6-aryl-2,4-dioxo-5-hexenoic acids, novel integrase inhibitors active against HIV-1 multiplication in cell-based assays

A series of 6-aryl-2,4-dioxo-5-hexenoic acids, were synthesized and tested against HIV-1 in cell-based assays and against recombinant HIV-1 integrase (rIN) in enzyme assays. Compound 8a showed potent antiretroviral activity (EC(50)=1.5 microM) and significant inhibition against rIN (strand transfer: IC(50)=7.9 microM; 3'-processing: IC(50)=7.0 microM). A preliminary molecular modeling study was carried out to compare the spatial conformation of 8a with those of L-731988 (4) and 5CITEP (7) in the IN core.     

Thalassiolins A-C: new marine-derived inhibitors of HIV cDNA integrase

Human immunodeficiency virus (HIV) replication requires integration of viral cDNA into the host genome, a process mediated by the viral enzyme integrase. We describe a new series of HIV integrase inhibitors, thalassiolins A-C (1-3), isolated from the Caribbean sea grass Thalassia testudinum. The thalassiolins are distinguished from other flavones previously studied by the substitution of a sulfated beta-D-glucose at the 7-position, a substituent that imparts increased potency against integrase in biochemical assays. The most active of these molecules, thalassiolin A (1), displays in vitro inhibition of the integrase catalyzed strand transfer reaction (IC50=0.4 microM) and an antiviral IC50 of 30 microM. Molecular modeling studies indicate a favorable binding mode is probable at the catalytic core domain of HIV-1 integrase.     

Carbonyl J Derivatives: A New Class of HIV-1 Integrase Inhibitors

Integration of a DNA copy of the HIV-1 genome is required for viral replication and pathogenicity, and this highly specific molecular process is mediated by the virus-encoded integrase protein. The requirement for integration, combined with the lack of a known analogous process in mammalian cells, makes integrase an attractive target for therapeutic inhibitors of HIV-1 replication. While many reports of HIV-1 IN inhibitors exist, no such compounds have yet emerged to treat HIV-1 infection. As such, new classes of integrase inhibitors are needed. We have combined molecular modeling and combinatorial chemistry to identify and develop a new class of HIV-1 integrase inhibitors, the Carbonyl J [N,N'-bis(2-(5-hydroxy-7-naphthalenesulfonic acid)urea] derivatives. This new class includes a number of compounds with sub-micromolar IC(50) values for inhibiting purified HIV-1 integrase in vitro. Herein we describe the chemical characteristics that are important for integrase inhibition and cell toxicity within the Carbonyl J derivatives. Copyright 2000 Academic Press.     

Interfacial peptide inhibitors of HIV-1 integrase activity and dimerization

Peptides derived from the interfacial region of dimeric HIV-1 integrase were evaluated as inhibitors of integrase's 3'-endonuclease activity. Three peptides were found to be moderately potent inhibitors with IC(50) values in the low micromolar range. The mode of inhibition was probed through protein crosslinking experiments. Active interfacial peptides were found to inhibit crosslinking of the dimeric form of integrase. Interfacial peptides that were poor inhibitors had no effect on integrase crosslinking.     

HIV-1 integrase inhibition by dimeric bisbenzimidazoles with different spacer structures

HIV-1 integrase is responsible for one of the key stages in virus replication, namely, integration of viral cDNA into the host cell genome. Integration inhibition leads to a complete block of the virus replication. We studied the integration inhibition by dimeric bisbenzimidazoles DBBI(7) with heptamethylene and DBBI(8) with tri(ethylene glycol) spacers and found that IC₅₀ for DBBI(7) was approximately 0.03 μM and for DBBI(8) it was approximately 10 μM. Cross-linking assays demonstrated that both compounds interfered with a proper positioning of the DNA substrate in the active centre of integrase. To clarify the inhibition mechanism, dissociation constants were determined for the complexes between DBBI and integrase DNA substrate. Calculated K _d values for the complexes formed by DBBI(7) and DBBI(8) were 270 and 140 nM, respectively. Thus, the integration inhibition is not directly connected with DBBI binding to DNA. The dependence of initial enzymatic reaction rate on DNA substrate concentration in the presence of different concentrations of inhibitors was found, and inhibition constants were determined. These data suggest that different inhibition activity of DBBI(7) and DBBI (8) is determined by different mechanisms underlying their action, namely, competitive inhibition of integrase by DBBI(7) and a more complex mechanism assumed for DBBI(8).     

Disruption of HIV-1 integrase-DNA complexes by short 6-oxocytosine-containing oligonucleotides

We recently found that oligonucleotides containing the 6-oxocytosine heterocyclic base are efficient inhibitors of the HIV-1 integrase in vitro [Brodin, P., et al. (2001) Nucleosides Nucleotides Nucleic Acids 20, 481-486]. In this report, we demonstrate that the inhibition arises from a noncompetitive mechanism in which the modified oligonucleotide attacks the integrase-DNA complex, leading to its active disruption. This conclusion is based on the following results. First, despite the fact that the respective affinities of a 6-oxocytosine-containing oligonucleotide and of its nonmodified counterpart for integrase were identical, only the modified compound inhibited the enzyme activities. Second, DNA binding and UV cross-linking assays indicated that the 6-oxocytosine-containing oligonucleotide prevented the formation of a stable integrase-DNA complex. Third, the kinetics of the dissociation of the integrase-DNA complex were dramatically accelerated in the presence of the modified ODN, whereas the nonmodified counterpart did not influence the dissociation. This mechanism was supported by the ability of the 6-oxocytosine-containing oligonucleotide to inhibit the strand transfer activity of HIV-1 preintegration complexes in vitro. Disruption of integrase-DNA complexes by 6-oxocytosine-containing oligonucleotides constitutes an original mechanism of integration inhibition, therefore suggesting a strategy for searching for inhibitors of the HIV-1 preintegration complexes.     

Design,synthesis and biological evaluation of novel acetamide-substituted doravirine and its prodrugs as potent HIV-1 NNRTIs

A novel series of acetamide-substituted derivatives and two prodrugs of doravirine were designed and synthesized as potent HIV-1 NNRTIs by employing the structure-based drug design strategy. In MT-4 cell-based assays using the MTT method, it was found that most of the new compounds exhibited moderate to excellent inhibitory potency against the wild-type (WT) HIV-1 strain with a minimum EC₅₀ value of 54.8?nM. Among them, the two most potent compounds 8i (EC₅₀?=?59.5?nM) and 8k (EC₅₀?=?54.8?nM) displayed robust activity against WT HIV-1 with double-digit nanomolar EC₅₀ values, being superior to lamivudine (3TC, EC₅₀?=?12.8?μM) and comparable to doravirine (EC₅₀?=?13?nM). Besides, 8i and 8k shown moderate activity against the double RT mutant (K103N?+?Y181C) HIV-1 RES056 strain. The HIV-1 RT inhibition assay further validated the binding target. Molecular simulation of the representative compounds was employed to provide insight on their structure-activity relationships (SARs) and direct future design efforts. Finally, the aqueous solubility and chemical stability of the prodrugs 9 and 10 were investigated in detail.