Recently established predators rewire food webs simplified by extinction

Eamonn I.F. Wooster; Owen S. Middleton; Arian D. Wallach; Daniel Ramp; Oscar Sanisidro; Valerie K. Harris; John Rowan; Simon D. Schowanek; Chris E. Gordon; Jens Christian Svenning; Matt Davis; Jörn P.W. Scharlemann; Dale G. Nimmo; Erick J. Lundgren; Christopher J. Sandom

doi:10.1016/j.cub.2024.09.049

Recently established predators rewire food webs simplified by extinction

Eamonn I.F. Wooster, Owen S. Middleton, Arian D. Wallach, Daniel Ramp, Oscar Sanisidro, Valerie K. Harris, John Rowan, Simon D. Schowanek, Chris E. Gordon, Jens Christian Svenning, Matt Davis, Jörn P.W. Scharlemann, Dale G. Nimmo, Erick J. Lundgren, Christopher J. Sandom

Hawkesbury Institute for the Environment

Research output: Contribution to journal › Article › peer-review

1 Citation (Scopus)

Abstract

Since prehistory, humans have altered the composition of ecosystems by causing extinctions and introducing species. However, our understanding of how waves of species extinctions and introductions influence the structure and function of ecological networks through time remains piecemeal. Here, focusing on Australia, which has experienced many extinctions and introductions since the Late Pleistocene, we compared the functional trait composition of Late Pleistocene (130,00–115,000 years before present [ybp]), Holocene (11,700–3,000 ybp), and current Australian mammalian predator assemblages (≥70% vertebrate meat consumption; ≥1 kg adult body mass). We then constructed food webs for each period based on estimated prey body mass preferences. We found that introduced predators are functionally distinct from extinct Australian predators, but they rewire food webs toward a state that closely resembles the Late Pleistocene, prior to the megafauna extinctions. Both Late Pleistocene and current-day food webs consist of an apex predator and three smaller predators. This leads to food web networks with a similar total number of links, link densities, and compartmentalizations. However, this similarity depends on the presence of dingoes: in their absence, food webs become simplified and reminiscent of those following the Late Pleistocene extinctions. Our results suggest that recently established predators, even those implicated in species extinctions and declines, can rewire food webs simplified by extinction.

Original language	English
Pages (from-to)	5164-5172
Number of pages	9
Journal	Current Biology
Volume	34
Issue number	22
DOIs	https://doi.org/10.1016/j.cub.2024.09.049
Publication status	Published - 18 Nov 2024

Bibliographical note

Publisher Copyright:
© 2024 Elsevier Inc.

Keywords

functional ecology
metaweb
network ecology
novel ecosystems
predator-prey interactions
trophic cascades

UN SDGs

This output contributes to the following UN Sustainable Development Goals (SDGs)

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Wooster, E. I. F., Middleton, O. S., Wallach, A. D., Ramp, D., Sanisidro, O., Harris, V. K., Rowan, J., Schowanek, S. D., Gordon, C. E., Svenning, J. C., Davis, M., Scharlemann, J. P. W., Nimmo, D. G., Lundgren, E. J., & Sandom, C. J. (2024). Recently established predators rewire food webs simplified by extinction. Current Biology, 34(22), 5164-5172. https://doi.org/10.1016/j.cub.2024.09.049

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abstract = "Since prehistory, humans have altered the composition of ecosystems by causing extinctions and introducing species. However, our understanding of how waves of species extinctions and introductions influence the structure and function of ecological networks through time remains piecemeal. Here, focusing on Australia, which has experienced many extinctions and introductions since the Late Pleistocene, we compared the functional trait composition of Late Pleistocene (130,00–115,000 years before present [ybp]), Holocene (11,700–3,000 ybp), and current Australian mammalian predator assemblages (≥70% vertebrate meat consumption; ≥1 kg adult body mass). We then constructed food webs for each period based on estimated prey body mass preferences. We found that introduced predators are functionally distinct from extinct Australian predators, but they rewire food webs toward a state that closely resembles the Late Pleistocene, prior to the megafauna extinctions. Both Late Pleistocene and current-day food webs consist of an apex predator and three smaller predators. This leads to food web networks with a similar total number of links, link densities, and compartmentalizations. However, this similarity depends on the presence of dingoes: in their absence, food webs become simplified and reminiscent of those following the Late Pleistocene extinctions. Our results suggest that recently established predators, even those implicated in species extinctions and declines, can rewire food webs simplified by extinction.",

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AU - Middleton, Owen S.

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AU - Ramp, Daniel

AU - Sanisidro, Oscar

AU - Harris, Valerie K.

AU - Rowan, John

AU - Schowanek, Simon D.

AU - Gordon, Chris E.

AU - Svenning, Jens Christian

AU - Davis, Matt

AU - Scharlemann, Jörn P.W.

AU - Nimmo, Dale G.

AU - Lundgren, Erick J.

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KW - metaweb

KW - network ecology

KW - novel ecosystems

KW - predator-prey interactions

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JO - Current Biology

JF - Current Biology

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ER -

Recently established predators rewire food webs simplified by extinction

Abstract

Bibliographical note

Keywords

UN SDGs

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