Andrew A Schmidt, Alexander Y Grosberg, Anna Grosberg
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引用次数: 0
Abstract
Understanding muscle contraction mechanisms is a standing challenge, and one of the approaches has been to create models of the sarcomere-the basic contractile unit of striated muscle. While these models have been successful in elucidating many aspects of muscle contraction, they fall short in explaining the energetics of functional phenomena, such as rigor, and in particular, their dependence on the concentrations of the biomolecules involved in the cross-bridge cycle. Our hypothesis posits that the stochastic time delay between ATP adsorption and ADP/Pi release in the cross-bridge cycle necessitates a modeling approach where the rates of these two reaction steps are controlled by two independent parts of the total free energy change of the hydrolysis reaction. To test this hypothesis, we built a two-filament, stochastic-mechanical half-sarcomere model that separates the energetic roles of ATP and ADP/Pi in the cross-bridge cycle's free energy landscape. Our results clearly demonstrate that there is a nontrivial dependence of the cross-bridge cycle's kinetics on the independent concentrations of ATP, ADP, and Pi. The simplicity of the proposed model allows for analytical solutions of the more basic systems, which provide novel insight into the dominant mechanisms driving some of the experimentally observed contractile phenomena.
了解肌肉收缩机制是一项长期挑战,其中一种方法是创建肌节模型--横纹肌的基本收缩单元。虽然这些模型成功地阐明了肌肉收缩的许多方面,但却无法解释功能现象(如僵直)的能量学,特别是它们对参与横桥循环的生物大分子浓度的依赖性。我们的假设认为,横桥循环中 ATP 吸附和 ADP/Pi 释放之间的随机时间延迟要求采用一种建模方法,即这两个反应步骤的速率由水解反应总自由能变化的两个独立部分控制。为了验证这一假设,我们建立了一个双丝随机机械半节模型,将 ATP 和 ADP/Pi 在横桥循环自由能图谱中的能量作用分开。我们的研究结果清楚地表明,横桥循环的动力学与 ATP、ADP 和 Pi 的独立浓度存在着不小的关系。所提出模型的简易性允许对更基本的系统进行分析求解,这为我们深入了解驱动实验观察到的某些收缩现象的主导机制提供了新的视角。
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