Carbonyl reduction of an anti-insect agent imidazole analogue of metyrapone in soil bacteria, invertebrate and vertebrate species.

Carbonyl reduction to the respective alcohol metabolites of the anti-insect agent imidazole analogue of metyrapone, NKI 42255 (2-(1-imidazolyl)-1-(4-methoxyphenyl)-2-methyl-1-propanone) and its parent compound metyrapone was characterized in subcellular fractions previously described bacterial and mammalian hydroxysteroid dehydrogenases/carbonyl from soil bacteria, as well as insect, invertebrate and teleost species. The enzymes involved in this metabolic step were characterized with respect to their cosubstrate specificities, inhibitor susceptibilities, and immunological crossreactivities with antibodies directed against reductases (HSD/CR). All fractions investigated rapidly reduced metyrapone, with highest specific activities found in insect, invertebrate and vertebrate fractions. Except for the insect fractions, all species examined reduced the NKI compound. Cosubstrate dependence and inhibitor specificities suggest that the enzymes described belong to the protein superfamilies of short-chain dehydrogenases/reductases (SDR) or aldo-keto reductases (AKR). Immunological crossreactions to the previously established subgroup of HSD/CRs were found in trout liver microsomes and insect homogenates, but not in all bacterial extracts or earthworm microsomes. These findings suggest that the high CR activities found in these fractions belong to different subgroups of SDR or AKR.

Biotransformation and detoxification of insecticidal metyrapone analogues by carbonyl reduction in the human liver.

1. The carbonyl reduction of insecticidal metyrapone analogues to their hydroxyl metabolites by human liver microsomes and cytosol was examined. Metabolite quantification was performed by means of hplc determination and inhibition experiments, using specific carbonyl reductase inhibitors, were conducted. 2. The cytotoxicity of the ketones and their hydroxy metabolites was assessed with the MTT test, using Chang liver cells. 3. It was found that the alcohol derivatives are the major metabolite, both in microsomes and cytosol. The microsomal reductive metabolism, considered to be mediated by 11 beta-hydroxysteroid dehydrogenase (11 beta-HSD) (EC 1.1.1.146), was more extensive than the cytosolic carbonyl reduction. In each case, this metabolism was inhibited significantly by equimolar concentrations of the microsomal 11 beta-HSD inhibitor glycyrrhetinic acid and the cytosolic carbonyl reductase inhibitor quercitrin, respectively. 4. The parent ketones were more cytotoxic than their alcohol metabolites. 5. These results demonstrate that the metyrapone analogues are extensively metabolized by human liver microsomes, presumably by 11 beta-HSD, to the less cytotoxic and readily excretable alcohols. 6. Since the metyrapone analogues can inhibit ecdysone 20-monooxygenase (EC 1.14.99.22), our results indicate potential application of these compounds as insecticides, which would be safer for humans, due to their reductive detoxification, mainly by the hepatic microsomal 11 beta-HSD, to the less toxic hydroxy metabolites.

Agonist-releasable intracellular calcium stores and the phenomenon of store-dependent calcium entry. A novel hypothesis based on calcium stores in organelles of the endo- and exocytotic apparatus.

Store-dependent calcium entry represents a little characterized calcium permeation pathway that is present in a variety of cell types. It is activated in an unknown way by depletion of intracellular calcium stores, for example in the course of phospholipase C stimulation. Current hypotheses propose that depleted calcium stores signal their filling state to this permeation pathway either by direct, protein-mediated interaction or by release of a small, diffusible messenger. The further characterization of store-dependent calcium entry will benefit from progress in the identification of the intracellular calcium storing compartments. Recent findings reviewed here suggest that these compartments include parts of the organelle system that is involved in endo- and exocytosis. This commentary describes a novel model of store-dependent calcium entry based on calcium stores belonging to the endo- and exocytotic organelle system. Such calcium stores could establish a tubule-like connection with the extracellular space, in analogy to the cellular compartments that contain the insulin-sensitive glucose transporter or the gastric proton pump. This connection will provide a pathway for store-dependent calcium entry. Under store depletion, extracellular calcium will permeate through the tubule-like connection into the store lumen and from there into the cytosol. The consequences of this model for the development of drugs modulating store-dependent calcium entry are discussed.

Effects of propionic acid and pravastatin on HMG-CoA reductase activity in relation to forestomach lesions in the rat.

Administration of 4% propionic acid in powdered diet to rats for 12 weeks induces severe hyperplastic lesions in the forestomach mucosa. The mechanisms underlying this damage are not yet clear. Several lipophilic 3-hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase inhibitors such as lovastatin and simvastatin produce forestomach lesions similar to propionic acid after oral administration and the degree of alterations is correlated with their in vitro inhibitory potency (Kloss et al. 1991). Therefore it is possible, that sustained inhibition of HMG-CoA reductase and induction of hyperplasias may be somehow connected. For that reason we investigated, whether or not propionic acid has any influence on HMG-CoA reductase activity in vitro and in vivo, because propionic acid has been suggested to suppress liver cholesterol synthesis, and also whether or not pravastatin, a more polar HMG-CoA reductase inhibitor than lovastatin displays similar effects on forestomach mucosa. In untreated forestomach microsomes in vitro, propionic acid at a concentration of 51 mM (pH 5.7) inhibited HMG-CoA reductase activity by 51 + or - 10%, but at pH 7.2 no inhibition of the enzyme could be detected. Furthermore 4% propionic acid-treatment did not lower serum cholesterol. In contrast to lovastatin (Kloss et al. 1991), oral administration of pravastatin (up to 25% in the diet) did not produce any forestomach lesions in the rat. On the other hand, pretreatment with pravastatin revealed that HMG-CoA reductase activity in microsomes exceeded the activity of control forestomach and liver microsomes by 4.9 fold and 6.7 fold respectively, whereas no induction of this enzyme (neither liver nor forestomach) could be observed by pretreatment with 4% propionic acid for 12 weeks. Despite increased hepatic HMG-CoA reductase activity, pravastatin-treatment significantly lowered serum cholesterol levels of rats. These results show that sustained inhibition of HMG-CoA reductase activity in forestomach microsomes is not strongly connected with hyperplasia development.

Induction of daunorubicin carbonyl reducing enzymes by daunorubicin in sensitive and resistant pancreas carcinoma cells.

Daunorubicin (DRC) and other anthracyclines are valuable cytotoxic agents in the clinical treatment of certain malignancies. However, as is the case with virtually all anticancer drugs, tumor cell resistance to these agents is one of the major obstacles to successful chemotherapy. In addition to an increased energy-dependent efflux of chemotherapeutic agents, enzymatic drug-inactivating mechanisms also contribute to multidrug resistance of tumor cells. In the case of DRC, carbonyl reduction leads to 13-hydroxydaunorubicinol (DRCOL), the major metabolite of DRC with a significantly lower antineoplastic potency compared to the parent drug. In the present study, we compared two pancreas carcinoma cell lines (a DRC-sensitive parental line and its DRC-resistant subline) with respect to their capacity of DRC inactivation via carbonyl reduction. In addition, we cultured the two cell lines in the presence of increasing sublethal concentrations of DRC. Evidence is presented that DRC treatment itself leads to a concentration-dependent induction of DRC carbonyl reduction in subcellular fractions of both the sensitive and resistant pancreas carcinoma cells, resulting, surprisingly, in different susceptibilities to DRC. The principal difference between the two cell lines becomes most apparent at high-dose DRC supplementation (1 microgram/mL), at which DRC resistant cells exhibited higher inducibility of DRC-inactivating enzymes, whereas respective sensitive cells already showed an impairment of cellular viability. The use of the diagnostic model substrates metyrapone and p-nitrobenzaldehyde reveals that this adaptive enhancement of DRC inactivation can be attributed to the induction of DRC carbonyl reductases different from known aldehyde and carbonyl reductases. In conclusion, these findings suggest that inactivation of anthracyclines by carbonyl reduction is inducible by the substrate itself, a fact that might be considered as one of the enzymatic mechanisms that contribute to the acquired resistance to these drugs.

Comparison of 11 beta-hydroxysteroid dehydrogenase in spontaneously hypertensive and Wistar-Kyoto rats.

11 beta-Hydroxysteroid dehydrogenase (11 beta-HSD) modulates glucocorticoid interactions with mineralocorticoid and glucocorticoid receptors in vivo, by converting 11 beta-hydroxyglucocorticoids to their inactive 11-ketone derivatives. Defective 11 beta-oxidation of glucocorticoids has been associated with hypertension. The objective of this study was to investigate whether 11 beta-HSD contributes to the occurrence of hypertension in spontaneously hypertensive rats (SHRs). The liver and kidney microsomal oxidations of corticosterone (the physiological glucocorticoid in rats) in organs from juvenile (3 weeks old) and adult (3 months old) SHR and Wistar-Kyoto (WKY) rats, with NAD and NADP, show no differences between rat strains. For cortisol, with NADP, adult SHRs show (1.3-3 times; P < 0.05) lower kidney microsomal oxidation rates. The liver microsomal reduction of cortisone shows remarkable interstrain differences; with NADH, reduction is conducted only by adult WKY rats, whereas with NADPH, juvenile animals show similar reduction rates, but at adulthood, only WKYs reduce cortisone. Using Western blot analysis with antibodies against 11 beta-HSD1, positive signals are obtained only for liver microsomes, appearing somewhat lower in SHRs for juvenile but not adult animals. Urinary corticosterone/11-dehydrocorticosterone ratios (measured in adult animals) are not different between rat strains, but are elevated after administration of corticosterone in both strains (although significant only in SHRs). The data provide no indications for exaggerated stimulation of renal corticosteroid receptors, due to modified 11 beta-HSD, in SHRs. However, the experiments suggest the existence of multiple 11 beta-HSDs, in addition to 11 beta-HSD1 and 11 beta-HSD2, some of which may be modified in SHR, but the nature and physiological role of these 11 beta-HSDs is unclear.

Cloning and primary structure of murine 11 beta-hydroxysteroid dehydrogenase/microsomal carbonyl reductase.

Screening of a mouse liver lambda gt 11 cDNA library with a rat liver 11 beta-hydroxysteroid dehydrogenase cDNA (11 beta-HSDr1A) and subsequent screening with an isolated mouse probe, resulted in the isolation and structure determination of a mouse cDNA encoding an amino acid sequence which is very similar to human and rat 11 beta-hydroxysteroid dehydrogenases (78% and 86% similar, respectively), and also to other known vertebrate 11 beta-hydroxysteroid dehydrogenase structures. Open-reading-frame analysis and the deduced amino acid sequence predict a protein with a molecular mass of 32.3 kDa which belongs to the superfamily of the short-chain dehydrogenase proteins. The amino acid sequence contains two potential glycosylation sites. These data are in agreement with information on the glycoprotein character of the native enzyme. This kind of post-translational modification seems to be a determining factor concerning the equilibrium of the catalyzed 11 beta-dehydrogenation/11-oxo reduction step [Obeid, J., Curnow, K. M., Aisenberg, J. & White, P.C. (1993) Mol. Endocrinol. 7, 154-160; Agarwal, A.K., Tusie-Luna, M.T., Monder, C. & White, P.C. (1990) Mol. Endocrinol. 4, 1827-1832]. After in vitro transcription/translation of the mouse cDNA, immunoprecipitation with anti-(microsomal carbonyl reductase) serum and N-terminal sequence analysis of the purified protein confirms the identity of microsomal 11 beta-hydroxysteroid dehydrogenase with the previously described, microsomal-bound xenobiotic carbonyl reductase [Maser, E. & Bannenberg, G. (1994) Biochem. Pharmacol. 47, 1805-1812], and points to an involvement of the 11 beta-HSD1A isoform in the reductive phase-I metabolism of xenobiotic compounds, besides its endocrinological functions. The alignment and comparison to other hydroxysteroid dehydrogenase forms of the same protein superfamily allows the identification of important residues in the 11 beta-HSD primary structure.

Factors affecting the distribution of ingested propionic acid in the rat forestomach.

Propionic acid (PA) when incorporated into food pellets and fed to male Wistar rats for 20 wk had no effect on the forestomach mucosa; however, in powdered diet PA led to pronounced hyperplasia and severe inflammatory lesions in the forestomach mucosa near the limiting ridge. Since this discrepancy in the effect of PA may have been caused by the type of diet in which PA was administered, the distribution of total PA (including the corresponding acid-soluble CoA ester) in different parts of the stomach and certain variables affecting this distribution were investigated. In the forestomachs of rats fed 4% PA in powdered diet, the amount of PA in hyperplasias (1553 +/- 508 micrograms PA/g tissue) was three times higher than that in the remainder of the tissue (479 +/- 247 micrograms PA/g tissue). The PA content decreased progressively towards the glandular parts. There was a slight, but not significant, decrease in the PA content of the forestomach and a slight increase in the PA content of the glandular stomach in rats fed pelleted food compared with those fed powdered diet. Supplementation of 1% L-carnitine to PA powdered diet for 12 wk led to a significant decrease (P < 0.02) in PA accumulation in hyperplastic tissues compared with hyperplasias induced by PA alone, although L-carnitine had no influence on the severity of hyperplastic changes in the forestomachs of rats. The present study shows that the type of diet in which PA was administered to male Wistar rats is of great importance for the development of hyperplasia, PA or the corresponding CoA ester can accumulate in the forestomach and is preferably accumulated in hyperplasias, and PA accumulation does not appear to be directly related to the severity of hyperplastic changes.

A novel membrane associated carbonyl reducing enzyme is present in smooth endoplasmic reticulum of mouse liver.

Evidence supporting the existence of two distinct carbonyl (metyrapone) reducing enzymes which differ in subcellular localization and immunological homology has been provided. A soluble enzyme, designated as carbonyl reductase (EC 1.1.1.184) is located in the cytosol. The distribution of the second, membrane associated, MPON-reductase shows an excellent linear correlation to NADPH-cytochrome c reductase and, on the other hand, is reciprocal to the RNA/protein ratio of submicrosomal preparations. This indicates that the membrane associated MPON-reductase is exclusively located in the smooth endoplasmic reticulum. Using antibodies against the purified membrane associated enzyme the extent of immunological crossreaction corresponds well to the specific activities of MPON-reductase in the granular fractions, thus further confirming the localization of this enzyme within this organelle. The absence of antigenic crossreaction to cytosolic MPON-reductase indicates differences also in terms of the immunological relationship between the two enzymes.

Homologies between enzymes involved in steroid and xenobiotic carbonyl reduction in vertebrates, invertebrates and procaryonts.

Evidence is reported for the existence of a structurally and functionally related and probably evolutionarily conserved class of membrane-bound liver carbonyl reductases/hydroxysteroid dehydrogenases involved in steroid and xenobiotic carbonyl metabolism. Carbonyl reduction was investigated in liver microsomes of 8 vertebrate species, as well as in insect larvae total homogenate and in purified 3 alpha-hydroxysteroid dehydrogenase preparations of the procaryont Pseudomonas testosteroni, using the ketone compound 2-methyl-1,2 di-(3-pyridyl)-1-propanone (metyrapone) as substrate. The enzyme activities involved in the metyrapone metabolism were screened for their sensitivity to several steroids as inhibitors. In all fractions tested, steroids of the adrostane or pregnane class strongly inhibited xenobiotic carbonyl reduction, whereas only in the insect and procaryotic species could ecdysteroids inhibit this reaction. Immunoblot analysis with antibodies against the respective microsomal mouse liver metyrapone reductase revealed strong crossrections in all fractions tested, even in those of the insect and the procaryont. A similar crossreaction pattern was achieved when the same fractions were incubated with antibodies against 3 alpha-hydroxysteroid dehydrogenase from Pseudomonas testosteroni. The mutual immunoreactivity of the antibody species against proteins from vertebrate liver microsomes, insects and procaryonts suggests the existence of structural homologies within these carbonyl reducing enzymes. This is further confirmed by limited proteolysis of purified microsomal mouse liver carbonyl reductase and subsequent analysis of the peptide fragments with antibodies specifically purified by immunoreactivity against this respective crossreactive antigen. These immunoblot experiments revealed a 22 kDa peptide fragment which was commonly recognized by all antibodies and which might represent a conserved domain of the enzyme.

Effects of phenolic smoke condensates and their components on hepatic drug metabolizing systems.

Treatment of food with wood smoke is a long-established method of preservation and flavouring food. Recently, hardwood smoke condensates, purified of polycyclic hydrocarbons, have become of importance for direct flavouring of sausage-meat. The acute toxicity of the purified phenolic fraction in mice after intraperitoneal administration was therefore investigated. The LD50 was found to be 940 mg/kg body weight, which is about three times the LD50 of phenol (about 300 mg/kg). Only high concentrations of phenols or smoke condensate fractions are able to damage cytochrome P-450 by conversion to cytochrome P-420, whereas lower concentrations exhibit inhibitory effects on monooxygenase activity. Inductive properties of the phenolic fractions could not be demonstrated. Concentrations in vivo of free phenolic compounds do not reach inhibitory levels, since the hexobarbital-induced sleeping-time and 14CO2-exhalation after administration of p-[methoxy-14C] acetanilide are not altered. It is concluded that the phenolic compound intake with food regularly treated with smoke condensate fractions is below a toxicologically relevant level.

High carbonyl reductase activity in adrenal gland and ovary emphasizes its role in carbonyl compound detoxication.

Carbonyl reduction has been studied in liver, kidney, adrenal gland and ovary of female Wistar and Sprague-Dawley rats as well as of female NMRI mice by using metyrapone as a substrate and by means of direct HPLC analysis of the reduced alcohol metabolite metyrapol. Carbonyl reducing activities were found in all tissues examined so far, with that in rat ovary and adrenal gland cytosol exceeding the liver cytosolic specific activity severalfold: 15-fold and 12-fold in the Wistar strain; 12-fold and 7-fold in the Sprague-Dawley strain, respectively. In general, Wistar rat enzyme activities were about four times higher than those of Sprague-Dawley rats in all fractions, which indicates an interesting genetic difference between the two rat strains. Due to the sensitivity towards the diagnostic inhibitor quercitrin, carbonyl reductase (EC 1.1.1.184) seems to be mainly responsible for metyrapone reduction in rat and mouse adrenal gland and ovary cytosol. However, sensitivity towards dicoumarol in microsomal fractions of mouse tissues points to the involvement of further carbonyl reducing enzymes. Western blot experiments revealed immunological differences between metyrapone reductase from liver microsomes and respective enzymes of all other tissues. In conclusion, the difference in tissue and intracellular distribution suggests that several enzymes are involved in carbonyl reduction of metyrapone and the intracellular multiplicity of the enzymes may have some relation to their significance in carbonyl compound detoxification. These results support the hypothesis that carbonyl reductases, besides their participation in the metabolism of physiologically occurring substances, provide the enzymatic basis for the detoxification of xenobiotic carbonyl compounds in adrenal gland and ovary which have escaped their metabolic conversion by the liver.

Pharmacokinetic interaction between carbamazepine and neuroleptics after combined prolonged treatment in rats.

This study investigates how neuroleptics of phenothiazine or thioxanthene structure influence the pharmacokinetics of carbamazepine. Experiments were carried out on male Wistar rats. Carbamazepine and the neuroleptics were administered i.p., separately or together, for 2 weeks in the following daily doses (mg/kg): carbamazepine 15 during the 1st week of treatment and 20 during the 2nd week of treatment, promazine 10, chlorpromazine 2, perazine 10, chlorprothixene 2, flupenthixol 0.5. One hour after the last injection of carbamazepine and/or the neuroleptic, samples of blood plasma and brain were taken to determine the concentrations of carbamazepine and two of its metabolites: 10,11-epoxide and trans-10,11-diol. The neuroleptics increased the concentration of carbamazepine in plasma and in brain, but tended to decrease (with the exception of chlorpromazine) the concentration of the epoxide and increased the concentration of trans-10,11-diol. Metabolic in vitro studies did not show any significant differences between rats treated with carbamazepine alone and those treated with carbamazepine plus neuroleptic in the rates of the carbamazepine epoxidation, of 10,11-epoxide hydrolysis or of 1-naphthol glucuronidation.

Functional and immunological relationships between metyrapone reductase from mouse liver microsomes and 3 alpha-hydroxysteroid dehydrogenase from Pseudomonas testosteroni.

3 Alpha-hydroxysteroid dehydrogenase (3 alpha-HSD) from Pseudomonas testosteroni was shown to reduce the xenobiotic carbonyl compound metyrapone (MPON). Reversely, MPON reductase purified from mouse liver microsomes and previously characterized as aldehyde reductase, was competitively inhibited by 3 alpha-HSD steroid substrates. For MPON reduction both enzymes can use either NADH or NADPH as co-substrate. Immunoblot analysis after native and SDS gel electrophoresis of 3 alpha-HSD gave a specific crossreaction with the antibodies against the microsomal mouse liver MPON reductase pointing to structural homologies between these enzymes. In conclusion, there seem to exist structural as well as functional relationships between a mammalian liver aldehyde reductase and prokaryotic 3 alpha-HSD. Moreover, based on the molecular weights and the co-substrate specificities microsomal mouse liver MPON reductase and Pseudomonas 3 alpha-HSD seem to be members of the short-chain alcohol dehydrogenase family.

Carbonyl reduction of metyrapone in human liver.

Carbonyl reduction was investigated in cytosolic and microsomal fractions of human liver using the ketone metyrapone as a substrate. The cytosolic enzyme has a stronger preference for NADPH over NADH than the microsomal enzyme: the former shows only 14% of the NADPH-supported activity while the latter exhibits 36% activity with NADH. Barbitone and quercitrin, the classic inhibitors of carbonyl reductases, do not affect metyrapone reduction in either fraction. Dicumarol and indomethacin, the specific inhibitors of NAD(P)H: quinone-oxidoreductase and dihydrodiol dehydrogenase, respectively, only slightly decreased metyrapol formation. In contrast, 5 alpha-dihydrotestosterone, the active form of the androgen steroid testosterone, inhibited metyrapone reduction very strongly in the microsomal fractions and is postulated to be the physiological substrate of the enzyme. This resembles the situation in mouse liver [E. Maser and K. J. Netter, Biochem Pharmacol 38: 3049-3054, 1989] where microsomal metyrapone reductase was inhibited by steroids and the purified enzyme was demonstrated to mediate androsterone oxidation. Immunoblot analysis revealed antigenic cross-reaction of antibodies against the 34 kDa metyrapone reductase from mouse liver microsomes with the homologous protein in human liver microsomes pointing to structural homologies between the respective enzymes of the two species. These results--together with previous findings, which have shown that there exist functional as well as structural relationships between microsomal mouse liver metyrapone reductase and 3 alpha-hydroxysteroid dehydrogenase from Pseudomonas testosteroni [E. Maser, U. Oppermann and K. J. Netter, Eur J Pharmacol 183:1366, 1990]--suggest that metyrapone reduction in human liver microsomes might be catalysed by a microsomal hydroxysteroid dehydrogenase.

Heterogeneity of carbonyl reduction in subcellular fractions and different organs in rodents.

The pattern and distribution of carbonyl reduction in liver, kidney and adrenal gland subcellular fractions of NMRI mice, Wistar rats and Hartley guinea pigs were examined using the ketone compound metyrapone (2-methyl-1,2-di(3-pyridyl)1-propanone) commonly used as a diagnostic cytochrome P450 inhibitor. A direct HPLC method for alcohol metabolite determination instead of the indirect spectrophotometric recording of pyridine nucleotide oxidation at 340 nm was applied. All the tissues examined in these species rapidly reduced the employed compound but at the subcellular level no general distribution scheme of specific activity was found, although in all fractions metyrapol formation could be attributed to aldo-keto reductases. Cytosolic and microsomal metyrapone reducing enzymes are distinguished by their inhibitor sensitivity to phenobarbitone and quercitrin and thus can be characterized as aldehyde and ketone reductases according to the inhibitor subclassification of the aldo-keto reductase family. Moreover, the enzymes also differ with respect to their immunological cross-reactivity to anti-microsomal mouse liver metyrapone reductase antibodies. Immunological homologies were found between metyrapone reductases of liver microsomes from all species and kidney and adrenal gland microsomes from guinea pig. However, the protein of all the cytosolic fractions as well as that of kidney and adrenal gland microsomes from mouse and rat did not cross-react with the antibodies, indicating the absence of common antigenic determinants. From catalytic properties and functional data it is concluded that hydroxysteroid dehydrogenases present in the suspected subcellular fractions form a structurally and functionally related enzyme family which may have been conserved during evolution.