ViLR: a novel virtual long read method for breakpoint identification and direct SNP haplotyping in de novo PGT-SR carriers without a proband.

IF 4.2 2区医学 Q1 ENDOCRINOLOGY & METABOLISM

Reproductive Biology and Endocrinology Pub Date : 2025-03-05 DOI:10.1186/s12958-025-01366-3

Jiangyang Xue, Min Xie, Jie Cai, Kai Kang, Mengnan Gu, Mai Li, Haiyue Shi, Xin Zhang, Lingyin Kong, Bo Liang, Liming Zhou, Changshui Chen, Haibo Li

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引用次数: 0

Abstract

Background: Despite the gradual application of third-generation long read sequencing (LRS) or reference embryo establishment to preimplantation genetic testing for structural rearrangement (PGT-SR) without familial involvement, there are still limitations to their extensive clinical application yet. This study developed a novel virtual NGS-based long read method (ViLR) and preliminarily evaluated its clinical feasibility of breakpoint characterization and direct SNP haplotyping for de novo chromosomal structural rearrangements (CSR).

Methods: A total of 10 families with de novo CSR risk were enrolled in this study for ViLR analysis. In contrast to LRS, ViLR is a virtual long read solution that used the same barcoded labeling and assembly of different long gDNAs differently barcoded. Notably, ViLR could generate an average fragment length of over 30 Kb, with an N50 block size of up to 16 Mb in a single assay, allowing to achieve accurate breakpoint mapping and direct carrier's haplotyping. An approximately 2 Mbp region flanking upstream and downstream of each breakpoint was selected for informative SNP collection. Embryo haplotype determination was based on the established carriers' haplotypes after whole genome amplification and sequencing. To confirm PGT-SR results, we performed prenatal genetic diagnosis.

Results: This study achieved an average mapping rate of 99.5%, > 90% coverage depth (> 10X), an average number of effective barcode (> 5 kb length) counts of 11,000,000 and an average fragment length of 40 kb, which generated sufficient informative SNPs for breakpoint characterization and haplotype phasing. ViLR analysis of 10 de novo PGT-SR carriers precisely identified breakpoints and haplotypes. Seven families obtained 18 euploid embryos, in which 10 were euploid/normal embryos, 7 were euploid/balanced carrier embryos, and the remaining one unknown was due to homologous recombination of the breakpoint region. Prenatal genetic diagnosis was performed for four women, and the outcomes coincided with the results from embryo PGT-SR. At the time of writing this paper, four healthy babies had been delivered uneventfully.

Conclusion: Here, we demonstrated the clinical potential of ViLR as a novel solution for breakpoint identification and direct SNP haplotyping in de novo PGT-SR families without proband involvement.

Clinical trial number: Not applicable.

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ViLR：一种新的虚拟长读方法，用于断点识别和无先证者的新生PGT-SR携带者的直接SNP单倍型。

背景：尽管第三代长读测序（LRS）或参考胚胎建立逐渐应用于无家族参与的着床前基因检测（PGT-SR），但其在临床的广泛应用仍有局限性。本研究开发了一种新的基于虚拟ngs的长读方法（ViLR），并初步评估了其断点表征和直接SNP单倍型用于新生染色体结构重排（CSR）的临床可行性。方法：选取10个有新发CSR风险的家庭进行ViLR分析。与LRS相比，ViLR是一种虚拟长读解决方案，它使用相同的条形码标记和不同条形码的不同长dna的组装。值得注意的是，ViLR可以在单次分析中产生超过30 Kb的平均片段长度，N50块大小高达16 Mb，从而实现准确的断点定位和直接载体的单倍型。选择每个断点的上下游两侧约2 Mbp的区域进行信息SNP收集。胚胎单倍型的确定是基于全基因组扩增和测序后确定的载体单倍型。为了确认PGT-SR结果，我们进行了产前遗传诊断。结果：本研究实现了平均定位率99.5%,>覆盖深度90% (> 10X)，平均有效条形码数（> 5kb长度）为11,000,000，平均片段长度为40kb，为断点表征和单倍型相位生成了足够的信息性snp。对10个新生PGT-SR携带者的ViLR分析精确地确定了断点和单倍型。7个家族共获得18个整倍体胚胎，其中10个为整倍体/正常胚，7个为整倍体/平衡载体胚，其余1个因断点区同源重组而未知。对4名妇女进行了产前遗传诊断，结果与胚胎PGT-SR的结果一致。在写这篇文章的时候，四个健康的婴儿平安无事地出生了。结论：在这里，我们证明了ViLR作为一种新的解决方案的临床潜力，可以在没有先证者参与的情况下对新生PGT-SR家族进行断点鉴定和直接SNP单倍型分型。临床试验号：不适用。

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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来源期刊

Reproductive Biology and Endocrinology 医学-内分泌学与代谢

CiteScore

7.90

自引率

2.30%

发文量

161

审稿时长

4-8 weeks

期刊介绍： Reproductive Biology and Endocrinology publishes and disseminates high-quality results from excellent research in the reproductive sciences. The journal publishes on topics covering gametogenesis, fertilization, early embryonic development, embryo-uterus interaction, reproductive development, pregnancy, uterine biology, endocrinology of reproduction, control of reproduction, reproductive immunology, neuroendocrinology, and veterinary and human reproductive medicine, including all vertebrate species.