杂拟谷盗的热适应特性

为了解杂拟谷盗Tribolium confusum Jacquelin du Val的热适应特性,将杂拟谷盗分别于15,25和35℃下驯化2周后,用温度梯度仪测量在不同温度驯化下杂拟谷盗的最适温度、临界低温和临界高温。结果表明,驯化温度对杂拟谷盗最适温度、临界低温和临界高温的影响极显著(P<0.01),最适温度、临界低温、临界高温均随着驯化温度的升高而升高。最适温区的范围随着驯化温度的升高而扩大。驯化温度对杂拟谷盗最适温度的影响最大(0.317),对临界低温的影响(0.310)大于临界高温(0.255)。     

斑马鱼热耐受性对温度驯化的响应及其性别差异

为了探究斑马鱼(Danio rerio)热耐受性对温度驯化的响应及其性别差异,将性成熟斑马鱼分别于适温(28℃)、低温(20℃)和高温(34℃)下驯化14 d,之后测定不同温度驯化下雌鱼和雄鱼的临界高温(critical thermal maxima,CTmax)、致死高温(lethal thermal maxima,LTmax)、临界低温(critical thermal minima,CTmin)、致死低温(lethal thermal minima,LTmin)等热耐受性参数.结果表明:驯化温度对雄鱼和雌鱼的所有热忍耐参数(CTmax、LTmax、CTmin和LTmin)均影响显著(P<0.05),并且驯化温度和性别对热耐受性参数的影响具有交互作用(P<0.05).适温(28℃)驯化下,雌鱼与雄鱼各个热忍耐参数相比无显著差异(P> 0.05);低温(20℃)驯化下雌鱼的耐高温能力强于雄鱼,而高温(34℃)驯化下雌鱼的耐低温能力弱于雄鱼.结果提示:繁殖适温下雌雄斑马鱼的热耐受性趋于一致,而非繁殖适温下二者的热耐受性出现分化.     

中华倒刺鲃不同生理性能对降温的响应速率

为了考查长期高温驯化的中华倒刺鲃(Spinibarbus sinensis)幼鱼快速降温后不同生理功能对低温环境的响应速率,将实验鱼分为2组分别在15℃和25℃条件下长期驯养(8周),随后25℃组快速降温至15℃(降温组),同时15℃组(恒低温对照组)温度保持不变;在降温后的第1、2、4和8周分别测定和比较降温组和恒温对照组实验鱼的温度耐受能力、游泳能力、自发活动水平、摄食代谢和生长性能等相关生理指标。结果显示:降温后,低温耐受能力(CT_(min))1周时就达到稳定与对照组不再有差异,而高温耐受能力(CT_(max))2周时才达到稳定;与对照组相比,降温处理导致实验鱼自发活动水平(运动时间百分比,PTM和运动总距离,TDM)显著上升,且此差异持续整个驯化周期(P0.05);降温组的临界游泳速度(Critical swimming speed U_(crit))在降温的1—2周均显著小于对照组(P0.05),直到4周才达到稳定;降温组实验鱼特殊动力作用(Specific dynamic action SDA)持续时间和摄食后代谢峰值(Peak metabolic rate PMR)与对照组在降温1—4周均没有显著差异;尽管降温组有更高的摄食率,其食物转化效率和增重率均显著低于对照组(P0.05)。研究表明:中华倒刺鲃在水体温度下降后,不同生理功能的稳定速率存在差异,这可能与不同生理功能的生态关联及内在机制的不同有关;降温处理导致机体生长受阻,其主要原因可能是由于应对环境温度变动的逆境胁迫、生理功能调整以及自发活动增加所导致的能量消耗上升所致。     

温度驯化对尖头鳉热耐受特征的影响

为了研究不同驯化温度对尖头鰂(Rhynchocypris oxycephalus)热耐受特征的影响, 本研究设置4组水温(14℃、19℃、24℃和29℃), 对尖头鰂驯化两周, 采用临界温度法观察尖头鰂的耐受温度。结果显示: 尖头鰂的热耐受性受到温度驯化的影响, 表现为高温驯化可以升高最大临界温度(CT_max), 4个驯化组的平均CT_max分别为32.29℃、33.23℃、33.40℃和35.71℃; 低温驯化可以降低最小临界温度(CT_min), 平均CT_min分别为0.00、0.10℃、2.10℃和5.27℃; 在适中的温度(19℃)驯化条件下具有最高的温度耐受范围(33.13℃)。在高温条件下的温度驯化具有较高的驯化反应率, 最大值出现在24—29℃内(0.46); 低温驯化反应率最大值出现在29—24℃内, 为0.63。尖头鰂在本研究的驯化区间(14—29℃)内的热耐受区域面积为478.98℃2, 与温水性鱼类的温度耐受性相当, 说明尖头鰂具有较强的温度适应能力。     

中华倒刺鲃能量代谢和热耐受特征的体重效应

为了探讨体重对中华倒刺鲃能量代谢和热耐受特征的影响,在25℃条件下分别测定不同体重大小(1、10、25、50 g组)中华倒刺鲃的静止代谢率(Resting metabolic rate,RMR)、力竭运动后过量耗氧(Excess post-exercise oxygen consumption,EPOC)和热耐受参数。随体重的增加,中华倒刺鲃个体RMR、最大代谢率(Maximum metabolic rate,MMR)、代谢空间(Metabolic scope,MS)和EPOC均显著增加(P0.05);单位体重RMR、MMR和MS则均显著降低,而单位体重EPOC随体重的增加显著增加(P0.05)。RMR、MMR、MS和EPOC的代谢尺度指数分别为0.796、0.834、0.849和1.137且显著大于2/3,因此中华倒刺鲃的能量代谢参数均呈异速度增加的关系而变化。这些变化可能与其个体变大游泳运动能力增强导致能量代谢需求增加相关。中华倒刺鲃临界低温(Critical thermal minimum,CT_(min))和致死低温(Lethal thermal minimum,IL_(min))与体重之间均呈"微笑型"二次函数的关系,临界高温(Critical thermal maximum,CT_(max))和致死高温(Lethal thermal maximum,IL_(max))均呈"钟型"二次函数的关系,因此中等大小的中华倒刺鲃具有更强的热耐受能力。这种非线性关系可能与其生长发育阶段和温度驯化历时有关。     

温度驯化对高体鳑鲏热耐受及低氧耐受能力的影响

为了考察温度驯化对鱼类热耐受及低氧耐受能力的影响,以高体鳑鲏(Rhodeus ocellatus)为对象,分别在15、20和25℃条件下驯化14 d,随后在不同驯化温度下测定其温度和低氧耐受指标。结果表明:高体鳑鲏的临界高温(CTmax)和致死高温(LTmax)随驯化温度的升高而上升,临界低温(CTmin)和致死低温(LTmin)随驯化温度的降低而下降,说明高体鳑鲏的热耐受性具有温度依赖性;高体鳑鲏在各驯化温度下的温度耐受幅分别为29.34、30.18和28.01℃;高体鳑鲏的低温驯化反应率在15~20℃和20~25℃的驯化温度范围分别为0.23和0.87,说明高体鳑鲏的低温耐受能力在高温段具有更高的温度敏感性;而高温驯化反应率在不同温度范围差别不大(0.40和0.44);高体鳑鲏失去平衡氧压则随着驯化温度的升高而上升,表明温度上升降低了高体鳑鲏的低氧耐受能力。     

鼎突多刺蚁热适应及运动行为的热依赖性

将鼎突多刺蚁(Polyrhachis vicina)分别置于15、20、25和30℃的恒温恒湿培养箱内,对其热适应及运动行为的热依赖性进行了研究。驯化2周后,采用温度梯度仪测量其热适应参数,并选用停顿频率(PF)、疾跑速度(SS)和最大持续运动距离(MDCCL)来衡量其运动能力。结果表明,驯化温度对鼎突多刺蚁的热适应和运动行为有极显著影响(P<0.01)。最适温度(PT)、临界低温(CLT)、临界高温(CHT)随驯化温度(AT)的升高而增大,最终适温为30.54℃,临界低温不低于3℃,临界高温不高于45℃;经过高温驯化的鼎突多刺蚁的运动能力显著大于经过低温驯化的个体运动能力,驯化温度与疾跑速度、最大持续运动距离呈显著的正相关,而与停顿频率呈极显著的负相关。     

恒温与变温对不同生活史阶段斑马鱼热耐受性的影响

为了探究恒温与变温以及生活史阶段对斑马鱼(Danio rerio)热耐受性的影响,将新孵出的斑马鱼仔鱼、幼鱼以及性成熟雌鱼与雄鱼分别于恒温(28℃)和变温(26～30℃)条件下驯养2周,之后,采用临界温度法测定不同温度驯化下仔鱼、幼鱼以及雌鱼和雄鱼的临界高温CT_(max)、致死高温LT_(max)、临界低温CTmin、致死低温LTmin等热耐受性参数。结果表明:驯化温度、生活史阶段以及二者交互作用对CT_(max)、LT_(max)、CTmin和LTmin均影响显著(P0.05),驯化温度和性别对斑马鱼成鱼的热忍耐参数无显著性影响(P 0.05);仔鱼的热耐受性较差,低于幼鱼和成鱼,表现为CT_(max)和LT_(max)低而CTmin和LTmin高,这可能主要与不同生活史阶段实验鱼的生活习性及其栖息环境有关;变温对幼鱼和成鱼热耐受性无显著影响,但导致仔鱼体长增加、热忍耐范围变窄,提示仔鱼生长和热耐受性可能存在权衡。     

虎纹蛙选择体温和热耐受性在个体发育过程中的变化

体温是影响变温动物表现的最重要生理学变量。检测了国家二级保护动物虎纹蛙的雌性亚成体、雄性亚成体、幼体和蝌蚪这4个发育阶段的选择体温和热耐受性。单因子方差分析表明,虎纹蛙选择体温、耐受低温、耐受高温和温度耐受范围的组间差异均显著,幼体的选择体温(24.13℃)显著低于雌性亚成体(28.06℃)、雄性亚成体(29.27℃)和蝌蚪(28.23℃),雌性亚成体、雄性亚成体和蝌蚪之间差异不显著;幼体的耐受低温(13.85℃)显著高于雌性亚成体(11.27℃)、雄性亚成体(10.84℃)和蝌蚪(10.74℃),雌性亚成体、雄性亚成体和蝌蚪之间差异不显著;幼体具有显著低的耐受高温(35.48℃)、蝌蚪具有显著高的耐受高温(43.31℃),雌性亚成体(39.55℃)和雄性亚成体(39.02℃)的耐受高温差异不显著;幼体(21.62℃)具有显著小的温度耐受范围、蝌蚪(32.58℃)具有显著大的温度耐受范围,雌性亚成体(28.28℃)和雄性亚成体(28.18℃)的温度耐受范围差异不显著。虎纹蛙幼体和亚成体体温和水温之间在降温速度和升温速度的相关关系均显著。用回归剩余值去除水温变化速度对体温变化的影响,双因子方差分析(降温和升温速度为重复检验设置)表明,幼体的体温变化速度显著大于亚成体,两性亚成体间差异不显著;温度变化类型(降温和升温)和两因子的交互作用对体温变化的影响不显著。基本热生态位分离和体温调节能力的发育限制是形成上述现象的最可能的原因。     

Effects of evolutionary thermal environment on temperature-preference relationships in fishes

Fishes exhibit a perplexing variety of temperature-preference relationships, ranging from positive to negative functions of acclimation temperature. However, these relationships tend to be consistent within species even across broad geographic ranges. We developed and tested an hypothesis that temperature-preference relationships are related to the amplitude of the annual thermal-cycle experienced by species during their recent evolutionary histories. Species experiencing annual cycles of relatively high amplitude (temperate species) were predicted to exhibit temperature-preference relationships that are positive functions of acclimation temperature. Those with low thermal amplitudes, such as cold stenotherms, or relatively high short-term amplitudes, such as tropical mesotherms, were predicted to exhibit relationships that are either independent or negative functions of acclimation temperature. This hypothesis was tested and strongly supported by a synthesis of studies from the literature. Of 42 species, for which data were available, 40 exhibited the class of temperature-preference relationships that we predicted on the basis of their thermal cycle. The concept of thermal guilds can be expanded by taking into consideration the capacity of fishes to adjust preferred temperatures through acclimation. This work shows the adaptive nature of temperature-preference behavior and may be useful for predicting general characteristics of temperature-preference relationships for the many species not yet examined in this regard.     

The Seasonal Acclimatisation of Locomotion in a Terrestrial Reptile,Plestiodon chinensis （Scincidae）

Studies of the seasonal acclimatisation of behavioural and physiological processes usually focus on aquatic or semi-aquatic ectotherms and focus less effort on terrestrial ectotherms that experience more thermally heterogeneous environments. We conducted comparative studies and thermal acclimation experiments on the locomotion of the Chinese skink （Plestiodon chinensis） to test whether seasonal acclimatisation in locomotion exists in these terrestrial ectothermic vertebrates, and whether seasonal acclimatisation is predominantly induced by thermal environments. In natural populations, skinks ran faster during the summer season than during the spring season at high-test temperatures ranging from 27℃ to 36℃ but not at low-test temperatures ranging from 18℃ to 24℃. In contrast, the thermal acclimation experiments showed that the cold-acclimated skinks ran faster than the warm-acclimated skinks at the low- test temperatures but not at high-test temperatures. Therefore, the seasonal acclimatisation occurs to P chinensis, and may be induced by temperature as well as other factors like food availability, as indicated by the seasonal variation in the thermal dependence of locomotion, and the discrepancy between seasonal acclimatisation and thermal acclimation on locomotion.     

Temperature-induced changes in the locomotor capacity of juveniles of Marenzelleria viridis (Polychaeta, Spionidae)

Abstract. Populations of Marenzelleria viridis in the Chester River (Kent County, Maryland) experience temperatures ranging from over 30°C in summer to near freezing in winter. Interestingly, M. viridis swims actively in winter. This observation led us to examine the relationship between locomotor capacity and temperature in individuals of M. viridis . Juvenile specimens were collected in February ("cold animals") and June ("warm animals"). Video analysis revealed that swimming is achieved by flexing the body in cyclic, helical waves. Wave frequencies were measured as an index of locomotor capacity at 5°C, 15°C, and 25°C. The mean wave frequencies of cold animals were 5.4 Hz at 5°C and 7.1 Hz at 15°C (Q₁₀= 1.3); the mean wave frequencies of warm animals were 6.1 Hz at 15°C and 7.8 Hz at 25°C (Q₁₀= 1.3). The effects of changes in water viscosity on wave frequency between 5–25°C were not significant. These results demonstrate that the temperature sensitivity of locomotor capacity in juvenile M. viridis is quite low. We conclude that low temperature sensitivity enables M. viridis to be active throughout the year.     

The combined effects of reactant kinetics and enzyme stability explain the temperature dependence of metabolic rates

A mechanistic understanding of the response of metabolic rate to temperature is essential for understanding thermal ecology and metabolic adaptation. Although the Arrhenius equation has been used to describe the effects of temperature on reaction rates and metabolic traits, it does not adequately describe two aspects of the thermal performance curve (TPC) for metabolic rate—that metabolic rate is a unimodal function of temperature often with maximal values in the biologically relevant temperature range and that activation energies are temperature dependent. We show that the temperature dependence of metabolic rate in ectotherms is well described by an enzyme‐assisted Arrhenius (EAAR) model that accounts for the temperature‐dependent contribution of enzymes to decreasing the activation energy required for reactions to occur. The model is mechanistically derived using the thermodynamic rules that govern protein stability. We contrast our model with other unimodal functions that also can be used to describe the temperature dependence of metabolic rate to show how the EAAR model provides an important advance over previous work. We fit the EAAR model to metabolic rate data for a variety of taxa to demonstrate the model's utility in describing metabolic rate TPCs while revealing significant differences in thermodynamic properties across species and acclimation temperatures. Our model advances our ability to understand the metabolic and ecological consequences of increases in the mean and variance of temperature associated with global climate change. In addition, the model suggests avenues by which organisms can acclimate and adapt to changing thermal environments. Furthermore, the parameters in the EAAR model generate links between organismal level performance and underlying molecular processes that can be tested for in future work.     

Northern grass lizards (<Emphasis Type="Italic">Takydromus septentrionalis</Emphasis>) from different populations do not differ in thermal preference and thermal tolerance when acclimated under identical thermal conditions

We acclimated adults of Takydromus septentrionalis (northern grass lizard) from four localities (populations) under identical thermal conditions to examine whether local thermal conditions have a fixed influence on thermal preference and thermal tolerance in the species. Selected body temperature (Tsel), critical thermal minimum (CTMin), and critical thermal maximum (CTMax) did not differ between sexes and among localities in lizards kept under identical laboratory conditions for ∼5 months, and the interaction effects between sex and locality on these measures were not significant. Lizards acclimated to the three constant temperatures (20, 25, and 35°C) differed in Tsel, CTMin, and CTMax. Tsel, CTMin, and CTMax all shifted upward as acclimation temperature increased, with Tsel shifting from 32.0 to 34.1°C, CTMin from 4.9 to 8.0°C, and CTMax from 42.0 to 44.5°C at the change-over of acclimation temperature from 20 to 35°C. Lizards acclimated to the three constant temperatures also differed in the range of viable body temperatures; the range was widest in the 25°C treatment (38.1°C) and narrowest in the 35°C treatment (36.5°C), with the 20°C treatment in between (37.2°C). The results of this study show that local thermal conditions do not have a fixed influence on thermal preference and thermal tolerance in T. septentrionalis.     

An experimental study of ontogenetic and seasonal changes in the temperature preferences of unfed and fed brown trout,Salmo trutta

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