Your search keyword '"Emily N. Taylor"' showing total 2 results

1. Body size impacts critical thermal maximum measurements in lizards

Author

Emmeleia Nix, Emily N. Taylor, Kathleen N Ivey, Kiley A. Rucker, Elina C. King, Megan Corn, P. Mason DuBois, Sunny Vansdadia, Averil E. Royal, Luis P. Burgos, Natalie M. Claunch, Tanner K. Shea, and John Stepanek

Subjects

Thermotolerance, 0106 biological sciences, 0301 basic medicine, Thermal inertia, Physiology, High body temperature, Zoology, Lizards, Body size, Biology, 010603 evolutionary biology, 01 natural sciences, Intraspecific competition, Body Temperature, 03 medical and health sciences, 030104 developmental biology, Ectotherm, Genetics, Animals, Body Size, Animal Science and Zoology, Critical thermal maximum, Molecular Biology, Ecology, Evolution, Behavior and Systematics, Monitoring, Physiologic

Abstract

Understanding the mechanisms behind critical thermal maxima (CTmax; the high body temperature at which neuromuscular coordination is lost) of organisms is central to understanding ectotherm thermal tolerance. Body size is an often overlooked variable that may affect interpretation of CTmax, and consequently, how CTmax is used to evaluate mechanistic hypotheses of thermal tolerance. We tested the hypothesis that body size affects CTmax and its interpretation in two experimental contexts. First, in four Sceloporus species, we examined how inter- and intraspecific variation in body size affected CTmax at normoxic and experimentally induced hypoxic conditions, and cloacal heating rate under normoxic conditions. Negative relationships between body size and CTmax were exaggerated in larger species, and hypoxia-related reductions in CTmax were unaffected by body size. Smaller individuals had faster cloacal heating rates and higher CTmax, and variation in cloacal heating rate affected CTmax in the largest species. Second, we examined how body size interacted with the location of body temperature measurements (i.e., cloaca vs. brain) in Sceloporus occidentalis, then compared this in living and deceased lizards. Brain temperatures were consistently lower than cloacal temperatures. Smaller lizards had larger brain-cloacal temperature differences than larger lizards, due to a slower cloacal heating rate in large lizards. Both live and dead lizards had lower brain than cloacal temperatures, suggesting living lizards do not actively maintain lower brain temperatures when they cannot pant. Thermal inertia influences CTmax data in complex ways, and body size should therefore be considered in studies involving CTmax data on species with variable sizes.

Published

2020

2. The thermal ecology and physiology of reptiles and amphibians: A user's guide

Author

Bálint Halpern, Emily N. Taylor, Rory S. Telemeco, Eric J. Gangloff, Sierra Spears, Joshua M. Hall, Bao-Jun Sun, Melanie D. Massey, Dennis Rödder, Luisa Maria Diele-Viegas, and Njal Rollinson

Subjects

0106 biological sciences, 0301 basic medicine, Embryo, Nonmammalian, Physiology, Ecology (disciplines), Climate change, Biology, 010603 evolutionary biology, 01 natural sciences, Body Temperature, Amphibians, 03 medical and health sciences, Genetics, Animals, Molecular Biology, Ecosystem, Ecology, Evolution, Behavior and Systematics, Monitoring, Physiologic, Ecology, Global warming, Reptiles, 030104 developmental biology, Ectotherm, Animal Science and Zoology, Global biodiversity

Abstract

Research on the thermal ecology and physiology of free-living organisms is accelerating as scientists and managers recognize the urgency of the global biodiversity crisis brought on by climate change. As ectotherms, temperature fundamentally affects most aspects of the lives of amphibians and reptiles, making them excellent models for studying how animals are impacted by changing temperatures. As research on this group of organisms accelerates, it is essential to maintain consistent and optimal methodology so that results can be compared across groups and over time. This review addresses the utility of reptiles and amphibians as model organisms for thermal studies by reviewing the best practices for research on their thermal ecology and physiology, and by highlighting key studies that have advanced the field with new and improved methods. We end by presenting several areas where reptiles and amphibians show great promise for further advancing our understanding of how temperature relations between organisms and their environments are impacted by global climate change.

Published

2020