首页>
美国卫生研究院文献>The Journal of Physiology
>The ATP hydrolysis and phosphate release steps control the time course of force development in rabbit skeletal muscle
【2h】
The ATP hydrolysis and phosphate release steps control the time course of force development in rabbit skeletal muscle
The time course of isometric force development following photolytic release of ATP in the presence of Ca2+ was characterized in single skinned fibres from rabbit psoas muscle. Pre-photolysis force was minimized using apyrase to remove contaminating ATP and ADP. After the initial force rise induced by ATP release, a rapid shortening ramp terminated by a step stretch to the original length was imposed, and the time course of the subsequent force redevelopment was again characterized. Force development after ATP release was accurately described by a lag phase followed by one or two exponential components. At 20°C, the lag was 5.6 ± 0.4 ms (s.e.m., n = 11), and the force rise was well fitted by a single exponential with rate constant 71 ± 4 s−1. Force redevelopment after shortening–restretch began from about half the plateau force level, and its single-exponential rate constant was 68 ± 3 s−1, very similar to that following ATP release. When fibres were activated by the addition of Ca2+ in ATP-containing solution, force developed more slowly, and the rate constant for force redevelopment following shortening–restretch reached a maximum value of 38 ± 4 s−1 (n = 6) after about 6 s of activation. This lower value may be associated with progressive sarcomere disorder at elevated temperature. Force development following ATP release was much slower at 5°C than at 20°C. The rate constant of a single-exponential fit to the force rise was 4.3 ± 0.4 s−1 (n = 22), and this was again similar to that after shortening–restretch in the same activation at this temperature, 3.8 ± 0.2 s−1. We conclude that force development after ATP release and shortening–restretch are controlled by the same steps in the actin–myosin ATPase cycle. The present results and much previous work on mechanical–chemical coupling in muscle can be explained by a kinetic scheme in which force is generated by a rapid conformational change bracketed by two biochemical steps with similar rate constants – ATP hydrolysis and the release of inorganic phosphate – both of which combine to control the rate of force development.
展开▼
机译:在兔腰肌单皮纤维中,在Ca 2 + 存在下光解ATP后,等距力的发展随时间变化。使用腺苷三磷酸酶去除污染的ATP和ADP可以最大程度降低预光解力。在由ATP释放引起的初始力上升之后,施加一个快速缩短的坡道,该坡道被逐步拉伸到原始长度终止,并再次表征了后续力重新发展的时间过程。 ATP释放后的力发展由滞后阶段和一或两个指数成分精确描述。在20°C下,滞后时间为5.6±0.4毫秒(s.e.m.,n = 11),力的上升完全由速率常数为71±4 s -1 的单个指数拟合。缩短-伸展后的力量重建从大约高原力量水平的一半开始,其单指数速率常数为68±3 s -1 ,与ATP释放后的相似。当通过在含ATP的溶液中添加Ca 2 + 激活纤维时,力发展得更慢,而缩短-再拉伸后力再发展的速率常数达到最大值38±4 s <激活约6 s后,sup> -1 (n = 6)。该较低的值可能与在升高的温度下进行性肌节疾病有关。 ATP释放后的力发展在5°C比在20°C慢得多。单指数拟合对力上升的速率常数为4.3±0.4 s −1 (n = 22),这再次类似于在相同激活下缩短-拉伸后的速率常数温度为3.8±0.2 s -1 。我们得出的结论是,肌动蛋白-肌球蛋白ATPase循环中的相同步骤控制了ATP释放和缩短-重新伸展后的力量发展。目前的结果和以前有关肌肉中机械化学耦合的研究可以通过动力学方案来解释,该动力学方案是通过快速构象变化产生力,该构象变化由两个具有相似速率常数的生化步骤(ATP水解和无机磷酸盐的释放)包围。两者结合起来可以控制力量的发展速度。
展开▼
