Membrane-Bound Dynamic Structure of an Arginine-Rich Cell-Penetrating Peptide, the Protein Transduction Domain of HIV TAT, from Solid-State NMR

Abstract

The protein transduction domain of HIV-1 TAT, TAT(48−60), is an efficient cell-penetrating peptide (CPP) that diffuses across the lipid membranes of cells despite eight cationic Arg and Lys residues. To understand its mechanism of membrane translocation against the free energy barrier, we have conducted solid-state NMR experiments to determine the site-specific conformation, dynamics, and lipid interaction of the TAT peptide in anionic lipid bilayers. We found that TAT(48−60) is a highly dynamic and nearly random coil peptide in the lipid bilayer and inserts into the membrane−water interface near the glycerol backbone region. Arg−phosphate salt bridge interaction was revealed by short guanidinium−phosphate distances and restricted dynamics of the guanidinium. Together with the observation of strong peptide−water cross-peaks in ¹H spin diffusion spectra, these results indicate that TAT binding to the membrane−water interface is stabilized not only by electrostatic attraction to the anionic lipids but also by intermolecular hydrogen bonding with the lipid phosphates and water, which may take the role of intramolecular hydrogen bonds in canonical secondary structures. The random coil structure of TAT and another CPP, penetratin, suggests that the lack of amphipathic structure is essential for rapid translocation of these Arg-rich CPPs across the lipid membrane without causing permanent damages to the membrane integrity.