Isabelle Mondor

Selective Interactions of Polyanions with Basic Surfaces on Human Immunodeficiency Virus Type 1 gp120

ABSTRACT It is well established that the gp120 V3 loop of T-cell-line-adapted human immunodeficiency virus type 1 (HIV-1) binds both cell-associated and soluble polyanions. Virus infectivity is increased by interactions between HIV-1 and heparan sulfate proteoglycans on some cell types, and soluble polyanions such as heparin and dextran sulfate neutralize HIV-1 in vitro. However, the analysis of gp120-polyanion interactions has been limited to T-cell-line-adapted, CXCR4-using virus and virus-derived gp120, and the polyanion binding ability of gp120 regions other than the V3 loop has not been addressed. Here we demonstrate by monoclonal-antibody inhibition, labeled heparin binding, and surface plasmon resonance studies that a second site, most probably corresponding to the newly defined, highly conserved coreceptor binding region on gp120, forms part of the polyanion binding surface. Consistent with the binding of polyanions to the coreceptor binding surface, dextran sulfate interfered with the gp120-CXCR4 association while having no detectable effect on the gp120-CD4 interaction. The interaction between polyanions and X4 or R5X4 gp120 was readily detectable, whereas weak or undetectable binding was observed with R5 gp120. Analysis of mutated forms of X4 gp120 demonstrated that the V3 loop is the major determinant for polyanion binding whereas other regions, including the V1/V2 loop structure and the NH2 and COOH termini, exert a more subtle influence. A molecular model of the electrostatic potential of the conserved coreceptor binding region confirmed that it is basic but that the overall charge on this surface is dominated by the V3 loop. These results demonstrate a selective interaction of gp120 with polyanions and suggest that the conserved coreceptor binding surface may present a novel and conserved target for therapeutic intervention.

HIV-1 attachment: another look

HIV-1 attachment to host cells is generally considered to take place via high-affinity binding between CD4 and gp120. However, the binding of virion-associated gp120 to cellular CD4 is often weak, and most cell types that are permissive for HIV-1 infection express little CD4. Thus, other interactions between the virion and the cell surface could dominate the attachment process.

Antibody neutralization of HIV-1 and the potential for vaccine design

Neutralisation by antibody is, for a number of viruses, an in vitro correlate for protection in vivo. For HIV-1 this is controversial. However, the induction of a potent anti-HIV neutralising antibody response remains one of the principal goals in vaccine development. A greater knowledge of the fundamental mechanisms underlying the neutralisation process would help direct research towards suitable vaccine immunogens. The primary determinant of HIV neutralisation appears to be antibody affinity for the trimeric envelope glycoprotein spike on the virion, suggesting that epitope-specific effects are secondary and implying a single, dominant mechanism of neutralisation. Antibody interference with virion attachment to the target cell appears to be a major mechanism of neutralisation by gp120-specific antibodies. This is probably achieved both by antibody-induced dissociation of gp120 from gp41 and by direct inhibition of virus binding to receptor-coreceptor complexes. A gp41-specific antibody neutralises by interfering with post-attachment steps leading to virus membrane fusion. Recent advances in structural analyses of the HIV envelope glycoproteins coupled with data obtained from antibody mapping and neutralisation studies allow a greater understanding of Env function and its inhibition. This in turn should lead to a more rational basis for vaccine design aimed at stimulating highly effective neutralising antibodies.

Expansion of epitope cross-reactivity by anti-idiotype modulation of the primary humoral response.

The primary humoral response produces antigen-specific antibodies so to clear the initial infection, and generates a population of corresponding memory cells to prevent infection by future encounters with the same pathogen. The continuous genetic modification of a pathogens exterior, however, is one mechanism used to evade the immune defenses of its host. Here we describe a novel means, involving anti-idiotypic antibodies, by which the host can counteract such pathogen genetic alterations by modulation of its primary humoral response. An autoimmune response against primary antibodies, Ab1s, creates anti-idiotypic antibodies (Ab2s), some of which (designated Ab2alpha) are able to bind the Ab1/antigen complex. We have discovered that binding of Ab2alpha to its corresponding Ab1 can expand Ab1s ability to bind variations of its antigen. This expanded epitope cross-reactivity is shown not only to increase the binding activity of Ab1 but also its ability to neutralize a variant infectious virus. MAb M77 is an Ab1, which is highly strain-specific for the HIV-1 envelope protein gp120(IIIB). This Ab1 can be rendered cross-reactive and neutralizing for an otherwise resistant HIV strain by its interaction with a unique anti-idiotypic Ab2alpha (GV12). Furthermore, molecular characterization of this expanded cross-reactivity was accomplished using combinatorial phage display peptide libraries.