HIV-1 GP120 V3 conformational and informational entropies

In an attempt to analyze structure, function and evolution of HIV-1 GP120 V3, interactions among the Hartree–Fock energy, the conformational entropy and the Shannon entropy were determined for the 1NJ0 set of antibody-bound V3 loop conformers. The Hartree–Fock energy of each conformer was determined at the MINI level with GAMESS. The conformational entropy was determined per conformer and per residue from the mass-weighted covariance matrices. The Shannon entropy per residue was determined from sequence-substitution frequencies. Correlations were determined by linear regression analysis. There was a negative correlation between the Hartree–Fock energy and the conformational entropy (R=−0.4840, p=0.0078, df =28) that enhanced the negative Helmholtz-free-energy change for the binding of the GP120 ligand to target CD4. The Shannon entropy of V3 was a function of the conformational entropy variance (R=0.7225, p=0.00157, df=15) and of the V3 Hartree–Fock energy. Biological implications of this work are that (1) conformational entropy interacts with V3 Hartree–Fock energy to enhance GP120 binding to CD4 cell receptors and that (2) the Hartree–Fock energy of V3 interacts with the evolutionary system to participate in the regulation of V3 diversity.     

Gp120 V3-dependent impairment of R5 HIV-1 infectivity due to virion-incorporated CCR5

Entry of R5 human immunodeficiency virus type 1 (HIV-1) into target cells requires sequential interactions of the envelope glycoprotein gp120 with the receptor CD4 and the coreceptor CCR5. We investigated replication of 45 R5 viral clones derived from the HIV-1JR-FLan library carrying 0-10 random amino acid substitutions in the gp120 V3 loop. It was found that 6.7% (3/45) of the viruses revealed >or=10-fold replication suppression in PM1/CCR5 cells expressing high levels of CCR5 compared with PM1 cells expressing low levels of CCR5. In HIV-1V3L#08, suppression of replication was not associated with entry events and viral production but with a marked decrease in infectivity of nascent progeny virus. HIV-1V3L#08, generated from infected PM1/CCR5 cells, was 98% immunoprecipitated by anti-CCR5 monoclonal antibody T21/8, whereas the other infectious viruses were only partially precipitated, suggesting that incorporation of larger amounts of CCR5 into the virions caused impairment of viral infectivity in HIV-1V3L#08. The results demonstrate the implications of an alternative influence of CCR5 on HIV-1 replication.     

The HF-SCF energy of HIV-1 MNgp120 V3 hairpin loop conformers

The purpose of this study is to analyze the structure of the V3 loop of the HIV-1 gp120 molecule at the atomic level. The total energy of each member of the antibody-complexed 16-mer V3 conformer data set of Sharon et al. (PDB 1NJ0) was determined by the Hartree–Fock-self-consistent field (HF-SCF) method and with the GROMOS96 force field. There was no correlation between the results of the classical GROMOS96 force field analysis and the ab initio HF-SCF quantum mechanical analysis of the energy of the V3-loop-peptide conformers. HF-SCF optimization (AM1) of conformer geometries yielded structures in which HIS315 is displaced from its original position in the combining site of human antibody fragment 447-52D, but with the hairpin turn intact. The hairpin shape of the V3 loop remained detectable, albeit distorted, even with perturbation by a lithium dicationic electrostatic force field and by substitution of the PRO320 at the crown of the V3 hairpin by a GLY. These data suggest that the hairpin conformation is at least partially stable to long-range electrostatic perturbations, either with or without PRO in the tip of the crown of the V3-hairpin loop. Figure Molecular geometry of HIV-1 V3 conformer model 5 and a GLY320 substituted model 5. Space-filling models were obtained with ViewMol3D [Sharon et al. (2002) PDB 1NJ0]). Red=oxygen, blue=nitrogen, black=carbon, white=hydrogen and purple=lithium. End-to-end distance (D) was obtained with ViewMol3D and is in Ångströms. Geometry optimized GLY320 Model 5, D=4.74 ÅThis revised version was published online in October 2004 with corrections to the Graphical Abstract.     

Molecular Recognition of CCR5 by an HIV-1 gp120 V3 Loop

The binding of protein HIV-1 gp120 to coreceptors CCR5 or CXCR4 is a key step of the HIV-1 entry to the host cell, and is predominantly mediated through the V3 loop fragment of HIV-1 gp120. In the present work, we delineate the molecular recognition of chemokine receptor CCR5 by a dual tropic HIV-1 gp120 V3 loop, using a comprehensive set of computational tools predominantly based on molecular dynamics simulations and free energy calculations. We report, what is to our knowledge, the first complete HIV-1 gp120 V3 loop : CCR5 complex structure, which includes the whole V3 loop and the N-terminus of CCR5, and exhibits exceptional agreement with previous experimental findings. The computationally derived structure sheds light into the functional role of HIV-1 gp120 V3 loop and CCR5 residues associated with the HIV-1 coreceptor activity, and provides insights into the HIV-1 coreceptor selectivity and the blocking mechanism of HIV-1 gp120 by maraviroc. By comparing the binding of the specific dual tropic HIV-1 gp120 V3 loop with CCR5 and CXCR4, we observe that the HIV-1 gp120 V3 loop residues 13–21, which include the tip, share nearly identical structural and energetic properties in complex with both coreceptors. This result paves the way for the design of dual CCR5/CXCR4 targeted peptides as novel potential anti-AIDS therapeutics.     

Solid-state NMR evidence for an antibody-dependent conformation of the V3 loop of HIV-1 gp120

Solid-state NMR measurements have been carried out on frozen solutions of the complex of a 24-residue peptide derived from the third variable (V3) loop of the HIV-1 envelope glycoprotein gp120 bound to the Fab fragment of an anti-gp120 antibody. The measurements place strong constraints on the conformation of the conserved central GPGR motif of the V3 loop in the antibody-bound state. In combination with earlier crystal structures of V3 peptide-antibody complexes and existing data on the cross-reactivity of the antibodies, the solid-state NMR measurements suggest that the Gly-Pro-Gly-Arg (GPGR) motif adopts an antibody-dependent conformation in the bound state and may be conformationally heterogeneous in unbound, full-length gp120. These measurements are the first application of solid-state NMR methods in a structural study of a peptide-protein complex.     

Recognition properties of V3-specific antibodies to V3 loop peptides derived from HIV-1 gp120 presented in multiple conformations

To identify structural constraints and amino acid sequences important for antibody recognition of the third variable domain (V3) of HIV-1 gp120, we have studied the solution conformation of three 35-mer circular V3 loop peptides derived from HIV-1 strains which differ in syncytium- (SI) and non-syncytium-inducing (NSI) capacity. In addition to 2D NMR and CD analyses, fluid- and solid-phase immunoassays were performed using V3-specific antibodies to V3 peptides and gp120 derived from different strains of HIV-1. NMR and CD spectroscopy indicated that circular and linear V3 loops exist in water as a dynamic ensemble of multiple conformations. Amino acid substitutions and biochemical modifications of the V3 loop were found to affect antibody binding depending on the presentation of the antigens. From NMR observations and immunological experiments, we provide evidence for a V3 loop specific monoclonal antibody interaction which is directed predominantly against linear epitopes rather than against discontinuous epitopes. The absence of a single defined solution conformation of 35-mer circular V3 peptides should be taken into account when using V3-related peptides to investigate structural elements in the V3 domain of the gp120 envelope protein of HIV-1 involved in biological processes of the virus.     

Ion channel activation by SPC3, a peptide derived from the HIV-1 gp120 V3 loop.

SPC3 is a multibranched peptide containing eight identical GPGRAF motifs which are derived from the human immunodeficiency virus (HIV)-1 gp120 V3 loop consensus sequence. This molecule was reported to prevent the infection of CD4+ cells by various HIV-1 and HIV-2 strains. However, the molecular mode of action of SPC3 remains unclear. Here, we investigated the possibility that SPC3 could interact with alpha/beta-chemokine receptors following observations that, first, the V3 loop is likely to be involved in alpha/beta-chemokine receptor-dependent HIV entry and, second, natural ligands of these receptors are potent inhibitors of cell infection. To address this point, we examined the effects of SPC3 on Xenopus oocytes either uninjected or expressing exogenous human CXCR4 alpha-chemokine receptors. Extracellular applications of micromolar concentrations of SPC3 onto Xenopus oocytes trigger potent inward chloride currents which can be inhibited by increasing extracellular Ca2+ concentration. This effect can be blocked by chloride channel antagonists and is highly specific to SPC3 as it is not triggered by structural analogs of SPC3. The SPC3-induced chloride conductance in oocytes is alpha/beta-chemokine receptor dependent because: (i) SPC3 alters the sensitivity of this channel to external applications of human recombinant MIP-1alpha, a natural ligand of human CCR5 receptor, and (ii) the amplitude of the inward current could be increased by the expression of exogenous human CXCR4 chemokine receptor. The effect of SPC3 appears to rely on the activation of a phospholipase A2 signaling pathway, but is not affected by changes in cytosolic Ca2+ concentration, or by alterations in Gi/Go protein, adenylate cyclase, phospholipase C or protein kinase C activity. Altogether, the data indicate that SPC3 is capable of activating a surface alpha/beta-chemokine-like receptor-mediated signaling pathway in competent cells, thereby triggering, either directly or indirectly, a Ca2+-inactivated chloride conductance.     

Membranotropic effects of peptides from the V3 loop of HIV-1

The V3 loop from HIV-1 envelope glycoprotein gp120 is involved in viral entry and determines the cellular tropism and HIV-1-induced cell–cell fusion. Earlier we have shown that V3 loop peptides representing the sequences of syncytia-inducing HIV strains have high membranotropic activity. These peptides caused the lysis of liposomes of various lipid compositions, could fuse negatively charged liposomes and induced hemolysis of erythrocytes. In contrast, peptides mimicking the sequences of non-syncytia-inducing viruses showed no lytic or fusion activities at the same concentrations. Now we have found that the V3 loop synthetic peptides containing the conserved GPGR region, derived from T-lymphotropic strains (BRU and MN), as opposed to peptides containing the GPGQ region, are able to cause a pronounced membrane permeabilization (dissipation of the pH and the of human peripheral blood lymphocytes, erythrocytes and plasma membrane vesicles at micromolar concentrations with a dose-dependent kinetics. Analysis of the secondary structures of the peptides by circular dichroism revealed conformational changes in V3 loop peptides depending on solvent hydrophobicity: from random coil in water to an -helix/-sheet conformation in trifluoroethanol. Such structural changes of the V3 loop together with the membrane insertion of the gp41 N-terminal fusion peptide may promote the formation of the fusion pore during virus–cell fusion.     

Membranotropic effects of peptides from the V3 loop of HIV-1

Summary The V3 loop from HIV-1 envelope glycoprotein gp120 is involved in viral entry and determines the cellular tropism and HIV-1-induced cell-cell fusion. Earlier we have shown that V3 loop peptides representing the sequences of syncytia-inducing HIV strains have high membranotropic activity. These peptides caused the lysis of liposomes of various lipid compositions, could fuse negatively charged liposomes and induced hemolysis of erythrocytes. In contrast, peptides mimicking the sequences of non-syncytia-inducing viruses showed no lytic or fusion activities at the same concentrations. Now we have found that the V3 loop synthetic peptides containing the conserved GPGR region, derived from T-lymphotropic strains (BRU and MN), as opposed to peptides containing the GPGQ region, are able to cause a pronounced membrane permeabilization (dissipation of the ΔpH and the Δψ) of human peripheral blood lymphocytes, erythrocytes and plasma membrane vesicles at micromolar concentrations with a dose-dependent kinetics. Analysis of the secondary structures of the peptides by circular dichroism revealed conformational changes in V3 loop peptides depending on solvent hydrophobicity: from random coil in water to an α-helix/β-sheet conformation in trifluoroethanol. Such structural changes of the V3 loop together with the membrane insertion of the gp41 N-terminal fusion peptide may promote the formation of the fusion pore during virus-cell fusion.     

Structural analysis of the HIV-1 gp120 V3 loop: application to the HIV-Haiti isolates

The model describing the structure and conformational preferences of the HIV-Haiti V3 loop in the geometric spaces of Cartesian coordinates and dihedral angles was generated in terms of NMR spectroscopy data published in literature. To this end, the following successive steps were put into effect: (i) the NMR-based 3D structure for the HIV-Haiti V3 loop in water was built by computer modeling methods; (ii) the conformations of its irregular segments were analyzed and the secondary structure elements identified; and (iii) to reveal a common structural motifs in the HIV-Haiti V3 loop regardless of its environment variability, the simulated structure was collated with the one deciphered previously for the HIV-Haiti V3 loop in a water/trifluoroethanol (TFE) mixed solvent. As a result, the HIV-Haiti V3 loop was found to offer the highly variable fragment of gp120 sensitive to its environment whose changes trigger the large-scale structural rearrangements, bringing in substantial altering the secondary and tertiary structures of this functionally important site of the virus envelope. In spite of this fact, over half of amino acid residues that reside, for the most part, in the functionally important regions of the gp120 protein and may present promising targets for AIDS drug researches, were shown to preserve their conformational states in the structures under review. In particular, the register of these amino acids holds Asn-25 that is critical for the virus binding with primary cell receptor CD4 as well as Arg-3 that is critical for utilization of CCR5 co-receptor and heparan sulfate proteoglycans. The conservative structural motif embracing one of the potential sites of the gp120 N-linked glycosylation was detected, which seems to be a promising target for the HIV-1 drug design. The implications are discussed in conjunction with the literature data on the biological activity of the individual amino acids for the HIV-1 gp120 V3 loop.     

Identification of the potential regions of Epap-1 that interacts with V3 loop of HIV-1 gp120

Early pregnancy associated protein-1 (Epap-1), a 90 kDa glycoprotein present in first trimester placental tissue, inhibits HIV-1 entry through interaction with HIV-1 gp120 at V3 and C5 regions. In the present study, we have identified the specific 32 mer region of Epap-1 that can interact with V3 loop. This was achieved by docking between Epap-1 molecular model and gp120 and studying the interaction of peptides with gp120 in vitro. Out of four peptides analyzed, two peptides (P-2 and P-3) showed significant interaction with V3 domain (N = 8; N = 7) of gp120. In the studies conducted using soluble gp120 and virus, peptide P-2 has shown conserved interaction at V3 loop regions recognized by 257D and F425 antibodies and higher anti-viral activity. Also, P-2 inhibited cell fusion mediated dye transfer between gp120 expressing HL2/3 and CD4 expressing Sup T1 cells suggesting its inhibition of viral entry, which is further confirmed by its action on HIV infection mediated by Tat activated beta gal expression in TZM-bl cells. Further optimization of P-2 peptide showed that the anti-viral activity and gp120 interaction residues lie in the N-terminal region of the peptide. These results together suggest that P-2 inhibits viral entry through specific interaction at V3 loop region.     

The binding of a glycoprotein 120 V3 loop peptide to HIV-1 neutralizing antibodies. Structural implications

The structural and antigenic properties of a peptide ("CRK") derived from the V3 loop of HIV-1 gp120 protein were studied using NMR and SPR techniques. The sequence of CRK corresponds to the central portion of the V3 loop containing the highly conserved "GPGR" residue sequence. Although the biological significance of this conserved sequence is unknown, the adoption of conserved secondary structure (type II beta-turn) in this region has been proposed. The tendency of CRK (while free or conjugated to protein), to adopt such structure and the influence of such structure upon CRK antigenicity were investigated by NMR and SPR, respectively. Regardless of conjugation, CRK is conformationally averaged in solution but a weak tendency of the CRK "GPGR" residues to adopt a beta-turn conformation was observed after conjugation. The influence of GPGR structure upon CRK antigenicity was investigated by measuring the affinities of two cognate antibodies: "5023A" and "5025A," for CRK, protein-conjugated CRK and gp120 protein. Each antibody bound to all the antigens with nearly the same affinity. From these data, it appears that: (a) antibody binding most likely involves an induced fit of the peptide and (b) the gp120 V3 loop is probably conformationally heterogeneous. Since 5023A and 5025A are HIV-1 neutralizing antibodies, neutralization in these cases appears to be independent of adopted GPGR beta-turn structure.     

Chimeras from a human rhinovirus 14-human immunodeficiency virus type 1 (HIV-1) V3 loop seroprevalence library induce neutralizing responses against HIV-1.

A chimeric virus library was designed whereby sequences corresponding to the V3 loop of human immunodeficiency virus type 1 (HIV-1) were presented on the surface of human rhinovirus 14. The V3 loop sequences consisted of a relatively conserved segment of seven amino acids and five adjacent residues that were allowed to vary in proportion to their seroprevalence among HIV-1 isolates of North America and Europe. A technique called random systematic mutagenesis was used to incorporate the composite V3 loop sequences flanked by zero to two randomized amino acids. This library could contain 2.7 x 10(8) members having diverse sequences and conformations. Immunoselection of a portion of this library by using two neutralizing V3 loop-directed monoclonal antibodies followed by selection for desirable growth and purification characteristics yielded a set of chimeric rhinoviruses, five of which are described. The inserted sequences in the five chimeras do not match those of any known isolate of HIV-1. Nonetheless, all five chimeras were neutralized by antibodies directed against different strains of HIV-1 and were able to elicit the production of antibodies that bind V3 loop peptides from diverse HIV-1 isolates. Moreover, antisera derived from four of the five chimeras were capable of neutralizing one or more strains of HIV-1 in cell culture. This study demonstrates that random systematic mutagenesis in conjunction with antibody screening is a powerful and efficient means to obtain antigenic chimeras with relevant immunogenic properties.     

Dual conformations for the HIV-1 gp120 V3 loop in complexes with different neutralizing fabs.

BACKGROUND: The third hypervariable (V3) loop of HIV-1 gp120 has been termed the principal neutralizing determinant (PND) of the virus and is involved in many aspects of virus infectivity. The V3 loop is required for viral entry into the cell via membrane fusion and is believed to interact with cell surface chemokine receptors on T cells and macrophages. Sequence changes in V3 can affect chemokine receptor usage, and can, therefore, modulate which types of cells are infected. Antibodies raised against peptides with V3 sequences can neutralize laboratory-adapted strains of the virus and inhibit syncytia formation. Fab fragments of these neutralizing antibodies in complex with V3 loop peptides have been studied by X-ray crystallography to determine the conformation of the V3 loop. RESULTS: We have determined three crystal structures of Fab 58.2, a broadly neutralizing antibody, in complex with one linear and two cyclic peptides the amino acid sequence of which comes from the MN isolate of the gp120 V3 loop. Although the peptide conformations are very similar for the linear and cyclic forms, they differ from that seen for the identical peptide bound to a different broadly neutralizing antibody, Fab 59.1, and for a similar peptide bound to the MN-specific Fab 50.1. The conformational difference in the peptide is localized around residues Gly-Pro-Gly-Arg, which are highly conserved in different HIV-1 isolates and are predicted to adopt a type II beta turn. CONCLUSIONS: The V3 loop can adopt at least two different conformations for the highly conserved Gly-Pro-Gly-Arg sequence at the tip of the loop. Thus, the HIV-1 V3 loop has some inherent conformational flexibility that may relate to its biological function.     

Conformation of the HIV-1 gp120 V3 loop. Structure functional analysis of the HIV-Haiti viral strain

The structural model describing the conformational preferences of the HIV-Haiti gp120 V3 loop in geometric space of dihedral angles was generated in terms of NMR spectroscopy data using the methods of computer modeling. The elements of secondary structure anti conformations of irregular stretches were deciphered for the fragment making the virus principal neutralizing determinant as well as the determinants of cell tropism and syncytium formation. The structurally conserved amino acids of the HIV-1 V3 loop, that may present the forward-looking targets for AIDS drug design, were identified based on the combined analysis of the results obtained with those derived previously. In particular, it was demonstrated that the register of these amino acids comprises Asn-25 critical for virus binding with primary cell receptor CD4 as well as Arg-3 critical for utilization of CCR5 coreceptor and heparan sulfate proteoglycan syndecans. The results obtained are discussed in conjunction with the literature data on the biological activity of individual amino acid residues of the HIV-1 gpl20 V3 loop.     

Structure and Dynamics of the gp120 V3 Loop That Confers Noncompetitive Resistance in R5 HIV-1JR-FL to Maraviroc

Maraviroc, an (HIV-1) entry inhibitor, binds to CCR5 and efficiently prevents R5 human immunodeficiency virus type 1 (HIV-1) from using CCR5 as a coreceptor for entry into CD4⁺ cells. However, HIV-1 can elude maraviroc by using the drug-bound form of CCR5 as a coreceptor. This property is known as noncompetitive resistance. HIV-1_V3-M5 derived from HIV-1_JR-FLan is a noncompetitive-resistant virus that contains five mutations (I304V/F312W/T314A/E317D/I318V) in the gp120 V3 loop alone. To obtain genetic and structural insights into maraviroc resistance in HIV-1, we performed here mutagenesis and computer-assisted structural study. A series of site-directed mutagenesis experiments demonstrated that combinations of V3 mutations are required for HIV-1_JR-FLan to replicate in the presence of 1 µM maraviroc, and that a T199K mutation in the C2 region increases viral fitness in combination with V3 mutations. Molecular dynamic (MD) simulations of the gp120 outer domain V3 loop with or without the five mutations showed that the V3 mutations induced (i) changes in V3 configuration on the gp120 outer domain, (ii) reduction of an anti-parallel β-sheet in the V3 stem region, (iii) reduction in fluctuations of the V3 tip and stem regions, and (iv) a shift of the fluctuation site at the V3 base region. These results suggest that the HIV-1 gp120 V3 mutations that confer maraviroc resistance alter structure and dynamics of the V3 loop on the gp120 outer domain, and enable interactions between gp120 and the drug-bound form of CCR5.     

Structural characterization of an anti-gp120 RNA aptamer that neutralizes R5 strains of HIV-1

We recently described the isolation of 2'-fluoropyrimidine-substituted RNA aptamers that bind specifically to the surface glycoprotein (gp 120) of the R5 strain, HIV-1(Ba-L), as presented in a previous study. These aptamers potently neutralize HIV-1 infectivity in human peripheral blood mononuclear cells of both tissue culture lab-adapted strains and diverse R5 clinical isolates from multiple clades. Here, we report a detailed structural characterization of one such neutralizing aptamer, B40, using enzymatic and chemical probing methods. We identify the minimal region of the aptamer essential for binding gp120 and accordingly design a 77-nucleotide truncated aptamer, B40t77. We then quantitatively analyze the binding affinity and neutralization potency of the parental and truncated (minimal) aptamer, and show them to be comparable. Furthermore, using results from secondary structure analysis, RNA mutagenesis and BIAcore surface plasmon resonance (SPR) binding assays, we hypothesize that a folded RNA structure is required to present specific nucleotide sequences to allow gp120-recognition and binding. The information gained from this study may provide leads for development of novel anti-HIV-1 therapies and can be used to extend our understanding of the molecular interactions between the virus and its host cell.     

Accurate and efficient gp120 V3 loop structure based models for the determination of HIV-1 co-receptor usage

Background  

HIV-1 targets human cells expressing both the CD4 receptor, which binds the viral envelope glycoprotein gp120, as well as either the CCR5 (R5) or CXCR4 (X4) co-receptors, which interact primarily with the third hypervariable loop (V3 loop) of gp120. Determination of HIV-1 affinity for either the R5 or X4 co-receptor on host cells facilitates the inclusion of co-receptor antagonists as a part of patient treatment strategies. A dataset of 1193 distinct gp120 V3 loop peptide sequences (989 R5-utilizing, 204 X4-capable) is utilized to train predictive classifiers based on implementations of random forest, support vector machine, boosted decision tree, and neural network machine learning algorithms. An in silico mutagenesis procedure employing multibody statistical potentials, computational geometry, and threading of variant V3 sequences onto an experimental structure, is used to generate a feature vector representation for each variant whose components measure environmental perturbations at corresponding structural positions.