Characterization of the membrane penetration-enhancing peptide S19 derived from human syncytin-1 for the intracellular delivery of TAT-fused proteins.

Although cell-penetrating peptides such as the HIV-derived TAT peptide have been used as tools for the intracellular delivery of therapeutic peptides and proteins, a problem persists: the endosomal escape efficiency is low. Previously, we found that the fusogenic peptide S19, derived from the human protein syncytin-1, enhance the endosomal escape efficiency of proteins that incorporated by endocytosis via TAT. In this study, we first performed Ala-scanning mutagenesis of S19, and found that all Ile, Val, Leu and Phe with high ß-sheet forming propensities in S19 are important for the intracellular uptake of S19-TAT-fused proteins. In a secondary structure analysis of the mutated S19-TAT peptides in the presence of liposomes mimicking late endosomes (LEs), the CD spectra of V3A and I4A mutants with low uptake activity showed the appearance of an α-helix structure, whereas the mutant G5A retained both the uptake activity and the ß-structure. In addition, we investigated the appropriate linking position and order of the S19 and TAT peptides to a cargo protein including an apoptosis-induced peptide and found that both the previous C-terminal S19-TAT tag and the N-terminal TAT-S19 tag promote the cytoplasmic delivery of the fusion protein. These results and previous results suggest that the interaction of TAT with the LE membrane causes a structural change in S19 from a random coil to a ß-strand and that the subsequent parallel ß-sheet formation between two S19 peptides may promote adjacent TAT dimerization, resulting in endosomal escape from the LE membrane.

Human-derived fusogenic peptides for the intracellular delivery of proteins.

The cytosolic delivery of therapeutic proteins (e.g., antibodies or enzymes) by cell-penetrating peptides (CPPs), such as a human immunodeficiency virus-derived TAT peptide, is facilitated by fusogenic peptides (FPs). For instance, we recently demonstrated that an FP, B18, which is derived from a sea urchin gamete fusion protein, promotes endosomal escape of an enhanced green fluorescent protein (eGFP)-TAT fusion protein directly conjugated to it. However, the potential clinical use of FPs raises concerns because all conventional FPs are non-human-derived. To solve this problem, we have attempted to identify novel human-derived FPs from two human proteins, including a human sperm protein, IZUMO1, which is involved in gamete recognition and fusion, and a human endogenous retroviral envelope protein, Syncytin1, which is involved in placental morphogenesis. Partial peptides from the core domains of the abovementioned proteins were chosen as candidates to generate human-derived FPs. We prepared fusion proteins of these peptides with eGFP and TAT in Escherichia coli and observed the localization of these fusion proteins in HeLa cells using confocal microscopy. Our results suggested that a 19-residues peptide of Syncytin1 (positions 322-340), named S19, possessed strong intracellular uptake activities with no detectable cytotoxicity. In addition, we estimated the number of molecules that escaped from endosomes using a nuclear localization signal, suggesting that the S19 peptide stimulated the intracellular delivery of TAT-fused eGFP by ~90-fold. Furthermore, we confirmed that S19 promoted the intracellular delivery of eGFP to various human cell lines, including HeLa, A431, HepG2, and SK-N-SH. In addition, we demonstrated that not only eGFP but also SNAP-tag and ß-galactosidase were delivered efficiently and retained their activities.