Size- and Stereochemistry-Dependent Transcriptional Bypass of DNA Alkyl Phosphotriester Adducts in Mammalian Cells.

DNA Pub Date : 2022-12-01 DOI:10.3390/dna2040016
Ying Tan, Jiabin Wu, Garrit Clabaugh, Lin Li, Hua Du, Yinsheng Wang
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引用次数: 3

Abstract

Environmental, endogenous and therapeutic alkylating agents can react with internucleotide phosphate groups in DNA to yield alkyl phosphotriester (PTE) adducts. Alkyl-PTEs are induced at relatively high frequencies and are persistent in mammalian tissues; however, their biological consequences in mammalian cells have not been examined. Herein, we assessed how alkyl-PTEs with different alkyl group sizes and stereochemical configurations (S P and R P diastereomers of Me and nPr) affect the efficiency and fidelity of transcription in mammalian cells. We found that, while the R P diastereomer of Me- and nPr-PTEs constituted moderate and strong blockages to transcription, respectively, the S P diastereomer of the two lesions did not appreciably perturb transcription efficiency. In addition, none of the four alkyl-PTEs induced mutant transcripts. Furthermore, polymerase η assumed an important role in promoting transcription across the S P-Me-PTE, but not any of other three lesions. Loss of other translesion synthesis (TLS) polymerases tested, including Pol κ, Pol ι, Pol ξ and REV1, did not alter the transcription bypass efficiency or mutation frequency for any of the alkyl-PTE lesions. Together, our study provided important new knowledge about the impact of alkyl-PTE lesions on transcription and expanded the substrate pool of Pol η in transcriptional bypass.

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哺乳动物细胞中DNA烷基磷酸三酯加合物的大小和立体化学依赖性转录旁路。
环境、内源性和治疗性烷基化剂可以与DNA中的核苷酸间磷酸基团反应生成烷基磷酸三酯(PTE)加合物。烷基pte的诱导频率相对较高,并在哺乳动物组织中持续存在;然而,它们在哺乳动物细胞中的生物学后果尚未得到检验。在此,我们评估了具有不同烷基大小和立体化学构型(Me和nPr的S P和R P非对映体)的烷基- pte如何影响哺乳动物细胞中的转录效率和保真度。我们发现,虽然Me-和npr - pte的rp非对映体分别构成中度和强烈的转录阻断,但两种病变的S P非对映体并未明显干扰转录效率。此外,四种烷基pte均未诱导突变体转录本。此外,聚合酶η在促进S - P-Me-PTE的转录中发挥了重要作用,但在其他三种病变中没有作用。其他翻译合成(TLS)聚合酶的缺失,包括Pol κ、Pol ι、Pol ξ和REV1,没有改变任何烷基pte病变的转录旁路效率或突变频率。总之,我们的研究为烷基- pte损伤对转录的影响提供了重要的新知识,并扩大了转录旁路中Pol η的底物池。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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DNA
DNA
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