ABSTRACT
CRISPR biotechnologies, where CRISPR effectors recognize and degrade specific nucleic acid targets that are complementary to their guide RNA (gRNA) cofactors, have been primarily used as a tool for precision gene editing1 but possess an emerging potential for novel antiviral diagnostics, prophylactics, and therapeutics.2–5 In gene editing applications, significant efforts are made to limit the natural tolerance of CRISPR effectors for nucleic acids with imperfect complementarity to their gRNAs in order to prevent degradation and mutation at unintended or “off-target” sites; here we exploit those tolerances to engineer gRNAs that are optimized to promote activity at multiple viral target sites, simultaneously, given that multiplexed targeting is a critical tactic for improving viral detection sensitivity,3 expanding recognition of clinical strain variants,6 and suppressing viral mutagenic escape from CRISPR antivirals.7 We demonstrate in vitro and in higher plants that single “polyvalent” gRNAs (pgRNAs) in complex with CRISPR effectors Cas9 or Cas13 can effectively degrade pairs of viral targets with significant sequence divergence (up to 40% nucleotide differences) that are prevalent in viral genomes. We find that CRISPR antivirals using pgRNAs can robustly suppress the propagation of plant RNA viruses, in vivo, better than those with a “monovalent” gRNA counterpart. These results represent a powerful new approach to gRNA design for antiviral applications that can be readily incorporated into current viral detection and therapeutic strategies, and highlight the need for specific approaches and tools that can address the differential requirements of precision gene editing vs. CRISPR antiviral applications in order to mature these promising biotechnologies.
Competing Interest Statement
EAJ has filed a provisional patent through the UNCG Innovation and Partnership Services Office, with regards to this work, with the aim of ensuring this technology can be made available for antiviral research and deployment. EAJ is also listed as the inventor on an unrelated patent application regarding CRISPR technologies.