Shazia Ashraf, Neha Deshpande, Queenie Cheung, Jeffrey Boakye Asabere, Raymond Jeff Wong, Alex G Gauthier, Mohit Parekh, Yadav Adhikari, Geetha Melangath, Ula V Jurkunas
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引用次数: 0
摘要
富克斯内皮性角膜营养不良症(FECD)是一种衰老性疾病,其特征是角膜内皮细胞(CEnCs)加速丧失,与正常的CEnCs相比,DNA损伤加剧。我们以前曾在一个非遗传小鼠模型中证实,紫外线 A(UVA)光会导致 DNA 损伤并导致 FECD 表型。在这里,我们证明了与正常 CEnCs 相比,用化学应激源 menadione 或生理应激源 UVA 和儿茶酚雌激素(4-OHE2)进行急性处理会导致 FECD 早期激活 ATM 介导的 DNA 损伤反应。与 NQO1+/+ 细胞相比,UVA 和 4-OHE2 的急性应激会导致 (i) 更大的细胞周期停滞和 G2/M 期的 DNA 修复,以及 (ii) 更大的细胞保护性衰老,这种衰老在抑制 ATM 后被逆转。UVA和4OHE2的慢性应激会导致ATM驱动的细胞周期停滞在G0/G1期,DNA修复能力降低,并由于持续损伤而导致细胞毒性衰老。同样,在Atm-null小鼠中,UVA诱导的细胞周期重入、γ-H2AX病灶和衰老相关异染色质也减少了。值得注意的是,在缺乏 NQO1 的 FECD 慢性细胞模型中,用 KU-55933 抑制 ATM 的活化可恢复 G2/M 期的 DNA 修复并减轻衰老。这项研究为了解ATM在氧化应激性疾病(如FECD)中调节细胞周期、DNA修复和衰老的关键作用提供了见解。
Modulation of ATM enhances DNA repair in G2/M phase of cell cycle and averts senescence in Fuchs endothelial corneal dystrophy.
Fuchs Endothelial Corneal Dystrophy (FECD) is an aging disorder characterized by expedited loss of corneal endothelial cells (CEnCs) and heightened DNA damage compared to normal CEnCs. We previously established that ultraviolet-A (UVA) light causes DNA damage and leads to FECD phenotype in a non-genetic mouse model. Here, we demonstrate that acute treatment with chemical stressor, menadione, or physiological stressors, UVA, and catechol estrogen (4-OHE2), results in an early and increased activation of ATM-mediated DNA damage response in FECD compared to normal CEnCs. Acute stress with UVA and 4OHE2 causes (i) greater cell-cycle arrest and DNA repair in G2/M phase, and (ii) greater cytoprotective senescence in NQO1-/- compared to NQO1+/+ cells, which was reversed upon ATM inhibition. Chronic stress with UVA and 4OHE2 results in ATM-driven cell-cycle arrest in G0/G1 phase, reduced DNA repair, and cytotoxic senescence, due to sustained damage. Likewise, UVA-induced cell-cycle reentry, gamma-H2AX foci, and senescence-associated heterochromatin were reduced in Atm-null mice. Remarkably, inhibiting ATM activation with KU-55933 restored DNA repair in G2/M phase and attenuated senescence in chronic cellular model of FECD lacking NQO1. This study provides insights into understanding the pivotal role of ATM in regulating cell-cycle, DNA repair, and senescence, in oxidative-stress disorders like FECD.
期刊介绍:
Communications Biology is an open access journal from Nature Research publishing high-quality research, reviews and commentary in all areas of the biological sciences. Research papers published by the journal represent significant advances bringing new biological insight to a specialized area of research.
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