Kinetic basis for DNA target specificity of CRISPR-Cas12a

Abstract

SUMMARYClass II CRISPR-Cas nucleases are programmable via a single guide RNA, enabling genome editing applications in nearly all organisms. However, DNA cleavage at off-target sites that resemble the target sequence is a pervasive problem that remains poorly understood mechanistically. Here, we use quantitative kinetics to dissect the reaction steps of DNA targeting by Acidaminococcus sp Cas12a (also known as Cpf1). We show that Cas12a binds DNA tightly in two kinetically-separable steps. Protospacer-adjacent motif (PAM) recognition is followed by rate-limiting R-loop propagation, leading to inevitable DNA cleavage of both strands. Despite the functionally irreversible binding, Cas12a discriminates strongly against mismatches along most of the DNA target sequence, implying substantial reversibility during R-loop formation –a late transition state– and the absence of a ‘seed’ region. Our results provide a quantitative underpinning for the DNA cleavage patterns measured in vivo and observations of greater reported target specificity of Cas12a than the Cas9 nuclease.