Diet Overlap and Predation between Smallmouth Bass and Walleye in a North Temperate Lake

Frey, Aaron P.; Bozek, Michael A.; Edwards, Clayton J.; Newman, Steve P.

doi:10.1080/02705060.2003.9663950

Cited by 19 publications

(36 citation statements)

References 29 publications

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“…Previous field studies have indicated some or complete diet overlap between the two species (Fedoruk 1966;Johnson and Hale 1977;Frey et al 2003;Fayram et al 2005;Bacula 2009;Wuellner et al 2010), but none indicated that prey resources were limiting, which would be a necessary criterion for competition (Crowder 1990). Controlling prey availability allowed us to examine both inter-and intraspecific competitions between WAE and SMB at two life stages and under different light conditions and prey resources while also examining feeding behaviors to help elucidate competitive mechanisms; this provided for a more complete understanding of potential interspecific competition that may occur in nature.…”

Section: Discussionmentioning

confidence: 99%

“…Walleye (Sander vitreus) is another native species that could potentially compete with SMB. Food habits studies of walleye (WAE) and SMB in sympatry describe at least some level of prey resources shared between the two species (Fedoruk 1966;Johnson and Hale 1977;Frey et al 2003;Fayram et al 2005;Bacula 2009;Wuellner et al 2010). To date, no study has examined competitive mechanisms of WAE and SMB under controlled conditions (Wuellner 2009).…”

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confidence: 99%

“…Feeding at different times of the day may help partition shared prey resources along a temporal scale (Pianka 1973). Finally, SMB is considered to be a generalist feeder, readily consuming both fish and invertebrates (Clady 1974;Hubert 1977;Johnson and Hale 1977;Winemiller and Taylor 1987;Frey et al 2003;Lott 1996;Gangl et al 1997;Bacula 2009), while WAE is considered to be more piscivorous in its feeding habits (Knight et al 1984;Lyons 1987). Plasticity in food habits of at least one species may allow interspecific competitors to co-exist by reducing demand for a prey resource (Gerking 1994).…”

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confidence: 99%

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Competitive interactions between walleye (Sander vitreus) and smallmouth bass (Micropterus dolomieu) under various controlled conditions

Wuellner

Graeb

Willis

et al. 2011

Journal of Freshwater Ecology

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The range of smallmouth bass (Micropterus dolomieu) is expanding northward, creating new interactions with native predators, including walleye (Sander vitreus). We used a series of experiments to investigate competition between walleye (WAE) and smallmouth bass (SMB) at different life stages and light conditions, identified behaviors that allowed one fish to outcompete another, and evaluated whether prey switching mitigated competitive interactions. Juvenile and adult SMB appeared to outcompete WAE when fed during the daytime; neither species dominated when fed near dusk. Attack rates and capture efficiencies of both species were similar with an intra-or interspecific competitor, but SMB often exploited prey before the competitor had a chance to feed (exploitative competition) or displayed agonistic behaviors toward a potential competitor (interference competition). Prey selectivity of WAE or SMB did not differ when by themselves or with a potential competitor. These results indicate that SMB could outcompete WAE under limiting prey conditions due to the aggressive nature of SMB, but resources may be partitioned at least along a temporal scale.

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Section: Discussionmentioning

confidence: 99%

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confidence: 99%

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confidence: 99%

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Competitive interactions between walleye (Sander vitreus) and smallmouth bass (Micropterus dolomieu) under various controlled conditions

Wuellner

Graeb

Willis

et al. 2011

Journal of Freshwater Ecology

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Section: Introductionmentioning

confidence: 99%

“…It is also presumed that producing eggs earlier confers greater fitness to offspring because earlier-spawned individuals can attain greater size during the growing season by acquiring more food and can reduce size-dependent mortality (Oliver et al 1979, Latto 1992, Ludson and DeVries 1997. Because mortality of young-of-year smallmouth bass can exceed 95% by early fall (Frey et al 2003), increased growth of earlier-spawned young-of-year is believed to translate into increased survival.Another presumed ecological advantage that the larger, earlier-spawned young-ofyear smallmouth bass have is that by attaining a larger size these fish are more prepared for the rigors of over-winter survival, a period of time when little feeding occurs (Oliver et al 1979, Shuter et al 1980. Shuter et al (1 980) demonstrated through modeling and in laboratory studies that smallmouth bass survival to later year classes is contingent on growing large enough by their first fall to sustain them through the winter.…”

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confidence: 99%

Anomalous Spawning of Smallmouth Bass in Nebish Lake, Wisconsin: Implications for Early Spawning and Over-Winter Survival

Brown

Bozek

2010

Journal of Freshwater Ecology

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We observed that the smallmouth bass (Micropterus dolomieu) population in Nebish Lake, Wisconsin spawned twice-once during the traditional spring period and then again in summer, well beyond the typical spawning season for north-temperate lakes. We documented this anomalous spawning behavior and compared the characteristics of smallmouth bass nests built during the two distinct spawning seasons. Smallmouth bass built 463 nests (1 10.2 n e s t s h shoreline) as water temperature was rising toward 20°C. During the summer spawning period, 24 nests (5.7 nestslkm shoreline) were constructed between 1 1 August and 29 August as water temperature was falling. Nests built in summer were significantly farther from shore, in deeper water, farther from cover, larger in diameter, and built by larger males than in the spring. INTRODUCTIONThe smallmouth bass (Micropterus dolomieu) has adapted to life in northtemperate lakes by adopting a spring spawning behavior. Rising spring water temperature triggers nest building by males, usually in shallow, gravel areas, and often associated with physical cover to increase survival on nests (Hubbs and Bailey 1938, Scott and Crossman 1973, Baylis et al. 1993). The largest males spawn first (Ridgway et al. 1991), procuring larger broods, which presumably results in better survival and fitness for offspring (Wiegmann et al. 1992). It is also presumed that producing eggs earlier confers greater fitness to offspring because earlier-spawned individuals can attain greater size during the growing season by acquiring more food and can reduce size-dependent mortality (Oliver et al. 1979, Latto 1992, Ludson and DeVries 1997. Because mortality of young-of-year smallmouth bass can exceed 95% by early fall (Frey et al. 2003), increased growth of earlier-spawned young-of-year is believed to translate into increased survival.Another presumed ecological advantage that the larger, earlier-spawned young-ofyear smallmouth bass have is that by attaining a larger size these fish are more prepared for the rigors of over-winter survival, a period of time when little feeding occurs (Oliver et al. 1979, Shuter et al. 1980. Shuter et al. (1 980) demonstrated through modeling and in laboratory studies that smallmouth bass survival to later year classes is contingent on growing large enough by their first fall to sustain them through the winter. They also used this work to explain the northern limit of smallmouth bass distribution. Lakes north of the 16.6"C mean July air temperature isotherm generally had lower over-winter survival because young-of-year were not able to acquire enough lipid stores during the short growing season. They concluded that smallmouth bass cannot become established in lakes with successive winter-induced year-class failures.It seems logical from a bioenergetics standpoint that spring-spawned fish should survive best and production of these individuals should regulate future year classes and

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18S rRNA metabarcoding diet analysis of a predatory fish community across seasonal changes in prey availability

Waraniak

Marsh

Scribner

2019

Ecology and Evolution

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Predator–prey relationships are important ecological interactions, affecting biotic community composition and energy flow through a system, and are of interest to ecologists and managers. Morphological diet analysis has been the primary method used to quantify the diets of predators, but emerging molecular techniques using genetic data can provide more accurate estimates of relative diet composition. This study used sequences from the 18S V9 rRNA barcoding region to identify prey items in the gastrointestinal (GI) tracts of predatory fishes. Predator GI samples were taken from the Black River, Cheboygan Co., MI, USA (n = 367 samples, 12 predator species) during periods of high prey availability, including the larval stage of regionally threatened lake sturgeon (Acipenser fulvescens Rafinesque 1817) in late May/early June of 2015 and of relatively lower prey availability in early July of 2015. DNA was extracted and sequenced from 355 samples (96.7%), and prey DNA was identified in 286 of the 355 samples (80.6%). Prey were grouped into 33 ecologically significant taxonomic groups based on the lowest taxonomic level sequences that could be identified using sequences available on GenBank. Changes in the makeup of diet composition, dietary overlap, and predator preference were analyzed comparing the periods of high and low prey abundance. Some predator species exhibited significant seasonal changes in diet composition. Dietary overlap was slightly but significantly higher during the period of high prey abundance; however, there was little change in predator preference. This suggests that change in prey availability was the driving factor in changing predator diet composition and dietary overlap. This study demonstrates the utility of molecular diet analysis and how temporal variability in community composition adds complexity to predator–prey interactions.

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Diet Overlap and Predation between Smallmouth Bass and Walleye in a North Temperate Lake

Cited by 19 publications

References 29 publications

Competitive interactions between walleye (Sander vitreus) and smallmouth bass (Micropterus dolomieu) under various controlled conditions

Competitive interactions between walleye (Sander vitreus) and smallmouth bass (Micropterus dolomieu) under various controlled conditions

Anomalous Spawning of Smallmouth Bass in Nebish Lake, Wisconsin: Implications for Early Spawning and Over-Winter Survival

18S rRNA metabarcoding diet analysis of a predatory fish community across seasonal changes in prey availability

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