Changes in trophic ecology of mobile predators in response to rainforest degradation

Lancaster Environment Centre

Text available via DOI:

https://doi.org/10.1111/1365-2664.14396
Final published version
Available under license: CC BY: Creative Commons Attribution 4.0 International License

Keywords

Community ecology, RESEARCH ARTICLE, RESEARCH ARTICLES, bats, diet breath, logging, predator–prey interactions, spatial scale, stable isotopes, trophic position, tropical rainforest

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Research output: Contribution to Journal/Magazine › Journal article › peer-review

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Standard

Changes in trophic ecology of mobile predators in response to rainforest degradation. / Kemp, Victoria A.; Grey, Jonathan; Hemprich‐Bennett, David et al.
In: Journal of Applied Ecology, Vol. 60, No. 6, 30.06.2023, p. 1139-1148.

Research output: Contribution to Journal/Magazine › Journal article › peer-review

Harvard

Kemp, VA, Grey, J, Hemprich‐Bennett, D, Rossiter, SJ, Lewis, OT, Wilkinson, CL, Clare, EL & Kratina, P 2023, 'Changes in trophic ecology of mobile predators in response to rainforest degradation', Journal of Applied Ecology, vol. 60, no. 6, pp. 1139-1148. https://doi.org/10.1111/1365-2664.14396

APA

Kemp, V. A., Grey, J., Hemprich‐Bennett, D., Rossiter, S. J., Lewis, O. T., Wilkinson, C. L., Clare, E. L., & Kratina, P. (2023). Changes in trophic ecology of mobile predators in response to rainforest degradation. Journal of Applied Ecology, 60(6), 1139-1148. https://doi.org/10.1111/1365-2664.14396

Vancouver

Kemp VA, Grey J, Hemprich‐Bennett D, Rossiter SJ, Lewis OT, Wilkinson CL et al. Changes in trophic ecology of mobile predators in response to rainforest degradation. Journal of Applied Ecology. 2023 Jun 30;60(6):1139-1148. Epub 2023 Mar 21. doi: 10.1111/1365-2664.14396

Author

Kemp, Victoria A. ; Grey, Jonathan ; Hemprich‐Bennett, David et al. / Changes in trophic ecology of mobile predators in response to rainforest degradation. In: Journal of Applied Ecology. 2023 ; Vol. 60, No. 6. pp. 1139-1148.

Bibtex

@article{c9e1f88e9bd64902a87a8e5c7f1c818e,

title = "Changes in trophic ecology of mobile predators in response to rainforest degradation",

abstract = "Accelerating loss and degradation of tropical forests has led to a pressing need to understand the conservation value of remaining forests. Whereas most studies focus on the responses in community composition and taxonomic richness, more sensitive responses to habitat degradation are likely to be apparent through changes in the trophic complexity of generalist predators. Food web theory predicts that both trophic position and niche breadth of predators decrease with habitat degradation, with consequences for biotic interactions and ecosystem functioning. Using a stable isotope approach, we analysed trophic positions and niche breaths of an important guild of top predators: insectivorous bats, in the tropical forests of Sabah, Borneo. We aimed to determine the responses in their trophic ecology across an experimental gradient of forest degradation at different spatial scales. At the landscape scale, trophic niche breadth contracted substantially (78%) in association with a narrow reduction (26%) in forest cover. However, food chains were longer in ecosystems with lower tree canopies, representative of localised habitat simplification. Marked differences in trophic niche breath of and trophic position between echolocation guilds provided further evidence for inter‐guild niche partitioning within bat assemblages. Overall, the functionally important shifts in trophic pathways discriminated among habitats of varying degrees of degradation more reliably than conventional community descriptors, such as diversity metrics. Synthesis and applications. This study reveals that habitat quality thresholds—below which we see substantial changes to trophic complexity—are higher than previously considered. Our analysis suggests that patches of forest with cover above 90% should be prioritised for conservation over more highly degraded ecosystems. As these effects were detected after approximately 30 years post‐logging, they likely reflect relatively long‐term responses to forest degradation.",

keywords = "Community ecology, RESEARCH ARTICLE, RESEARCH ARTICLES, bats, diet breath, logging, predator–prey interactions, spatial scale, stable isotopes, trophic position, tropical rainforest",

author = "Kemp, {Victoria A.} and Jonathan Grey and David Hemprich‐Bennett and Rossiter, {Stephen J.} and Lewis, {Owen T.} and Wilkinson, {Clare L.} and Clare, {Elizabeth L.} and Pavel Kratina",

year = "2023",

month = jun,

day = "30",

doi = "10.1111/1365-2664.14396",

language = "English",

volume = "60",

pages = "1139--1148",

journal = "Journal of Applied Ecology",

issn = "0021-8901",

publisher = "Blackwell Publishing Ltd",

number = "6",

}

RIS

TY - JOUR

T1 - Changes in trophic ecology of mobile predators in response to rainforest degradation

AU - Kemp, Victoria A.

AU - Grey, Jonathan

AU - Hemprich‐Bennett, David

AU - Rossiter, Stephen J.

AU - Lewis, Owen T.

AU - Wilkinson, Clare L.

AU - Clare, Elizabeth L.

AU - Kratina, Pavel

PY - 2023/6/30

Y1 - 2023/6/30

N2 - Accelerating loss and degradation of tropical forests has led to a pressing need to understand the conservation value of remaining forests. Whereas most studies focus on the responses in community composition and taxonomic richness, more sensitive responses to habitat degradation are likely to be apparent through changes in the trophic complexity of generalist predators. Food web theory predicts that both trophic position and niche breadth of predators decrease with habitat degradation, with consequences for biotic interactions and ecosystem functioning. Using a stable isotope approach, we analysed trophic positions and niche breaths of an important guild of top predators: insectivorous bats, in the tropical forests of Sabah, Borneo. We aimed to determine the responses in their trophic ecology across an experimental gradient of forest degradation at different spatial scales. At the landscape scale, trophic niche breadth contracted substantially (78%) in association with a narrow reduction (26%) in forest cover. However, food chains were longer in ecosystems with lower tree canopies, representative of localised habitat simplification. Marked differences in trophic niche breath of and trophic position between echolocation guilds provided further evidence for inter‐guild niche partitioning within bat assemblages. Overall, the functionally important shifts in trophic pathways discriminated among habitats of varying degrees of degradation more reliably than conventional community descriptors, such as diversity metrics. Synthesis and applications. This study reveals that habitat quality thresholds—below which we see substantial changes to trophic complexity—are higher than previously considered. Our analysis suggests that patches of forest with cover above 90% should be prioritised for conservation over more highly degraded ecosystems. As these effects were detected after approximately 30 years post‐logging, they likely reflect relatively long‐term responses to forest degradation.

AB - Accelerating loss and degradation of tropical forests has led to a pressing need to understand the conservation value of remaining forests. Whereas most studies focus on the responses in community composition and taxonomic richness, more sensitive responses to habitat degradation are likely to be apparent through changes in the trophic complexity of generalist predators. Food web theory predicts that both trophic position and niche breadth of predators decrease with habitat degradation, with consequences for biotic interactions and ecosystem functioning. Using a stable isotope approach, we analysed trophic positions and niche breaths of an important guild of top predators: insectivorous bats, in the tropical forests of Sabah, Borneo. We aimed to determine the responses in their trophic ecology across an experimental gradient of forest degradation at different spatial scales. At the landscape scale, trophic niche breadth contracted substantially (78%) in association with a narrow reduction (26%) in forest cover. However, food chains were longer in ecosystems with lower tree canopies, representative of localised habitat simplification. Marked differences in trophic niche breath of and trophic position between echolocation guilds provided further evidence for inter‐guild niche partitioning within bat assemblages. Overall, the functionally important shifts in trophic pathways discriminated among habitats of varying degrees of degradation more reliably than conventional community descriptors, such as diversity metrics. Synthesis and applications. This study reveals that habitat quality thresholds—below which we see substantial changes to trophic complexity—are higher than previously considered. Our analysis suggests that patches of forest with cover above 90% should be prioritised for conservation over more highly degraded ecosystems. As these effects were detected after approximately 30 years post‐logging, they likely reflect relatively long‐term responses to forest degradation.

KW - Community ecology

KW - RESEARCH ARTICLE

KW - RESEARCH ARTICLES

KW - bats

KW - diet breath

KW - logging

KW - predator–prey interactions

KW - spatial scale

KW - stable isotopes

KW - trophic position

KW - tropical rainforest

U2 - 10.1111/1365-2664.14396

DO - 10.1111/1365-2664.14396

M3 - Journal article

VL - 60

SP - 1139

EP - 1148

JO - Journal of Applied Ecology

JF - Journal of Applied Ecology

SN - 0021-8901

IS - 6

ER -

Research

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Text available via DOI:

Keywords