Metapopulation capacity determines food chain length in fragmented landscapes

Metapopulation capacity provides an analytic tool to quantify the impact of landscape configuration on metapopulation persistence, which has proven powerful in biological conservation. Yet surprisingly few efforts have been made to apply this approach to multispecies systems. Here, we extend metapopulation capacity theory to predict the persistence of trophically interacting species. Our results demonstrate that metapopulation capacity could be used to predict the persistence of trophic systems such as prey–predator pairs and food chains in fragmented landscapes. In particular, we derive explicit predictions for food chain length as a function of metapopulation capacity, top-down control, and population dynamical parameters. Under certain assumptions, we show that the fraction of empty patches for the basal species provides a useful indicator to predict the length of food chains that a fragmented landscape can support and confirm this prediction for a host–parasitoid interaction. We further show that the impact of habitat changes on biodiversity can be predicted from changes in metapopulation capacity or approximately by changes in the fraction of empty patches. Our study provides an important step toward a spatially explicit theory of trophic metacommunities and a useful tool for predicting their responses to habitat changes.

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Primary Consumer Body Size and Food-Chain Length in Terrestrial Communities

Israel Journal of Ecology and Evolution ◽

10.1560/ijee.55.4.329 ◽

2009 ◽

Vol 55 (4) ◽

pp. 329-343 ◽

Cited By ~ 3

Author(s):

Yoram Ayal ◽

Elli Groner

Keyword(s):

Body Size ◽

Chain Length ◽

Food Chain ◽

Energetic Efficiency ◽

Food Chains ◽

Food Chain Length ◽

Primary Consumer ◽

Size Limitation ◽

Energy Limitation ◽

Primary Consumers

Using 21 community food webs, we tested Elton's two hypotheses regarding the main factors limiting food-chain length in terrestrial communities, namely, energy (energy limitation hypothesis—ELH) and body size (size limitation hypothesis—SLH). As predators tend to be larger than their prey, food-chains are size-structured: animal size increases with trophic position. We found a negative correlation between the size of the primary consumer and the length of the chain. Food-chains based on small primary consumers are longer than those based on large primary consumers, and size rather than energetic efficiency is the main contributing factor. We found no correlation between habitat productivity and mean food-chain length. All these findings support the SLH over the ELH. Our results suggest that, as in aquatic communities, a single factor—a predator/prey size-ratio greater than 1—governs the structure of terrestrial communities.

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The impact of introduced Ponto-Caspian mysids (Paramysis lacustris) on the trophic position of perch (Perca fluviatilis) in European mesotrophic lakes

Knowledge and Management of Aquatic Ecosystems ◽

10.1051/kmae/2019030 ◽

2019 ◽

pp. 38

Author(s):

Vytautas Rakauskas

Keyword(s):

Primary Production ◽

Chain Length ◽

Food Chain ◽

Trophic Position ◽

Perca Fluviatilis ◽

Trophic Levels ◽

Gut Contents ◽

Potential Predator ◽

Food Chain Length ◽

The Impact

Paramysis lacustris was introduced into Lithuanian lakes in the middle of the 20th century. It was assumed that P. lacustris will enhance efficiency of primary production utilization and channelling of primary production towards higher trophic levels, i.e. commercially important fish species. However, at the time of P. lacustris introduction, there were no reliable data about its trophic position in lakes. Thus, P. lacustris was considered to have no or little impact on native ecosystems. Until now, there is a gap in the knowledge of the trophic role and potential impacts of P. lacustris on local food webs in lakes. Here we investigated the impact of P. lacustris on the food chain length of its potential predator Perca fluviatilis in temperate lakes. In this study, gut contents and stable isotope analyses were performed to assess the diet and trophic position of P. lacustris and P. fluviatilis in lakes with and without invasive mysids. The results obtained revealed that P. lacustris consumes a significant amount of animal prey and occupies the third trophic level in lake littoral zones. Furthermore, our results showed that P. lacustris might enhance the food chain length for at least some zooplanktivorous fishes. Overall, the assumption that P. lacustris invasion has no whole-ecosystem consequences, as it was thought before its introduction, is not correct.

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