用力量换取速度:为何超快横桥动力学导致超低力量。
Trading force for speed: why superfast crossbridge kinetics leads to superlow forces.
作者信息
Rome L C, Cook C, Syme D A, Connaughton M A, Ashley-Ross M, Klimov A, Tikunov B, Goldman Y E
机构信息
Biology Department, Leidy Laboratories, University of Pennsylvania, Philadelphia, PA 19104, USA.
出版信息
Proc Natl Acad Sci U S A. 1999 May 11;96(10):5826-31. doi: 10.1073/pnas.96.10.5826.
Abstract
Superfast muscles power high-frequency motions such as sound production and visual tracking. As a class, these muscles also generate low forces. Using the toadfish swimbladder muscle, the fastest known vertebrate muscle, we examined the crossbridge kinetic rates responsible for high contraction rates and how these might affect force generation. Swimbladder fibers have evolved a 10-fold faster crossbridge detachment rate than fast-twitch locomotory fibers, but surprisingly the crossbridge attachment rate has remained unchanged. These kinetics result in very few crossbridges being attached during contraction of superfast fibers (only approximately 1/6 of that in locomotory fibers) and thus low force. This imbalance between attachment and detachment rates is likely to be a general mechanism that imposes a tradeoff of force for speed in all superfast fibers.
摘要
超快肌为诸如发声和视觉追踪等高频运动提供动力。作为一个类别,这些肌肉产生的力量也较小。我们利用蟾鱼的鱼鳔肌(已知最快的脊椎动物肌肉),研究了负责高收缩率的横桥动力学速率以及这些速率如何影响力量产生。与快肌纤维相比,鱼鳔纤维的横桥解离速率快了10倍,但令人惊讶的是,横桥结合速率并未改变。这些动力学特性导致超快肌纤维收缩时附着的横桥非常少(仅约为运动纤维的1/6),从而产生的力量较小。附着和解离速率之间的这种不平衡可能是一种普遍机制,在所有超快肌纤维中都存在力量与速度的权衡。
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