l-731988 and chicoric-acid

AIDS is currently treated with a combination therapy of reverse transcriptase and protease inhibitors. Recently, the FDA approved a drug targeting HIV-1 entry into cells. There are currently no FDA approved drugs targeting HIV-1 integrase, though many scientists and drug companies are actively in pursuit of clinically useful integrase inhibitors. The objective of this review is to provide an update on integrase inhibitors reported in the last two years, including two novel inhibitors in early clinical trials, recently developed hydroxylated aromatics, natural products, peptide, antibody and oligonucleotide inhibitors. Additionally, the proposed mechanism of diketo acid inhibition is reviewed.

Topics: Acetoacetates; Anti-HIV Agents; Biological Factors; Caffeic Acids; Clinical Trials as Topic; Furans; HIV Integrase; HIV Integrase Inhibitors; HIV-1; Humans; Indoles; Models, Molecular; Molecular Structure; Oligonucleotides; Pyrroles; Reverse Transcriptase Inhibitors; Succinates; Tetrazoles; Triazoles

Fourteen analogues of the anti-HIV-1 integrase (IN) inhibitor L-chicoric acid (L-CA) were prepared. Their IC(50) values for 3'-end processing and strand transfer against recombinant HIV-1 IN were determined in vitro, and their cell toxicities and EC(50) against HIV-1 were measured in cells (ex vivo). Compounds 1-6 are catechol/β-diketoacid hybrids, the majority of which exhibit submicromolar potency against 3'-end processing and strand transfer, though only with modest antiviral activities. Compounds 7-10 are L-CA/p-fluorobenzylpyrroloyl hybrids, several of which were more potent against strand transfer than 3'-end processing, a phenomenon previously attributed to the β-diketo acid pharmacophore. Compounds 11-14 are tetrazole bioisosteres of L-CA and its analogues, whose in vitro potencies were comparable to L-CA but with enhanced antiviral potency. The trihydroxyphenyl analogue 14 was 30-fold more potent than L-CA at relatively nontoxic concentrations. These data indicate that L-CA analogues are attractive candidates for development into clinically relevant inhibitors of HIV-1 IN.

Topics: Caffeic Acids; Cell Line; HIV Integrase; HIV Integrase Inhibitors; HIV-1; Humans; Keto Acids; Structure-Activity Relationship; Succinates; Tetrazoles; Virology

The human immunodeficiency virus (HIV) integrase (IN) must covalently join the viral cDNA into a host chromosome for productive HIV infection. l-Chicoric acid (l-CA) enters cells poorly but is a potent inhibitor of IN in vitro. Using quantitative real-time polymerase chain reaction (PCR), l-CA inhibits integration at concentrations from 500 nM to 10 microM but also inhibits entry at concentrations above 1 microM. Using recombinant HIV IN, steady-state kinetic analyses with l-CA were consistent with a noncompetitive or irreversible mechanism of inhibition. IN, in the presence or absence of l-CA, was successively washed. Inhibition of IN diminished, demonstrating that l-CA was reversibly bound to the protein. These data demonstrate that l-CA is a noncompetitive but reversible inhibitor of IN in vitro and of HIV integration in vivo. Thus, l-CA likely interacts with amino acids other than those which bind substrate.

Topics: Acetoacetates; Binding Sites; Caffeic Acids; Cell Line, Tumor; Dose-Response Relationship, Drug; Echinacea; HIV Integrase; HIV Integrase Inhibitors; HIV-1; Humans; Kinetics; Mutation; Polymerase Chain Reaction; Pyrroles; Succinates; Virus Integration

L-chicoric acid (L-CA) is a potent inhibitor of HIV integrase (IN) in vitro. In this report, the effects of a glycine to serine mutation at position 140 (G140S) on HIV IN and its effects on IN inhibitor resistance are described. HIV containing the G140S mutation showed a delay in replication. Using real-time polymerase chain reaction, the delay was secondary to a failure in integration. The mutant protein (IN(G140S)) was attenuated approximately four-fold for catalysis under equilibrium conditions compared to wild-type IN (IN(WT)) and attenuated five-fold in steady-state kinetic analysis of disintegration. Fifty percent inhibitory concentration assays were performed with IN inhibitors against both IN proteins in disintegration and strand transfer reactions. IN(G140S) was resistant to both L-CA and L-731,988, a diketoacid. HIV containing the mutation was resistant to both inhibitors as well. The G140S mutation attenuates IN activity and confers resistance to IN inhibitors, suggesting that diketoacids and L-CA interact with a similar binding site on HIV IN.

Topics: Acetoacetates; Amino Acid Substitution; Caffeic Acids; Cell Line; Drug Resistance, Viral; HIV Integrase; HIV Integrase Inhibitors; HIV-1; Humans; Pyrroles; Reverse Transcriptase Polymerase Chain Reaction; Succinates; Virus Integration; Virus Replication