易科泰两爬动物能量代谢测量技术部分参考文献目录
时间:2024-09-26 阅读:233
两爬类动物的能量代谢研究对于理解它们的生存策略、适应环境变化的能力以及在生态系统中的角色至关重要。通过测量这些动物在不同生态条件下的耗氧量(VO2),科学家们预测和解释它们对气候变化、栖息地破坏和其他环境压力的反应,从而为保护生物多样性和维持生态平衡提供重要的数据支持。此外,这些研究还有助于揭示代谢过程的生物学基础,为比较生理学提供见解,并可能对人类医学和保健有所启发。
l Baškiera, Senka, and Lumír Gvoždík. "Repeatability and heritability of resting metabolic rate in a long-lived amphibian." Comparative Biochemistry and Physiology Part A: Molecular & Integrative Physiology 253 (2021): 110858.
l Burger I J, Carter E T, Magner L M, et al. Assessing hybrid vigour using the thermal sensitivity of physiological trade‐offs in tiger salamanders[J]. Functional Ecology, 2024, 38(1): 143-152.
l Capparelli M V , Bordon I C , Araujo G , et al. Combined effects of temperature and copper on oxygen consumption and antioxidant responses in the mudflat fiddler crab Minuca rapax (Brachyura, Ocypodidae)[J]. Comparative Biochemistry and Physiology Part C: Toxicology & Pharmacology, 2019, 223:35-41.
l Dubiner S, Jamison S, Meiri S, et al. Squamate metabolic rates decrease in winter beyond the effect of temperature[J]. Journal of Animal Ecology, 2023, 92(11): 2163-2174.
l Faria, S. C., Bianchini, A., Lauer, M. M., Zimbardi, A. L. R. L., Tapella, F., Romero, M. C., & McNamara, J. C. (2020). Living on the Edge: Physiological and Kinetic Trade-Offs Shape Thermal Tolerance in Intertidal Crabs From Tropical to Sub-Antarctic South America. Frontiers in Physiology, 11.
l Gvozdik, Lumir, Kratochvil, et al. An energetic perspective on tissue regeneration: The costs of tail autotomy in growing geckos[J]. Comparative biochemistry and physiology, Part A. Molecular and integrative physiology, 2017.
l Jiang ZW, Ma L, Tao SA, Wenda C, Cheng C, Wu DY, Du WG. Analysis of resting status reveals distinct elevational variation in metabolisms of lizards. Ecology. 2024 Sep 10:e4414. doi: 10.1002/ecy.4414. Epub ahead of print. PMID: 39256909.
l Kouyoumdjian L , Gangloff E J , et al. Transplanting gravid lizards to high elevation alters maternal and embryonic oxygen physiology, but not reproductive success or hatchling phenotype[J]. Journal of Experimental Biology, 2019, 222(14):jeb.206839.
l Lardies M A , Munoz J L , Paschke K A , et al. Latitudinal variation in the aerial/aquatic ratio of oxygen consumption of a supratidal high rocky-shore crab[J]. Marine Ecology, 2011, 32(1):42-51.
l Louppe, V., Courant, J., Videlier, M., & Herrel, A. (2018). Differences in standard metabolic rate at the range edge versus the center of an expanding invasive population of Xenopus laevis in the West of France. Journal of Zoology, 305, 163-172.
l Messerman, Arianne F., and Manuel Leal. "Inter-and intraspecific variation in juvenile metabolism and water loss among five biphasic amphibian species." Oecologia 194.3 (2020): 371-382.
l Messerman, Arianne F., and Manuel Leal. "The contributions of individual traits to survival among terrestrial juvenile pond‐breeding salamanders." Functional Ecology 36.3 (2022): 516-525.
l Padilla P, Herrel A, Denoël M. Invading new climates at what cost? Ontogenetic differences in the thermal dependence of metabolic rate in an invasive amphibian[J]. Journal of Thermal Biology, 2024, 121: 103836.
l Riddell, E.A., Roback, E.Y., Wells, C.E.et al.Thermal cues drive plasticity of desiccation resistance in montane salamanders with implications for climate change. Nat Commun 10,4091 (2019).
l Senzano L M, Andrade D V. Temperature and dehydration effects on metabolism, water uptake and the partitioning between respiratory and cutaneous evaporative water loss in a terrestrial toad[J]. Journal of Experimental Biology, 2018, 221(24): jeb188482.