Synthesis and activity of N-acyl azacyclic urea HIV-1 protease inhibitors with high potency against multiple drug resistant viral strains.

As part of our efforts to identify potent HIV-1 protease inhibitors that are active against resistant viral strains, structural modification of the azacyclic urea (I) was undertaken by incorporating acyl groups as P(1)' ligands. The extensive SAR study has yielded a series of N-acyl azacyclic ureas (II), which are highly potent against both wild-type and multiple PI-resistant viral strains.

Novel lopinavir analogues incorporating heterocyclic replacements of six-member cyclic urea--synthesis and structure-activity relationships.

The HIV protease inhibitor ABT-378 (lopinavir) has a six-member cyclic urea in the P-2 position. A series of analogues in which the six-member cyclic urea is replaced by various heterocycles was synthesized and the structure-activity relationships explored.

Hepatitis C NS3 protease inhibition by peptidyl-alpha-ketoamide inhibitors: kinetic mechanism and structure.

A series of novel peptidyl-alpha-ketoamide compounds were evaluated as inhibitors of the deltaNS3-NS4A serine protease from the hepatitis C virus. These peptidyl-alpha-ketoamide inhibitors with Ki values ranging from 0.17 nM to 5.6 microM exhibited slow-binding inhibition. Kinetic studies established one-step kinetic mechanisms and dissociation rate constants in the 3-7 x 10(-5) s(-1) range for these compounds. The association rate constants, which ranged from 10 to 263,000 M(-1) s(-1), were responsible for the greater than four order of magnitude overall binding affinity range exhibited by this series. An X-ray crystal structure of a protease-inhibitor complex revealed an unusual interaction between the oxyanion of the adduct and the protein as well as a significant movement in the S1' region of the protein loop comprising residues 35-42. These results are quite different from peptidyl-alpha-ketoacid inhibition of HCV protease, which reportedly undergoes no notable conformational changes and proceeds with a two-step slow-binding kinetic mechanism.

Synthesis and SAR studies of potent HIV protease inhibitors containing novel dimethylphenoxyl acetates as P2 ligands.

Isopropyl substituted 4-thioazolyl valine side chains are highly optimized P(2)-P(3) ligands for C2 symmetry-based HIV protease inhibitors, as exemplified by the drug ritonavir. Replacement of the side chain with the conformationally constrained hexahydrofurofuranyloxy P(2) ligand in combination with a dimethylphenoxyacetate on the other end of the ritonavir core diamine yielded highly potent HIV protease inhibitors. The in vitro antiviral activity in MT4 cells increased by 10- and 20-fold, respectively, in the absence and presence of 50% human serum compared to ritonavir. The structure-activity relationships of inhibitor series with this combination of ligands were investigated. Preliminary pharmacokinetic studies in rats indicated rapid elimination of the inhibitors from the blood, and the plasma levels were not significantly enhanced by coadministration with ritonavir. However, the novel structural features and the high intrinsic antiviral potency of this series provides potential for the future exploration of prodrug strategies.

Investigating the origin of the slow-binding inhibition of HCV NS3 serine protease by a novel substrate based inhibitor.

Indandiones were identified as a novel class of small molecule inhibitors of hepatitis C virus NS3 serine protease from high throughput screening. We further studied the structure activity relationships and the mechanisms of inhibition for this class of compounds. Our studies revealed two similar, yet different, mechanisms accounting for the apparent indandione inhibition of HCV NS3 protease. In one case, the apparent inhibition results from the chemical breakdown of the parent compound and the subsequent redox chemistry of the compound. Oxidation of the cysteine containing substrate A to a disulfide-linked dimer converts this substrate to a potent, slow-binding inhibitor with a K(i) value of 170 nM. The second class of indandiones appears to react directly with the substrate to form an S-phenyl disulfide adduct with the P1 cysteine. This modification converts the substrate to a slow-binding inhibitor with a K(i) value of 110 nM, a k(on) = 2370 M(-1) s(-1), and k(off) = 2.5 x 10(-4) s(-1). A stable analogue of this latter compound was synthesized that contained a CH(2)-S linkage instead of the S-S linkage. The CH(2)-S compound showed no inhibition at concentrations as high as 40 microM, which suggests an important role for the S-S linkage in the inhibitory mechanism. Cysteine 159, which lies near the active site of the HCV protease, was mutated to serine. The C159S mutant displayed wild-type catalytic activity and susceptibility to inhibition by the S-S linked inhibitor. This result argues against a mechanism involving disulfide exchange between the inhibitor and the sulfhydryl group of C159. The mechanism of inhibition for this S-S linked substrate based inhibitor is likely due to oxidation of cysteines involved in chelation of the structural zinc atom.

Influenza neuraminidase inhibitors: structure-based design of a novel inhibitor series.

Combinatorial and structure-based medicinal chemistry strategies were used together to advance a lead compound with an activity of K(i) = 58 microM via a potency enhancement of >70 000-fold to an analogue with an activity of K(i) = 0.8 nM against influenza neuraminidase (A/Tokyo/67). Lead optimization was initiated using molecular modeling and combinatorial chemistry. Protein crystal structures revealed that inconsistent structure-activity relationship (SAR) data resulted from different binding orientations of the inhibitor core five-membered rings from one series to another. Binding modes for a series of compounds showed up to a 180 degrees variation in orientation of the five-membered ring within the active site. Potent analogues were only achieved with chemical series that were observed to bind in the same orientation and yielded consistent SAR. In one series, consistent binding was obtained by an unprecedented occupation of a negatively charged binding pocket by a neutral methyl ester unit. The structural rationale for this novel SAR variation, based on protein crystallographic data, is given.

Novel lopinavir analogues incorporating non-Aromatic P-1 side chains--synthesis and structure--activity relationships.

The HIV protease inhibitor Lopinavir has a pseudosymmetric core unit incorporating benzyl groups at both P-1, P-1' positions. A series of analogues incorporating non-aromatic side chains at the P-1 position were synthesized and the structure-activity relationships explored.

Synthesis and structure-activity relationships of a novel series of HIV-1 protease inhibitors encompassing ABT-378 (Lopinavir).

The HIV protease inhibitor ABT-378 (Lopinavir) has a 2,6-dimethylphenoxyacetyl group in the P-2' position. Analogues in which this group is replaced with various substituted phenyl or heteroaryl groups were synthesized and the structure-activity relationships explored.