Time-dependent diaryl ether inhibitors of InhA: structure-activity relationship studies of enzyme inhibition, antibacterial activity, and in vivo efficacy.

The diaryl ethers are a novel class of antituberculosis drug candidates that inhibit InhA, the enoyl-ACP reductase involved in the fatty acid biosynthesis (FASII) pathway, and have antibacterial activity against both drug-sensitive and drug-resistant strains of Mycobacterium tuberculosis. In the present work, we demonstrate that two time-dependent B-ring modified diaryl ether InhA inhibitors have antibacterial activity in a mouse model of TB infection when delivered by intraperitoneal injection. We propose that the efficacy of these compounds is related to their residence time on the enzyme, and to identify structural features that modulate drug-target residence time in this system, we have explored the inhibition of InhA by a series of B-ring modified analogues. Seven ortho-substituted compounds were found to be time-dependent inhibitors of InhA, where the slow step leading to the final enzyme-inhibitor complex (EI*) is thought to correlate with closure and ordering of the InhA substrate binding loop. A detailed mechanistic understanding of the molecular basis for residence time in this system will facilitate the development of InhA inhibitors with improved in vivo activity.

Probing HIV-1 integrase inhibitor binding sites with position-specific integrase-DNA cross-linking assays.

HIV-1 integrase binds site-specifically to the ends of the viral cDNA. We used two HIV-1 integrase-DNA cross-linking assays to probe the binding sites of integrase inhibitors from different chemical families and with different strand transfer selectivities. The disulfide assay probes cross-linking between the integrase residue 148 and the 5'-terminal cytosine of the viral cDNA, and the Schiff base assay probes cross-linking between an integrase lysine residue and an abasic site placed at selected positions in the viral cDNA. Cross-linking interference by eight integrase inhibitors shows that the most potent cross-linking inhibitors are 3'-processing inhibitors, indicating that cross-linking assays probe the donor viral cDNA (donor binding site). In contrast, strand transfer-selective inhibitors provide weak cross-linking interference, consistent with their binding to a specific acceptor (cellular DNA) site. Docking and crystal structure studies illustrate specific integrase-inhibitor contacts that prevent cross-linking formation. Four inhibitors that prevented Schiff base cross-linking to the conserved 3'-terminal adenine position were examined for inhibition at various positions within the terminal 21 bases of the viral cDNA. Two of them selectively inhibited upper strand cross-linking, whereas the other two had a more global effect on integrase-DNA binding. These findings have implications for elucidating inhibitor binding sites and mechanisms of action. The cross-linking assays also provide clues to the molecular interactions between integrase and the viral cDNA.

Effect of DNA modifications on DNA processing by HIV-1 integrase and inhibitor binding: role of DNA backbone flexibility and an open catalytic site.

Integration of the viral cDNA into host chromosomes is required for viral replication. Human immunodeficiency virus integrase catalyzes two sequential reactions, 3'-processing (3'-P) and strand transfer (ST). The first integrase inhibitors are undergoing clinical trial, but interactions of inhibitors with integrase and DNA are not well understood in the absence of a co-crystal structure. To increase our understanding of integrase interactions with DNA, we examined integrase catalysis with oligonucleotides containing DNA backbone, base, and groove modifications placed at unique positions surrounding the 3'-processing site. 3'-Processing was blocked with substrates containing constrained sugars and alpha-anomeric residues, suggesting that integrase requires flexibility of the phosphodiester backbone at the 3'-P site. Of several benzo[a]pyrene 7,8-diol 9,10-epoxide (BaP DE) adducts tested, only the adduct in the minor groove at the 3'-P site inhibited 3'-P, suggesting the importance of the minor groove contacts for 3'-P. ST occurred in the presence of bulky BaP DE DNA adducts attached to the end of the viral DNA suggesting opening of the active site for ST. Position-specific effects of these BaP DE DNA adducts were found for inhibition of integrase by diketo acids. Together, these results demonstrate the importance of DNA structure and specific contacts with the viral DNA processing site for inhibition by integrase inhibitors.

Identification of an inhibitor-binding site to HIV-1 integrase with affinity acetylation and mass spectrometry.

We report a methodology that combines affinity acetylation with MS analysis for accurate mapping of an inhibitor-binding site to a target protein. For this purpose, we used a known HIV-1 integrase inhibitor containing aryl di-O-acetyl groups (Acetylated-Inhibitor). In addition, we designed a control compound (Acetylated-Control) that also contained an aryl di-O-acetyl group but did not inhibit HIV-1 integrase. Examination of the reactivity of these compounds with a model peptide library, which collectively contained all 20 natural amino acids, revealed that aryl di-O-acetyl compounds effectively acetylate Cys, Lys, and Tyr residues. Acetylated-Inhibitor and Acetylated-Control exhibited comparable chemical reactivity with respect to these small peptides. However, these two compounds differed markedly in their interactions with HIV-1 integrase. In particular, Acetylated-Inhibitor specifically acetylated K173 at its inhibitory concentration (3 microM) whereas this site remained unrecognized by Acetylated-Control. Our data enabled creation of a detailed model for the integrase:Acetylated-Inhibitor complex, which indicated that the inhibitor selectively binds at an architecturally critical region of the protein. The methodology reported herein has a generic application for systems involving a variety of ligand-protein interactions.