Abstract
The application of gene-editing technology is currently limited by the lack of safe and efficient methods to deliver RNA-guided endonucleases to target cells. We engineered lentivirus-based nanoparticles to co-package the U6-sgRNA template and the CRISPR-associated protein 9 (Cas9) fused with a virion-targeted protein Vpr (Vpr.Prot.Cas9), for simultaneous delivery to cells. Equal spatiotemporal control of the vpr.prot.cas9 and gag/pol gene expression (the presence of Rev responsive element, RRE) greatly enhanced the encapsidation of the fusion protein and resulted in the production of highly efficient lentivector nanoparticles. Transduction of the unconcentrated, Vpr.Prot.Cas9-containing vectors led to >98% disruption of the EGFP gene in reporter HEK293-EGFP cells with minimal cytotoxicity. Furthermore, we detected indels in the targeted endogenous loci at frequencies of up to 100% in cell lines derived from lymphocytes and monocytes and up to 15% in primary CD4+ T cells by high-throughput sequencing. This approach may provide a platform for the efficient, dose-controlled and tissue-specific delivery of genome editing enzymes to cells and it may be suitable for simultaneous endogenous gene disruption and a transgene delivery.