Designing optimized multi-species monitoring networks to detect range shifts driven by climate change: a case study with bats in the North of Portugal

Here we develop a framework to design multi-species monitoring networks using species distribution models and conservation planning tools to optimize the location of monitoring stations to detect potential range shifts driven by climate change. For this study, we focused on seven bat species in Nort...

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Bibliographic Details
Published inPloS one Vol. 9; no. 1; p. e87291
Main Authors Amorim, Francisco, Carvalho, Sílvia B, Honrado, João, Rebelo, Hugo
Format Journal Article
LanguageEnglish
Published United States Public Library of Science 27.01.2014
Public Library of Science (PLoS)
Subjects
Acoustics
Animal behavior
Animal Distribution - physiology
Animals
Bats
Biodiversity
Biological monitoring
Biology
Case reports
Case studies
Chiroptera
Chiroptera - physiology
Climate Change
Climate models
Climatic conditions
Computer Simulation
Conservation
Conservation of Natural Resources - methods
Conservation status
Decision Support Techniques
Design
Design optimization
Ecological Parameter Monitoring - methods
Ecosystems
Entropy
Global temperature changes
Human influences
Maximum entropy
Models, Biological
Monitoring
Networks
Population Dynamics
Portugal
Software
Species
Species Specificity
Stations
Trends
Wildlife conservation
Portugal
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Summary:Here we develop a framework to design multi-species monitoring networks using species distribution models and conservation planning tools to optimize the location of monitoring stations to detect potential range shifts driven by climate change. For this study, we focused on seven bat species in Northern Portugal (Western Europe). Maximum entropy modelling was used to predict the likely occurrence of those species under present and future climatic conditions. By comparing present and future predicted distributions, we identified areas where each species is likely to gain, lose or maintain suitable climatic space. We then used a decision support tool (the Marxan software) to design three optimized monitoring networks considering: a) changes in species likely occurrence, b) species conservation status, and c) level of volunteer commitment. For present climatic conditions, species distribution models revealed that areas suitable for most species occur in the north-eastern part of the region. However, areas predicted to become climatically suitable in the future shifted towards west. The three simulated monitoring networks, adaptable for an unpredictable volunteer commitment, included 28, 54 and 110 sampling locations respectively, distributed across the study area and covering the potential full range of conditions where species range shifts may occur. Our results show that our framework outperforms the traditional approach that only considers current species ranges, in allocating monitoring stations distributed across different categories of predicted shifts in species distributions. This study presents a straightforward framework to design monitoring schemes aimed specifically at testing hypotheses about where and when species ranges may shift with climatic changes, while also ensuring surveillance of general population trends.
Bibliography:Competing Interests: The authors have declared that no competing interests exist.
Conceived and designed the experiments: FA SBC JH HR. Performed the experiments: FA HR. Analyzed the data: FA SBC HR. Wrote the paper: FA SBC JH HR.
ISSN:1932-6203
1932-6203
DOI:10.1371/journal.pone.0087291