NMR study of the peptide present in the principal neutralizing determinant (PND) of HIV-1 envelope glycoprotein gp120

Crystal structures of human immunodeficiency virus type 1 (HIV-1) neutralizing antibody 2219 in complex with three different V3 peptides reveal a new binding mode for HIV-1 cross-reactivity

Human monoclonal antibody 2219 is a neutralizing antibody isolated from a human immunodeficiency virus type 1-infected individual. 2219 was originally selected for binding to a V3 fusion protein and can neutralize primary isolates from subtypes B, A, and F. Thus, 2219 represents a cross-reactive, human anti-V3 antibody. Fab 2219 binds to one face of the variable V3 beta-hairpin, primarily contacting conserved residues on the N-terminal beta-strand of V3, leaving the V3 crown or tip largely accessible. Three V3/2219 complexes reveal the antibody-bound conformations for both the N- and C-terminal regions that flank the V3 crown and illustrate how twisting of the V3 loop alters the relative dispositions and pairing of the amino acids in the adjacent V3 beta-strands and how the antibody can accommodate V3 loops with different sequences.

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.

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.

V3: HIV's switch-hitter

The third variable region, V3, of the gp120 surface envelope glycoprotein is an approximately 35-residue-long, frequently glycosylated, highly variable, disulfide-bonded structure that has a major influence on HIV-1 tropism. Thus the sequence of V3, directly or indirectly, can determine which coreceptor (CCR5 or CXCR4) is used to trigger the fusion potential of the Env complex, and hence which cells the virus can infect. V3 also influences HIV-1's sensitivity to, and ability to escape from, entry inhibitors that are being developed as antiviral drugs. For some strains, V3 is a prominent target for HIV-1 neutralizing antibodies (NAbs); indeed, for many years it was considered to be the "principal neutralization determinant" (PND). Some efforts to use V3 as a vaccine target continue to this day, despite disappointing progress over more than a decade. Recent findings on the structure, function, antigenicity, and immunogenicity of V3 cast new doubts on the value of this vaccine approach. Here, we review recent advances in the understanding of V3 as a determinant of viral tropism, and discuss how this new knowledge may inform the development of HIV-1 drugs and vaccines.

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.

Structural Rationale for the Broad Neutralization of HIV-1 by Human Monoclonal Antibody 447-52D

447-52D is a human monoclonal antibody isolated from a heterohybridoma derived from an HIV-1-infected individual. This antibody recognizes the hypervariable gp120 V3 loop, and neutralizes both X4 and R5 primary isolates, making it one of the most effective anti-V3 antibodies characterized to date. The crystal structure of the 447-52D Fab in complex with a 16-mer V3 peptide at 2.5 A resolution reveals that the peptide beta hairpin forms a three-stranded mixed beta sheet with complementarity determining region (CDR) H3, with most of the V3 side chains exposed to solvent. Sequence specificity is conferred through interaction of the type-II turn (residues GPGR) at the apex of the V3 hairpin with the base of CDR H3. This novel mode of peptide-antibody recognition enables the antibody to bind to many different V3 sequences where only the GPxR core epitope is absolutely required.

3D Structure Model of the Principal Neutralizing Epitope of Minnesota HIV-1 Isolate

A hierarchical procedure, using a "bottom-up" strategy and combining (i). a probabilistic approach for estimating all possible starting structures, (ii). restrained molecular mechanics algorithms for preliminary selection of all energetically preferred conformers, as well as (iii). quantum chemical computations for refining their geometry, was used to study the structural properties of the HIV-MN neutralizing epitope in terms of NMR spectroscopy data. As a result, only one of initial structures matching the experimental and theoretical data was found to be well-ground for implementing the function of immunoreactive conformation of the virus immunogenic crown. The geometric parameters of this structure in water solution were shown to correspond to a double beta-turn conformation similar to that revealed in crystal for synthetic molecules imitating the central region of the HIV-MN V3 loop. The following conclusion was drawn from the comparative analysis of simulated structure with the one computed previously: the HIV-MN immunogenic tip has some inherent conformational flexibility that manifests at the alterations of hexapeptide environment and leads to the structural transitions changing the local conformation of the stretch of interest but retaining its spatial main chain fold. As a matter of record, the high resolution 3D structure model for the HIV-MN principal neutralization site was constructed, and its geometric parameters were compared with the corresponding characteristics of conformers derived earlier for describing the conformational features of immunogenic tip of gp120 from Thailand HIV-1 isolate.

Recurring conformation of the human immunodeficiency virus type 1 gp120 V3 loop

The crystal structure of the human immunodeficiency virus type 1 (HIV-1) neutralizing, murine Fab 83.1 in complex with an HIV-1 gp120 V3 peptide has been determined to 2.57 A resolution. The conformation of the V3 loop peptide in complex with Fab 83.1 is very similar to V3 conformations seen previously with two other neutralizing Fabs, 50.1 and 59.1. The repeated identification of this same V3 conformation in complex with three very different, neutralizing antibodies indicates that it is a highly preferred structure for V3 loops on some strains of the HIV-1 virus.

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.