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1. Diet changes thermal acclimation capacity, but not acclimation rate, in a marine ectotherm ( Girella nigricans ) during warming

   https://doi.org/10.1098/rspb.2022.2505  

   Hardison, Emily A.; Schwieterman, Gail D.; Eliason, Erika J. (March 2023, Proceedings of the Royal Society B: Biological Sciences)

   Global climate change is increasing thermal variability in coastal marine environments and the frequency, intensity and duration of marine heatwaves. At the same time, food availability and quality are being altered by anthropogenic environmental changes. Marine ectotherms often cope with changes in temperature through physiological acclimation, which can take several weeks and is a nutritionally demanding process. Here, we tested the hypothesis that different ecologically relevant diets (omnivorous, herbivorous, carnivorous) impact thermal acclimation rate and capacity, using a temperate omnivorous fish as a model (opaleye,Girella nigricans).We measured acute thermal performance curves for maximum heart rate because cardiac function has been observed to set upper thermal limits in ectotherms. Opaleye acclimated rapidly after raising water temperatures, but their thermal limits and acclimation rate were not affected by their diet. However, the fish's acclimation capacity for maximum heart rate was sensitive to diet, with fish in the herbivorous treatment displaying the smallest change in heart rate throughout acclimation. Mechanistically, ventricle fatty acid composition differed with diet treatment and was related to cardiac performance in ways consistent with homoviscous adaptation. Our results suggest that diet is an important, but often overlooked, determinant of thermal performance in ectotherms on environmentally relevant time scales. 

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2. Trade-off between thermal preference and sperm maturation in a montane lizard

   https://doi.org/10.1016/j.jtherbio.2023.103526  

   Quintero-Pérez, Rosa Isela; Méndez-de_la_Cruz, Fausto Roberto; Miles, Donald B; Vera_Chávez, Mirna Crizel; López-Ramírez, Yolanda; Arenas-Moreno, Diego Miguel; Arenas-Ríos, Edith (April 2023, Journal of Thermal Biology)

   Temperature is a key abiotic factor that influences performance of several physiological traits in ectotherms. Organisms regulate their body temperature within a range of temperatures to enhance physiological function. The capacity of ectotherms, such as lizards, to maintain their body temperature within their preferred range influences physiological traits such as speed, various reproductive patterns, and critical fitness components, such as growth rates or survival. Here, we evaluate the influence of temperature on locomotor performance, sperm morphology and viability in a high elevation lizard species (Sceloporus aeneus). Whereas maximal values for sprint speed coincides with field active and preferred body temperature, short-term exposure at the same range of temperatures produces abnormalities in sperm morphology, lower sperm concentration and diminishes sperm motility and viability. In conclusion, we confirmed that although locomotor performance is maximized at preferred temperatures, there is a trade-off with male reproductive attributes, which may cause infertility. As a consequence, prolonged exposure to preferred temperatures could threaten the persistence of the species through reduced fertility. Persistence of the species is favored in environments with access to cooler, thermal microhabitats that enhance reproductive parameters. 

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3. Temperature determines physiological rates and predation in Galápagos rocky reefs

   https://doi.org/10.3354/meps14912  

   Agudo-Adriani, Esteban; Chico-Ortiz, Nicole; Silva, Isabel; Brandt, Margarita; Bruno, John F (August 2025, Marine Ecology Progress Series)

   Water temperature plays a critical role in determining physiological rates in marine ectotherms and influences the strength of ecological interactions. We investigated the effects of temperature on multiple traits of the whelkHexaplex princeps—a common predator in the rocky reefs of the Galápagos, a region characterized by significant temperature fluctuations. We measured metabolic rate, activity levels, prey handling time, and feeding rates across a temperature gradient. First, we conducted respirometry assays to measure the temperature dependence of metabolism. Next, we performed mesocosm experiments to assess how temperature affects predator activity, prey handling time, and feeding rates. Third, we conducted a field experiment to measure predation’s response to seasonal temperature changes. The results from our mesocosms experiment showed a large variation in thermal performance across traits. Nevertheless, all traits exhibit low performance at our coldest experimental temperature with a peak at intermediate temperature, suggesting a unimodal response. Similarly, we observed higher feeding rates in the field at medium temperatures. Our results highlight the importance of temperature in moderating physiological rates and interactions between species, and the challenges of predicting complex ecological processes from individual traits (e.g. metabolic rate, movement, prey handling time). As ocean temperatures continue to rise, understanding how temperature shapes physiological responses across organisms is essential for predicting the future dynamics of marine communities. 

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4. The impacts of diet on cardiac performance under changing environments

   https://doi.org/10.1242/jeb.247749  

   Eliason, Erika J; Hardison, Emily A (October 2024, Journal of Experimental Biology)

   ABSTRACT Natural and anthropogenic stressors are dramatically altering environments, impacting key animal physiological traits, including cardiac performance. Animals require energy and nutrients from their diet to support cardiac performance and plasticity; however, the nutritional landscape is changing in response to environmental perturbations. Diet quantity, quality and options vary in space and time across heterogeneous environments, over the lifetime of an organism and in response to environmental stressors. Variation in dietary energy and nutrients (e.g. lipids, amino acids, vitamins, minerals) impact the heart's structure and performance, and thus whole-animal resilience to environmental change. Notably, many animals can alter their diet in response to environmental cues, depending on the context. Yet, most studies feed animals ad libitum using a fixed diet, thus underestimating the role of food in impacting cardiac performance and resilience. By applying an ecological lens to the study of cardiac plasticity, this Commentary aims to further our understanding of cardiac function in the context of environmental change. 

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5. Interindividual plasticity in metabolic and thermal tolerance traits from populations subjected to recent anthropogenic heating

   https://doi.org/10.1098/rsos.210440  

   Drown, Melissa K.; DeLiberto, Amanda N.; Ehrlich, Moritz A.; Crawford, Douglas L.; Oleksiak, Marjorie F. (July 2021, Royal Society Open Science)

   To better understand temperature's role in the interaction between local evolutionary adaptation and physiological plasticity, we investigated acclimation effects on metabolic performance and thermal tolerance among natural Fundulus heteroclitus (small estuarine fish) populations from different thermal environments. Fundulus heteroclitus populations experience large daily and seasonal temperature variations, as well as local mean temperature differences across their large geographical cline. In this study, we use three populations: one locally heated (32°C) by thermal effluence (TE) from the Oyster Creek Nuclear Generating Station, NJ, and two nearby reference populations that do not experience local heating (28°C). After acclimation to 12 or 28°C, we quantified whole-animal metabolic (WAM) rate, critical thermal maximum (CT max ) and substrate-specific cardiac metabolic rate (CaM, substrates: glucose, fatty acids, lactate plus ketones plus ethanol, and endogenous (i.e. no added substrates)) in approximately 160 individuals from these three populations. Populations showed few significant differences due to large interindividual variation within populations. In general, for WAM and CT max , the interindividual variation in acclimation response (log 2 ratio 28/12°C) was a function of performance at 12°C and order of acclimation (12–28°C versus 28–12°C). CT max and WAM were greater at 28°C than 12°C, although WAM had a small change (2.32-fold) compared with the expectation for a 16°C increase in temperature (expect 3- to 4.4-fold). By contrast, for CaM, the rates when acclimatized and assayed at 12 or 28°C were nearly identical. The small differences in CaM between 12 and 28°C temperature were partially explained by cardiac remodeling where individuals acclimatized to 12°C had larger hearts than individuals acclimatized to 28°C. Correlation among physiological traits was dependent on acclimation temperature. For example, WAM was negatively correlated with CT max at 12°C but positively correlated at 28°C. Additionally, glucose substrate supported higher CaM than fatty acid, and fatty acid supported higher CaM than lactate, ketones and alcohol (LKA) or endogenous. However, these responses were highly variable with some individuals using much more FA than glucose. These findings suggest interindividual variation in physiological responses to temperature acclimation and indicate that additional research investigating interindividual may be relevant for global climate change responses in many species. 

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