Section of Pediatric Neurology and Developmental Neuroscience, Department of Pediatrics, Baylor College of Medicine, Houston, Texas, USA.
Department of Molecular and Human Genetics, Baylor College of Medicine, Houston, Texas, USA.
Am J Med Genet A. 2022 Mar;188(3):735-750. doi: 10.1002/ajmg.a.62565. Epub 2021 Nov 23.
Genomic sequencing and clinical genomics have demonstrated that substantial subsets of atypical and/or severe disease presentations result from multilocus pathogenic variation (MPV) causing blended phenotypes. In an infant with a severe neurodevelopmental disorder, four distinct molecular diagnoses were found by exome sequencing (ES). The blended phenotype that includes brain malformation, dysmorphism, and hypotonia was dissected using the Human Phenotype Ontology (HPO). ES revealed variants in CAPN3 (c.259C > G:p.L87V), MUSK (c.1781C > T:p.A594V), NAV2 (c.1996G > A:p.G666R), and ZC4H2 (c.595A > C:p.N199H). CAPN3, MUSK, and ZC4H2 are established disease genes linked to limb-girdle muscular dystrophy (OMIM# 253600), congenital myasthenia (OMIM# 616325), and Wieacker-Wolff syndrome (WWS; OMIM# 314580), respectively. NAV2 is a retinoic-acid responsive novel disease gene candidate with biological roles in neurite outgrowth and cerebellar dysgenesis in mouse models. Using semantic similarity, we show that no gene identified by ES individually explains the proband phenotype, but rather the totality of the clinically observed disease is explained by the combination of disease-contributing effects of the identified genes. These data reveal that multilocus pathogenic variation can result in a blended phenotype with each gene affecting a different part of the nervous system and nervous system-muscle connection. We provide evidence from this n = 1 study that in patients with MPV and complex blended phenotypes resulting from multiple molecular diagnoses, quantitative HPO analysis can allow for dissection of phenotypic contribution of both established disease genes and novel disease gene candidates not yet proven to cause human disease.
基因组测序和临床基因组学表明,大量非典型和/或严重疾病表现是由多基因致病性变异(MPV)引起的混合表型引起的。在一名患有严重神经发育障碍的婴儿中,通过外显子组测序(ES)发现了四个不同的分子诊断。使用人类表型本体(HPO)对包括脑畸形、发育不良和张力减退在内的混合表型进行了剖析。ES 显示 CAPN3(c.259C>G:p.L87V)、MUSK(c.1781C>T:p.A594V)、NAV2(c.1996G>A:p.G666R)和 ZC4H2(c.595A>C:p.N199H)中的变异。CAPN3、MUSK 和 ZC4H2 是与肢带型肌营养不良症(OMIM#253600)、先天性肌无力(OMIM#616325)和 Wieacker-Wolff 综合征(WWS;OMIM#314580)相关的已确立疾病基因。NAV2 是一种视黄酸反应性新型疾病基因候选物,在小鼠模型中具有神经突生长和小脑发育不良的生物学作用。使用语义相似性,我们表明,ES 鉴定的单个基因都不能单独解释先证者的表型,而是通过鉴定的疾病基因的致病效应的总和来解释所观察到的临床疾病的全部。这些数据表明,多基因致病性变异可导致混合表型,每个基因都会影响神经系统和神经系统-肌肉连接的不同部位。我们从这项 n=1 研究中提供证据表明,在具有多基因致病性变异和由多个分子诊断引起的复杂混合表型的患者中,定量 HPO 分析可以剖析已确立疾病基因和尚未证明导致人类疾病的新型疾病基因候选物的表型贡献。
