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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. 

Predicting ecological responses to rapid environmental change has become one of the greatest challenges of modern biology. One of the major hurdles in forecasting these responses is accurately quantifying the thermal environments that organisms experience. The distribution of temperatures available within an organism's habitat is typically measured using data loggers called operative temperature models (OTMs) that are designed to mimic certain properties of heat exchange in the focal organism. The gold standard for OTM construction in studies of terrestrial ectotherms has been the use of copper electroforming which creates anatomically accurate models that equilibrate quickly to ambient thermal conditions. However, electroformed models require the use of caustic chemicals, are often brittle, and their production is expensive and time intensive. This has resulted in many researchers resorting to the use of simplified OTMs that can yield substantial measurement errors. 3D printing offers the prospect of robust, easily replicated, morphologically accurate, and cost-effective OTMs that capture the benefits but alleviate the problems associated with electroforming. Here, we validate the use of OTMs that were 3D printed using several materials across eight lizard species of different body sizes and living in habitats ranging from deserts to tropical forests. We show that 3D printed OTMs have low thermal inertia and predict the live animal's equilibration temperature with high accuracy across a wide range of body sizes and microhabitats. Finally, we developed a free online repository and database of 3D scans (https://www.3dotm.org/) to increase the accessibility of this tool to researchers around the world and facilitate ease of production of 3D printed models. 3D printing of OTMs is generalizable to taxa beyond lizards. If widely adopted, this approach promises greater accuracy and reproducibility in studies of terrestrial thermal ecology and should lead to improved forecasts of the biological impacts of climate change.