Abstract

BackgroundThe development of CRISPR genome editing has transformed biomedical research. Most applications reported thus far rely upon the Cas9 protein from Streptococcus pyogenes SF370 (SpyCas9). With many RNA guides, wildtype SpyCas9 can induce significant levels of unintended mutations at near-cognate sites, necessitating substantial efforts toward the development of strategies to minimize off-target activity. Although the genome-editing potential of thousands of other Cas9 orthologs remains largely untapped, it is not known how many will require similarly extensive engineering to achieve single-site accuracy within large genomes. In addition to its off-targeting propensity, SpyCas9 is encoded by a relatively large open reading frame, limiting its utility in applications that require size-restricted delivery strategies such as adeno-associated virus vectors. In contrast, some genome-editing-validated Cas9 orthologs are considerably smaller and therefore better suited for viral delivery.ResultsHere we show that wildtype NmeCas9, when programmed with guide sequences of the natural length of 24 nucleotides, exhibits a nearly complete absence of unintended editing in human cells, even when targeting sites that are prone to off-target activity with wildtype SpyCas9. We also validate at least six variant protospacer adjacent motifs (PAMs), in addition to the preferred consensus PAM (5′-N4GATT-3′), for NmeCas9 genome editing in human cells.ConclusionsOur results show that NmeCas9 is a naturally high-fidelity genome-editing enzyme and suggest that additional Cas9 orthologs may prove to exhibit similarly high accuracy, even without extensive engineering.

Highlights

  • The development of CRISPR genome editing has transformed biomedical research

  • Co-expressed single-guide RNA (sgRNA) increases Neisseria meningitidis Cas9 (NmeCas9) accumulation in mammalian cells Previously, we demonstrated that NmeCas9 can efficiently edit chromosomal loci in human stem cells using either dual RNAs or a sgRNA [53]

  • A different type II-C Cas9 (Corynebacterium diphtheria Cas9, Corynebacterium diptheria Cas9 (CdiCas9)) was shown to be dramatically stabilized by its cognate sgRNA when subjected to proteolysis in vitro [55]; if similar resistance to proteolysis occurs with NmeCas9 upon sgRNA binding, it could explain some or all of the sgRNA-dependent increase in cellular accumulation

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Summary

Introduction

The development of CRISPR genome editing has transformed biomedical research. Most applications reported far rely upon the Cas protein from Streptococcus pyogenes SF370 (SpyCas). In conjunction with CRISPR-associated (Cas) proteins, crRNAs recognize target nucleic acids (DNA, RNA, or both, depending on the system) by base pairing, leading to their destruction. CRISPR-Cas systems are divided into two main classes: class 1, with large, multi-subunit effector complexes, and class 2, with single-protein-subunit effectors [7]. Both CRISPR-Cas classes include multiple types based primarily on the identity of a signature effector protein. The interference function of type II CRISPR-Cas systems requires the Cas protein, the crRNA, and a separate non-coding RNA known as the trans-activating crRNA (tracrRNA) [8,9,10]. Successful interference requires that the DNA target (the “protospacer”) be highly complementary to the spacer portion of Amrani et al Genome Biology (2018) 19:214 the crRNA and that the PAM consensus be present at neighboring base pairs [11, 12]

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