Purpose: A molecular genetic diagnosis is essential for accurate counselling and management of patients with ciliopathies. Uncharacterized missense alleles are often classified as variants of uncertain significance (VUS) and are not clinically useful. In this study, we explore the use of a tractable animal model (C. elegans) for in vivo interpretation of missense VUS alleles of TMEM67, a gene frequently mutated as a cause of ciliopathies. Methods: CRISPR/Cas9 gene editing was used to generate homozygous worm strains carrying TMEM67 patient variants. Quantitative phenotypic assays (dye filling, roaming, chemotaxis) assessed cilia structure and function. Results were validated by genetic complementation assays in a human TMEM67 knock-out hTERT-RPE1 cell line. Results: Quantitative assays in C. elegans distinguished between known benign (Asp359Glu, Thr360Ala) and pathogenic (Glu361Ter, Gln376Pro) variants. Analysis of seven missense VUS alleles predicted two benign (Cys173Arg, Thr176Ile) and four pathogenic variants (Cys170Tyr, His782Arg, Gly786Glu, His790Arg). Results from one VUS (Gly979Arg) were inconclusive in worms, but additional in vitro validation suggested it was likely benign. Conclusion: Efficient genome editing and quantitative functional assays in C. elegans make it a tractable in vivo animal model that allows stratification and rapid, cost-effective interpretation of ciliopathy-associated missense VUS alleles.
Influence of Exogenous Estrogen Receptor Ligands on Uterine Leiomyoma: Evidence from an in Vitro/in Vivo Animal Model for Uterine Fibroids
