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Resolution of ring chromosomes, Robertsonian translocations, and complex structural variants from long-read sequencing and telomere-to-telomere assembly

端粒 生物 染色体易位 遗传学 真核细胞染色体精细结构 计算生物学 DNA 基因
作者
Yulia Mostovoy,Philip M. Boone,Yongqing Huang,Kiran Garimella,Kar‐Tong Tan,Bianca Russell,Monica Salani,Celine de Esch,John Lemanski,Benjamin Curall,Jen Hauenstein,Diane Lucente,Tera Bowers,Tim DeSmet,Stacey Gabriel,Cynthia C. Morton,Matthew Meyerson,Alex Hastie,James F. Gusella,Fabiola Quintero‐Rivera
出处
期刊:American Journal of Human Genetics [Elsevier BV]
被引量:2
标识
DOI:10.1016/j.ajhg.2024.10.006
摘要

SummaryDelineation of structural variants (SVs) at sequence resolution in highly repetitive genomic regions has long been intractable. The sequence properties, origins, and functional effects of classes of genomic rearrangements such as ring chromosomes and Robertsonian translocations thus remain unknown. To resolve these complex structures, we leveraged several recent milestones in the field, including (1) the emergence of long-read sequencing, (2) the gapless telomere-to-telomere (T2T) assembly, and (3) a tool (BigClipper) to discover chromosomal rearrangements from long reads. We applied these technologies across 13 cases with ring chromosomes, Robertsonian translocations, and complex SVs that were unresolved by short reads, followed by validation using optical genome mapping (OGM). Our analyses resolved 10 of 13 cases, including a Robertsonian translocation and all ring chromosomes. Multiple breakpoints were localized to genomic regions previously recalcitrant to sequencing such as acrocentric p-arms, ribosomal DNA arrays, and telomeric repeats, and involved complex structures such as a deletion-inversion and interchromosomal dispersed duplications. We further performed methylation profiling from long-read data to discover phased differential methylation in a gene promoter proximal to a ring fusion, suggesting a long-range position effect (LRPE) with heterochromatin spreading. Breakpoint sequences suggested mechanisms of SV formation such as microhomology-mediated and non-homologous end-joining, as well as non-allelic homologous recombination. These methods provide some of the first glimpses into the sequence resolution of Robertsonian translocations and illuminate the structural diversity of ring chromosomes and complex chromosomal rearrangements with implications for genome biology, prediction of LRPEs from integrated multi-omics technologies, and molecular diagnostics in rare disease cases.Graphical abstract
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