Cellular and molecular contractile function in aged human skeletal muscle is altered by phosphate and acidosis and partially reversed with an ATP analog.

IF 5 2区生物学 Q2 CELL BIOLOGY

American journal of physiology. Cell physiology Pub Date : 2025-04-01 Epub Date: 2025-03-06 DOI:10.1152/ajpcell.00332.2024

Aurora D Foster, Chad R Straight, Philip C Woods, Christopher Lee, Jane A Kent, Stuart R Chipkin, Edward P Debold, Mark S Miller

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引用次数: 0

Abstract

Skeletal muscle fatigue occurs, in part, from the accumulation of hydrogen (H⁺) and phosphate (P_i); however, the molecular basis through which these ions inhibit function is not fully understood. Therefore, we examined the effects of these metabolites on myosin-actin cross-bridge kinetics and mechanical properties in skeletal muscle fibers from older (65-75 yr) adults. Slow-contracting myosin heavy chain (MHC) I and fast-contracting MHC IIA fibers were examined under control (5 mM P_i, pH 7.0) and fatigue (30 mM P_i, pH 6.2) conditions at maximal calcium-activation [5 mM adenosine triphosphate (ATP)] and rigor (0 mM ATP). In MHC I and IIA fibers, fatigue decreased force per fiber size (23%-37%), which was accompanied by reduced strongly bound myosin head characteristics (number and/or stiffness; 21%-47%) and slower cross-bridge kinetics [longer myosin attachment times (22%-46%) and reduced rates of force production (20%-33%)] compared with control. MHC I myofilaments became stiffer with fatigue, a potential mechanism to increase force production. In rigor, which causes the myosin that can bind actin to be strongly bound, fatigue decreased force per fiber size (32%-33%) in MHC I and IIA fibers, indicating less force was generated per cross bridge. By replacing ATP with 2-deoxy-ATP, the fatigue-induced slowing of cross-bridge kinetics in MHC I and IIA fibers was reversed, and reduced force production in MHC I fibers was partially improved, revealing potential mechanisms to help mitigate fatigue in older adults. Overall, our results identify novel fiber type-specific changes in cross-bridge kinetics, force per cross bridge, and myofilament stiffness that help explain fatigue in older adults.NEW & NOTEWORTHY Skeletal muscle fatigue is caused, in part, by increased production of phosphate and hydrogen ions, resulting in decreased force generation. We found that reduced force in fibers from older adults was due to altered function of myosin and actin, including slower protein interactions and reduced force per myosin head. Additionally, an ATP analog, dATP, partially reversed contractile dysfunction induced by increased phosphate and hydrogen, improving force production and altering myosin-actin interactions dependent upon fiber type.

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磷酸和酸中毒改变了老年人类骨骼肌的细胞和分子收缩功能，并通过ATP类似物部分逆转。

骨骼肌疲劳的发生，部分是由于氢（H+）和磷酸盐（Pi）的积累；然而，通过这些离子抑制功能的分子基础尚未完全了解。因此，我们研究了这些代谢物对老年（65-75岁）成年人骨骼肌纤维中肌球蛋白-肌动蛋白过桥动力学和力学特性的影响。慢收缩肌球蛋白重链（MHC） I和快收缩MHC IIA纤维在控制（5 mM Pi, pH 7.0）和疲劳（30 mM Pi, pH 6.2）条件下，在最大钙活化（5 mM ATP）和严格（0 mM ATP）条件下进行检测。在MHC I和IIA纤维中，疲劳降低了每个纤维尺寸的力（23-37%），这伴随着强结合肌球蛋白头特征(数量和/或刚度；21-47%)和较慢的过桥动力学（更长的肌球蛋白附着时间（22-46%）和降低的力产生率（20-33%））。MHC I肌丝随着疲劳而变硬，这是一种增加力量产生的潜在机制。在僵硬状态下，可以结合肌动蛋白的肌球蛋白被强烈结合，疲劳使MHC I和IIA纤维的每根纤维尺寸的力降低（32-33%），表明每个交叉桥产生的力减少。通过用2-脱氧ATP （dATP）替代ATP，可以逆转MHC I和IIA纤维疲劳引起的过桥动力学减慢，MHC I纤维的力产生减少得到部分改善，揭示了帮助缓解老年人疲劳的潜在机制。总的来说，我们的研究结果确定了新的纤维类型特异性变化，包括跨桥动力学、跨桥力和肌丝刚度，这有助于解释老年人的疲劳。

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来源期刊

American journal of physiology. Cell physiology 生物-生理学

CiteScore

9.10

自引率

1.80%

发文量

252

审稿时长

1 months

期刊介绍： The American Journal of Physiology-Cell Physiology is dedicated to innovative approaches to the study of cell and molecular physiology. Contributions that use cellular and molecular approaches to shed light on mechanisms of physiological control at higher levels of organization also appear regularly. Manuscripts dealing with the structure and function of cell membranes, contractile systems, cellular organelles, and membrane channels, transporters, and pumps are encouraged. Studies dealing with integrated regulation of cellular function, including mechanisms of signal transduction, development, gene expression, cell-to-cell interactions, and the cell physiology of pathophysiological states, are also eagerly sought. Interdisciplinary studies that apply the approaches of biochemistry, biophysics, molecular biology, morphology, and immunology to the determination of new principles in cell physiology are especially welcome.