Regional thermal specialisation in a mammal: temperature affects power output of core muscle more than that of peripheral muscle in adult mice (Mus musculus)
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- 作者:Rob S. James ; Jason Tallis…
- 关键词:Endotherm ; Force ; Power ; Temperature ; Tetanus ; Thermal sensitivity
- 刊名:Journal of Comparative Physiology B: Biochemical, Systemic, and Environmental Physiology
- 出版年:2015
- 出版时间:January 2015
- 年:2015
- 卷:185
- 期:1
- 页码:135-142
- 全文大小:281 KB
- 参考文献:1. Altringham JD, Block BA (1997) Why do tuna maintain elevated slow muscle temperatures? Power output of muscle isolated from endothermic and ectothermic fish. J Exp Biol 200:2617-627
2. Altringham JD, Young IA (1991) Power output and the frequency of oscillatory work in mammalian diaphragm muscle: the effects of animal size. J Exp Biol 157:318-89
3. Angilletta MJ Jr (2009) Thermal adaptation. A theoretical and empirical synthesis. Oxford University Press, Oxford
4. Angilletta MJ Jr, Cooper BS, Schuler MS, Boyles JG (2010) The evolution of thermal physiology in endotherms. Front Biosci E2:861-81 CrossRef
5. Bennett AF (1984) Thermal dependence of muscle function. Am J Physiol 247:R217–R229
6. Bernal D, Smith D, Lopez G, Weitz D, Grimminger T, Dickson K, Graham JB (2003) Comparative studies of high performance swimming in sharks II. Metabolic biochemistry of locomotor and myocardial muscle in endothermic and ectothermic sharks. J Exp Biol 206:2845-857 CrossRef
7. Bernal D, Donley JM, Shadwick RE, Syme DA (2005) Mammal-like muscles power swimming in a cold-water shark. Nature 437:1349-352 CrossRef
8. Caiozzo VJ (2002) Plasticity of skeletal muscle phenotype: mechanical consequences. Muscle Nerve 26:740-68 CrossRef
9. Castle PC, Macdonald AL, Philp A, Webborn A, Watt PW, Maxwell NS (2006) Precooling leg muscle improves intermittent sprint exercise performance in hot, humid conditions. J Appl Physiol 100:1377-384 CrossRef
10. Choi IH, Cho Y, Oh YK, Jung NP, Shin HC (1998) Behavior and muscle performance in heterothermic bats. Physiol Zool 71:257-66
11. Crawley MJ (2007) The R book. Wiley, New York CrossRef
12. Curtin NA, Woledge RC (1993a) Efficiency of energy conversion during sinusoidal movement of white muscle fibres from the dogfish / Scyliorhinus canicula. J Exp Biol 183:137-47
13. Curtin NA, Woledge RC (1993b) Efficiency of energy conversion during sinusoidal movement of red muscle fibres from the dogfish / Scyliorhinus canicula. J Exp Biol 185:195-06
14. De Ruiter CJ, Jones DA, Sargeant AJ, De Haan A (1999) Temperature effect on the rates of isometric force development and relaxation in the fresh and fatigued human adductor pollicis muscle. Exp Physiol 84:1137-150 CrossRef
15. Donley JM, Shadwick RE, Sepulveda CA, Syme DA (2007) Thermal dependence of contractile properties of the aerobic locomotor muscle in the leopard shark and shortfin mako shark. J Exp Biol 210:1194-203 CrossRef
16. Donley JM, Sepulveda CA, Aalbers SA, McGillivray DG, Syme DA, Bernal D (2012) Effects of temperature on power output and contraction kinetics in the locomotor muscle of the regionally endothermic common thresher shark ( / Alopias vulpinus). Fish Physiol Biochem 38:1507-519 CrossRef
17. Ducharme MB, VanHelder WP, Radomski MW (1991) Tissue temperature profile in the human forearm during thermal stress at thermal stability. J Appl Physiol 71:1973-978
18. Herrel A, James RS, Van Damme R (2007) Fight versus flight: physiological basis for temperature dependent behavioral shifts in lizards. J Exp Biol 210:1762-767 CrossRef
19. James RS (2013) A review of the thermal sensitivity of the mechanics of vertebrate skeletal muscle. J Comp Physiol 183:723-33 CrossRef
20. James RS, Altringham JD, Goldspink DF (1995) The mechanical properties of fast and slow skeletal muscles of the mouse in relation to their locomotory function. J Exp Biol 198:491-02
21. James RS, Young IS, Cox VM, Goldspink DF, Altringham JD (1996) Isometric and isotonic muscle properties as determinants of work loop power output. Pflug Arch Eur J Physiol 432:767-74
文摘
In endotherms, such as mammals and birds, internal organs can specialise to function within a narrow thermal range. Consequently, these organs should become more sensitive to changes in body temperature. Yet, organs at the periphery of the body still experience considerable fluctuations in temperature, which could select for lower thermal sensitivity. We hypothesised that the performance of soleus muscle taken from the leg would depend less on temperature than would the performance of diaphragm muscle taken from the body core. Soleus and diaphragm muscles were isolated from mice and subjected to isometric and work-loop studies to analyse mechanical performance at temperatures between 15 and 40?°C. Across this thermal range, soleus muscle took longer to generate isometric force and longer to relax, and tended to produce greater normalised maximal force (stress) than did diaphragm muscle. The time required to produce half of maximal force during isometric tetanus and the time required to relax half of maximal force were both more sensitive to temperature in soleus than they were in diaphragm. However, thermal sensitivities of maximal force during isometric tetani were similar for both muscles. Consistent with our hypothesis, power output (the product of speed and force) was greater in magnitude and more thermally sensitive in diaphragm than it was in soleus. Our findings, when combined with previous observations of muscles from regionally endothermic fish, suggest that endothermy influences the thermal sensitivities of power output in core and peripheral muscles.