The Surprising Diversity of UV-Induced Mutations

Marian F. Laughery, Hannah E. Wilson, Allysa Sewell, Scott Stevison, John J. Wyrick
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Abstract

Ultraviolet (UV) light is the most pervasive environmental mutagen and the primary cause of skin cancer. Genome sequencing of melanomas and other skin cancers has revealed that the vast majority of somatic mutations in these tumors are cytosine-to-thymine (C>T) substitutions in dipyrimidine sequences, which, together with tandem CC>TT substitutions, comprise the canonical UV mutation “signature”. These mutation classes are caused by DNA damage directly induced by UV absorption, namely cyclobutane pyrimidine dimers (CPDs) or 6-4 pyrimidine-pyrimidone photoproducts (6-4PP), which form between neighboring pyrimidine bases. However, many of the key driver mutations in melanoma do not fit this mutation signature, but instead are caused by T>A, T>C, C>A, or AC>TT substitutions, frequently occurring in non-dipyrimidine sequence contexts. This article describes recent studies indicating that UV light causes a more diverse spectrum of mutations than previously appreciated, including many of the mutation classes observed in melanoma driver mutations. Potential mechanisms for these diverse mutation signatures are discussed, including UV-induced pyrimidine-purine photoproducts and indirect DNA damage induced by UVA light. Finally, the article reviews recent findings indicating that human DNA polymerase eta normally suppresses these non-canonical UV mutation classes, which can potentially explain why canonical C>T substitutions predominate in human skin cancers.

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紫外线诱导突变的惊人多样性
紫外线(UV)是最普遍的环境诱变剂,也是导致皮肤癌的主要原因。黑色素瘤和其他皮肤癌的基因组测序显示,这些肿瘤中的绝大多数体细胞突变都是二嘧啶序列中胞嘧啶-胸腺嘧啶(C>T)的置换,它们与串联的 CC>TT 置换一起构成了典型的紫外线突变 "特征"。这些突变类别是由紫外线吸收直接诱导的 DNA 损伤引起的,即在相邻嘧啶碱基之间形成的环丁烷嘧啶二聚体(CPD)或 6-4 嘧啶-嘧啶酮光致产物(6-4PP)。然而,黑色素瘤中的许多关键驱动突变并不符合这种突变特征,而是由T>A、T>C、C>A或AC>TT置换引起的,而且经常发生在非二嘧啶序列上下文中。本文介绍了最近的一些研究,这些研究表明,紫外线导致的突变比以前认识到的更为多样,其中包括在黑色素瘤驱动突变中观察到的许多突变类别。文章讨论了这些不同突变特征的潜在机制,包括紫外线诱导的嘧啶-嘌呤光产物和紫外线诱导的间接 DNA 损伤。最后,文章回顾了最近的研究结果,这些结果表明人类DNA聚合酶eta通常会抑制这些非典型紫外线突变类别,这有可能解释了为什么典型的C>T置换在人类皮肤癌中占主导地位。
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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