Selection between Densities of Artificial Vegetation by Young Bluegills Avoiding Predation

Gotceitas, Vytenis; Colgan, Patrick W.

doi:10.1577/1548-8659(1987)116<40:sbdoav>2.0.co;2

Cited by 80 publications

(61 citation statements)

References 32 publications

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“…Bluegill and green sunfish (L. cyanellus), two species present in many reservoirs in this region, are phytophyllic at multiple life stages (Crowder and Cooper 1982;Werner and Hall 1977), particularly early life stages (Gotceitas and Colgan 1987;Werner and Hall 1988). Thus, they may also be negatively affected by the loss of aquatic macrophytes as a consequence of extreme reservoir drawdown (Martin et al 1981;Bettoli et al 1993).…”

Section: Larval Fish Assemblagementioning

confidence: 99%

“…Low water levels can reduce the availability of adequate spawning (Ploskey 1986;Kallemeyn 1987) and nursery (Edwards and Twomey 1982;Werner et al 1983;Gotceitas and Colgan 1987;Werner and Hall 1988) habitat for fish. Seasonal changes in reservoir flushing rate can cause changes in zooplankton and phytoplankton abundance; a high flushing rate can lead to low zooplankton abundance (Watson et al 1996;Kalff 2003), which could reduce food availability for larval fish at a critical stage.…”

Section: Introductionmentioning

confidence: 99%

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The influence of a severe reservoir drawdown on springtime zooplankton and larval fish assemblages in Red Willow Reservoir, Nebraska

DeBoer

Webber

Dixon

et al. 2015

Journal of Freshwater Ecology

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Reservoirs can be dynamic systems, often prone to unpredictable and extreme waterlevel fluctuations, and can be environments where survival is difficult for zooplankton and larval fish. Although numerous studies have examined the effects of extreme reservoir drawdown on water quality, few have examined extreme drawdown on both abiotic and biotic characteristics. A fissure in the dam at Red Willow Reservoir in southwest Nebraska necessitated an extreme drawdown; the water level was lowered more than 6 m during a two-month period, reducing reservoir volume by 76%. During the subsequent low-water period (i.e., post-drawdown), spring sampling (AprilÀJune) showed dissolved oxygen concentration was lower, while turbidity and chlorophyll-a concentration were greater, relative to pre-drawdown conditions. Additionally, there was an overall increase in zooplankton density, although there were differences among taxa, and changes in mean size among taxa, relative to pre-drawdown conditions. Zooplankton assemblage composition had an average dissimilarity of 19.3% from pre-drawdown to post-drawdown. The ratio of zero to non-zero catches was greater post-drawdown for larval common carp and for all larval fishes combined, whereas we observed no difference for larval gizzard shad. Larval fish assemblage composition had an average dissimilarity of 39.7% from pre-drawdown to postdrawdown. Given the likelihood that other dams will need repair or replacement in the near future, it is imperative for effective reservoir management that we anticipate the likely abiotic and biotic responses of reservoir ecosystems as these management actions will continue to alter environmental conditions in reservoirs.

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Section: Larval Fish Assemblagementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

The influence of a severe reservoir drawdown on springtime zooplankton and larval fish assemblages in Red Willow Reservoir, Nebraska

DeBoer

Webber

Dixon

et al. 2015

Journal of Freshwater Ecology

View full text Add to dashboard Cite

show abstract

“…When predators are absent, prey habitat choice should maximize foraging (Werner et al 1983). Under perceived predator threat, prey should respond with behaviors that maximize immediate survival (Stein & Magnuson 1976), including retreat to refuge structure, reduced activity, reduced foraging, and direct defense (Stein & Magnuson 1976, Gilliam & Fraser 1987, Gotceitas & Colgan 1987, Laurel & Brown 2006. This trade-off results in reduced growth rates (Werner et al 1983, Werner 1991, 1992, Tupper & Boutilier 1995, with population-level consequences such as reduced reproductive potential.…”

Section: Introductionmentioning

confidence: 99%

Habitat structure influences the survival and predator–prey interactions of early juvenile red king crab Paralithodes camtschaticus

Pirtle

Eckert²,

Stoner³

2012

Mar. Ecol. Prog. Ser.

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Highly structured nursery habitats promote the survival of juvenile stages of many species by providing foraging opportunities and refuge from predators. Through integrated laboratory and field experiments, we demonstrate that nursery habitat structure affects survival and predator-prey interactions of red king crab Paralithodes camtschaticus. Crabs (< 1 yr old [Age 0]; 8 to 10 mm carapace length [CL]) preferred complex biogenic habitats formed by structural invertebrates and macroalgae over structural mimics and sand in the absence of predators in laboratory experiments, yet they associated with any available structural habitat when fish predators were present. Survival was higher in the presence of complex habitat for Age 0 crabs (5 to 7.5 mm CL) with Pacific cod Gadus macrocephalus predators in the laboratory and for Age 0 (4 to 8 mm CL) and Age 1 (16 to 28 mm CL) crabs with fish and invertebrate predators in the field. Crab activity and refuge response behavior varied with crab stage and habitat. Age 0 crabs were cryptic, avoiding predators by associating with habitat structure or remaining motionless in the absence of structure, and were less likely to respond to an attack. In contrast, Age 1 crabs were more likely to respond to an attacking predator and were less likely to remain motionless in the absence of structural refuge, suggesting an ontogenetic shift in behavior. Complex habitats, cryptic behavior, and direct defense improve juvenile red king crab survival against certain predators, including demersal fishes.

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“…Yet juveniles often forage suboptimally in structurally complex habitats, such as dense vegetation, to avoid pelagic predation risk (Mittelbach 1981), which can be a major factor determining recruitment to age-1 (Santucci and Wahl 2003). Studies of bluegill behavior in the laboratory (Gotceitas and Colgan 1987;Savino and Stein 1989;Shoup et al 2003) and in ponds (Werner et al 1983a) both show that bluegill spend more time in structurally complex habitats when predators are present. Furthermore, structurally complex habitats can negatively affect foraging returns of juvenile bluegill (Mittelbach 1981;Gotceitas 1990a;Pothoven et al 1999), and vegetation density negatively correlates with bluegill growth (Shoup et al 2007).…”

Section: Introductionmentioning

confidence: 99%

“…Foraging by fishes can be affected in many ways by habitat, which can influence prey abundance (Gerking 1957;Savino et al 1992;Barwick 2004), behavior patterns (Savino and Stein 1989), predator attack success (Savino and Stein 1982;Gotceitas and Colgan 1987), and ultimately prey selection (Schramm and Zale 1985;Dibble and Harrel 1997;Shoup and Wahl 2009) and competitive interactions (Abrahams 1994;Wellenreuther et al 2007;Robertson et al 2008). Therefore, changes in vegetation abundance could cause changes in diet and growth rate of juvenile bluegill that are independent of the effects of predation risk.…”

Section: Introductionmentioning

confidence: 99%

The effect of vegetation density on juvenile bluegill diet and growth

Shoup

Nannini²,

Wahl³

2012

Journal of Freshwater Ecology

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Experimental ponds (0.4 ha) were used to evaluate the effects of vegetation density on bluegill (Lepomis macrochirus) diet and growth in the absence of pelagic predation risk. Fish (30-50 mm, total length) were stocked at a rate of 15 kg per pond. By the end of the 3-month experiment, bluegill in the low vegetation treatment (109 g m À2 AE 21.0 SE, n ¼ 4) had grown 20% longer than the fish in the high vegetation treatment (712 g m À2 AE 54.3 SE, n ¼ 4) despite having similar mean stomach fullness. Bluegill in the high vegetation treatment ingested more gastropods and odonates and less benthic prey (chironomids) than did the fish in the low vegetation treatment. Very little pelagic zooplankton were eaten by fish in either treatment despite the lack of predation risk in the open water habitat. These results suggest that bluegill chose to forage in a vegetated habitat even in the absence of predation risk, resulting in reduced growth.

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Selection between Densities of Artificial Vegetation by Young Bluegills Avoiding Predation

Cited by 80 publications

References 32 publications

The influence of a severe reservoir drawdown on springtime zooplankton and larval fish assemblages in Red Willow Reservoir, Nebraska

The influence of a severe reservoir drawdown on springtime zooplankton and larval fish assemblages in Red Willow Reservoir, Nebraska

Habitat structure influences the survival and predator–prey interactions of early juvenile red king crab Paralithodes camtschaticus

The effect of vegetation density on juvenile bluegill diet and growth

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