The left-handed, extended polyproline II (PPII) helix is a unique secondary structure which potently modulates peptide/protein functions through its constraint conformation. To investigate the effect of PPII helix on the direct cell membrane penetration of arginine-rich peptides, we designed a polyproline-containing arginine-rich peptide P9R7W (PPPPPPPPPRRRRRRRW) by introducing nine proline residues into a linear R7W (RRRRRRRW) peptide. Circular dichroism spectroscopy showed that P9R7W has the PPII helix structure in solution whereas R7W is predominantly in random coil structure. Tryptophan fluorescence measurements demonstrated that P9R7W binds to negatively charged lipid vesicles with similar affinity to R7W, in which there was no significant change in the PPII helix structure. Flow cytometry and confocal laser scanning microscopy analyses showed that P9R7W has an ability to penetrate into CHO-K1 cells more efficiently compared to R7W with no cytotoxicity. Consistently, a channel current analysis unveiled that P9R7W penetrates planar lipid bilayer membranes more efficiently than R7W without significant membrane perturbation. Our results indicate that the PPII helix structure can enhance the membrane penetration efficiency of arginine-rich peptides without lipid membrane perturbation.
Keywords: Arginine-rich peptide; Cell membrane penetration; Lipid membrane; Polyproline II helix.
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