5’ modifications to CRISPR Cas9 gRNA can change the dynamics and size of R-loops and inhibit DNA cleavage

Abstract

A key aim in exploiting CRISPR-Cas is the engineering of gRNA to introduce additional functionalities, ranging from small nucleotide changes that increase efficiency of on-target binding to the inclusion of large functional RNA aptamers and ribonucleoproteins (RNPs. Interactions between gRNA and Cas9 are crucial for RNP complex assembly but several distinct regions of the gRNA are amenable to modification. Using a library of modified gRNAs, we used in vitro ensemble and single-molecule assays to assess the impact of RNA structural alterations on RNP complex formation, R-loop dynamics, and endonuclease activity. Our results indicate that R-loop formation and DNA cleavage activity are essentially unaffected by gRNA modifications of the Upper Stem, first Hairpin and 3’ end. In contrast, 5’ additions of only two or three nucleotides reduced R-loop formation and cleavage activity of the RuvC domain relative to a single nucleotide addition. Such gRNA modifications are a common by-product of in vitro transcribed gRNA. We also observed that addition of a 20 nt RNA hairpin to the 5’ end supported formation of a stable ~9 bp R-loop that could not activate DNA cleavage. These observations will assist in successful gRNA design.