Scientific Publications

Host cell barriers to the early phase of immunodeficiency virus replication explain the current distribution of these viruses among human and non-human primate species. Human immunodeficiency virus type 1 (HIV-1), the cause of acquired immunodeficiency syndrome (AIDS) in humans, efficiently enters the cells of Old World monkeys but encounters a block before reverse transcription. This species-specific restriction acts on the incoming HIV-1 capsid and is mediated by a dominant repressive factor. Here we identify TRIM5alpha, a component of cytoplasmic bodies, as the blocking factor. HIV-1 infection is restricted more efficiently by rhesus monkey TRIM5alpha than by human TRIM5alpha. The simian immunodeficiency virus, which naturally infects Old World monkeys, is less susceptible to the TRIM5alpha-mediated block than is HIV-1, and this difference in susceptibility is due to the viral capsid. The early block to HIV-1 infection in monkey cells is relieved by interference with TRIM5alpha expression. Our studies identify TRIM5alpha as a species-specific mediator of innate cellular resistance to HIV-1 and reveal host cell components that modulate the uncoating of a retroviral capsid.

The linear peptide 12p1 (RINNIPWSEAMM) was previously isolated from a phage display library and was found to inhibit interaction of HIV-1 gp120 with both CD4 and a CCR5 surrogate, mAb 17b [Ferrer, M., and Harrison, S. (1999) J. Virol. 73, 5795-5802]. In this work, we investigated the mechanism that leads to this dual inhibition of gp120 binding. We found that there is a direct interaction of 12p1 with gp120, which occurs with a binding stoichiometry of 1:1. The peptide inhibits binding of monomeric YU2 gp120 to both sCD4 and 17b at IC(50) values of 1.1 and 1.6 microM, respectively. The 12p1 peptide also inhibited the binding of these ligands to trimeric envelope glycoproteins, blocked the binding of gp120 to the native coreceptor CCR5, and specifically inhibited HIV-1 infection of target cells in vitro. Analyses of sCD4 saturation of monomeric gp120 in the presence or absence of a fixed concentration of peptide suggest that 12p1 suppression of CD4 binding to gp120 is due to allosteric inhibitory effects rather than competitive inhibition of CD4 binding. Using a panel of gp120 mutants that exhibit weakened inhibition by 12p1, the putative binding site of the peptide was mapped to a region immediately adjacent to, but distinguishable from, the CD4 binding footprint. In the case of the peptide, the effects of single-12p1 residue substitutions and various peptide truncations indicate that the side chain of Trp7 and other structural elements of 12p1 are critical for gp120 binding or efficient inhibition of binding of a ligand to gp120. Finally, 12p1 was unable to inhibit binding of sCD4 to a gp120 mutant that is believed to resemble the CD4-induced conformation of gp120. These results suggest that 12p1 preferentially binds gp120 prior to engagement of CD4; binding of the peptide to gp120 limits the interaction with ligands (CD4 and CCR5) that are generally crucial for viral entry. More importantly, these results indicate that 12p1 binds to a unique site that may prove to be a prototypic target for novel CD4-gp120 inhibitors.

Passage of a nonpathogenic simian-human immunodeficiency virus (SHIV-HXBc2) in monkeys resulted in changes in the viral envelope glycoproteins that are responsible for a dramatic increase in replication and pathogenicity in vivo. Here, we show that the envelope glycoproteins of the pathogenic SHIV-HXBc2P 3.2 mediate virus entry into rhesus monkey peripheral blood mononuclear cells (PBMC) more efficiently than the parental SHIV-HXBc2 envelope glycoproteins, and study the basis for this increase. Both parental and pathogenic SHIVs exclusively use CXCR4 as a coreceptor. The determinants of the increased entry associated with the SHIV-HXBc2P 3.2 envelope glycoproteins are located in both the gp120 and gp41 subunits. Changes in the gp120 V3 variable loop specify a decreased sensitivity to SDF-1, consistent with an increase in the affinity of the HXBc2P 3.2 gp120 glycoprotein for CXCR4. Thus, multiple changes in the gp120 variable loops and the gp41 ectodomain of a pathogenic SHIV cooperate to allow enhanced replicative capacity, which in part results from increased chemokine receptor binding.

One mechanism of immune evasion utilized by human immunodeficiency virus (HIV) and simian immunodeficiency virus (SIV) envelope glycoproteins is the presence of a dense carbohydrate shield. Accumulating evidence from in vitro and in vivo experiments suggests that alterations in N-linked glycosylation of SIV gp120 can enhance host humoral immune responses that may be involved in immune control. The present study was designed to determine the ability of glycosylation mutant viruses to redirect antibody responses to shielded envelope epitopes. The influence of glycosylation on the maturation and specificity of antibody responses elicited by glycosylation mutant viruses containing mutations of specific N-linked sites in and near the V1 and V2 regions of SIVmac239 gp120 was determined. Results from these studies demonstrated a remarkably similar maturation of antibody responses to native, fully glycosylated envelope proteins. However, analyses of antibodies to defined envelope domains revealed that mutation of glycosylation sites in V1 resulted in increased antibody recognition to epitopes in V1. In addition, we demonstrated for the first time that mutation of glycosylation sites in V1 resulted in a redirection of antibody responses to the V3 loop. Taken together, these results demonstrate that N-linked glycosylation is a determinant of SIV envelope B-cell immunogenicity in addition to in vitro antigenicity. In addition, our results demonstrate that the absence of N-linked carbohydrates at specific sites can influence the exposure of epitopes quite distant in the linear sequence.

An increasing body of evidence suggests that a vaccine that elicits anti-HIV-1 cellular immunity could provide the basis for an effective AIDS vaccine. Comparative immunization experiments testing a variety of vaccine approaches have demonstrated that replication-incompetent adenovirus vectors are an effective means for eliciting cytotoxic T-lymphocyte (CTL) immune responses against HIV-1 antigens. These immune responses effectively control viremia in nonhuman primates following challenge with simian AIDS viruses. Such data, coupled with epidemiology studies that identify HIV-1 gag, pol, and nef as the best antigens for broadly directed cellular immune responses, provide guidance for the development of a potential AIDS vaccine.

Human immunodeficiency virus type 1 (HIV-1) fuses with cells after sequential interactions between its envelope glycoproteins, CD4 and a coreceptor, usually CC chemokine receptor 5 (CCR5) or CXC receptor 4 (CXCR4). CMPD 167 is a CCR5-specific small molecule with potent antiviral activity in vitro. We show that CMPD 167 caused a rapid and substantial (4-200-fold) decrease in plasma viremia in six rhesus macaques chronically infected with simian immunodeficiency virus (SIV) strains SIVmac251 or SIVB670, but not in an animal infected with the X4 simian-human immunodeficiency virus (SHIV), SHIV-89.6P. In three of the SIV-infected animals, viremia reduction was sustained. In one, there was a rapid, but partial, rebound and in another, there was a rapid and complete rebound. There was a substantial delay (>21 d) between the end of therapy and the onset of full viremia rebound in two animals. We also evaluated whether vaginal administration of gel-formulated CMPD 167 could prevent vaginal transmission of the R5 virus, SHIV-162P4. Complete protection occurred in only 2 of 11 animals, but early viral replication was significantly less in the 11 CMPD 167-recipients than in 9 controls receiving carrier gel. These findings support the development of small molecule CCR5 inhibitors as antiviral therapies, and possibly as components of a topical microbicide to prevent HIV-1 sexual transmission.

Coreceptor use of HIV can evolve during infection. We previously examined coreceptor use of related SIVsm inoculum viruses and sequential reisolates from cynomolgus macaques. These viruses exhibited broad coreceptor specificities and, generally, CCR5 use remained efficient and stable, while alternative coreceptor use decreased longitudinally. Here we demonstrate that individual envelopes (Envs) from inoculum and reisolate viruses fuse via a range of coreceptors, including CCR5, CCR8, CXCR6, GPR15, GPR1, and APJ. On the whole, coreceptor use of Envs from sequential reisolates recapitulated that of reisolate viruses, thus CCR5 use remained stable while alternative coreceptor use tended to decrease over time. Rhesus CCR5, GPR15, and CXCR6 supported fusion to a similar extent as their human counterparts. Additionally, a number of Envs mediated CD4-independent fusion via CCR5 and GPR15. Envs from different inoculum viruses exhibited distinct dependencies on CD4 for fusion via CCR5, ranging from strictly CD4-dependent to efficiently CD4-independent. Early reisolates from macaques infected with CD4-independent inoculums maintained or evolved Envs with a broad range of CD4-independence. CD4-independence became less variable/efficient in late reisolates from macaques that developed neutralizing antibodies. Infection with a CD4-dependent virus resulted in evolution of CD4-independent Envs in late reisolates. While CD4 independence can potentially broaden tropism in vivo, CD4-independent viruses are particularly sensitive to neutralizing antibodies. Therefore, interplay between receptor tropism and neutralization may shape viral evolution and SIV pathogenesis.

Residues within the highly conserved C3 region of human and simian immunodeficiency virus (HIV, SIV) envelope proteins (Envs) bind directly to the cellular CD4 receptor. However, substitutions of D385, which is critical for CD4 engagement along with other changes such as G382R, G383R, frequently arise in SIV mac-infected macaques. We investigated the influence of substitutions in the SIVmac and HIV-1 C3 regions on viral entry, dependence on CD4, and replication. Mutations flanking the C3 region such as G382R or V388A enhanced and changes within the C3 region (i.e., G383R or D385N) impaired SIVmac infectivity. Several naturally occurring sequence variations in the SIVmac Env C3 region facilitated CD4-independent membrane fusion but abrogated viral replication, suggesting that efficient infection requires additional changes elsewhere in Env. Substitutions of S365R and D368G in the HIV-1 Env, which correspond to G382 and D385 in SIVmac Env, consistently impaired viral infectivity. In contrast, mutation of D368N resulted in a virus that could not spread in cells expressing low levels of CD4, but which replicated efficiently when high levels of CD4 were expressed. Thus, changes in the C3 region of HIV-1 or SIVmac Env can have differential effects on viral infectivity and CD4-dependency. We conclude that substitutions flanking the C3 region in SIVmac Env such as G382R or V388A represent one step toward adaptation to growth in target cells expressing low CD4 levels, whereas changes within the C3 region that disrupt CD4 binding might indicate the emergence of CD4-independent variants at later stages of infection, which could potentially broaden viral tropism.

Human immunodeficiency virus (HIV-1) enters target cells by binding its gp120 exterior envelope glycoprotein to CD4 and one of the chemokine receptors, CCR5 or CXCR4. CD4-induced (CD4i) antibodies bind gp120 more efficiently after CD4 binding and block the interaction with the chemokine receptor. Examples of CD4i antibodies are limited, and the prototypes of the CD4i antibodies exhibit only weak neutralizing activity against primary, clinical HIV-1 isolates. Here we report the identification of a novel antibody, E51, that exhibits CD4-induced binding to gp120 and neutralizes primary HIV-1 more efficiently than the prototypic CD4i antibodies. The E51 antibody blocks the interaction of gp120-CD4 complexes with CCR5 and binds to a highly conserved, basic gp120 element composed of the beta 19-strand and surrounding structures. Thus, on primary HIV-1 isolates, this gp120 region, which has been previously implicated in chemokine receptor binding, is accessible to a subset of CD4i antibodies.

Anti-human immunodeficiency virus type 1 (HIV-1) antibodies whose binding to gp120 is enhanced by CD4 binding (CD4i antibodies) are generally considered nonneutralizing for primary HIV-1 isolates. However, a novel CD4i-specific Fab fragment, X5, has recently been found to neutralize a wide range of primary isolates. To investigate the precise nature of the extraordinary neutralizing ability of Fab X5, we evaluated the abilities of different forms (immunoglobulin G [IgG], Fab, and single-chain Fv) of X5 and other CD4i monoclonal antibodies to neutralize a range of primary HIV-1 isolates. Our results show that, for a number of isolates, the size of the neutralizing agent is inversely correlated with its ability to neutralize. Thus, the poor ability of CD4i-specific antibodies to neutralize primary isolates is due, at least in part, to steric factors that limit antibody access to the gp120 epitopes. Studies of temperature-regulated neutralization or fusion-arrested intermediates suggest that the steric effects are important in limiting the binding of IgG to the viral envelope glycoproteins after HIV-1 has engaged CD4 on the target cell membrane. The results identify hurdles in using CD4i epitopes as targets for antibody-mediated neutralization in vaccine design but also indicate that the CD4i regions could be efficiently targeted by small molecule entry inhibitors.