Haplotype-specific assembly of shattered chromosomes in esophageal adenocarcinomas.

IF 11.1 Q1 CELL BIOLOGY
Cell genomics Pub Date : 2024-02-14 Epub Date: 2024-01-16 DOI:10.1016/j.xgen.2023.100484
Jannat Ijaz, Edward Harry, Keiran Raine, Andrew Menzies, Kathryn Beal, Michael A Quail, Sonia Zumalave, Hyunchul Jung, Tim H H Coorens, Andrew R J Lawson, Daniel Leongamornlert, Hayley E Francies, Mathew J Garnett, Zemin Ning, Peter J Campbell
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引用次数: 0

Abstract

The epigenetic landscape of cancer is regulated by many factors, but primarily it derives from the underlying genome sequence. Chromothripsis is a catastrophic localized genome shattering event that drives, and often initiates, cancer evolution. We characterized five esophageal adenocarcinoma organoids with chromothripsis using long-read sequencing and transcriptome and epigenome profiling. Complex structural variation and subclonal variants meant that haplotype-aware de novo methods were required to generate contiguous cancer genome assemblies. Chromosomes were assembled separately and scaffolded using haplotype-resolved Hi-C reads, producing accurate assemblies even with up to 900 structural rearrangements. There were widespread differences between the chromothriptic and wild-type copies of chromosomes in topologically associated domains, chromatin accessibility, histone modifications, and gene expression. Differential epigenome peaks were most enriched within 10 kb of chromothriptic structural variants. Alterations in transcriptome and higher-order chromosome organization frequently occurred near differential epigenetic marks. Overall, chromothripsis reshapes gene regulation, causing coordinated changes in epigenetic landscape, transcription, and chromosome conformation.

食管腺癌中破碎染色体的单倍型特异性组合
癌症的表观遗传结构受多种因素调控,但主要来自基因组序列。染色质脱落是一种灾难性的局部基因组破碎事件,它推动并经常引发癌症进化。我们利用长线程测序以及转录组和表观基因组剖析,对五个患有染色体裂解的食管腺癌器官组织进行了鉴定。复杂的结构变异和亚克隆变异意味着需要单倍型感知的从头方法来生成连续的癌症基因组组装。使用单倍型分辨的 Hi-C 读数分别组装染色体并构建支架,即使存在多达 900 个结构重排,也能生成准确的组装结果。在拓扑相关域、染色质可及性、组蛋白修饰和基因表达等方面,染色体的染色质拷贝和野生型拷贝之间存在广泛差异。差异表观基因组峰在染色质结构变异的 10 kb 范围内最为富集。转录组和高阶染色体组织的改变经常发生在差异表观遗传标记附近。总体而言,染色体三分裂重塑了基因调控,导致表观遗传景观、转录和染色体构象发生协调变化。
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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CiteScore
7.10
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0.00%
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