Direct delivery of Cas-embedded cytosine base editors as ribonucleoprotein complexes for efficient and accurate editing of clinically relevant targets.

Recently, cytosine base editors (CBEs) have emerged as a promising therapeutic tool for specific editing of single nucleotide variants and disrupting specific genes associated with disease. Despite this promise, the currently available CBEs have the significant liabilities of off-target and bystander editing activities, partly due to the mechanism by which they are delivered, causing limitations in their potential applications. In this study, we engineered optimized, soluble and stable Cas-embedded CBEs (CE_CBEs) that integrate several recent advances, which were efficiently formulated for direct delivery into cells as ribonucleoprotein (RNP) complexes.

Next generation APOBEC3 inhibitors: Optimally designed for potency and nuclease stability.

APOBEC3 (or A3) enzymes have emerged as potential therapeutic targets due to their role in introducing heterogeneity in viruses and cancer, often leading to drug resistance. Inhibiting these enzymes has remained elusive as initial phosphodiester (PO) linked DNA based inhibitors lack stability and potency. We have enhanced both potency and nuclease stability, of 2'-deoxy-zebularine (dZ), substrate-based oligonucleotide inhibitors for two critical A3's: A3A and A3G.

Direct delivery of stabilized Cas-embedded base editors achieves efficient and accurate editing of clinically relevant targets.

Over the last 5 years, cytosine base editors (CBEs) have emerged as a promising therapeutic tool for specific editing of single nucleotide variants and disrupting specific genes associated with disease. Despite this promise, the currently available CBE's have the significant liabilities of off-target and bystander editing activities, in part due to the mechanism by which they are delivered, causing limitations in their potential applications. In this study we engineeredhighly stabilized Cas-embedded CBEs (sCE_CBEs) that integrate several recent advances, andthat are highly expressible and soluble for direct delivery into cells as ribonucleoprotein (RNP) complexes.