Seebacher Frank, Guderley Helga, Elsey Ruth M, Trosclair Phillip L
School of Biological Sciences A08, University of Sydney, New South Wales 2006, Australia.
J Exp Biol. 2003 Apr;206(Pt 7):1193-200. doi: 10.1242/jeb.00223.
Reptiles living in heterogeneous thermal environments are often thought to show behavioural thermoregulation or to become inactive when environmental conditions prevent the achievement of preferred body temperatures. By contrast, thermally homogeneous environments preclude behavioural thermoregulation, and ectotherms inhabiting these environments (particularly fish in which branchial respiration requires body temperature to follow water temperature) modify their biochemical capacities in response to long-term seasonal temperature fluctuations. Reptiles may also be active at seasonally varying body temperatures and could, therefore, gain selective advantages from regulating biochemical capacities. Hence, we tested the hypothesis that a reptile (the American alligator Alligator mississippiensis) that experiences pronounced seasonal fluctuations in body temperature will show seasonal acclimatisation in the activity of its metabolic enzymes. We measured body temperatures of alligators in the wild in winter and summer (N=7 alligators in each season), and we collected muscle samples from wild alligators (N=31 in each season) for analysis of metabolic enzyme activity (lactate dehydrogenase, citrate synthase and cytochrome c oxidase). There were significant differences in mean daily body temperatures between winter (15.66+/-0.43 degrees C; mean +/- S.E.M.) and summer (29.34+/-0.21 degrees C), and daily body temperatures fluctuated significantly more in winter compared with summer. Alligators compensated for lower winter temperatures by increasing enzyme activities, and the activities of cytochrome c oxidase and lactate dehydrogenase were significantly greater in winter compared with summer at all assay temperatures. The activity of citrate synthase was significantly greater in the winter samples at the winter body temperature (15 degrees C) but not at the summer body temperature (30 degrees C). The thermal sensitivity (Q(10)) of mitochondrial enzymes decreased significantly in winter compared with in summer. The activity of mitochondrial enzymes was significantly greater in males than in females, but there were no differences between sexes for lactate dehydrogenase activity. The differences between sexes could be the result of the sex-specific seasonal demands for locomotor performance. Our data indicate that biochemical acclimatisation is important in thermoregulation of reptiles and that it is not sufficient to base conclusions about their thermoregulatory ability entirely on behavioural patterns.
生活在异质热环境中的爬行动物通常被认为会表现出行为体温调节,或者当环境条件阻碍达到偏好的体温时变得不活跃。相比之下,热均匀环境排除了行为体温调节,栖息在这些环境中的变温动物(特别是鳃呼吸需要体温跟随水温的鱼类)会根据长期的季节性温度波动来改变其生化能力。爬行动物也可能在季节性变化的体温下保持活跃,因此,通过调节生化能力可能会获得选择优势。因此,我们测试了这样一个假设:经历明显体温季节性波动的爬行动物(美国短吻鳄密西西比鳄)会在其代谢酶的活性上表现出季节性适应。我们测量了冬季和夏季野生短吻鳄的体温(每个季节(N = 7)只短吻鳄),并从野生短吻鳄身上采集肌肉样本(每个季节(N = 31)只)用于分析代谢酶活性(乳酸脱氢酶、柠檬酸合酶和细胞色素(c)氧化酶)。冬季((15.66 ± 0.43)摄氏度;平均值 ± 标准误)和夏季((29.34 ± 0.21)摄氏度)的平均每日体温存在显著差异,并且冬季的每日体温波动比夏季明显更大。短吻鳄通过增加酶活性来补偿较低的冬季温度,在所有测定温度下,细胞色素(c)氧化酶和乳酸脱氢酶的活性在冬季均显著高于夏季。柠檬酸合酶的活性在冬季体温((15)摄氏度)下的冬季样本中显著更高,但在夏季体温((30)摄氏度)下则不然。与夏季相比,冬季线粒体酶的热敏感性((Q_{10}))显著降低。线粒体酶的活性在雄性中显著高于雌性,但乳酸脱氢酶活性在两性之间没有差异。两性之间的差异可能是由于运动性能的性别特异性季节性需求导致的。我们的数据表明,生化适应在爬行动物的体温调节中很重要,并且仅基于行为模式来得出关于它们体温调节能力的结论是不够的。
