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DISTRIBUTION AND ABUNDANCE OF FISHES IN RELATION TO
BARRIERS: IMPLICATIONS FOR MONITORING STREAM
RECOVERY AFTER BARRIER REMOVAL.
By
Cory Gardner
B.S. Wildlife Ecology, University of Maine 2007.
A THESIS
Submitted in Partial Fulfillment of the
Requirements for the Degree of
Master of Science
Department of Wildlife Ecology
The University of Maine
December, 2010
Advisory Committee:
Stephen M. Coghlan Jr., Assistant Professor of Wildlife Ecology, Co-Advisor
Joseph Zydlewski, Assistant Professor of Wildlife Ecology, Co-Advisor
Kevin Simon, Assistant Professor of Biology
Rory Saunders, Fishery Biologist, NOAA NMFS (ad hoc)
LIBRARY RIGHTS STATEMENT
In presenting this thesis in partial fulfillment of the requirements for an advanced degree
at The University of Maine, I agree that the Library shall make it freely available for
inspection. I further agree that permission for "fair use" copying of this thesis for
scholarly purposes may be granted by the Librarian. It is understood that any copying or
publication of this thesis for financial gain shall not be allowed without my written
permission.
DISTRIBUTION AND ABUNDANCE OF FISHES IN RELATION TO
BARRIERS: IMPLICATIONS FOR MONITORING STREAM
RECOVERY AFTER BARRIER REMOVAL.
By Cory Gardner
Thesis Co-Advisors: Stephen M. Coghlan Jr. and Joseph Zydlewski
An Abstract of the Thesis Presented
In Partial Fulfillment of the Requirements for the
Degree of Master of Science
in Wildlife Ecology
December 2010
Dams are ubiquitous in coastal Maine, and have altered both instream habitats and
the distribution and abundance of fishes in these habitats. These impacts are caused
mainly by a disruption of the natural hydrology, temperature regime, and habitat
connectivity due to physical barriers; the subsequent fragmentation limits the movement
of resident fishes, and prevents anadromous fishes from reaching historic spawning
habitat. Dam removal has become a common method for restoring streams to a more
natural state, but often the response of the fish community is not monitored rigorously.
Sedgeunkedunk Stream, a small tributary to the Penobscot River (Maine, USA)
has been the focus of a restoration effort, which includes the removal of two dams (at 0.6
and 5.3 km upstream of the Penobscot confluence). Currently sea lamprey (Petromyzon
marinus) is the only anadromous species known to spawn successfully in the system.
In this study we quantified fish community metrics, by conducting electrofishing
surveys, along a headwaters-to-mouth gradient in Sedgeunkedunk Stream, establishing
pre-removal baseline conditions and variability. We also described the distribution and
abundance of spawning of sea lamprey in Sedgeunkedunk Stream, in anticipation of
potential range expansion after the completion of the dam removals. Sea lampreys, and
their nests, were censused using daily stream surveys and a mark-recapture model.
Over three years prior to dam removal (2007-2009), the fish community in
Sedgeunkedunk Stream showed consistent trends in species richness and abundance, with
metrics always highest downstream of the lowest dam (minimums of 14 species and 2.7
fish/m2), always lowest immediately upstream of that dam (minimums of 5 species and
0.9 fish/m2), and generally recovering upstream towards the headwaters. Although
seasonal and annual variation in metrics within each site were substantial, patterns across
all sites were remarkably consistent regardless of sampling episode. Immediately after
dam removal, we saw significant decreases in richness and abundance (10 species, 0.7
fish/m2) below the former dam site and a corresponding increase in fish abundance at the
upstream site (5 species, 5.0 fish/m2), and for the first time, anadromous Atlantic salmon
were found upstream of the former dam site. No such changes were obvious in a
reference stream.
In 2008 forty-seven sea lamprey entered the stream, and constructed 31 nests; all
fish received PIT tags, which allowed us to identify and follow movements of
individuals. Individuals that arrived early in the run were active in the system longer, and
used more nests, than did late migrants. Sea lamprey frequently ascended to the first dam
encountered before swimming back downstream and beginning nest construction. Nests
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were distributed from head-of-tide to the lowermost dam; no spawners or nests were
observed in the tidally-influenced zone or upstream of this dam.
Our results show that by quantifying baseline conditions in a small stream before
restoration, the effects of stream restoration efforts on fish communities can be monitored
successfully. Based on the observed movements in the system, and the range of their
habitat use, we anticipate that spawning sea lamprey will re-colonize formerly
inaccessible habitat
Deleted: ,
Deleted: following dam removal,
ii
ACKNOWLEDGEMENTS
Funding for this project was provided by NOAA’s National Marine Fisheries Service, the
Maine United States Geological Survey Cooperative Fish and Wildlife Research Unit, the
University of Maine, and the Maine Agriculture and Forestry Experiment Station. We
also thank R. Cope, G. Goulette, D. Kircheis, T. Liebech, K. Mueller, J. Murphy, B.
Perry, K. Ravana, D. Skall and T. Trinko for assistance in sampling. We thank our field
technicians Silas Ratten, Jacob Kwapiszeski, Ryan Haley, Scott Ouellette, Anthony
Feldpausch, Michael Picard, Meghan Nelson, and many others who helped out along the
way (University of Maine) for their hard work, and Rory Saunders (NOAA) for sparking
our interest in the role of sea lamprey in Sedgeunkedunk Stream. Mention of trade names
does not imply endorsement by the United States government.
Deleted: NOAA NMFS Maine Field Station for assistance with sampling,
Deleted: especially Kyle Ravana and Tara Trinko
iii
TABLE OF CONTENTS
ACKNOWLEDGMENTS………………………………………………………………...ii
LIST OF TABLES………………………………………………………………………...v
LIST OF FIGURES………………………………………………………………………vi
Chapter
1. DISTRIBUTION AND ABUNDANCE OF STREAM FISHES IN RELATION TO
BARRIERS: IMPLICATIONS FOR MONITORING STREAM
RECOVERY AFTER BARRIER REMOVAL……………………………………….......1
Introduction………………………………………………………………………..1
Methods……………………………………………………………………………6
Study Area…………………………………………………………………6
Study Design………………………………………………………………7
Fish Surveys……………………………………………………………….8
Abundance Estimates……………………………………………………...9
Community Assessment…………………………………………………..10
Results……………………………………………………………………………11
Discussion………………………………………………………………………..15
2. DISTRIBUTION AND ABUNDANCE OF ANADROMOUS SEA LAMPREY
(Petromyzon marinus) SPAWNERS IN A DAMMED STREAM: CURRENT STATUS
AND POTENTIAL RANGE EXPANSION
FOLLOWING BARRIER REMOVAL…………………………………………………24 Deleted: 3
iv
Introduction………………………………………………………………………23
Methods…………………………………………………………………………..28
Study area…………………………………………………......................28
Sea lamprey population estimate and behavioral evaluation……………28
Nest surveys and abundance estimation…………………………………29
Results……………………………………………………………………………30
Discussion………………………………………………………………………..33
REFERENCES…………………………………………………………………………..37
BIOGRAPHY OF THE AUTHOR………………………………………………………46
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v
LIST OF TABLES
Table 1.1. Occurrence of species, before the removal of the Mill Dam, in study sites in
Sedgeunkedunk Stream and Johnson Brook, Penobscot Co., Maine. 2007-
2009. …….........................................................................................................11
Table1.2. Shannon Wiener diversity index values for fish community composition in sites
in Sedgeunkedunk Stream and Johnson Brook, Penobscot Co. ME. 2009. …..12
Table 1.3. Sorenson’s Similarity Index values comparing fish community
composition between sites in Sedgeunkedunk Stream and Johnson Brook,
Penobscot CO. ME. 2009…………………………………………………......13
Table 2.1. Number of live sea lamprey captured for the first time on each day of the
sampling period, the mean water temperature of that day and the mean number
of days observed active in the river, and mean number of total nests sea
lamprey that entered on that day used before they died, Sedgeunkedunk
Stream, Penobscot Co., ME 2008. …...............................................................31
Table 2.2. Smallest, largest and mean sizes of sea lamprey nests, and the maximum
number of sea lamprey observed on them in Sedgeunkedunk Stream,
Penobscot Co. ME. 2008. …………………………………………………...33
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vi
LIST OF FIGURES
Figure 1.1. Study sites on Sedgeunkedunk Stream (S1-S5) and Johnson Brook (J1-J3),
Penobscot Co. ME. 2007-2009. ………………………………………………6
Figure 1.2. Species richness at sampling sits along stream gradient in Sedgeunkedunk
Stream and Johnson brook, Penobscot Co. Maine 2008-2009. …..…………12
Figure 1.3. Fish density (#/m2) at sites along stream gradient of Sedgeunkedunk Stream
and Johnson Brook, Penobscot Co. Maine. 2007-2009……………………...14
Figure 1.4. Blacknose dace density (#/m2) at sites along stream gradient of
Sedgeunkedunk Stream and Johnson Brook, Penobscot Co. Maine,
2007-2009. …………………………………………………………………..14
Figure 1.5. Length frequency distribution of blacknose dace at sites below and above
removed dam in Sedgeunkedunk Stream, Penobscot Co. Maine. 2009. …...15
Figure 1.6. Net gain of blacknose dace within size classes at site S1 and S2 following
dam removal in Sedgeunkedunk Stream, Penobscot Co. Maine. 2009. ……15
Figure 2.1. Location of Sedgeunkedunk Stream, Fields Pond, and the dams that were
removed during the Sedgeunkedunk Stream restoration. Penobscot Co.
Maine, USA. ………………………………………………………………...28
Figure 2.2 The cumulative proportion of sea lamprey entering Sedgeunkedunk Stream,
Penobscot Co. Maine. 2008. ………………………………………………...30
Figure 2.3. Frequency of the number of nests individual male, and female sea lamprey
were observed using during the duration of their activity in Sedgeunkedunk
Stream, Penobscot, Co., Maine. 2008. ………………………………………31
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vii
Figure 2.4. Distribution sea lamprey nests, and percentage of substrate made up fines
(smaller than 2mm) along the stream gradient of Sedgeunkedunk Stream,
Penobscot Co., Maine. 2008. ………………………………………………..32
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1
Chapter 1
DISTRIBUTION AND ABUNDANCE OF STREAM FISHES IN RELATION TO
BARRIERS: IMPLICATIONS FOR MONITORING STREAM
RECOVERY AFTER BARRIER REMOVAL.
Introduction
Resilience is defined as the ability of an ecosystem to return to a natural state
following a disturbance (Holling 1973). Often, resilience is dependent upon sufficient
species diversity persisting so that functional groups necessary to restore a natural state
remain (Elmqvist et al. 2003). Ecosystems which are subject to disturbances that occur
over large spatial and temporal scales are more sensitive to a lack of diversity (Elmqvist
et al. 2003). The temporal, and spatial, variability in species-specific responses to
disturbance are likewise important to maintaining ecosystem resilience (Elmqvist at el.
2003). Without a sufficient amount of species diversity the post-disturbance community
may attain different stable states than the one that preceded disturbance (Gunderson
2000).
Since the arrival of European settlers on the east coast of North America, human
population growth and development have led to myriad disturbances in most terrestrial
and aquatic ecosystems (Ehrlich and Holden 1971; Vitousek et al. 1997). Of interest here
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is the construction of dams. For centuries, dams have been built to control flows, create
water supplies, and generate electricity in the coastal watersheds of New England and
elsewhere (Benke 1990). Dams caused changes in hydrology, sediment loading,
temperature regimes, and connectivity within and among ecosystems (Koster et al. 2007;
Petts 1980). Dams building was also associated with increases in industrial pollution.
While the physicochemical effects of dams on streams have been well documented, the
impact of dams on fish communities has not (Baldigo and Warren 2008; Quinn and Kwak
2003). There has been great recent emphasis on restoring stream ecosystems perturbed
by dams; however, it is unknown if these ecosystems have the ecological resilience to
return to a state that resembles preindustrial conditions after centuries of chronic
disturbance.
Dams may impact the distribution and abundance of fish communities by the
disrupting the natural hydrologic and thermal regimes and fragmenting habitat (Winston
et al. 1991). Impoundments convert lotic habitats to lentic (Martinez et al. 1994), and
may decrease sediment loading and increase water temperature downstream (Kinsolving
and Bain 1993; Ligon et al. 1995). Habitat fragmentation can prevent resident fish
species, which make relatively short movements, from accessing habitats that are
necessary in completing their life history (Schmetterling and Adams 2004) or
maximizing energy balance during critical periods (Hall 1972), thus disrupting energy
and material flows in the stream (Hall 1972).
Anadromous fishes are likely to suffer a greater impact from fragmentation
(Benke 1990) than would freshwater residents. Historically, many rivers and ponds in
Maine harbored spawning runs of numerous migratory species, such as Atlantic salmon
Deleted: were built during a period of increasing industrial pollution, as well as directly
3
(Salmo salar), alewife (Alosa pseudoharengus) sea lamprey (Petromyzon marinus) and
rainbow smelt (Osmerus mordax) (Saunders et al. 2006). In the Pacific Northwest,
anadromous fish such as Pacific salmon (Oncorhynchus spp.) can transport marine
derived nutrients and energy into otherwise oligotrophic freshwater ecosystems and
increase primary productivity and microbial decomposition rates of detritus (Brock et al.
2007; Durbin et al. 1979; Wipfli et al. 1998). Such increased productivity , in turn,
facilitates growth in resident fish species (Bilby et al 1996; Scheuerell et al. 2007; Wipfli
et al. 2003). It is likely that some of these relations exist, or existed, in systems on the
Atlantic coast as well. As dams have severed this marine-freshwater connectivity,
anadromous species have experienced worldwide decline (Limburg and Waldman 2009)
and freshwater systems have become more oligotrophic (Stockner et al. 2000). This
connection between anadromous communities and the resilience resident communities in
a perturbed system is poorly characterized.
Abundance, richness, and ultimately diversity of stream fishes increase along the
gradient from headwaters to mouth in a small, non-fragmented stream, due to predictable
increases in the availability and diversity of habitats (Sheldon 1968) and the species pool
of potential colonizers in nearby rivers (Smith and Kraft 2005). These metrics can ebb
and flow upstream and downstream over time in response to discharge and resultant
velocity barriers to potential colonizers from downstream reaches (Grossman et al.,
2010). Ultimately, stream discharge and other physicochemical conditions driven by
landscape changes along this longitudinal gradient lead to patterns of energy and nutrient
flow to which stream ecosystems respond dynamically yet predictably (Vannote et al.,
1980), although interruptions in the continuum evince marked changes in the stream biota
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4
(Ward and Stanford 1983; Jones 2010). In coastal streams, anadromous fish may
penetrate relatively far into headwaters, and the subsidies of marine-derived nutrients and
energy associated with these migrants provides another gradient to which resident fishes
may respond (Mitchell and Cunjak 2007). If the presence of a dam alters these natural
gradients, then the structure and function of fish communities should shift as well.
Sedgeunkedunk Stream, a small tributary of the Penobscot River below head-of-
tide (Figure 1.1), typifies small streams in Maine impacted by dams. Current restoration
efforts offer an opportunity to assess the resilience of the structure and function of this
fish community when released from habitat fragmentation caused by multiple dams.
Runs of anadromous fishes in Sedgeunkedunk Stream have either disappeared or were
reduced substantially after the building of three dams on the stream. Recent declines in
anadromous fishes in Sedgeunkedunk Stream mirror those in the entire Penobscot
watershed, which contains over 100 known dams; however, because Sedgeunkedunk
Stream flows into the Penobscot River below the lowermost mainstem dam (Veazie
Dam), it is one of only three major tributaries that could receive anadromous fishes
before they encounter a relatively large, mainstem dam. Currently, Atlantic salmon in
Sedgeunkedunk Stream and most of the Penobscot watershed are listed as a federally-
endangered species (74 Fed. Reg. 29344; June 19, 2009), and alewife, sea lamprey, and
rainbow smelt are at historic low levels of abundance throughout Maine watersheds
(Saunders et al. 2006).
As part of a collaborative restoration project, fish passage has been created or
restored in Sedgeunkedunk Stream at the location of two former dam sites between Fields
Pond and the confluence with the Penobscot River (Figure 1.1). The lowermost dam
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Deleted: responding to long-term disturbance by, and then relief from,
Deleted: from
Deleted: Sedgeunkedunk Stream drains a 5400 hectare watershed with numerous wetlands and natural and augmented headwater impoundments.
Deleted: (at 0.6, 5.3 and 8.0 km upstream of the confluence with the Penobscot River; heretoafter referred as “stream km).
Deleted: (PRRT 2009)
Deleted: NOAA 2009
5
(Mill Dam) was removed in August 2009, and the middle dam (Meadow Dam) was
bypassed in August 2008 by a rock-ramp fish-way that allows fish passage while
maintaining current water levels in Fields Pond and adjacent wetlands. Thus habitat
connectivity for migrating anadromous and resident fishes has been restored throughout
most of the Sedgunkedunk watershed.
This study began in 2007, two years prior to removal of the lowermost dam, as a
long term monitoring effort directed toward the effects of this restoration on the fish
community in the Sedgeunkedunk watershed. While the reversion towards a more
historic species composition is desired or expected following dam removal, there is often
an initial decline in abundance of resident species until the geomorphology of the stream
is stabilized (Catalano et al. 2007; Doyle et al. 2005). In small streams the physical
recovery from the immediate disturbance of a dam removal can take as little as a year, if
high water events move the sediment from the impoundment downstream quickly
(Burroughs et al. 2009), but the response of the fish community may be protracted (Hart
et al. 2002), illustrating the importance of long term monitoring to characterize biotic
response. Many small streams are characterized by a great deal of variability at different
scales, both spatially (e.g., longitudinally and within short reaches) and temporally (e.g.,
both annually and seasonally) ,which could make the detection of community changes
difficult (Baldigo and Warren 2008; Jackson et al. 2001, Moyle and Vondracek 1985). In
this study the data collected before the removals are used to quantify the baseline
conditions and variability in this altered system, and a neighboring reference system.
Specifically, our objectives were to: 1) Quantify the baseline distribution and
abundance, and the associated variability, of fish species in Sedgeunkedunk Stream
Deleted: impoundment sediment
Deleted: are
6
before final dam removal; 2) Quantify the distribution and abundance of fish species in
Sedgeunkedunk Stream immediately following removal of the lowermost dam; 3)
Determine if the temporal and spatial variability in fish community metrics will allow us
to detect changes in response to dam removals. This work represents the first step in
assessing the long term research goal of characterizing resilience and recovery in small
coastal systems.
Methods
Study Areas
Sedgeunkedunk Stream is a third-order tributary of the Penobscot River,
Penobscot Co. Maine. The stream flows out of Fields Pond at 44°44’05’’N and
68°45’56’’W and debouches into the Penobscot River (at river km 36, which is
approximately at head-of-tide) at 44°46’08’’N and 68°47’06’’W. The stream drains 5400
hectares including Brewer Lake and Fields Pond (Figure 1.1). The lowermost Mill Dam,
which was removed in August 2009, was located just 600 meters upstream of the
stream’s confluence with the Penobscot
River. The middle Meadow Dam, which
was located at stream km 5.3 upstream
from the Penobscot confluence, was
replaced by a rock-ramp fishway in
August 2008. The removal of these two
barriers provides for presumably
unimpeded access from the Atlantic
Figure 1.1. Study sites on Sedgeunkedunk Stream (S1-S5) and Johnson Brook (J1-J3), Penobscot Co. ME. 2007-2009.
P E N
O B S C
O T
R I V
E R
Swetts Pond
Fields Pond
Brewer Lake
Johnson Brook
Sedgeunkedunk Stream
Mill Dam
Meadow Dam
S1
S2
S3
S4
S5
J1 J2 J3
P E N
O B S C
O T
R I V
E R
Swetts Pond
Fields Pond
Brewer Lake
Johnson Brook
Sedgeunkedunk Stream
Mill Dam
Meadow Dam
S1
S2
S3
S4
S5
J1 J2 J3
Deleted: flowing through the Town of Orrington and the City of Brewer, Maine
Deleted: ,
Deleted: draining
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7
Ocean into Fields Pond, via the lower Penobscot River and then Sedgeunkedunk Stream.
The uppermost Brewer Lake Dam, located between Fields Pond and Brewer Lake, will
remain intact, and continue to block passage further upstream in the watershed.
For future monitoring following the dam removal, our study incorporated a
Before-After-Control-Impact design (BACI; Stewart-Oaten et al. 1986), which accounts
for naturally-occurring temporal and spatial variation so that we can attribute differences
in Sedgeunkedunk Stream fishes to restoration efforts irrespective of background noise.
A BACI design requires that pre-impact conditions and variability are known, which we
established by sampling for one year before the restoration project began, and two years
before the lowermost dam removal took place. We also monitored a reference system,
Johnson Brook, which is a tributary of the Penobscot River located in Orrington, Maine
(Figure 1). The stream flows out of Swetts Pond at 44°42’18’’N and 68°47’10’’W and
debouches into the Penobscot River (at river km 24) at 44°42’08’’N and 68°49’50’’W.
This system includes a natural barrier (Clark’s Falls, at stream km 2.2) and a dam at the
outlet of Swetts Pond (at stream km 5.5); these barriers to passage are analogous to the
dams located in Sedgeunkedunk Stream.
Study Design
Five 100-m sampling locations were selected along Sedgeunkedunk Stream
(Figure 1.1). Site S1 is located at stream km 0.45-0.55, immediately downstream of the
former Mill Dam, and was the only site accessible to anadromous fish. Site S2 is located
immediately upstream of the Mill Dam site at stream km 0.62-0.72. Site S3 is located
approximately halfway between the Mill Dam and Meadow Dam sites at stream km 2.5-
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8
2.6. Site S4 is located immediately downstream of the Meadow Dam / Fishway site at
stream km 5.2-5.3. Site S5 is located in upstream of Brewer Lake; because the Brewer
Lake Dam is not scheduled for removal, this site will remain unaffected by the restoration
project and serve as a reference site within Sedgeunkedunk Stream.
Three 50-m sampling locations were selected along Johnson Brook in order to
compare with sites on Sedgeunkedunk Stream before and after barrier removal (Figure
1). These sites were limited to 50 m due to access problems and the presence of beaver
dams and their associated impoundments, which would have limited our ability to sample
100-m long reaches effectively, but likely did not impede fish passage. Site J1 is located
immediately downstream of Clark’s Falls at stream km 3.62-3.67. Site J2 is located
immediately upstream of Clark’s Falls at stream km 3.71-3.76 Site J3 is located
immediately downstream of the dam at the outlet of Swetts Pond at stream km 7.3-7.8.
Fish surveys
Each location was sampled in August of 2007. In 2008 and 2009, each location
was sampled twice per year, once in the spring (usually late May) as soon as spring
runoff subsided and again in late summer (usually mid August) during low-flow
conditions. The Meadow Dam was removed after sampling was completed in 2008. The
Mill Dam was removed immediately before the second sampling of 2009. Fish
abundance at each site was estimated by conducting three-pass depletion estimates
(Zippin 1958) using backpack electrofishers, except for spring 2007 when we conducted
2-pass depletions. Electrofisher settings were 30-60Hz, 20% duty cycle, and ~300-500V,
depending on measured ambient conductivity, and were optimized for maximum power
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9
transfer (Reynolds 1996). Each site was closed to immigration and emigration during the
survey using 3mm-mesh blocking nets. All fish caught were identified to species, and the
first 300 individuals of each species at each site were measured (total length; mm) and
weighed (wet mass; 0.1 g). Except for incidental mortality (<2% for all sampling
events), fish were returned to the stream alive. This repeated electrofishing probably did
not influence the fish community measurably (e.g., Latimore and Hayes 2008). In
summer 2008 all sampling was completed before the removal of the Meadow Dam. In
2009 the summer round of sampling took place within 7 days after the removal of the
Brewer Dam. We sampled Site S1 three days after the dam removal, as soon as that
stream had cleared of suspended sediment enough for us electrofish effectively. We note
that although American eel were present and abundant at all sites at all times, our
catchability was extremely low for small elvers (< 100 mm TL), so we limit analysis of
eel data to qualitative, rather than quantitative, measures (i.e., presence / absence).
Abundance Estimates
At each sampling reach, stream width was measured at ten locations and the area
estimated as the product of reach length and mean width. This sampling area was used in
our estimates of total fish density (# of fish / m2), with associated variances, for each
sampling location (with the exception of American eel, as described above). Differences
in density among reaches and over time were assessed by inspecting overlap of 95%
confidence intervals, which is a conservative estimate (Simpson et al. 1961). This
method does not allow us to assume “no significant difference” when there is an overlap,
Deleted: Each location was sampled twice per year, once in the spring (usually late May), as soon as spring runoff subsided and again in late summer (usually mid August) during low-flow conditions.
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10
however it does allow us to assume a significant difference (at α = 0.05) when there is no
overlap (Payton et al., 2003).
Community Assessment
Temporal and longitudinal changes in the fish assemblages were characterized
using four methods. First, species richness was determined by noting presence/absence
of each species. Comparisons of species richness at among sites, and over time, were
made using a Friedman test and Tukey multiple comparisons (Zar, 1984).
Presence/absence was also used to describe species distribution before barrier removal, in
order to monitor species movement and colonization after removal. Second, we used a
Shannon Wiener species diversity index (Krebs, 1989);
ii PPH ln
for each site over time, where Pi is the proportion of the population belonging to species
i. Third, we used a Sorensen’s Similarity Index (Krebs, 1989);
)/(2 bacQS
where c is the number of common species, and a and b are the total number of species in
the two sites respectively. In this index of similarity the results range from 0 (no
similarity) to 1 (identity).
Differences between mean length and mean mass of species found at all sites
were detected using a two-way ANOVA, with site and sampling time as the main effects.
Lengths of each species were used to construct length frequency histograms, and by
finding natural breaks in the size distribution which separate age classes, we determine
size and age structure, for three common species at each site. A Kolmogorov-Smimov
test was used to find differences between length frequency distributions.
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11
Results
Over the course of this study we
encountered 22 species and 26,873
individual fish (Table 1.1). In 2007, we
captured 4,760 fish in Sedgeunkedunk
Stream. In 2008, we captured 7,872 fish
in Sedgeunkedunk Stream and 3,693 fish
in Johnson Brook. In 2009, we captured
8,516 fish in Sedgeunkedunk Steam and
2,032 in Johnson Brook. The dominant
species in both streams was eastern
blacknose dace (Rhinichthys a.
atratulus). In Sedgeunkedunk Stream
species richness, diversity, and the
density of total fish was highest below the Mill Dam and lowest above the dam. These
metrics then increased along the gradient with increasing upstream from the dam, but
then declined in the isolated headwater site (S5).
In Sedgeunkedunk Stream, prior to dam removal, species richness was always
greatest ( p < 0.03) at site S1 (immediately downstream of Mill Dam) (Figure 1.2). Prior
to dam removal, 14 species were encountered at each sampling episode at S1. This
richness decreased to either 5 or 6 species at site S2 (immediately upstream of Mill Dam).
Species richness remained at this lower level at site S3 at all sampling episodes, but at
site S4 had risen to 9 or 11 species. Site S5 had 8 species present in each spring
Species S1 S2 S3 S4 S5 J1 J2 J3Atlantic salmon Blacknose dace Bluntnose minnow Brown bullhead Creek chub Pumpkinseed sunfish Common shiner Eastern brook trout Chain pickerel American eel Fathead minnow Fallfish Finescale dace Golden shiner Northern redbelly dace Ninespine stickleback Redbreast sunfish White sucker Smallmouth bass White perch Black crappie Yellow perch Alewife
Rainbow smelt
Sea Lamprey
Table 1.1. Occurrence of species, before the removal of the Mill Dam, in study sites in Sedgeunkedunk Stream and Johnson Brook, Penobscot Co., Maine. 2007-2009.
density ≥ 0.1 fish/m2 density ≥ 0.01 fish/m2 density < 0.01 fish/m2 no density estimated
Comment [SC1]: Check with the formatting desired by the graduate school, but usually figures and tables are given their own pages, rather than snuggled nest to text. Same comment applies throughout
Deleted: from moving
Deleted: all
12
sampling, and 7 species present in each summer sampling. Immediately after removal of
the Mill Dam the species richness at site S1 decreased from 14 to 10, and the richness at
the sites upstream were similar to that found in previous samplings. Species that were no
longer found at site S1 following the dam removal were: northern redbelly dace
(Phoxinus eos), finescale dace (Phoxinus neogaeus), fathead minnow (Pimephales
promelas), and ninespine stickleback (Pungitius pungitius). In Johnson Brook, the
species richness at site J1
(downstream of Clark’s Falls)
ranged from 8-11. This decreased
to 4-6 species at site J2 (upstream
of Clark’s Falls). Richness was
always highest at site J3
(downstream of Swett’s Pond
Dam, ranging from 10-13 species.
Prior to the removal of the
Mill Dam, Atlantic salmon were
encountered only at site S1. In the fall
of 2008 one Atlantic salmon parr was captured (TL = 152mm), and in the spring of 2009,
one Atlantic salmon fry (TL = 30 mm) was
captured. After the removal of the Mill Dam in
2009, Atlantic salmon parr were captured at site
S2 (5 individuals, mean TL = 83 mm), and 55
were captured at site S3 (55 individuals, mean
0
2
4
6
8
10
12
14
S1 S2 S3 S4 S5
May-08
Jul-08
May-09
Aug-09
0
2
4
6
8
10
12
14
J1 J2 J3
# o
f s
pe
cies
a.Sedgeunkedunk Stream
b.Johnson Brook
0
2
4
6
8
10
12
14
S1 S2 S3 S4 S5
May-08
Jul-08
May-09
Aug-09
0
2
4
6
8
10
12
14
J1 J2 J3
# o
f s
pe
cies
a.Sedgeunkedunk Stream
b.Johnson Brook
Figure 1.2. Species richness at sampling sits along stream gradient in Sedgeunkedunk Stream and Johnson brook, Penobscot Co. Maine 2008-2009.
a. Sedgunkedunk StreamS1 S2 S3 S4 S5
Jul-07 1.18 1.03 0.51 0.82 1.58May-08 1.63 0.66 0.67 1.16 1.67Aug-08 1.22 0.77 0.60 0.65 1.04May-09 1.40 0.43 0.41 0.77 1.32Aug-09 1.44 0.82 0.69 0.56 1.06
b. Johnson BrookJ1 J2 J3
May-08 1.12 1.40 1.88Aug-08 1.06 1.38 1.92May-09 1.36 1.15 1.58Aug-09 1.41 1.24 2.22
Table1.2. Shannon Wiener diversity index values for fish community composition in sites in Sedgeunkedunk Stream and Johnson Brook, Penobscot Co. ME. 2009.
Deleted: In the sampling that followed
Deleted: 5
13
TL = 65 mm).
Species diversity in Sedgeunkedunk Stream was always highest at sites S1 and S5
(Table 1.2). Before the removal of the Mill Dam, sites S1, S4, and S5 had high (i.e., QS
> 0.70) pairwise similarity values, but were less similar to sites S2 and S3; sites S2 which
were highly similar (Table 1.3). In Johnson Brook the diversity was highest at site S3
and lower at site S1 and S2. Total fish density in Sedgeunkedunk Stream was highest at
site S1 and lowest at site S2 during all sampling occasions before the removal of the Mill
Dam (Figure 1.3a). Densities followed a pattern along the stream gradient of increasing
at site S3 and site S4, but decreasing at site S5. Total fish density in Johnson Brook
showed a consistent pattern at all sampling events. Density was higher at site J1, than at
sites J2 and J3 (Figure 1.3b).
The community structure in
Sedgeunkedunk Stream changed following
the removal of the Mill Dam. There was
an increase in diversity at site S2 (Table
1.2). All of the sites in Sedgeunkedunk
stream became more similar (Table 1.3).
Fish density at site S1 showed a significant
decline, while the density at site S2
increased more than five-fold (Figure 1.3a). The density also increased at site S3 and site
S4, but the density at site S5 did not change significantly. There was no change in the
pattern in Johnson Brook over this time period (Figure 1.3b)
a. Sedgeunkedunk StreamS1 S2 S3 S4 S5
S1 - 0.53 0.57 0.80 0.73S2 0.67 - 0.80 0.53 0.57S3 0.78 0.88 - 0.78 0.82S4 0.84 0.71 0.82 - 0.94S5 0.82 0.80 0.93 0.88 -
b. Johnson BrookJ1 J2 J3
J1 - 0.53 0.67J2 0.67 - 0.47J3 0.82 0.59 -
Table 1.3. Sorenson’s Similarity Index values comparing fish community composition between sites in Sedgeunkedunk Stream and Johnson Brook, Penobscot CO. ME. 2009. Values range from 0 (no similarity) and 1 (identity). Values above the dashed line are from before the dam removal. Values below are from after the dam removal.
Deleted: and S3
14
Three species were ubiquitous spatially and temporally in Sedgeunkedunk stream:
eastern blacknose dace, fallfish (Semotilus corporalis), and white sucker (Catostomus
commersoni). Blacknose dace was, often by an order of magnitude, the most abundant
species at all sampling locations and times, and mirrored the pattern seen in overall fish
density. After the removal of the Mill Dam the density of blacknose dace at site S1
decreased significantly, whereas the density at site S2 more than tripled (Figure 1.4a).
The density rose significantly at site S3 and site S4 while the density at site S5 remained
statistically unchanged. Blacknose dace density in Johnson Brook also showed a
S1 S2 S3 S4 S5
Fis
h D
ensi
ty (
#/m
2 )
0
1
2
3
4
5
6
August 2007May 2008July 2008May 2009 August 2009
SITE
J1 J2 J3
0
1
2
3
4
5
6
a. Sedgeunkedunk Stream
b. Johnson Brook
Figure 1.3. Fish density (#/m2) at sites along stream gradient of Sedgeunkedunk Stream and Johnson Brook, Penobscot Co. Maine. 2007-2009. Error bars represent ± 2SE (95% confidence interval).
S1 S2 S3 S4 S5
Fis
h D
ens
ity (
#/m
2 )
0.0
0.5
1.0
1.5
2.0
2.5
3.0
August 2007May 2008July 2008May 2009 August 2009
SITE
J1 J2 J3
0.0
0.5
1.0
1.5
2.0
2.5
3.0
a. Sedgeunkedunk Stream
b. Johnson Brook
Figure 1.4. Blacknose dace density (#/m2) at sites along stream gradient of Sedgeunkedunk Stream and Johnson Brook, Penobscot Co. Maine, 2007-2009. Error bars represent ± 2SE (95% confidence interval).
Deleted: over any other species
Deleted: significantly
15
consistent pattern at all sampling events, with density higher at site J1 than at sites J2 and
J3 (Figure 1.4b).
The mean length and mass of blacknose dace, and all other common species,
differed among all sites at each sampling
occasion (all p < 0.05), but did not show any
consistent spatial or temporal pattern. The
same was true of the size distribution of
blacknose dace, but there was a noticeable
pattern. Before the removal of the Mill
Dam, the size distribution of blacknose dace
lengths was similar among sites S1, S3, and
S4, but skewed towards smaller individuals
at site S2. Immediately following the
removal of the Mill Dam the length
distribution in site S1 was truncated, while the size distribution at site S2 appears to
expand and resemble the distribution in other sites prior to removal (Figure 1.5). The net
losses at site S1 and the net
additions at site S2 of
blacknose dace within size
classes appear to correspond
to each other (Figure 1.6),
especially assuming some
growth in length over the
Figure 1.5. Length frequency distribution of blacknose dace at sites below and above removed dam in Sedgeunkedunk Stream, Penobscot Co. Maine. 2009.
-500 -400 -300 -200 -100 0 100 200 300
25
35
45
55
65
75
Size
Cla
ss
Net Gain in numbers of individuals
S2
S1
Figure 1.6. Net gain of blacknose dace within size classes at site S1 and S2 following dam removal in Sedgeunkedunk Stream, Penobscot Co. Maine. 2009.
Deleted: While our analysis did not show a statistically significant difference between size distributions,
Deleted: ere
Deleted: s
Deleted: and changes
Deleted: S1,
Deleted: if one
Deleted: es
16
time period between samples. There was no such change in Johnson Brook.
Discussion
In the two years of sampling that preceded the removal of the Mill Dam and the
completion of the restoration project in Sedgeunkedunk Stream, we documented
consistent patterns in the distribution and abundance of fishes. These patterns and the
low variability associated with them give us confidence in our ability to detect any long-
term changes that may occur in the system, as does our ability to detect short-term
differences in these patterns that immediately followed the removal of the Mill Dam.
The presence of the Mill Dam in Sedgeunkedunk Stream influenced the
composition, and size structure, of the fish community along the stream gradient. Each
study site along the stream showed a consistent pattern over time, prior to dam removal.
The site directly below the dam (S1), although affected by the hydrological disturbances
associated with a dam, most likely represented the natural habitat condition of the stream
most closely, and was the only site readily accessible to fishes migrating from the
Penobscot River and the Atlantic Ocean. This connectivity to the larger aquatic
ecosystems can allow for the increased species richness and diversity (Lyons and
Schneider 1990; Smith and Kraft 2005); migratory species, like Atlantic salmon and
nine-spine stickleback, as well as resident species from the Penobscot River, could enter
this section of stream. Connectivity also increased habitat availability, due to access to
parts of the Penobscot, and increased thermal variability, due to the presence of a tidal
zone near the mouth of the stream that could create a thermal refuge.
Deleted: .
Deleted: ; migratory
Deleted: variability
17
The study site located directly above the dam (S2) was a straight, slow moving,
impoundment. The riparian zone consisted of grasses that had colonized the sediment
that had been deposited above the dam, replacing the normal forest cover along the
stream. The combination of the exposure, channel straightening, and siltation resulted
seemingly in habitat homogeneity. Because of this, and the lack of connectivity caused
by the dam, this section of stream had fewer fish, and lower species richness and
diversity, than all other sites. The community also contained more large bodied species
like fallfish and white sucker, which could use deeper pools caused by the impoundment
(Petts 1980; Swink and Jacobs 1983). Populations of small-bodied minnows, like
blacknose dace, were dominated by smaller fish. All species found in this site could be
found at other sites as well. While these decreases in abundance and diversity are to be
expected as part of the natural process as one moves up a stream gradient (Sheldon 1968),
the differences between these sites were drastic and occurred over a distance of less than
100 meters.
Species richness, diversity, and the density of total fish increased along the
gradient from moving upstream from the dam. This probably represents a decreasing
impact of the dam on the fish community as it moves upstream from the disturbance
caused by the dam (Kinsolving and Bain 1993; Phillips and Johnston 2004), and shows
that the community at the site directly above the dam represents an interruption of a
natural stream gradient (Sheldon 1968). The fish communities at sites S3and S4 became
more similar to site S1 corresponding to a gradual recover from the interruption caused
by the Mill Dam. The relatively low fish density at site S5, located much further
upstream in the watershed, was probably caused by two factors. Connectivity to
Deleted: utilize
Deleted: ; Vannote et al. 1980),
Deleted: continuum
Deleted: Vannote et al. 1980
Deleted: ,
Deleted: species richness and
18
downstream reaches and the Penobscot River is reduced by another dam and two lakes,
as well as a comparatively long distance from a large pool of potential migrants or
colonizers (e.g., Smith and Kraft 2005). More importantly, this headwaters reach is
located in a steeper, more heavily forested section of the watershed, and is characterized
by lower temperatures and conductivity than in downstream sites. It is also characterized
by shallower pools. Thus, overall production potential of fishes is probably reduced here
(Schlosser 1982). The community at this site is what would be expected in a stream
section higher up in the watershed, and probably is representative of a lightly-impacted
headwaters reach not influenced strongly by anadromous fishes.
The pattern in Johnson Brook was similar to the longitudinal pattern that we
found in Sedgeunkedunk Stream, although the differences above and below the
impassible barrier were not as dramatic, and the distinct changes associated with the Mill
Dam removal was not present here. The site below the impassible falls (J1) showed
higher species richness and diversity than the site directly above the falls (J2), which is
probably a function of habitat disconnectivity, similar to the effect of the Mill Dam in
Sedgeunkedunk Stream. However, there were differences between the site above the
falls in Johnson Brook (J2) and the site above the Mill Dam in Sedgeunkedunk (S2).
While the waterfall acted as a barrier to upstream migration, it was not associated with a
deforested, channelized and sedimented impoundment, like in Sedgeunkedunk Stream, so
it did not harbor a community dominated by larger bodied species. Despite this we still
observed a decline in fish density and species richness above the waterfall in Johnson
Brook analogous to what occurred above the Mill Dam in Sedgeunkedunk. Species that
were found at S1 and J1, and not at S2 or J2 include: fathead minnow, golden shiner
Deleted: Vannote et al., 1980
Deleted: gradient
19
(Notemigonus crysoleucas), northern redbelly dace, and ninespine stickleback. Creek
chub (Semotilus atromaculatus ) was the only species found at site S1, J1 and J2, but not
found at S2. This could imply that it was the impoundment in Sedgeunkedunk that led to
the absence of creek chub, while it was the lack of habitat connectivity that led to the
absence of the previous species. While the farthest upstream site in Johnson Brook (J3)
contained lower fish densities than the site below the falls, it did show an increase in
species richness, most likely due to its location below an old low-head dam located at the
outlet of Swett's Pond. This site often included species normally associated with a lentic
environment that had probably been washed downstream during floods in the spring and
had persisted in a few pools located within the site, associated with a road crossing,
which do not exist in the analogous site in Sedgunkedunk Stream (S4). These species
include brown bullhead Ameiurus nebulosus, chain pickerel Esox niger, and white perch
Morone americana. Predation by these species might explain the very low density of
small-bodied fishes like blacknose dace.
The fact that the fish community in Johnson Brook also showed consistent trends
along the stream gradient over time, similar to those that we found in Sedgeunkedunk
Stream up until dam removal, will allow us to use the BACI design to detect future
changes. During the continued monitoring of the recovery of Sedgeunkedunk Stream,
comparing the changes in the fish community of Sedgeunkedunk Stream to what happens
in Johnson Brook in the context of a BACI design will help isolate changes that are
attributable to restoration from those due to natural variability. This is possible because
the close proximity of the streams should make other regional environmental factors
constant. Over the course of this study longitudinal and temporal patterns in
Formatted: Font: (Default) TimesNew Roman, 12 pt, Italic
Formatted: Font: Not Bold
Formatted: Font: Not Bold, NotItalic
Deleted: e
Deleted: high flow events
Deleted: .
Deleted: Americana
Deleted: background noise
20
Sedgeunkedunk Stream, before the removal of the Mill Dam, and Johnson Brook were
consistent. This consistency allowed us to detect the immediate effects of the disturbance
that took place after the removal of the Mill Dam.
Three days after the removal of the Mill Dam on August 14, 2009, we began post-
removal sampling at site S1. The removal of the dam caused a large amount of sediment
to move through the system; immediately downstream of the former dam site, the stream
was very turbid and the substrate became covered in a layer of silt. The immediate
response to these changes was a decline in species richness and fish density below the
former dam location. Fish mortality can be expected during these types of events of
increased flow and turbidity (Doeg and Koehn 1994). In this case though, some of the
observed decline in density could be caused by movement and not mortality. While there
was not an increase in species richness above the dam site, there was a dramatic increase
in fish density. This is evidence that the species that were common in the stream were
able to move upstream of the disturbance.
The changes in the size structure of blacknose dace show that some of the decline
in fish density below the former dam site could be explained by fish moving upstream.
The length distribution of blacknose dace at site S1 and S2 immediately following the
removal of the Mill Dam show that while site S1 lost a majority of the larger fish during
the disturbance, site S2 showed gains in larger fish. The net gains for each site show that
the losses at site S1 correlate with the gains at site S2, especially if summer growth is
assumed to have taken place. There is still evidence of some mortality associated with
the disturbance, but it is clear that in the larger size-classes of blacknose dace (> 40mm)
many of the fish were able to move upstream. While successful colonization of former
Deleted:
21
dam impoundments by downstream fish species has been shown (Catalanato et al. 2007),
this would have occurred very quickly in our study. Fish densities at sites S3 and S4
reached their highest levels in the study after the dam removal. Small stream fishes like
blacknose dace can move over 1 km in a day (Albanese et al. 2003), which makes the
colonization of site S3 and S4 by fish that previously occupied reaches below the dam
possible. Even if individuals did not migrate all the way up to site S4 it is possible that
there could have been a cascading effect of displacement pushing fish upstream as
densities increased in sites upstream of the former dam. In sites that were not affected by
the removal of the Mill Dam, site S5 in Sedgeunkedunk Stream and all of the sites in
Johnson Brook, we did not detect any deviations from the dominant patterns in
abundance or community structure.
Another possible effect of the dam removal was the colonization of previously
unavailable stream sections by juveniles of anadromous Atlantic salmon. Prior to dam
removal we usually encountered one juvenile Atlantic salmon every time we sampled
below the dam. We were unsure if this was the result of spawning activity in the lower
stream reaches, or if these were individuals who had strayed from elsewhere in the
Penobscot watershed. In the sampling that took place following the dam removal we
captured 5 age 0+ Atlantic salmon parr directly above the former dam site and 55 parr at
site S3. It is possible that adults spawned in Sedgeunkedunk Stream below the Mill
Dam, and that resultant parr moved upstream in response to the disturbance caused by
dam removal. It is also possible that these salmon were juvenile landlocked Atlantic
salmon, but no spawning of landlocked Atlantic salmon has been documented in the
lower Penobscot watershed., Both of these explanations seem unlikely because we
Deleted: .
Deleted: E
Deleted: ,
Deleted: ,
Comment [SC2]: According to Joan, the anadromous explanation is the most likely
Deleted: This seems
22
captured only one fry in the spring of 2009, but otherwise the presence of Atlantic salmon
upstream of the dam immediately after its removal is unexplained and natural
recolonization of formerly inaccessible habitat is the most parsimonious explanation.
In order to detect the response of Sedgeunkedunk Stream to dam removal it is
important to know what the baseline conditions and variability were before the dam
removal. Prior to dam removal we found consistent patterns in space and over time,
which will allow us to detect the changes that take place following the restoration project.
The only deviation from this pattern occurred at the two sites immediately adjacent to the
dam immediately after removal, and our sampling allowed us to detect these changes.
Continued monitoring will allow us to show how the stream fishes below the dam site
recover from the disturbance, and how the entire stream fish community responds to a
more natural hydrology and increased connectivity to large river and marine ecosystems.
Dams have been in place in New England watersheds, for centuries. Every year
more and more dams are being removed in this country in with the goal of river
restoration (Heinz Center 2003). This is often done without a clear idea of what that
restoration means ecologically and without any plan to monitor the response (Bernhardt
et al. 2005). If there is monitoring it is often directed towards a target fish species of
interest (Doyle et al. 2005) rather than a community response.
Dam removals in this country are an expensive undertaking. This money is often
spent without ever really knowing what the results of the efforts are. The preferred
method of implementing a dam removal requires adaptive management. This form of
management involves constant scientific feedback, so that the effects of previous
Formatted: Indent: First line: 0.5"
Deleted: ,
Deleted: ¶
Deleted: Sedgeunkedunk Stream, and in other coastal Maine
Deleted: Their construction and continued presence has caused changes in habitat availability, water quality, and stream connectivity, and ultimately fish abundance and diversity.
Deleted: on
Comment [SC3]: Citation?
23
decisions are known and can inform future actions. This is impossible without effective,
well planned, monitoring (Heinz Center 2003).
Palmer et al. (2005) presented five criteria for successful restoration projects: a
guiding image of the restored system, indicators of ecosystem recovery are improved,
resilience is increased, there is no lasting harm, and that an ecological assessment is
completed. Monitoring is necessary if the project is to be deemed successful.
Sedgeunkedunk Stream provides a model of small coastal stream restoration throughout
Maine and elsewhere. The results of the monitoring here will inform adaptive
management within this system, the Penobscot River watershed, and other restoration
projects in the region.
Formatted: Indent: First line: 0.5"
Deleted: this type of managem
Deleted: which
Comment [SC4]: Here, you should either have an example from Sedgeunkedunk (e.g., monitoring costs vs. removal costs), or a citation. I called Rory and left a message to see if he has those dollar values…
Deleted: inexpensive
Deleted: laid out
Comment [SC5]: Not sure what “improved” means - are they specific?
Comment [SC6]: Technically Johnson IS DAMMED!!!
Deleted: of in the lower Penobscot watershed (includingrecords of ), , and
Deleted: for
Deleted: or not
Deleted: The biotic responses to dam removals usually are not monitored (Bernhardt et al. 2005), or the research is focused on a target fish species (Doyle et al. 2005), rather than a community response, like we have done in this study. Because we do not know what the abundances and size structure of fish species was before the construction of the dams, it is important to know what the baseline conditions and variability were before the restoration. Prior to dam removal we found consistent patterns in space and over time, and low variability, which will allow us to detect the changes that take place following the restoration project. The only deviation from this pattern occurred at the two sites immediately adjacent to the dam immediately after removal, and our sampling allowed us to detect these changes. Continued monitoring will allow us to show how the stream fishes below the dam site recover from the disturbance, and how the entire stream fish community responds to a more natural hydrology and increased connectivity to large river and marine ecosystems. ¶This type of monitoring can be useful in detecting the response of fish communities in dammed streams as dam removals become a more popular restoration effort in Maine and beyond. This restoration project is notable because it takes place downstream of the anticipated Penobscot River Restoration Project, in which two large main-stem dams are to be removed, and fish passage installed or improved at two other dams (PRRT 2009). We view the Penobscot River, structurally and functionally as thousands of Sedgeunkedunk –sized tributaries, and thus this small scale restoration project is the first step towards ... [1]
24
Chapter 2
DISTRIBUTION AND ABUNDANCE OF ANADROMOUS SEA LAMPREY
(Petromyzon marinus) SPAWNERS IN A DAMMED STREAM: CURRENT
STATUS AND POTENTIAL RANGE EXPANSION
FOLLOWING BARRIER REMOVAL
Introduction
Many rivers and ponds in Maine once harbored spawning runs of anadromous fish
species, such as Atlantic salmon (Salmo salar), alewife (Alosa pseudoharengus) sea
lamprey (Petromyzon marinus) and rainbow smelt (Osmerus mordax), (Saunders et al.
2006). These fish likely transported marine derived nutrients and energy (MDNE) into
otherwise oligotrophic freshwater ecosystems, that could stimulate primary productivity
and microbial decomposition of detritus (Brock et al. 2007; Durbin et al. 1979; Wipfli et
al. 1998). MDNE subsidies from Pacific salmon increase productivity and growth of
resident fish species in many Pacific Northwest watersheds (Bilby et al 1996; Scheuerell
et al. 2007; Wipfli et al. 2003), and historically, anadromous fishes in Maine probably
provided similar subsidies (Saunders et al., 20056) . As dams have severed this marine-
freshwater connectivity in Maine and elsewhere, anadromous species have experienced
worldwide decline (Limburg and Waldman 2009) and freshwater systems have become
more oligotrophic (Stockner et al. 2000).
Sedgeunkedunk Stream, a small tributary of the Penobscot River below head-of-
tide (Figure 2.1), typifies small streams in Maine impacted by dams. Current restoration
efforts offer an opportunity to assess how the structure, function, and resilience of the fish
Deleted: likely
Deleted: ing
Deleted: rates
Deleted: Presumably, such
Deleted: ed
Deleted: subsidized
Comment [SC7]: Alaska IS the PNW
Deleted: and Alaskan
25
community responds to long-term disturbance by, and then relief from, habitat
fragmentation from multiple dams. Runs of anadromous fishes in Sedgeunkedunk
Stream either disappeared or were reduced substantially after the building of three dams
on the stream (at 0.6, 5.3 and 8.0 km upstream of the confluence with the Penobscot
River; “stream km”). The downstream dam has been there, in some form, for over two
centuries (S. Shepard, Aquatic Science Associates, personal communication). Declines
in anadromous fishes in Sedgeunkedunk Stream mirror those in the entire Penobscot
watershed, which contains over 100 known dams; because Sedgeunkedunk Stream is one
of only three major tributaries that could receive anadromous fishes before they
encounter a relatively large, mainstem dam on the Penobscot River (i.e., Veazie Dam),
restoration of anadromous fishes here should precede that in tributaries farther upstream
in the watershed when the mainstem dams are removed or bypassed. Currently, Atlantic
salmon in Sedgeunkedunk Stream and most of the Penobscot watershed are listed as a
federally-endangered species (74 Fed. Reg. 29344; June 19, 2009), and alewife, sea
lamprey, and rainbow smelt are at historic low levels of abundance (Saunders et al.
2006).
As part of a collaborative restoration project, fish passage has been created or
restored in Sedgeunkedunk Stream at the location of two former dam sites between Fields
Pond and the confluence with the Penobscot River (Figure 2.1). The lowermost dam
(Mill Dam) was removed in August 2009, and the middle dam (Meadow Dam) was
bypassed in August 2008 by a rock-ramp fish-way that allows fish passage while
maintaining current water levels in Fields Pond and adjacent wetlands. Thus habitat
Deleted: Recent d
Deleted: (PRRT 2009)
Deleted: be accelerated relative to
Deleted: NOAA 2009
26
connectivity for migrating anadromous and resident fishes has been restored throughout
most of the Sedgunkedunk watershed.
Currently, Sedgeunkedunk Stream receives a small run of anadromous sea
lamprey, the only anadromous fish known to spawn in the stream reliably. Adult sea
lampreys are parasitic in the ocean and return to freshwater after two to seven years to
spawn (Beamish 1980). Unlike many anadromous species, sea lamprey do not home to
natal streams (Bergstedt and Seeyle 1995; Waldman et al. 2008), and may select
spawning streams based on flow, temperature (Andrade et al. 2007), or the presence of
chemical compounds released by both ammocoetes and sexually-mature males (Li et al.
2002; Vrieze et al. 2010). This should allow for faster expansion and colonization into
new habitats than for anadromous species with strong homing tendencies, like Atlantic
salmon. The rapid expansion of sea lamprey throughout the upper Great Lakes is strong
evidence of their ability to colonize suitable and accessible streams (Smith and Tibbles
1980). Their capacity for rapid range expansion makes sea lamprey likely to benefit
immediately from restoration efforts in Sedgeunkedunk Stream.
In North America, research on sea lamprey is dominated by Great Lakes issues,
where the species is invasive upstream of Niagara Falls but probably native throughout
the watersheds of Lakes Ontario and Champlain (Waldman et al. 2004, 2006; but see
Eshenmeyer 2009). Sea lamprey invasion has been devastating for economically-
valuable recreational and commercial fisheries (Christie 1973). Because of their highly-
visible parasitism on popular sport fish, sea lamprey have acquired a negative public
image not only in the Great Lakes region, but also within their native range.
Deleted: documented
Deleted: Sea lamprey, u
Deleted: es
Deleted: certainly
Deleted: , and
27
Recolonization and recovery of sea lamprey may be a critical step in the
restoration of native anadromous fish assemblages in Maine. Sea lamprey are an
ecologically significant member of stream ecosystems, both as spawning adults and in the
larval form. They are selemparous, dying in early summer after spawning, making the
adults potential sources of MDNE in otherwise oligotrophic streams – a potentially
important combination of time and place for nutrient subsidies in Maine (Nislow and
Kynard 2009). Adults build nests in shallow riffles or the tails of pools, by moving
cobbles and pebbles into mounds located downstream of a pit. Spawning occurs in the
pit and includes tail and body flexions and vibrations on or near the substrate. Both nest
building and spawning activities appear to clear away fine sediments from the coarse
substrate on a local scale (Kircheis 2004), perhaps reducing substrate armoring and
embeddedness, similar to the effects seen from Pacific salmon aggregations
(Montgomery et al. 1996). Thus it has been suggested that sea lamprey nest building
activities may “condition” potential spawning habitat for Atlantic salmon (Kircheis 2004;
Saunders 2006). Finally, ammocoetes are a potential prey base for other resident species
and act as filter feeders actively trapping nutrients from the water column (Applegate
1950).
This study provides a baseline assessment of the status of sea lamprey in
Sedgeunkedunk Stream, where restoration efforts should make the watershed more
accessible to anadromous fishes. Specifically, our objectives are to: 1) quantify the
abundance and movements of sea lamprey in Sedgeunkedunk Stream before the removal
of the Mill Dam 2) quantify the distribution and abundance sea lamprey nests in
Sedgeunkedunk Stream before the removal of the Mill Dam 3) Assess the likelihood of
Deleted: Sea lamprey are of particular interest in this system not only because they are the lone anadromous species that has been documented to spawn reliably, but because they likely play an important ecological role as a member of a historic assemblage of native anadromous fishes.
Deleted: Q
Deleted: Q
28
colonization of sea lamprey into new habitats made accessible following the removal of
the Mill Dam. This work represents the first step in a long term monitoring of the
response of sea lamprey to this restoration, and the influence of their presence on the
Sedgeunkedunk Stream ecosystem.
Methods
Study Area
Sedgeunkedunk Stream is a third-order tributary of the Penobscot River, flowing
through the Town of Orrington and the City of Brewer, Maine. (Figure 2.1). The
lowermost Mill Dam, which was removed in August 2009, was located just 700 meters
upstream of head of tide, near the stream’s confluence with the Penobscot River, and
Figure 2.1. Location of Sedgeunkedunk Stream, Fields Pond, and the dams that were removed during the Sedgeunkedunk Stream restoration. Penobscot Co. Maine, USA.
P E N
O B S C
O T
R
I V E R
Fields Pond
Sedgeunkedunk Stream
Mill Dam
Meadow Dam
Comment [SC8]: Text in this figure way too small. Same comments about embedding figure in textbody
Deleted: <sp>
29
limited access for anadromous species farther upstream. The removal of this barrier
provides for presumably unimpeded access from the Atlantic Ocean into Sedgeunkedunk
Stream, via the lower Penobscot River. The uppermost Brewer Lake Dam, located
between Fields Pond and Brewer Lake, will remain intact, and continue to block passage
further upstream in the watershed.
Sea lamprey population estimate and behavioral evaluation
We captured sea lamprey in an Indiana-style trap-net that spanned the entire width
of the Sedgeunkedunk Stream, 90 m upstream of the confluence with the Penobscot River
(river km 36), approximately at head-of-tide. Net dimensions included a 3 mm square
mesh, 1.3m x 1.6m rectangular mouth, 1m diameter circular cod end, 2.5 m length, and
wings that extended the width of the stream (4.0 m at time of deployment). We deployed
the net from 15 May to 1 July, 2008. At deployment the thalweg depth was 0.8m, but
water depth varied with stream discharge and tidal cycle. During the first five sampling
days (18-22 June) high water rendered this net ineffective. During this time period we
captured sea lamprey easily with hand nets during stream surveys. The lack of deep
pools and instream structure, combined with low turbidity, facilitated capture of sea
lamprey in the stream. We tagged each captured sea lamprey with both an internal
Passive Integrated Transponder (PIT) tag and an external floy tag. Mass, length, and sex
were recorded for each sea lamprey before release.
During the sea lamprey run, stream surveys were conducted daily. We surveyed
the 610-m reach from the trap net to the Mill Dam, and 2 km above the Mill Dam, and
identified observed fish using a portable PIT tag reader, thus obviating the need to handle
Deleted: 1 inch
Deleted: made us confident in out ability to spot sea la
Deleted: ,
Deleted: was
Deleted: walked
Deleted: -
Deleted: pack
30
fish repeatedly (Hill et al. 2006). We captured any non-tagged sea lamprey with a hand
net and processed them accordingly. At each encounter with a sea lamprey the following
were recorded: whether it was alive or dead, the location in the stream, whether or not it
was found on a nest, and if so which nest and what other individuals were in the nest.
We estimated abundance of adult sea lamprey in Sedgeunkedunk Stream using a POPAN
Jolly-Seber open population mode (Arnason and Schwarz 1995) in the program MARK
(White, G.C. 2008).
Nest surveys and abundance estimation
Daily nest surveys were also conducted throughout the duration of the sea
lamprey spawning run. Each nest location recorded and marked on the stream bank with
flagging. Maximum length, width, and depth were recorded for both the upstream
depression and the downstream mound of each nest, and any sea lamprey occupying nests
were identified. Abundance of nests was estimated using a Cormack-Jolly-Seber mark-
recapture method in MARK. The 610 meters of accessible stream below the Mill Dam
was divided into 61 10-meter sections and lamprey nest abundance was recorded for each
section. We also recorded substrate size along a random transect, running perpendicular
to the stream bank, in each
stream section. Substrate was
sampled by walking heel to toe
along the transect and measuring
the size of the substrate
component at each step.
0
0.2
0.4
0.6
0.8
1
6/18 6/19 6/20 6/21 6/22 6/23 6/24 6/25 6/26 6/27
Date
Prop
orti
on e
nter
ed
Figure 2.2 The cumulative proportion of sea lamprey entering Sedgeunkedunk Stream, Penobscot Co. Maine. 2008.
31
Results
In 2008, the spawning run of
sea lamprey in Sedgeunkedunk
Stream began on 18 June and ended
on 27 June. During that time period
a total of 47 sea lamprey (21 female
and 26 male) was captured and
tagged. The mark-recapture model estimated total abundance (N ± 2SE) of 47 ± 0. Of the
47 lamprey caught only 16 were captured using the trap net. Of those sea lamprey that
evaded the trap net, the mean point of capture was 345 ± 52 m upstream of the net, and 5
sea lamprey were captured initially in the pool directly downstream of the Mill Dam. No
lamprey were observed above the Mill Dam. Males and females were similar in size
(males mean length was 625 ± 23cm and mean mass was 750 ± 100g, females mean
length was 612 ± 22cm and mean mass was 700 ± 100g). There was not a detectable
pattern in size or sex of a sea lamprey and the arrival of it to the stream. Sea lamprey
entered the stream at a
relatively steady rate
throughout the period (Figure
2.2).
Individual sea
lamprey were active in the
stream for an average of 2.5
± 0.5 days (range 1 – 6 days),
Date entered Total Males Females Water temp. (°C) Days active Nests used6/18 5 1 4 16.9 4.4±1.0 1.8±1.26/19 9 5 4 16.5 3.3±1.0 2.0±0.76/20 3 3 0 16.9 4.0±2.0 3.3±1.36/21 7 4 3 18.8 2.1±0.5 1.4±0.76/22 4 2 2 19.5 3.0±2.2 2.8±1.76/23 5 2 3 19.5 1.4±0.8 0.8±0.66/24 3 1 2 20.9 2.0±2.0 0.3±0.36/25 5 4 1 20.9 1.2±0.4 0.2±0.26/26 3 2 1 20.8 1.0 0.3±0.36/27 1 1 0 21.9 1.0 0.0N/A 2 1 1 - - -Total 47 26 21 - 2.5±0.5 1.4±0.4
Table 2.1. Number of live sea lamprey captured for the first time on each day of the sampling period, the mean water temperature of that day and the mean number of days observed active in the river, and mean number of total nests sea lamprey that entered on that day used before they died, Sedgeunkedunk Stream, Penobscot
Co., ME 2008. Means are presented with ±2SE.
02468
1012
0 1 2 3 4 5
# of nests used
# of
lam
prey
Male
Female
Figure 2.3. Frequency of the number of nests individual male, and female sea lamprey were observed using during the duration of their activity in Sedgeunkedunk Stream, Penobscot, Co., Maine. 2008
Deleted: captured
32
and were observed on average 2.3 ± 0.4 times (range 1 – 5 observations). Average linear
distance traveled, based on successive observations of individuals, was 103 ± 48 m (not
including individuals observed only once); minimum and maximum daily means were 89
± 55 m, and 138 ± 50 m. Daily distances ranged from 0 m (i.e. individuals found on the
same nest on consecutive days, n = 3 ) to 255 m. Every lamprey was observed alive; of
these 47 live fish captured, we observed the carcasses of 17 individuals. All observed
carcasses were observed in the wetted stream channel. Carcasses were found, on average,
116 ± 71 m downstream of the point of last live observation. We did not observe any
additional downstream movement of carcasses after first sighting.
While sea lamprey entered the stream everyday from June 18-June 27, we did not
observe any live sea lamprey after June 27. Mean water temperature increased everyday
during the run starting at 16.9° C and reaching 21.9°C on the last day. Sea lamprey that
arrived in the stream earlier, regardless of sex, were able to spend more days in the
stream and, on average, were associated with more total nests before death (Table 2.1).
Females were more likely to be observed on only one or two nests than were males,
whereas males were less likely to be observed associated with a nest or be seen on 3 or
more nests, than were
females (Figure 2.3).
During stream
surveys, 31 nests were
identified. There were
no nests identified
above the Mill Dam.
0
1
2
3
4
5
6
0100 200 300 400 500 600 700
Stream meter
# of
lam
prey
nes
ts
00.10.20.30.40.50.60.70.80.91
% fi
nes
Nests
Fines
Mill Dam
NO ACCESS
Figure 2.4. Distribution sea lamprey nests, and percentage of substrate made up fines (smaller than 2mm) along the stream gradient of Sedgeunkedunk Stream, Penobscot Co., Maine. 2008.
Deleted: .
Deleted: all had died by
Deleted: 8
33
The mark-recapture model estimated total nest abundance (N ± 2SE) of 31 ± 0. Sea
lamprey nests were present in 39% (24 of 61 stream sections) of the stream available to
them. These nests were distributed throughout the stream upstream of head-of-tide to
immediately downstream of the Mill Dam, where the substrate had a low percentage of
fine sediment (<2mm) (Figure 2.4). Sea lamprey nests were present in 87% of the stream
sections characterized by less than 20% fine sediment. No nests were found below head-
of-tide or above the dam. Mean nest dimensions included a pit that was 75cm long, 56cm
wide and 20cm deep, and a mound that was 62cm long, 57cm wide
and 8cm deep (Table 2.2). Nests as attendance ranged from 0 to 6 sea lamprey at one
time, never with more than 2 males or 4 females on any one nest, with a mean number
1.7±0.4 individuals. Females on nests were associated with, on average, 0.9 ± 0.3 other
males and 0.8 ± 0.4 other females. Males, on average, occupied nests with 0.2 ± 0.2
other males, and 0.7 ± 0.4 other females. Females shared nests with, on average, more
male partners than did males (two sample paired means t-test p < 0.0004, df = 15).
Discussion
In 2008, lamprey arrived in Sedgeunkedunk Stream later than in most streams in
the lower Penobscot watershed (Oliver Cox, Maine Department of Marine Resources,
personal communication). In Maine, sea lamprey spawning occurs in late May and early
June when the water temperature reaches 17-19° C (Kircheis 2004). By the time the sea
lamprey arrived the mean daily water temperature in Sedgeunkedunk Stream had
Pit length Pit width Pit depth Pile length Pile width Pile depth Max. # of sea lampreySmallest 4 2 40 23 37 35 11 0Largest 126 101 23 128 101 9 6M ean 7 5±1 1 56±9 20±2 62±14 57±8 8±1 1.8±0.4
Table 2.2. Smallest, largest and mean sizes of sea lamprey nests, and the maximum number of sea lamprey observed on them in Sedgeunkedunk Stream ,Penobscot Co. ME. 2008. Measurements are in cm. Mean of the maximum number of sea lamprey for all nests is shown with ±2SE. Smallest and largest nests determines by area.
Comment [SC9]: Very awkward. “Females shared nests with, on average, more male partners than did males” or something like that
Deleted: There was significantly different between males
Deleted: and females in the number of other males occupying the dame nest nest
34
exceeded 20° C for most of early June. The sea lamprey run might have been triggered
by the temperatures dropping below 17° C on June 17, and then increasing back up to
20°C over 9 days (Binder and McDonald 2008). This decrease in temperature coincided
with an increase in discharge, which has been shown to initiate migration (Almeida et al.
2002). This period of lower temperatures was short, so individuals who arrived early had
more opportunity to take advantage of a brief period of favorable spawning conditions.
We saw no evidence of nest fidelity in either male or female sea lamprey. In fact
we observed that sea lamprey moved often in the system and used multiple nests, with
individuals using as many as 5 nests and travelling as much as 255m between nest sites in
consecutive days. This is consistent with what has been observed in other lamprey
species (Moser et al. 2007). Thus, a single sea lamprey may modify the substrate in
several reaches of the same stream, and multiple sea lampreys may build and expand
upon on a communal nest. Males initiate nest building (Kircheis 2004), and typically
were associated with multiple nests. Males were more likely to be observed away from a
nest than were females, which could be caused by their tendency to move among multiple
nests, possibly in order to avoid sharing nests with other males.
Despite the relatively short reach of Sedgeunkedunk Stream accessible to
anadromous fishes, sea lampreys did spawn there in modest numbers. Our methods of
capture and survey for both sea lamprey and their nests were successful, and our models
of abundance indicated that we were able to capture every sea lamprey in the system and
record every nest location. The use of PIT packs was also very successful in identifying
individuals without any observable disruption of their behavior and we were able to
record the location and activity of individuals on a daily basis.
Deleted: was
35
Historic abundances of sea lamprey in Maine are unknown (Kircheis 2004).
Therefore, we do not know whether 47 sea lamprey in Sedgeunkedunk Stream represents
a run of spawners that is persistent in the system, despite the limited habitat available to
them, or one that is in decline. During 20 year study on the Fort River (which is similar in
size to Sedgeunkedunk Stream), Massachusetts, there was a mean of 80 spawners per
year entering the stream (Nislow and Kynard 2009). Tributaries of Lake Ontario with
less than 1km of available stream below a dam support runs of up to 800 sea lamprey
(Binder et al. 2010). Now that the dams on Sedgeunkedunk have been removed, what
happens next will help us to determine the viability of the sea lamprey spawning run in
the stream. In Portugal, sea lamprey have been shown to use previously-inaccessible
habitat after connectivity is restored (Almeida et al. 2002). It is likely that there will be
an immediate expansion of sea lamprey spawning range in Sedgeunkedunk Stream now
that the Mill Dam has been removed. Many sea lamprey swam to the Mill Dam on the
first day they entered the stream before moving downstream to other nesting habitats.
Also. sea lamprey nests were distributed throughout the available stream below the dam.
We found nests in almost all of the reaches that were not dominated by fine sediment.
This makes us believe that the only factor preventing spawning by sea lamprey further
upstream was the Mill Dam.
Sea lamprey potentially provide important ecological functions in the stream
communities, particularly ones that have lost other anadromous components. Their
semelparous life history make them a potential source of MDNE. We only observed 17
carcasses in the stream, which suggests that the other sea lamprey left before death, the
carcasses were transported somewhere that we could not see it, either by the current or
Deleted:
Deleted: danger of disappearing
Deleted: currently
Deleted: i
Deleted: all the way upstream either to the riffle, or the pool, below the
Deleted: as
36
terrestrial scavengers, or the carcass was washed out of the system. Most sea lamprey
carcasses decompose within 1-2 weeks (Nislow and Kynard 2009), such that MDNE
addition occurs in Sedgeunkedunk Stream before high discharge events wash the
carcasses into the Penobscot River. We did not observe downstream movements of intact
carcasses, but did witness rapid disintegration following carcass deposition.
The nest building behavior of sea lamprey has the potential to act as a substrate
conditioner for Atlantic salmon, especially in a system that does not currently support
reliable salmon spawning. The mean length of sea lamprey nests in the stream was
1.37m, and even the smallest nests that we observed were nearly a meter long; nests of
this size could have a potentially important impact on the substrate of a stream that is
often less than 4 meters wide. If the abundance and distribution of the spawning run
increases with restoration, as we expect, this creates a large potential for sea lamprey to
affect the substrate of a large portion of Sedgeunkedunk Stream. The synergism between
a suite of anadromous species could be an important factor in each species’ recovery
(Saunders et al. 2006). If the numbers of spawning sea lamprey using Sedgeunkedunk
Stream increase following dam removals it could potentially impact the ecology of other
anadromous species through nutrient addition and substrate modification.
Deleted: t
37
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BIOGRAPHY OF THE AUTHOR
Cory Gardner was born in Bangor, Maine on September 13. 1978. He was raised
in Orono, Maine and graduated from Orono High School in 1997. He attended the
University of Maine and graduated in 2007 with a Bachelor’s degree in Wildlife Ecology.
Cory is a candidate for the Master of Science degree in Wildlife Ecology from The
University of Maine in December, 2010.
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The biotic responses to dam removals usually are not monitored (Bernhardt et al.
2005), or the research is focused on a target fish species (Doyle et al. 2005), rather than a
community response, like we have done in this study. Because we do not know what the
abundances and size structure of fish species was before the construction of the dams, it
is important to know what the baseline conditions and variability were before the
restoration. Prior to dam removal we found consistent patterns in space and over time,
and low variability, which will allow us to detect the changes that take place following
the restoration project. The only deviation from this pattern occurred at the two sites
immediately adjacent to the dam immediately after removal, and our sampling allowed us
to detect these changes. Continued monitoring will allow us to show how the stream
fishes below the dam site recover from the disturbance, and how the entire stream fish
community responds to a more natural hydrology and increased connectivity to large
river and marine ecosystems.
This type of monitoring can be useful in detecting the response of fish communities in
dammed streams as dam removals become a more popular restoration effort in Maine and
beyond. This restoration project is notable because it takes place downstream of the
anticipated Penobscot River Restoration Project, in which two large main-stem dams are
to be removed, and fish passage installed or improved at two other dams (PRRT 2009).
We view the Penobscot River, structurally and functionally as thousands of
Sedgeunkedunk –sized tributaries, and thus this small scale restoration project is the first
step towards rehabilitation of a major river system.