Force and kinetics of fast and slow muscle myosin determined with a synthetic sarcomere-like nanomachine

arXiv - QuanBio - Tissues and Organs Pub Date : 2024-08-01 DOI:arxiv-2408.00373

Valentina Buonfiglio, Irene Pertici, Matteo Marcello, Ilaria Morotti, Marco Caremani, Massimo Reconditi, Marco Linari, Duccio Fanelli, Vincenzo Lombardi, Pasquale Bianco

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Abstract

Myosin II is the muscle molecular motor that works in two bipolar arrays in each thick filament of the striated (skeletal and cardiac) muscle, converting the chemical energy into steady force and shortening by cyclic ATP--driven interactions with the nearby actin filaments. Different isoforms of the myosin motor in the skeletal muscles account for the different functional requirements of the slow muscles (primarily responsible for the posture) and fast muscles (responsible for voluntary movements). To clarify the molecular basis of the differences, here the isoform--dependent mechanokinetic parameters underpinning the force of slow and fast muscles are defined with a unidimensional synthetic nanomachine powered by pure myosin isoforms from either slow or fast rabbit skeletal muscle. Data fitting with a stochastic model provides a self--consistent estimate of all the mechanokinetic properties of the motor ensemble including the motor force, the fraction of actin--attached motors and the rate of transition through the attachment--detachment cycle. The achievements in this paper set the stage for any future study on the emergent mechanokinetic properties of an ensemble of myosin molecules either engineered or purified from mutant animal models or human biopsies.

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用合成的类肉瘤纳米机械测定快慢肌肌球蛋白的力量和动力学特性

肌球蛋白Ⅱ是肌肉分子马达，它在横纹肌（骨骼肌和心肌）每条粗丝的两个双极阵列中工作，通过与附近肌动蛋白丝的循环 ATP 驱动相互作用，将化学能转化为稳定的力量和缩短。由于骨骼肌中肌球蛋白运动的同工形式不同，慢肌（主要负责姿势）和快肌（负责自主运动）的功能要求也不同。为了阐明这种差异的分子基础，本文通过一个由纯兔慢肌或快肌肌球蛋白同工酶驱动的单维合成纳米机器，定义了支撑慢肌和快肌力量的同工酶依赖性机械动力学参数。随机模型的数据拟合为运动组合的所有机械动力学特性提供了自我一致的估计，包括运动力、肌动蛋白附着运动的比例以及附着-分离循环的转换率。本文的研究成果为今后研究从突变动物模型或人体活组织中设计或纯化的肌球蛋白分子集合的新机械动力学特性奠定了基础。

本文章由计算机程序翻译，如有差异，请以英文原文为准。

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arXiv - QuanBio - Tissues and Organs

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