Environmental and ecological signals predict food shortages for subtropical populations of Australian flying foxes, reservoirs of Hendra virus

John H. Lagergren; Manuel Ruiz-Aravena; Daniel J. Becker; Wyatt G. Madden; Lib Ruytenberg; Andrew Hoegh; Barbara A. Han; Alison J. Peel; Peggy Eby; Daniel Jacobson; Raina K. Plowright

doi:10.1098/rsbl.2025.0371

Environmental and ecological signals predict food shortages for subtropical populations of Australian flying foxes, reservoirs of Hendra virus

John H. Lagergren
, Manuel Ruiz-Aravena
, Daniel J. Becker
, Wyatt G. Madden
, Lib Ruytenberg
, Andrew Hoegh
, Barbara A. Han
, Alison J. Peel
, Peggy Eby
, Daniel Jacobson
, Raina K. Plowright

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

Abstract

Food availability determines where and how animals use space across a landscape and, therefore, affects the risk of encounters leading to zoonotic spillover. This relationship is evident in Australian flying foxes (Pteropus spp.; fruit bats), where acute food shortages precede clusters of Hendra virus spillovers. Using machine learning, we predicted months of food shortages from climatological and ecological covariates (1996-2022) in subtropical Australia. Overall accuracy in predicting months of low food availability on a test set from 2018 up to 2022 reached 93.33 and 92.59% based on climatological and bat-level features, respectively. Seasonality and the Oceanic El Niño Index were the most important environmental features, while the number of bats in rescue centres and their body weights were the most important bat-level features. These models support predictive signals up to nine months in advance, facilitating action to mitigate spillover risk.

Original language	English
Journal	Biology letters
Volume	21
Issue number	12
DOIs	https://doi.org/10.1098/rsbl.2025.0371
State	Published - Dec 1 2025

Keywords

Pteropus
disease
resources
wildlife

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10.1098/rsbl.2025.0371

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Lagergren, J. H., Ruiz-Aravena, M., Becker, D. J., Madden, W. G., Ruytenberg, L., Hoegh, A., Han, B. A., Peel, A. J., Eby, P., Jacobson, D., & Plowright, R. K. (2025). Environmental and ecological signals predict food shortages for subtropical populations of Australian flying foxes, reservoirs of Hendra virus. Biology letters, 21(12). https://doi.org/10.1098/rsbl.2025.0371

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title = "Environmental and ecological signals predict food shortages for subtropical populations of Australian flying foxes, reservoirs of Hendra virus",

abstract = "Food availability determines where and how animals use space across a landscape and, therefore, affects the risk of encounters leading to zoonotic spillover. This relationship is evident in Australian flying foxes (Pteropus spp.; fruit bats), where acute food shortages precede clusters of Hendra virus spillovers. Using machine learning, we predicted months of food shortages from climatological and ecological covariates (1996-2022) in subtropical Australia. Overall accuracy in predicting months of low food availability on a test set from 2018 up to 2022 reached 93.33 and 92.59\% based on climatological and bat-level features, respectively. Seasonality and the Oceanic El Ni{\~n}o Index were the most important environmental features, while the number of bats in rescue centres and their body weights were the most important bat-level features. These models support predictive signals up to nine months in advance, facilitating action to mitigate spillover risk.",

keywords = "Pteropus, disease, resources, wildlife",

author = "Lagergren, \{John H.\} and Manuel Ruiz-Aravena and Becker, \{Daniel J.\} and Madden, \{Wyatt G.\} and Lib Ruytenberg and Andrew Hoegh and Han, \{Barbara A.\} and Peel, \{Alison J.\} and Peggy Eby and Daniel Jacobson and Plowright, \{Raina K.\}",

note = "Publisher Copyright: {\textcopyright} 2025 The Authors.",

year = "2025",

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doi = "10.1098/rsbl.2025.0371",

language = "English",

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TY - JOUR

T1 - Environmental and ecological signals predict food shortages for subtropical populations of Australian flying foxes, reservoirs of Hendra virus

AU - Lagergren, John H.

AU - Ruiz-Aravena, Manuel

AU - Becker, Daniel J.

AU - Madden, Wyatt G.

AU - Ruytenberg, Lib

AU - Hoegh, Andrew

AU - Han, Barbara A.

AU - Peel, Alison J.

AU - Eby, Peggy

AU - Jacobson, Daniel

AU - Plowright, Raina K.

PY - 2025/12/1

Y1 - 2025/12/1

N2 - Food availability determines where and how animals use space across a landscape and, therefore, affects the risk of encounters leading to zoonotic spillover. This relationship is evident in Australian flying foxes (Pteropus spp.; fruit bats), where acute food shortages precede clusters of Hendra virus spillovers. Using machine learning, we predicted months of food shortages from climatological and ecological covariates (1996-2022) in subtropical Australia. Overall accuracy in predicting months of low food availability on a test set from 2018 up to 2022 reached 93.33 and 92.59% based on climatological and bat-level features, respectively. Seasonality and the Oceanic El Niño Index were the most important environmental features, while the number of bats in rescue centres and their body weights were the most important bat-level features. These models support predictive signals up to nine months in advance, facilitating action to mitigate spillover risk.

AB - Food availability determines where and how animals use space across a landscape and, therefore, affects the risk of encounters leading to zoonotic spillover. This relationship is evident in Australian flying foxes (Pteropus spp.; fruit bats), where acute food shortages precede clusters of Hendra virus spillovers. Using machine learning, we predicted months of food shortages from climatological and ecological covariates (1996-2022) in subtropical Australia. Overall accuracy in predicting months of low food availability on a test set from 2018 up to 2022 reached 93.33 and 92.59% based on climatological and bat-level features, respectively. Seasonality and the Oceanic El Niño Index were the most important environmental features, while the number of bats in rescue centres and their body weights were the most important bat-level features. These models support predictive signals up to nine months in advance, facilitating action to mitigate spillover risk.

KW - Pteropus

KW - disease

KW - resources

KW - wildlife

UR - https://www.scopus.com/pages/publications/105027705808

U2 - 10.1098/rsbl.2025.0371

DO - 10.1098/rsbl.2025.0371

M3 - Article

C2 - 41537809

AN - SCOPUS:105027705808

SN - 1744-957X

VL - 21

JO - Biology letters

JF - Biology letters

IS - 12

ER -

Environmental and ecological signals predict food shortages for subtropical populations of Australian flying foxes, reservoirs of Hendra virus

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