YAP Overcomes Mechanical Barriers to Induce Mitotic Rounding and Adult Cardiomyocyte Division.

IF 5.2 3区 工程技术 Q2 ENERGY & FUELS Energy & Fuels Pub Date : 2024-10-11 DOI:10.1161/CIRCULATIONAHA.123.066004
Yuka Morikawa, Jong H Kim, Rich Gang Li, Lin Liu, Shijie Liu, Vaibhav Deshmukh, Matthew C Hill, James F Martin
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Abstract

Background: Many specialized cells in adult organs acquire a state of cell cycle arrest and quiescence through unknown mechanisms. Our limited understanding of mammalian cell cycle arrest is derived primarily from cell culture models. Adult mammalian cardiomyocytes, a classic example of cell cycle arrested cells, exit the cell cycle postnatally and remain in an arrested state for the life of the organism. Cardiomyocytes can be induced to re-enter the cell cycle by YAP5SA, an active form of the Hippo signaling pathway effector YAP.

Methods: We performed clonal analyses to determine the cell kinetics of YAP5SA cardiomyocytes. We also performed single-cell RNA sequencing, marker gene analysis, and functional studies to examine how YAP5SA cardiomyocytes progress through the cell cycle.

Results: We discovered that YAP5SA-expressing cardiomyocytes divided efficiently, with >20% of YAP5SA cardiomyocyte clones containing ≥2 cardiomyocytes. YAP5SA cardiomyocytes re-entered cell cycle at the G1/S transition and had an S phase lasting ≈48 hours. Sarcomere disassembly is required for cardiomyocyte progression from S to G2 phase and the induction of mitotic rounding. Although oscillatory Cdk expression was induced in YAP5SA cardiomyocytes, these cells inefficiently progressed through G2 phase. This is improved by inhibiting P21 function, implicating checkpoint activity as an additional barrier to YAP5SA-induced cardiomyocyte division.

Conclusions: Our data reveal that YAP5SA overcomes the mechanically constrained myocardial microenvironment to induce mitotic rounding with cardiomyocyte division, thus providing new insights into the in vivo mechanisms that maintain cell cycle quiescence in adult mammals.

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YAP 克服机械障碍,诱导有丝分裂和成体心肌细胞分裂
背景:成体器官中的许多特化细胞通过未知机制获得细胞周期停滞和静止状态。我们对哺乳动物细胞周期停滞的有限了解主要来自细胞培养模型。成年哺乳动物心肌细胞是细胞周期停滞细胞的典型例子,它们在出生后退出细胞周期,并在机体的整个生命周期中保持停滞状态。YAP5SA是Hippo信号通路效应因子YAP的活性形式,可诱导心肌细胞重新进入细胞周期:我们进行了克隆分析,以确定YAP5SA心肌细胞的细胞动力学。我们还进行了单细胞RNA测序、标记基因分析和功能研究,以考察YAP5SA心肌细胞如何在细胞周期中生长:结果:我们发现,表达 YAP5SA 的心肌细胞能有效分裂,超过 20% 的 YAP5SA 心肌细胞克隆含有≥2 个心肌细胞。YAP5SA心肌细胞在G1/S转换期重新进入细胞周期,S期持续≈48小时。心肌细胞从 S 期进入 G2 期和诱导有丝分裂凋亡都需要肌节分解。虽然在 YAP5SA 心肌细胞中诱导了 Cdk 的振荡表达,但这些细胞在 G2 期的进展效率很低。抑制 P21 功能可改善这种情况,这表明检查点活性是 YAP5SA 诱导的心肌细胞分裂的另一个障碍:我们的数据揭示了 YAP5SA 克服了机械限制的心肌微环境,诱导有丝分裂轮和心肌细胞分裂,从而为了解维持成年哺乳动物细胞周期静止的体内机制提供了新的视角。
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来源期刊
Energy & Fuels
Energy & Fuels 工程技术-工程:化工
CiteScore
9.20
自引率
13.20%
发文量
1101
审稿时长
2.1 months
期刊介绍: Energy & Fuels publishes reports of research in the technical area defined by the intersection of the disciplines of chemistry and chemical engineering and the application domain of non-nuclear energy and fuels. This includes research directed at the formation of, exploration for, and production of fossil fuels and biomass; the properties and structure or molecular composition of both raw fuels and refined products; the chemistry involved in the processing and utilization of fuels; fuel cells and their applications; and the analytical and instrumental techniques used in investigations of the foregoing areas.
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