通过组蛋白动力学,细胞核新生NAD+合成对细胞衰老过程中DNA修复的影响,以防止肿瘤发生。

IF 4.3 3区 材料科学 Q1 ENGINEERING, ELECTRICAL & ELECTRONIC
Masae Ikura, Kanji Furuya, Tomonari Matsuda, Tsuyoshi Ikura
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引用次数: 1

摘要

NAD+的合成是活细胞的一个基本过程。局部代谢物对染色质的影响影响染色质在DNA代谢中的表观遗传状态。我们之前已经证明,TIP60对H2AX的K5乙酰化是PARP-1的ADP核糖基化活性和组蛋白H2AX在DNA损伤位点交换所必需的。然而,其具体的分子机制尚不清楚。在这里,我们发现新生的NAD合成酶1 (NAD syn1)是H2AX的一个新的结合伙伴。NAD syn1的酶活性对于DNA损伤位点上PARP-1的ADP核糖基化活性至关重要。抑制细胞核内NAD合成酶活性可降低细胞内NAD+浓度,导致细胞衰老。因此,乙酰化依赖性的H2AX动力学和同源重组修复被抑制,导致肿瘤发生增加。我们的研究结果揭示了细胞核中新生NAD+的产生对防止细胞衰老引起的DNA修复能力下降的重要性,从而防止肿瘤发生。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
Impact of Nuclear De Novo NAD+ Synthesis via Histone Dynamics on DNA Repair during Cellular Senescence To Prevent Tumorigenesis.

NAD+ synthesis is a fundamental process in living cells. The effects of local metabolite production on chromatin influence the epigenetic status of chromatin in DNA metabolism. We have previously shown that K5 acetylation of H2AX by TIP60 is required for the ADP ribosylation activity of PARP-1, for histone H2AX exchange at DNA damage sites. However, the detailed molecular mechanism has remained unclear. Here, we identified de novo NAD synthetase 1 (NAD syn1) as a novel binding partner to H2AX. The enzymatic activity of NAD syn1 is crucial for the ADP ribosylation activity of PARP-1 for the H2AX dynamics at sites of DNA damage. Inhibition of the NAD synthetase activity in the cell nucleus decreased the overall cellular NAD+ concentration, leading to cellular senescence. Accordingly, the acetylation-dependent H2AX dynamics and homologous recombination repair were suppressed, leading to increased tumorigenesis. Our findings have revealed the importance of de novo NAD+ production in the cell nucleus for protection against the decreased DNA repair capacity caused by cellular senescence and thus against tumorigenesis.

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来源期刊
CiteScore
7.20
自引率
4.30%
发文量
567
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