Approaches and materials for endocytosis-independent intracellular delivery of proteins

Abstract

The intracellular delivery of proteins is of great significance. For diseases such as cancer, heart disease and neurodegenerative diseases, many important pharmacological targets are located inside cells. For genetic engineering and cell engineering, various functional proteins need to be delivered into cells for gene editing or cell state regulation. However, most existing protein delivery strategies involve endosomal escape (endocytosis-dependent), resulting in inefficient delivery due to endosome trapping. In contrast, endocytosis-independent intracellular delivery, which refers to the directly delivery of proteins across the cell membrane to the cytoplasm, will bypass the low efficiency of early endosomal escape, avoid protein inactivation caused by late endosome/lysosome, fundamentally improve the intracellular delivery efficiency, and open up a new way for intracellular protein delivery. In this review, the latest advances in direct intracellular delivery of proteins through membrane perforation, membrane translocation, and membrane fusion were summarized. The mechanisms, related materials and potential therapeutic in living cells/in vivo for each approach were discussed in detail, and the future development in this promising field was briefly presented.