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High-resolution functional mapping of RAD51C by saturation genome editing

Rebeca Olvera-León, Fang Zhang, Victoria Offord, Yajie Zhao, Hong Kee Tan, Prashant Gupta, Tuya Pal, Carla Daniela Robles‐Espinoza, Fernanda G Arriaga-González, Larissa Satiko Alcântara Sekimoto Matsuyama, Erwan Delage, Ed Dicks, Suzana Ezquina, Charlie F Rowlands, Clare Turnbull, Paul D.P. Pharoah, John R. B. Perry, Maria Jasin, Andrew Waters, David J. Adams

2024Cell38 citationsDOIOpen Access PDF

Abstract

Pathogenic variants in RAD51C confer an elevated risk of breast and ovarian cancer, while individuals homozygous for specific RAD51C alleles may develop Fanconi anemia. Using saturation genome editing (SGE), we functionally assess 9,188 unique variants, including >99.5% of all possible coding sequence single-nucleotide alterations. By computing changes in variant abundance and Gaussian mixture modeling (GMM), we functionally classify 3,094 variants to be disruptive and use clinical truth sets to reveal an accuracy/concordance of variant classification >99.9%. Cell fitness was the primary assay readout allowing us to observe a phenomenon where specific missense variants exhibit distinct depletion kinetics potentially suggesting that they represent hypomorphic alleles. We further explored our exhaustive functional map, revealing critical residues on the RAD51C structure and resolving variants found in cancer-segregating kindred. Furthermore, through interrogation of UK Biobank and a large multi-center ovarian cancer cohort, we find significant associations between SGE-depleted variants and cancer diagnoses.

Topics & Concepts

BiologyComputational biologySaturation (graph theory)Genome editingGenomeGeneticsGeneCombinatoricsMathematicsCRISPR and Genetic EngineeringRNA and protein synthesis mechanismsRNA regulation and disease
High-resolution functional mapping of RAD51C by saturation genome editing | Litcius