Intracellular delivery is a bottleneck in the development of therapeutic peptides and proteins. Here, we demonstrate the efficient delivery of omoMYC, the first MYC inhibitor in clinical trials, using HBpep-SP, an engineered peptide forming liquid-liquid phase-separated coacervates. HBpep-SP coacervates facilitate efficient cellular uptake and intracellular delivery of the omoMYC peptide at concentrations lower than those required for spontaneous uptake. Strikingly, omoMYC coacervates result in reduced proliferation and apoptosis induction in the low c-MYC expressing cell lines HEK293 and SH-SY5Y cells, but not in HeLa and SK-N-BE(2) cells with high c-MYC/MYCN expression, respectively, suggesting that endogenous MYC/N levels may impact the effects of omoMYC. Importantly, our approach bypasses the need for cell penetration-enhancing chemical modifications, offering a novel strategy for the investigation of peptide drug mechanisms in therapeutic development.
Keywords: drug delivery; liquid−liquid phase separation; protein engineering.