' range may affect a listing determination, other than to say
that such efforts will be evaluated in the context of other efforts
being made and the species' overall viability. There are circumstances
where threats are so imminent, widespread, and/or complex that it may
be impossible for any agreement or plan to include sufficient efforts
to result in a determination that listing is not warranted.
Outlined below are current and future protective efforts that may
minimize threats facing the GOM DPS. Each of these efforts or projects
is measured against the PECE criteria to evaluate the certainty of
implementation and effectiveness to determine the relative contribution
of the efforts to reducing extinction risk.
Fish Passage, Dams, and Hydropower
The Services are involved in hydroelectric project relicensing and
other fish passage issues. Fisheries agencies in Maine continue to work
to establish and improve upstream and downstream fish passage, and to
remove dams and other blockages to habitat connectivity. The majority
of fish passage work in the range of the GOM DPS focuses on FERC
licensed dams on the Penobscot, Kennebec, and Androscoggin watersheds
and on opportunities to enhance passage throughout historical Atlantic
salmon habitat. This includes participating in the Penobscot River
Restoration Project, negotiating improved passage on a number of dams
on the Kennebec River pursuant in part to the 1998 Lower Kennebec River
Comprehensive Hydropower Settlement Accord, replacing culverts on
highways and logging roads, and removing dams. The Services, in
coordination with other state and Federal agencies, are also making
efforts to improve fish passage on the Narraguagus and Sheepscot
Rivers. Information regarding some of the most notable efforts made to
improve passage for Atlantic salmon in the GOM DPS is summarized below.
(1) Lower Kennebec River Comprehensive Hydropower Settlement Accord
(KHDG Accord, May 26th, 1998): The KHDG Accord addresses fish passage
issues at eight hydroelectric projects on the Kennebec River and
Sebasticook River. The 1998 Accord was signed by various state and
Federal fishery agencies and approved by the FERC. In addition, the
Anson and Abenaki Offer of Settlement (January 30, 2002), also signed
by various state and Federal fishery agencies and approved by FERC,
addresses fish passage provisions on two hydroelectric projects within
the middle reaches of the Kennebec River (Anson and Abenaki Projects).
On the Kennebec River, fish passage agreements were reached at the
lower four hydroelectric projects including the Lockwood, Hydro-
Kennebec, Shawmut, and Weston as part of the KHDG Accord. The lowermost
hydroelectric project, Edwards Dam, was removed as part of the KHDG
Accord. On the Sebasticook River, fish passage agreements were reached
on the Benton and Burnham Projects, and in 2008, the Fort Halifax dam
was breached pursuant to the passage agreement.
During the spring of 2006, upstream fish passage facilities were
installed at the Lockwood Dam, the lowermost dam in the Kennebec,
pursuant to the KHDG Accord. Fish passage at the Lockwood Dam currently
consists of a fish lift with trap and truck facilities. Atlantic salmon
captured at the Lockwood Dam are transported upstream to suitable
habitat in the Sandy River. In 2006, upstream fish passage, in the form
of a fish lift, was also installed at the Benton Falls and Burnham
facilities on the Sebasticook River, a tributary to the Kennebec.
Currently on the Kennebec, only the Lockwood Dam has upstream fish
passage facilities for Atlantic salmon (FPL Energy Maine Hydro LLC,
2008). While some salmon rearing habitat is now available in the
restored reach below Lockwood, the vast majority of salmon habitat
(nearly 90 percent) in the Kennebec River watershed is located above
Lockwood.
The KHDG Accord and Anson-Abenaki Settlement contain biological
triggers for implementing upstream passage on the Kennebec River. Based
upon the KHDG biological triggers, the next mainstem dam upstream of
Lockwood (Hydro-Kennebec) may not have upstream fish passage facilities
installed until 2010 at the earliest, and the last dam with upstream
habitat may not have fishways until 2020. The main biological trigger
to sequential implementation of upstream passage at the remaining KHDG
dams is the establishment of a large run of shad in the Kennebec that
will be trapped at Lockwood. The shad program in the Kennebec is
supported by stocking; however, that program is limited by funding and
production capabilities. Funding was secured through 2008; however,
funding for the stocking program for 2009 and beyond is highly
uncertain. The KHDG Accord does offer one other alternative to state
and Federal resource agencies to trigger fishway installation. Text in
the Accord states the alternative approach is available to state and
Federal resource agencies ``should the growth of salmon or river
herring runs make it necessary to adopt an alternative approach for
triggering fishway installation.'' However, this process would have to
be handled through FERC, and the Licensee would have to agree to the
proposed alternative triggers. Even after fish passage facilities are
installed in the Kennebec River in accordance with this plan, Atlantic
salmon will need to pass at least six mainstem dams (Lockwood, Hydro-
Kennebec, Shawmut, Weston, Abenaki, and Anson).
The KHDG Accord and Anson-Abenaki Settlement are legally binding,
requiring all parties to fulfill their obligations as stated in the
agreement. When all of the conditions in the Accord and Settlement have
been fulfilled, passage on the Kennebec River and some of the
tributaries will be improved, allowing Atlantic salmon and other
diadromous species access to important habitat. However, neither the
Accord nor the Settlement is likely to recover Atlantic salmon in the
Kennebec watershed in the foreseeable future. The legal procedural
requirements in the agreements are based upon biological triggers that
currently are contingent upon the
[[Page 29379]]
success of a shad stocking program for which production capacity and
funding are uncertain for 2009 and beyond. Therefore, the second, third
and seventh criteria in the PECE for certainty of implementation are
not satisfied. Under PECE, the effectiveness of the agreements to fully
address passage issues for Atlantic salmon in the Kennebec River, or
the entire GOM DPS, also can not be fully guaranteed at this time,
given that all objectives and project parameters are based upon
biological triggers that are uncertain. Thus, while the Accord and the
Settlement have time tables associated with implementation, monitoring
components, and project objectives (effectiveness criteria two, three,
and five), these are contingent upon biological triggers being met.
(2) Penobscot River Restoration Project (PRRP): Perhaps the most
significant of the agreements mentioned above is the PRRP. The PRRP is
the result of many years of negotiations between Pennsylvania Power and
Light (PPL), U.S. Department of the Interior (i.e., USFWS, Bureau of
Indian Affairs, National Park Service), Penobscot Indian Nation, the
state of Maine (i.e., Maine State Planning Office, Inland Fisheries and
Wildlife, MDMR), and several non-governmental organizations (NGOs;
Atlantic Salmon Federation, American Rivers, Trout Unlimited, Natural
Resources Council of Maine, among others). If implemented, the PRRP
would lead to the removal of the two lowermost mainstem dams on the
Penobscot River (Veazie and Great Works) and would decommission the
Howland Dam and construct a nature-like fishway around it. This
initiative would improve habitat accessibility for all diadromous
species. For example, less than 7 percent of post-project salmon
habitat will be above four or more dams, and at least 43 percent of the
habitat would require, at most, one dam passage in each direction with
conventional passage facilities. At least 15 percent of salmon habitat
would have no intervening dams remaining, compared to 2.5 percent
presently (see section 8.1 in Fay et al., 2006).
In addition to improved habitat accessibility for Atlantic salmon
and other diadromous species, the PRRP will also provide an opportunity
to study the ecological linkages between Atlantic salmon and the 11
other diadromous species with which they co-evolved. The linkage
between other diadromous species and Atlantic salmon may be crucial to
recovering Atlantic salmon to self-sustaining levels. As stated
previously, this co-evolution likely provided ecological benefits to
the diadromous species complex (e.g., marine-derived nutrient
deposition and prey buffering), which may enhance Atlantic salmon
survival at key life stages. Therefore, a full understanding of these
benefits and a multi-species approach is required for the successful
recovery of Atlantic salmon to the Penobscot system.
In June 2004, the Parties to the negotiations signed the Penobscot
Multiparty Settlement Agreement (MPA). The MPA includes a 5-year option
period during which time the ``Penobscot River Restoration Trust''
raised the necessary funds to purchase the dams. In addition, another
$25-30M is required for decommissioning and removal. NOAA's budget for
the 2008 fiscal year contained $10M to support the PRRP.
There is a significant effort on behalf of the Parties to the MPA
and other Federal and non-Federal bodies to secure funds for the
purchase, decommissioning, and removal of the dams. However, as stated
above, the certainty of that funding is not known at this time. While
the necessary funding has been committed by the government and other
private donors to achieve the purchase of the dams, a significant
amount of money still must be acquired in order for the parties to
exercise the option to decommission and remove the dams as well as
construct a nature like fishway. While significant progress has been
made in fundraising and permitting, staffing, funding level, funding
source and other resources necessary to fully implement the PRRP are
not identified at this time. There is not currently a high level of
certainty that the necessary funding will be obtained. Therefore, at
this time, the PRRP does not satisfy criteria one and seven in the
certainty of implementation of the PECE. Permitting and regulatory
requirements are also uncertain at this stage because they are
contingent upon the ability of the parties to raise the full amount of
funds necessary, FERC approval of the Trust's permit to surrender the
dams, and completion of required environmental review. Thus, the PRRP
does not satisfy criterion four of the PECE, which requires that all
authorizations (e.g., permits, land owner permission) necessary to
implement the conservation effort are identified and that there is a
high certainty that the parties to the agreement will obtain all
necessary authorizations. If proper funding is acquired to fulfill the
MPA and the project undergoes the appropriate environmental and
regulatory review and permitting, Atlantic salmon in the Penobscot
River will clearly benefit. However, it is not possible to state at
this time with a high level of certainty that this project will be
fully implemented, especially in light of the present economic
conditions and energy issues facing the United States. If the removal
option is not exercised, fishway prescriptions issued by the Services
will be implemented.
The PRRP provides unique opportunities for restoration efforts.
Many species will benefit from the PRRP directly, but many other
passage impediments exist in the basin. Some diadromous fish species,
such as Atlantic salmon, alewife, and shad, may require additional
habitat improvements (barrier removal, fishways, etc.) or stocking.
Thus, additional active restoration measures may be required to realize
the full potential of the PRRP. Due to the high profile of the project
and the high costs involved, there is a need to prioritize restoration
efforts in the basin to increase the probability for project success.
There are many ways to determine what a ``successful'' PRRP would look
like. In March 2008, the Penobscot Interagency Technical Committee
(PNITC) was formed to develop operational management plans for
diadromous fish within the basin. Members of the PNITC include managers
and scientists from MDMR, MIFW, NMFS, the Penobscot Indian Nation, and
FWS. The PNITC has been tasked with developing one set of restoration
goals and priorities for the basin. To help facilitate this goal, we
have begun developing an ecologically-based GIS tool to help set goals
and to help identify and prioritize various restoration efforts. The
outputs of this tool will help to ensure that achievable goals are
established, and that funding and restoration efforts are applied in
the most appropriate manner. The PNITC, in conjunction with NMFS, are
making strides towards defining the scope of restoration efforts and
operational plans for diadromous species including Atlantic salmon.
Despite these efforts, the effectiveness of the PRRP is still uncertain
given that explicit incremental objectives and an implementation plan
still need to be identified (criteria two and three); quantifiable,
scientifically valid parameters by which to measure progress have yet
to be established (criterion four); and provisions for reporting and
monitoring have not been established (criterion five).
(3) New England Atlantic Salmon Committee (NEASC): In addition to
these efforts, NEASC requested that the USASAC provide a list of the
top priority fish passage projects in New England. NEASC hopes to use
this information to leverage funding from a
[[Page 29380]]
variety of sources to implement these projects. The prioritized list
was developed by soliciting information from representatives from each
of the New England states responsible for managing Atlantic salmon.
NEASC hopes that this initiative will result in a large scale effort to
improve passage and remove obstructions for salmon and other diadromous
fish species throughout New England. This effort may result in gaining
both support and resources for improved passage. However, the outcome
of this effort is highly uncertain in terms of both implementation and
effectiveness. Therefore, the NEASC effort to prioritize fish passage
projects in hopes to leverage funding for implementation does not
satisfy any of the six effectiveness and nine implementation criteria
of the PECE.
Adaptive Management Initiatives
(1) Habitat Connectivity: In 2006, 18 stream habitat connectivity
projects were completed in 3 of the Downeast Rivers. The principal
funding sources were Natural Resources Conservation Service-Wildlife
Habitat Improvement Program, USFWS, Maine Atlantic Salmon Conservation
Partnership-Student Career Experience Program, Project Salmon Habitat
and River Enhancement, Washington County Soil and Water Conservation
District, and private landowner contributions. Four stream-road
crossings (culverts) were completely removed in the Machias River
watershed. The remaining 14 projects replaced undersized culverts with
open bottom arches that spanned 1.2 times bankfull stream width in the
Machias, Narraguagus, and East Machias watersheds. These restoration
projects are effectively contributing to salmon recovery by improving
access to habitat for Atlantic salmon and other diadromous species.
These types of restoration initiatives are likely to continue; however,
they are contingent upon the continued availability of funding sources,
voluntary participation of landowners and other groups, and
identification of specific implementation dates. Therefore, while the
aforementioned projects are deemed to be effective, the certainty of
implementation of additional projects is unknown and the future
initiatives do not satisfy certainty of implementation criteria one,
five, seven and eight.
(2) Watershed Councils: Watershed councils are actively engaged in
cooperative Atlantic salmon conservation activities. Local watershed
councils, formed under the auspices of the Maine Atlantic Salmon
Conservation Partnership, continue to play an important role in
recovery activities in their respective watersheds, particularly the
planning and implementation of watershed-specific habitat protection
and restoration. Watershed councils have representatives from state and
Federal agencies, conservation groups, industries, towns, landowners
and other interested groups or individuals. These groups coordinate
their efforts with those of local groups with similar goals. The
councils continue to review the status of threats in each watershed and
determine the need for continued or new efforts to further minimize any
potential threat to Atlantic salmon from future activities present in
the watershed. The process ensures that all stakeholders in the
watersheds have the opportunity to participate in decisions concerning
conservation actions. The activities of watershed councils are largely
voluntary and vary by council, depending on the level of participation
from members. Many of the efforts undertaken by watershed councils have
been and continue to be extremely effective at contributing to salmon
recovery. Future efforts will likely continue to make positive
contributions as well, provided that voluntary participation within
each council continues. There is no overarching management plan that
outlines the collective work or goals of the councils into the future;
therefore, it is uncertain what projects will be implemented on an
annual basis, and whether the necessary resources will be available to
implement the projects in terms of both funding sources and voluntary
participation. PECE criteria one, five, seven and eight require a high
level of certainty that: the necessary resources are identified and
secured; the necessary voluntary participation and permissions to
implement conservation plan have been obtained; and an implementation
schedule for the project is provided. While past activities have been
effective in restoring salmon habitat and improving access, the
effectiveness of future efforts can not be evaluated in terms of the
conservation contribution to the status of the species.
(3) Large Woody Debris Project: Maine's rivers have experienced
dramatic changes over the last 300 years. One of the most sweeping is
the removal, lack of recruitment, and subsequent attrition of LWD. The
result is that the rivers likely have very low loading of LWD, and
thus, have less complex fish habitat compared to the past. LWD creates
pools, retains gravel and nutrients, supports benthic
macroinvertebrates, influences current velocities and water depth,
provides cover, and during high water, refugia for fishes. The value of
LWD in promoting productive Atlantic salmon habitat is undocumented. In
October 2006, a project was implemented to enhance habitat at a scale
that will have population-level benefits, with a design that evaluates
the effects of LWD additions on stream geomorphology. LWD was added to
two sites, each with a paired control site, in Creamer Brook, East
Machias Drainage. Streams in the Narraguagus, Machias, and East Machias
drainages were also evaluated for potential LWD additions. The Creamer
Brook sites were scouted and surveyed for similarity and surveyed for
fish populations immediately prior to the habitat work. Each site was
electrofished using multiple pass depletion, and fish were weighed,
measured, and released into their site. LWD was added at a rate of
approximately 12 pieces per 100m by cutting trees in the riparian zone
and adjusting their placement to achieve either stability or
geomorphologic effect. In addition, all LWD (existing and added) in the
treatment sites was tagged with metal numeric tags and marked with
spray paint. The site was surveyed before and after LWD placements.
Trees were also felled in the riparian zone to increase roughness to
minimize channel migration as a result of the LWD additions.
The LWD project directly incorporates the principles of adaptive
management. The project is aimed at improving the complexity of fish
habitat through the addition of LWD. The project plan lays out explicit
objectives, qualitative and quantitative parameters by which progress
will be measured, and sites to be monitored, fulfilling two through six
of the PECE effectiveness criteria. The effectiveness of this project
has not been demonstrated because LWD additions have not been shown to
enhance salmon survival. Therefore, it is not yet clear to what extent
the LWD project is addressing the threat posed by the loss of habitat
complexity; thus, criterion one of the certainty of effectiveness is
not satisfied.
(4) The Penobscot Indian Nation Water Quality Monitoring Program:
Water quality is a critical issue to the Penobscot Indian Nation, given
that many of the fish and other aquatic species serve as an important
source of traditional food. Industrial discharge has resulted in the
presence of harmful chemicals in the waters that flow through
reservation waters. The Penobscot Indian Nation has implemented a
rigorous water quality testing program to: ensure that water
[[Page 29381]]
quality standards are being met and that licensed discharges are in
compliance with permit conditions; upgrade river and tributary
classifications; identify and remediate sources of non-point source
pollution; and gather data needed to support the role of the tribe in
hydroelectric re-licensing. The Penobscot Indian Nation also has a
cooperative agreement with the MDEP to share water quality data and
technical assistance. The data provided by the Penobscot Indian Nation
has led to the revision of water classifications for over 500 rivers
and streams and improved water quality. The Penobscot Indian Nation's
water quality monitoring program satisfies all of the certainty of
effectiveness and implementation criteria. While this program is very
important in terms of improving water quality and the health of aquatic
organisms, the results of the program in terms of threat abatement
across the entire GOM DPS are not sufficient to warrant a change in the
listing status of the GOM DPS.
International Efforts
(1) North Atlantic Salmon Conservation Organization: The Convention
for the Conservation of Salmon in the North Atlantic Ocean, ratified by
the United States in 1982, provides a mechanism for managing the
international commercial fishery for Atlantic salmon for the purpose of
conserving and restoring salmon stocks. The Convention provides a forum
for coordination among members, proposing regulatory measures, and for
making recommendations regarding scientific research. The Convention
was adopted by the United States, Canada, Greenland (as represented by
Denmark), Iceland, Faroes Islands, Norway, and the European Commission.
Russia joined later. The NASCO was formed by this Convention. The
United States became a charter member of NASCO in 1984. NASCO is
charged with the international management of Atlantic salmon stocks on
the high seas. NASCO is composed of three geographic Commissions:
Northeast Atlantic, West Greenland, and North American. NASCO seeks
scientific advice from the International Council for the Exploration of
the Seas (ICES) on the status of stocks, the effectiveness of
management measures, monitoring and data needs, and catch options.
NASCO uses this scientific advice as a basis for formulating
biologically sound management recommendations for the conservation of
North Atlantic salmon stocks. Providing catch options for the fishery
at West Greenland is one area where this advice is specifically
applied.
The West Greenland fishery was one of the last directed Atlantic
salmon commercial fisheries in the Northwest Atlantic. In 2005, in
recognition of the depressed status of the stocks and the fact that the
resulting scientific advice was unchanged year-to-year, the NASCO
Parties asked ICES for multi-annual regulatory advice. Based on this
advice, a provisional multi-annual regulatory measure was adopted at
the 2006 annual meeting of NASCO to restrict the fishery in 2006 to
internal use only and conditionally also for 2007 and 2008. The
provisional multi-annual regulatory measure adopted in 2006 was
contingent upon finalization and acceptance of a finalized Framework of
Indicators (FWI). ICES provided NASCO with a finalized FWI for the
mixed stock off West Greenland that all Parties accepted in 2007. The
multi-annual regulatory measure agreed to in 2006 were continued for
2007 and 2008. This measure, like those of recent years, limits harvest
in West Greenland to internal use only (estimated to be about 20 mt).
Denmark, representing Greenland and the Faroe Islands, stated that it
would accept the FWI for a fixed period 2006-2008 and would consider
accepting new multi-annual catch advice at the 2009 Annual Meeting in
light of further development of the FWI, the continued research of the
mortality of salmon stocks, and possible improvement of the stocks.
In 2001, NASCO established an International Atlantic Salmon
Research Board (IASRB) to promote collaboration and cooperation on
research on the causes of marine mortality of Atlantic salmon and the
opportunities to counteract this mortality. The IASRB has made great
progress in improving coordination of the existing research and
supporting initiation of new research projects. However, there are
still substantial gaps in our knowledge of what factors may be
affecting salmon at sea. The IASRB, therefore, commissioned the
development of an international program of cooperative research on
salmon at sea (SALSEA). The SALSEA program has been developed by
scientists from all NASCO's Parties. The four areas on which SALSEA is
currently focusing are: (1) Supporting technologies to assist in the
genetic identification of the origin of salmon sampled at sea,
improving efficiency of sampling of salmon at sea, and improving
standardized scale analysis of salmon at sea; (2) studying early
migration through the inshore zone: fresh waters, estuaries, and
coastal waters to specifically understand what factors may be
influencing marine mortality; (3) studying the distribution and
migration of salmon at sea; and (4) improving communications and public
relations. The United States has contributed $150,000 to the IASRB to
help fund SALSEA. The United States has also participated in a marking
workshop sponsored by SALSEA and actively participates in the West
Greenland Sampling Program on an annual basis.
The West Greenland Sampling Program is an international sampling
program of the internal use fishery at West Greenland. Scale and tissue
samples are taken to allow examination of stock origin, catch
composition, and fish health. This sampling program has provided a
wealth of information on the extent, location, and origin of the catch.
Scale and genetic analyses have allowed for detailed knowledge of the
characteristics of the catch, including age and continent of origin. In
recent years, approximately 70 percent of the catch has been of North
American origin and 30 percent of European origin.
The United States intends to continue to participate fully in NASCO
and associated negotiations over the West Greenland Fishery. The
legislative authority, funding, authorizations, staffing resources, an
approved plan (U.S. Implementation Plan) and associated schedule for
implementation of actions, and legal requirements allowing for United
States participation in NASCO are certain. Although NASCO does not have
any regulatory authority over any of the Parties, it has been
successful at influencing salmon management in member states. The West
Greenland fishery is a prime example of NASCO facilitating negotiations
and ultimately, management, of this fishery for the benefit of salmon
as a whole in the North Atlantic Ocean. However, while NASCO has been
successful in reducing the threat of directed harvest of Atlantic
salmon in the West Greenland fishery, a small, but significant, portion
of the catch continues to be Atlantic salmon of U.S. origin. The NASCO
guidelines and agreements are contributing to reducing threats to
salmon recovery (e.g., fishing, disease, aquaculture, habitat
destruction, stocking practices). While the NASCO agreements and
guidelines appear to have reduced the threat from direct harvest, the
agreements and guidelines are not regulatory. It is incumbent on each
Party to NASCO to enforce the actions identified in the Implementation
Plan drafted by each country as well as report on their success
relative to the health of salmon stocks. Therefore, the effectiveness
of
[[Page 29382]]
specific NASCO guidelines and agreements is not certain. Some parties
have failed to develop rigorous Implementation Plans with explicit
incremental objectives and dates for achieving the action, scientific
parameters, and ability to report under these plans. Thus,
effectiveness criteria two through five are not certain at this time.
There is also some uncertainty in terms of the implementation of the
NASCO guidelines and agreements. There is even more uncertainty about
the individual Implementation Plans, given that, in some regions, there
is not the necessary voluntary support by landowners, necessary funding
to implement the conservation measures, or even the necessary
regulatory mechanisms within the jurisdiction of each Party to regulate
certain activities. Thus, certainty of implementation criteria four to
seven cannot be satisfied for the NASCO guidelines and agreements. It
is also unknown to what extent current IASRB and SALSEA activities will
abate the threat from poor marine survival.
(2) West Greenland Conservation Agreement: In August 2002, a multi-
year conservation agreement with an annual termination date (available
to both parties) was established between the North Atlantic Salmon Fund
and the Organization of Hunters and Fishermen in Greenland, effectively
buying out the commercial fishery for Atlantic salmon for a 5-year
period. The internal-use fishery is not included in the agreement. In
June 2007, the agreement was extended and revised to cover the 2007
fishing season with a provision which allows the agreement to continue
to be extended on an annual basis through 2013. An implementation plan
and schedule are already developed as well as the necessary
authorizations and legal authority. However, certainty of
implementation criteria five, seven, and nine cannot be satisfied,
considering the certainty that the necessary funding has not been
secured, and it is not known if all parties will agree to extend the
Agreement.
Summary of Protective Efforts
The current endangered status of the GOM DPS as listed in 2000 and
the desire to restore the Penobscot to a free flowing river have
created an incentive for various agencies, groups, and individuals to
carry out a number of efforts aimed at protecting and conserving
salmon. These actions are being directed at reducing threats faced by
Atlantic salmon and could contribute to the recovery and restoration of
the GOM DPS and its ecosystem substantially in the future. However,
apart from the Penobscot Indian Nation Water Quality Monitoring
Program, there is still considerable uncertainty regarding the
implementation and effectiveness of these efforts in the future.
Therefore, they cannot be considered to affect the listing status of
the GOM DPS.
Finding
As stated previously in this final rule, the main difference
between the GOM DPS as listed in 2000 and the GOM DPS as finalized in
this rule is the inclusion of the majority of the Androscoggin,
Kennebec, and Penobscot River basins. The 2000 GOM DPS consisted of
only small coastal rivers on either side of the Penobscot River.
The small coastal rivers were subject to similar threats, including
water withdrawals, aquaculture escapees, and habitat degradation.
Although the rivers to the east and west of the Penobscot are exposed
to different stressors, they have more threats in common with each
other than with the larger river systems included in the GOM DPS as
currently defined. Habitat degradation from poor water quality and
water withdrawals still pose a threat to salmon within some of the
small coastal rivers. For the most part, the small coastal rivers
included within the 2000 GOM DPS boundaries are not dammed for
hydroelectric generation (an exception would be the Union River), and,
therefore, this threat was not highlighted in the 2000 listing.
However, other barriers were identified in the 2000 listing as
impacting habitat.
The larger river basins face some additional threats compared to
the small coastal rivers because they have higher human population
densities, more development, and a significant number of dams and other
barriers. Dams are present on all three of the larger rivers within the
range of the GOM DPS and impact all salmon moving up and downstream.
Given the number of salmon affected by dams and the amount of the
habitat within the GOM DPS affected by dams, this threat is a
significant factor in this listing determination.
Poor marine survival was identified as one of the most significant
threats in our 2000 listing. Since then, we have improved our knowledge
and understanding of the impact of marine survival on the GOM DPS.
Survival and eventual recovery of the GOM DPS depends on an increase in
marine survival, which is why that threat is a significant factor in
this listing determination.
There are extremely few naturally-reared, spawning adult salmon
present in the GOM DPS (184 in 2007). With the addition of Atlantic
salmon in the Penobscot and other large rivers to the GOM DPS, the
demographic security is somewhat increased because populations that are
geographically widespread are less likely to experience spatially-
correlated catastrophes. However, the number of naturally-reared,
spawning adults within the GOM DPS is extremely low and the majority of
returning adults (whether naturally-reared or smolt-stocked) are found
in the Penobscot River, despite the addition of other large rivers to
the range of the DPS. In 2007, only 16 adults returned to the Kennebec
and 20 returned to the Androscoggin.
The GOM DPS is sustained by a carefully managed hatchery
supplementation program. Hatchery supplementation is crucial to the
continued existence of the GOM DPS, though we recognize that reliance
on artificial propagation carries risks that cannot be completely
avoided despite managers' best efforts. We have carefully examined both
the positive and negative effects of hatchery supplementation,
including the risk of disruptions to hatchery operations (e.g., due to
disease outbreak) or the genetic risks (such as inbreeding and
domestication selection). Although hatchery supplementation of the GOM
DPS is currently important in maintaining genetic diversity levels,
these programs have not been successful at recovering or maintaining
wild, self-sustaining populations of Atlantic salmon.
Further, at the present time, there is no evidence to suggest that
marine survival will increase in the near future. In short, without
both conservation hatcheries continuing to operate and an increase in
marine survival, the risk of extinction is high.
As described above, the demographic effects of the currently low
marine survival on the GOM DPS are severe, dams limit the viability of
salmon populations through numerous and sometimes synergistic ways
(e.g., blocking up and downstream passage, entrainment, water quality
effects, fish community effects), and the existing regulatory
mechanisms for dams are inadequate. As a result, we find that low
marine survival, dams, and the inadequacy of existing regulatory
mechanisms for dams are each significant factors in this listing
determination.
We find that threats from reduced habitat complexity, reduced
habitat connectivity, and reduced water quantity and degraded water
quality within Factor A; overutilization within Factor B; disease and
predation within
[[Page 29383]]
Factor C; inadequacy of existing regulatory mechanisms for water
withdrawals and water quality within Factor D; and aquaculture,
depleted diadromous fish communities, and competition within Factor E
all act as stressors on the GOM DPS. Collectively, these are
significant factors in this listing determination, contributing to the
poor status of the GOM DPS. At this time, we do not have enough
information to determine whether climate change (within Factor E) is a
threat to the long-term persistence of the GOM DPS.
We have considered all the above factors, efforts to protect the
species, and the status of the species. We have concluded that the GOM
DPS of Atlantic salmon is in danger of extinction. Therefore, we are
listing it as endangered.
Available Conservation Measures
Conservation measures provided to species listed as endangered or
threatened under the ESA include recovery actions, requirements for
Federal agencies to avoid jeopardizing the continued existence of the
species, and prohibitions against taking the species, as defined in the
ESA. Recognition through listing may improve public awareness and
encourage conservation actions by Federal, state, and local agencies,
private organizations, and individuals. The ESA provides for possible
land acquisition and cooperation with the States and provides for
recovery actions to be carried out for listed species. The requirement
of Federal agencies to avoid jeopardy and the prohibitions against take
are discussed below.
Section 7(a) of the ESA, as amended, requires Federal agencies to
evaluate their actions with respect to any species that is listed as
endangered or threatened and with respect to its critical habitat, if
any is designated. Regulations implementing this interagency
cooperation provision of the ESA are codified at 50 CFR part 402.
Section 7(a)(4) requires Federal agencies to confer informally with us
on any action that is likely to jeopardize the continued existence of a
species proposed for listing or result in destruction or adverse
modification of proposed critical habitat. If a species is subsequently
listed, section 7(a)(2) requires Federal agencies to ensure that
activities they authorize, fund, or carry out are not likely to
jeopardize the continued existence of the species or destroy or
adversely modify its critical habitat. If a Federal action may affect a
listed species or its critical habitat, the responsible Federal agency
must enter into formal consultation with us under the provisions of
section 7(a)(2) of the ESA.
Several Federal agencies are expected to have involvement under
section 7 of the ESA regarding the Atlantic salmon. The Environmental
Protection Agency may be required to consult on its permitting
oversight authority for the CWA and Clear Air Act. The ACOE may be
required to consult on permits it issues under section 404 of the CWA
and section 10 of the Rivers and Harbors Act. The FERC may be required
to consult on licenses it issues for hydroelectric dams under the FPA.
The Federal Highway Administration may be required to consult on
transportation projects it authorizes, funds, or carries out.
ESA section 9(a) take prohibitions (16 U.S.C. 1538(a)(1)(B)) apply
to all species listed as endangered. Those prohibitions, in part, make
it illegal for any person subject to the jurisdiction of the United
States to take, import or export, ship in interstate commerce in the
course of commercial activity, or sell or offer for sale in interstate
or foreign commerce any wildlife species listed as endangered, except
as provided in sections 6(g)(2) and 10 of the ESA. It is also illegal
under ESA section 9 to possess, sell, deliver, carry, transport, or
ship any such wildlife that has been taken illegally. Section 11 of the
ESA provides for civil and criminal penalties for violation of section
9 or of regulations issued under the ESA.
The ESA provides for the issuance of permits to authorize
incidental take during the conduct of activities that may result in the
take of threatened or endangered wildlife under certain circumstances.
Regulations governing permits are codified at 50 CFR 17.22, 17.23, and
17.32. Such permits are available for scientific purposes, to enhance
the propagation or survival of the species, and for incidental take in
the course of otherwise lawful activities provided that certain
criteria are met.
It is our policy, published in the Federal Register on July 1, 1994
(59 FR 34272), to identify, to the maximum extent practicable at the
time a species is listed, those activities that would or would not
likely constitute a violation of section 9 of the ESA. The intent of
this policy is to increase public awareness of the effects of the
listing on proposed and ongoing activities within a species' range.
The Services believe that, based on the best available information,
the following actions are unlikely to result in a violation of section
9:
(1) Any incidental take of GOM DPS Atlantic salmon resulting from
an otherwise lawful activity conducted in accordance with the
conditions of an incidental take permit issued by one of the Services
under section 10 of the ESA. Examples of such actions may include
operation of dams and fishways, State sport fish stocking programs,
State recreational fishing programs for other species, silviculture,
agriculture, State programs regulating water quality, and State
programs regulating water withdrawals and instream flow;
(2) Any action authorized, funded, or carried out by a Federal
agency that is likely to adversely affect the GOM DPS of Atlantic
salmon, when the action is conducted in accordance with the terms and
conditions of an incidental take statement issued by either of the
Services under section 7 of the ESA. Examples of such actions may
include dam construction and operation, road construction, discharge of
fill material, siting and operation of aquaculture facilities, and
stream channelization or diversion; and
(3) Any action carried out for scientific purposes or to enhance
the propagation or survival of the species that is conducted in
accordance with the conditions of a permit issued by one of the
Services under section 10 of the ESA. Examples of such actions may
include the river-specific hatchery conservation program at CBNFH and
GLNFH, habitat restoration activities, and scientific monitoring
programs.
Activities that could lead to violation of section 9 prohibitions
against ``take'' of the GOM DPS of anadromous Atlantic salmon include,
but are not limited to, the following:
(1) Unauthorized killing, collecting, handling, or harassing of
individual GOM DPS Atlantic salmon. Examples of such actions may
include targeted recreational or commercial fishing for GOM DPS salmon,
and non-targeted recreational or commercial fishing for other species
(bycatch),
(2) Siting or operation of an aquaculture facility without adopting
and implementing fish health practices that adequately protect against
the introduction and spread of disease or the destruction of habitat;
(3) Unauthorized destruction or alteration of spawning, rearing, or
migration habitat. Examples of such activities may include erecting or
operating structures that block migration routes (such as dams,
culverts, or other barriers); instream dredging, rock removal,
operation of heavy equipment, or channelization; riparian and in-river
damage due to livestock; discharge of fill material; or manipulation of
river flow;
[[Page 29384]]
(4) Discharge or dumping of toxic chemicals, silt, or other
pollutants (e.g., fertilizers, pesticides, heavy metals, oil, organic
wastes) into the aquatic environment of the GOM DPS.
Other activities not identified here will be reviewed on a case-by-
case basis to determine if violation of section 9 of the ESA may be
likely to result from such activities. When there are questions about
the effect of an action on the GOM DPS, the Services are available to
provide technical assistance. We do not consider these lists to be
exhaustive, and we provide them as general information to the public.
Critical Habitat
Section 4(b)(2) of the ESA requires us to designate critical
habitat for threatened and endangered species ``on the basis of the
best scientific data available and after taking into consideration the
economic impact, the impact on national security, and any other
relevant impact, of specifying any particular area as critical
habitat.'' This section grants the Secretary of the Interior or of
Commerce discretion to exclude an area from critical habitat if the
Secretary determines ``the benefits of such exclusion outweigh the
benefits of specifying such area as part of the critical habitat.'' The
Secretary may not exclude areas if exclusion ``will result in the
extinction of the species.'' In addition, the Secretary may not
designate as critical habitat any lands or other geographical areas
owned or controlled by the Department of Defense, or designated for its
use, that are subject to an integrated natural resources management
plan under Section 101 of the Sikes Act (16 U.S.C. 670a), if the
Secretary determines in writing that such a plan provides a benefit to
the species for which critical habitat is proposed for designation (see
section 318(a)(3) of the National Defense Authorization Act, Pub. L.
108-136).
The ESA defines critical habitat under section 3(5)(A) as: ``(i)
the specific areas within the geographical area occupied by the
species, at the time it is listed * * *, on which are found those
physical or biological features (I) essential to the conservation of
the species and (II) which may require special management
considerations or protection; and (ii) specific areas outside the
geographical area occupied by the species at the time it is listed * *
*, upon a determination by the Secretary that such areas are essential
for the conservation of the species.''
Once critical habitat is designated, Section 7 of the ESA requires
Federal agencies to ensure they do not fund, authorize, or carry out
any actions that will destroy or adversely modify that habitat. This
requirement is in addition to the other principal section 7 requirement
that Federal agencies ensure their actions do not jeopardize the
continued existence of listed species.
The Secretary of Commerce is designating critical habitat in a
separate rulemaking.
Peer Review
In December 2004, the Office of Management and Budget (OMB) issued
a Final Information Quality Bulletin for Peer Review, establishing
minimum peer review standards, a transparent process for public
disclosure of peer review planning, and opportunities for public
participation. The OMB Bulletin, implemented under the Information
Quality Act (Pub. L. 106-554), is intended to enhance the quality and
credibility of the Federal government's scientific information, and
applies to influential or highly influential scientific information
disseminated on or after June 16, 2005. We obtained independent peer
review of the scientific information compiled in the 2006 Status Review
(Fay et al., 2006) that supports this proposal to list the GOM DPS of
Atlantic salmon as endangered.
On July 1, 1994, the Services published a policy for peer review of
scientific data (59 FR 34270). The intent of the peer review policy is
to ensure that listings are based on the best scientific and commercial
data available. During the public comment period for the proposed rule
to list the GOM DPS of Atlantic salmon as endangered, the Services
solicited the expert opinions of four qualified specialists. These
independent specialists represented expertise from the academic and
scientific community. Out of the four reviewers solicited, two
individuals completed a critical review of the proposed rule. Peer
review comments are summarized and addressed in the public comment
section of this rule, and the text of the final rule has been changed
where necessary.
References
A complete list of the references used in this final rule is
available upon request (see ADDRESSES).
Classification
National Environmental Policy Act
ESA listing decisions are exempt from the requirement to prepare an
environmental assessment (EA) or environmental impact statement (EIS)
under the National Environmental Policy Act of 1969 (NEPA) (NOAA
Administrative Order 216-6.03(e)(1); Pacific Legal Foundation v.
Andrus, 675 F. 2d 825 (6th Cir. 1981)). Thus, we have determined that
the final listing determination for the GOM DPS of Atlantic salmon
described in this notice is exempt from the requirements of NEPA.
Information Quality Act
The Information Quality Act directed the Office of Management and
Budget to issue government wide guidelines that ``provide policy and
procedural guidance to Federal agencies for ensuring and maximizing the
quality, objectivity, utility, and integrity of information (including
statistical information) disseminated by Federal agencies.'' Compliance
of this document with NOAA guidelines is evaluated below.
Utility: The information disseminated is intended to describe the
species' life history, population status, threats, and risks;
management actions; and the effects of management actions. The
information is intended to be useful to state and Federal agencies,
non-governmental organizations, industry groups and other interested
parties so they can understand the listing status of the species.
Integrity: No confidential data were used in the analysis of the
impacts associated with this document. All scientific data considered
in this document and used to analyze the proposed action, is considered
public information.
Objectivity: The NOAA Information Quality Guidelines require
disseminated information to be presented in an accurate, clear,
complete, and unbiased manner. This document was prepared with these
objectives in mind. It was also reviewed by agency biologists, policy
analysts, and managers and NOAA and Department of Commerce attorneys.
Administrative Procedure Act
The Federal Administrative Procedure Act (APA) establishes
procedural requirements applicable to informal rulemaking by Federal
agencies. The purpose of the APA is to ensure public access to the
Federal rulemaking process and to give the public notice and an
opportunity to comment before the agency promulgates new regulations.
These public notice and comment procedures have been completed in this
rulemaking.
[[Page 29385]]
Coastal Zone Management Act
Section 307(c)(1) of the Federal Coastal Zone Management Act of
1972 requires that all Federal activities that affect any land or water
use or natural resource of the coastal zone be consistent with approved
state coastal zone management programs to the maximum extent
practicable. NMFS has determined that this action is consistent to the
maximum extent practicable with the enforceable policies of approved
Coastal Zone Management Programs of Maine. A letter documenting NMFS'
determination and a copy of the proposed rule was sent to the coastal
zone management program office in Maine. The specific state contact and
a copy of the letter is available upon request. A copy of the final
rule will be sent to the coastal zone management program office in
Maine.
Executive Order (E.O.) 13132 Federalism
E.O. 13132, otherwise known as the Federalism E.O., was signed by
President Clinton on August 4, 1999, and published in the Federal
Register on August 10, 1999 (64 FR 43255). This E.O. is intended to
guide Federal agencies in the formulation and implementation of
``policies that have Federal implications.'' Such policies are
regulations, legislative comments or proposed legislation, and other
policy statements or actions that have substantial direct effects on
the states, on the relationship between the national government and the
states, or on the distribution of power and responsibilities among the
various levels of government. E.O. 13132 requires Federal agencies to
have a process to ensure meaningful and timely input by state and local
officials in the development of regulatory policies that have
federalism implications. A Federal summary impact statement is also
required for rules that have federalism implications.
Pursuant to E.O. 13132, the Assistant Secretary for Legislative and
Intergovernmental Affairs provided notice of the action at the proposed
rulemaking stage and requested comments from the appropriate
official(s) in Maine. Comments were received from Senators Snowe and
Collins, Congressman Michaud, and from the State of Maine. Among other
concerns, they stated that a threatened listing determination could be
justified under the ESA and advocated that the Services suspend a
decision on the Androscoggin until further genetic data could be
gathered and analyzed. These comments were considered by the Services
in preparing this final rulemaking action and are addressed in the
Response to Public Comments section above. A Federal summary impact
statement has been prepared and sent to the appropriate State
officials.
Environmental Justice
Executive Order 12898 requires that Federal actions address
environmental justice in decision-making process. In particular, the
environmental effects of the actions should not have a disproportionate
effect on minority and low-income communities. The final listing
determination is not expected to have a disproportionately high effect
on minority populations and low-income populations in Maine because the
implications of this listing action do not adversely affect the human
health of low-income, minority, or other populations or the environment
in which these various populations live.
E.O. 12866, Regulatory Flexibility Act, and Paperwork Reduction Act
As noted in the Conference Report on the 1982 amendments to the
ESA, economic impacts shall not be considered when assessing the status
of a species. Therefore, the economic analysis requirements of the
Regulatory Flexibility Act are not applicable to the listing process.
In addition, this rule is exempt from review under E.O. 12866. This
rule does not contain a collection-of-information requirement for the
purposes of the Paperwork Reduction Act.
E.O. 13175--Consultation and Coordination With Indian Tribal
Governments
E.O. 13175 requires that, if we issue a regulation that
significantly or uniquely affects the communities of Indian tribal
governments and imposes substantial direct compliance costs on those
communities, we consult with those governments or the Federal
government must provide the funds necessary to pay the direct
compliance costs incurred by the tribal governments. This rule does not
impose substantial direct compliance costs on the communities of Indian
tribal governments. Accordingly, the requirements of section 3(b) of
E.O. 13175 do not apply to this final rule. Nonetheless, we met with
tribal governments potentially affected by this listing decision and to
solicit their input on the proposed rule. We have given careful
consideration to all written and oral comments received and will
continue our coordination and discussions with interested tribes as we
move forward specifically with implementing this final rule as well as
salmon recovery and management in general.
List of Subjects
50 CFR Part 17
Endangered and threatened species, Exports, Imports, Reporting and
recordkeeping requirements, Transportation.
50 CFR Part 224
Administrative practice and procedure, Endangered and threatened
species, Exports, Imports, Reporting and recordkeeping requirements,
Transportation.
Dated: June 11, 2009.
Samuel D. Rauch III,
Acting Assistant Administrator for Fisheries, National Marine Fisheries
Service.
Dated: May 12, 2009.
Stephen Guertin,
Acting Director, U.S. Fish and Wildlife Service.
0
For the reasons set out in the preamble, 50 CFR parts 17 and 224 are
amended as follows:
PART 17--ENDANGERED AND THREATENED WILDLIFE AND PLANTS
0
1. The authority citation for part 17 continues to read as follows:
Authority: 16 U.S.C. 1361-1407; 16 U.S.C. 1531-1544; 16 U.S.C.
4201-4245; Pub. L. 99-625, 100 Stat. 3500, unless otherwise noted.
0
2. In Sec. 17.11(h) revise the entry for ``Salmon, Atlantic'', which
is in alphabetical order under FISHES, to read as follows:
Sec. 17.11 Endangered and threatened wildlife.
(h) * * *
* * * * *
[[Page 29386]]
--------------------------------------------------------------------------------------------------------------------------------------------------------
Species
-------------------------------------------------------- Historic range Vertebrate population where Status When Critical Special
Common name Scientific name endangered or threatened listed habitat rules
--------------------------------------------------------------------------------------------------------------------------------------------------------
* * * * * * *
Fishes
* * * * * * *
Salmon, Atlantic, Gulf of Maine.. Salmo salar......... U.S.A., Canada, U.S.A., ME, Gulf of Maine Distinct E ........ NA NA
Greenland, western Population Segment. The GOM DPS
Europe. includes all anadromous Atlantic
salmon whose freshwater range
occurs in the watersheds from the
Androscoggin River northward
along the Maine coast to the
Dennys River, and wherever these
fish occur in the estuarine and
marine environment. The following
impassable falls delimit the
upstream extent of the freshwater
range: Rumford Falls in the town
of Rumford on the Androscoggin
River; Snow Falls in the town of
West Paris on the Little
Androscoggin River; Grand Falls
in Township 3 Range 4 BKP WKR, on
the Dead River in the Kennebec
Basin; the un-named falls
(impounded by Indian Pond Dam)
immediately above the Kennebec
River Gorge in the town of Indian
Stream Township on the Kennebec
River; Big Niagara Falls on
Nesowadnehunk Stream in Township
3 Range 10 WELS in the Penobscot
Basin; Grand Pitch on Webster
Brook in Trout Brook Township in
the Penobscot Basin; and Grand
Falls on the Passadumkeag River
in Grand Falls Township in the
Penobscot Basin. The marine range
of the GOM DPS extends from the
Gulf of Maine, throughout the
Northwest Atlantic Ocean, to the
coast of Greenland. Included are
all associated conservation
hatchery populations used to
supplement these natural
populations; currently, such
conservation hatchery populations
are maintained at Green Lake
National Fish Hatchery (GLNFH)
and Craig Brook National Fish
Hatchery (CBNFH). Excluded are
landlocked salmon and those
salmon raised in commercial
hatcheries for aquaculture.
* * * * * * *
--------------------------------------------------------------------------------------------------------------------------------------------------------
PART 224--ENDANGERED MARINE AND ANADROMOUS SPECIES
0
3. The authority citation for part 224 continues to read as follows:
Authority: 16 U.S.C. 1531-1543 and 16 U.S.C. 1361 et seq.
0
4. Amend the table in Sec. 224.101, by revising the entry for
``Atlantic salmon'' in the table in Sec. 224.101(a) to read as
follows:
Sec. 224.101 Enumeration of endangered marine and anadromous species.
* * * * *
(a) Marine and anadromous fish. * * *
[[Page 29387]]
----------------------------------------------------------------------------------------------------------------
Species \1\ Citation(s) for Citation(s) for
------------------------------------------------ Where listed listing critical habitat
Common name Scientific name determination(s) designation(s)
----------------------------------------------------------------------------------------------------------------
* * * * * * *
Gulf of Maine Atlantic salmon Salmo salar..... U.S.A., ME, Gulf of Maine 65 FR 69469; NA
Distinct Population November 17,
Segment. The GOM DPS 2000; 74 FR
includes all anadromous [Insert page
Atlantic salmon whose number where the
freshwater range occurs document
in the watersheds from begins]; June
the Androscoggin River 19, 2009.
northward along the
Maine coast to the
Dennys River, and
wherever these fish
occur in the estuarine
and marine environment.
The following impassable
falls delimit the
upstream extent of the
freshwater range:
Rumford Falls in the
town of Rumford on the
Androscoggin River; Snow
Falls in the town of
West Paris on the Little
Androscoggin River;
Grand Falls in Township
3 Range 4 BKP WKR, on
the Dead River in the
Kennebec Basin; the un-
named falls (impounded
by Indian Pond Dam)
immediately above the
Kennebec River Gorge in
the town of Indian
Stream Township on the
Kennebec River; Big
Niagara Falls on
Nesowadnehunk Stream in
Township 3 Range 10 WELS
in the Penobscot Basin;
Grand Pitch on Webster
Brook in Trout Brook
Township in the
Penobscot Basin; and
Grand Falls on the
Passadumkeag River in
Grand Falls Township in
the Penobscot Basin. The
marine range of the GOM
DPS extends from the
Gulf of Maine,
throughout the Northwest
Atlantic Ocean, to the
coast of Greenland.
Included are all
associated conservation
hatchery populations
used to supplement these
natural populations;
currently, such
conservation hatchery
populations are
maintained at Green Lake
National Fish Hatchery
(GLNFH) and Craig Brook
National Fish Hatchery
(CBNFH). Excluded are
landlocked salmon and
those salmon raised in
commercial hatcheries
for aquaculture.
* * * * * * *
----------------------------------------------------------------------------------------------------------------
\1\ Species includes taxonomic species, subspecies, distinct population segments (DPSs) (for a policy statement,
see 61 FR 4722, February 7, 1996), and evolutionarily significant units (ESUs) (for a policy statement, see 56
FR 58612, November 20, 1991).
* * * * *
[FR Doc. E9-14269 Filed 6-18-09; 8:45 am]
BILLING CODE 3510-22-P