Ahmad Besaratinia, Andrew W Caliri, Stella Tommasi
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There was a distinct interconnection between Ogg1 and Polβ expression and DNA damage formation and repair whereby changes in expression of these two genes were proportionate to the levels of oxidative DNA damage, once a 3-plus hour lag time passed (P < .05). Equally notable was the matching pattern of Polκ expression and kinetics of oxidative DNA damage and repair (P < .05). The DNA damage and gene expression data were remarkably consistent with mutagenicity data in the treated cells; the induced mutation spectrum is indicative of erroneous bypass of oxidized DNA bases and incorporation of oxidized deoxynucleoside triphosphates during replication of the genomic DNA. Our findings support follow-up functional studies to elucidate how oxidation of DNA bases and the nucleotide pool, overexpression of Polκ, delayed upregulation of Ogg1 and Polβ, and inadequate expression of Nudt1 and Mutyh collectively affect mutagenesis consequent to oxidative stress.</p>","PeriodicalId":9446,"journal":{"name":"Carcinogenesis","volume":" ","pages":"868-879"},"PeriodicalIF":3.3000,"publicationDate":"2024-11-22","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"https://www.ncbi.nlm.nih.gov/pmc/articles/PMC11584291/pdf/","citationCount":"0","resultStr":"{\"title\":\"The interplay of DNA damage and repair, gene expression, and mutagenesis in mammalian cells during oxidative stress.\",\"authors\":\"Ahmad Besaratinia, Andrew W Caliri, Stella Tommasi\",\"doi\":\"10.1093/carcin/bgae046\",\"DOIUrl\":null,\"url\":null,\"abstract\":\"<p><p>We investigated the interplay among oxidative DNA damage and repair, expression of genes encoding major base excision repair (BER) enzymes and bypass DNA polymerases, and mutagenesis in mammalian cells. Primary mouse embryonic fibroblasts were challenged with oxidative stress induced by methylene blue plus visible light, and formation and repair of DNA damage, changes in gene expression, and mutagenesis were determined at increasing intervals posttreatment (0-192 hours). Significant formation of oxidative DNA damage together with upregulation of Ogg1, Polβ, and Polκ, and no changes in Mutyh and Nudt1 expression were found in treated cells. There was a distinct interconnection between Ogg1 and Polβ expression and DNA damage formation and repair whereby changes in expression of these two genes were proportionate to the levels of oxidative DNA damage, once a 3-plus hour lag time passed (P < .05). Equally notable was the matching pattern of Polκ expression and kinetics of oxidative DNA damage and repair (P < .05). The DNA damage and gene expression data were remarkably consistent with mutagenicity data in the treated cells; the induced mutation spectrum is indicative of erroneous bypass of oxidized DNA bases and incorporation of oxidized deoxynucleoside triphosphates during replication of the genomic DNA. 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引用次数: 0
摘要
我们研究了哺乳动物细胞中 DNA 氧化损伤和修复、编码主要碱基切除修复(BER)酶和旁路 DNA 聚合酶的基因表达以及诱变之间的相互作用。原代小鼠胚胎成纤维细胞受到亚甲基蓝和可见光诱导的氧化应激的挑战,并在处理后增加的时间间隔(0 - 192 小时)内测定 DNA 损伤的形成和修复、基因表达的变化以及诱变。在处理后的细胞中,发现氧化 DNA 损伤明显形成,Ogg1、Polβ 和 Polκ 上调,而 Mutyh 和 Nudt1 的表达没有变化。Ogg1和Polβ的表达与DNA损伤的形成和修复之间存在明显的相互联系,一旦经过3个多小时的滞后期,这两个基因的表达变化与氧化性DNA损伤的水平成正比(P < 0.05)。同样值得注意的是,Polκ 的表达与氧化 DNA 损伤和修复的动力学模式相匹配(P < 0.05)。DNA 损伤和基因表达数据与处理细胞的诱变性数据明显一致;诱导的突变谱表明,在复制基因组 DNA 的过程中,氧化 DNA 碱基和氧化脱氧核苷三磷酸酯的错误绕过。我们的研究结果支持后续功能研究,以阐明 DNA 碱基和核苷酸池的氧化、Polκ 的过度表达、Ogg1 和 Polβ 的延迟上调以及 Nudt1 和 Mutyh 的表达不足如何共同影响氧化应激导致的突变。
The interplay of DNA damage and repair, gene expression, and mutagenesis in mammalian cells during oxidative stress.
We investigated the interplay among oxidative DNA damage and repair, expression of genes encoding major base excision repair (BER) enzymes and bypass DNA polymerases, and mutagenesis in mammalian cells. Primary mouse embryonic fibroblasts were challenged with oxidative stress induced by methylene blue plus visible light, and formation and repair of DNA damage, changes in gene expression, and mutagenesis were determined at increasing intervals posttreatment (0-192 hours). Significant formation of oxidative DNA damage together with upregulation of Ogg1, Polβ, and Polκ, and no changes in Mutyh and Nudt1 expression were found in treated cells. There was a distinct interconnection between Ogg1 and Polβ expression and DNA damage formation and repair whereby changes in expression of these two genes were proportionate to the levels of oxidative DNA damage, once a 3-plus hour lag time passed (P < .05). Equally notable was the matching pattern of Polκ expression and kinetics of oxidative DNA damage and repair (P < .05). The DNA damage and gene expression data were remarkably consistent with mutagenicity data in the treated cells; the induced mutation spectrum is indicative of erroneous bypass of oxidized DNA bases and incorporation of oxidized deoxynucleoside triphosphates during replication of the genomic DNA. Our findings support follow-up functional studies to elucidate how oxidation of DNA bases and the nucleotide pool, overexpression of Polκ, delayed upregulation of Ogg1 and Polβ, and inadequate expression of Nudt1 and Mutyh collectively affect mutagenesis consequent to oxidative stress.
期刊介绍:
Carcinogenesis: Integrative Cancer Research is a multi-disciplinary journal that brings together all the varied aspects of research that will ultimately lead to the prevention of cancer in man. The journal publishes papers that warrant prompt publication in the areas of Biology, Genetics and Epigenetics (including the processes of promotion, progression, signal transduction, apoptosis, genomic instability, growth factors, cell and molecular biology, mutation, DNA repair, genetics, etc.), Cancer Biomarkers and Molecular Epidemiology (including genetic predisposition to cancer, and epidemiology), Inflammation, Microenvironment and Prevention (including molecular dosimetry, chemoprevention, nutrition and cancer, etc.), and Carcinogenesis (including oncogenes and tumor suppressor genes in carcinogenesis, therapy resistance of solid tumors, cancer mouse models, apoptosis and senescence, novel therapeutic targets and cancer drugs).