Influence of a Potentially Destabilizing Central Tryptophan on Transmembrane Helix Domains

Abstract

Synthetic model peptides, such as GWALP23 (acetyl-GGALW5LALALALALALALW19LAGA-amide), provide a favorable “host” framework for investigations of the influence of chosen “guest” amino acids. For example, it is of interest to know the consequences of having a third, centrally located, tryptophan (Trp) within the hydrophobic core of a well characterized, anchored, transmembrane helix. It is crucial to note that the orientation and rotation of GWALP23 are sensitive to single-residue replacements, in part because the membrane-spanning helix exhibits only limited dynamic averaging of solid-state NMR observables such as the 2H quadrupolar splitting (Biophys. J. 101, 2939). A Trp residue was introduced in the 12th or 13th position of GWALP23, and specific deuterated alanine labels (2H-Ala) were included as probes within the core helical sequence. The 2H quadrupolar splittings from solid-state NMR spectra of GWALP23-W12 and GWALP23-W13 show that the peptide remains helical and retains a dominant preferred tilted transmembrane orientation (similar to GWALP23) in lipid bilayer membranes of DOPC, DLPC, and DMPC. Modified Gaussian and semi-static treatments of the dynamics yield similar conclusions. While a central Trp at position 12 or 13 does not alter the characteristics of bilayer-spanning GWALP23, incorporation of the peptide helix into the bilayer membrane becomes more difficult. The properties of W4, 5 GWALP23 are also being investigated, for comparison with the highly dynamic Y4, 5 and the less dynamic F4, 5 peptides. Deuterium labels at Ala3 and Ala21 will allow assessment of possible fraying of the ends of selected helices in differing lipid membrane environments.