Aridity and land use negatively influence a dominant species' upper critical thermal limits

Andrew, Nigel R; Miller, Cara; Hall, Graham; Hemmings, Zac; Oliver, Ian

doi:10.7717/peerj.6252

Author(s)

Andrew, Nigel R

Miller, Cara

Hall, Graham

Hemmings, Zac

Oliver, Ian

Publication Date

2019-01-10

Abstract

Understanding the physiological tolerances of ectotherms, such as thermal limits, is important in predicting biotic responses to climate change. However, it is even more important to examine these impacts alongside those from other landscape changes: such as the reduction of native vegetation cover, landscape fragmentation and changes in land use intensity (LUI). Here, we integrate the observed thermal limits of the dominant and ubiquitous meat ant Iridomyrmex purpureus across climate (aridity), land cover and land use gradients spanning 270 km in length and 840 m in altitude across northern New South Wales, Australia. Meat ants were chosen for study as they are ecosystem engineers and changes in their populations may result in a cascade of changes in the populations of other species. When we assessed critical thermal maximum temperatures (CTmax) of meat ants in relation to the environmental gradients we found little influence of climate (aridity) but that CTmax decreased as LUI increased. We found no overall correlation between CTmax and CTmin. We did however find that tolerance to warming was lower for ants sampled from more arid locations. Our findings suggest that as LUI and aridification increase, the physiological resilience of I. purpureus will decline. A reduction in physiological resilience may lead to a reduction in the ecosystem service provision that these populations provide throughout their distribution.

Citation

PeerJ, v.6, p. 1-20

ISSN

2167-8359

Pubmed ID

30656070

Link

https://hdl.handle.net/1959.11/29542

Language

en

Publisher

PeerJ, Ltd

Rights

Attribution 4.0 International

Title

Aridity and land use negatively influence a dominant species' upper critical thermal limits

Type of document

Journal Article

Entity Type

Publication

Author(s)	Andrew, Nigel R Miller, Cara Hall, Graham Hemmings, Zac Oliver, Ian
Publication Date	2019-01-10
Abstract	Understanding the physiological tolerances of ectotherms, such as thermal limits, is important in predicting biotic responses to climate change. However, it is even more important to examine these impacts alongside those from other landscape changes: such as the reduction of native vegetation cover, landscape fragmentation and changes in land use intensity (LUI). Here, we integrate the observed thermal limits of the dominant and ubiquitous meat ant <i>Iridomyrmex purpureus</i> across climate (aridity), land cover and land use gradients spanning 270 km in length and 840 m in altitude across northern New South Wales, Australia. Meat ants were chosen for study as they are ecosystem engineers and changes in their populations may result in a cascade of changes in the populations of other species. When we assessed critical thermal maximum temperatures (CT<sub>max</sub>) of meat ants in relation to the environmental gradients we found little influence of climate (aridity) but that CT<sub>max</sub> decreased as LUI increased. We found no overall correlation between CT<sub>max</sub> and CT<sub>min</sub>. We did however find that tolerance to warming was lower for ants sampled from more arid locations. Our findings suggest that as LUI and aridification increase, the physiological resilience of <i>I. purpureus</i> will decline. A reduction in physiological resilience may lead to a reduction in the ecosystem service provision that these populations provide throughout their distribution.
Citation	PeerJ, v.6, p. 1-20
ISSN	2167-8359
Pubmed ID	30656070
Link	https://hdl.handle.net/1959.11/29542
Language	en
Publisher	PeerJ, Ltd
Rights	Attribution 4.0 International
Title	Aridity and land use negatively influence a dominant species' upper critical thermal limits
Type of document	Journal Article
Entity Type	Publication

Aridity and land use negatively influence a dominant species' upper critical thermal limits

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