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RNA structure modulates Cas13 activity and enables mismatch detection

Bianca Larsen, Ofer Kimchi, Owen R. S. Dunkley, M. Grimm, Jurre Y. Siegers, Yujia Huang, Venu Gopal Vandavasi, Long Thành Nguyễn, Caitlin H. Lamb, Irina Aranovich, Dirk Eggink, Adam Meijer, Hamid Jalal, Daniel A. Notterman, Erik A. Karlsson, Aartjan J.W. te Velthuis, Cameron Myhrvold

2025Nature Biotechnology11 citationsDOIOpen Access PDF

Abstract

Cas13 is activated by the hybridization of a CRISPR RNA to a complementary single-stranded RNA protospacer in a target RNA. While Cas13 is not activated by double-stranded RNA in vitro, it robustly targets RNA in cellular environments where RNAs are highly structured. The mechanism by which Cas13 targets structured RNAs remains unknown. Here, we systematically probe the effects of secondary structure on Cas13. We find that secondary structure in the protospacer and 3' to it inhibits Cas13 activity and quantitatively explains the former effect through a strand displacement framework. We then harness strand displacement to generate an 'occluded' Cas13, which enhances mismatch discrimination up to 50-fold and enables sequence-agnostic mutation identification at low (<1%) allele frequencies. Using occluded Cas13, we identify human-adaptive mutations in SARS-CoV-2 and human and avian influenza A viruses, as well as oncogenic mutations in KRAS. Our work leverages improved mechanistic understanding of Cas13 to expand the scope of RNA diagnostics and enable structure-informed Cas13 approaches.

Topics & Concepts

RNACell biologyChemistryRNA interferenceCRISPRDisplacement (psychology)RNA silencingComputational biologySmall interfering RNAMechanism (biology)BiologyMolecular biologyMutationmicroRNARNA editingNon-coding RNAOligonucleotideNucleic acid structureRegulation of gene expressionGene expressionCRISPR and Genetic EngineeringRNA and protein synthesis mechanismsViral Infections and Immunology Research