Differential protein acetylation induced by novel histone deacetylase inhibitors.

Histone deacetylase (HDAC) inhibitors induce the hyperacetylation of nucleosomal histones in carcinoma cells resulting in the expression of repressed genes that cause growth arrest, terminal differentiation, and/or apoptosis. In vitro selectivity of several novel hydroxamate HDAC inhibitors including succinimide macrocyclic hydroxamates and the non-hydroxamate alpha-ketoamide inhibitors was investigated using isolated enzyme preparations and cellular assays. In vitro selectivity for the HDAC isozymes (HDAC1/2, 3, 4/3, and 6) was not observed for these HDAC inhibitors or the reference HDAC inhibitors, MS-275 and SAHA. In T24 and HCT116 cells these compounds caused the accumulation of acetylated histones H3 and H4; however, the succinimide macrocyclic hydroxamates and the alpha-ketoamides did not cause the accumulation of acetylated alpha-tubulin. These data suggest "selectivity" can be observed at the cellular level with HDAC inhibitors and that the nature of the zinc-chelating moiety is an important determinant of activity against tubulin deacetylase.

Biaryl ether retrohydroxamates as potent, long-lived, orally bioavailable MMP inhibitors.

A novel series of biaryl ether reverse hydroxamate MMP inhibitors has been developed. These compounds are potent MMP-2 inhibitors with limited activity against MMP-1. Select members of this series exhibit excellent pharmacokinetic properties with long elimination half-lives (7 h) and high oral bioavailability (100%).

Discovery and characterization of the potent, selective and orally bioavailable MMP inhibitor ABT-770.

Modification of the biphenyl portion of MMP inhibitor 2a gave analogue 2i which is greater than 1000-fold selective against MMP-2 versus MMP-1. The stereospecific synthesis of both enantiomers of 2i was achieved beginning with (S)- or (R)-benzyl glycidyl ether. The (S)-enantiomer, 11 (ABT-770), is orally bioavailable and efficacious in an in vivo model of tumor growth.

Characterization of matrix metalloproteinase inhibitors: enzymatic assays.

The matrix metalloproteinases (MMPs) are a family of tightly regulated proteases that are involved in the catabolic aspect of remodeling and maintenance of normal tissue, and more than 20 human MMPs have been identified thus far. The MMPs collectively degrade a broad range of protein components of the extracellular matrix. While some substrate overlap exists, individual MMPs have been shown to process certain substrates more efficiently than others. These differences raise the critical issue of whether broad-spectrum inhibitors, active against all MMPs, or selective inhibitors, targeted to a subset of enzymes, represent the optimal therapeutic strategy for a given disease. This suggests the need to assess the inhibition potency of test compounds across a range of MMP family members. Described in this unit is a method for the in vitro characterization of MMP inhibitors. The is used to determine the potency of test compounds as inhibitors of 8 representative MMPs through the measurement of their inhibition of cleavage of a fluorogenic substrate. Since this substrate is efficiently hydrolyzed by all MMPs in the screening assays presented here, the method is convenient for assessing the selectivity of inhibitors against multiple enzymes. A describes the activation of MMP zymogens.

Evaluation of the inhibition of other metalloproteinases by matrix metalloproteinase inhibitors.

Two series of compounds synthesized as specific matrix metalloproteinase (MMP) inhibitors have been evaluated for their inhibition of non-MMPs. In a series of substituted succinyl hydroxamic acids, some were found to be significant (IC50 < 1 microM) inhibitors of leucine (microsomal) aminopeptidase, neprilysin (3.4.24.11), and thermolysin. Macrocyclic compounds in which the alpha carbon of the succinyl hydroxamate is linked to the side chain of the P2' amino acid were found to be good inhibitors of aminopeptidase, but not of neprilysin or thermolysin. Compounds of neither series were found to be significant inhibitors of angiotensin converting enzyme or carboxypeptidase A.

Broad spectrum matrix metalloproteinase inhibitors: an examination of succinamide hydroxamate inhibitors with P1 C alpha gem-disubstitution.

A series of P1 C alpha gem-disubstituted succinamide hydroxamate matrix metalloproteinase inhibitors were prepared stereoselectively and evaluated in vitro for their ability to inhibit MMP-1, MMP-2, and MMP-3. It was found that while methyl/allyl substitution as in 2 and 18 provided compounds that were broad spectrum inhibitors and nearly equipotent with parent inhibitor 1, a larger group such as bis-allyl as in 13 or gem-cyclopentyl as in 14 significantly reduced enzyme inhibition.

The design, synthesis, and structure-activity relationships of a series of macrocyclic MMP inhibitors.

A series of succinate-derived hydroxamic acids incorporating a macrocyclic ring were designed, synthesized, and evaluated as inhibitors of matrix metalloproteinases. The inhibitors were designed based on the published X-ray crystal structure of batimastat (1) complexed with human neutrophil collagenase (MMP-8). The synthesized compounds were shown to inhibit selected MMPs in vitro with low nanomolar potency.

Aryl ketones as novel replacements for the C-terminal amide bond of succinyl hydroxamate MMP inhibitors.

A series of succinyl hydroxamate MMP inhibitors were prepared incorporating an aryl amino ketone moiety in place of the more typical C-terminal amino acid amides. Compounds of the C-terminal ketone series displayed potent inhibition of MMPs. Several compounds of the series were shown to be orally bioavailable.

Characterization of the activation of pro-urokinase by thermolysin.

The bacterial metalloproteinase thermolysin catalyzes the efficient activation of pro-urokinase to an active high-molecular-weight form of the protein. Thermolysin and plasmin convert pro-urokinase to enzymes of essentially equal activities in amidolytic assays, but with different molecular structures. The B-chains of the proteins produced by thermolysin and plasmin are of the same size (33 kDa) and have the same amino-terminal sequences, demonstrating that the cleavage of the Lys158-Ile159 bond of pro-urokinase is catalyzed by both enzymes. However, thermolysin also reacts at additional sites in the growth factor domain of the A-chain at nearly the same rate as that of the activation reaction. Polypeptides derived from hydrolyses of the Glu3-Leu4, Tyr24-Phe25, Asn27-Ile28 and Lys36-Phe37 bonds are recovered after reduction of the activated protein. The carboxy-terminus of the A-chain has been shown to be Arg-156, a consequence of proteolysis of the Arg156-Phe157 bond. In contrast to plasmin, thermolysin activates thrombin-inactivated pro-urokinase nearly as rapidly as it does the native zymogen. Thermolysin provides a useful alternative to plasmin for the catalytic activation and analysis of pro-urokinase, since the bacterial metalloproteinase is stable in solution and not susceptible to inhibition by aprotinin and other serine proteinase inhibitors.

The matrix metalloproteinase pump-1 catalyzes formation of low molecular weight (pro)urokinase in cultures of normal human kidney cells.

The enzyme responsible for the metalloproteinase activity which cleaves the Glu143-Leu144 bond of (pro)urokinase has been isolated from the conditioned medium of cultured normal human kidney cells. Using S-Sepharose and Cibacron Blue-agarose chromatography, then C-4 reversed phase high pressure liquid chromatography, a protein of about 20,000 Da was isolated. Through an identical amino-terminal sequence, the protein was shown to be the matrix metalloproteinase previously referred to in the literature as "pump-1" (putative metalloproteinase). When aprotinin was added during the course of the purification, the major species isolated was the zymogen form (28,000 Da) of pump-1. Pump-1 has been shown to efficiently cleave the susceptible bond of both pro-urokinase (single-chain) and active (two-chain) urokinase and thereby produce the corresponding low molecular weight forms. The amino-terminal sequences of the A and B chains of low molecular weight urokinase prepared by action of pump-1 on recombinant high molecular weight urokinase are identical to those of the low molecular weight urokinase isolated from human kidney cell culture. Since the reaction of urokinase with this metalloproteinase results in separation of its serine proteinase region from the domain which mediates binding to the urokinase receptor, it may be of importance in the regulation of the functional activity of the plasminogen activator in cellular processes.

Synthesis of 2,2-dimethyl-4-hydroxy-4-androstene-3,17-dione as an inhibitor of aromatase.

2,2-Dimethyl-4-hydroxy-4-androstene-3,17-dione (4) has been synthesized and has been shown to be a powerful competitive inhibitor of aromatase (Ki = 11.4 nM). However, compound 4 does not cause time-dependent loss of enzyme activity, in contrast to the unmethylated parent compound, 4-OHA.

Pure human inactive renin. Evidence that native inactive renin is prorenin.

To clarify contradicting observations on the identity of inactive renin and prorenin, inactive renin was completely purified from native human chorion laeve and the culture medium of human chorion cells. A 720,000-fold purification with 14% recovery was achieved from chorion laeve in 6 steps, including immunoaffinity chromatography on a monoclonal antibody to human renin coupled to Protein A-Sepharose CL-4B. A 3,100-fold purification with 40% recovery was achieved from chorion culture medium in 4 steps, including immunoaffinity chromatography. Inactive renin purified from the two different sources migrated as a single protein band with the same molecular weight of 47,000 on sodium dodecyl sulfate-polyacrylamide gel electrophoresis and consisted of multiple components that could be resolved by isoelectric focusing. Both had the same pI values which shifted downward upon activation by trypsin; however, relative peak heights were different between the two preparations. The purified inactive renin from chorion laeve was completely inactive and did not bind to pepstatin-aminohexyl-Sepharose; however, that from chorion culture medium was partially active and completely bound to the pepstatin gel, indicating that each molecule is partially activated. Trypsin-activated inactive renins from both sources were identical with human renal renin in terms of pH optimum and Km. Specific activities of trypsin-activated inactive renin from chorion laeve and chorion culture medium were 529 Goldblatt units/mg of protein and 449 Goldblatt units/mg of protein, respectively. Amino acid sequence analysis of both of the purified inactive renin preparations demonstrated a leucine residue at the amino terminus. The sequence of 11 additional amino acids was identical in both and agreed with that predicted from the base sequence of the renin gene. These findings indicate that preprorenin is converted to prorenin following removal of a 23-amino acid signal peptide and that the native inactive renin, whose amino acid sequence commences with Leu-Pro-Thr..., is prorenin.

Renin inhibitors. Dipeptide analogues of angiotensinogen utilizing a dihydroxyethylene transition-state mimic at the scissile bond to impart greater inhibitory potency.

The synthesis of diol-containing renin inhibitors has revealed that a simple vicinal diol functionality corresponding to the scissile Leu-Val bond in human angiotensinogen is capable of imparting inhibitory activity at a comparable or higher level than either the corresponding aldehyde or hydroxymethyl functionality (compare inhibitors 2a-c or 3a-c). This finding has led to the further optimization of a series of small transition-state analogue inhibitors by the inclusion of a second hydroxyl group in the Leu-Val surrogate to give compounds that inhibited human renin in the 200-700-pM range (e.g. 43, 45, 63, 66). The magnitude of effect of the second hydroxyl group on potency is not only dictated by the absolute stereochemistry of the diol but also by the side chain of the P1 residue. Molecular modeling of the diol-containing inhibitors suggests that one of the hydroxyl groups hydrogen bonds to Asp 32 and Asp 215, while the second hydrogen bonds to Asp 215. These diol inhibitors are extremely selective for human renin over the related enzymes cathepsin D, pepsin, and gastricsin. At high concentrations, compounds containing a leucine or phenylalanine rather than a histidine at the P2 position gave only minor amounts of inhibition of the other enzymes. Inhibitor 43 suppressed plasma renin activity completely and lowered mean blood pressure in monkeys after both intravenous and intraduodenal administration, but the blood pressure drop lasted less than 1 h. Monitoring the blood levels of 43 by enzyme inhibition assay after intraduodenal administration to monkeys or oral administration to rats revealed low absorption and rapid clearance. While intratracheal administration to dogs gave approximately 50% bioavailability, rapid clearance was still a problem. After examination of inhibitor 45 in a sensitive primate model in which monkeys were rendered both hypertensive and hyperreninemic, the effects on lowering systolic but not diastolic pressure were apparent even after 22 h postdosing. Details on the synthesis, in vitro structure-activity relationships, molecular modeling, in vivo activity, and metabolism of these inhibitors are described.

Renin inhibitors. Dipeptide analogues of angiotensinogen utilizing a structurally modified phenylalanine residue to impart proteolytic stability.

A series of renin inhibitors have been prepared and evaluated for their susceptibility to cleavage by the serine protease chymotrypsin. The compounds were designed by consideration of the structural requirements in the active-site region of renin and chymotrypsin. By systematic alteration of the P3 phenylalanine residue, compounds with varying degrees of renin inhibitory potency and chymotrypsin susceptibility were obtained. Selected analogues from this group were examined in vivo for both their hypotensive effects and metabolic patterns.

Human placental chorionic renin: production, purification and characterization.

Native human renin, produced from the culture of human chorionic trophoblasts, has been purified to homogeneity on a milligram scale using a five-step purification scheme. The chorion cells secrete 50-200 milliGoldblatt Units of trypsin-activatable prorenin per ml into the medium. The pro-enzyme is partially purified by ammonium sulfate fractionation and chromatographies on QAE-Sephadex and cibracon blue-agarose. Following conversion of prorenin to the active enzyme by porcine trypsin, the renin is purified to homogeneity by affinity chromatography and gel filtration. Chorionic prorenin has a molecular weight of 43,000; the active enzyme 40,000. Both proteins exist as a single polypeptide chain as determined by SDS-polyacrylamide gel electrophoresis under reducing conditions. The average specific activity of six different preparations was found to be 1072 Goldblatt Units/mg. The amino acid composition and N-terminal sequence of the active enzyme has been determined and is identical to the human kidney enzyme. Microheterogeneity of chorionic renin was demonstrated by isoelectrofocusing analysis. The physical characterization of chorionic renin is compared with that reported for the human kidney enzyme.

Renin inhibitors. Improvements in the stability and biological activity of small peptides containing novel Leu-Val replacements.

We have designed a novel class of potent (0.3-7 nM) renin inhibitors which contain a dihydroxyethylene replacement for what is formally the Leu10-Val11 amide bond. Good potency (0.6 nM), water solubility (greater than 10 mg/ml at 37 degrees C), stability toward degradation by chymotrypsin (t1/2 = 820 min), and in vivo activity in a primate model (15% drop in mean arterial pressure in association with complete inhibition of plasma renin activity) are properties which have been incorporated into compound 10, an interesting new agent to be used in the study of hypertension.

Renin inhibitors. Design and synthesis of a new class of conformationally restricted analogues of angiotensinogen.

Molecular modeling methods have been used to design a novel series of conformationally constrained cyclic peptide inhibitors of human renin. Three goals were defined: enhanced inhibitory potency, high specificity for renin, and increased metabolic stability. Three cyclic compounds were synthesized with ring sizes 10, 12, and 14, based upon a linear hexapeptide inhibitor with a reduced amide replacing the scissile bond at the active site. When tested, the 14-membered-ring compound was as potent an inhibitor of human renin as the parent while the 12-membered-ring compound was 6-fold more potent than the parent against mouse renin. However, the 10-membered-ring compound was inactive against both renins. The lack of potency of the 10-membered compound was explained by using NMR and molecular modeling techniques. It forms another conformation in solution that is inconsistent with binding at the active site. The cyclic compounds did not inhibit either pepsin or cathepsin D significantly. The cyclic modification rendered these inhibitors significantly resistant to cleavage by chymotrypsin and thus prevented loss of activity by this enzyme. Thus, the goals of enhanced inhibitory potency, high specificity, and metabolic stability were achieved in the series of compounds.

Renin inhibitors. Dipeptide analogues of angiotensinogen incorporating transition-state, nonpeptidic replacements at the scissile bond.

A series of dipeptide analogues of angiotensinogen have been prepared and evaluated for their ability to inhibit the aspartic proteinase renin. The compounds were derived from the renin substrate by replacing the scissile amide bond with a transition-state mimic and by incorporating bioisosteric replacements for the Val-10 amide bond. Analogue 21a exhibited an IC50 of 7.6 nM against purified human renin, showed high specificity for this enzyme, and produced a hypotensive response in anesthetized, salt-depleted cynomolgus monkeys.

Novel renin inhibitors containing analogues of statine retro-inverted at the C-termini: specificity at the P2 histidine site.

Substituted 1,3- and 1,4-diamines were prepared from epoxides derived from Boc-leucine or Boc-cyclohexylalanine. These diamines were incorporated into renin inhibitors (IC50 = 4-1500 nM) replacing the Leu-Val scissile bond in small peptide analogues of angiotensinogen. Replacement of the P2 histidine imidazole with other heterocycles maintained or enhanced binding while changing the overall basicity of the inhibitor. Finally, substitution of O-methyltyrosine for the P3 phenylalanine suppressed chymotrypsin cleavage of the P3-P2 bond.

Modified peptides which display potent and specific inhibition of human renin.

A new class of angiotensinogen analogues which contain heteroatom-methylene and retro-inverso amide bond replacements was synthesized and evaluated for renin inhibition. Selected compounds in the series were specific for renin over other aspartic proteinases, and the most potent inhibitor demonstrated hypotensive activity in a salt depleted monkey.