Discovery of a small-molecule HIV-1 integrase inhibitor-binding site.

Herein, we report the identification of a unique HIV-1 integrase (IN) inhibitor-binding site using photoaffinity labeling and mass spectrometric analysis. We chemically incorporated a photo-activatable benzophenone moiety into a series of coumarin-containing IN inhibitors. A representative of this series was covalently photo-crosslinked with the IN core domain and subjected to HPLC purification. Fractions were subsequently analyzed by using MALDI-MS and electrospray ionization (ESI)-MS to identify photo-crosslinked products. In this fashion, a single binding site for an inhibitor located within the tryptic peptide (128)AACWWAGIK(136) was identified. Site-directed mutagenesis followed by in vitro inhibition assays resulted in the identification of two specific amino acid residues, C130 and W132, in which substitutions resulted in a marked resistance to the IN inhibitors. Docking studies suggested a specific disruption in functional oligomeric IN complex formation. The combined approach of photo-affinity labeling/MS analysis with site-directed mutagenesis/molecular modeling is a powerful approach for elucidating inhibitor-binding sites of proteins at the atomic level. This approach is especially important for the study of proteins that are not amenable to traditional x-ray crystallography and NMR techniques. This type of structural information can help illuminate processes of inhibitor resistance and thereby facilitate the design of more potent second-generation inhibitors.

Mutations in both env and gag genes are required for HIV-1 resistance to the polysulfonic dendrimer SPL2923, as corroborated by chimeric virus technology.

A drug-resistant NL4.3/SPL2923 strain has previously been generated by in vitro selection of HIV-1(NL4.3) in the presence of the polysulfonic dendrimer SPL2923 and mutations were reported in its gp120 gene (Witvrouw et al., 2000). Here, we further analysed the (cross) resistance profile of NL4.3/SPL2923. NL4.3/SPL2923 was found to contain additional mutations in gp41 and showed reduced susceptibility to SPL2923, dextran sulfate (DS) and enfuvirtide. To delineate to what extent the mutations in each env gene were accountable for the phenotypic (cross) resistance of NL4.3/SPL2923, the gp120-, gp41- and gp160-sequences derived from this strain were placed into a wild-type background using env chimeric virus technology (CVT). The cross resistance of NL4.3/SPL2923 towards DS was fully reproduced following gp160-recombination, while it was only partially reproduced following gp120- or gp41-recombination. The mutations in gp41 of NL4.3/SPL2923 were sufficient to reproduce the cross resistance to enfuvirtide. Unexpectedly, the reduced sensitivity towards SPL2923 was not fully reproduced after gp160-recombination. The search for mutations in NL4.3/SPL2923 in viral genes other than env revealed several mutations in the gene encoding the HIV p17 matrix protein (MA) and one mutation in the gene encoding the p24 capsid protein (CA). In order to analyse the impact of the gag mutations alone and in combination with the mutations in env on the phenotypic resistance towards SPL2923, we developed a novel p17- and p17/gp160-CVT. Phenotypic analysis of the NL4.3/SPL2923 p17- and p17/gp160-recombined strains indicated that the mutations in both env and gag have to be present to fully reproduce the resistance of NL4.3/SPL2923 towards SPL2923.

Resistance of human immunodeficiency virus type 1 to the high-mannose binding agents cyanovirin N and concanavalin A.

Due to the biological significance of the carbohydrate component of the human immunodeficiency virus type 1 (HIV-1) glycoproteins in viral pathogenesis, the glycosylation step constitutes an attractive target for anti-HIV therapy. Cyanovirin N (CV-N), which specifically targets the high-mannose (HM) glycans on gp120, has been identified as a potent HIV-1 entry inhibitor. Concanavalin A (ConA) represents another mannose-binding lectin, although it has a lower specificity for HM glycans than that of CV-N. For the present study, we selected CV-N- and ConA-resistant HIV-1 strains in the presence of CV-N and ConA, respectively. Both resistant strains exhibited a variety of mutations eliminating N-linked glycans within gp120. Strains resistant to CV-N or ConA displayed high levels of cross-resistance towards one another. The N-glycan at position 302 was eliminated in both of the lectin-resistant strains. However, the elimination of this glycan alone by site-directed mutagenesis was not sufficient to render HIV-1 resistant to CV-N or ConA, suggesting that HIV-1 needs to mutate several N-glycans to become resistant to these lectins. Both strains also demonstrated clear cross-resistance towards the carbohydrate-dependent monoclonal antibody 2G12. In contrast, the selected strains did not show a reduced susceptibility towards the nonlectin entry inhibitors AMD3100 and enfuvirtide or towards reverse transcriptase or protease inhibitors. Recombination of the mutated gp160 genes of the strains resistant to CV-N or ConA into a wild-type background fully reproduced the (cross-)resistance profiles of the originally selected strains, pointing to the impact of the N-glycan mutations on the phenotypic resistance profiles of both selected strains.

Multiple mutations in human immunodeficiency virus-1 integrase confer resistance to the clinical trial drug S-1360.

OBJECTIVES: Study of HIV-1 resistance development to the diketo analogue S-1360, the first HIV-1 integrase strand transfer inhibitor that has entered clinical development. DESIGN: HIV-1(IIIB) was passaged in cell culture in the presence of increasing concentrations of S-1360 (IIIB/S-1360(res)). METHODS: The IIIB/S-1360(res) strains selected for 30, 50 and 70 passages in the presence of S-1360 were evaluated genotypically by sequencing analysis and phenotypically using the MT-4/MTT assay. RESULTS: Multiple mutations, nine in total, emerged progressively in the catalytic domain of integrase as a result of the selection process. They included T66I and L74M that have both been associated with resistance against the diketo acid L-708,906. After 30, 50 and 70 passages in the presence of S-1360, IIIB/S-1360(res) displayed a four-, eight- and more than 62-fold reduced susceptibility for S-1360, respectively. Phenotypic cross-resistance to L-708,906 was modest for the IIIB/S-1360(res) strain selected during 50 passages, but pronounced for the strain selected during 70 passages. Interesting, all IIIB/S-1360(res) strains remained fully susceptible to the pyranodipyrimidine V-165, an integrase DNA binding inhibitor. Recombination of the mutant integrase genes into wild-type background by integrase-chimeric virus technology entirely reproduced the resistance profile of the IIIB/S-1360(res) strains. As for the replication kinetics of the selected and recombined strains, reduced replication fitness was measured for all strains when compared with their respective wild-type strains. CONCLUSIONS: The accumulation of integrase mutations coincided with an increasing level of (cross-)resistance of IIIB/S-1360(res). Integrase-chimeric virus technology confirmed that the integrase mutations are indeed fully responsible for the resistance phenotype of IIIB/S-1360.

Development of resistance against diketo derivatives of human immunodeficiency virus type 1 by progressive accumulation of integrase mutations.

The diketo acid L-708,906 has been reported to be a selective inhibitor of the strand transfer step of the human immunodeficiency virus type 1 (HIV-1) integration process (D. Hazuda, P. Felock, M. Witmer, A. Wolfe, K. Stillmock, J. A. Grobler, A. Espeseth, L. Gabryelski, W. Schleif, C. Blau, and M. D. Miller, Science 287:646-650, 2000). We have now studied the development of antiviral resistance to L-708,906 by growing HIV-1 strains in the presence of increasing concentrations of the compound. The mutations T66I, L74M, and S230R emerged successively in the integrase gene. The virus with three mutations (T66I L74M S230R) was 10-fold less susceptible to L-708,906, while displaying the sensitivity of the wild-type virus to inhibitors of the RT or PRO or viral entry process. Chimeric HIV-1 strains containing the mutant integrase genes displayed the same resistance profile as the in vitro-selected strains, corroborating the impact of the reported mutations on the resistance phenotype. Phenotypic cross-resistance to S-1360, a diketo analogue in clinical trials, was observed for all strains. Interestingly, the diketo acid-resistant strain remained fully sensitive to V-165, a novel integrase inhibitor (C. Pannecouque, W. Pluymers, B. Van Maele, V. Tetz, P. Cherepanov, E. De Clercq, M. Witvrouw, and Z. Debyser, Curr. Biol. 12:1169-1177, 2002). Antiviral resistance was also studied at the level of recombinant integrase. Single mutations did not appear to impair specific enzymatic activity. However, 3' processing and strand transfer activities of the recombinant integrases with two (T66I L74M) and three (T66I L74M S230R) mutations were notably lower than those of the wild-type integrase. Although the virus with three mutations was resistant to inhibition by diketo acids, the sensitivity of the corresponding enzyme to L-708,906 or S-1360 was reduced only two- to threefold. As to the replication kinetics of the selected strains, the replication fitness for all strains was lower than that of the wild-type HIV-1 strain.

Potent and selective inhibition of HIV and SIV by prostratin interacting with viral entry.

Prostratin, a non-tumour promoting phorbol ester, exhibit a potent anti-HIV activity against human immunodeficiency virus type 1 (HIV-1). However, the antiviral mechanism of prostratin is not well defined. In the present study, we report that prostratin exhibits potent antiviral activity against different strains of HIV-1 (subtypes B and D), a clinical HIV isolate (L1), HIV-2 (ROD and EHO) and SIV (MAC251) with EC50-values ranging from 0.02-0.09 microg/ml. Prostratin was equally active against HIV strains resistant to the polyanionic binding inhibitor dextran sulphate, the fusion inhibitor T-20 (enfuvirtide), nucleoside reverse transcriptase inhibitors (NRTIs) or protease inhibitors (PIs). In contrast, prostratin lost 4.4- and 6.8-fold of its effect against the HIV strains resistant to AMD3100 and the quaternary ammonium salt QAS10+, respectively. As shown by time-of-addition experiments, prostratin needs to be present at the time of viral adsorption to exert its antiviral activity. We selected an HIV strain (NL4.3/PROS) resistant to prostratin in MT-4 cells. The sensitivity of NL4.3/PROS towards prostratin, dextran sulphate and QAS10+ was reduced by 3.2, 4.1 and >50-fold, respectively. However, NL4.3/ PROS was still sensitive to AMD3100, T-20, NRTIs (zidovudine and nevirapine) and a PI (ritonavir). Recombination of the gp160-gene of the NL4.3/PROS strain in a NL4.3 wild-type molecular clone fully rescued its phenotypic resistance. DNA sequencing of the NL4.3/PROS strain revealed mutations throughout the gp120 gene previously associated with resistance towards other HIV entry inhibitors. We concluded that prostratin inhibits the entry step of the replication cycle of HIV by interacting with a cellular target necessary for viral entry.

env chimeric virus technology for evaluating human immunodeficiency virus susceptibility to entry inhibitors.

We describe the development of chimeric virus technology (CVT) for human immunodeficiency virus (HIV) type 1 (HIV-1) env genes gp120, gp41, and gp160 for evaluation of the susceptibilities of HIV to entry inhibitors. This env CVT allows the recombination of env sequences derived from different strains into a proviral wild-type HIV-1 clone (clone NL4.3) from which the corresponding env gene has been deleted. An HIV-1 strain (strain NL4.3) resistant to the fusion inhibitor T20 (strain NL4.3/T20) was selected in vitro in the presence of T20. AMD3100-resistant strain NL3.4 (strain NL4.3/AMD3100) was previously selected by De Vreese et al. (K. De Vreese et al., J. Virol. 70:689-696, 1996). NL4.3/AMD3100 contains several mutations in its gp120 gene (De Vreese et al., J. Virol. 70:689-696, 1996), whereas NL4.3/T20 has mutations in both gp120 and gp41. Phenotypic analysis revealed that NL4.3/AMD3100 lost its susceptibility to dextran sulfate, AMD3100, AMD2763, T134, and T140 but not its susceptibility to T20, whereas NL4.3/T20 lost its susceptibility only to the inhibitory effect of T20. The recombination of gp120 of NL4.3/AMD3100 and gp41 of NL4.3/T20 or recombination of the gp160 genes of both strains into a wild-type background reproduced the phenotypic (cross-)resistance profiles of the corresponding strains selected in vitro. These data imply that mutations in gp120 alone are sufficient to reproduce the resistance profile of NL4.3/AMD3100. The same can be said for gp41 in relation to NL4.3/T20. In conclusion, we demonstrate the use of env CVT as a research tool in the delineation of the region important for the phenotypic (cross-)resistance of HIV strains to entry inhibitors. In addition, we obtained a proof of principle that env CVT can become a helpful diagnostic tool in assessments of the phenotypic resistance of clinical HIV isolates to HIV entry inhibitors.

Inhibition of human immunodeficiency virus type 1 integration by diketo derivatives.

A series of diketo derivatives was found to inhibit human immunodeficiency virus type 1 (HIV-1) integrase activity. Only L-708,906 inhibited the replication of HIV-1(III(B)) (50% effective concentration, 12 micro M), HIV-1 clinical strains, HIV-1 strains resistant to reverse transcriptase or fusion inhibitors, HIV-2 (ROD strain) and simian immunodeficiency virus (MAC(251)). The combinations of L-708,906 with zidovudine, nevirapine, or nelfinavir proved to be subsynergistic. In cell culture, addition of L-708,906 could be postponed for 7 h after infection, a moment coinciding with HIV integration. Inhibition of integration in cell culture was confirmed by quantitative Alu-PCR.