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Environmental temperature fundamentally shapes insect physiology, fitness and interactions with parasites. Differential climate warming effects on host versus parasite biology could exacerbate or inhibit parasite transmission, with far-reaching implications for pollination services, biocontrol and human health. Here, we experimentally test how controlled temperatures influence multiple components of host and parasite fitness in monarch butterflies (Danaus plexippus) and their protozoan parasitesOphryocystis elektroscirrha. Using five constant-temperature treatments spanning 18–34°C, we measured monarch development, survival, size, immune function and parasite infection status and intensity. Monarch size and survival declined sharply at the hottest temperature (34°C), as did infection probability, suggesting that extreme heat decreases both host and parasite performance. The lack of infection at 34°C was not due to greater host immunity or faster host development but could instead reflect the thermal limits of parasite invasion and within-host replication. In the context of ongoing climate change, temperature increases above current thermal maxima could reduce the fitness of both monarchs and their parasites, with lower infection rates potentially balancing negative impacts of extreme heat on future monarch abundance and distribution.
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This content will become publicly available on September 15, 2026
Higher parasite load is associated with lower heat tolerance in a tropical lizard
ABSTRACT Climate change can influence host–parasite dynamics by altering the abundance and distribution of hosts and their parasites as well as the physiology of both parasite and host. While the physiological effects of hosting parasites have been extensively studied in aquatic and laboratory model systems, these dynamics have been much less studied in wild terrestrial vertebrates, such as ectotherms that live in tropical forests. These organisms are particularly vulnerable to climate change because they have limited scope for behavioral buffering of stressful temperatures while already living at body temperatures close to their heat tolerance limits. Thus, it is imperative to understand how parasitism and tolerance to stressful thermal conditions, both of which are changing under climate warming, might interact to shape survival of non-model organisms. We measured heat tolerance and assessed endoparasites and ectoparasites in slender anole lizards (Anolis apletophallus; a lowland tropical forest species from central Panama). We then treated lizards with the antiparasitic drugs ivermectin and praziquantel and measured changes in immune function and heat tolerance compared with an unmanipulated control group. Immune function was not altered by treatment; however, heat tolerance increased in treated lizards. Additionally, higher endoparasite and ectoparasite abundance was associated with lower heat tolerance in a separate set of wild-caught lizards. Our results suggest that increasing environmental temperatures may have especially severe effects on host survival when parasites are present and highlight the need to consider interactions between thermal physiology and host–parasite dynamics when forecasting the responses of tropical animals to climate change.
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- PAR ID:
- 10649285
- Publisher / Repository:
- The Company of Biologists
- Date Published:
- Journal Name:
- Journal of Experimental Biology
- Volume:
- 228
- Issue:
- 18
- ISSN:
- 0022-0949
- Format(s):
- Medium: X
- Sponsoring Org:
- National Science Foundation
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