The membrane-spanning domain of gp41 plays a critical role in intracellular trafficking of the HIV envelope protein.

BACKGROUND: The sequences of membrane-spanning domains (MSDs) on the gp41 subunit are highly conserved among many isolates of HIV-1. The GXXXG motif, a potential helix-helix interaction motif, and an arginine residue (rare in hydrophobic MSDs) are especially well conserved. These two conserved elements are expected to locate on the opposite sides of the MSD, if the MSD takes a α-helical secondary structure. A scanning alanine-insertion mutagenesis was performed to elucidate the structure-function relationship of gp41 MSD. RESULTS: A circular dichroism analysis of a synthetic gp41 MSD peptide determined that the secondary structure of the gp41 MSD was α-helical. We then performed a scanning alanine-insertion mutagenesis of the entire gp41 MSD, progressively shifting the relative positions of MSD segments around the helix axis. Altering the position of Gly694, the last residue of the GXXXG motif, relative to Arg696 (the number indicates the position of the amino acid residues in HXB2 Env) around the axis resulted in defective fusion. These mutants showed impaired processing of the gp160 precursor into gp120 and gp41. Furthermore, these Env mutants manifested inefficient intracellular transport in the endoplasmic reticulum and Golgi regions. Indeed, a transplantation of the gp41 MSD portion into the transmembrane domain of another membrane protein, Tac, altered its intracellular distribution. Our data suggest that the intact MSD α-helix is critical in the intracellular trafficking of HIV-1 Env. CONCLUSIONS: The relative position between the highly conserved GXXXG motif and an arginine residue around the gp41 MSD α-helix is critical for intracellular trafficking of HIV-1 Env. The gp41 MSD region not only modulates membrane fusion but also controls biosynthesis of HIV-1 Env.

Molecular dynamics studies of the transmembrane domain of gp41 from HIV-1.

Helix-helix interactions in the putative three-helix bundle formation of the gp41 transmembrane (TM) domain may contribute to the process of virus-cell membrane fusion in HIV-1 infection. In this study, molecular dynamics is used to analyze and compare the conformations of monomeric and trimeric forms of the TM domain in various solvent systems over the course of 4 to 23-ns simulations. The trimeric bundles of the TM domain were stable as helices and remained associated in a hydrated POPE lipid bilayer for the duration of the 23-ns simulation. Several stable inter-chain hydrogen bonds, mostly among the three deprotonated arginine residues located at the center of each of the three TM domains, formed in a right-handed bundle embedded in the lipid bilayer. No such bonds were observed when the bundle was left-handed or when the central arginine residue in each of the three TM helices was replaced with isoleucine (R_I mutant), suggesting that the central arginine residues may play an essential role in maintaining the integrity of the three-helix bundle. These observations suggest that formation of the three-helix bundle of the TM domain may play a role in the trimerization of gp41, thought to occur during the virus-cell membrane fusion process.

Folding kinetics of an alpha helical membrane protein in phospholipid bilayer vesicles.

We report a detailed kinetic study of the folding of an alpha-helical membrane protein in a lipid bilayer environment. SDS denatured bacteriorhodopsin was folded directly into phosphatidylcholine lipid vesicles by stopped-flow mixing. The folding kinetics were monitored with millisecond time resolution by time-resolving changes in protein fluorescence as well as in the absorption of the retinal chromophore. The kinetics were similar to those previously reported for folding bacteriorhodopsin in detergent or lipid micelles, except for the presence of an additional apoprotein intermediate. We suggest this intermediate is a result of the greater internal two-dimensional pressure present in these lipid vesicles as compared to micelles. These results lay the groundwork for future studies aimed at understanding the mechanistic origin of the effect of lipid bilayer properties on protein folding. Furthermore, the use of biologically relevant phosphatidylcholine lipids, together with a straightforward rapid mixing process to initiate the folding reaction, means the method is generally applicable, and thus paves the way for an improved understanding of the in vitro folding of transmembrane alpha-helical proteins.

Controlling the folding efficiency of an integral membrane protein.

Research into the folding mechanisms of integral membrane proteins lags far behind that of water-soluble proteins, to the extent that the term protein folding is synonymous with water-soluble proteins. Hydrophobic membrane proteins, and particularly those with transmembrane alpha-helical motifs, are frequently considered too difficult to work with. We show that the stored curvature elastic stress of lipid bilayers can be used to guide the design of efficient folding systems for these integral membrane proteins. The curvature elastic stress of synthetic phosphatidylcholine/phosphatidylethanolamine lipid bilayers can be used to control both the rate of folding and the yield of folded protein. The use of a physical bilayer property generalises this approach beyond the particular chemistry of the lipids involved.

The affinity of GXXXG motifs in transmembrane helix-helix interactions is modulated by long-range communication.

Sequence motifs are responsible for ensuring the proper assembly of transmembrane (TM) helices in the lipid bilayer. To understand the mechanism by which the affinity of a common TM-TM interactive motif is controlled at the sequence level, we compared two well characterized GXXXG motif-containing homodimers, those formed by human erythrocyte protein glycophorin A (GpA, high-affinity dimer) and those formed by bacteriophage M13 major coat protein (MCP, low affinity dimer). In both constructs, the GXXXG motif is necessary for TM-TM association. Although the remaining interfacial residues (underlined) in GpA (LIXXGVXXGVXXT) differ from those in MCP (VVXXGAXXGIXXF), molecular modeling performed here indicated that GpA and MCP dimers possess the same overall fold. Thus, we could introduce GpA interfacial residues, alone and in combination, into the MCP sequence to help decrypt the determinants of dimer affinity. Using both in vivo TOXCAT assays and SDS-PAGE gel migration rates of synthetic peptides derived from TM regions of the proteins, we found that the most distal interfacial sites, 12 residues apart (and approximately 18 A in structural space), work in concert to control TM-TM affinity synergistically.

Membrane protein folding: beyond the two stage model.

The folding of alpha-helical membrane proteins has previously been described using the two stage model, in which the membrane insertion of independently stable alpha-helices is followed by their mutual interactions within the membrane to give higher order folding and oligomerization. Given recent advances in our understanding of membrane protein structure it has become apparent that in some cases the model may not fully represent the folding process. Here we present a three stage model which gives considerations to ligand binding, folding of extramembranous loops, insertion of peripheral domains and the formation of quaternary structure.

Sequence motifs, polar interactions and conformational changes in helical membrane proteins.

The alpha helices of transmembrane proteins interact to form higher order structures. These interactions are frequently mediated by packing motifs (such as GxxxG) and polar residues. Recent structural data have revealed that small sidechains are able to both stabilize helical membrane proteins and allow conformational changes in the structure. The strong interactions involving polar sidechains often contribute to protein misfolding or malfunction.