The Impact of Individual Variation on Abrupt Collapses in Mutualistic Networks

Overview

Journal Ecol Lett

Specialty Environmental Health

Date 2021 Oct 21

PMID 34672068

Citations 4

Authors

Gaurav Baruah

Affiliations

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Abstract

Individual variation is central to species involved in complex interactions with others in an ecological system. Such ecological systems could exhibit tipping points in response to changes in the environment, consequently leading to abrupt transitions to alternative, often less desirable states. However, little is known about how individual trait variation could influence the timing and occurrence of abrupt transitions. Using 101 empirical mutualistic networks, I model the eco-evolutionary dynamics of such networks in response to gradual changes in strength of co-evolutionary interactions. Results indicated that individual variation facilitates the timing of transition in such networks, albeit slightly. In addition, individual variation significantly increases the occurrence of large abrupt transitions. Furthermore, topological network features also positively influence the occurrence of such abrupt transitions. These findings argue for understanding tipping points using an eco-evolutionary perspective to better forecast abrupt transitions in ecological systems.

Citing Articles

Reviving collapsed plant-pollinator networks from a single species.

Baruah G, Wittmann M PLoS Biol. 2024; 22(10):e3002826.

PMID: 39365839 PMC: 11482677. DOI: 10.1371/journal.pbio.3002826.

Rising temperature drives tipping points in mutualistic networks.

Bhandary S, Deb S, Dutta P R Soc Open Sci. 2023; 10(2):221363.

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The impact of individual variation on abrupt collapses in mutualistic networks.

Baruah G Ecol Lett. 2021; 25(1):26-37.

PMID: 34672068 PMC: 9297894. DOI: 10.1111/ele.13895.

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