Split Cas12a protospacer engineering enables ultra-specific, PAM-free detection

CRISPR-Cas12a is a programmable, RNA-guided endonuclease that has revolutionized biotechnology, with applications in genome engineering and diagnostics. To induce nuclease activity, Cas12a must first interact with the target dsDNA duplex by associating with a short protospacer adjacent motif (PAM) in the sequence. In this study we have split this target duplex to create PAM-proximal and PAM-distal duplex regions, which has allowed us to regulate trans-cleavage activity when these regions are included in combination or separately. These observations on Cas12a activity led to hypotheses into the related functional mechanisms, which we have tested and that have highlighted DNA/protein interactions during Cas12a complex assembly that were not otherwise apparent. Selective destabilization of the nucleic acid complexes appears to drive greater reliance on the Cas12a protein for complex stability. We have exploited this to provide significant improvements in both structural selectivity and nucleotide specificity in PAM-proximal and PAM-distal duplex regions, respectively. The result is an architecture that shows promise as a PAM-free ultra-specific platform to resolve single nucleotide polymorphisms.