How structure correlates to function for membrane associated HIV-1 gp41 constructs corresponding to the N-terminal half of the ectodomain

To address the structure-function relationship of discrete regions within the gp41 ectodomain, 70-residue peptide constructs corresponding to the N-terminal subdomain of the HIV-1 gp41 ectodomain were examined in a membrane-associated context. These fragments encompass both fusion peptide (FP) and N-terminal heptad repeat (NHR) regions, and model the N-terminal half of the pre-hairpin intermediate (PHI), which is believed to be the target of the potent entry inhibitor DP-178, recently approved by the FDA. Using mutants, we attempted to map the structural organization of the N-terminal subdomain. Our results suggest that the N-terminal subdomain contains two discrete structural regions: the FP adopts a beta-sheet conformation and the NHR is alpha-helical. This structural make-up is essential for fusogenic function, since loss of function mutants exhibit both a significant reduction in region-specific secondary structure as well as significant impairment in lipid mixing of large unilamellar vesicles. Our results, delineating membrane-associated structure of the FP region differ from previous ones by inclusion of the autonomous oligomerization domain (NHR), which likely contributes to stabilization of the FP structure. Correspondingly, the alpha-helical structure for the NHR, in context of the FP, correlates with structural predictions for this region in both the hairpin and PHI conformations during fusion. Based on our results, we postulate how oligomerization of regions in this sub-domain is essential for fusion pore formation.     

The N-terminal 12 residue long peptide of HIV gp41 is the minimal peptide sufficient to induce significant T-cell-like membrane destabilization in vitro

Here, we predicted the minimal N-terminal fragment of gp41 required to induce significant membrane destabilization using IMPALA. This algorithm is dedicated to predict peptide interaction with a membrane. We based our prediction of the minimal fusion peptide on the tilted peptide theory. This theory proposes that some protein fragments having a peculiar distribution of hydrophobicity adopt a tilted orientation at a hydrophobic/hydrophilic interface. As a result of this orientation, tilted peptides should disrupt the interface. We analysed in silico the membrane-interacting properties of gp41 N-terminal peptides of different length derived from the isolate BRU and from an alignment of 710 HIV strains available on the Los Alamos National Laboratory. Molecular modelling results indicated that the 12 residue long peptide should be the minimal fusion peptide. We then assayed lipid-mixing and leakage of T-cell-like liposomes with N-terminal peptides of different length as first challenge of our predictions. Experimental results confirmed that the 12 residue long peptide is necessary and sufficient to induce membrane destabilization to the same extent as the 23 residue long fusion peptide. In silico analysis of some fusion-incompetent mutants presented in the literature further revealed that they cannot insert into a modelled membrane correctly tilted. According to this work, the tilted peptide model appears to explain at least partly the membrane destabilization properties of HIV fusion peptide.     

Fatty acids can substitute the HIV fusion peptide in lipid merging and fusion: an analogy between viral and palmitoylated eukaryotic fusion proteins

Various fusion proteins from eukaryotes and viruses share structural similarities such as a coiled coil motif. However, compared with eukaryotic proteins, a viral fusion protein contains a fusion peptide (FP), which is an N-terminal hydrophobic fragment that is primarily involved in directing fusion via anchoring the protein to the target cell membrane. In various eukaryotic fusion proteins the membrane targeting domain is cysteine-rich and must undergo palmitoylation prior to the fusion process. Here we examined whether fatty acids can replace the FP of human immunodeficiency virus type 1 (HIV-1), thereby discerning between the contributions of the sequence versus hydrophobicity of the FP in the lipid-merging process. For that purpose, we structurally and functionally characterized peptides derived from the N terminus of HIV fusion protein - gp41 in which the FP is lacking or replaced by fatty acids. We found that fatty acid conjugation dramatically enhanced the capability of the peptides to induce lipid mixing and aggregation of zwitterionic phospholipids composing the outer leaflet of eukaryotic cell membranes. The enhanced effect of the acylated peptides on membranes was further supported by real-time atomic force microscopy (AFM) showing nanoscale holes in zwitterionic membranes. Membrane-binding experiments revealed that fatty acid conjugation did not increase the affinity of the peptides to the membrane significantly. Furthermore, all free and acylated peptides exhibited similar α-helical structures in solution and in zwitterionic membranes. Interestingly, the fusogenic active conformation of N36 in negatively charged membranes composing the inner leaflet of eukaryotic cells is β-sheet. Apparently, N-terminal heptad repeat (NHR) can change its conformation as a response to a change in the charge of the membrane head group. Overall, the data suggest an analogy between the eukaryotic cysteine-rich domains and the viral fusion peptide, and mark the hydrophobic nature of FP as an important characteristic for its role in lipid merging.     

Suitable fusion of N-terminal heptad repeats to achieve covalently stabilized potent N-peptide inhibitors of HIV-1 infection

N-terminal heptad repeat (NHR)-derived peptide (N-peptide) fusion inhibitors, which are derived from human immunodeficiency virus (HIV) envelope glycoprotein 41 (gp41), are limited by aggregation and unstable trimer conformation. However, they could function as potent inhibitors of viral infection by forming a coiled-coil structure covalently stabilized by interchain disulfide bonds. We previously synthesized N-peptides with potent anti-HIV-1 activity and high stability by coiled-coil fusion and covalent stabilization. Here, we attempted to study the effects of NHRs of chimeric N-peptides by fusing de novo coiled-coil isopeptide bridge-tethered T21 peptides of different NHR lengths. Peptides (T21N23)₃ and (T21N36)₃ was a more potent HIV-1 fusion inhibitor than (T21N17)₃. The site of isopeptide bond formation was precisely controlled and had little influence on N-peptide properties. The N-peptide (T21N36)₃, which had a similar conformation as the NHR trimer and interacted well with the C34 peptide, may be useful for screening other C-peptides and small-molecule fusion inhibitors, and for studying the interactions between the NHR trimer and C-terminal heptad repeats.     

A study of a Calpha,beta-didehydroalanine homo-oligopeptide series in the solid-state by 13C cross-polarization magic angle spinning NMR.

The fully extended peptide conformation (2.0(5)-helix) has been investigated for the first time in the solid-state by 13C cross-polarization magic angle spinning NMR. The compounds examined are members of a terminally protected, homo-oligopeptide series (from monomer through hexamer) based on Calpha,beta-didehydroalanine.     

The structure and assembly model of the third transmembrane domain of Slc11a1 in SDS micelles revealed by NMR study of the Leu‐substituted peptide

Slc11a1 is an integral membrane protein with 12 putative transmembrane domains (TMDs) and functions as a pH‐coupled divalent metal cation transporter. The conservation of three negatively charged residues in the TMD3 of Slc11 protein family implies the important role of this domain in the function of the proteins. However, aggregation of the transmembrane peptide in micelles prevents structural study of the peptide in these membrane‐mimetic environments by NMR spectroscopy. Here, we characterized the structure, position, and assembly model of Slc11a1‐TMD3 (Lys128‐Ile151) in SDS micelles by the NMR study of its Leu‐substituted peptide. It was found that the two‐site substitutions of Ala for Leu residues at positions 136 and 140 of TMD3 disrupt the aggregation without altering the secondary structure of the peptide. The Leu‐substituted peptide folds as an α‐helix spanning from Leu133 to Gly144 and embedded in the micelles. A Leu zipper is suggested to account for the self‐assembly of the wild‐type peptide in SDS micelles. Copyright © 2011 European Peptide Society and John Wiley & Sons, Ltd.