Thermal limits in the face of infectious disease: How important are pathogens?

Hector, Tobias E.; Sgrò, Carla M.; Hall, Matthew D.

doi:10.1111/gcb.15761

Cited by 22 publications

(21 citation statements)

References 131 publications

(261 reference statements)

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“…Only 10 studies were found highlighting the general lack of data available. amplifies the risk that many populations face (reviewed in [14,26]). Indeed, infection can alter a host's entire thermal performance curve, shifting lower and upper thermal limits, alongside thermal optima (e.g.…”

Section: Introductionmentioning

confidence: 99%

Infection burdens and virulence under heat stress: ecological and evolutionary considerations

Hector

Gehman

King

2023

Phil. Trans. R. Soc. B

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As a result of global change, hosts and parasites (including pathogens) are experiencing shifts in their thermal environment. Despite the importance of heat stress tolerance for host population persistence, infection by parasites can impair a host's ability to cope with heat. Host–parasite eco-evolutionary dynamics will be affected if infection reduces host performance during heating. Theory predicts that within-host parasite burden (replication rate or number of infecting parasites per host), a key component of parasite fitness, should correlate positively with virulence—the harm caused to hosts during infection. Surprisingly, however, the relationship between within-host parasite burden and virulence during heating is often weak. Here, we describe the current evidence for the link between within-host parasite burden and host heat stress tolerance. We consider the biology of host–parasite systems that may explain the weak or absent link between these two important host and parasite traits during hot conditions. The processes that mediate the relationship between parasite burden and host fitness will be fundamental in ecological and evolutionary responses of host and parasites in a warming world. This article is part of the theme issue ‘Infectious disease ecology and evolution in a changing world’.

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Section: Introductionmentioning

confidence: 99%

Infection burdens and virulence under heat stress: ecological and evolutionary considerations

Hector

Gehman

King

2023

Phil. Trans. R. Soc. B

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“…2B ) than fundamental TPCs. Even though antagonists (pathogens and competitors) can reduce the thermal performance breadths of animals in the absence of facilitative interactions ( Tsai et al 2020 ; Hector et al 2021 ), the stress-gradient hypothesis suggests that facilitative interactions would overpower these negative effects of antagonists at thermal extremes. Further, because warming often increases drought intensity, facilitative microbes that increase drought tolerance ( Kivlin et al 2013 ) may be more beneficial to plants under future climate change, potentially elevating performance under increasing temperatures relative to a no-microbe control.…”

Section: Future Avenues For Tpcs In Plant Ecology and Evolutionmentioning

confidence: 99%

A viewpoint on ecological and evolutionary study of plant thermal performance curves in a warming world

et al. 2022

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We can understand the ecology and evolution of plant thermal niches through thermal performance curves (TPCs), which are unimodal, continuous reaction norms of performance across a temperature gradient. Though there are numerous plant TPC studies, plants remain underrepresented in syntheses of TPCs. Further, few studies quantify plant TPCs from fitness-based measurements (i.e., growth, survival, and reproduction at the individual level and above), limiting our ability to draw conclusions from the existing literature about plant thermal adaptation. We describe recent plant studies that use a fitness-based TPC approach to test fundamental ecological and evolutionary hypotheses, some of which have uncovered key drivers of climate change responses. Then, we outline three conceptual questions in ecology and evolutionary biology for future plant TPC studies: 1) Do populations and species harbor genetic variation for TPCs? 2) Do plant TPCs exhibit plastic responses to abiotic and biotic factors? 3) Do fitness-based TPCs scale up to population-level thermal niches? Moving forward, plant ecologists and evolutionary biologists can capitalize on TPCs to understand how plasticity and adaptation will influence plant responses to climate change.

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“…Temperature interacts with a number of other environmental factors to determine performance; or stated differently, the TPC is itself a function of other factors. Food/nutrient availability, pH, light (for photosynthetic organisms), salinity, water availability, oxygen concentration, as well as biotic interactions such as parasitism or mutualism, all can alter the shape of the TPC (Ern et al 2016, Thomas et al 2017, Aldea-Sánchez et al 2021, Hector et al 2021.…”

Section: The Dependence Of Tpcs On Environmental Factorsmentioning

confidence: 99%

Are we underestimating the ecological and evolutionary effects of warming? Interactions with other environmental drivers may increase species vulnerability to high temperatures

Litchman¹,

Thomas²

2022

Preprint

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Warming, the most prominent aspect of global environmental change, already affects most ecosystems on Earth. In recent years, biologists have increasingly integrated the effects of warming into their models by capturing how temperature shapes their physiology, ecology, behavior, evolutionary adaptation, and probability of extirpation/extinction. The more physiologically-grounded approaches to predicting ectotherms’ responses use thermal performance curves (TPCs) obtained by measuring species performance (e.g., growth rate) under different temperatures while other factors are held constant. These other factors are usually held at benign levels to ‘isolate’ the effects of temperature. Here we highlight that this practice may paint a misleading picture because TPCs are functions of other factors, including global change stressors. We review evidence that resource limitation, pH, oxygen and CO2 concentration, water availability, as well as parasites, all influence TPC shape and thermal traits such as optimum temperature for growth. Evidence from a wide variety of organisms – phytoplankton, protists, plants, insects, and fish – points towards such interactions increasing organisms’ susceptibility to high temperatures. Failing to account for these interactions is likely to lead to erroneous predictions of performance in nature and possibly an underestimation of the risks of warming. We discuss the general patterns and possible consequences of such interactions for ecological communities. But importantly, interactions with TPCs share common features that we can learn from. Incorporating these interactions into population and community models should lead to deeper insights and more accurate predictions of species’ performance in nature, now and in the future.

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Thermal limits in the face of infectious disease: How important are pathogens?

Cited by 22 publications

References 131 publications

Infection burdens and virulence under heat stress: ecological and evolutionary considerations

Infection burdens and virulence under heat stress: ecological and evolutionary considerations

A viewpoint on ecological and evolutionary study of plant thermal performance curves in a warming world

Are we underestimating the ecological and evolutionary effects of warming? Interactions with other environmental drivers may increase species vulnerability to high temperatures

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