Optimization of TAM16, a Benzofuran That Inhibits the Thioesterase Activity of Pks13; Evaluation toward a Preclinical Candidate for a Novel Antituberculosis Clinical Target

With increasing drug resistance in tuberculosis (TB) patient populations, there is an urgent need for new drugs. Ideally, new agents should work through novel targets so that they are unencumbered by preexisting clinical resistance to current treatments. Benzofuran 1 was identified as a potential lead for TB inhibiting a novel target, the thioesterase domain of Pks13. Although, having promising activity against Mycobacterium tuberculosis, its main liability was inhibition of the hERG cardiac ion channel. This article describes the optimization of the series toward a preclinical candidate. Despite improvements in the hERG liability in vitro, when new compounds were assessed in ex vivo cardiotoxicity models, they still induced cardiac irregularities. Further series development was stopped because of concerns around an insufficient safety window. However, the demonstration of in vivo activity for multiple series members further validates Pks13 as an attractive novel target for antitubercular drugs and supports development of alternative chemotypes.

Nafamostat is hydrolysed by human liver cytosolic long-chain acyl-CoA hydrolase

Although the authors recently reported that nafamostat, a clinically used serine protease inhibitor, was mainly hydrolysed by carboxylesterase in human liver microsomes, the involvement of human liver cytosol has not been elucidated. The current study examined the in vitro metabolism of nafamostat with human liver cytosols. Kinetic analysis indicated that the Vmax and Km values in the liver cytosols were 9.82 nmolmin(-1) mg(-1) protein and 197 microM for a liver sample HL-1, and 15.1 nmolmin(-1) mg(-1) protein and 157 microM for HL-2, respectively. The Vmax/Km values in both cytosols were at least threefold higher than those in the corresponding microsomes. The liver cytosolic activity for nafamostat hydrolysis was inhibited by phenylmethylsulfonyl fluoride (PMSF) (43% inhibition at 100 microM), whereas diisopropyl fluorophosphate (DFP) and bis(p-nitrophenyl)phosphate (BNPP) failed to inhibit the activity. Furthermore, the hydrolytic activity was also reduced by palmitoyl-CoA (67% inhibition at 100 microM) but not by acetyl-CoA. Effects of PMSF, DFP and BNPP on cytosolic palmitoyl-CoA hydrolytic activity were comparable with those of the cytosolic nafamostat hydrolytic activity. In addition, the palmitoyl-CoA hydrolytic activity was competitively inhibited by nafamostat with the apparent Ki value of 164 microM for the liver cytosol from HL-2. These results suggest that an isoform of long-chain acyl-CoA hydrolase may be responsible for the nafamostat hydrolysis in human liver cytosol.

Practical, catalytic, asymmetric synthesis of beta-lactones via a sequential ketene dimerization/hydrogenation process: inhibitors of the thioesterase domain of fatty acid synthase

The recent finding that the FDA-approved antiobesity agent orlistat (tetrahydrolipstatin, Xenical) is a potent inhibitor of the thioesterase domain of fatty acid synthase (FAS) led us to develop a concise and practical asymmetric route to pseudosymmetric 3,4-dialkyl-cis-beta-lactones. The well-documented up-regulation of FAS in cancer cells makes this enzyme complex an interesting therapeutic target for cancer. The described route to 3,4-dialkyl-beta-lactones is based on a two-step process involving Calter's catalytic, asymmetric ketene dimerization of acid chlorides followed by a facial-selective hydrogenation leading to cis-substituted-beta-lactones. Importantly, the ketene dimer intermediates were found to be stable to flash chromatography, enabling opportunities for subsequent transformations of these optically active, reactive intermediates. Subsequent alpha-epimerization and alpha-alkylation or acylation led to trans-beta-lactones and beta-lactones bearing alpha-quaternary carbons, respectively. Several of the ketene dimers and beta-lactones displayed antagonistic activity (apparent Ki in the low micromolar range) in competition with a fluorogenic substrate toward a recombinant form of the thioesterase domain of fatty acid synthase. The best antagonist, a simple phenyl-substituted cis-beta-lactone 3d, displayed an apparent Ki (2.5 +/- 0.5 microM) of only approximately 10-fold lower than that of orlistat (0.28 +/- 0.06 microM). In addition, mechanistic studies of the ketene dimerization process by ReactionView infrared spectroscopy support previous findings that ketene formation is rate determining.

Arachidonic acid regulation of steroid synthesis: new partners in the signaling pathway of steroidogenic hormones

Although the role of arachidonic acid (AA) in trophic hormone-stimulated steroid production in various steroidogenic cells is well documented, the mechanism responsible for AA release remains unknown. We have previously shown evidence of an alternative pathway of AA generation in steroidogenic tissues. Our results are consistent with the hypothesis that, in steroidogenic cells, AA is released by the action of a mitochondrial acyl-CoA thioesterase (MTE-I). We have shown that recombinant MTE-I hydrolyses arachidonoyl-CoA to release free AA. An acyl-CoA synthetase specific for AA, acyl-CoA synthetase 4, has also been described in steroidogenic tissues. In the present study we investigate the new concept in the regulation of intracellular levels of AA, in which trophic hormones can release AA by mechanisms different from the classical PLA2-mediated pathway. Inhibition of ACS4 and MTE-I activity by triacsin C and NDGA, respectively results in a reduction of StAR mRNA and protein abundance. When both inhibitors are added together there is a synergistic effect in the inhibition of StAR mRNA, StAR protein levels and ACTH-stimulated steroid synthesis. The inhibition of steroidogenesis produced by the NDGA and triacsin C can be overcome by the addition of exogenous AA. In summary, results shown here demonstrate a critical role of the acyl-CoA synthetase and the acyl-CoA thioesterase in the regulation of AA release, StAR induction, and steroidogenesis. This further suggests a new concept in the regulation of intracellular distribution of AA through a mechanism different from the classical PLA2-mediated pathway that involves a hormone-induced acyl-CoA synthetase and a hormone-regulated acyl-CoA thioesterase.

Characterization of fatty acid synthase monomers restrained from reassociating by immobilization to a solid support

The controversial question as to whether the ketoreductase activity of the animal fatty acid synthase is lost on dissociation of the homodimer has been addressed by using immobilized subunits which cannot reassociate under the conditions of assay. Ketoreductase activity, assessed with the model substrate S-acetoacetyl-N-acetylcysteamine, was identical in immobilized monomers and dimers, exhibiting normal Michaelis-Menten kinetics with Km values in the millimolar range. When acetoacetyl-CoA was used as a substrate, however, biphasic kinetics were observed in the case of the dimer, with estimated Km values in the micro- and milli-molar ranges, but only the high-Km reaction was observed with the monomer. Thus when the ketoreductase activities of the monomer and dimer are assessed with acetoacetyl-CoA at concentrations sufficient to saturate only the low-Km reaction, it appears that the ketoreductase activity towards acetoacetyl-CoA is lost upon dissociation. Reduction of acetoacetyl-CoA via the low-Km pathway is CoA-dependent, indicating that acetoacetyl-CoA can react with the dimer by two mechanisms: a high-Km pathway analogous to that utilized by model substrates and a low-Km pathway in which substrate and product are transferred between acyl-CoA and acyl-enzyme forms. The results indicate that the ketoreductase activity per se is unaffected by subunit dissociation and are consistent with a model in which the transfer of substrate from CoA ester to the acyl-carrier-protein domain necessitates juxtaposition of the transferase active-site serine residue of one subunit and the phosphopantetheine moiety of the adjacent subunit.

Differential inhibition of long-chain acyl-CoA hydrolases by hypolipidemic drugs in vitro

The effect of in vitro addition of three hypolipidemic drugs (clofibric acid, bezafibrate and gemfibrozil) on rat palmitoyl-CoA hydrolases has been studied, by using a spectrophotometric method (Berge RK, Biochim Biophys Acta 574: 321-333, 1979) optimized for valoration of crude enzyme preparations. Mitochondrial and microsomal hepatic palmitoyl-CoA hydrolase activities were inhibited by the three drugs in a concentration-dependent fashion. The order of inhibitory potency was gemfibrozil greater than bezafibrate greater than clofibric acid, irrespective of the enzyme activity tested. Cytosolic rat brain palmitoyl-CoA hydrolase activity was not affected. Kinetic studies with gemfibrozil on the solubilized microsomal palmitoyl-CoA hydrolase activity point to a mixed non-competitive type of inhibition.

The functional size of acyl-coenzyme A (CoA):cholesterol acyltransferase and acyl-CoA hydrolase as determined by radiation inactivation

Frozen rat liver microsomes and rough endoplasmic reticulum were irradiated with high energy electrons. The surviving enzymatic activity of acyl-CoA:cholesterol acyltransferase and activity for esterification of 25-hydroxycholesterol decreased as a simple exponential function of radiation exposure, leading to a target size of 170-180 kDa. The loss of acyl-CoA hydrolase activity with a radiation dose was complex and resolved as a 45-kDa enzyme associated with a large inhibitor. It is interpreted that acyl-CoA hydrolase is the acyl-CoA-binding component and the inhibitor is the cholesterol-binding component of acyl-CoA:cholesterol acyltransferase.

Inhibition of palmitoyl co-enzyme A hydrolase in mitochondria and microsomes by pharmaceutical organic anions

Rat microsomes and mitochondria were isolated and incubated with selected pharmaceutical organic anions at concentrations of 0, 0.2, 0.5, 1.0, and 2 mM. Activity of palmitoyl CoA hydrolase (PCAH) was shown to be reduced in a dose-dependent manner in microsomes by ibuprofen, valproate, acetyl salicylate, 2,4-dichlorophenoxyacetate (2,4-D), and 4-pentenoate, but not salicylate. Mitochondrial PCAH activity was inhibited by clofibrate, ibuprofen, valproate, and 2,4-D. Mitochondrial oxidative phosphorylation was impaired or uncoupled by each of the mitochondrial PCAH inhibitors. The inhibition of PCAH by some of these agents may lead to fatty acyl CoA accumulation. Very low concentrations of fatty acyl CoA are known to cause mitochondrial uncoupling and increase permeability. This action may play a role in the mitochondrial injury caused by some of these agents or related disease processes.

Identity of purified monoacylglycerol lipase, palmitoyl-CoA hydrolase and aspirin-metabolizing carboxylesterase from rat liver microsomal fractions. A comparative study with enzymes purified in different laboratories

Two purified carboxylesterases that were isolated from a rat liver microsomal fraction in a Norwegian and a German laboratory were compared. The Norwegian enzyme preparation was classified as palmitoyl-CoA hydrolase (EC 3.1.2.2) in many earlier papers, whereas the German preparation was termed monoacylglycerol lipase (EC 3.1.1.23) or esterase pI 6.2/6.4 (non-specific carboxylesterase, EC 3.1.1.1). Antisera against the two purified enzyme preparations were cross-reactive. The two proteins co-migrate in sodium dodecyl sulphate/polyacrylamide-gel electrophoresis. Both enzymes exhibit identical inhibition characteristics with Mg2+, Ca2+ and bis-(4-nitrophenyl) phosphate if assayed with the two substrates palmitoyl-CoA and phenyl butyrate. It is concluded that the two esterase preparations are identical. However, immunoprecipitation and inhibition experiments confirm that this microsomal lipase differs from the palmitoyl-CoA hydrolases of rat liver cytosol and mitochondria.

Isolation and characterization of an acyl-CoA thioesterase from dark-grown Euglena gracilis

An acyl-CoA hydrolase from dark-grown Euglena gracilis Z was purified 700-fold by subjecting the 105,000g supernatant of the cell-free extract to (NH4)2SO4 precipitation, acid precipitation, calcium phosphate gel treatment, gel filtration on Sephadex G-100, and chromatography on QAE-Sephadex, hydroxylapatite, and CM-Sephadex. Polyacrylamide disc gel electrophoresis of the purified enzyme showed a major protein band (greater than 80%) which contained thioesterase activity and a minor protein band with no thioesterase activity. Molecular weight estimated by gel filtration was 37,000 and sodium dodecyl sulfate-electrophoresis showed one major band (greater than 80%) corresponding to a molecular weight of 37,000 and a minor band of molecular weight 32,000, suggesting that the enzyme was monomeric. The pH optimum of the purified enzyme progressively increased with the chain length of the substrate, with hexanoyl-CoA showing a pH optimum at 4.5 and stearoyl-CoA at 7.0. The rate of hydrolysis of acyl-CoA showed a nonlinear dependence on protein concentration, and bovine serum albumin overcame this effect as well as stimulated the rate. The extent of stimulation by albumin increased with chain length of the substrate up to lauroyl-CoA and then decreased as chain length increased; albumin inhibited the hydrolysis of stearoyl-CoA. This enzyme hydrolyzed CoA esters of C6 to C18 fatty acids with a maximal rate of 17 mumol min-1 mg protein-1 for C14. Typical substrate saturation patterns were obtained with all substrates except that high concentrations were inhibitory. Studies on the effect of pH on the apparent Km and Vmax values for octanoyl-CoA, lauroyl-CoA, and palmitoyl-CoA showed that in all cases Vmax was greatest and Km was lowest at the respective pH optima. Active-serine-directed reagents severely inhibited the thioesterase activity, suggesting the participation of an active serine residue in catalysis; thiol-directed reagents were not effective inhibitors. Diethylpyrocarbonate also inhibited the enzyme and hydroxylamine reversed this inhibition, suggesting the involvement of a histidine residue in catalysis as expected for enzymes containing active serine. This thioesterase did not affect the chain length distribution of the products generated by the Euglena fatty acid synthase I.

Long-chain acyl-CoA and acylcarnitine hydrolase activities in normal and ischemic rabbit heart

Long-chain acyl-CoA and acylcarnitine hydrolase activities were determined in fresh and perfused rabbit heart and correlated with tissue levels of their respective substrates, long-chain acyl-CoA and acylcarnitine. In fresh heart homogenate acyl-CoA hydrolase activity was 3-fold greater than acylcarnitine hydrolase activity; sonication of homogenate doubled acyl-CoA hydrolase activity but did not significantly change acylcarnitine hydrolase activity. Hearts perfused with 10 mM glucose by the nonrecirculating Langendorff method had depressed levels of acyl-CoA hydrolase activity under both aerobic and ischemic conditions. Extract from buffer-perfused heart showed increased acylcarnitine hydrolase activity and elevated levels of acylcarnitine. Homogenate acyl-CoA hydrolase activity was not sedimented by centrifugal forces up to 50,000 X g; however, less than 25% of homogenate acylcarnitine hydrolase activity remained in the 50,000 X g supernatant. The hypolipidemic drug clofibrate was an effective in vitro inhibitor of acylcarnitine hydrolase activity but not of acyl-CoA hydrolase activity. The fatty acid analog tetradecylglycidic acid inhibited only acyl-CoA hydrolase activity. These results suggest that acyl-CoA hydrolase and acylcarnitine hydrolase activities are differentially affected in the perfused heart by substrate levels and oxygen availability. In addition, the diverse response of these two hydrolase activities to a variety of biochemical parameters implies that the observed hydrolyses of palmitoyl-CoA and palmitoylcarnitine are catalyzed by at least two separate hydrolase enzymes.

Metabolism of oleoyl-CoA in rat brain synaptosomes: effects of calcium and post-decapitative ischemia

The hydrolysis of acyl-CoA by acyl-CoA hydrolase (EC 3.1.2.2.) in brain synaptosomes was inhibited by calcium. This inhibition was partly due to interaction of Ca2+ with the acyl-CoA, which was present in the soluble form, and partly due to complex formation among acyl-CoA, Ca2+ and membrane phospholipids. The inhibition of acyl-CoA hydrolase activity, as well as the complex formation, could be reversed if incubation was carried out in the presence of Ca2+ chelating agents. Synaptosomes isolated from brain samples after 1 min of postdecapitative treatment showed a decrease in oleoyl-CoA hydrolase activity. The physiological implication of acyl-CoA metabolism in relation to synaptic function is discussed.

Factors affecting the activity and stability of the palmitoyl-coenzyme A hydrolase of rat brain

Palmitoyl-CoA hydrolase (EC 3.1.2.2) catalyses the irreversible hydrolysis of long-chain acyl-CoA thioesters. This enzyme is found primarily in the postmicrosomal supernatant fraction prepared from homogenates of rat brain. Either of two forms of the hydrolase, a lower-molecular-weight species of approx. 70000 or a higher-molecular-weight species of approx. 130000 can be isolated by gel filtration. The higher-molecular-weight form is obtained from columns of Sephadex G-200 eluted with buffer containing 10mum-palmitoyl-CoA or 20% (v/v) glycerol, whereas the lower-molecular-weight form is obtained when the eluting buffer does not contain palmitoyl-CoA or glycerol. The two forms of the hydrolase have the same pH optimum of 7.5, are equally sensitive to the thiol-blocking reagents p-hydroxymercuribenzoate, HgCl(2), and 5,5'-dithiobis-(2-nitrobenzoic acid), and exhibit the same K(m) (1.8mum) with palmitoyl-CoA as substrate. The two forms differ in the availability or reactivity of certain external thiol groups, as determined by covalent chromatography with activated thiol Sepharose. Dilute solutions of the lower-molecular-weight form of the hydrolase rapidly lose activity (50% in 60min at 0 degrees C), but there is no change in the K(m) with palmitoyl-CoA as substrate during this progressive inactivation. Dilutions of the hydrolase in buffer containing 10mum-palmitoyl-CoA retain full activity. However, addition of palmitoyl-CoA to solutions of the lower-molecular-weight form will not restore previously lost hydrolase activity. The evidence supports the conclusion that the substrate palmitoyl-CoA promotes the formation of a relatively stable dimer from two unstable subunits. This process may not be reversible, since the removal of palmitoyl-CoA or glycerol from solutions of the higher-molecular-weight form does not result in the appearance of the lower-molecular-weight form of the hydrolase.