Shenghan Gao, Yimeng Zhang, Stephen J Bush, Bo Wang, Xiaofei Yang, Kai Ye
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引用次数: 0
摘要
高保真(HiFi)测序促进了基因组中重复性最高的区域--中心粒的组装和分析。然而,我们目前对人类中心粒的了解是基于数量相对较少的端粒到端粒的组装,还没有捕捉到其全部的多样性。在这项研究中,我们从正在进行的泛基因组测序项目中抽取了数百个样本,通过HiFi读数和单体型解析组装研究了人类中心粒高阶重复序列(HORs)的基因组多样性,并通过新型HOR注释管道HiCAT-human对其进行了再处理。我们利用这些丰富的数据对中心粒 HOR 状况进行了全面调查;特别是,我们发现 23 个 HOR 在不同种群之间存在显著的拷贝数变异。我们在 5 号、8 号和 17 号染色体上发现了三种群体频率不平衡的中心粒基因型。对 HOR 基因座进行组装间比较进一步发现,虽然 HOR 阵列结构多种多样,但它们往往会形成一些特定的景观,每种景观都表现出不同程度的 HOR 亚基扩展,可能反映了从同源结构到嵌套结构再到嵌套结构的循环进化过渡。
Centromere Landscapes Resolved from Hundreds of Human Genomes.
High-fidelity (HiFi) sequencing has facilitated the assembly and analysis of the most repetitive region of the genome, the centromere. Nevertheless, our current understanding of human centromeres is based on a relatively small number of telomere-to-telomere assemblies, which has not yet captured its full diversity. In this study, we investigated the genomic diversity of human centromere higher order repeats (HORs) via both HiFi reads and haplotype-resolved assemblies from hundreds of samples drawn from ongoing pangenome-sequencing projects and reprocessed them via a novel HOR annotation pipeline, HiCAT-human. We used this wealth of data to provide a global survey of the centromeric HOR landscape; in particular, we found that 23 HORs presented significant copy number variability between populations. We detected three centromere genotypes with unbalanced population frequencies on chromosomes 5, 8, and 17. An inter-assembly comparison of HOR loci further revealed that while HOR array structures are diverse, they nevertheless tend to form a number of specific landscapes, each exhibiting different levels of HOR subunit expansion and possibly reflecting a cyclical evolutionary transition from homogeneous to nested structures and back.