The rate of formation of the three initial metabolites of cyclosporine metabolism has been determined in liver microsomes of 15 kidney transplant donors. Interindividual variation in metabolite formation was considerable but all three metabolites varied in parallel. An antiserum raised against a steroid-inducible rat cytochrome P-450 (P-450 PCN) strongly inhibited the formation of these metabolites. Immunoquantitation of the protein recognized by a monoclonal antibody reacting with human cytochromes P-450 of the P-450III gene family, homologues of rat P-450 PCN and rabbit P-4503C, revealed a high degree of correlation with microsomal cyclosporine metabolism. The data suggest that this cytochrome P-450 is the major cyclosporine-metabolizing enzyme in human liver. The substrate specificity and the known inducers and inhibitors of this cytochrome P-450 explain several clinically observed drug interactions with cyclosporine.
Using the stereospecific metabolism of (+)- and (-)-bufuralol and (+)- and (-)-metoprolol as model reactions, we have characterized the enzymic deficiency of the debrisoquine/sparteine-type polymorphism by comparing kinetic data of subjects in vivo with their microsomal activities in vitro and with reconstituted activities of cytochrome P-450 isozymes purified from human liver. The metabolism of bufuralol in liver microsomes of in vivo phenotyped 'poor metabolizers' of debrisoquine and/or sparteine is characterized by a marked increase in Km, a decrease in Vmax and a virtual loss of the stereoselectivity of the reaction. These parameters apparently allow the 'phenotyping' of microsomes in vitro. A structural model of the active site of a cytochrome P-450 for stereospecific metabolism of bufuralol and other polymorphically metabolized substrates was constructed. Two cytochrome P-450 isozymes, P-450 buf I and P-450 buf II, both with MW 50,000 Da, were purified from human liver on the basis of their ability to metabolize bufuralol to 1'-hydroxy-bufuralol. However, P-450 buf I metabolized bufuralol in a highly stereoselective fashion ((-)/(+) ratio 0.16) as compared to P-450 buf II (ratio 0.99) and had a markedly lower Km for bufuralol. Moreover, bufuralol 1'-hydroxylation by P-450 buf I was uniquely characterized by its extreme sensitivity to inhibition by quinidine. Antibodies against P-450 buf I and P-450 buf II inhibited bufuralol metabolism in microsomes and with the reconstituted enzymes. Immunochemical studies with these antibodies with microsomes and translations in vitro of RNA from livers of extensive and poor metabolizers showed no evidence for a decrease in the recognized protein or its mRNA. Because the antibodies do not discriminate between P-450 buf I and P-450 buf II, both a decreased content of P-450 buf I or its functional alteration could explain the polymorphic metabolism in microsomes. The genetically defective stereospecific metabolism of mephenytoin was determined in liver microsomes of extensive and poor metabolizers of mephenytoin phenotyped in vivo. Microsomes of poor metabolizers were characterized by an increased Km and a decreased Vmax for S-mephenytoin hydroxylation as compared to extensive metabolizers and a loss of stereospecificity for the hydroxylation of S-versus R-mephenytoin. A cytochrome P-450 with high activity for mephenytoin 4-hydroxylation was purified from human liver. Immunochemical studies with inhibitory antibodies against this isozyme suggest the presence in poor-metabolizer microsomes of a functionally altered enzyme.
- [1-(4-fluorobenzyl)-5-hydroxy-indole-3-yl]-glyoxylic acid amide (AWD 12-281) is a highly potent and selective phosphodiesterase 4 (PDE4) inhibitor that was designed to have a metabolic profile that was optimized for topical administration. The aim of the current study was to explore the pharmacological profile of intratracheally administered AWD 12-281 in different models of asthma and chronic obstructive pulmonary disease (COPD) in comparison with steroids. To assess the anti-inflammatory potential of AWD 12-281, the antigen-induced cell infiltration in bronchoalveolar lavage fluid (BALF) of Brown Norway rats was determined. AWD 12-281 (ID 50 of 7 g/kg i.t.) as well as beclomethasone (0.1 g/kg i.t.) suppresses late-phase eosinophilia when administered intrapulmonary. Furthermore, AWD 12-281 has also strong anti-inflammatory properties when tested in lipopolysaccharide-induced acute lung neutrophilia in Lewis rats (ID 50 of 0.02 g/kg i.t.), ferrets (ID 50 of 10 g/kg i.t.), and domestic pigs (2-4 mg/pig i.t. or 1 mg/kg i.v.). In pigs, AWD 12-281 was as effective as beclomethasone (0.4 mg/pig i.t.) and dexamethasone (0.28 mg/kg i.v.), although at 3 to 10 times the dosage. The bronchodilatory activity of AWD 12-281 was assessed in sensitized guinea pigs. AWD 12-281 (1.5 mg/kg i.t., 1-h pretreatment) inhibited allergen-induced bronchoconstriction by 68% (parameter airway resistance). In sensitized BP-2 mice AWD 12-281 abolished the allergen-induced bronchial hyperresponsiveness and eosinophilia in BALF, showing dose dependence. When given orally, i.v. or i.t., AWD 12-281 has a considerably lower emetic potential than cilomilast in ferrets and roflumilast in pigs. When given topically by inhalation, no emesis could be induced in dogs up to the highest feasible dose (15 mg/kg in 50% lactose blend). These results indicate that AWD 12-281 is a unique potential new drug for the topical treatment of asthma and COPD.
The identification of highly potent and orally active phenylpyrazines for the inhibition of PDE10A is reported. The new analogues exhibit subnanomolar potency for PDE10A, demonstrate high selectivity against all other members of the PDE family, and show desired druglike properties. Employing structure-based drug design approaches, we methodically explored two key regions of the binding pocket of the PDE10A enzyme to alter the planarity of the parent compound 1 and optimize its affinity for PDE10A. Bulky substituents at the C9 position led to elimination of the mutagenicity of 1, while a crucial hydrogen bond interaction with Glu716 markedly enhanced its potency and selectivity. A systematic assessment of the ADME and PK properties of the new analogues led to druglike development candidates. One of the more potent compounds, 96, displayed an IC(50) for PDE10A of 0.7 nM and was active in predictive antipsychotic animal models.
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