Abstract
Crossing the cellular membrane is one of the main barriers during drug discovery; many potential drugs are rejected for their inability to integrate into the intracell fluid. Although many solutions have been proposed to overcome this barrier, arguably the most promising solution is the use of cell-penetrating peptides. Recently, an array of hydrophobic penetrating peptides was discovered via high throughput screening which proved to be able to cross the membrane passively, and although these peptides proved to be effective at penetrating the cell, the details behind the underlying mechanism of this process remain unknown. In this study, we developed a method to find the equilibrium structure at the transmembrane domain of TP1, a hydrophobic penetrating peptide. In this method, we selectively deuterium-label amino acids in the peptidic chain, and employ results of [Formula: see text]H-NMR spectroscopy to find a molecular dynamics simulation of the peptide that reproduces the experimental results. Effectively finding the equilibrium orientation and dynamics of the peptide in the membrane. We employed this equilibrium structure to simulate the entire translocation mechanism and found that after the peptide reaches its equilibrium structure, it must undergo a two-step mechanism in order to completely translocate the membrane, each step involving the flip-flop of each arginine residue in the peptide. This leads us to conclude that the RLLR motif is essential for the translocating activity of the peptide.