Variants in the first methionine of RAD51C are homologous recombination proficient due to an alternative start site

IF 3 3区 生物学 Q2 GENETICS & HEREDITY DNA Repair Pub Date : 2024-02-01 DOI:10.1016/j.dnarep.2024.103644
Hayley L. Rein , Kara A. Bernstein
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Abstract

In the 20+ years since the discovery of RAD51C, scientists have been perplexed as to how missense variants in this tumor suppressor gene impacts its function and pathogenicity. With a strong connection to breast and ovarian cancer, classifying these variants as pathogenic or benign aids in the diagnosis and treatment of patients with RAD51C variants. In particular, variants at translational starts sites are disruptive as they prevent protein expression. These variants are often classified as pathogenic, unless an alternative translational start is shown to produce a functional isoform to rescue protein expression. In this study, we utilized the ribosome profiling database GWIPS-VIZ to identify two active translational start sites in human RAD51C at methionine one and methionine ten. This second translational start at methionine ten is both conserved in 97 % of mammals and is the sole translational start in 80 % of mammals. Missense variants at either methionine have been identified in 47 individuals, preventing expression from one of these two start sites. Therefore, we stably expressed both wildtype isoforms, as well as the RAD51C M1 and M10 variants in a RAD51C CRISPR/Cas9 knockout U2OS cell and compared their homologous recombination function. Surprisingly, we find that expression of human RAD51C from either start site can equivalently rescue homologous recombination of RAD51C CRISPR/Cas9 knockout U2OS cells through a sister chromatid recombination assay. Similarly, each of our RAD51C CRISPR/Cas9 KO cells stably complemented with RAD51C missense variants at either M1 or M10 are homologous recombination proficient. Together, our data demonstrate that RAD51C has two translational start sites and that variants in either methionine result in homologous recombination proficiency. With this critical discovery, individuals with variants at M1 will be more accurately informed of their cancer risk upon reclassification of these variants.

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RAD51C 第一个蛋氨酸的变异因另一个起始位点而具有同源重组能力
自发现 RAD51C 以来的 20 多年里,科学家们一直困惑于这种肿瘤抑制基因中的错义变异是如何影响其功能和致病性的。RAD51C变异与乳腺癌和卵巢癌有密切关系,将这些变异分为致病性和良性有助于对RAD51C变异患者的诊断和治疗。尤其是位于翻译起始位点的变体,它们会阻碍蛋白质的表达,因而具有破坏性。这些变体通常被归类为致病变体,除非能证明替代的翻译起始位点能产生功能性同工酶来挽救蛋白质的表达。在这项研究中,我们利用核糖体图谱数据库 GWIPS-VIZ 在人类 RAD51C 中的蛋氨酸 1 和蛋氨酸 10 处发现了两个活跃的翻译起始位点。蛋氨酸十处的第二个转译起始位点在 97% 的哺乳动物中是保守的,在 80% 的哺乳动物中是唯一的转译起始位点。在 47 个个体中发现了这两个蛋氨酸上的错义变体,从而阻止了这两个起始位点之一的表达。因此,我们在 RAD51C CRISPR/Cas9 基因敲除的 U2OS 细胞中稳定表达了野生型异构体以及 RAD51C M1 和 M10 变体,并比较了它们的同源重组功能。令人惊讶的是,通过姐妹染色单体重组试验,我们发现从任一起始位点表达人 RAD51C 都能等效地挽救 RAD51C CRISPR/Cas9 基因敲除 U2OS 细胞的同源重组。同样,我们的每个 RAD51C CRISPR/Cas9 KO 细胞在 M1 或 M10 稳定地与 RAD51C 错义变体互补后都能进行同源重组。总之,我们的数据证明了 RAD51C 有两个翻译起始位点,其中一个蛋氨酸的变异会导致同源重组能力低下。有了这一重要发现,在对 M1 位点的变异进行重新分类时,就能更准确地了解这些变异的个体患癌症的风险。
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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来源期刊
DNA Repair
DNA Repair 生物-毒理学
CiteScore
7.60
自引率
5.30%
发文量
91
审稿时长
59 days
期刊介绍: DNA Repair provides a forum for the comprehensive coverage of DNA repair and cellular responses to DNA damage. The journal publishes original observations on genetic, cellular, biochemical, structural and molecular aspects of DNA repair, mutagenesis, cell cycle regulation, apoptosis and other biological responses in cells exposed to genomic insult, as well as their relationship to human disease. DNA Repair publishes full-length research articles, brief reports on research, and reviews. The journal welcomes articles describing databases, methods and new technologies supporting research on DNA repair and responses to DNA damage. Letters to the Editor, hot topics and classics in DNA repair, historical reflections, book reviews and meeting reports also will be considered for publication.
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