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Broad-scale patterns of geographic avoidance between species emerge in the absence of fine-scale mechanisms of coexistence

Broad-scale patterns of geographic avoidance between species emerge in the absence of fine-scale mechanisms of coexistence
Broad-scale patterns of geographic avoidance between species emerge in the absence of fine-scale mechanisms of coexistence
Aim: The need to forecast range shifts under future climate change has motivated an increasing interest in better understanding the role of biotic interactions in driving diversity patterns. The contribution of biotic interactions to shaping broad-scale species distributions is however, still debated, partly due to the difficulty of detecting their effects. We aim to test whether spatial exclusion between potentially competing species can be detected at the species range scale, and whether this pattern relates to fine-scale mechanisms of coexistence. Location: Western Palearctic Time period: Anthropocene Taxa: bats (Chiroptera) Methods: We develop and evaluate a measure of geographic avoidance that uses outputs of species distribution models to quantify geographic exclusion patterns expected if interspecific competition affects broad-scale distributions. We apply the measure to 10 Palearctic bat species belonging to four morphologically similar cryptic groups in which competition is likely to occur. We compare outputs to null models based on pairs of virtual species and to expectations based on ecological similarity and fine-scale coexistence mechanisms. We project changes in range suitability under climate change taking into account effects of geographic avoidance. Results: Values of geographic avoidance were above null expectations for two cryptic species pairs, suggesting that interspecific competition could have contributed to shaping their broad-scale distributions. These two pairs showed highest levels of ecological similarity and no trophic or habitat partitioning. Considering the role of competition modified predictions of future range suitability. Conclusions: Our results support the role of interspecific competition in limiting the geographic ranges of morphologically similar species in the absence of fine-scale mechanisms of coexistence. This study highlights the importance of incorporating biotic interactions into predictive models of range shifts under climate change, and the need for further integration of community ecology with species distribution models to understand the role of competition in ecology and biogeography.
Dryad
Novella-Fernandez, Roberto
25b2cef1-c3a7-4fae-99f5-8c26b584445b
Juste, Javier
d44bbd1c-ec75-43f4-87e6-214729740e0e
Ibanez, Carlos
720fc66b-56ca-469e-90cb-dacef91483e3
Rebelo, Hugo
81a4b2cf-7d26-4a69-974f-ea0854c33b0d
Russo, Danilo
da0cb292-a6c8-4d7d-ac52-702153623fe2
Alberdi, Antton
9811e238-964e-48e6-8bfb-b0a9d08a3f4a
Kiefer, Andreas
0eff2f42-fa0a-4e35-b6ac-475ad3482047
Graham, Laura
0eff2f42-fa0a-4e35-b6ac-475ad3482047
Kiefer, Andreas
0eff2f42-fa0a-4e35-b6ac-475ad3482047
Paul, Hynek
4f7ce88c-6890-4341-a126-f5a53329be63
Razgour, Orly
107f4912-304a-44d5-99f8-cdf2a9ce6f14
Novella-Fernandez, Roberto
25b2cef1-c3a7-4fae-99f5-8c26b584445b
Juste, Javier
d44bbd1c-ec75-43f4-87e6-214729740e0e
Ibanez, Carlos
720fc66b-56ca-469e-90cb-dacef91483e3
Rebelo, Hugo
81a4b2cf-7d26-4a69-974f-ea0854c33b0d
Russo, Danilo
da0cb292-a6c8-4d7d-ac52-702153623fe2
Alberdi, Antton
9811e238-964e-48e6-8bfb-b0a9d08a3f4a
Kiefer, Andreas
0eff2f42-fa0a-4e35-b6ac-475ad3482047
Graham, Laura
0eff2f42-fa0a-4e35-b6ac-475ad3482047
Kiefer, Andreas
0eff2f42-fa0a-4e35-b6ac-475ad3482047
Paul, Hynek
4f7ce88c-6890-4341-a126-f5a53329be63
Razgour, Orly
107f4912-304a-44d5-99f8-cdf2a9ce6f14

Novella-Fernandez, Roberto, Juste, Javier, Ibanez, Carlos, Rebelo, Hugo, Russo, Danilo, Alberdi, Antton, Kiefer, Andreas, Graham, Laura, Kiefer, Andreas, Paul, Hynek and Razgour, Orly (2022) Broad-scale patterns of geographic avoidance between species emerge in the absence of fine-scale mechanisms of coexistence. Dryad doi:10.5061/dryad.rbnzs7hbq [Dataset]

Record type: Dataset

Abstract

Aim: The need to forecast range shifts under future climate change has motivated an increasing interest in better understanding the role of biotic interactions in driving diversity patterns. The contribution of biotic interactions to shaping broad-scale species distributions is however, still debated, partly due to the difficulty of detecting their effects. We aim to test whether spatial exclusion between potentially competing species can be detected at the species range scale, and whether this pattern relates to fine-scale mechanisms of coexistence. Location: Western Palearctic Time period: Anthropocene Taxa: bats (Chiroptera) Methods: We develop and evaluate a measure of geographic avoidance that uses outputs of species distribution models to quantify geographic exclusion patterns expected if interspecific competition affects broad-scale distributions. We apply the measure to 10 Palearctic bat species belonging to four morphologically similar cryptic groups in which competition is likely to occur. We compare outputs to null models based on pairs of virtual species and to expectations based on ecological similarity and fine-scale coexistence mechanisms. We project changes in range suitability under climate change taking into account effects of geographic avoidance. Results: Values of geographic avoidance were above null expectations for two cryptic species pairs, suggesting that interspecific competition could have contributed to shaping their broad-scale distributions. These two pairs showed highest levels of ecological similarity and no trophic or habitat partitioning. Considering the role of competition modified predictions of future range suitability. Conclusions: Our results support the role of interspecific competition in limiting the geographic ranges of morphologically similar species in the absence of fine-scale mechanisms of coexistence. This study highlights the importance of incorporating biotic interactions into predictive models of range shifts under climate change, and the need for further integration of community ecology with species distribution models to understand the role of competition in ecology and biogeography.

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More information

Published date: 7 July 2022

Identifiers

Local EPrints ID: 471514
URI: http://eprints.soton.ac.uk/id/eprint/471514
PURE UUID: c824efc6-33a8-4f42-8a61-d7435f46dd25
ORCID for Andreas Kiefer: ORCID iD orcid.org/0000-0001-9406-0693
ORCID for Laura Graham: ORCID iD orcid.org/0000-0001-9406-0693
ORCID for Andreas Kiefer: ORCID iD orcid.org/0000-0001-9406-0693
ORCID for Hynek Paul: ORCID iD orcid.org/0000-0002-2202-7971
ORCID for Orly Razgour: ORCID iD orcid.org/0000-0003-3186-0313

Catalogue record

Date deposited: 09 Nov 2022 18:39
Last modified: 27 Feb 2024 02:35

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Contributors

Creator: Roberto Novella-Fernandez
Creator: Javier Juste
Creator: Carlos Ibanez
Creator: Hugo Rebelo
Creator: Danilo Russo
Creator: Antton Alberdi
Creator: Andreas Kiefer ORCID iD
Creator: Laura Graham ORCID iD
Creator: Andreas Kiefer ORCID iD
Creator: Hynek Paul ORCID iD
Creator: Orly Razgour ORCID iD

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