Department of Obstetrics and Gynaecology, The Chinese University of Hong Kong, Hong Kong, China.
Shenzhen Research Institute, The Chinese University of Hong Kong, Shenzhen, China.
Hum Genet. 2021 Feb;140(2):361-380. doi: 10.1007/s00439-020-02210-x. Epub 2020 Jul 29.
Chromosomal insertions are thought to be rare structural rearrangements. The current understanding of the underlying mechanisms of their origin is still limited. In this study, we sequenced 16 cases with apparent simple insertions previously identified by karyotyping and/or chromosomal microarray analysis. Using mate-pair genome sequencing (GS), we identified all 16 insertions and revised previously designated karyotypes in 75.0% (12/16) of the cases. Additional cryptic rearrangements were identified in 68.8% of the cases (11/16). The incidence of additional cryptic rearrangements in chromosomal insertions was significantly higher compared to balanced translocations and inversions reported in other studies by GS. We characterized and classified the cryptic insertion rearrangements into four groups, which were not mutually exclusive: (1) insertion segments were fragmented and their subsegments rearranged and clustered at the insertion site (10/16, 62.5%); (2) one or more cryptic subsegments were not inserted into the insertion site (5/16, 31.3%); (3) segments of the acceptor chromosome were scattered and rejoined with the insertion segments (2/16, 12.5%); and (4) copy number gains were identified in the flanking regions of the insertion site (2/16, 12.5%). In addition to the observation of these chromothripsis- or chromoanasynthesis-like events, breakpoint sequence analysis revealed microhomology to be the predominant feature. However, no significant correlation was found between the number of cryptic rearrangements and the size of the insertion. Overall, our study provide molecular characterization of karyotypically apparent simple insertions, demonstrate previously underappreciated complexities, and evidence that chromosomal insertions are likely formed by nonhomologous end joining and/or microhomology-mediated replication-based DNA repair.
染色体插入被认为是罕见的结构重排。目前对于其起源的潜在机制的理解仍然有限。在这项研究中,我们对 16 例通过核型分析和/或染色体微阵列分析先前鉴定为明显简单插入的病例进行了测序。使用 mate-pair 基因组测序(GS),我们鉴定了所有 16 个插入,并在 75.0%(12/16)的病例中修正了先前指定的核型。在 68.8%(11/16)的病例中发现了额外的隐匿性重排。与 GS 报道的其他研究中的平衡易位和倒位相比,染色体插入中隐匿性重排的发生率明显更高。我们将隐匿性插入重排特征化为并分类为四个组,这些组不是相互排斥的:(1)插入片段碎片化,其亚片段在插入部位重新排列和聚集(10/16,62.5%);(2)一个或多个隐匿性亚片段未插入插入部位(5/16,31.3%);(3)接受染色体的片段散布并与插入片段重新连接(2/16,12.5%);和(4)插入部位侧翼区域的拷贝数增益(2/16,12.5%)。除了观察到这些类似于染色体碎裂或染色体重合的事件外,断裂点序列分析显示微同源性是主要特征。然而,未发现隐匿性重排的数量与插入的大小之间存在显著相关性。总体而言,我们的研究提供了染色体显型简单插入的分子特征,表明了以前被低估的复杂性,并表明染色体插入可能是通过非同源末端连接和/或微同源介导的复制为基础的 DNA 修复形成的。
