Empirical evidence that metabolic theory describes the temperature dependency of within-host parasite dynamics

Kirk, Dudley; Jones, Natalie T.; Peacock, Stephanie J.; Phillips, Jessica Ann; Molnár, Péter K.; Krkošek, Martin; Luijckx, Pepijn

doi:10.1371/journal.pbio.2004608

Cited by 76 publications

(131 citation statements)

References 50 publications

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“…• How can trait-based model predictions best be combined with observed dynamics of human cases to infer and predict the role of temperature in disease dynamics? 2013; Moln ar et al 2013;Kirk et al 2018Kirk et al , 2019. Whether these canonical values from metabolic theory apply to the traits of mosquitoes and pathogens that drive vector-borne disease transmission is unknown (Moln ar et al 2013(Moln ar et al , 2017.…”

Section: Foundational Concepts In Thermal Biologymentioning

confidence: 99%

Thermal biology of mosquito‐borne disease

et al. 2019

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Mosquito‐borne diseases cause a major burden of disease worldwide. The vital rates of these ectothermic vectors and parasites respond strongly and nonlinearly to temperature and therefore to climate change. Here, we review how trait‐based approaches can synthesise and mechanistically predict the temperature dependence of transmission across vectors, pathogens, and environments. We present 11 pathogens transmitted by 15 different mosquito species – including globally important diseases like malaria, dengue, and Zika – synthesised from previously published studies. Transmission varied strongly and unimodally with temperature, peaking at 23–29ºC and declining to zero below 9–23ºC and above 32–38ºC. Different traits restricted transmission at low versus high temperatures, and temperature effects on transmission varied by both mosquito and parasite species. Temperate pathogens exhibit broader thermal ranges and cooler thermal minima and optima than tropical pathogens. Among tropical pathogens, malaria and Ross River virus had lower thermal optima (25–26ºC) while dengue and Zika viruses had the highest (29ºC) thermal optima. We expect warming to increase transmission below thermal optima but decrease transmission above optima. Key directions for future work include linking mechanistic models to field transmission, combining temperature effects with control measures, incorporating trait variation and temperature variation, and investigating climate adaptation and migration.

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Section: Foundational Concepts In Thermal Biologymentioning

confidence: 99%

Thermal biology of mosquito‐borne disease

et al. 2019

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“…By now, significant progress toward more realistic assessments has been achieved in multifactorial (several drivers) and multivariate (several responses) long‐term mesocosm studies (Sommer ; Jokiel et al ; Nagelkerken and Connell ; Riebesell and Gattuso ; Boyd et al ). Several studies show the capacity of biotic interactions—or the shift of such—to modulate or even mask the direct impact at the organism level of global‐change‐driven abiotic environmental pressures, for instance, for parasite‐host interactions (e.g., Kirk et al ), pathogen‐host interaction (e.g., Kiesecker and Blaustein ; Campbell et al ), epibiont‐host interaction (e.g., Werner et al ; Takolander et al ), competition, and predation (e.g., Alsterberg et al ; Falkenberg et al ; Goldenberg et al ; Provost et al ). The amplification or buffering of environmental impacts by biotic interactions should be particularly pronounced where foundational, that is, habitat‐forming, species are involved (Doney et al ).…”

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confidence: 99%

Season affects strength and direction of the interactive impacts of ocean warming and biotic stress in a coastal seaweed ecosystem

Wahl

Werner

Buchholz

et al. 2019

Limnology & Oceanography

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The plea for using more "realistic," community-level, investigations to assess the ecological impacts of global change has recently intensified. Such experiments are typically more complex, longer, more expensive, and harder to interpret than simple organism-level benchtop experiments. Are they worth the extra effort? Using outdoor mesocosms, we investigated the effects of ocean warming (OW) and acidification (OA), their combination (OAW), and their natural fluctuations on coastal communities of the western Baltic Sea during all four seasons. These communities are dominated by the perennial and canopy-forming macrophyte Fucus vesiculosus-an important ecosystem engineer Baltic-wide. We, additionally, assessed the direct response of organisms to temperature and pH in benchtop experiments, and examined how well organism-level responses can predict community-level responses to the dominant driver, OW. OW affected the mesocosm communities substantially stronger than acidification. OW provoked structural and functional shifts in the community that differed in strength and direction among seasons. The organism-level response to OW matched well the community-level response of a given species only under warm and cold thermal stress, that is, in summer and winter. In other seasons, shifts in biotic interactions masked the direct OW effects. The combination of direct OW effects and OW-driven shifts of biotic interactions is likely to jeopardize the future of the habitat-forming macroalga F. vesiculosus in the Baltic Sea. Furthermore, we conclude that seasonal mesocosm experiments are essential for our understanding of global change impact because they take into account the important fluctuations of abiotic and biotic pressures.This is an open access article under the terms of the Creative Commons Attribution-NonCommercial-NoDerivs License, which permits use and distribution in any medium, provided the original work is properly cited, the use is non-commercial and no modifications or adaptations are made.Additional Supporting Information may be found in the online version of this article.

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“…One context in which the effect of temperature on species interactions has been repeatedly demonstrated to reflect the predictions of metabolic theory is that of host-parasite interactions (Raffel et al, 2013;Kirk et al, 2018;Cohen et al, 2019). Metabolic theory predicts that the success of parasites at any given temperature reflects the relative performance of hosts and parasites at that temperature, rather than the absolute performance of either in isolation (Cohen et al, 2017).…”

Section: Introductionmentioning

confidence: 99%

“…Metabolic theory predicts that the success of parasites at any given temperature reflects the relative performance of hosts and parasites at that temperature, rather than the absolute performance of either in isolation (Cohen et al, 2017). As a result, the temperature dependence of parasite growth may differ for parasites grown in cell cultures versus in live hosts (James, 2005;Cohen et al, 2017;Kirk et al, 2018).…”

Section: Introductionmentioning

confidence: 99%

Temperature dependence of parasitic infection and gut bacterial communities in bumble bees

Palmer‐Young

Ngor

Nevarez

et al. 2019

Environmental Microbiology

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Summary High temperatures (e.g., fever) and gut microbiota can both influence host resistance to infection. However, effects of temperature‐driven changes in gut microbiota on resistance to parasites remain unexplored. We examined the temperature dependence of infection and gut bacterial communities in bumble bees infected with the trypanosomatid parasite Crithidia bombi. Infection intensity decreased by over 80% between 21 and 37°C. Temperatures of peak infection were lower than predicted based on parasite growth in vitro, consistent with mismatches in thermal performance curves of hosts, parasites and gut symbionts. Gut bacterial community size and composition exhibited slight but significant, non‐linear, and taxon‐specific responses to temperature. Abundance of total gut bacteria and of Orbaceae, both negatively correlated with infection in previous studies, were positively correlated with infection here. Prevalence of the bee pathogen‐containing family Enterobacteriaceae declined with temperature, suggesting that high temperature may confer protection against diverse gut pathogens. Our results indicate that resistance to infection reflects not only the temperature dependence of host and parasite performance, but also temperature‐dependent activity of gut bacteria. The thermal ecology of gut parasite‐symbiont interactions may be broadly relevant to infectious disease, both in ectothermic organisms that inhabit changing climates, and in endotherms that exhibit fever‐based immunity.

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Empirical evidence that metabolic theory describes the temperature dependency of within-host parasite dynamics

Cited by 76 publications

References 50 publications

Thermal biology of mosquito‐borne disease

Thermal biology of mosquito‐borne disease

Season affects strength and direction of the interactive impacts of ocean warming and biotic stress in a coastal seaweed ecosystem

Temperature dependence of parasitic infection and gut bacterial communities in bumble bees

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