USP20 deletion promotes eccentric cardiac remodeling in response to pressure overload and increases mortality.

IF 4.1 2区 医学 Q1 CARDIAC & CARDIOVASCULAR SYSTEMS American journal of physiology. Heart and circulatory physiology Pub Date : 2024-11-01 Epub Date: 2024-10-04 DOI:10.1152/ajpheart.00329.2024
Pierre-Yves Jean-Charles, Bipradas Roy, Samuel Mon-Wei Yu, Gianluigi Pironti, Karim Nagi, Lan Mao, Suneet Kaur, Dennis M Abraham, Stuart Maudsley, Howard A Rockman, Sudha K Shenoy
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Abstract

Left ventricular hypertrophy (LVH) caused by chronic pressure overload with subsequent pathological remodeling is a major cardiovascular risk factor for heart failure and mortality. The role of deubiquitinases in LVH has not been well characterized. To define whether the deubiquitinase ubiquitin-specific peptidase 20 (USP20) regulates LVH, we subjected USP20 knockout (KO) and cognate wild-type (WT) mice to chronic pressure overload by transverse aortic constriction (TAC) and measured changes in cardiac function by serial echocardiography followed by histological and biochemical evaluations. USP20-KO mice showed severe deterioration of systolic function within 4 wk of TAC compared with WT cohorts. Both USP20-KO TAC and WT-TAC cohorts presented cardiac hypertrophy following pressure overload. However, USP20-KO-TAC mice showed an increase in cardiomyocyte length and developed maladaptive eccentric hypertrophy, a phenotype generally observed with volume overload states and decompensated heart failure. In contrast, WT-TAC mice displayed an increase in cardiomyocyte width, producing concentric remodeling that is characteristic of pressure overload. In addition, cardiomyocyte apoptosis, interstitial fibrosis, and mouse mortality were augmented in USP20-KO-TAC compared with WT-TAC mice. Quantitative mass spectrometry of LV tissue revealed that the expression of sarcomeric myosin heavy chain 7 (MYH7), a fetal gene normally upregulated during cardiac remodeling, was significantly reduced in USP20-KO after TAC. Mechanistically, we identified increased degradative lysine-48 polyubiquitination of MYH7 in USP20-KO hearts, indicating that USP20-mediated deubiquitination likely prevents protein degradation of MYH7 during pressure overload. Our findings suggest that USP20-dependent signaling pathways regulate the layering pattern of sarcomeres to suppress maladaptive remodeling during chronic pressure overload and prevent cardiac failure.NEW & NOTEWORTHY We identify ubiquitin-specific peptidase 20 (USP20) as an important enzyme that is required for cardiac homeostasis and function, particularly during myocardial pressure overload. USP20 regulates protein stability of cardiac MYH7, an essential molecular motor protein expressed in sarcomeres; loss-of-function mutations of MYH7 are associated with human hypertrophic cardiomyopathy, cardiac failure, and sudden death. Enhancing USP20 activity could be a potential therapeutic approach to prevent the development of maladaptive state of eccentric hypertrophy and heart failure.

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Usp20 基因缺失会在压力过载时促进偏心性心脏重塑,并增加死亡率。
慢性压力超负荷引起的左心室肥厚(LVH)以及随后的病理重塑是导致心力衰竭和死亡的主要心血管风险因素。去泛素酶在左心室肥厚中的作用尚未得到很好的描述。为了确定泛素特异性肽酶 20(USP20)是否调节 LVH,我们通过横向主动脉收缩(TAC)使 USP20 基因敲除(KO)小鼠和同源野生型(WT)小鼠承受慢性压力过载,并通过连续超声心动图测量心脏功能的变化,然后进行组织学和生化评估。与 WT 小鼠相比,USP20-KO 小鼠在 TAC 后 4 周内的收缩功能严重恶化。USP20-TAC 和 WT-TAC 组群在压力过载后都出现了心脏肥大。然而,USP20-KO-TAC 小鼠的心肌细胞长度增加,并出现适应不良的偏心性肥大,这是容量过载状态和失代偿性心力衰竭时通常会出现的表型。与此相反,WT-TAC 小鼠的心肌细胞宽度增加,产生了压力过载所特有的同心重塑。此外,与 WT-TAC 小鼠相比,USP20-KO-TAC 小鼠的心肌细胞凋亡、间质纤维化和小鼠死亡率都有所增加。左心室组织的定量质谱分析表明,在 TAC 后,USP20-KO 中肉瘤肌球蛋白重链 7 (MYH7) 的表达显著降低,而 MYH7 是一种在心脏重塑过程中正常上调的胎儿基因。从机理上讲,我们发现 USP20-KO 心脏中 MYH7 的赖氨酸-48 多泛素降解增加,这表明 USP20 介导的去泛素化可能会阻止 MYH7 在压力过载期间的蛋白降解。我们的研究结果表明,依赖于 USP20 的信号通路可调节肌节的分层模式,从而抑制慢性压力过载期间的不良重塑,预防心力衰竭。
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来源期刊
CiteScore
9.60
自引率
10.40%
发文量
202
审稿时长
2-4 weeks
期刊介绍: The American Journal of Physiology-Heart and Circulatory Physiology publishes original investigations, reviews and perspectives on the physiology of the heart, vasculature, and lymphatics. These articles include experimental and theoretical studies of cardiovascular function at all levels of organization ranging from the intact and integrative animal and organ function to the cellular, subcellular, and molecular levels. The journal embraces new descriptions of these functions and their control systems, as well as their basis in biochemistry, biophysics, genetics, and cell biology. Preference is given to research that provides significant new mechanistic physiological insights that determine the performance of the normal and abnormal heart and circulation.
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