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Environmental Influences on Juvenile Fish Abundances
in a River-Dominated Coastal System
L. Carassou
Graham
a b
a
, B. Dzwonkowski
& J. Mareska
a
, F. J. Hernandez
a
, S. P. Powers
a b
, K. Park
a b
, W. M.
c
a
Dauphin Island Sea Laborat ory, 101 Bienville Boulevard, Dauphin Island, Alabama, 36528,
USA
b
Depart ment of Marine Sciences, Universit y of Sout h Alabama, 307 Universit y Boulevard,
Lif e Science Building Room 25, Mobile, Alabama, 36688, USA
c
Alabama Depart ment of Conservat ion and Nat ural Resources, Marine Resources Division,
Post Of f ice Box 189, 2 Nort h Iberville Drive, Dauphin Island, Alabama, 36528, USA
Available online: 22 Dec 2011
To cite this article: L. Carassou, B. Dzwonkowski, F. J. Hernandez, S. P. Powers, K. Park, W. M. Graham & J. Mareska (2011):
Environment al Inf luences on Juvenile Fish Abundances in a River-Dominat ed Coast al Syst em, Marine and Coast al Fisheries,
3: 1, 411-427
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Marine and Coastal Fisheries: Dynamics, Management, and Ecosystem Science 3:411–427, 2011
C American Fisheries Society 2011
ISSN: 1942-5120 online
DOI: 10.1080/19425120.2011.642492
ARTICLE
Environmental Influences on Juvenile Fish Abundances
in a River-Dominated Coastal System
L. Carassou,* B. Dzwonkowski, and F. J. Hernandez
Dauphin Island Sea Laboratory, 101 Bienville Boulevard, Dauphin Island, Alabama 36528, USA
S. P. Powers, K. Park, and W. M. Graham
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Department of Marine Sciences, University of South Alabama, 307 University Boulevard,
Life Science Building Room 25, Mobile, Alabama 36688, USA; and Dauphin Island Sea Laboratory,
101 Bienville Boulevard, Dauphin Island, Alabama 36528, USA
J. Mareska
Alabama Department of Conservation and Natural Resources, Marine Resources Division,
Post Office Box 189, 2 North Iberville Drive, Dauphin Island, Alabama 36528, USA
Abstract
We investigated the influence of climatic and environmental factors on interannual variations in juvenile abundances of marine fishes in a river-dominated coastal system of the north-central Gulf of Mexico, where an elevated
primary productivity sustains fisheries of high economic importance. Fish were collected monthly with an otter trawl
at three stations near Mobile Bay from 1982 to 2007. Fish sizes were used to isolate juvenile stages within the data set,
and monthly patterns in juvenile fish abundance and size were then used to identify seasonal peaks for each species.
The average numbers of juvenile fish collected during these seasonal peaks in each year were used as indices of annual
juvenile abundances and were related to corresponding seasonal averages of selected environmental factors via a
combination of principal components analysis and co-inertia analysis. Factors contributing the most to explain interannual variations in juvenile fish abundances were river discharge and water temperature during early spring–early
summer, wind speed and North Atlantic Oscillation index during late fall–winter, and atmospheric pressure and
wind speed during summer–fall. For example, juvenile abundances of southern kingfish Menticirrhus americanus
during summer–fall were positively associated with atmospheric pressure and negatively associated with wind speed
during this period. Southern kingfish juvenile abundances during late fall–winter were also negatively associated with
wind speed during the same period and were positively associated with river discharge during early spring–early
summer. Juvenile abundances of the Atlantic croaker Micropogonias undulatus during early spring–early summer
were negatively associated with river discharge and North Atlantic Oscillation during late fall–winter. Overall, the
importance of river discharge for many of the species examined emphasizes the major role of watershed processes
for marine fisheries production in coastal waters of the north-central Gulf of Mexico.
Long-term monitoring of many marine fish populations has
revealed the importance of temporal variability at interannual
and decadal scales (Hollowed et al. 2001; Lehodey et al. 2006).
Interannual variations in adult fish abundances are mainly dependent on processes occurring during the early life stages
(Cushing 1996; Fuiman and Werner 2002). In turn, survival
rates of juvenile fish are a principal driver of variable year-class
strength in the resulting adult population (Houde 1997; Miller
and Kendall 2009). Identifying the factors that affect the interannual variability in juvenile fish abundances is thus critical for
Subject editor: Suam Kim, Pukyong National University, Busan, South Korea
*Corresponding author: laurecarassou@gmail.com
Received January 24, 2011; accepted August 16, 2011
411
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412
CARASSOU ET AL.
a better understanding of variability in adult fish abundances and
fisheries landings, and of fish population responses to a changing
environment (Myers 1998; Brunel and Boucher 2007).
Among the factors affecting interannual patterns in juvenile
fish abundances, climatic and local environmental variability
plays an important role (Cushing 1996; Brunel and Boucher
2007). Juvenile abundances of a variety of fish species throughout the world have been related to indices of large-scale climate
patterns, such as the Pacific Decadal Oscillation, the North Atlantic Oscillation (NAO), or El Niño–Southern Oscillation Index
(SOI; Hollowed et al. 2001; Lehodey et al. 2006). These general
climatic indices are synthetic representations of climate patterns
at ocean basin scales, which affect local environmental conditions influencing juvenile fish abundances at the local habitat
level. For example, minimum winter air temperature along the
East Coast of the United States was shown to track larger-scale
variations in NAO and was identified as a potential mechanism
explaining juvenile abundances of the Atlantic croaker Micropogonias undulatus (Hare and Able 2007). Variability in sea
surface temperatures (Ciannelli et al. 2005; Brunel and Boucher
2007), river discharge (Crecco et al. 1986; Martino and Houde
2010), and wind patterns (Daskalov 2003; Lloret et al. 2004)
also participate in shaping variable estuarine–coastal hydrodynamic conditions that influence juvenile fish abundances.
The extent to which earlier studies can be generalized,
however, remains uncertain because the intensity of climatic
and environmental controls on juvenile fish abundances varies
as a function of space and time (Myers 1998; Planque and
Buffaz 2008). For example, correlations between environmental
factors and juvenile fish abundances are generally more obvious
and robust at the edges of the biogeographical ranges of fish
species (Myers 1998) or during specific seasons or climatic
phases (Ottersen et al. 2006; Planque and Buffaz 2008).
Moreover, different components of environmental variability
influence fish production at high versus low latitudes (Brander
2007). Biological factors, such as spawning stock biomass,
have also been shown to affect the strength and significance
of environmental controls on juvenile fish abundance patterns
(Ottersen et al. 2006; Brander 2007). These spatial, temporal,
and population-specific variations emphasize a need for
addressing the influence of environmental factors on juvenile
fish abundances for multiple fish species in diverse ecosystems.
This may provide crucial information on the consistency or
variability of environment–juvenile abundance linkages for specific species and help in developing local tools for forecasting
fish population responses to environmental changes.
Whereas many studies have addressed the effect of climatic
and environmental factors on juvenile fish abundance dynamics
along the U.S. East Coast (e.g., Lankford and Targett 2001; Hare
and Able 2007) and West Coast (e.g., Kimmerer et al. 2001;
Clark and Hare 2002), this question has rarely been examined
in the northern Gulf of Mexico despite the economic importance
of fisheries from this region (Browder 1993). The northern Gulf
of Mexico is characterized by several coastal river systems that
are known to enhance coastal primary productivity and support
large finfish and penaeid shrimp fisheries (Browder 1993). Much
of the research conducted in the region has focused on the
Mississippi–Atchafalaya River system, which contributes 90%
of the freshwater input to the Gulf of Mexico (Rabalais et al.
1996) and has been linked to fisheries production (Govoni 1997;
Grimes 2001). However, relatively little research has focused
on other Gulf river systems and their relationships to fisheries
production. The Mobile Bay River system, in particular, which
is formed at the confluence of the Tombigbee and Alabama
rivers, drains an area of 115,000 km2 and represents the fourthlargest discharge in the USA and the second largest in the Gulf
of Mexico (Schroeder 1978).
In the Mobile Bay area, published studies dealing with the
ecology of fish early life stages had so far been limited to analyses of ichthyoplankton seasonality (Hernandez et al. 2010a,
2010b). Information about juvenile fish dynamics and responses
to environmental factors is thus essential for a better understanding of interannual variability in fisheries production in this area.
The objectives of the present study are thus to (1) describe interannual patterns in juvenile abundance displayed by common
coastal marine fish species over a 26-year time series in coastal
waters off Mobile Bay, Alabama, and (2) explore the relationships between these abundance patterns and a variety of climatic
and local environmental factors.
METHODS
Data sources.—Fish abundance data were provided by a
fisheries-independent survey, the Fisheries Assessment and
Monitoring Program (FAMP), conducted by the Alabama Department of Conservation and Natural Resources (ADCNR),
Marine Resources Division (MRD). Sampling consisted of
monthly otter trawl collections at a variety of sites along the
Alabama coast from 1982 to 2007. The otter trawl had a 4.9-m
opening and was made of 35-mm stretched mesh with a 4.5-mm
cod end fitted with a 4.7-mm liner. For the present study, data obtained at three coastal stations near Mobile Bay were compiled:
Petit Bois Pass, Mobile Pass, and Perdido Pass (Figure 1). At
each station and month (i.e., each sample), fish collected were
identified and a maximum of 50 individuals were measured for
each species (standard length, to the nearest 1 mm). Due to
some modifications in the sampling design over the course of
this long-term survey, 12 out of the 312 months of sampling
were missing (no sample in October, November, or December
1998; January, June, July, August, or October 1999; January,
March, or May 2000; or August 2005). In these instances, fish
abundance values were replaced by the corresponding monthly
averages over the 26-year period (i.e., 1982–2007).
Two general climate indices and seven local environmental
factors (listed in Table 1) were obtained from National Oceanic
and Atmospheric Administration (NOAA) National Weather
Service (NWS) Climate Prediction Center (NOAA 2010a),
NOAA National Data Buoy Center (NDBC; NOAA 2010b),
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ENVIRONMENTAL INFLUENCES IN A RIVER-DOMINATED COASTAL SYSTEM
413
FIGURE 1. Locations of otter trawl stations (circles) of the Fisheries Assessment and Monitoring Program conducted by the Alabama Department of Conservation
and Natural Resources’ Marine Resources Division, and locations of environmental stations (squares) of the National Oceanic and Atmospheric Administration’s
National Data Buoy Center (stations DPIA1 and 42007). Locations of the two U.S. Geological Survey gaging stations (Alabama and Tombigbee rivers; USGS
2010a, 2010b) are not shown because they are situated farther north on land.
and U.S. Geological Survey (USGS) websites (USGS 2010a,
2010b). Data from NOAA–NWS were provided at monthly
intervals. Data from NOAA–NDBC were collected at hourly
intervals. Daily river discharge data were collected from two
USGS gaging stations in the Alabama River (Clairborne Lock
and Dam; USGS 2010a) and in the Tombigbee River (Coffeeville Lock and Dam; USGS 2010b). Their sum was used as
a total freshwater discharge into Mobile Bay (Park et al. 2007).
Fish data analysis.—Due to the scarcity of information regarding relationships between juvenile fish abundances and
TABLE 1.
environmental conditions in the study area, a multispecies approach was favored. We removed very rare species since their
highly variable abundance and occurrence may confound multispecies patterns of interest (Wood and Austin 2009). Only the
species contributing to at least 0.5% of the total fish abundance
observed over the 26-year period were thus retained. Furthermore, fish age estimations are not available in the FAMP data
set used in this study and published size-at-age relationships
are not available for the retained species in the study region.
We thus used size data to sort out juvenile stages in the data set.
Climatic and environmental factors examined, with their respective units, sources, and codes. Measurement stations are depicted in Figure 1.
Variable
Units
General climatic factors
El Niño–Southern Oscillation Index
North Atlantic Oscillation index
Local environmental factors
Air temperature
Water temperature
Wind speed
u-wind component (alongshore)
v-wind component (cross-shore)
Atmospheric pressure
River discharge
◦
C
C
m/s
m/s
m/s
bar
m3/s
◦
Source
Code
NOAA 2010a
NOAA 2010a
soi
nao
NOAA 2010b (stations 42007 and DPIA1)
NOAA 2010b (stations 42007 and DPIA1)
NOAA 2010b (stations 42007 and DPIA1)
NOAA 2010b (stations 42007 and DPIA1)
NOAA 2010b (stations 42007 and DPIA1)
NOAA 2010b (stations 42007 and DPIA1)
USGS 2010a (Clairborne Lock and Dam, Alabama River); USGS
2010b (Coffeeville Lock and Dam, Tombigbee River)
AT
WT
WS
uW
vW
AP
RD
414
CARASSOU ET AL.
TABLE 2. Fish species commonly collected as juveniles in otter trawl samples at three stations in the Mobile Bay area from 1982 to 2007, the respective juvenile
size boundaries (standard length, mm), total number of juveniles (estimated N), 3-month peaks in juvenile abundance (2-month peaks for pinfish; see Figure 3), and
corresponding seasonal groups and codes. Species are ordered alphabetically. Monthly patterns in juvenile abundance and mean size are depicted in Figure 3. See
Methods for details on juvenile fish abundance estimations and on the determination of juvenile size boundaries and seasonal groups. Juvenile fish size distribution
plots are provided in Figure 2.
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Species
Juvenile size
boundaries (mm)
Estimated N Peak months
Bay anchovy Anchoa mitchilli
25–36
943
May–Jul
Hardhead catfish Ariopsis felis (formerly
Arius felis)
Atlantic bumper Chloroscombrus chrysurus
Sand seatrout Cynoscion arenarius
60–125
2,172
Nov–Jan
30–97
30–128
1,591
245
Sep–Nov
Apr–Jun
Silver seatrout Cynoscion nothus
Fringed flounder Etropus crossotus
30–159
20–84
278
565
Pinfish Lagodon rhomboides
30–105
161
Spot Leiostomus xanthurus
30–122
719
Southern kingfish Menticirrhus americanus
30–136
279
Atlantic croaker Micropogonias undulatus
30–139
1,936
Nov–Jan
Sep–Nov
Dec–Feb
Jul–Sep
Dec, Jan
Aug, Sep
Dec–Feb
Jun–Aug
Nov–Jan
Jun–Aug
May–Jul
Atlantic thread herring Opisthonema
oglinum
Gulf butterfish Peprilus burti
30–109
2,851
Apr–Jun
16–99
618
Feb–Apr
Atlantic moonfish Selene setapinnis
Blackcheek tonguefish Symphurus plagiusa
20–236
20–90
294
772
Aug–Oct
May–Jul
Hogchoker Trinectes maculatus
20–99
247
Nov–Jan
Jul–Sep
We followed Miller and Kendall’s (2009) definition of the juvenile stage: only fish larger than the size at metamorphosis, size
at which squamation begins, size at which fin rays development
is completed (depending on data availability in the literature),
or a combination thereof, and smaller than the size at maturity,
were considered as juveniles. Consequently, only species for
which the latter parameters were available in the literature were
finally retained (Table 2).
Species-specific sizes at maturity (Smat ) were obtained from
FishBase (Froese and Pauly 2010) and Pattillo et al. (1997).
When Smat estimates differed between the two references, the
lower value was retained because using a lower Smat value
reduces the likelihood that any mature individuals are included
in the analysis (i.e., most conservative approach). Size at metamorphosis, size at which squamation begins, or size at which
fin ray development is completed were obtained from Gallaway
Seasonal group
Code
Early spring–early anmit(I)
summer
Late fall and winter arfel(II)
Summer and fall
Early spring–early
summer
Late fall and winter
Summer and fall
Late fall and winter
Summer and fall
Late fall and winter
Summer and fall
Late fall and winter
Summer and fall
Late fall and winter
Summer and fall
Early spring–early
summer
Early spring–early
summer
Early spring–early
summer
Summer and fall
Early spring–early
summer
Late fall and winter
Summer and fall
chchr(III)
cyare(I)
cyare(II)
cynot(III)
etcro(II)
etcro(III)
larho(II)
larho(III)
lexan(II)
lexan(III)
meame(II)
meame(III)
miund(I)
opogl(I)
pebur(I)
seset(III)
sypla(I)
sypla(II)
trmac(III)
and Strawn (1974), Richards (2006), Fahay (2007), and Able
and Fahay (2010) for hardhead catfish; Martin and Drewry
(1978), Ditty and Truesdale (1983), and Rotunno and Cowen
(1997) for Gulf butterfish; and Switzer (2003) for blackcheek
tonguefish. When these latter estimates differed between
different references for a given species, the larger value (i.e.,
most conservative) was retained. Juvenile size boundaries were
then refined for each species by visualizing length frequency
plots of all measured fish for each species (data not shown).
Final juvenile size boundaries are shown in Table 2, and length
frequency plots of measured juvenile fish for each species are
shown in Figure 2. For each sample, the proportion of measured
individuals comprised within the juvenile size boundaries was
then calculated and applied to the total number of fish collected
for each species, providing an estimate of the abundance of
juveniles for each species in each sample (Table 2).
415
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ENVIRONMENTAL INFLUENCES IN A RIVER-DOMINATED COASTAL SYSTEM
FIGURE 2. Size distribution of measured juvenile fish from 15 species collected between 1982 and 2007 with an otter trawl at three stations from the Mobile
Bay area, Alabama. Common names of species are provided in Table 2.
Monthly patterns in juvenile fish abundances over the 26year study period were examined in order to identify seasonal
peaks for each species (Figure 3). Depending on species, one
to two seasonal peaks were selected, a seasonal peak cor-
responding to the three consecutive months (two months in
the case of pinfish) during which juvenile abundances were
the highest (Figure 3). Based on these seasonal peaks, three
groups of species were identified: (1) species for which juvenile
CARASSOU ET AL.
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416
FIGURE 3. Monthly patterns in juvenile abundance and mean size for 15 fish species collected in 1982–2007 at three sites (Figure 1). Average (±SE) juvenile
abundances are shown with column charts and are associated with the left y-axes. Mean sizes (standard length [SL], mm) are represented by black shaded circles
and are associated with the right y-axes. Species are presented in alphabetical order. Months selected for the calculation of annual juvenile abundance indices and
corresponding seasonal groups for each species are shown in Table 2; common names of species are also provided in Table 2.
abundances peaked from early spring through early summer
(i.e., group I, six species), (2) species for which juvenile abundances peaked in late fall and winter (group II, seven species),
and (3) species for which juvenile abundances peaked during
summer and fall (group III, eight species; Figure 3; Table 2).
For each group, the average number of juvenile fish collected
during the seasonal peak was used as the annual juvenile fish
abundance index (JAI) for each species (JAIs were thus based
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ENVIRONMENTAL INFLUENCES IN A RIVER-DOMINATED COASTAL SYSTEM
on average numbers of juveniles collected in the two to three
seasonal peak months × three stations = six to nine samples
per year).
The JAIs were processed to obtain standardized annual
anomalies by removing the mean and dividing with the SD
over the 26-year period. Multispecies patterns in JAIs were then
analyzed using centered principal components analysis (PCA),
which is adapted to the treatment of variables expressed in
similar units, and relies on the computation of covariances between variables (Legendre and Legendre 1998). The JAIs were
log10 (x + 1) transformed in order to clarify the projection of
highly variable observations (years) and descriptors (species)
on the factorial axes (principal components [PCs]), as recommended by Legendre and Legendre (1998) for Poisson distributed data. Three centered PCAs were conducted, one for
each fish species group (I, II, III). The visualization of covariances between species (columns) and years (lines) on the two
first PCs (PC1–PC2) provided a graphical synthetic representation of interannual patterns in juvenile abundances for each
group of species. The absolute contributions (i.e., loadings) of
each species on PC1 and PC2 were finally examined to isolate
species that had a minor contribution (i.e., <5%) in driving interannual patterns in juvenile abundances for each group. This
resulted in a total of three species from group III that were
ignored in analyses of environment–juvenile abundance relationships.
Environmental data analysis.—Data for all climatic and environmental factors were processed to obtain monthly averages
for each variable. These monthly averages were obtained from
higher resolution data for environmental factors (minimum of
20 d of data for each monthly average) or directly provided
for climatic factors (Table 1). Short gaps in the NOAA–NDBC
data (less than 13 h) were replaced with an estimated value determined by linear interpolation between the two closest data
points. Due to large gaps in temperature and wind data, two
NDBC stations (42007 and DPIA1 in Figure 1) were merged
into a single time series. Gaps in the DPIA1 time series were
filled using data from station 42007 that was adjusted using a
linear fit to account for the minor magnitude differences for each
parameter at the individual sites.
Monthly averages were then used to calculate seasonal averages for each factor. These seasonal averages were computed in
accordance with the seasonal groups identified in fish data: (1)
average of months included in JAI calculations for fish species
of group I, February–July (i.e., early spring–early summer);
(2) average of months included in JAI calculations for fish
species of group II, November–February (i.e., late fall–winter);
and (3) average of months included in JAI calculations for fish
species of group III, June–November (i.e., summer–fall). Seasonal averages of environmental factors were then analyzed
using normed PCA (Legendre and Legendre 1998), which is
adapted to the treatment of variables expressed with different
units and relies on the computation of correlations between variables (Legendre and Legendre 1998). Three normed PCAs were
417
conducted, one for each seasonal group (I, II, III). The visualization of correlations between environmental factors (columns)
and years (lines) on the two first PCs (PC1–PC2) provided
a graphical synthetic representation of interannual patterns in
environmental conditions for each seasonal group. Moreover,
correlations between variables on PC1–PC2 and absolute contributions (i.e., loadings) of variables were used to isolate a small
number of independent factors that drove interannual patterns in
environmental conditions at each season. Only variables with a
contribution greater than 20% were retained, and when two variables were found highly correlated, only the one showing the
highest contribution on PC1–PC2 was selected. This resulted
in a total of 12 variables (four per seasonal group) that were
retained for analyses of environment–juvenile fish abundance
relationships.
Analysis of relationships between environmental and fish
data.—The influence of environmental variables on interannual
patterns in juvenile fish abundances was studied using a coinertia analysis (COIA). Co-inertia analysis is a two-table symmetric coupling method that provides great flexibility in identifying the common structure in a pair of data tables (Dolédec and
Chessel 1994; Dray et al. 2003). Co-inertia analysis is based on
the statistic of co-inertia, which provides a measure of concordance between two data sets (Dray et al. 2003). The principle
of COIA is to search for a vector in the environmental space
and a vector in the faunistic space that maximizes the co-inertia
between them (Thioulouse et al. 2004). These two vectors are
used to define a new ordination plan on which environmental
and faunistic variables are compared. Graphical results are then
interpreted as in other multivariate methods: the distance of
variables to the origin is indicative of their contribution on the
ordination plan, and the angle between them measures their relationship (Legendre and Legendre 1998). In the present study,
COIA was based on the matching between the coordinates of
selected environmental factors on a new normed PCA and of selected fish variables on a new centered PCA (PCA–PCA–COIA;
Dray et al. 2003). The normed PCA on environmental factors
was based on a matrix composed of 26 lines (years) and 12
columns (four variables per seasonal group). The centered PCA
on fish data was based on a matrix composed of 26 lines (years)
and 18 columns (six species from group I, seven species from
group II, and five species from group III). A Monte-Carlo test
with 1,000 permutations of the observations was used to confirm the significance of the co-inertia results (fixed-D test; Dray
et al. 2003). All multivariate analyses were performed with the
ADE-4 software (Thioulouse et al. 2001).
RESULTS
Interannual Variations in Juvenile Fish Abundances
The two first PCs of the PCA conducted on fish group I
(species for which juvenile abundances peaked in early spring
through early summer; Figure 4a) explained 65.8% of interannual variability in juvenile abundances. Relatively high JAIs
CARASSOU ET AL.
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418
FIGURE 4. Principal components analyses conducted on log10 (x + 1) transformed standardized annual juvenile abundance indices of (a) six fish species
characterized by juvenile seasonal peaks in early spring through early summer (seasonal group I), (b) seven fish species characterized by juvenile seasonal peaks
in late fall and winter (seasonal group II), and (c) eight fish species characterized by juvenile seasonal peaks in summer and fall (seasonal group III). Covariances
between species and projections of years on the principal components 1 and 2 (PC1–PC2) are represented in the left and right columns, respectively. Bold labels
indicate species that were retained for co-inertia analysis of environment–juvenile abundance relationships (i.e., species with total contributions > 5% on PC1–PC2;
Table 3). Scales are given in the rounded boxes. Fish species codes and seasonal groups are defined in Table 2. Six species were represented in more than one
seasonal group as a result of large juvenile abundances throughout several seasons (Figure 3; Table 2): sand seatrout and blackcheek tonguefish in groups I and II;
and fringed flounder, pinfish, spot, and southern kingfish in groups II and III.
419
ENVIRONMENTAL INFLUENCES IN A RIVER-DOMINATED COASTAL SYSTEM
TABLE 3. Absolute contributions (%) of environmental variables and fish species on the two first principal components (PC1, PC2, and sum of PC1–PC2) of
the normed and centered principal components analyses (PCAs), respectively. For each data set, three PCAs were conducted: one on early spring–early summer
values (group I), one on late fall–winter values (group II), and one on summer–fall values (group III). Projections of variables–species and years on the PC1–PC2
plane are depicted in Figures 4 and 5. Codes of environmental variables are defined in Table 1. Fish species codes and groups are defined in Table 2. See Methods
for details on the selection of variables and species retained for the co-inertia analysis.
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PCA group I
Variable or species
PC1
PC2
soi
nao
AT
WT
WS
uW
vW
AP
RD
22.91
8.34
16.58
8.65
3.78
0.10
9.43
25.04
5.13
3.85
0.34
19.77
35.04
20.09
3.24
0.02
2.55
15.06
anmit
arfel
chchr
cyare
cynot
etcro
larho
lexan
meame
miund
opogl
pebur
seset
sypla
trmac
16.47
4.61
34.76
2.83
PCA group II
Sum
PC1
PC2
Environmental Variables
26.76
13.46
15.33
8.68
1.80
19.63
36.35
25.27
12.56
43.69
24.52
9.96
23.87
6.78
6.79
0.50
11.68
3.34
9.45
10.08
0.00
27.59
8.69
11.51
20.19
8.86
12.49
Fish Species
21.08
1.13
14.31
37.59
28.69
0.05
5.62
0.95
15.89
71.68
29.64
15.94
77.30
14.38
4.01
18.39
PCA group III
Sum
PC1
PC2
Sum
28.79
21.43
37.83
34.48
13.57
12.18
10.08
20.20
21.35
3.93
9.98
14.92
25.63
11.03
4.68
0.77
28.99
0.05
0.54
0.64
27.54
5.48
27.68
0.32
11.47
4.00
22.28
4.47
10.62
42.46
31.11
38.71
5.00
12.24
32.99
22.33
1.01
0.14
1.15
7.12
23.32
0.00
7.98
37.05
83.10
0.20
0.40
1.60
0.02
90.22
23.52
0.40
9.58
37.07
0.72
2.09
2.81
22.76
12.42
35.18
15.44
10.97
44.43
55.40
16.39
0.61
29.48
32.37
23.27
11.31
0.73
1.90
39.66
11.92
30.21
34.27
9.02
4.02
13.04
were observed for Gulf butterfish and Atlantic thread herring in
1988, 2004, and 2007; for Atlantic croakers in 1985 and 2005;
and for sand seatrout, bay anchovy, and blackcheek tonguefish
in 1983 and 1999. For the six species from group I, JAIs were
generally lower for 10 out of the 26 years of the time series (years
grouped in the top-right part of the PC1–PC2 plane; Figure 4a).
These six species all presented total contributions greater than
5% on the PC1–PC2 factorial plane (Table 3).
The two first PCs of the PCA conducted on fish group II
(species for which juvenile abundances peaked in late fall and
winter; Figure 4b) explained 68.0% of interannual variability in
juvenile abundances. Sand seatrout and spot presented relatively
high JAIs in 1990, 1999, and 2001 and lower JAIs in 1992.
Southern kingfish, fringed flounder, and blackcheek tonguefish
had higher JAIs in 1983, 1984, and 1988 and lower JAIs in 1982
and 2002. Hardhead catfish and pinfish presented relatively high
JAIs in 2000 and 2004 (Figure 4b). The seven species from
group II were generally characterized by low JAIs for 13 out of
the 26 years of the time series (years grouped on the bottomleft part of the PC1–PC2 plane; Figure 4b). All seven species
presented total contributions greater than 5% on the PC1–PC2
plane (Table 3).
The two first PCs of the PCA conducted on fish group
III (species for which juvenile abundances peaked in summer
and fall; Figure 4c) explained 54.6% of interannual variability in juvenile abundances. Silver seatrout presented relatively
high JAIs in 1995, 1996, 2000, 2002, 2005, and 2007 (Figure 4c). Hogchokers and spot had high JAIs in 1983, 1985,
1998, and 1999 (Figure 4c). Fringed flounder and southern
kingfish JAIs were also generally higher in 1982, 1984, and
1987 (Figure 4c). Atlantic bumpers, pinfish, and Atlantic moonfish had minor contributions to interannual patterns in JAIs
during this season, their contributions being less than 5% on
the PC1–PC2 plane (Table 3). As a result, these three species
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CARASSOU ET AL.
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were ignored for the COIA of environment–juvenile abundance
relationships.
Interannual Variations in Environmental Conditions
The two first PCs of the PCA conducted on environmental averages from group I (Figure 5a) explained 48.0% of interannual variability in environmental conditions during early
spring through early summer. Six variables had total contributions greater than 20% of the PC1–PC2 plane (Table 3). Years
1990, 1999, 2000, and 2006 were generally characterized by
relatively higher water and air temperatures (Figure 5a). Higher
river discharge and wind speeds were observed in 1991, 1995,
1997, 1998, and 2003, and the contrary was true in 1985, 1986,
1996, and 2007 (Figure 5a). High values of SOI and atmospheric
pressure characterized 1982 and 1989, and the contrary was true
in 1983 and 1987 (Figure 5a). In total, four variables were selected as representative of environmental interannual variability
in early spring through early summer based on a compromise
between their correlations and relative contributions (Figure 5a;
Table 3) and consistency with variables selected for the two
other seasonal groups (see below): SOI, water temperature, river
discharge, and wind speed (Figure 5a).
The two first PCs of the PCA conducted on environmental
averages from group II (Figure 5b) explained 50.9% of interannual variability in environmental conditions during late fall
and winter. Six variables had total contributions greater than
20% on the PC1–PC2 plane (Table 3). Years 1986, 1989, 1992,
and 1997 were characterized by high values of wind speed and
river discharge and low values of SOI and atmospheric pressure,
whereas the contrary was true for 1985 and 1999 (Figure 5b).
The NAO presented relatively high values in 1994 and 2004 and
relatively low values in 1995, 2000, and 2002 (Figure 5b). Relatively high water and air temperatures were observed in 1988,
1990, 1998, and 2007, and the contrary was true in 1983, 1987,
1991, 1993, 2003, and 2006 (Figure 5b). Four variables were
selected as representative of environmental interannual variability in late fall and winter based on a compromise between
their correlations and relative contributions (Figure 5b; Table 3): NAO, water temperature, river discharge, and wind speed
(Figure 5b).
The two first PCs of the PCA conducted on environmental averages from group III (Figure 5c) explained 45.7% of
interannual variability in environmental conditions during summer and fall. Five variables had total contributions greater than
20% on the PC1–PC2 plane (Table 3). Wind speed appeared
relatively high in 1988, 1995, 1999, 2003, and 2005 and relatively low in 1982, 1984, 1985, 1986, 1990, 1993, and 2000
(Figure 5c). Water and air temperatures were relatively high in
1998, 2002, 2004, 2006, and 2007 and were relatively low in
1987, 1991, and 1992 (Figure 5c). Particularly low river discharge occurred in 1982 and 1986, and high river discharge
occurred in 1997 (Figure 5c). Four variables were selected as
representative of environmental interannual variability in summer and fall based on a compromise between their correlations
and relative contributions (Figure 5c; Table 3): atmospheric
pressure, water temperature, river discharge, and wind speed
(Figure 5c).
Of noticeable interest is also the observation that for two out
of the three seasonal groups, river discharge appeared highly
negatively correlated with SOI (in early spring–early summer
and in late fall–winter; Figure 5a, b). Similarly, a slight positive
correlation was observed between NAO and water temperature
in late fall and winter, and a strong negative correlation was
observed between NAO and water temperature in summer and
fall (Figure 5b, c).
Environment–Juvenile Abundance Relationships
The three first axes of the COIA allowed 78.3% of the
common structure between environmental and fish data sets
to be visualized (Figure 6a, b). The significance level from
the Monte Carlo permutation test was 0.027. However, the
total inertia was 0.80, indicating a relatively low statistical
agreement between the two data sets. Nevertheless, relationships emphasized by the COIA appeared to be of meaningful ecological sense. The common structure between fish and
environmental data sets was mainly driven by river discharge
during early spring through early summer, wind speed during late fall and winter, and water temperature during summer
and fall (Figure 6a, b; Table 4). For brevity, only the clearest relationships linking environmental factors and species presenting total contributions greater than 10% on the three first
axes of the co-inertia will be commented on further (Figure 6;
Table 4).
Juvenile abundances of sand seatrout during early spring
through early summer were positively associated with river discharge during this season (Figure 6a). Juvenile abundances of
Atlantic croakers in early spring through early summer were
negatively associated with river discharge and NAO, and to a
lesser extent with water temperature, during late fall and winter
(Figure 6a, b). Juvenile abundances of Gulf butterfish during
early spring through early summer were positively associated
with SOI and water temperature and negatively associated with
river discharge during this season (Figure 6a, b).
Juvenile abundances of sand seatrout during late fall and winter were positively associated with water temperature and NAO
during late fall–winter and were negatively associated with river
discharge during late fall–winter and early spring–early summer
(Figure 6a, b). Juvenile abundances of fringed flounder during late fall and winter were negatively associated with water
temperature and positively associated with river discharge during early spring through early summer (Figure 6a, b). Juvenile
abundances of southern kingfish during late fall and winter were
negatively associated with wind speed during this season, and
were positively associated with river discharge during early
spring through early summer (Figure 6a, b).
Juvenile abundances of silver seatrout during summer and
fall were positively associated with water temperature and
wind speed and negatively associated with atmospheric pressure
421
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ENVIRONMENTAL INFLUENCES IN A RIVER-DOMINATED COASTAL SYSTEM
FIGURE 5. Principal components analyses conducted on normalized environmental factors averaged over (a) early spring through early summer (i.e.,
February–July; seasonal group I), (b) late fall and winter (November–February; seasonal group II), and (c) summer and fall (i.e., June–November; seasonal
group III). Correlations between environmental factors and projections of years on the principal components 1 and 2 (PC1–PC2) are represented in the left and right
columns, respectively. Bold labels indicate variables that were retained for co-inertia analysis of environment–juvenile abundance relationships (i.e., independent
variables with a total contribution > 20% on PC1–PC2; Table 4). Scales are given in the rounded boxes. Codes for environmental factors are defined in Table 1.
Downloaded by [109.215.205.118] at 09:18 22 December 2011
422
CARASSOU ET AL.
FIGURE 6. Co-inertia analysis (see Methods) coupling 12 normalized environmental factors (four variables/seasonal group) and log10 (x + 1) transformed
standardized juvenile abundance indices of 18 fish species (six species from seasonal group I, early spring–early summer; seven species from seasonal group II, late
fall–winter; and five species from seasonal group III, summer–fall; Table 2) on (a) axes 1 and 2 of the co-inertia and (b) axes 1 and 3 of the co-inertia. Projections
of environmental variables and fish species are given in the top and bottom panels, respectively. Total inertia is 0.80, and the percentage of variance explained is
64.3% on axes 1 and 2 and 56.2% on axes 1 and 3. Significance level (P) of the fixed-D Monte Carlo permutation test with 1,000 permutations was 0.027. Fish
species codes and seasonal groups are defined in Table 2; environmental factor abbreviations are defined in Table 1.
during this season (Figure 6a, b). Juvenile abundances of fringed
flounder during summer and fall were positively associated with
atmospheric pressure and negatively associated with wind speed
during this season, and were positively associated with river
discharge during early spring through early summer (Figure
6a, b). Juvenile abundances of spot during summer and fall
were positively associated with river discharge during early
spring through early summer (Figure 6a). Juvenile abundances
of southern kingfish during summer and fall were positively
associated with atmospheric pressure and negatively associated
with wind speed during this season, and were positively associated with river discharge and negatively associated with wind
speed during early spring through early summer (Figure 6a, b).
Finally, juvenile abundances of hogchokers during summer and
fall were positively associated with atmospheric pressure and
negatively associated with wind speed during this season, and
were positively associated with river discharge and negatively
associated with water temperature and SOI during early spring
through early summer (Figure 6a, b). Overall, river discharge
during early spring through early summer appeared to be related to juvenile fish abundances of many species from several
seasonal groups and also presented the highest total contributions of all environmental variables on the three first axes of the
co-inertia (sum of axes 1, 2, and 3 = 50.4%; Table 4).
DISCUSSION
Whereas a variety of local environmental variables were identified as potential controls of juvenile fish abundances in our
study, three of them appeared to affect juvenile dynamics of
ENVIRONMENTAL INFLUENCES IN A RIVER-DOMINATED COASTAL SYSTEM
TABLE 4. Absolute contributions (%) of fish species and environmental variables on the first three axes of the co-inertia analysis. Projections of environmental variables and fish species on axes 1–2 and axes 1–3 of the co-inertia
are depicted in Figure 6a and 6b. Codes of environmental variables are given in
Table 1; fish species codes are defined in Table 2 (seasonal groups: I = early
spring–early summer; II = late fall–winter; III = summer–fall).
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Species or variable
anmit(I)
cyare(I)
miund(I)
opogl(I)
pebur(I)
sypla(I)
arfel(II)
cyare(II)
etcro(II)
larho(II)
lexan(II)
meame(II)
sypla(II)
cynot(III)
etcro(III)
lexan(III)
meame(III)
trmac(III)
soi(I)
WT(I)
WS(I)
RD(I)
nao(II)
WT(II)
WS(II)
RD(II)
WT(III)
WS(III)
AP(III)
RD(III)
Axis 1
Axis 2
Axis 3
0.39
7.77
5.47
0.55
3.52
0.09
4.42
15.52
1.91
2.47
6.59
3.96
0.07
20.95
4.45
20.54
0.02
1.21
7.63
0.28
22.43
1.37
12.21
7.86
1.91
20.49
0.28
1.82
0.00
1.60
4.18
4.07
8.87
0.13
4.09
0.69
Environmental Variables
3.83
3.77
12.87
2.91
6.00
0.54
16.96
2.39
0.75
0.05
0.08
24.75
16.33
22.07
0.61
13.63
10.89
24.41
11.20
0.30
19.44
0.25
0.98
4.88
9.01
0.67
17.77
31.02
9.60
1.68
3.57
0.32
0.03
8.61
9.28
8.38
Fish Species
0.50
6.50
0.21
0.10
2.29
1.07
0.77
0.00
10.09
0.00
2.56
15.23
3.18
3.08
16.09
4.90
22.36
10.99
many species: river discharge, wind speed, and water temperature. Climatic indices that were representative of large-scale,
oceanwide climatic conditions (e.g., SOI and NAO) were also
found to play a role.
River Discharge
River discharge appeared to have a major effect on interannual variations in juvenile fish abundances in the Mobile
Bay area. This result is consistent with previous studies reporting the influence of river discharge on larval or juvenile
fish abundances (or both) along the East Coast (Crecco et al.
1986; Rulifson and Manooch 1990; North and Houde 2003) and
423
West Coast (Turner and Chadwick 1972; Kimmerer et al. 2001)
of the United States. However, the studies cited above were
conducted on anadromous fish species (striped bass Morone
saxatilis, white perch Morone americana, and American shad
Alosa sapidissima) that directly utilize riverine habitats during
the larval or juvenile stages. Our results indicate that juvenile
abundances of nonanadromous coastal marine fish species are
also affected by river discharge variability in waters off Mobile Bay, as has been suggested for Gulf menhaden Brevoortia
patronus, king mackerel Scomberomorus cavalla, and Atlantic
bumpers in the Mississippi River delta (Grimes and Finucane
1991; Govoni 1997). In Europe, variability in recruitment of European anchovy Engraulis encrasicolus (in the Mediterranean
Sea, the Bay of Biscay, and the Black Sea), European whiting
Merlangius merlangus (in the Black Sea), and European bass
Dicentrarchus labrax (in Portugal) has also been linked to variability in river discharge within their respective water bodies
(Daskalov 1999, 2003; Lloret et al. 2004; Planque and Buffaz
2008; Vinagre et al. 2009).
A likely explanation for the observed effect of river discharge
on juvenile abundances of these nonanadromous species may be
the stimulation of coastal marine primary and secondary production by terrestrial nutrient inputs (Day et al. 1989), which in turn
affects the abundance and distribution of zooplanktonic prey of
larval and juvenile fish (Kimmerer 2002; Martino and Houde
2010). Moreover, the inputs of the freshwater layer in coastal
surface waters affect water column stratification, which also influences the distribution of fish larvae and juveniles and their
zooplankton food in the estuaries (Mann 1993; Kimmerer 2002;
Martino and Houde 2010). The influence of river discharge on
juvenile fish abundances may thus result either from variable
feeding conditions for larval and juvenile fish or from variability
in salinity habitats associated with water column stratification.
In the present study, among species for which juvenile abundances peaked in summer and fall (e.g., the fringed flounder,
spot, southern kingfish, and hogchoker) or in late fall and winter
(e.g., the Atlantic croaker, sand seatrout, fringed flounder, and
southern kingfish), many were associated with river discharge
during early spring through early summer, consistent with a
probable effect of river discharge on larval and early juvenile
feeding conditions.
The present study also demonstrated a correlation between
river discharge and large-scale climatic conditions (SOI), illustrating the sensitivity of watershed processes to global climate
variation (Nohara et al. 2006). More specifically, the fluctuations
of El Niño–La Niña phases, reflected by SOI in the present
study, have been shown to affect precipitation patterns in the
study region, which in turn strongly affect river discharge interannual variability (Srivastava et al. 2010). Our results from
the north-central Gulf of Mexico, along with those from other
marine systems, thus suggest that large-scale variations in discharge arising from climate variability as well as from human
watershed regulations (such as dams) can strongly affect coastal
marine fish population dynamics.
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424
CARASSOU ET AL.
Wind
The JAIs of four species—namely southern kingfish during
late fall–winter and summer–fall and silver seatrout, fringed
flounder, and hogchokers during summer and fall—were found
to relate with wind speed in the study area. Variations in juvenile abundances of marine fishes from a wide diversity of coastal
systems, including the U.S. East Coast (Hare and Cowen 1996;
Luettich et al. 1999), South Africa (Hutchings et al. 1998),
Denmark (Nielsen et al. 1998), and Japan (Nakata et al. 2000),
have been linked to wind-driven mechanisms of larval transport. However, in contrast to larval fish, juvenile fish examined
in the present study were well developed and able to control
their swimming direction. Wind is also known to affect vertical
mixing of the water column, thereby influencing primary and
secondary production processes and leading to variable feeding
conditions for juveniles (Mann 1993). Turbulence generated by
wind stress also affects encounter rates of juvenile fish with their
zooplanktonic prey (Mann 1993). In addition, wind stress can
also be an important driver of coastal circulation, thus affecting the distribution of juvenile zooplanktonic prey (North and
Houde 2003). However, most of the relationships found between
wind speed and juvenile abundances in the present study were
negative and were generally found to occur with no seasonal
lags (e.g., juvenile abundances of silver seatrout and fringed
flounder during late fall and winter were negatively related to
wind speed during this season). This tends to suggest that strong
winds resulted in smaller numbers of juveniles collected at the
three sampling stations. Consequently, it remains difficult to
disentangle an effect of wind stress on species catchability from
its potential influence on water column structure and associated
larval transport, larval and juvenile feeding, or both.
Temperature
In the present study, variations in juvenile abundances of
many species were related to water temperature variations (e.g.,
the Atlantic croaker and Gulf butterfish during early spring
through early summer; sand seatrout and fringed flounder during
late fall and winter; and silver seatrout and hogchoker during
summer and fall; Figure 6a, b). Temperature effects on juvenile fish abundances have been widely documented in a variety
of marine ecosystems but primarily for fishes in northern latitudes, such as Atlantic cod Gadus morhua (North Atlantic),
European anchovy and European whiting (Black Sea), walleye pollock Theragra chalcogramma (Alaska), European sprat
Sprattus sprattus (Baltic Sea), and others (Daskalov 1999;
Planque and Frédou 1999; MacKenzie and Köster 2004; Ciannelli et al. 2005). Temperature variations were also shown to
be correlated with NAO in late fall–winter and summer–fall in
the present study (Figure 5b, c). This is consistent with observations from the U.S. East Coast by Hare and Able (2007), who
proposed that winter severity, and in particular minimum temperature (which tracked NAO variability well), was the main
environmental control of winter-spawned Atlantic croaker re-
cruitment success. In the present study, the relationship between Atlantic croaker abundance during early spring through
early summer and water temperature during late fall and winter also reflected a similar relationship, tracking variations of
NAO during late fall and winter (Figure 6b). However, this
relationship was found to be negative, such that juvenile abundances of Atlantic croakers during early spring through early
summer appeared to increase when water temperature and NAO
during fall and winter decreased. This inconsistency between
Hare and Able’s (2007) result and our observations could be
accounted for by the fact that Atlantic croakers are at the edge
of the species’ biogeographical range in the northeast continental shelf of the United States, where Hare and Able (2007)
conducted their study. Conversely, the northern Gulf of Mexico is not only characterized by the highest relative probability of occurrence for this species (Froese and Pauly 2010) but
also by much less severe winters, which could explain a different relationship between this species and temperature conditions than those observed elsewhere. This is consistent with
the hypothesis that correlations between environmental factors and juvenile fish abundances vary as a function of relative locations within the biogeographical ranges of fish species
(Myers 1998).
Other species’ abundances were related to water temperature
in our study: positive relationships were observed for Gulf butterfish in early spring through early summer, for silver seatrout in
summer and fall, and for sand seatrout during late fall and winter
(Figure 6a, b). Conversely, fringed flounder during late fall and
winter and hogchokers during summer and fall were negatively
associated with water temperature during early spring through
early summer (Figure 6a, b). Gulf butterfish spawn from fall
through spring in the study area (Pattillo et al. 1997; Hernandez
et al. 2010a, 2010b). Growth and survival of larvae and early
juveniles of this species could thus be favored by warm conditions during early spring through early summer, explaining
the positive relationship we observed with water temperature
during early spring through early summer for this species. Conversely, fringed flounder and hogchokers spawn in spring and
summer in the region (Pattillo et al. 1997; Hernandez et al.
2010a, 2010b). Larval and early juvenile survival for these two
species could thus be favored in years with cool water temperatures in spring and summer, contributing to higher juvenile
abundances of fringed flounder in late fall and winter and of hogchokers in summer and fall. Such effects of water temperature
on larval and early juvenile growth and survival during spring
and summer (contributing to variable juvenile abundances in
summer, late fall, and winter) were also reported for larval
striped bass along the U.S. East Coast (Secor and Houde 1995;
Rutherford et al. 1997).
Other Potential Drivers
Although the multivariate approach used in this study identified the major environmental variables involved in shaping
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ENVIRONMENTAL INFLUENCES IN A RIVER-DOMINATED COASTAL SYSTEM
multispecies patterns in juvenile fish abundances, the total inertia remained relatively low (0.80), indicating that other biological and environmental factors that have not been considered in
the present study play an important role. For example, dissolved
oxygen concentrations (particularly the occurrence of hypoxic
water masses during summer) have been shown to contribute to
the dynamic of coastal marine communities in the Mississippi
River delta (Rabalais and Turner 1998). The higher probability
of occurrence of hypoxic events during warm years may also
further help in explaining some of the negative relationships between juvenile abundances and water temperature observed in
the present study (e.g., for the fringed flounder and hogchoker).
Such hypoxic events indeed occur every summer in Mobile Bay
(Park et al. 2007) and the Mississippi–Alabama shelf (Brunner
et al. 2006), and they may affect juvenile abundances of fish
species whose larvae or juveniles (or both) are found during
summer in the study area. Similarly, seasonal jellyfish invasions reported in coastal Alabama waters, which are also more
frequent during warm conditions, could also influence juvenile
abundance patterns for some coastal fish species (Graham et al.
2003).
Biological variables, such as spawning stock biomass, may
further help to increase the amount of explained variability in juvenile abundances for some of the species examined (Clark and
Hare 2002; Ottersen et al. 2006). Sand seatrout, Atlantic croakers, and southern kingfish, for example, are heavily harvested in
our region (NOAA 2006), and all three species are bycatch of the
shrimp industry (Diamond et al. 2000; Steele et al. 2002). The
influence of general harvest pressure and shrimp fishery effort
on juvenile abundance and survival of these fishes in our region
is an interesting area of research and should be given particular
attention in a separate analysis. Finally, single-species analyses need to be conducted to account for the potential additive
effects of several environmental and biological factors on fish
juvenile dynamics. Such single-species analyses should be conducted at first on species for which otoliths records are available
and can be used to build the size-at-age relationships requested
for the development of age-specific models (e.g., Atlantic
croaker).
To conclude, this study provides the first investigation of
environmental influences on juvenile fish dynamics by using
a multispecies and multivariable approach in the north-central
Gulf of Mexico, outside of the Mississippi River delta. It confirms the importance of river discharge for fish dynamics in the
region and for nonanadromous coastal marine fish species in
general. Consistent with previous studies, juvenile fish abundances in river-dominated, productive coastal ecosystems appear to track some of the large-scale climate patterns represented by synthetic indices such as the SOI or NAO and by
local environmental conditions, among which river discharge
is prevailing. This result has strong implications for management since it emphasizes the strong associations between
watershed processes and the production of adjacent coastal
fisheries.
425
ACKNOWLEDGMENTS
This study was funded by the Fisheries Oceanography of
Coastal Alabama program at the Dauphin Island Sea Laboratory,
supported by ADCNR. We thank Marcus Drymon (Dauphin Island Sea Laboratory) for help in the acquisition and processing of the FAMP data used in this study, and we are grateful
to the technical personnel from MRD for field and laboratory
work.
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