John A. Craft

A comparative study of Leishmania mexicana amastigotes and promastigotes, enzyme activities and subcellular locations

Leishmania mexicana mexicana amastigotes have been shown to contain greater activities than promastigotes of the enzymes that catalyse the beta-oxidation of fatty acids, but lower activities of several glycolytic enzymes, with the activity of pyruvate kinase being especially low. The results suggest the beta-oxidation of fatty acids is relatively more important to Leishmania amastigotes than promastigotes, whereas the reverse is true for glycolysis. Succinic dehydrogenase and peptidase activities were much higher in promastigotes than amastigotes. The activities of glucose-6-phosphatase, fructose-1,6-bisphosphatase, acid phosphatase and glucose-6-phosphate dehydrogenase varied less, although in each case the activity was significantly lower in the mammalian stage. A method for lysing and fractionating L. m. mexicana promastigotes has been developed. Using this procedure it has been established that many of the glycolytic and functionally related enzymes are located in cell organelles, that hexokinase is intimately connected with the particulate part of the parasite, and that the microsomal fraction of L. m. mexicana is very different in composition from the microsomes of mammalian liver cells.

Membrane topology of epoxide hydrolase.

The amino acid sequences of epoxide hydrolase from rat, rabbit and human have been subjected to hydropathy analysis and a novel model for the membrane topology of this enzyme is presented. The enzyme would appear to be retained in microsomal membranes by a single transmembrane segment located at the N-terminus and the majority (96%) of the protein is exposed at the cytosolic membrane surface. This model is significantly different from a scheme suggested by analysis of the rat enzyme alone which proposed six transmembrane domains (Porter et al. (1988) Arch. Biochem. Biophys. 248, 121-129). Experiments with rat microsomal membranes were conducted to distinguish between the two models and used proteolytic enzymes and non-permeant chemical probes. Epoxide hydrolase of intact and permeabilised membranes was resistant to digestion by a number of proteinases. However, this is likely to be related to a compact fold of the protein rather than membrane association since purified, delipidated enzyme preparations were also resistant to proteolysis. While the use of proteinases did not provide useful membrane topological information, experiments with the fluorescent probe, 3-azido-2,7-naphthalenedisulphonate strongly support the view that the majority of the protein is indeed exposed at the cytosolic surface of the membranes. The analysis illustrates the caution which must be employed in the formulation of topological models based on hydropathy plots alone and the value of considering homologous proteins.

Metabolism of 7,12-dimethylbenz[a]anthracene in hepatic microsomal membranes from rats treated with isoenzyme-selective inducers of cytochromes P450

Previous work has shown that member(s) of the cytochrome P450IIC sub-family play significant roles in the formation of diols of 7,12-dimethylbenz[a]anthracene (DMBA) and are particularly important in formation of the proximate carcinogen (DMBA-3,4-diol). To further characterize the role of members of this subfamily in DMBA-diol formation and to assess the part played by other P450s, DMBA metabolism has been investigated in microsomes prepared from animals pre-treated with isoenzyme selective inducers. The rates of formation of DMBA-diols in membranes from phenobarbital-treated rats were very low when NADH was used as reductant and rates were not altered when NADPH and NADH were used in combination rather than using NADPH alone. This suggests that cytochrome b5 is not involved in DMBA-diol formation in these membranes. Treatment of animals with clofibrate, pyrazole and dexamethasone produced regio-selective alterations in the rates of formation of DMBA-diols at the -3,4-, -5,6- and -8,9- positions. However, none of the inducers caused increases in the rates of DMBA-diol formation of any great magnitude suggesting that the isoforms which are the major induced proteins (P450IVA1, P450IIE1 and P450IIIA1) do not play a significant role in diol formation. The content of other P450s in these membrane are also altered and these were investigated by Western blot using antibodies to P450IIC6, P450IIB1 and P450IIIA1. The results of the Western blots show that the effects of the inducing agents on DMBA-diol formation can be explained by alterations of members of the P450IIC and P450IIB subfamilies.

Effects of metyrapone and norharmane on microsomal mono-oxygenase and epoxide hydrolase activities

This study was undertaken to examine the possibility that metyrapone and norharmane stimulate epoxide hydrolase and inhibit mono-oxygenase activities by binding to a cytochrome P-450 component of a stable complex containing the two enzymes. The concentration of metyrapone and norharmane which inhibited mono-oxygenase activities of hepatic microsomes from untreated and diethylnitrosamine treated rats was lower than that required to stimulate epoxide hydrolase of the same microsomes. The ability of metyrapone and norharmane to stimulate epoxide hydrolase in these microsomes was not inhibited by the addition of carbon monoxide and reductant. Epoxide hydrolase activity was inhibited by detergents but the enzyme was still stimulated by metyrapone and norharmane under conditions of total membrane disaggregation. When microsomes were solubilized, epoxide hydrolase could be quantitatively recovered by immunoprecipitation. The immunoprecipitate contained no detectable cytochrome P-450 but was stimulated by metyrapone and norharmane. A purified epoxide hydrolase was stimulated by metyrapone but not by norharmane. The response of the enzyme to norharmane was not restored by the inclusion of cytochrome P-448. These findings suggest that metyrapone and norharmane act at separate sites on both cytochrome P-450 and epoxide hydrolase.

The role of specific cytochromes P450 in the formation of 7,12-dimethylbenz(a)anthracene-protein adducts in rat liver microsomes in vitro

The role of specific cytochrome P450 (P450) isoforms in the formation of adducts of 7,12-dimethylbenz(a)anthracene metabolites and membrane proteins has been investigated in vitro with microsomal fractions prepared from rats pretreated with various isoenzyme selective inducers. The effects of isoenzyme selective inhibitors were also evaluated. Adduct formation was shown to be mediated by P450 catalysed reactions but was unaltered, relative to untreated animals, in membranes from pyrazole- and clofibrate-treated animals suggesting that CYP2E1 and CYP4A1 are not involved in this process. However, adduct formation was significantly increased in microsomes from Sudan III-, phenobarbital- and dexamethasone-treated rats, suggesting the involvement of the CYP1A, CYP2B and CYP3A subfamilies, respectively. These conclusions were further supported by the finding that adduct formation in these microsomes could be inhibited by the isoenzyme-selective inhibitors alpha-naphthoflavone, metyrapone and troleandomycin, respectively.

The contribution of specific cytochromes P-450 in the metabolism of 7,12-dimethylbenz[a]anthracene in rat and human liver microsomal membranes.

The role of specific cytochrome P-450 isoenzymes in the regio-selective metabolism of 7,12-dimethylbenz[a]anthracene (DMBA) has been studied in microsomal membranes from rat and human liver. An antibody inhibition study using membranes from phenobarbital-treated rats demonstrates that a member(s) of the CYP2C family accounts for up to 90% of the formation of the proximate carcinogen, DMBA-3,4-diol, and makes significant contributions to the formation of DMBA-5,6-diol and DMBA-8,9-diol. In these membranes the formation of DMBA-5,6-diol can be entirely accounted by the combined activity of members of the CYP2C and CYP2B families. The metabolism of DMBA has been investigated in human using microsomes from 10 individuals and the metabolites formed by these membranes were found to be mainly hydroxymethyl- and -diol products. The rates of formation of each metabolite show considerable interindividual variation and there was no correlation between these rates for any pairing of metabolites. The CYP content in these membranes of specific members of families 1, 2, 3 and 4 did correlate with the rates of formation of individual metabolites. Surprisingly there was no correlation between the content of CYP2C and formation of DMBA-3,4-diol but an antibody to rat CYP2C6 partially inhibited the formation of this metabolite. The results indicate that in human both inducible sub-families of CYPs, particularly of the PB-type, and constitutively expressed CYPs may be important in DMBA metabolism and that each metabolite may be produced by the combined activity of several CYP isoforms.

Effects of pyrazole on nitrosodimethylamine demethylase and other microsomal xenobiotic metabolising activities

Pyrazole administered to immature rats at one day or on four successive days prior to sacrifice increased a microsomal NDMAD with apparent Km 0.04 mM. Aniline hydroxylase activity was also increased by these treatments. Ethoxycoumarin deethylase and amino pyrine demethylase activities were not altered when animals were treated with pyrazole one day prior to sacrifice but were reduced to below control activity when animals were treated for four successive days. All microsomal mono-oxygenases were decreased when animals received a single administration of pyrazole four days prior to sacrifice and the cytochrome P-450 content of these microsomes was reduced by up to 50%. When microsomes from untreated animals or animals treated for four successive days were incubated with pyrazole in the presence of NADPH, cytochrome P-450 content decreased in a time dependent process to a limiting value. The effect was dependent on pyrazole concentration and saturable. These results suggest that pyrazole induces a cytochrome P-450 isoenzyme with high affinity for NDMA but also acts as a suicide inhibitor of the cytochrome.

Changes in hepatic xenobiotic-metabolising enzymes in mouse liver following infection with Leishmania donovani

Infection of mice with Leishmania donovani resulted in decreased activities of several liver enzymes involved in the metabolism of xenobiotics. Microsomal membranes from infected livers contained reduced amounts of cytochromes P450 and b5 and NADPH-cytochrome P450 reductase. Several cytochrome P450 isoenzymes (P450-PB1, P450-PB3, P450-PCN and P450-UT1) and P450-mediated reactions (aminopyrine demethylase, aniline hydroxylase, benzphentamine demethylase and ethoxycoumarin deethylase) were affected similarly. The metabolism of two carcinogens (nitrosodimethylamine and 7,12-dimethylbenz[a]anthracene) by liver microsomal membrane preparations was also reduced. Leishmania infection caused an increase of cytosolic epoxide hydrolase and microsomal epoxide hydrolase and NADH-cytochrome b5 reductase were unaffected. The results suggest that Leishmania-infected animals are likely to have altered responses to exogenous toxins compared to uninfected animals.

Induction of microsomal epoxide hydrolase by nitrosamines in rat liver: Effect on messenger ribonucleic acids

Nitrosomethylethylamine and nitrosomethylpropylamine were found to be more potent inducers of rat liver microsomal epoxide hydrolase (styrene oxide hydrolase) than nitrosodiethylamine or nitrosodimethylamine. The time course of induction following a single administration of nitrosodimethylethylamine, nitrosomethylpropylamine or nitrosodiethylamine each showed a delay of 24 hr during which enzyme activity was unaltered. After that time activity increased and reached a maximum at between 72 and 120 hr. Increased enzyme activity following NDEA was paralleled by changes in the content of epoxide hydrolase in microsomes as measured by Western blots. Nitrosamines caused an increase of mRNA for epoxide hydrolase which was detected by probing Northern blots with a [32]-P labelled epoxide hydrolase cDNA and by in vitro translation of polyadenylated mRNA. Both methods showed a maximal increase at 72 hr after nitrosodiethylamine treatment but a significant increase was also observed at 24 hr although at this time no increase in enzyme activity was apparent.

Evidence for protein phosphorylation as a regulatory mechanism for hepatic microsomal glucose 6 phosphatase.

Abstract Incubation of microsomal vesicles with ATP and protein kinase results in a fivefold increased glucose-6-phosphatase activity. Evidence is presented that this effect is mediated via a moiety of the outer membrane surface. Evidence is also presented for the presence of an endogenous, peripheral membrane protein also capable of activating glucose-6-phosphatase in an ATP dependent reaction. It is suggested that the glucose-6-phosphate transmembrane carrier system may be the target of phosphorylation.