CFTR haplotype phasing using long-read genome sequencing from ultralow input DNA

Genetics in Medicine Open Pub Date : 2025-01-01 Epub Date: 2025-01-07 DOI:10.1016/j.gimo.2025.101962

Neeru Gandotra , Antariksh Tyagi , Irina Tikhonova , Caroline Storer , Curt Scharfe

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Abstract

Purpose

Newborn screening identifies rare diseases that result from the recessive inheritance of pathogenic variants in both copies of a gene. Long-read genome sequencing (LRS) is used for identifying and phasing genomic variants, but further efforts are needed to develop LRS for applications using low-yield DNA samples.

Methods

In this study, genomic DNA with high molecular weight was obtained from 2 cystic fibrosis patients, comprising a whole-blood sample (CF1) and a newborn dried blood spot sample (CF2). Library preparation and genome sequencing (30-fold coverage) were performed using 20 ng of DNA input on both the PacBio Revio system and the Illumina NovaSeq short-read sequencer. Single-nucleotide variants, small indels, and structural variants were identified for each data set.

Results

Our results indicated that the genotype concordance between long- and short-read genome sequencing data was higher for single-nucleotide variants than for small indels. Both technologies accurately identified known pathogenic variants in the CFTR gene (CF1: p.(Met607_Gln634del), p.(Phe508del); CF2: p.(Phe508del), p.(Ala455Glu)) with complete concordance for the polymorphic poly-TG and consecutive poly-T tracts. Using PacBio read-based haplotype phasing, we successfully determined the allelic phase and identified compound heterozygosity of pathogenic variants at genomic distances of 32.4 kb (CF1) and 10.8 kb (CF2).

Conclusion

Haplotype phasing of rare pathogenic variants from minimal DNA input is achieved through LRS. This approach has the potential to eliminate the need for parental testing, thereby shortening the time to diagnosis in genetic disease screening.

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利用来自超低输入DNA的长读基因组测序进行CFTR单倍型分相

目的新生儿筛查识别由基因两个拷贝中致病变异的隐性遗传引起的罕见疾病。长读基因组测序（LRS）用于鉴定和确定基因组变异，但需要进一步努力开发用于使用低产量DNA样本的LRS。方法从2例囊性纤维化患者的全血样本（CF1）和新生儿干血斑点样本（CF2）中获得高分子量的基因组DNA。在PacBio Revio系统和Illumina NovaSeq短读测序仪上使用20 ng的DNA输入进行文库制备和基因组测序（30倍覆盖率）。每个数据集都识别出单核苷酸变异、小索引和结构变异。结果单核苷酸变异的基因型一致性高于小序列变异的基因型一致性。这两种技术都能准确地鉴定出CFTR基因中已知的致病变异(CF1: p.(Met607_Gln634del), p.(Phe508del)；CF2: p.(Phe508del), p.(Ala455Glu))，多态性多聚tg和连续多聚t链完全一致。利用基于PacBio read的单倍型相位分析，我们成功地确定了等位基因相位，并在基因组距离32.4 kb （CF1）和10.8 kb （CF2）处鉴定了致病变异的复合杂合性。结论通过LRS，可以从最小的DNA输入中实现罕见致病变异的单倍型分期。这种方法有可能消除对父母检测的需要，从而缩短遗传病筛查的诊断时间。

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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Genetics in Medicine Open

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