Cold-hearted bats: uncoupling of heart rate and metabolism during torpor at subzero temperatures

迟钝 温度调节 氧气 休眠(计算) 生物 恒温 心率 基础代谢率 动物科学 化学 内科学 生态学 内分泌学 医学 血压 国家(计算机科学) 计算机科学 有机化学 算法
作者
Shannon E. Currie,Clare Stawski,Fritz Geiser
出处
期刊:The Journal of Experimental Biology [The Company of Biologists]
卷期号:221 (Pt 1) 被引量:23
标识
DOI:10.1242/jeb.170894
摘要

Many hibernating animals thermoregulate during torpor and defend their body temperature (Tb) near 0°C by an increase in metabolic rate. Above a critical temperature (Tcrit), animals usually thermoconform. We investigated the physiological responses above and below Tcrit for a small tree-dwelling bat (Chalinolobus gouldii, ∼14 g) that is often exposed to sub-zero temperatures during winter. Through simultaneous measurement of heart rate (fH) and oxygen consumption (O2 ), we show that the relationship between oxygen transport and cardiac function is substantially altered in thermoregulating torpid bats between 1 and -2°C, compared with thermoconforming torpid bats at mild ambient temperatures (Ta 5-20°C). Tcrit for this species was at a Ta of 0.7±0.4°C, with a corresponding Tb of 1.8±1.2°C. Below Tcrit, animals began to thermoregulate, as indicated by a considerable but disproportionate increase in both fH and O2 The maximum increase in fH was only 4-fold greater than the average thermoconforming minimum, compared with a 46-fold increase in O2 The differential response of fH and O2 to low Ta was reflected in a 15-fold increase in oxygen delivery per heart beat (cardiac oxygen pulse). During torpor at low Ta, thermoregulating bats maintained a relatively slow fH and compensated for increased metabolic demands by significantly increasing stroke volume and tissue oxygen extraction. Our study provides new information on the relationship between metabolism and fH in an unstudied physiological state that may occur frequently in the wild and can be extremely costly for heterothermic animals.
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