The role of the Cockayne syndrome proetin

科凯恩综合征蛋白的作用

• 批准号: 8335903
• 负责人: Vilhelm A Bohr
• 金额: $ 31.85万
• 依托单位: NATIONAL INSTITUTE ON AGING
• 依托单位国家: 美国
• 资助国家: 美国
• 起止时间: 至
• 项目状态: 未结题
• 来源: https://reporter.nih.gov/project-details/8335903
• 关键词: 8-hydroxyadenine; 8-hydroxyguanosine; ATP phosphohydrolase; Aging; Aging-Related Process; Autophagocytosis; Base Excision Repairs; Bioenergetics; Biological Models; Brain; Cachexia; Cells; Cockayne Syndrome; Complex; DNA; DNA Damage; DNA Excision Repair Protein ERCC-6; DNA Repair Pathway; DNA glycosylase; Disease; Excision; Guanine; Inner mitochondrial membrane; Lesion; Lyase; Membrane; Mitochondria; Mitochondrial DNA; Mus; Mutation; Nerve Degeneration; Nuclear; Nucleotide Excision Repair; OGG1 gene; Oxidative Stress; Pathology; Pathway interactions; Patients; Play; Premature aging syndrome; Process; Proteins; Recruitment Activity; Repair Complex; Role; Single Strand Break Repair; Surgical incisions; Syndrome; Tissues; Transcription-Coupled Repair; Type II Cockayne Syndrome; Uracil; Vitamin K 3; aged; base; brain tissue; cell type; early onset; helicase; in vivo; mitochondrial DNA mutation; oxidative DNA damage; protein B; protein function; repaired; response

In CS cells, there are deficiencies in the repair of oxidative DNA damage in the nuclear and mitochondrial DNA, and this may be a major underlying cause of the disease. Previously we found that CSB-deficient cells accumulate oxidized bases, 8-hydroxyguanine and 8-hydroxyadenine, after oxidative stress, consistent with the observation that CSB and oxoguanine DNA glycosylase (OGG1), the major DNA glycosylase for 8-oxoG repair, are in a complex in vivo. We also found that the CSB protein physically interacts with the Nei-like DNA glycosylase, NEIL1, which is also involved in the repair of oxidized bases. This interaction significantly stimulates NEIL1 catalytic activities, both the glycosylase and the AP-lyase. The observation that CSB-deficient mice accumulate significantly higher levels of several oxidized DNA bases in brain tissue, including fapyadenine and fapyguanine, supports a role for the CSB protein in the removal of oxidized lesions in vivo. Previously we demonstrated that the CSB protein also interacts with PARP1, a protein involved in the early steps of single-strand break repair, and that these two proteins cooperate in the cellular responses to oxidative stress. CSB is a substrate for PARP-1 ribosylation and it is likely that these two proteins function together in the process of base excision. Our results indicate that the CSB protein plays an important role in the repair of oxidative DNA damage and that accumulation of unrepaired lesions, particular in target tissues, like the brain, may be relevant to the CS pathology, which is characterized by severe early onset neurodegeneration. To further explore the role of CSB in mitochondria, we evaluated the mitochondrial localization of CSB following oxidative stress. We found increased CSB localization to mitochondria following menadione treatment, which causes a form of oxidative stress. Additionally, we found reduced 8-oxo-guanine, uracil, and 5-hydroxy-uracil incision activities in CSB-deficient cells compared to wild-type cells. This deficiency correlated with a loss of mitochondrial inner membrane associated BER activities. These CSB-dependent changes had a functional consequence because we observed elevated mtDNA mutations in CSB deficient cells. Together the results suggest that CSB plays a direct role in mitochondrial BER by helping to recruit, stabilize, and/or retain BER proteins in repair complexes that in mitochondria are associated with the inner membrane. Not only does CSB play a role in mtDNA repair, we are also pursuing the proposal that CSB functions in mitochondria to modulate mitochondrial quality and thereby mitochondrial bioenergetics. We have shown that aged CSBm/m mice display cachexia and altered mitochondrial bioenergetic profiles than their WT counterparts. We presently are exploring the role of CSB in autophagy.

在CS细胞中，核和线粒体DNA中的氧化DNA损伤修复存在缺陷，这可能是疾病的主要潜在原因。以前，我们发现，CSB缺陷细胞积累氧化的碱基，8-羟基鸟嘌呤和8-羟基腺嘌呤，氧化应激后，与观察到的CSB和氧代鸟嘌呤DNA糖基化酶（OGG 1），主要的DNA糖基化酶8-oxoG修复，在体内是一个复杂的一致。我们还发现CSB蛋白与Nei样DNA糖基化酶NEIL 1发生物理相互作用，NEIL 1也参与氧化碱基的修复。这种相互作用显着刺激NEIL 1的催化活性，无论是糖基化酶和AP-裂解酶。观察到CSB缺陷小鼠在脑组织中积累了显著更高水平的几种氧化DNA碱基，包括fapyadenine和fapyguanine，这支持了CSB蛋白在体内去除氧化损伤中的作用。 以前，我们证明了CSB蛋白也与PARP 1相互作用，PARP 1是一种参与单链断裂修复早期步骤的蛋白质，并且这两种蛋白质在细胞对氧化应激的反应中相互作用。CSB是PARP-1核糖基化的底物，并且这两种蛋白质可能在碱基切除过程中一起起作用。我们的研究结果表明，CSB蛋白在氧化性DNA损伤的修复中起着重要作用，并且未修复病变的积累，特别是在靶组织中，如大脑，可能与CS病理学有关，其特征在于严重的早发性神经变性。 为了进一步探讨CSB在线粒体中的作用，我们评估了CSB在氧化应激后的线粒体定位。我们发现甲萘醌治疗后CSB定位于线粒体的增加，这会导致一种形式的氧化应激。此外，我们发现与野生型细胞相比，CSB缺陷细胞中的8-氧代-鸟嘌呤、尿嘧啶和5-羟基-尿嘧啶切割活性降低。这种缺陷与线粒体内膜相关BER活性的丧失相关。这些CSB依赖性变化具有功能性后果，因为我们观察到CSB缺陷细胞中mtDNA突变升高。总之，结果表明，CSB在线粒体BER中起着直接的作用，通过帮助招募，稳定和/或保留BER蛋白在线粒体中与内膜相关的修复复合物。CSB不仅在线粒体DNA修复中发挥作用，我们还在寻求CSB在线粒体中发挥作用以调节线粒体质量从而调节线粒体生物能量学的建议。我们已经表明，老年CSBm/m小鼠表现出恶病质和改变线粒体生物能量谱比他们的WT对应。我们目前正在探索CSB在自噬中的作用。