The authors present a system for modulating CRISPR activity in response to RNA detection using engineered single-guide RNAs (iSBH-sgRNAs). The iSBH-sgRNAs are designed to fold into complex secondary structures that inhibit their activity in the absence of complementary RNA triggers. When the iSBH-sgRNAs detect their target RNA sequences, the structures unfold, activating the CRISPR system and enabling transcriptional regulation.
The authors first demonstrate that first-generation iSBH-sgRNA designs can detect short RNA triggers and activate CRISPR transcriptional activators (dCas9-Vp64) in HEK293T cells. They then optimize the designs to enable detection of longer RNA triggers up to 300 nucleotides.
To further improve the system, the authors develop the MODesign computational pipeline, which allows for the independent design of the CRISPR target sequence and the RNA-sensing component. This modular approach enables detection of a wider range of RNA sequences.
Mechanistic investigations reveal that the iSBH-sgRNA activation involves cleavage of the engineered sgRNA components, likely by cellular double-stranded RNA processing pathways. The authors identify key positions for chemical modifications to stabilize the iSBH-sgRNAs and demonstrate their functionality in zebrafish embryos.
The authors discuss the potential of this RNA-sensing CRISPR technology for developing more specific and effective gene editing approaches, as well as therapeutic applications that leverage endogenous RNA biomarkers to control CRISPR activity.
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by Pelea,O., Ma... о www.biorxiv.org 05-08-2023
https://www.biorxiv.org/content/10.1101/2023.05.08.539738v2Глибші Запити