Excess Mortality of Infected Ectotherms Induced by Warming Depends on Pathogen Kingdom and Evolutionary History

Overview

Journal PLoS Biol

Specialty Biology

Date 2024 Nov 18

PMID 39556605

Authors

Jingdi Li

Nele Guttmann

Georgia C Drew

Tobias E Hector

Justyna Wolinska

Kayla C King

Affiliations

Soon will be listed here.

Abstract

Climate change is causing extreme heating events and can lead to more infectious disease outbreaks, putting species persistence at risk. The extent to which warming temperatures and infection may together impair host health is unclear. Using a meta-analysis of >190 effect sizes representing 101 ectothermic animal host-pathogen systems, we demonstrate that warming significantly increased the mortality of hosts infected by bacterial pathogens. Pathogens that have been evolutionarily established within the host species showed higher virulence under warmer temperatures. Conversely, the effect of warming on novel infections-from pathogens without a shared evolutionary history with the host species-were more pronounced with larger differences between compared temperatures. We found that compared to established infections, novel infections were more deadly at lower/baseline temperatures. Moreover, we revealed that the virulence of fungal pathogens increased only when temperatures were shifted upwards towards the pathogen thermal optimum. The magnitude of all these significant effects was not impacted by host life-stage, immune complexity, pathogen inoculation methods, or exposure time. Overall, our findings reveal distinct patterns in changes of pathogen virulence during warming. We highlight the importance of pathogen taxa, thermal optima, and evolutionary history in determining the impact of global change on infection outcomes.

Citing Articles

Warming During Different Life Stages has Distinct Impacts on Host Resistance Ecology and Evolution.

Li J, Smith C, Chen J, Bates K, King K Ecol Lett. 2025; 28(2):e70087.

PMID: 39981937 PMC: 11843851. DOI: 10.1111/ele.70087.

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