Causes and consequences of DNA double-stranded breaks in cardiovascular disease.

IF 3.5 2区 生物学 Q3 CELL BIOLOGY Molecular and Cellular Biochemistry Pub Date : 2024-10-15 DOI:10.1007/s11010-024-05131-9
A J Marian
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Abstract

The genome, whose stability is essential for survival, is incessantly exposed to internal and external stressors, which introduce an estimated 104 to 105 lesions, such as oxidation, in the nuclear genome of each mammalian cell each day. A delicate homeostatic balance between the generation and repair of DNA lesions maintains genomic stability. To initiate transcription, DNA strands unwind to form a transcription bubble and provide a template for the RNA polymerase II (RNAPII) complex to synthesize nascent RNA. The process generates DNA supercoils and introduces torsional stress. To enable RNAPII processing, the supercoils are released by topoisomerases by introducing strand breaks, including double-stranded breaks (DSBs). Thus, DSBs are intrinsic genomic features of gene expression. The breaks are quickly repaired upon processing of the transcription. DNA lesions and damaged proteins involved in transcription could impede the integrity and efficiency of RNAPII processing. The impediment, which is referred to as transcription stress, not only could lead to the generation of aberrant RNA species but also the accumulation of DSBs. The latter is particularly the case when topoisomerase processing and/or the repair mechanisms are compromised. The DSBs activate the DNA damage response (DDR) pathways to repair the damaged DNA and/or impose cell cycle arrest and cell death. In addition, the release of DSBs into the cytosol activates the cytosolic DNA-sensing proteins (CDSPs), which along with the nuclear DDR pathways induce the expression of senescence-associated secretory phenotype (SASP), cell cycle arrest, senescence, cell death, inflammation, and aging. The primary stimulus in hereditary cardiomyopathies is a mutation(s) in genes encoding the protein constituents of cardiac myocytes; however, the phenotype is the consequence of intertwined complex interactions among numerous stressors and the causal mutation(s). Increased internal DNA stressors, such as oxidation, alkylation, and cross-linking, are expected to be common in pathological conditions, including in hereditary cardiomyopathies. In addition, dysregulation of gene expression also imposes transcriptional stress and collectively with other stressors provokes the generation of DSBs. In addition, the depletion of nicotinamide adenine dinucleotide (NAD), which occurs in pathological conditions, impairs the repair mechanism and further facilitates the accumulation of DSBs. Because DSBs activate the DDR pathways, they are expected to contribute to the pathogenesis of cardiomyopathies. Thus, interventions to reduce the generation of DSBs, enhance their repair, and block the deleterious DDR pathways would be expected to impart salubrious effects not only in pathological states, as in hereditary cardiomyopathies but also aging.

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心血管疾病中 DNA 双链断裂的原因和后果。
基因组的稳定性对生存至关重要,但基因组不断受到内部和外部压力的影响,估计每个哺乳动物细胞的核基因组每天会产生 104 到 105 个病变,如氧化。DNA 损伤的产生和修复之间的微妙平衡维持着基因组的稳定。启动转录时,DNA 链会松开形成转录泡,为 RNA 聚合酶 II(RNAPII)复合体合成新生 RNA 提供模板。这一过程会产生 DNA 超螺旋并带来扭转应力。为了使 RNAPII 能够进行处理,拓扑异构酶会通过引入链断裂(包括双链断裂(DSB))来释放超螺旋。因此,DSB 是基因表达的内在基因组特征。在转录处理过程中,断裂会被迅速修复。DNA 损伤和参与转录的受损蛋白质可能会妨碍 RNAPII 处理的完整性和效率。这种障碍被称为转录应激,它不仅会导致异常 RNA 的产生,还会导致 DSB 的积累。当拓扑异构酶处理和/或修复机制受到损害时,后者的情况尤为严重。DSB会激活DNA损伤应答(DDR)途径,以修复受损的DNA和/或导致细胞周期停滞和细胞死亡。此外,DSBs 释放到细胞质中会激活细胞质 DNA 感蛋白(CDSPs),CDSPs 与核 DDR 通路一起诱导衰老相关分泌表型(SASP)的表达、细胞周期停滞、衰老、细胞死亡、炎症和衰老。遗传性心肌病的主要刺激因素是编码心肌细胞蛋白质成分的基因发生突变;然而,这种表型是众多应激源和诱因突变之间相互交织的复杂相互作用的结果。氧化、烷基化和交联等 DNA 内部应激因素的增加预计在病理情况下很常见,包括在遗传性心肌病中。此外,基因表达失调也会造成转录应激,并与其他应激源共同引发 DSB 的产生。此外,病理情况下出现的烟酰胺腺嘌呤二核苷酸(NAD)耗竭也会损害修复机制,进一步促进DSB的积累。由于DSB会激活DDR途径,因此预计它们会导致心肌病的发病机制。因此,减少DSB的产生、加强DSB的修复和阻断有害的DDR途径的干预措施,不仅会对病理状态(如遗传性心肌病)产生有益的影响,而且也会对衰老产生有益的影响。
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来源期刊
Molecular and Cellular Biochemistry
Molecular and Cellular Biochemistry 生物-细胞生物学
CiteScore
8.30
自引率
2.30%
发文量
293
审稿时长
1.7 months
期刊介绍: Molecular and Cellular Biochemistry: An International Journal for Chemical Biology in Health and Disease publishes original research papers and short communications in all areas of the biochemical sciences, emphasizing novel findings relevant to the biochemical basis of cellular function and disease processes, as well as the mechanics of action of hormones and chemical agents. Coverage includes membrane transport, receptor mechanism, immune response, secretory processes, and cytoskeletal function, as well as biochemical structure-function relationships in the cell. In addition to the reports of original research, the journal publishes state of the art reviews. Specific subjects covered by Molecular and Cellular Biochemistry include cellular metabolism, cellular pathophysiology, enzymology, ion transport, lipid biochemistry, membrane biochemistry, molecular biology, nuclear structure and function, and protein chemistry.
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