PAM-interacting domain turn-helix 51 motifs can improve Cas9-SpRY activity.

Cas9-SpRY is an engineered variant of the Streptococcus pyogenes Cas9 with relaxed PAM recognition, which can technically be utilized at any target in the genome but some targets are addressed with low efficiency. Here, we show that a previously unexplored motif at the turn and beginning of α-helix 51 (TH51) can be engineered to improve both nuclease and prime-editing activity of Cas9-SpRY. Interaction of the lysine-rich PID loop 2 (PL2) with the target DNA downstream of the PAM (post-PAM) mediates initiation of R-loop formation and subsequent cleavage yet it was unclear if other regions of the PID engage with post-PAM as well. To this end, the NAAN-PAM-targeting iSpyMac hybrid nuclease, which lacks all lysine residues in PL2, was compared with Cas9-SpRY at identical targets using molecular dynamics simulation and in cell culture models, uncovering four crucial post-PAM-interacting lysines in TH51 and TH53 of iSpyMac. Ectopic insertion of a lysine-rich PL2 into iSpyMac boosted its nuclease and prime-editing activities and, in turn, Cas9-SpRY benefited from certain lysine-rich TH51 motifs. Specifically, TH51 from an uncultured Abiotrophia Cas9 species boosted overall Cas9-SpRY activity. Together, this study demonstrates that engineering of post-PAM interacting motifs opens new avenues for the design of advanced CRISPR enzymes.