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RNA variant assessment using transactivation and transdifferentiation

Emmylou C Nicolas-Martinez, O.F. Robinson, Christian Pflueger, Alison Gardner, Mark Corbett, Tarin Ritchie, Thessa Kroes, Clare L. van Eyk, Ingrid E. Scheffer, Michael S. Hildebrand, Jean‐Vianney Barnier, Véronique Rousseau, David Geneviève, Virginie Haushalter, Amélie Piton, Anne‐Sophie Denommé‐Pichon, Ange‐Line Bruel, Sophie Nambot, Bertrand Isidor, John Grigg, Tina Gonzalez, Sondhya Ghedia, Rhett G. Marchant, Adam Bournazos, Wui‐Kwan Wong, Richard Webster, Frances J. Evesson, Kristi Jones, Dimitar N. Azmanov, Christopher P. Barnett, Simon C. Barry, Gareth Baynam, Samuel F. Berkovic, John Christodoulou, David J. Coman, Sandra Cooper, Mark A. Corbett, Martin Delatycki, Tracy E. Dudding, Sue Fletcher, Alison E. Gardner, Jozef Gecz, Jozef Gecz, Megan J. Higgins, Michael S. Hildebrand, Lachlan A. Jolly, Lachlan A. Jolly, Ryan Lister, Julie McGaughran, Christian Pflueger, Cathryn Poulton, Tony Roscioli, Ingrid Scheffer Hamish S. Scott, Andrew H. Sinclair, Amanda B. Spurdle, Tiong Y. Tan, Clare L. van Eyk, Irina Voineagu, Sandra T. Cooper, Ryan Lister, Jozef Gécz, Jozef Gécz, Lachlan A. Jolly, Lachlan A. Jolly

2024The American Journal of Human Genetics19 citationsDOIOpen Access PDF

Abstract

Understanding the impact of splicing and nonsense variants on RNA is crucial for the resolution of variant classification as well as their suitability for precision medicine interventions. This is primarily enabled through RNA studies involving transcriptomics followed by targeted assays using RNA isolated from clinically accessible tissues (CATs) such as blood or skin of affected individuals. Insufficient disease gene expression in CATs does however pose a major barrier to RNA based investigations, which we show is relevant to 1,436 Mendelian disease genes. We term these "silent" Mendelian genes (SMGs), the largest portion (36%) of which are associated with neurological disorders. We developed two approaches to induce SMG expression in human dermal fibroblasts (HDFs) to overcome this limitation, including CRISPR-activation-based gene transactivation and fibroblast-to-neuron transdifferentiation. Initial transactivation screens involving 40 SMGs stimulated our development of a highly multiplexed transactivation system culminating in the 6- to 90,000-fold induction of expression of 20/20 (100%) SMGs tested in HDFs. Transdifferentiation of HDFs directly to neurons led to expression of 193/516 (37.4%) of SMGs implicated in neurological disease. The magnitude and isoform diversity of SMG expression following either transactivation or transdifferentiation was comparable to clinically relevant tissues. We apply transdifferentiation and/or gene transactivation combined with short- and long-read RNA sequencing to investigate the impact that variants in USH2A, SCN1A, DMD, and PAK3 have on RNA using HDFs derived from affected individuals. Transactivation and transdifferentiation represent rapid, scalable functional genomic solutions to investigate variants impacting SMGs in the patient cell and genomic context.

Topics & Concepts

TransactivationTransdifferentiationBiologyTranscriptomeGene expressionSmall hairpin RNAGeneticsGeneRNAComputational biologyCellCRISPR and Genetic EngineeringRNA Research and SplicingGenomics and Rare Diseases
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