Department of Pathology, Brigham and Women's Hospital, Boston, MA, USA.
Harvard Medical School, Boston, MA, USA.
Vox Sang. 2020 Nov;115(8):790-801. doi: 10.1111/vox.12963. Epub 2020 Jun 22.
Rh is one of the most diverse and complex blood group systems. Recently, next generation sequencing (NGS) has proven to be a viable option for RH genotyping. We have developed automated software (bloodTyper) for determining alleles encoding RBC antigens from NGS-based whole genome sequencing (WGS). The bloodTyper algorithm has not yet been optimized and evaluated for complex and uncommon RH alleles.
Twenty-two samples with previous polymerase chain reaction (PCR) and Sanger sequencing-based RH genotyping underwent WGS. bloodTyper was used to detect RH alleles including those defined by structural variation (SV) using a combination of three independent strategies: sequence read depth of coverage, split reads and paired reads.
bloodTyper was programmed to identify D negative and positive phenotypes as well as the presence of alleles encoding weak D, partial D and variant RHCE. Sequence read depth of coverage calculation accurately determined RHD zygosity and detected the presence of RHD/RHCE hybrids. RHCEC was determined by sequence read depth of coverage and by split read methods. RHD hybrid alleles and RHCEC were confirmed by using a paired read approach. Small SVs present in RHCECeRN and RHCEceHAR were detected by a combined read depth of coverage and paired read approach.
The combination of several different interpretive approaches allowed for automated software based-RH genotyping of WGS data including RHD zygosity and complex compound RHD and RHCE heterozygotes. The scalable nature of this automated analysis will enable RH genotyping in large genomic sequencing projects.
Rh 是最具多样性和复杂性的血型系统之一。最近,下一代测序(NGS)已被证明是 RH 基因分型的可行选择。我们已经开发了一种自动化软件(bloodTyper),用于从基于 NGS 的全基因组测序(WGS)中确定编码 RBC 抗原的等位基因。bloodTyper 算法尚未针对复杂和罕见的 RH 等位基因进行优化和评估。
22 例先前进行过聚合酶链反应(PCR)和基于 Sanger 测序的 RH 基因分型的样本进行了 WGS。bloodTyper 用于检测 RH 等位基因,包括使用三种独立策略(序列读取深度覆盖、拆分读取和配对读取)定义的结构变异(SV)。
bloodTyper 被编程为识别 D 阴性和阳性表型,以及存在编码弱 D、部分 D 和变体 RHCE 的等位基因。序列读取深度覆盖计算准确确定了 RHD 基因型,并检测到 RHD/RHCE 杂合体的存在。通过序列读取深度覆盖和拆分读取方法确定 RHCEC。通过使用配对读取方法来确认 RHD 杂合子等位基因和 RHCEC。通过结合序列读取深度覆盖和配对读取方法检测到 RHCECeRN 和 RHCEceHAR 中存在的小 SV。
几种不同解释方法的结合允许对 WGS 数据进行基于自动化软件的 RH 基因分型,包括 RHD 基因型和复杂的复合 RHD 和 RHCE 杂合子。这种自动化分析的可扩展性将使大规模基因组测序项目中的 RH 基因分型成为可能。
