Individuals in Food Webs: the Relationships Between Trophic Position, Omnivory and Among-individual Diet Variation

Overview

Journal Oecologia

Specialty Environmental Health

Date 2015 Feb 6

PMID 25651804

Citations 16

Authors

Richard Svanback

Mario Quevedo

Jens Olsson

Peter Eklov

Affiliations

Soon will be listed here.

Abstract

Among-individual diet variation is common in natural populations and may occur at any trophic level within a food web. Yet, little is known about its variation among trophic levels and how such variation could affect phenotypic divergence within populations. In this study we investigate the relationships between trophic position (the population's range and average) and among-individual diet variation. We test for diet variation among individuals and across size classes of Eurasian perch (Perca fluviatilis), a widespread predatory freshwater fish that undergoes ontogenetic niche shifts. Second, we investigate among-individual diet variation within fish and invertebrate populations in two different lake communities using stable isotopes. Third, we test potential evolutionary implications of population trophic position by assessing the relationship between the proportion of piscivorous perch (populations of higher trophic position) and the degree of phenotypic divergence between littoral and pelagic perch sub-populations. We show that among-individual diet variation is highest at intermediate trophic positions, and that this high degree of among-individual variation likely causes an increase in the range of trophic positions among individuals. We also found that phenotypic divergence was negatively related to trophic position in a population. This study thus shows that trophic position is related to and may be important for among-individual diet variation as well as to phenotypic divergence within populations.

Citing Articles

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Seasonal Diet Changes and Trophic Links of Cold-Water Fish () within a Northern Lake Ecosystem.

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Preparing for the future offspring: European perch (Perca fluviatilis) biosynthesis of physiologically required fatty acids for the gonads happens already in the autumn.

Rigaud C, Kahilainen K, Calderini M, Pilecky M, Kainz M, Tiirola M Oecologia. 2023; 203(3-4):477-489.

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Integrating isotopic and nutritional niches reveals multiple dimensions of individual diet specialisation in a marine apex predator.

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