The landcape of Helicobacter pylori-mediated DNA breaks links bacterial genotoxicity to its oncogenic potential.

IF 10.4 1区生物学 Q1 GENETICS & HEREDITY

Genome Medicine Pub Date : 2025-02-24 DOI:10.1186/s13073-025-01439-3

Hadas Sibony-Benyamini, Rose Jbara, Tania Shubash Napso, Layan Abu-Rahmoun, Daniel Vizenblit, Michal Easton-Mor, Shira Perez, Alexander Brandis, Tamar Leshem, Avi Peretz, Yaakov Maman

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引用次数: 0

Abstract

Background: Helicobacter pylori (H. pylori) infection is a significant risk factor for gastric cancer (GC) development. A growing body of evidence suggests a causal link between infection with H. pylori and increased DNA breakage in the host cells. While several mechanisms have been proposed for this damage, their relative impact on the overall bacterial genotoxicity is unknown. Moreover, the link between the formation of DNA damage following infection and the emergence of cancerous structural variants (SV) in the genome of infected cells remained unexplored.

Methods: We constructed a high-resolution map of genomic H. pylori-induced recurrent break sites using the END-seq method on AGS human gastric cells before and after infection. We next applied END-seq to cycling and arrested cells to identify the role of DNA replication on break formation. Recurrent H. pylori-mediated break sites were further characterized by analyzing published RNA-seq, DRIP-seq, and GRO-seq data at these sites. γH2AX staining and comet assay were used for DNA breakage quantification. Liquid chromatography-mass spectrometry (LC-MS) assay was used to quantify cellular concentrations of dNTPs.

Results: Our data indicated that sites of recurrent H. pylori-mediated DNA breaks are ubiquitous across cell types, localized at replication-related fragile sites, and their breakage is dependent on replication. Consistent with that, we found that H. pylori inflicts nucleotide depletion, and that rescuing the cellular nucleotide pool largely reduced H. pylori-induced DNA breaks. Intriguingly, we found that this genotoxic mechanism operates independently of H. pylori cag pathogenicity island (CagPAI) that encodes for the bacterial type 4 secretion system (T4SS), and its virulence factor, CagA, which was previously implicated in increasing DNA damage by downregulating the DNA damage response. Finally, we show that sites of recurrent H. pylori-mediated breaks coincide with chromosomal deletions observed in patients with intestinal-type GC and that this link potentially elucidates the persistent transcriptional alterations observed in cancer driver genes.

Conclusions: Our findings indicate that dNTP depletion by H. pylori is a key component of its genotoxicity and suggest a link between H. pylori genotoxicity and its oncogenic potential.

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幽门螺杆菌介导的DNA断裂将细菌遗传毒性与其致癌潜力联系起来。

背景：幽门螺杆菌（h.p ylori）感染是胃癌发生的重要危险因素。越来越多的证据表明，幽门螺杆菌感染与宿主细胞DNA断裂增加之间存在因果关系。虽然已经提出了这种损伤的几种机制，但它们对总体细菌遗传毒性的相对影响尚不清楚。此外，感染后DNA损伤的形成与感染细胞基因组中癌变结构变异（SV）的出现之间的联系仍未被探索。方法：采用END-seq方法对感染前后的AGS人胃细胞构建了幽门螺杆菌诱导的复发断裂位点的高分辨率基因组图谱。接下来，我们将END-seq应用于循环和捕获细胞，以确定DNA复制在断裂形成中的作用。通过分析已发表的RNA-seq、dip -seq和GRO-seq数据，进一步表征了幽门螺杆菌介导的复发断裂位点。用γ - h2ax染色和彗星法定量DNA断裂。采用液相色谱-质谱法（LC-MS）测定dNTPs的细胞浓度。结果：我们的数据表明，反复出现的幽门螺杆菌介导的DNA断裂位点在细胞类型中普遍存在，定位于复制相关的脆弱位点，并且它们的断裂依赖于复制。与此一致的是，我们发现幽门螺杆菌造成核苷酸耗竭，而挽救细胞核苷酸库在很大程度上减少了幽门螺杆菌诱导的DNA断裂。有趣的是，我们发现这种基因毒性机制独立于幽门螺杆菌cag致病性岛（CagPAI）的作用，该岛编码细菌4型分泌系统（T4SS）及其毒力因子CagA， CagA先前被认为通过下调DNA损伤反应来增加DNA损伤。最后，我们发现幽门螺杆菌介导的复发性断裂位点与肠型胃癌患者中观察到的染色体缺失相吻合，这种联系可能阐明了在癌症驱动基因中观察到的持续转录改变。结论：我们的研究结果表明，幽门螺杆菌消耗dNTP是其遗传毒性的关键组成部分，并表明幽门螺杆菌遗传毒性与其致癌潜力之间存在联系。

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

Genome Medicine GENETICS & HEREDITY-

CiteScore

20.80

自引率

0.80%

发文量

128

审稿时长

6-12 weeks

期刊介绍： Genome Medicine is an open access journal that publishes outstanding research applying genetics, genomics, and multi-omics to understand, diagnose, and treat disease. Bridging basic science and clinical research, it covers areas such as cancer genomics, immuno-oncology, immunogenomics, infectious disease, microbiome, neurogenomics, systems medicine, clinical genomics, gene therapies, precision medicine, and clinical trials. The journal publishes original research, methods, software, and reviews to serve authors and promote broad interest and importance in the field.