分化的心肌细胞中完整的 DNA 修复是小鼠在压力超负荷时维持心脏功能的必要条件

IF 5.3 2区 医学 Q1 PHYSIOLOGY
Martine de Boer, J. H. Hoeijmakers, D. J. Duncker
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引用次数: 0

摘要

引言每个细胞中的 DNA 都会不断受损,而 DNA 修复机制对于防止 DNA 损伤引起的衰老相关疾病至关重要。例如,在心肌细胞限制性失活的 Xpg 小鼠中,内源性 DNA 损伤的修复不足与进行性心力衰竭有关(de Boer 等,《衰老细胞》,2023 年)。在此,我们测试了一个假设,即分化的心肌细胞中未修复的 DNA 损伤会增加心脏对血流动力学超负荷的脆弱性。方法:8周大时,αMHC-Xpgc/-小鼠和对照组(Ctrl)小鼠通过轻度横主动脉收缩(TAC)承受压力过载。TAC八周后,使用超声心动图和血液动力学测量评估左心室(LV)功能,然后进行组织学和分子分析。研究结果心肌细胞限制性失活Xpg导致左心室收缩和舒张功能障碍。TAC诱导的左心室肥厚在两组中相似(Ctrl组为38%;αMHC-Xpgc/-组为34%)。在 Ctrl 组小鼠中,左心室肥厚伴随着极小的左心室扩张,左心室收缩和舒张功能变化不大。相反,αMHC-Xpgc/-小鼠的 TAC 会导致严重的左心室扩张和功能障碍,并导致明显的后向衰竭,表现为左心室舒张末期压力、左心房重量和肺液重量明显增加。伴随这些变化的是肥大标记基因心房利钠肽和β肌球蛋白重链表达水平的进一步升高。此外,凝集素染色显示毛细血管密度下降,TUNEL染色显示与Ctrl-TAC小鼠相比,αMHC-Xpgc/-TAC小鼠的心肌凋亡水平进一步升高。此外,在αMHC-Xpgc/--TAC小鼠中观察到心肌胶原蛋白含量明显增加,而在Ctrl-TAC小鼠中则没有发现。结论心肌细胞受限 DNA 修复蛋白 Xpg 的缺失增加了心脏在压力过载时发生心力衰竭的脆弱性。这些发现强调了基因组稳定性对维持心脏功能的重要性,不仅在基础条件下如此,在心脏负荷增加的条件下也是如此。本文由荷兰心脏基金会资助[资助号:2017B018-ARENA-PRIME;2021B008-RECONNEXT]。本文是在 2024 年美国生理学峰会上发表的摘要全文,仅提供 HTML 格式。本摘要没有附加版本或附加内容。生理学》未参与同行评审过程。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Intact DNA Repair in Differentiated Cardiomyocytes Is Essential for Maintaining Cardiac Function in Response to Pressure Overload in Mice
Introduction: DNA in every cell is continuously damaged and DNA repair mechanisms are essential for protection against DNA damage-induced aging-related diseases. For example, deficient repair of endogenously generated DNA damage in mice with cardiomyocyte-restricted inactivation of Xpg, is associated with progressive heart failure (de Boer et al. Aging Cell 2023). Here we tested the hypothesis that unrepaired DNA damage in differentiated cardiomyocytes increases cardiac vulnerability in response to hemodynamic overload. Methods: At 8 weeks of age, αMHC-Xpgc/- and control (Ctrl) mice were subjected to pressure overload by mild transverse aortic constriction (TAC). Eight weeks after TAC, left ventricular (LV) function was assessed using echocardiography and hemodynamic measurements, followed by histological and molecular analyses. Results: Cardiomyocyte-restricted inactivation of Xpg resulted in systolic as well as diastolic LV dysfunction. TAC-induced LV hypertrophy was similar in both groups (Ctrl 38%; αMHC-Xpgc/- 34%). In Ctrl mice, LV hypertrophy was accompanied by minimal LV dilation and only modest changes in systolic and diastolic LV function. Conversely, TAC in αMHC-Xpgc/- produced severe LV dilation and dysfunction and resulted in overt backward failure, demonstrated by marked increases in LV end-diastolic pressure, left atrial weight and lung fluid weight. These changes were accompanied by further increases in the expression levels of the hypertrophic marker genes atrial natriuretic peptide and beta-myosin heavy chain. Moreover, lectin staining revealed a decrease in capillary density and TUNEL staining revealed further elevated levels of myocardial apoptosis in αMHC-Xpgc/--TAC mice as compared to Ctrl-TAC mice. In addition, a significant increase of myocardial collagen content was observed in αMHC-Xpgc/--TAC but not in Ctrl-TAC mice. Conclusion: Cardiomyocyte-restricted loss of DNA repair protein Xpg increases cardiac vulnerability to develop heart failure in response to pressure-overload. These findings underscore the importance of genomic stability for maintenance of cardiac function, not only under basal conditions, but also during increased cardiac loading conditions. Supported by the Dutch Heart Foundation [Grants 2017B018-ARENA-PRIME; 2021B008-RECONNEXT]. This is the full abstract presented at the American Physiology Summit 2024 meeting and is only available in HTML format. There are no additional versions or additional content available for this abstract. Physiology was not involved in the peer review process.
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来源期刊
Physiology
Physiology 医学-生理学
CiteScore
14.50
自引率
0.00%
发文量
37
期刊介绍: Physiology journal features meticulously crafted review articles penned by esteemed leaders in their respective fields. These articles undergo rigorous peer review and showcase the forefront of cutting-edge advances across various domains of physiology. Our Editorial Board, comprised of distinguished leaders in the broad spectrum of physiology, convenes annually to deliberate and recommend pioneering topics for review articles, as well as select the most suitable scientists to author these articles. Join us in exploring the forefront of physiological research and innovation.
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