Greenspan, Sasha E; Bower, Deborah S; Roznik, Elizabeth A; Pike, David A; Marantelli, Gerry; Alford, Ross A; Schwarzkopf, Lin; Scheffers, Brett R

Author(s)

Greenspan, Sasha E

Bower, Deborah S

Roznik, Elizabeth A

Pike, David A

Marantelli, Gerry

Alford, Ross A

Schwarzkopf, Lin

Scheffers, Brett R

Publication Date

2017-08-24

Abstract

Unprecedented global climate change and increasing rates of infectious disease emergence are occurring simultaneously. Infection with emerging pathogens may alter the thermal thresholds of hosts. However, the effects of fungal infection on host thermal limits have not been examined. Moreover, the influence of infections on the heat tolerance of hosts has rarely been investigated within the context of realistic thermal acclimation regimes and potential anthropogenic climate change. We tested for effects of fungal infection on host thermal tolerance in a model system: frogs infected with the chytrid Batrachochytrium dendrobatidis. Infection reduced the critical thermal maxima (CTmax) of hosts by up to ~4 °C. Acclimation to realistic daily heat pulses enhanced thermal tolerance among infected individuals, but the magnitude of the parasitism effect usually exceeded the magnitude of the acclimation effect. In ectotherms, behaviors that elevate body temperature may decrease parasite performance or increase immune function, thereby reducing infection risk or the intensity of existing infections. However, increased heat sensitivity from infections may discourage these protective behaviors, even at temperatures below critical maxima, tipping the balance in favor of the parasite. We conclude that infectious disease could lead to increased uncertainty in estimates of species’ vulnerability to climate change.

Citation

Scientific Reports, v.7, p. 1-10

ISSN

2045-2322

Pubmed ID

28839273

Link

https://hdl.handle.net/1959.11/26889

Publisher

Nature Publishing Group

Rights

Attribution 4.0 International

Title

Infection increases vulnerability to climate change via effects on host thermal tolerance

Type of document

Journal Article

Entity Type

Publication

Author(s)	Greenspan, Sasha E Bower, Deborah S Roznik, Elizabeth A Pike, David A Marantelli, Gerry Alford, Ross A Schwarzkopf, Lin Scheffers, Brett R
Publication Date	2017-08-24
Abstract	Unprecedented global climate change and increasing rates of infectious disease emergence are occurring simultaneously. Infection with emerging pathogens may alter the thermal thresholds of hosts. However, the effects of fungal infection on host thermal limits have not been examined. Moreover, the influence of infections on the heat tolerance of hosts has rarely been investigated within the context of realistic thermal acclimation regimes and potential anthropogenic climate change. We tested for effects of fungal infection on host thermal tolerance in a model system: frogs infected with the chytrid Batrachochytrium dendrobatidis. Infection reduced the critical thermal maxima (CTmax) of hosts by up to ~4 °C. Acclimation to realistic daily heat pulses enhanced thermal tolerance among infected individuals, but the magnitude of the parasitism effect usually exceeded the magnitude of the acclimation effect. In ectotherms, behaviors that elevate body temperature may decrease parasite performance or increase immune function, thereby reducing infection risk or the intensity of existing infections. However, increased heat sensitivity from infections may discourage these protective behaviors, even at temperatures below critical maxima, tipping the balance in favor of the parasite. We conclude that infectious disease could lead to increased uncertainty in estimates of species’ vulnerability to climate change.
Citation	Scientific Reports, v.7, p. 1-10
ISSN	2045-2322
Pubmed ID	28839273
Link	https://hdl.handle.net/1959.11/26889
Publisher	Nature Publishing Group
Rights	Attribution 4.0 International
Title	Infection increases vulnerability to climate change via effects on host thermal tolerance
Type of document	Journal Article
Entity Type	Publication

Infection increases vulnerability to climate change via effects on host thermal tolerance

Files: