Prey Selectivity and Diet of Striped Bass in Western Albemarle Sound, North Carolina

Rudershausen, Paul J.; Tuomikoski, Jack; Buckel, Jeffrey A.; Hightower, Joseph E.

doi:10.1577/t04-115.1

Cited by 25 publications

(38 citation statements)

References 35 publications

Supporting

Mentioning

Contrasting

Order By: Relevance

“…Plots in Walter and Austin (2003), Rudershausen et al (2005), and Overton et al (2009) indicated that 3-year-old Striped Bass were the first ageclass capable of consuming age-1 Atlantic Menhaden. We considered all size-groups of Bluefish capable of consuming age-1 Atlantic Menhaden after examining prey fish length and Bluefish length plots in Scharf et al (2000).…”

Section: Methodsmentioning

confidence: 99%

“…However, diet studies of large Striped Bass by Walter and Austin (2003) and Overton et al (2008) suggested a greater role of Atlantic Menhaden of all ages in Striped Bass diets. Atlantic Menhaden were often dominant prey in studies of Striped Bass diets in the Chesapeake Bay and the midAtlantic region and were important prey in New England waters (Walter and Austin 2003;Rudershausen et al 2005;Nelson et al 2006;Overton et al 2008Overton et al , 2009Overton et al , 2015. After recovery of Atlantic coast Striped Bass was declared in 1995 (Richards and Rago 1999), concern emerged about the impact of the large Striped Bass population size on its prey base, and multiple analyses suggested that the recovered Striped Bass population had the potential to deplete prey populations along the Atlantic coast (Hartman 2003;Hartman and Margraf 2003;Uphoff 2003;ASMFC 2004;Savoy and Crecco 2004;Heimbuch 2008;ASMFC Weakfish Technical Committee 2009;Davis et al 2012).…”

mentioning

confidence: 99%

See 1 more Smart Citation

Striped Bass and Atlantic Menhaden Predator–Prey Dynamics: Model Choice Makes the Difference

Uphoff

Sharov

2018

Mar Coast Fish

View full text Add to dashboard Cite

show abstract

Section: Methodsmentioning

confidence: 99%

mentioning

confidence: 99%

Striped Bass and Atlantic Menhaden Predator–Prey Dynamics: Model Choice Makes the Difference

Uphoff

Sharov

2018

Mar Coast Fish

View full text Add to dashboard Cite

show abstract

“…Similarly, Markle and Grant (1970) found that fish occurred in >20% of the stomachs containing food and represented >50% by volume of the diet of juvenile striped bass between 30 and 150 mm TL from three major tributaries in the southern region of Chesapeake Bay. Moreover, striped bass appear to make an even earlier shift to piscivory at more southern latitudes, as age-1 striped bass in the Albemarle Sound estuary, North Carolina, were found to be completely piscivorous (>95% FO and % weight) by June of their second summer during two independent studies separated by more than 30 years (Manooch 1973;Rudershausen et al 2005). Larger body sizes at age-1 for striped bass at southern latitudes (Rudershausen et al 2005) provide a greater size advantage over piscine prey and may be mostly responsible for an earlier shift to a piscivorous diet in these systems.…”

Section: Patterns Of Resource Utilizationmentioning

confidence: 99%

Contrasting patterns of resource utilization between juvenile estuarine predators: the influence of relative prey size and foraging ability on the ontogeny of piscivory

Scharf

Buckel

Juanes

2009

Can. J. Fish. Aquat. Sci.

Self Cite

View full text Add to dashboard Cite

In aquatic systems, ontogenetic patterns of resource utilization strongly influence growth and survival, particularly during early life stages. We compared prey resource use and evaluated potential factors affecting the timing of the shift to piscivorous feeding in two juvenile estuarine fish predators: striped bass (Morone saxatilis) and bluefish (Pomatomus saltatrix). In New York Bight estuaries, bluefish shift to piscivory earlier in ontogeny and consume larger relative prey fish sizes compared with striped bass. Predator gape allometries are similar and did not determine maximum prey sizes eaten. Experimental results revealed marked differences in foraging abilities between predators, with bluefish realizing much greater foraging efficiency compared with striped bass feeding on identical fish prey. Both predators demonstrated lower feeding efficiency and grew relatively poorly when feeding on invertebrates compared with fish prey. When held together under limited prey conditions, bluefish exploited a greater proportion of available prey at the expense of striped bass. Our findings highlight the importance of the availability of appropriately sized forage fishes to the ontogeny of piscivory and provide evidence that predator-prey size relationships and disparate foraging abilities can generate interand intra-specific variation in patterns of resource utilization and predator growth.Résumé : Dans les systèmes aquatiques, les patrons ontogéniques d'utilisation des ressources influencent fortement la croissance et la survie, particulièrement durant les premiers stades de la vie. Nous comparons l'utilisation des ressources en proies et évaluons les facteurs potentiels qui affectent le moment du changement vers un régime alimentaire piscivore chez deux jeunes poissons prédateurs estuariens, le bar rayé (Morone saxatilis) et le tassergal (Pomatomus saltatrix). Dans les estuaires du golfe de New York, les tassergals deviennent piscivores plus tôt dans leur ontogénie et consomment des proies de taille relativement plus grande que les bars rayés. Les allométries de l'ouverture de la bouche sont semblables et ne déterminent pas la taille maximale de proie consommée. Des données expérimentales indiquent des différences marquées dans l'habileté de recherche de nourriture entre ces prédateurs et les tassergals atteignent une efficacité de recherche de nourriture beaucoup plus grande que celle des bars rayés qui se nourrissent des mêmes poissons proies. Lorsqu'ils s'alimentent d'invertébrés plutôt que de poissons, les deux prédateurs montrent une efficacité alimentaire réduite et croissent relativement mal. Gardés ensemble en présence de proies limitées, les tassergals exploitent une proportion plus élevée des proies disponibles au détriment des bars rayés. Nos résultats soulignent l'importance de la disponibilité de poissons fourrage de taille adéquate dans l'ontogénie de l'ichtyophagie et démontrent que les relations de taille entre les prédateurs et les proies, ainsi que les différences d'habileté de recherche de nourrit...

show abstract

“…Adults spawn in the spring in inshore waters, and their offspring grow rapidly at mid and high latitudes until the young of the year migrate offshore in autumn (Conover and Murawski 1982;Conover and Present 1990). This species is an important prey item for many recreationally and commercially valuable fishes, such as Bluefish Pomatomus saltatrix, Striped Bass Morone saxatilis, and Summer Flounder Paralichthys dentatus (Buckel et al 1999;Manderson et al 2000;Rudershausen et al 2005), and it faces high mortality from both predation and overwinter starvation (Munch et al 2003). Silversides are easily cultured in the laboratory, making it possible to obtain precise estimates of their size distributions through time; daily increment formation has previously been validated (Barkman and Bengtson 1987).…”

Section: Methodsmentioning

confidence: 99%

Validating Back‐Calculation Models Using Population Data

Perez

Munch

2012

Trans Am Fish Soc

View full text Add to dashboard Cite

Otolith back‐calculation, an estimation of size and growth at some previous age, is a valuable and widely used method of tracking the traits of surviving individuals. Although numerous back‐calculation models have been developed, the accuracy of model prediction is rarely assessed before using a model on wild populations. Using the Atlantic Silverside Menidia menidia, we tested the precision of four commonly used back‐calculation models (body proportional hypothesis, modified Fry, biological intercept, and time‐varying growth). We calculated the moments of the observed length frequency distribution (mean, variance, skewness, and kurtosis) and compared them with the moments of the back‐calculated length frequency distribution predicted by each model. We also compared how the most accurate back‐calculation model changed under various scenarios of size‐selective mortality and found that bias in back‐calculation could not be explained by size‐selective mortality. The differences between functional forms over a wide range of fish sizes were slight for the biological intercept and modified Fry models, whereas the time‐varying growth and body proportional hypothesis models differed considerably. We found that all models performed well for at least one measure of accuracy. However, the modified Fry model was the most accurate overall when back‐calculating to the observed population moments.

show abstract

Prey Selectivity and Diet of Striped Bass in Western Albemarle Sound, North Carolina

Cited by 25 publications

References 35 publications

Striped Bass and Atlantic Menhaden Predator–Prey Dynamics: Model Choice Makes the Difference

Striped Bass and Atlantic Menhaden Predator–Prey Dynamics: Model Choice Makes the Difference

Contrasting patterns of resource utilization between juvenile estuarine predators: the influence of relative prey size and foraging ability on the ontogeny of piscivory

Validating Back‐Calculation Models Using Population Data

Contact Info

Product

Resources

About