M2 proton channel structural validation from full-length protein samples in synthetic bilayers and E. coli membranes.

TLDR: Exactly how well the native membrane needs to be modeled to achieve a native membrane protein structure is explored here, where the structure of the tetrameric M2 conductance domain (M2CD; residues 22–62; PDB #2L0J) that has been structurally characterized in synthetic lipid bilayers is validated.

Abstract: Membrane protein structure and function, especially for small membrane proteins, can be highly sensitive to the membrane mimetic environment used for structural characterization, as exemplified by the M2 protein from influenza A virus that has been characterized in liquid crystalline lipid bilayers, detergent micelles and in detergent based crystals.[3–8] Various transmembrane (TM) helical tilt angles, different drug binding sites and amphipathic helix interactions, as well as a lack of consensus on the sidechain geometry for the functionally critical residues is apparent from this set of structures. Many of these structural differences can be explained based on the influence of the protein's environment. Hydrophobic thickness influences the helical tilt; detergent penetration into the helical bundle and crystal contacts influence the packing and hence tilt of the helices, while the highly curved surface of micelles destabilize the interactions of amphipathic helices with what would be the bilayer interface.[9] These structural perturbations can influence functional properties such as the binding of the antiviral drug to the protein and our understanding of the proton channel functional mechanism. Exactly how well the native membrane needs to be modeled to achieve a native membrane protein structure is explored here, where we aim to validate the structure of the tetrameric M2 conductance domain (M2CD; residues 22–62; PDB #2L0J) that has been structurally characterized in synthetic lipid bilayers. We have set out to do this by observing the full length protein in synthetic bilayers, as well as in native E. coli membranes. For the first time we report on structural insights from the full length M2 (M2FL) protein using magic angle spinning solid state NMR (ssNMR) and we present spectra of the protein as it is inserted into the E. coli membranes by the cellular apparatus without ever being exposed to a detergent environment. These results validate the earlier structural results obtained from the M2CD observed in a liquid crystalline bilayer envionment.