Dionnet Eugénie, Defour Aurélia, Da Silva Nathalie, Salvi Alexandra, Lévy Nicolas, Krahn Martin, Bartoli Marc, Puppo Francesca, Gorokhova Svetlana
Faculté des Sciences Médicales et Paramédicales, Marseille Medical Genetics, Aix Marseille Université, INSERM, Marseille, France.
Service de génétique Médicale, Hôpital de la Timone, APHM, Marseille, France.
Hum Mutat. 2020 Oct;41(10):1797-1810. doi: 10.1002/humu.24083. Epub 2020 Jul 27.
Improving the accuracy of variant interpretation during diagnostic sequencing is a major goal for genomic medicine. To explore an often-overlooked splicing effect of missense variants, we developed the functional assay ("minigene") for the majority of exons of CAPN3, the gene responsible for limb girdle muscular dystrophy. By systematically screening 21 missense variants distributed along the gene, we found that eight clinically relevant missense variants located at a certain distance from the exon-intron borders (deep exonic missense variants) disrupted normal splicing of CAPN3 exons. Several recent machine learning-based computational tools failed to predict splicing impact for the majority of these deep exonic missense variants, highlighting the importance of including variants of this type in the training sets during the future algorithm development. Overall, 24 variants in CAPN3 gene were explored, leading to the change in the American College of Medical Genetics and Genomics classification of seven of them when results of the "minigene" functional assay were considered. Our findings reveal previously unknown splicing impact of several clinically important variants in CAPN3 and draw attention to the existence of deep exonic variants with a disruptive effect on gene splicing that could be overlooked by the current approaches in clinical genetics.
提高诊断性测序过程中变异解读的准确性是基因组医学的主要目标。为了探究错义变异中一种常被忽视的剪接效应,我们针对导致肢带型肌营养不良的基因CAPN3的大多数外显子开发了功能检测方法(“微型基因”)。通过系统筛选沿该基因分布的21个错义变异,我们发现位于距外显子-内含子边界一定距离处的8个临床相关错义变异(外显子深部错义变异)破坏了CAPN3外显子的正常剪接。最近的几种基于机器学习的计算工具未能预测这些外显子深部错义变异中的大多数的剪接影响,这凸显了在未来算法开发过程中将此类变异纳入训练集的重要性。总体而言,我们探究了CAPN3基因中的24个变异,当考虑“微型基因”功能检测结果时,其中7个变异的美国医学遗传学与基因组学学会分类发生了变化。我们的研究结果揭示了CAPN3中几个临床重要变异以前未知的剪接影响,并提请注意存在对基因剪接有破坏作用的外显子深部变异,而这些变异可能会被临床遗传学的当前方法所忽视。
