Structural Analysis of the HIV-1 gp120 V3 Loop: Application to the HIV-Haiti Isolates

Abstract

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.     

Determining the invariant structure elements of the HIV-1 variable V3 loops: insight into the HIV-MN and HIV-Haiti isolates

The computer approaches that combined the 3D protein structure modeling with the mathematical statistics methods were used to compute the NMR-based 3D structures of the HIV-1 gp120 V3 loop for the HIV-MN and HIV-Haiti isolates in water as well as to compare their conformational characteristics with the purpose of determining the structure elements common for the two virus modifications. As a result, the variability of the amino acid sequence was found to stimulate the considerable structural rearrangements of the V3 loop. However, despite this fact, one functionally crucial stretch of V3 and a greater portion of its residues were shown to preserve the conformations in the viral strains of interest. To reveal the structural motifs and individual amino acids giving rise to the close conformations in the HIV-MN and HIV-Haiti V3 loops regardless of the sequence and environment variability, the simulated structures were collated with those deciphered previously in terms of NMR data in a water/trifluoroethanol mixed solvent. The structure elements and single residues of V3 residing in its biologically significant sites and keeping the conformations in all of the cases at question are considered to be the promising targets for anti-AIDS drugs studies. In this context, the structurally inflexible motifs of V3 presenting the weak units in the virus protection system may be utilized as the most convenient landing-places for molecular docking of the V3 loop and ligand structures followed by selecting chemical compounds suitable as a basis for the design of safe and effective antiviral agents.     

Determination of structurally conservative amino acids of the HIV-1 protein gp120 V3 loop as promising targets for drug design by protein engineering approaches

Based on the published NMR spectroscopy data, three-dimensional structures of the HIV-1 gp120 protein V3 loop were obtained by computer modeling in the viral strains HIV-Haiti and HIV-MN. In both cases, the secondary structure elements and conformations of irregular stretches were determined for the fragment representing the principal antigenic determinant of the virus, as well as determinants of the cellular tropism and syncytium formation. Notwithstanding the high variability of the amino acid sequence of gp120 protein, more than 50% of the V3 loop residues retained their conformations in the different HIV-1 virions. The combined analysis of the findings and the literature data on the biological activity of the individual residues of the HIV-1 V3 loop resulted in identification of its structurally conservative amino acids, which seem to be promising targets for antiviral drug design by protein engineering approaches.     

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.     

Conformational preferences of the HIV-1 principal neutralizing determinant

The model describing the conformational properties of the HIV-1 principal neutralizing determinant in the geometric space of dihedrals was generated in terms of NMR spectroscopy data published in literature. To gain an object in view, the following successive steps were put into effect: (i) the NMR-based local structures for the HIV(MN) V3 loop were determined in water and in a mixed water/trifluoroethanol (TFE) solvent (7:3), (ii) in either case, the conformations of its irregular segments were analyzed and the secondary structure elements identified, (iii) to appreciate the degree of conformational mobility of the stretch of interest, the simulated structures were compared with each other, (iv) to detect the amino acids retaining their conformations inside the diverse HIV-1 isolates, the structures computed were collated with the one derived previously for the V3 loop from Thailand isolate, and (v) as a matter of record, the structurally rigid residues, that may present the forward-looking targets for AIDS drug researches, were revealed. Summing up the principal results arising from these studies, the following conclusions were drawn: I. The HIV(MN) V3 loop offers the highly mobile fragment of gp120 sensitive to its environment whose changes trigger the large-scale structural reforms, bringing in substantial altering the secondary structure of this functionally important site of the virus envelope. II. In water, it exhibits extended site 1-14 separated by double beta-turn 15-20 with unordered region 21-35. III. Adding the TFE gives rise to destruction of the regular structure in the V3 loop N-terminal, stimulates the formation of 3(10)-helix in site 24-31, and affects also its central region 20-25 forming the HIV-1 immunogenic crown. IV. Regardless of statistically significant differences between local structures of the HIV(MN) V3 loop in water and in water/TFE solution, over one-third of residues keeps their conformational states; 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. V. There are no conserved structural motifs within the V3 loops from Minnesota and Thailand HIV-1 strains. However, perceptible portion of amino acids (more than 35%), including those appearing in the functionally important regions of gp120, holds the values of dihedral angles in which case. The implications are discussed in conjunction with the data on the experimental observations for the HIV-1 principal neutralizing determinant.     

Study on conformational homology of the HIV-1 gp120 protein V3 loop. Structural analysis of the HIV-RF and HIV-thailand viral strains

Based on NMR spectroscopy data, conformation of the HIV-RF gp120 protein V3 loop giving rise to the virus principal neutralizing determinant and also determinants of cell tropism and syncytium formation was calculated by computer modeling approaches. Elements of the HIV-RF V3 loop secondary structure and conformational states of its irregular stretches were determined. The calculated structure was compared with the conformation of the homologous stretch of the HIV-Thailand protein gp120 V3 loop, and structural elements preserved in the two viral strains were identified. Conservative elements of the HIV-1 V3 loop structure are considered to be promising targets for deriving chemically modified forms of this loop with the enhanced immunogenicity and cross-reactivity of neutralizing antibodies and also for creation of effective antiviral drugs on this base.     

The Influence of N-Linked Glycans on the Molecular Dynamics of the HIV-1 gp120 V3 Loop

N-linked glycans attached to specific amino acids of the gp120 envelope trimer of a HIV virion can modulate the binding affinity of gp120 to CD4, influence coreceptor tropism, and play an important role in neutralising antibody responses. Because of the challenges associated with crystallising fully glycosylated proteins, most structural investigations have focused on describing the features of a non-glycosylated HIV-1 gp120 protein. Here, we use a computational approach to determine the influence of N-linked glycans on the dynamics of the HIV-1 gp120 protein and, in particular, the V3 loop. We compare the conformational dynamics of a non-glycosylated gp120 structure to that of two glycosylated gp120 structures, one with a single, and a second with five, covalently linked high-mannose glycans. Our findings provide a clear illustration of the significant effect that N-linked glycosylation has on the temporal and spatial properties of the underlying protein structure. We find that glycans surrounding the V3 loop modulate its dynamics, conferring to the loop a marked propensity towards a more narrow conformation relative to its non-glycosylated counterpart. The conformational effect on the V3 loop provides further support for the suggestion that N-linked glycosylation plays a role in determining HIV-1 coreceptor tropism.     

Modeling of the 3D structure of the HIV-Haiti immunodominant epitope

The 3D structure for the HIV-Haiti immunodominant epitope was computed in terms of NMR spectroscopy data using the theoretical procedure including a probabilistic approach in conjunction with molecular mechanics algorithms and quantum chemical methods. The immunogenic crown of the virus protein gp120 was shown to form in solution a prevalent conformation whose geometric parameters match the double beta-turn IV-IV. Two structures observed in crystal were found in the ensemble of the best-energy conformations of the HIV-Haiti principal neutralizing epitope. From a comparison of simulated structures with those computed previously for the HIV-Thailand and HIV-MN isolates, it was concluded that the immunogenic tip of gp120 gives rise to similar spatial backbone forms in different HIV-1 strains but has some inherent conformational flexibility of its individual amino acid residues. The differences in local fragment structures revealed in three isolates of HIV-1 are supposed to be important for the specificity of its binding with neutralizing antibodies.     

Dual spatial folds and different local structures of the HIV-1 immunogenic crown in various virus isolates

Local and global structural properties of the HIV-1 principal neutralizing epitope were studied in terms of NMR spectroscopy data reported in literature for the HIV-Haiti and HIV-RF isolates. To this effect, the NMR-based method comprising a probabilistic model of protein conformation in conjunction with the molecular mechanics and quantum chemical computations was used for determining the ensembles of conformers matching the NMR requirements and energy criteria. As a matter of record, the high resolution 3D structure models were constructed for the HIV-Haiti and HIV-RF immunogenic crowns, and their geometric parameters were collated with the ones of conformers derived previously for describing the conformational features of immunogenic tip of gp120 from Thailand and MN HIV-1 strains. The HIV-1 neutralization site was demonstrated to constitute in water solution highly flexible system sensitive to its environment. This inference is completely valid for the geometric space of dihedral angles where statistically significant differences in local structures of simulated conformers have been found for all virus isolates of interest. In spite of this fact, the stretch analyzed was shown to manifest a certain conservatism in the space of atomic coordinates, building up in four HIV-1 isolates two spatial folds similar to those observed in crystal for the V3 loop peptides bound to different neutralizing Fabs. The results are discussed in the light of literature data on HIV-1 neutralizing epitope structure.     

Computer modeling of promising inhibitors of the HIV-1 subtype A replication as a framework for the rational anti-AIDS drug design

The model of the structural complex of cyclophilin B belonging to the immunophilins family with the HIV-1 subtype A V3 loop presenting the principal neutralizing determinant of the virus gp120 envelope protein as well as determinants of cell tropism and syncytium formation was generated by molecular docking methods. Based on the conformational and energy characteristics of the built complex, computer-aided design of the polypeptide able to block effectively the functionally crucial V3 segments was implemented. Analysis of the results obtained in this study and literature data suggests that the generated molecule represents a promising pharmacological substance, which may be used as the basis structure for realization of the protein engineering projects aimed to develop effective drugs for anti-AIDS therapy.     

Modeling of the spatial structure of an HIV-haiti immunodominant epitope

A model of the spatial structure of the immunodominant epitope of human immunodeficiency virus type 1 (HIV-Haiti virion) consistent with the NMR data was constructed using an earlier proposed method based on theoretical calculations. It was found that, in aqueous solution, the main immunogenic region of the virus protein gp120 took the prevalent conformation of a double β-turn IV–IV. It is shown that two structures of this fragment found in the crystal were present in the set of preferable conformations of the HIV-Haiti immunodominant epitope. On the basis of comparative analysis of the 3D structures of the immunodominant epitopes of type 1 human immunodeficiency virus (HIV-Haiti, HIV-Thailand, and HIV-MN virions), it was concluded that the studied gp120 fragment forms similar spatial backbone structures in these three virus subtypes; however, these structures are formed from different local minimums of the constituent amino acids. It was assumed that the detected distinctions between the local structures of this fragment determine the specificity of HIV-1 binding to virus-neutralizing antibodies.     

Human immunodeficiency virus type 1 tropism for brain microglial cells is determined by a region of the env glycoprotein that also controls macrophage tropism.

Human immunodeficiency virus type 1 (HIV-1), the agent of AIDS, frequently infects the central nervous system. We inoculated adult human brain cultures with chimeric viruses containing parts of the env gene of a cloned primary isolate from brain tissue, HIV-1 JRFl, inserted into the cloned DNA of a T-cell-tropic strain. A chimeric virus containing the carboxy-terminal portion of HIV-1 JRFl env did not replicate in these brain tissue cultures, while a chimera expressing an env-encoded protein containing 158 amino acids of HIV-1 JRFl gp120, including the V3 loop, replicated well in brain microglial cells, as it does in blood macrophages. Infection of brain microglial cells with such a chimera was blocked by an antibody to the V3 loop of gp 120. Thus, env determinants in the region of gp120, outside the CD4-binding site and comprising the V3 loop, are critical for efficient viral binding to and/or entry into human brain microglia.     

Structural analysis of the envelope gp120 V3 loop for some HIV-1 variants circulating in the countries of Eastern Europe

The V3 loop on gp120 from human immunodeficiency virus type 1 (HIV-1) is a focus of many research groups involved in anti-AIDS drug development because this region of the protein is a principal target for neutralizing antibodies and a major determinant for cell tropism and syncytium formation. In this study, the nucleotide sequences of the env gene region coding the V3 loop were determined by DNA sequencing methods for four novel HIV-1 strains that circulate in the countries of Eastern Europe, such as Russia, Belarus, Ukraine, etc. Based on the empirical data obtained, the 3D structures of the V3 loops associated with these viral modifications were generated by computer modeling and then compared to discover similarities in the spatial arrangement of this functionally important site of gp120. Despite the HIV-1 genetic variety, several regions of the V3 loop that contain residues critical for cell tropism were shown to be structurally invariant, which may explain its exceptional role in a co-receptor usage. These data together with those on the biological activity of the V3 individual residues clearly show that these conserved structural motifs of gp120 represent potential HIV-1 weak points most suitable for therapeutic intervention.     

Covariance of Charged Amino Acids at Positions 322 and 440 of HIV-1 Env Contributes to Coreceptor Specificity of Subtype B Viruses,and Can Be Used to Improve the Performance of V3 Sequence-Based Coreceptor Usage Prediction Algorithms

The ability to determine coreceptor usage of patient-derived human immunodeficiency virus type 1 (HIV-1) strains is clinically important, particularly for the administration of the CCR5 antagonist maraviroc. The envelope glycoprotein (Env) determinants of coreceptor specificity lie primarily within the gp120 V3 loop region, although other Env determinants have been shown to influence gp120-coreceptor interactions. Here, we determined whether conserved amino acid alterations outside the V3 loop that contribute to coreceptor usage exist, and whether these alterations improve the performance of V3 sequence-based coreceptor usage prediction algorithms. We demonstrate a significant covariant association between charged amino acids at position 322 in V3 and position 440 in the C4 Env region that contributes to the specificity of HIV-1 subtype B strains for CCR5 or CXCR4. Specifically, positively charged Lys/Arg at position 322 and negatively charged Asp/Glu at position 440 occurred more frequently in CXCR4-using viruses, whereas negatively charged Asp/Glu at position 322 and positively charged Arg at position 440 occurred more frequently in R5 strains. In the context of CD4-bound gp120, structural models suggest that covariation of amino acids at Env positions 322 and 440 has the potential to alter electrostatic interactions that are formed between gp120 and charged amino acids in the CCR5 N-terminus. We further demonstrate that inclusion of a “440 rule” can improve the sensitivity of several V3 sequence-based genotypic algorithms for predicting coreceptor usage of subtype B HIV-1 strains, without compromising specificity, and significantly improves the AUROC of the geno2pheno algorithm when set to its recommended false positive rate of 5.75%. Together, our results provide further mechanistic insights into the intra-molecular interactions within Env that contribute to coreceptor specificity of subtype B HIV-1 strains, and demonstrate that incorporation of Env determinants outside V3 can improve the reliability of coreceptor usage prediction algorithms.     

Molecular mimicry between the human immunodeficiency virus type 1 gp120 V3 loop and human brain proteins.

Immunologically cross-reactive proteins in the human brain that resemble the V3 loop of human immunodeficiency virus type 1 (HIV-1) gp120 have been identified. When several homogenized tissues from normal brains were used, a monoclonal antibody raised against amino acids 308 to 320 of the V3 loop reacted with three prominent human brain proteins (HBP) of 35, 55, and 110 kDa. Among the three, the 55-kDa HBP appears to be specific to the central nervous system. These results indicate that the V3 loop of HIV-1 gp120 shares an epitope with HBP. An immune response to the V3 loop that generates cross-reactive antibodies to cellular proteins may be an autoimmune mechanism by which HIV-1 can damage the central nervous system.     

Regions required for CD4 binding in the external glycoprotein gp120 of simian immunodeficiency virus.

The external domain of the envelope glycoprotein, gp120, of simian immunodeficiency virus (SIV) has been expressed as a mature secreted product using recombinant baculoviruses and the expressed protein, which has an observed molecular mass of 110 kDa, was purified by monoclonal antibody (MAb) affinity chromatography. N-terminal sequence analysis showed a signal sequence cleavage identity similar to that of the gp120s of both human immunodeficiency virus type 1 (HIV-1) and HIV type 2. The expressed molecule bound to soluble CD4 with an affinity that was approximately 10-fold lower than that of gp120 from HIV-1. A screening of the ability of SIV envelope MAbs to inhibit CD4 binding revealed two groups of inhibitory MAbs. One group is dependent on conformation, while the second group maps to a discrete epitope near the amino terminus. The particular role of the V3 loop region of the molecule in CD4 binding was investigated by the construction of an SIV-HIV hybrid in which the V3 loop of SIV was precisely replaced with the equivalent domain from HIV-1 MN. The hybrid glycoprotein bound HIV-1 V3 loop MAbs and not SIV V3 MAbs but continued to bind conformational SIV MAbs and soluble CD4 as well as the parent molecule.     

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.     

Brucella abortus conjugated with a gp120 or V3 loop peptide derived from human immunodeficiency virus (HIV) type 1 induces neutralizing anti-HIV antibodies, and the V3-B. abortus conjugate is effective even after CD4+ T-cell depletion.

Human immunodeficiency virus type 1 (HIV-1) infection is associated with loss of function and numbers of CD4+ T-helper cells. In order to bypass the requirement for CD4+ cells in antibody responses, we have utilized heat-inactivated Brucella abortus as a carrier. In this study we coupled a 14-mer V3 loop peptide (V3), which is homologous to 9 of 11 amino acids from the V3 loop of HIV-1 MN, and gp120 from HIV-1 SF2 to B. abortus [gp120(SF2)-B. abortus]. Our results showed that specific antibody responses, dominated by immunoglobulin G2a in BALB/c mice, were induced by these conjugates. Sera from the immunized mice bound native gp120 expressed on the surfaces of cells infected with a recombinant vaccinia virus gp160 vector (VPE16). Sera from mice immunized with gp120(SF2)-B. abortus inhibited binding of soluble CD4 to gp120, whereas sera from mice immunized with V3-B. abortus were ineffective. Sera from mice immunized with either conjugate were capable of blocking syncytium formation between CD4+ CEM cells and H9 cells chronically infected with the homologous virus. Sera from mice immunized with gp120(SF2)-B. abortus were more potent than sera from mice immunized with V3-B. abortus in inhibiting syncytia from heterologous HIV-1 laboratory strains. Importantly, in primary and secondary responses, V3-B. abortus evoked anti-HIV MN antibodies in mice depleted of CD4+ cells, and sera from these mice were able to inhibit syncytia. These findings indicate that B. abortus can provide carrier function for peptides and proteins from HIV-1 and suggest that they could be used for immunization of individuals with compromised CD4+ T-cell function.     

Immunochemical analysis of the gp120 surface glycoprotein of human immunodeficiency virus type 1: probing the structure of the C4 and V4 domains and the interaction of the C4 domain with the V3 loop.

We have probed the structure of the C4 and V3 domains of human immunodeficiency virus type 1 gp120 by immunochemical techniques. Monoclonal antibodies (MAbs) recognizing an exposed gp120 sequence, (E/K)VGKAMYAPP, in C4 were differentially sensitive to denaturation of gp120, implying a conformational component to some of the epitopes. The MAbs recognizing conformation-sensitive C4 structures failed to bind to a gp120 mutant with an alteration in the sequence of the V3 loop, and their binding to gp120 was inhibited by both V3 and C4 MAbs. This implies an interaction between the V3 and C4 regions of gp120, which is supported by the observation that the binding of some MAbs to the V3 loop was often enhanced by amino acid changes in an around the C4 region.     

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.