Deletion of a terminal residue disrupts oligomerization of a transmembrane alpha-helix.

In studies of the structural biology of membrane proteins, the success of strategies based on the "divide and conquer" approach, where peptides are used to model the individual transmembrane (TM) alpha-helices of membrane proteins, depends on the correct identification of the membrane-embedded TM alpha-helix amino acid sequence within the full-length protein. In the present work, we examine the effects of excluding or including TM boundary residues on the intrinsic properties of a Lys-tagged TM2 alpha-helix of myelin proteolipid protein (PLP), of parent sequence KKKK-66AFQYVIYGTASFFFLYGALLLAEG89-KKKK along with analogs containing an additional wild type Phe-90, Phe-90 and Tyr-91, and of a hydrophobic mutant Leu-90. Using protein gel electrophoresis, circular dichroism, and fluorescence resonance energy transfer in the membrane-mimetic detergent sodium dodecylsulfate (SDS), we demonstrate that the removal of a single amino acid from the C-terminus of this TM segment is enough to change its intrinsic properties, with TM2 66-89 displaying only a monomeric form, but with dimers arising for the other 3 peptides. A novel use of trifluoroethanol (TFE) as a maximal helix-supporting solvent demonstrated that peptides containing residues at positions 90 and (or) 90-91 displayed significantly increased helical content vs. the TM2 parent peptide. The findings suggest that deletion of critical C-terminal residue(s) tends to reposition the helix terminus toward the membrane-aqueous interface. Our overall results emphasize the potential influence of boundary residues on TM properties when using peptides as models for TM alpha-helices, and may implicate a role for these residues in membrane protein folding and assembly.