Dobson G P, Parkhouse W S, Hochachka P W
Am J Physiol. 1987 Jul;253(1 Pt 2):R186-94. doi: 10.1152/ajpregu.1987.253.1.R186.
In the process of defining the recruitment of fuel and pathway selection in rainbow trout fast-twitch white skeletal muscle, it was clear that the near-maximal myosin adenosinetriphosphatase activity during a 10-s sprint was supported solely by phosphocreatine hydrolysis. A conservative estimate of the ATP turnover was 188 mumol X g wet wt-1 X min-1. It was not until the rate and force of contraction decreased that the relative contribution of anaerobic glycogenolysis became increasingly important. Over a 10-min period of burst swimming at approximately 120% of maximum aerobic steady-state swimming velocity of trout determined in a Brett-type swim tunnel, fatigue was associated with the near-depletion of glycogen in white muscle. The ATP turnover supported by anaerobic glycogenolysis was 78 mumol X g wet wt-1 X min-1. The glycolytic pathway appeared functional at this time with control sites being identified at hexokinase and phosphofructokinase (PFK-1). PFK-1 did not appear to be inhibited by low muscle pH (pH 6.66). In another exercise protocol lasting 30 min, complete exhaustion was related to glycogen depletion. The sum of all glycolytic intermediates from glucose 6-phosphate to pyruvate at exhaustion decreased by a dramatic 80% compared with the 25% decrease for the 10-min fatigue swimming protocol. This large depletion of glycolytic intermediates was accompanied by an 80% fall in ATP, a 70-80% reduction in the ATP/ADP and phosphorylation potential, and a 2.5-fold increase in the NAD/NADH. Associated with these changes was a marked displacement of the phosphoglycerate kinase (PGK), and the combined glyceraldehyde-3-phosphate dehydrogenase-PGK reactions from thermodynamic equilibrium. As a general conclusion, fatigue and exhaustion should be viewed as a multicomponent biochemical process in response to low glycogen and not leveled at one particular step of the glycolytic pathway.
在确定虹鳟鱼快肌白色骨骼肌中燃料募集和途径选择的过程中,很明显,在10秒冲刺过程中接近最大的肌球蛋白三磷酸腺苷酶活性仅由磷酸肌酸水解来支持。对三磷酸腺苷周转率的保守估计为188μmol·g湿重⁻¹·min⁻¹。直到收缩速率和力量下降,无氧糖酵解的相对贡献才变得越来越重要。在以布雷特式游泳隧道中测定的鳟鱼最大有氧稳态游泳速度的约120%进行的10分钟爆发式游泳期间,疲劳与白色肌肉中糖原的近乎耗尽有关。无氧糖酵解支持的三磷酸腺苷周转率为78μmol·g湿重⁻¹·min⁻¹。此时糖酵解途径似乎发挥了作用,己糖激酶和磷酸果糖激酶(PFK-1)被确定为控制点。PFK-1似乎不受低肌肉pH值(pH 6.66)的抑制。在另一个持续30分钟的运动方案中,完全疲劳与糖原耗尽有关。与10分钟疲劳游泳方案中25%的下降相比,疲劳时从6-磷酸葡萄糖到丙酮酸的所有糖酵解中间产物的总和急剧下降了80%。糖酵解中间产物的大量消耗伴随着三磷酸腺苷下降80%、三磷酸腺苷/二磷酸腺苷和磷酸化电位降低70 - 80%以及烟酰胺腺嘌呤二核苷酸/还原型烟酰胺腺嘌呤二核苷酸增加2.5倍。与这些变化相关的是磷酸甘油酸激酶(PGK)的明显移位,以及甘油醛-3-磷酸脱氢酶 - PGK联合反应偏离热力学平衡。总的来说,疲劳和完全疲劳应被视为对低糖原的多组分生化过程,而不应归咎于糖酵解途径的某一特定步骤。
