Advancing long-read nanopore genome assembly and accurate variant calling for rare disease detection.

IF 8.1 1区生物学 Q1 GENETICS & HEREDITY

American journal of human genetics Pub Date : 2025-02-06 Epub Date: 2025-01-24 DOI:10.1016/j.ajhg.2025.01.002

Shloka Negi, Sarah L Stenton, Seth I Berger, Paolo Canigiula, Brandy McNulty, Ivo Violich, Joshua Gardner, Todd Hillaker, Sara M O'Rourke, Melanie C O'Leary, Elizabeth Carbonell, Christina Austin-Tse, Gabrielle Lemire, Jillian Serrano, Brian Mangilog, Grace VanNoy, Mikhail Kolmogorov, Eric Vilain, Anne O'Donnell-Luria, Emmanuèle Délot, Karen H Miga, Jean Monlong, Benedict Paten

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引用次数: 0

Abstract

More than 50% of families with suspected rare monogenic diseases remain unsolved after whole-genome analysis by short-read sequencing (SRS). Long-read sequencing (LRS) could help bridge this diagnostic gap by capturing variants inaccessible to SRS, facilitating long-range mapping and phasing and providing haplotype-resolved methylation profiling. To evaluate LRS's additional diagnostic yield, we sequenced a rare-disease cohort of 98 samples from 41 families, using nanopore sequencing, achieving per sample ∼36× average coverage and 32-kb read N50 from a single flow cell. Our Napu pipeline generated assemblies, phased variants, and methylation calls. LRS covered, on average, coding exons in ∼280 genes and ∼5 known Mendelian disease-associated genes that were not covered by SRS. In comparison to SRS, LRS detected additional rare, functionally annotated variants, including structural variants (SVs) and tandem repeats, and completely phased 87% of protein-coding genes. LRS detected additional de novo variants and could be used to distinguish postzygotic mosaic variants from prezygotic de novos. Diagnostic variants were established by LRS in 11 probands, with diverse underlying genetic causes including de novo and compound heterozygous variants, large-scale SVs, and epigenetic modifications. Our study demonstrates LRS's potential to enhance diagnostic yield for rare monogenic diseases, implying utility in future clinical genomics workflows.

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推进用于罕见病检测的长线程纳米孔基因组组装和准确的变异调用。

超过50%的疑似罕见单基因疾病的家庭在短读测序（SRS）全基因组分析后仍未得到解决。长读测序（LRS）可以通过捕获SRS无法获得的变异，促进远程定位和分相，并提供单倍型解决的甲基化分析，从而帮助弥合这一诊断差距。为了评估LRS的额外诊出率，我们对来自41个家族的98个罕见疾病样本进行了测序，使用纳米孔测序，从单个流式细胞获得每个样本约36倍的平均覆盖率和32 kb的读取N50。我们的Napu管道生成组装、阶段性变体和甲基化调用。LRS平均覆盖了约280个基因的编码外显子和约5个未被SRS覆盖的已知孟德尔病相关基因。与SRS相比，LRS检测到更多罕见的、功能注释的变异，包括结构变异（SVs）和串联重复序列，并完全分期了87%的蛋白质编码基因。LRS检测到额外的新生变异，并可用于区分合子后镶嵌变异和合子前新生变异。通过LRS在11个先证物中建立了诊断变异，这些变异具有不同的潜在遗传原因，包括新生和复合杂合变异、大规模sv和表观遗传修饰。我们的研究表明，LRS有潜力提高罕见单基因疾病的诊断率，这意味着在未来的临床基因组学工作流程中具有实用性。

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来源期刊

American journal of human genetics 生物-遗传学

CiteScore

14.70

自引率

4.10%

发文量

185

审稿时长

1 months

期刊介绍： The American Journal of Human Genetics (AJHG) is a monthly journal published by Cell Press, chosen by The American Society of Human Genetics (ASHG) as its premier publication starting from January 2008. AJHG represents Cell Press's first society-owned journal, and both ASHG and Cell Press anticipate significant synergies between AJHG content and that of other Cell Press titles.