Abstract
CRISPR-Cas13d is increasingly used for RNA knockdowns due to its programmability, but off-target RNA binding and cleavage of near-cognate RNAs hinder its broader adoption. Here, we explore the mechanisms of nuclease activation by solving seven ternary cryo-electron mi-croscopy structures of wild-type Cas13d in complex with matched and mismatched targets. These structures reveal a series of active, intermediate, and inactive states that illustrate a detailed activation mechanism. The crRNA undergoes dramatic conformational changes upon target RNA binding, with the helical-1 domain transitioning from an initially docked state with the N-terminal domain to an allosterically switched conformation that stabilizes the RNA duplex. Quantitative kinetics reveal that a single proximal mismatch preserves nanomolar binding affinity but completely abolishes nuclease activity by trapping Cas13d in an inactive state. We identify an active site loop in the HEPN domains that regulates substrate accessibility, with alanine scanning mutagenesis revealing both hypo- and hyperactivated variants. These findings establish the structural basis for Cas13d’s exquisite mismatch surveillance and provide a mechanistic framework for engineering RNA-targeting specificity and activity across HEPN nuclease family members.
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Abstract
CRISPR-Cas13d is increasingly used for RNA knockdowns due to its programmability, but off-target RNA binding and cleavage of near-cognate RNAs hinder its broader adoption. Here, we explore the mechanisms of nuclease activation by solving seven ternary cryo-electron mi-croscopy structures of wild-type Cas13d in complex with matched and mismatched targets. These structures reveal a series of active, intermediate, and inactive states that illustrate a detailed activation mechanism. The crRNA undergoes dramatic conformational changes upon target RNA binding, with the helical-1 domain transitioning from an initially docked state with the N-terminal domain to an allosterically switched conformation that stabilizes the RNA duplex. Quantitative kinetics reveal that a single proximal mismatch preserves nanomolar binding affinity but completely abolishes nuclease activity by trapping Cas13d in an inactive state. We identify an active site loop in the HEPN domains that regulates substrate accessibility, with alanine scanning mutagenesis revealing both hypo- and hyperactivated variants. These findings establish the structural basis for Cas13d’s exquisite mismatch surveillance and provide a mechanistic framework for engineering RNA-targeting specificity and activity across HEPN nuclease family members.
Competing Interest Statement
The authors have declared no competing interest.
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