Oral Microto-Nano Genome-Editing System Enabling Targeted Delivery and Conditional Activation of CRISPR-Cas9 for Gene Therapy of Inflammatory Bowel Disease

Abstract

The potent CRISPR-Cas9 technology can correct genes in human mutated cells to achieve the treatment of multiple diseases, but it lacks safe and effective delivery systems. Herein, we proposed an oral microto-nano genome-editing system aiming at the enteric excessive level of TNF-α for specific gene therapy of inflammatory bowel disease (IBD). This editing system facilitated the assembly of Cas9/sgRNA ribonucleoprotein (RNP) into nanoclusters (NCs) through the bridging of disulfide bonds. RNP-NCs were subsequently encapsulated within inflammatory cell-targeted lipopolysaccharide-deleted outer membrane vesicles (dOMVs) sourced from Escherichia coli Nissle 1917, which were further shielded by an outer layer of calcium alginate microspheres (CAMs). By leveraging the protection effect of CAMs, the oral administration system withstood gastric acid degradation upon entry into the stomach, achieving targeted delivery to the intestines with high efficiency. As the pH gradually rose, the microscale CAMs swelled and disintegrated, releasing nanoscale RNP-NCs encapsulated in dOMVs into the intestines. These RNP-NCs@dOMVs could traverse the mucosal barrier and target inflammatory macrophages where conditionally activated Cas9/sgRNA RNPs effectively perform genomic editing of TNF-α within the nucleus. Such oral microto-nano genome-editing systems represent a promising translational platform for the treatment of IBD.