Lidia Cristian

Use of thiol-disulfide equilibria to measure the energetics of assembly of transmembrane helices in phospholipid bilayers

Despite significant efforts and promising progress, the understanding of membrane protein folding lags behind that of soluble proteins. Insights into the energetics of membrane protein folding have been gained from biophysical studies in membrane-mimicking environments (primarily detergent micelles). However, the development of techniques for studying the thermodynamics of folding in phospholipid bilayers remains a considerable challenge. We had previously used thiol-disulfide exchange to study the thermodynamics of association of transmembrane α-helices in detergent micelles; here, we extend this methodology to phospholipid bilayers. The system for this study is the homotetrameric M2 proton channel protein from the influenza A virus. Transmembrane peptides from this protein specifically self-assemble into tetramers that retain the ability to bind to the drug amantadine. Thiol-disulfide exchange under equilibrium conditions was used to quantitatively measure the thermodynamics of this folding interaction in phospholipid bilayers. The effects of phospholipid acyl chain length and cholesterol on the peptide association were investigated. The association of the helices strongly depends on the thickness of the bilayer and cholesterol levels present in the phospholipid bilayer. The most favorable folding occurred when there was a good match between the width of the apolar region of the bilayer and the hydrophobic length of the transmembrane helix. Physiologically relevant variations in the cholesterol level are sufficient to strongly influence the association. Evaluation of the energetics of peptide association in the presence and absence of cholesterol showed a significantly tighter association upon inclusion of cholesterol in the lipid bilayers.

Amide vibrations are delocalized across the hydrophobic interface of a transmembrane helix dimer

The tertiary interactions between amide-I vibrators on the separate helices of transmembrane helix dimers were probed by ultrafast 2D vibrational photon echo spectroscopy. The 2D IR approach proves to be a useful structural method for the study of membrane-bound structures. The 27-residue human erythrocyte protein Glycophorin A transmembrane peptide sequence: KKITLIIFG79VMAGVIGTILLISWG94IKK was labeled at G79 and G94 with 13C16O or 13C18O. The isotopomers and their 50:50 mixtures formed helical dimers in SDS micelles whose 2D IR spectra showed components from homodimers when both helices had either 13C16O or 13C18O substitution and a heterodimer when one had 13C16O substitution and the other had 13C18O substitution. The cross-peaks in the pure heterodimer 2D IR difference spectrum and the splitting of the homodimer peaks in the linear IR spectrum show that the amide-I mode is delocalized across a pair of helices. The excitation exchange coupling in the range 4.3–6.3 cm−1 arises from through-space interactions between amide units on different helices. The angle between the two Gly79 amide-I transition dipoles, estimated at 103° from linear IR spectroscopy and 110° from 2D IR spectroscopy, combined with the coupling led to a structural picture of the hydrophobic interface that is remarkably consistent with results from NMR on helix dimers. The helix crossing angle in SDS is estimated at 45°. Two-dimensional IR spectroscopy also sets limits on the range of geometrical parameters for the helix dimers from an analysis of the coupling constant distribution.

The Interplay of Functional Tuning, Drug Resistance, and Thermodynamic Stability in the Evolution of the M2 Proton Channel from the Influenza A Virus

We explore the interplay between amino acid sequence, thermodynamic stability, and functional fitness in the M2 proton channel of influenza A virus. Electrophysiological measurements show that drug-resistant mutations have minimal effects on M2s specific activity, and suggest that resistance is achieved by altering a binding site within the pore rather than a less direct allosteric mechanism. In parallel, we measure the effects of these mutations on the free energy of assembling the homotetrameric transmembrane pore from monomeric helices in micelles and bilayers. Although there is no simple correlation between the evolutionary fitness of the mutants and their stability, all variants formed more stable tetramers in bilayers, and the least-fit mutants showed the smallest increase in stability upon moving from a micelle to a bilayer environment. We speculate that the folding landscape of a micelle is rougher than that of a bilayer, and more accommodating of conformational variations in nonoptimized mutants.

Determination of membrane protein stability via thermodynamic coupling of folding to thiol–disulfide interchange

Although progress has been made in understanding the thermodynamic stability of water‐soluble proteins, our understanding of the folding of membrane proteins is at a relatively primitive level. A major obstacle to understanding the folding of membrane proteins is the discovery of systems in which the folding is in thermodynamic equilibrium, and the development of methods to quantitatively assess this equilibrium in micelles and bilayers. Here, we describe the application of disulfide cross‐linking to quantitatively measure the thermodynamics of membrane protein association in detergent micelles. The method involves initiating disulfide cross‐linking of a protein under reversible redox conditions in a thiol–disulfide buffer and quantitative assessment of the extent of cross‐linking at equilibrium. The 19–46 α‐helical transmembrane segment of the M2 protein from the influenza A virus was used as a model membrane protein system for this study. Previously it has been shown that transmembrane peptides from this protein specifically self‐assemble into tetramers that retain the ability to bind to the drug amantadine. We used thiol–disulfide exchange to quantitatively measure the tetramerization equilibrium of this transmembrane protein in dodecylphosphocholine (DPC) detergent micelles. The association constants obtained agree remarkably well with those derived from analytical ultracentrifugation studies. The experimental method established herein should provide a broadly applicable tool for thermodynamic studies of folding, oligomerization and protein–protein interactions of membrane proteins.

Mechanistic insights from functional characterization of an unnatural His37 mutant of the influenza A/M2 protein.

The influenza A/M2 protein is a homotetrameric single-pass integral membrane protein encoded by the influenza A viral genome. Its transmembrane domain represents both a crucial drug target and a minimalistic model system for transmembrane proton transport and charge stabilization. Recent structural and functional studies of M2 have suggested that the proton transport mechanism involves sequential extraviral protonation and intraviral deprotonation of a highly conserved His37 side chain by the transported proton, consistent with a pH-activated proton shuttle mechanism. Multiple tautomeric forms of His can be formed, and it is not known whether they contribute to the mechanism of proton shuttling. Here we present the thermodynamic and functional characterization of an unnatural amino acid mutant at His37, where the imidazole side chain is substituted with a 4-thiazolyl group that is unable to undergo tautomerization and has a significantly lower solution pKa. The mutant construct has a similar stability to the wild-type protein at pH8 in bilayers and is virtually inactive at external pH7.4 in a semiquantitative liposome flux assay as expected from its lower sidechain pKa. However when the external buffer pH is lowered to 4.9 and 2.4, the mutant shows increasing amantadine sensitive flux of a similar magnitude to that of the wild type construct at pH7.4 and 4.9 respectively. These findings are in line with mechanistic hypotheses suggesting that proton flux through M2 is mediated by proton exchange from adjacent water molecules with the His37 sidechain, and that tautomerization is not required for proton translocation. This article is part of a Special Issue entitled: Viral Membrane Proteins - Channels for Cellular Networking.

Nanosecond dynamics of influenza A/M2TM and an amantadine resistant mutant probed by time-dependent red shifts of a native tryptophan

Proteins involved in functions such as electron transfer or ion transport must be capable of stabilizing transient charged species on time scales ranging from picoseconds to microseconds. We study the influenza A M2 proton channel, containing a tryptophan residue that serves as an essential part of the proton conduction pathway. We induce a transition dipole in tryptophan by photoexcitation, and then probe the dielectric stabilization of its excited state. The magnitude of the stabilization over this time regime was larger than that generally found for tryptophan in membrane or protein environments. M2 achieves a water-like stabilization over a 25 nanosecond time scale, slower than that of bulk water, but sufficiently rapid to contribute to stabilization of charge as protons diffuse through the channel. These measurements should stimulate future MD studies to clarify the role of sidechain versus non-bulk water in defining the process of relaxation.