Deletion of the highly conserved N-glycan at Asn260 of HIV-1 gp120 affects folding and lysosomal degradation of gp120, and results in loss of viral infectivity.

N-linked glycans covering the surface of the HIV-1 glycoprotein gp120 are of major importance for the correct folding of this glycoprotein. Of the, on average, 24 N-linked glycans present on gp120, the glycan at Asn260 was reported to be essential for the correct expression of gp120 and gp41 in the virus particle and deletion of the N260 glycan in gp120 heavily compromised virus infectivity. We show here that gp160 containing the N260Q mutation reaches the Golgi apparatus during biosynthesis. Using pulse-chase experiments with [35S] methionine/cysteine, we show that oxidative folding was slightly delayed in case of mutant N260Q gp160 and that CD4 binding was markedly compromised compared to wild-type gp160. In the search of compensatory mutations, we found a mutation in the V1/V2 loop of gp120 (S128N) that could partially restore the infectivity of mutant N260Q gp120 virus. However, the mutation S128N did not enhance any of the above-mentioned processes so its underlying compensatory mechanism must be a conformational effect that does not affect CD4 binding per se. Finally, we show that mutant N260Q gp160 was cleaved to gp120 and gp41 to a much lower extent than wild-type gp160, and that it was subject of lysosomal degradation to a higher extent than wild-type gp160 showing a prominent role of this process in the breakdown of N260-glycan-deleted gp160, which could not be counteracted by the S128N mutation. Moreover, at least part of the wild-type or mutant gp160 that is normally targeted for lysosomal degradation reached a conformation that enabled CD4 binding.

Feglymycin, a unique natural bacterial antibiotic peptide, inhibits HIV entry by targeting the viral envelope protein gp120.

Feglymycin (FGM), a natural Streptomyces-derived 13mer peptide, consistently inhibits HIV replication in the lower µM range. FGM also inhibits HIV cell-to-cell transfer between HIV-infected T cells and uninfected CD4(+) T cells and the DC-SIGN-mediated viral transfer to CD4(+) T cells. FGM potently interacts with gp120 (X4 and R5) as determined by SPR analysis and shown to act as a gp120/CD4 binding inhibitor. Alanine-scan analysis showed an important role for l-aspartic acid at position 13 for its anti-HIV activity. In vitro generated FGM-resistant HIV-1 IIIB virus (HIV-1 IIIB(FGMres)) showed two unique mutations in gp120 at positions I153L and K457I. HIV-1 IIIB(FGMres) virus was equally susceptible to other viral binding/adsorption inhibitors with the exception of dextran sulfate (9-fold resistance) and cyclotriazadisulfonamide (>15-fold), two well-described compounds that interfere with HIV entry. In conclusion, FGM is a unique prototype lead peptide with potential for further development of more potent anti-HIV derivatives.

Thioredoxin-1 and protein disulfide isomerase catalyze the reduction of similar disulfides in HIV gp120.

HIV-1 enters cells via interaction of the viral glycoprotein gp120, the host cell surface receptor CD4 and the co-receptors CCR5 or CXCR4. For entry, gp120 undergoes conformational changes that depend on the reduction of one or more disulfides. Previous studies indicate that protein disulfide isomerase (PDI), thioredoxin-1 (Trx1), and glutaredoxin-1 (Grx1) catalyze gp120 reduction, but their specific disulfide targets are not known. Here, it was demonstrated that PDI and Trx1 have similar gp120 disulfide targets as determined by labeling after reduction, but with some pattern differences, including overall stronger labeling with Trx1 than with PDI. Furthermore, uneven labeling of the residues of a disulfide may reflect altered accessibility by conformational changes upon the reduction process. Since both PDI and Trx1 may be involved in viral entry, compounds that target the host redox system or the viral gp120 were tested in vitro to investigate whether redox regulation is a target for anti-HIV therapy. Carbohydrate binding agents (CBAs), previously shown to bind gp120 and inhibit HIV entry, were now demonstrated to inhibit gp120 disulfide reduction. Auranofin, an inhibitor of thioredoxin reductase 1 (TrxR1), also showed inhibitory activity towards HIV infection, although close to its cytotoxic concentration. Our results demonstrate that both the host redox system and the viral surface glycoproteins are of interest for the development of new generations of anti-HIV therapeutics.

The highly conserved glycan at asparagine 260 of HIV-1 gp120 is indispensable for viral entry.

Carbohydrate-binding agents bind to the N-glycans of HIV-1 envelope gp120 and prevent viral entry. Carbohydrate-binding agents can select for mutant viruses with deleted envelope glycans. Not all glycosylation motifs are mutated to the same extent. Site-directed mutagenesis revealed that deletions destroying the highly conserved (260)NGS(262) glycosylation motif resulted in non-infectious virus particles. We observed a significant lower CD4 binding in the case of the N260Q mutant gp120 virus strains, caused by a strikingly lower expression of gp120 and gp41 in the virus particle. In addition, the mutant N260Q HIV-1 envelope expressed in 293T cells was unable to form syncytia in co-cultures with U87.CD4.CXCR4.CCR5 cells, due to the lower expression of envelope protein on the surface of the transfected 293T cells. The detrimental consequence of this N-glycan deletion on virus infectivity could not be compensated for by the creation of novel glycosylation sites near this amino acid, leaving this uncovered envelope epitope susceptible to neutralizing antibody binding. Thus, the Asn-260 glycan in the gp120 envelope of HIV-1 represents a hot spot for targeting suicidal drugs or antibodies in a therapeutic effort to efficiently neutralize a broad array of virus strains.

Actinohivin, a broadly neutralizing prokaryotic lectin, inhibits HIV-1 infection by specifically targeting high-mannose-type glycans on the gp120 envelope.

The lectin actinohivin (AH) is a monomeric carbohydrate-binding agent (CBA) with three carbohydrate-binding sites. AH strongly interacts with gp120 derived from different X4 and R5 human immunodeficiency virus (HIV) strains, simian immunodeficiency virus (SIV) gp130, and HIV type 1 (HIV-1) gp41 with affinity constants (KD) in the lower nM range. The gp120 and gp41 binding of AH is selectively reversed by (alpha1,2-mannose)3 oligosaccharide but not by alpha1,3/alpha1,6-mannose- or GlcNAc-based oligosaccharides. AH binding to gp120 prevents binding of alpha1,2-mannose-specific monoclonal antibody 2G12, and AH covers a broader epitope on gp120 than 2G12. Prolonged exposure of HIV-1-infected CEM T-cell cultures with escalating AH concentrations selects for mutant virus strains containing N-glycosylation site deletions (predominantly affecting high-mannose-type glycans) in gp120. In contrast to 2G12, AH has a high genetic barrier, since several concomitant N-glycosylation site deletions in gp120 are required to afford significant phenotypic drug resistance. AH is endowed with broadly neutralizing activity against laboratory-adapted HIV strains and a variety of X4 and/or R5 HIV-1 clinical clade isolates and blocks viral entry within a narrow concentration window of variation (approximately 5-fold). In contrast, the neutralizing activity of 2G12 varied up to 1,000-fold, depending on the virus strain. Since AH efficiently prevents syncytium formation in cocultures of persistently HIV-1-infected HuT-78 cells and uninfected CD4+ T lymphocytes, inhibits dendritic cell-specific intercellular adhesion molecule 3-grabbing nonintegrin-mediated capture of HIV-1 and subsequent virus transmission to CD4+ T lymphocytes, does not upregulate cellular activation markers, lacks mitogenic activity, and does not induce cytokines/chemokines in peripheral blood mononuclear cell cultures, it should be considered a potential candidate drug for microbicidal use.

Pradimicin S, a highly soluble nonpeptidic small-size carbohydrate-binding antibiotic, is an anti-HIV drug lead for both microbicidal and systemic use.

Pradimicin S (PRM-S) is a highly water-soluble, negatively charged derivative of the antibiotic pradimicin A (PRM-A) in which the terminal xylose moiety has been replaced by 3-sulfated glucose. PRM-S does not prevent human immunodeficiency virus (HIV) adsorption on CD4(+) T cells, but it blocks virus entry into its target cells. It inhibits a wide variety of HIV-1 laboratory strains and clinical isolates, HIV-2, and simian immunodeficiency virus (SIV) in various cell culture systems (50% and 90% effective concentrations [EC(50)s and EC(90)s] invariably in the lower micromolar range). PRM-S inhibits syncytium formation between persistently HIV-1- and SIV-infected cells and uninfected CD4(+) T lymphocytes, and prevents dendritic cell-specific intercellular adhesion molecule-3-grabbing nonintegrin (DC-SIGN)-mediated HIV-1 and SIV capture and subsequent virus transmission to CD4(+) T cells. Surface plasmon resonance (SPR) studies revealed that PRM-S strongly binds to gp120 in a Ca(2+)-dependent manner at an affinity constant (K(D)) in the higher nanomolar range. Its anti-HIV activity and HIV-1 gp120-binding properties can be dose-dependently reversed in the presence of an (alpha-1,2)mannose trimer. Dose-escalating exposure of HIV-1-infected cells to PRM-S eventually led to the isolation of mutant virus strains that had various deleted N-glycosylation sites in the envelope gp120 with a strong preference for the deletion of the high-mannose-type glycans. Genotypic resistance development occurred slowly, and significant phenotypic resistance occurred only after the sequential appearance of up to six mutations in gp120, pointing to a high genetic barrier of PRM-S. The antibiotic is nontoxic against a variety of cell lines, is not mitogenic, and does not induce cytokines and chemokines in peripheral blood mononuclear cells as determined by the Bio-Plex human cytokine 27-plex assay. It proved stable at high temperature and low pH. Therefore, PRM-S may qualify as a potential anti-HIV drug candidate for further (pre)clinical studies, including its microbicidal use.

The phthalocyanine prototype derivative Alcian Blue is the first synthetic agent with selective anti-human immunodeficiency virus activity due to its gp120 glycan-binding potential.

Alcian Blue (AB), a phthalocyanine derivative, is able to prevent infection by a wide spectrum of human immunodeficiency virus type 1 (HIV-1), HIV-2, and simian immunodeficiency virus strains in various cell types [T cells, (co)receptor-transfected cells, and peripheral blood mononuclear cells]. With the exception of herpes simplex virus, AB is inactive against a broad variety of other (DNA and RNA) viruses. Time-of-addition studies show that AB prevents HIV-1 infection at the virus entry stage, exactly at the same time as carbohydrate-binding agents do. AB also efficiently prevents fusion between persistently HIV-1-infected HUT-78 cells and uninfected (CD4(+)) lymphocytes, DC-SIGN-directed HIV-1 capture, and subsequent transmission to uninfected (CD4(+)) T lymphocytes. Prolonged passaging of HIV-1 at dose-escalating concentrations of AB resulted in the selection of mutant virus strains in which several N-glycans of the HIV-1 gp120 envelope were deleted and in which positively charged amino acid mutations in both gp120 and gp41 appeared. A mutant virus strain in which four N-glycans were deleted showed a 10-fold decrease in sensitivity to the inhibitory effect of AB. These data suggest that AB is likely endowed with carbohydrate-binding properties and can be considered an important lead compound in the development of novel synthetic nonpeptidic antiviral drugs targeting the glycans of the envelope of HIV.

Capture and transmission of HIV-1 by the C-type lectin L-SIGN (DC-SIGNR) is inhibited by carbohydrate-binding agents and polyanions.

It was recently shown that capture of HIV-1 by DC-SIGN-expressing cells and the subsequent transmission of HIV to CD4+ T-lymphocytes can be prevented by carbohydrate-binding agents (CBAs), whereas polyanions were unable to block virus capture by DC-SIGN. In this study, we could show that a short pre-exposure of HIV-1 to both mannose- and N-acetylglucosamine (GlcNAc)-specific CBAs or polyanions dose-dependently prevented virus capture by L-SIGN-expressing 293T-REx/L-SIGN cells and subsequent syncytia formation in co-cultures of the drug-exposed HIV-1-captured 293T-REx/L-SIGN cells and uninfected C8166 CD4+ T-lymphocytes. Additionally, the inhibitory potential of the compounds against L-SIGN-mediated HIV-1 capture and transmission was more pronounced than observed for DC-SIGN expressing293T-REx/DC-SIGN cells. The excess value of CBAs and polyanions to prevent HIV-1 capture and transmission by DC-SIGN and L-SIGN-expressing cells to susceptible T-lymphocytes could be of interest for the development of new drug leads targeting HIV entry/fusion.

Glycan deletions in the HIV-1 gp120 V1/V2 domain compromise viral infectivity, sensitize the mutant virus strains to carbohydrate-binding agents and represent a specific target for therapeutic intervention.

Carbohydrate-binding agents (CBAs), such as the mannose-specific Hippeastrum hybrid agglutinin (HHA) and the GlcNAc-specific Urtica dioica agglutinin (UDA), frequently select for glycan deletions in all different domains of HIV-1 gp120, except in the V1/V2 domain. To reveal the underlying mechanisms, a broad variety of 31 different virus strains containing one or several N-glycan deletions in V1/V2 of the gp120 of the X4-tropic HIV-1(NL4.3) were constructed by chimeric virus technology. No co-receptor switch to CCR5 was observed for any of the replication-competent mutant virus strains. With a few exceptions, the more glycans were deleted in the gp120 V1/V2 domain, the more the replication capacity of the mutant viruses became compromised. None of the mutant virus strains showed a markedly decreased sensitivity to the inhibitory activity of HHA and UDA. Instead, an up to 2- to 10-fold higher sensitivity to the inhibitory activity of these CBAs was observed. Our data may provide an explanation why glycan deletions in the gp120 V1/V2 domain rarely occur under CBA pressure and confirm the important functional role of the glycans in the HIV-1 gp120 V1/V2 domain. The gp120 V1/V2 loop glycans of HIV-1 should therefore be considered as a hot spot and novel target for specific therapeutic drug intervention.

Simian immunodeficiency virus is susceptible to inhibition by carbohydrate-binding agents in a manner similar to that of HIV: implications for further preclinical drug development.

Carbohydrate-binding agents (CBAs), such as the plant lectins Hippeastrum hybrid agglutinin (HHA) and Urtica dioica agglutinin (UDA), but also the nonpeptidic antibiotic pradimicin A (PRM-A), inhibit entry of HIV into its target cells by binding to the glycans of gp120. Given the high sequence identity and similarity between the envelope gp120 glycoproteins of HIV and simian immunodeficiency virus (SIV), the inhibitory activity of a variety of CBAs were evaluated against HIV-1, HIV-2, and SIV. There seemed to be a close correlation for the inhibitory potential of CBAs against HIV-1, HIV-2, and SIV replication in cell culture and syncytia formation in cocultures of persistently SIV-infected HUT-78 cell cultures and uninfected CEM cells. CBAs also inhibit transmission of the SIV to T lymphocytes after capture of the virus by dendritic cell-specific ICAM3-grabbing nonintegrin (DC-SIGN)-expressing cells. A total of 8 different SIV strains were isolated after prolonged HHA, UDA, and PRM-A exposure in virus-infected cell cultures. Each virus isolate consistently contained at least 2 or 3 glycan deletions in its gp120 envelope and showed decreased sensitivity to the CBAs and cross-resistance toward all CBAs. Our data revealed that CBAs afford SIV and HIV-1 inhibition in a similar manner regarding prevention of virus infection, DC-SIGN-directed virus capture-related transmission, and selection of drug-resistant mutant virus strains. Therefore, SIV(mac251)-infected monkeys might represent a relevant animal model to study the efficacy of CBAs in vivo.