Hormonal regulation of male-specific 20beta-hydroxysteroid dehydrogenase with carbonyl reductase-like activity present in kidney microsomes of rats.

Progesterone, 17alpha-hydroxyprogesterone, cortisone and cortisol, which are C(21)-steroids with a ketone group at the 20-position, potently inhibited the activity of enzyme acetohexamide reductase (AHR) responsible for the reductive metabolism of acetohexamide in kidney microsomes of male rats. Furthermore, progesterone was a competitive inhibitor of AHR. In the case of progesterone usage as the substrate, 20beta-hydroxysteroid dehydrogenase (20beta-HSD) activity was much higher than 20alpha-hydroxysteroid dehydrogenase (20alpha-HSD) activity in kidney microsomes of male rats. These results indicate that AHR present in kidney microsomes of male rats, functions as 20beta-HSD with carbonyl reductase-like activity. In male rats, both testectomy and hypophysectomy decreased the renal microsomal 20beta-HSD activity, but the decreased enzyme activities were increased by the treatment with testosterone propionate (TP). We propose the possibility that TP treatment regulates the renal microsomal 20beta-HSD activity by acting directly on the kidney of male rats. This is supported from the fact that when TP was given to ovariectomized and hypophysectomized female rats, the male-specific 20beta-HSD activity was detected in their kidney microsomes.     

Modification of microsomal 11beta-HSD1 activity by cytosolic compounds: glutathione and hexose phosphoesters

11beta-Hydroxysteroid dehydrogenase1(11beta-HSD1) can serve either as an oxo-reductase or dehydrogenase determined by the redox state in the endoplasmic reticulum (ER). This bidirectional enzyme governs paracrine glucocorticoid production. Recent in vitro studies have underscored the key role of cytoplasmic glucose-6-phosphate (G6P) in controlling the flux direction of 11betaHSD-1 by altering the intraluminal ER NADPH/NADP ratio. The hypothesis that other hexose phosphoesters or the plentiful cellular oxidative protector glutathione could also regulate microsomal 11betaHSD-1 activity was tested. Fructose-6-phosphate increased the activity of 11beta-HSD1 reductase in isolated rat and porcine liver microsomes but not porcine fat microsomes. Moreover, oxidized glutathione (GSSG) attenuated 11beta-HSD1 reductase activity by 40% while reduced glutathione (GSH) activated the reductase in liver. Fat microsomes were unaffected because they lack glutathione reductase. Nonetheless, another oxidizing agent, hydrogen peroxide (0.5mM), inhibited both fat and liver 11beta-HSD1 reductase. Consistent with the major role of the redox state, 2.5mM GSSG and hydrogen peroxide augmented the 11beta-HSD1 dehydrogenase, antithetical to the reductase, by 20-30% in liver microsomes. Given the key role of reactive oxygen species and hexose phosphate accumulation in the pathoetiology of obesity and diabetes, these compounds might also modify 11beta-HSD1 in these conditions.     

Microsomal electron-transport reductase activities and fatty acid elongation in rat brain. Developmental changes, regional distribution and comparison with liver activity.

Gestational and postnatal changes of microsomal NADH:cytochrome b5 reductase and NADPH:cytochrome c reductase activities were examined in rat brain. The specific activity of NADH:cytochrome b5 reductase was high at 18-19 days of gestational age, decreased to a minimum at 4 to 6 days after birth and increased thereafter. An essentially similar developmental pattern was observed for the specific activity of NADPH:cytochrome c reductase. In contrast, the specific activities of these reductases in liver microsomes were low, did not display a peak during gestation and increased steadily to a maximum at 40-50 days after birth. The rate of incorporation of [2-14C]malonyl-CoA into palmitoyl-CoA in brain microsomes was found to be high in the foetus, sharply decreased to a minimum at the time of birth and increased thereafter. The activity of fatty acid elongation in liver microsomes was much less than that in brain during gestation and increased rapidly after birth to values at 50-60 days 20-fold greater than the foetal activity. NADH and NADPH were equally effective for brain microsomal fatty acid elongation. Regional distribution of cytochrome reductase activities and the activity of fatty acid elongation showed the lowest specific activity in cerebellum. These results suggest that brain microsomal electron transport may be correlated with the developmental alteration in fatty acid elongation.     

The in vivo effects of acenocoumarol, phenprocoumon and warfarin on vitamin K epoxide reductase and vitamin K-dependent carboxylase in various tissues of the rat

In rats the in vivo effects of a chronic low-dose treatment (+/- 60 micrograms/rat per day) with different coumarins (acenocoumarol, phenprocoumon and warfarin) on hepatic and non-hepatic vitamin K-dependent enzyme systems were compared. The plasma concentrations of the three coumarins differed largely but these differences were not reflected in the microsomal coumarin contents. The non-hepatic microsomes contained less than 20% of the coumarins found in liver microsomes. No substantial differences were observed between the following effects of the three anticoagulant treatments. The blood coagulation factor activities were about 10% of normal. The hepatic microsomal vitamin K epoxide reductase activity was diminished to about 35% of control values. The vitamin K epoxide reductase activities present in kidney, lung, spleen, testis and brain microsomes were less influenced by the coumarin treatments; activities ranged between 45 and 65% of normal. In the liver microsomes a 15-fold accumulation of non-carboxylated precursor proteins was found; in the non-hepatic microsomes this effect was less pronounced but still present. The hepatic vitamin K-dependent carboxylase activity was enhanced but the corresponding non-hepatic enzyme activities were slightly or not affected. In addition, the effects of a chronic low-dose warfarin treatment were compared with those after an acute high dose of the drug.     

The effect of the administration of cobaltic protoporphyrin IX on drug metabolism, carbon tetrachloride activation and lipid peroxidation in rat liver microsomes

The effects of cobaltic protoporphyrin IX (CPP) administration on hepatic microsomal drug metabolism, carbon tetrachloride activation and lipid peroxidation have been investigated using male Wistar rats. CPP (125 mumol/kg, 72 h before sacrifice) profoundly decreased the levels of hepatic microsomal heme, particularly cytochrome P-450. Consequently, the associated mixed-function oxidase systems were equally strongly depressed. An unexpected finding was that CPP administration also greatly decreased the activity of NADPH/cytochrome c reductase, a result not generally found with the administration of the more widely used cytochrome P-450 depleting agents, cobaltous chloride. Activation of carbon tetrachloride, measured as covalent binding of [14C] CCl4, spin-trapping of CCl3 and CCl4-stimulated lipid peroxidation, was much lower in liver microsomes from CPP-treated rats. Other microsomal lipid peroxidation systems, utilising cumene hydroperoxide or NADPH/ADP-Fe2+, were also depressed in parallel with the decrease in microsomal enzyme activities.     

The effects of unsaturated fatty acids on hepatic microsomal drug metabolism and cytochrome P-450

1. The effects of unsaturated fatty acids on drug-metabolizing enzymes in vitro were measured by using rat and rabbit hepatic 9000g supernatant fractions. 2. Unsaturated fatty acids inhibited the hepatic microsomal metabolism of ;type I' drugs with inhibition increasing with unsaturation: arachidonic acid>linolenic acid>linoleic acid>oleic acid. Inhibition was independent of lipid peroxidation. Linoleic acid competitively inhibited the microsomal O-demethylation of p-nitroanisole and the N-demethylation of (+)-benzphetamine. 3. The hepatic microsomal metabolism of ;type II' substrates, aniline and (-)-amphetamine, was not affected by unsaturated fatty acids. 4. The rate of reduction of p-nitrobenzoic acid and Neoprontosil was accelerated by unsaturated fatty acids. 5. Linoleic acid up to 3.5mm did not decelerate the generation of NADPH by rat liver soluble fraction, nor the activity of NADPH-cytochrome c reductase of rat liver microsomes. Hepatic microsomal NADPH oxidase activity was slightly enhanced by added linoleic acid. 6. No measurable disappearance of exogenously added linoleic acid occurred when this fatty acid was incubated with rat liver microsomes and an NADPH source. 7. The unsaturated fatty acids used in this study produced type I spectra when added to rat liver microsomes, and affected several microsomal enzyme activities in a manner characteristic of type I ligands.     

Properties of cytosolic components activating rat hepatic 5'' [corrected]-deiodination in the presence of NADPH.

The effects of cytosol, NADPH and reduced glutathione (GSH) on the activity of 5'-deiodinase were studied by using washed hepatic microsomes from normal fed rats. Cytosol alone had little stimulatory effect on the activation of microsomal 5'-deiodinase. NADPH had no stimulatory effect on the microsomal 5'-deiodinase unless cytosol was added. 5'-deiodinase activity was greatly enhanced by the simultaneous addition of NADPH and cytosol (P less than 0.001); this was significantly higher than that with either NADPH or cytosol alone (P less than 0.001). GSH was active in stimulating the enzyme activity in the absence of cytosol, but the activity of 5'-deiodinase with 62 microM-NADPH in the presence of cytosol was significantly higher than that with 250 microM-GSH in the presence of the same concentration of cytosol (P less than 0.001). The properties of the cytosolic components essential for the NADPH-dependent activation of microsomal 5'-deiodinase independent of a glutathione/glutathione reductase system were further assessed using Sephadex G-50 column chromatography to yield three cytosolic fractions (A, B and C), wherein A represents pooled fractions near the void volume, B pooled fractions of intermediate Mr (approx. 13 000), and C of low Mr (approx. 300) containing glutathione. In the presence of NADPH (1 mM), the 5'-deiodination rate by hepatic washed microsomes is greatly increased if both A and B are added and is a function of the concentrations of A, B, washed microsomes and NADPH. A is heat-labile, whereas B is heat-stable and non-dialysable. These observations provide the first evidence of an NADPH-dependent cytosolic reductase system not involving glutathione which stimulates microsomal 5'-deiodinase of normal rat liver. The present data are consistent with a deiodination mechanism involving mediation by a reductase (other than glutathione reductase) in fraction A of an NADPH-dependent reduction of a hydrogen acceptor in fraction B, followed by reduction of oxidized microsomal deiodinase by the reduced acceptor (component in fraction B).     

Properties of purified rat hepatic 3-hydroxy-3-methylglutaryl coenzyme A reductase and regulation of enzyme activity

3-Hydroxy-3-methylglutaryl coenzyme A (HMG-CoA) reductase from rat liver microsomes has been purified to apparent homogeneity with recoveries of approximately 50%. The enzyme obtained from rats fed a diet supplemented with cholestyramine had specific activities of approximately 21,500 nmol of NADPH oxidized/min/mg of protein. After amino acid analysis a specific activity of 31,000 nmol of NADPH oxidized/min/mg of amino acyl mass was obtained. The s20,w for HMG-CoA reductase was 6.14 S and the Stokes radius was .39 nm. The molecular weight of the enzyme was 104,000 and the enzyme subunit after sodium dodecyl sulfate-polyacrylamide gel electrophoresis was 52,000. Antibodies prepared against the homogeneous enzyme specifically precipitated HMG-CoA reductase from crude and pure fractions of the enzyme. Incubation of rat hepatocytes for 3 h in the presence of lecithin dispersions, compactin, or rat serum resulted in significant increases in the specific activity of the microsomal bound reductase. Immunotitrations indicated that in all cases these increases were associated with an activated form of the reductase. However activation of the enzyme accounted for only a small percentage of the total increase in enzyme activity; the vast majority of the increase was apparently due to an increase in the number of enzyme molecules. In contrast, when hepatocytes were incubated with mevalonolactone the lower enzyme activity which resulted was primarily due to inactivation of the enzyme with little change in the number of enzyme molecules. Immunotitrations of microsomes obtained from rats killed at the nadir or peak of the diurnal rhythm of 3-hydroxy-3-methylglutaryl-CoA reductase indicated that the rhythm results both from enzyme activation and an increased number of reductase molecules.     

NADPH: cytochrome P-450 reductase in olfactory epithelium. Relevance to cytochrome P-450-dependent reactions.

The presence of a very active cytochrome P-450-dependent drug-metabolizing system in the olfactory epithelium has been confirmed by using 7-ethoxycoumarin, 7-ethoxyresorufin, hexobarbitone and aniline as substrates, and the reasons for the marked activity of the cytochrome P-450 in this tissue have been investigated. The spectral interaction of hexobarbitone and aniline with hepatic and olfactory microsomes has been examined. By this criterion there was no evidence for marked differences in the spin state of the cytochromes of the two tissues, or for the olfactory epithelium containing a greater amount of cytochrome capable of binding hexobarbitone, a very actively metabolized substrate. Rates of NADPH and NADH: cytochrome c reductase activity were found to be higher in the olfactory epithelium than in the liver, and direct evidence was obtained for a greater amount of the NADPH-dependent flavoprotein in the olfactory microsomes. Investigation of male rats and male and female mice, as well as male hamsters, demonstrated that, in all cases, the cytochrome P-450 levels of the olfactory epithelium were lower than those of the liver, while the 7-ethoxycoumarin de-ethylase and NADPH:cytochrome c reductase activities were higher. A correlation was found between 7-ethoxycoumarin de-ethylase and NADPH:cytochrome c reductase activities for both tissues in all species examined. The ratio of reductase to cytochrome P-450 was found to be considerably higher in the olfactory epithelium (1:2-1:3) than in the liver (1:11-1:15), regardless of the species examined, suggesting that facilitated electron flow may contribute significantly to the cytochrome P-450 catalytic turnover in the olfactory tissue.     

Evidence that the 11 beta-hydroxysteroid dehydrogenase (11 beta-HSD1) is regulated by pentose pathway flux. Studies in rat adipocytes and microsomes

11 beta-hydroxysteroid dehydrogenase type 1 (11 beta-HSD1) catalyzes the interconversion of biologically inactive 11 keto derivatives (cortisone, 11-dehydrocorticosterone) to active glucocorticoids (cortisol, corticosterone) in fat, liver, and other tissues. It is located in the intraluminal compartment of the endoplasmic reticulum. Inasmuch as an oxo-reductase requires NADPH, we reasoned that 11 beta-HSD1 would be metabolically interconnected with the cytosolic pentose pathway because this pathway is the primary producer of reduced cellular pyridine nucleotides. To test this theory, 11 beta-HSD1 activity and pentose pathway were simultaneously measured in isolated intact rodent adipocytes. Established inhibitors of NAPDH production via the pentose pathway (dehydroandrostenedione or norepinephrine) inhibited 11 beta-HSD1 oxo-reductase while decreasing cellular NADPH content. Conversely these compounds slightly augmented the reverse, or dehydrogenase, reaction of 11 beta-HSD1. Importantly, using isolated intact microsomes, the inhibitors did not directly alter the tandem microsomal 11 beta-HSD1 and hexose-6-phosphate dehydrogenase enzyme unit. Metabolites of 11 beta-HSD1 (corticosterone or 11-dehydrocorticosterone) inhibited or increased pentose flux, respectively, demonstrating metabolic interconnectivity. Using isolated intact liver or fat microsomes, glucose-6 phosphate stimulated 11 beta-HSD1 oxo-reductase, and this effect was blocked by selective inhibitors of glucose-6-phosphate transport. In summary, we have demonstrated a metabolic interconnection between pentose pathway and 11 beta-HSD1 oxo-reductase activities that is dependent on cytosolic NADPH production. These observations link cytosolic carbohydrate flux with paracrine glucocorticoid formation. The clinical relevance of these findings may be germane to the regulation of paracrine glucocorticoid formation in disturbed nutritional states such as obesity.     

Post mortem characteristics of the hepatic microsomal drug oxidising enzyme system

The stability of hepatic microsomal drug oxidation and its associated electron transport has been studied in rabbits under conditions approximating those existing prior to human autopsy. Aminopyrine N-demethylation, aniline p-hydroxylation. NADPH cytochrome c reductase, NADPH cytochrome P-450 reductase, and the microsomal content of cytochrome P-450 declined appreciably in 2 h when microsomes were prepared from rabbit liver left in situ after death. In livers removed immediately after death and kept on ice these microsomal components remained stable for at least 4.5 h. Evidence of degeneration of human microsomes prepared from liver obtained at autopsy is discussed. The lability of hepatic microsomes from livers left in situ in these experiments or prior to autopsy is most likely secondary to slow cooling of the liver with coincidental autolysis. The possibility that the degeneration observed was due to the rapid growth of bacteria was disproved. These experiments demonstrate that care must be exercised in interpreting data obtained using microsomes from human autopsy material.     

Rat hepatic microsomal acetoacetyl-CoA reductase. A beta-ketoacyl-CoA reductase distinct from the long chain beta-ketoacyl-CoA reductase component of the microsomal fatty acid chain elongation system

The present study provides evidence for a new rat liver microsomal enzyme, a short chain beta-ketoacyl (acetoacetyl)-CoA reductase, which is separate from the long chain beta-ketoacyl-CoA reductase component of the microsomal fatty acid chain elongation system. This microsomal reductase converts acetoacetyl-CoA to beta-hydroxybutyryl-CoA at a rate of 70 nmol/min/mg of protein; the enzyme has a specific requirement for NADH and appears to obtain electrons directly from the reduced pyridine nucleotide without the intervention of cytochrome b5 and its flavoprotein reductase. The apparent Km of the enzyme of the acetoacetyl-CoA was 21 microM and for the cofactor, 18 microM. The pH optimum was broad, ranging from 6.5 to 8.0. The product formed is the D-isomer of beta-hydroxybutyryl-CoA. High carbohydrate fat-free diet resulted in a small but significant (35%) increase in microsomal acetoacetyl-CoA reductase activity. The cytosol also contains this enzyme activity, measuring approximately 57% of that found in the microsomes. The mitochondrial activity which is 20-25% higher than the microsomal activity appears to be due to L-beta-hydroxyacyl-CoA dehydrogenase which converts acetoacetyl-CoA to L-beta-hydroxybutyryl-CoA. The microsomal acetoacetyl-CoA reductase activity was extracted from the microsomal membrane by 0.4 M KCl, resulting in an 8- to 10-fold purification; in addition, the long chain fatty acid elongation system was unaffected by this extraction procedure. Employing beta- hydroxyhexanoyl -CoA as a substrate, evidence is also provided for a separate dehydratase which acts on short chain substrates. Lastly, the liver microsomes had no detectable acetoacetyl-CoA synthetase or acetyl-CoA acetyltransferase activities. Hence, the possible involvement of the rat hepatic microsomal short chain beta-ketoacyl-CoA reductase, short chain beta-hydroxyacyl-CoA dehydratase, and the previously reported short chain trans-2-enoyl-CoA reductase in the hepatic utilization of acetoacetyl-CoA and in the synthesis of butyryl-CoA for hepatic lipogenesis is discussed.     

Evidence for a second microsomal trans-2-enoyl coenzyme A reductase in rat liver. NADPH-specific short chain reductase

Evidence for the existence of a previously unknown rat hepatic microsomal reductase, short chain trans-2-enoyl-CoA reductase (SC reductase) is presented. This reductase has a specific requirement for NADPH, is unable to utilize NADH, and catalyzes the conversion of crotonyl-CoA and trans-2-hexenoyl-CoA to butyric acid and hexenoic acid at a rate of 5 and 65 nmol per min per mg of microsomal protein, respectively. Highly purified NADPH cytochrome P-450 reductase incorporated into liposomes prepared from dilauroyl phosphatidylcholine in the presence or absence of cytochrome P-450 possesses no SC reductase activity. These liposomal preparations did, however, catalyze mixed function oxidations of benzphetamine and testosterone. Rabbit antibody to rat liver NADPH cytochrome P-450 reductase had little to no effect on the conversion of crotonyl-CoA and trans-2-hexenoyl-CoA, suggesting that the SC reductase accepts reducing equivalents directly from NADPH. When acetoacetyl-CoA was incubated with hepatic microsomes and either NADH or NADPH, no formation of butyrate was detected; however, when both cofactors were present, a rate of formation of 3 nmol of butyrate was determined per min per mg of microsomal protein. These results suggest the presence of a previously unknown short chain beta-ketoreductase which catalyzes the reduction of short chain beta-keto acids, only in the presence of NADH. Our results also indicate that the electrons from NADH to the beta-ketoreductase bypass cytochrome b5. The physiological significance is discussed in terms of lipogenesis and ketone body utilization by the liver.     

Effect of dietary fat saturation on acylcoenzyme A:cholesterol acyltransferase activity of rat liver microsomes

The saturation of the fat contained in the diet has been observed to affect the acylcoenzyme A:cholesterol acyltransferase (ACAT) activity of rat liver microsomes. ACAT activity in microsomes (Mp) prepared from livers of rats fed a polyunsaturated fat-enriched diet containing 14% sunflower seed oil was 70-90% higher than in microsomes (Ms) prepared from livers of rats fed a saturated fat-enriched diet containing 14% coconut oil. This difference was observed within 20 days after the diets were begun, the earliest time tested, and persisted throughout the 70-day experimental period. The difference was noted at all [1-14C]palmitoyl CoA concentrations tested, 2.5-33 micronM, and at temperatures between 18 and 40 degrees C. Arrhenius plots revealed a single transition in enzyme activity, occurring at 29 degrees C in both microsomal preparations. Likewise, the activation energy above this transition was the same in Mp and Ms, 12.5 KCal/mol. Addition of albumin to the incubation medium increased the ACAT activity of both microsome preparations, but the difference between Mp and Ms persisted. Mp was enriched in polyenoic fatty acids, primarily 18:2 and 20:4, while Ms was enriched in monoenoic acids. Although the 20:4 increase in Mp occurred in all phosphoglycerides, it was especially pronounced in the serine and inositol phosphoglyceride fraction. There were no differences in the phospholipid or cholesterol content, phospholipid head group composition, or protein composition of the two microsomal preparations. The possibility is discussed that the changes in ACAT activity result from the differences in fatty acid composition of the microsomes. Other microsomal enzymes exhibited varying responses to these dietary fatty acid modifications. Palmitoyl CoA hydrolase and NADPH cytochrome c reductase activities were unchanged. UDP glucuronyl transferase activity was 50% higher in Mp, but glucose-6-phosphatase and NADH cytochrome b5 reductase activities were 25% higher in Ms. Therefore, dietary fat modifications do not produce a uniform effect on the activity of microsomal enzymes.     

Enhancement of microsomal drug oxidation and glucuronidation in rat liver by an environmental chemical, polychlorinated biphenyl

A polychlorinated biphenyl (PCB) compound, Clophen A 50, enhanced both hepatic aryl hydrocarbon hydroxylase and p-nitroanisole O-demethylase activities (7.5-fold and 16-fold, respectively), after treating the rats for 6 days with consecutive daily injections of Clophen A 50 (15 mg/kg i.p.). The treatment increased 3-fold the content of the carbon monoxide binding hemoprotein in liver microsomes, causing a concomitant shift in its reduced carbon monoxide absorbance peak to 448 nm. NADPH cytochrome c reductase, another component reaction of the microsomal mixed-function oxidase, was enhanced 1.5-fold in 6 days. A slight enhancement in the overall hydroxylation reactions was already observable 24 h after a single injection of Clophen A 50.The UDPglucuronosyltransferase activity of native liver microsomes was enhanced 3-fold in 6 days by the Clophen A 50 treatment of rats. The enhancement was, however, more pronounced, if the microsomes were treated in vitro with membrane-perturbing agents to activate the latent UDPglucuronosyltransferase before measuring its activity. After treatment for 6 days, the enhancement was about 6-fold in digitonin-treated, 5-fold in phospholipase C-treated and about 10-fold in trypsin-digested microsomes. No enhancement could be detected 24 h after a single Clophen A 50 injection.Aryl hydrocarbon hydroxylase activity was also enhanced in lung (5-fold), and kidney (8-fold) microsomes, whereas the microsomes from the duodenal mucosa exhibited no enhancement by a Clophen A 50 treatment of rats for 3 days.The data obtained support the assumption that PCBs form a new type of inducer group in enhancing the microsomal drug biotransformation. Both the monooxygenase complex and UDPglucuronosyltransferase differ in their properties from those after enhancement with the known types of inducers, exemplified by phenobarbital and 3-methylcholanthrene, respectively.     

Induction of hepatic drug metabolizing enzymes by DL-methionine in rats

A single intraperitoneal injection of DL-methionine (500 mg/kg body wt.) to adult male Wistar rats was shown to significantly induce all the components of the hepatic microsomal mixed function oxidase system such as NADPH cytochrome C reductase activity, cytochromes P-450 and b₅, as well as activities of drug metabolizing enzymes such as aminopyrine demethylase and uridine 5′ -diphosphate-glucuronosyltransferase. Combined administration of nicotinamide (250 mg/kg body wt.) and DL-methionine (500 mg/kg body wt.) was shown to bring about an additional increase (25-30%) in the activities of these enzymes as compared to their induction on independent administration of the two endobiotics. In rats bearing Yoshida sarcoma (ascites) tumour as well as in normal rats injected with serum from tumour bearing animals, the decreased activities of hepatic mixed function oxidases could be restored to their normal levels by administration of DL-methionine (500 mg/kg body wt.) to these rats. Whereas actinomycin D (1 mg/kg body wt.) had no effect on the increased incorporation of [¹⁴C] labelled leucine into microsomal proteins following administration of nicotinamide, the enhanced incorporation of the label following DL-methionine administration was completely inhibited by the same dose of actinomycin D. Administration of cycloheximide (0·5 mg/kg body wt.) to rats could completely inhibit the increased incorporation of [¹⁴C] leucine into hepatic microsomal proteins following independent administration of nicotinamide and DL-methionine. Similar inhibitory pattern with actinomycin D and cycloheximide was also demonstrated in case of induction of NADPH cytochromeC reductase activity by both these endobiotics.     

Increase of a form of UDP-glucuronyltransferase glucuronizing various phenolic xenobiotics and the corresponding translatable mRNA in 3-methylcholanthrene-treated rat liver

Induction of hepatic microsomal UDP-glucuronyltransferase activity toward various phenolic xenobiotics by 3-methylcholanthrene treatment of rats was observed, and the process of the induction was studied. We had previously purified a form of UDP-glucuronyltransferase (called GT-1) having a catalytic activity toward phenolic xenobiotics from liver microsomes of 3-methylcholanthrene-treated rats. The antibodies against GT-1 inhibited the enzyme activity toward those xenobiotics in liver microsomes, and bound to a single protein having a molecular weight of about 54,000 Da (same value as that of GT-1) among microsomal proteins on immunoblotting analysis. The amount of GT-1 protein in hepatic microsomes was found to be increased in close correspondence with the activity increase by 3-methylcholanthrene treatment, by immunoblotting analysis using an uninducible cytochrome P-450 reductase as a negative standard. It was shown by in vitro translation assays that the protein increase described above resulted from the enhancement of the level of translatable mRNA encoding for GT-1. Increases in the amount of the protein immunochemically corresponding to GT-1 in the microsomes from liver of phenobarbital-treated rats and from extrahepatic organs, such as kidney, small intestine, and lung, of phenobarbital- or 3-methylcholanthrene-treated rats were also observed.     

Diurnal changes in the fraction of 3-hydroxy-3-methylglutaryl-CoA reductase in the active form in rat liver microsomal fractions.

'Initial' and 'total' activities of 3-hydroxy-3-methylglutaryl-CoA reductase (HMG-CoA reductase) were measured in cold-clamped samples of liver from rats at 2h intervals throughout the 24h light/dark cycle. Initial activities were obtained in microsomes (microsomal fractions) isolated and assayed in the presence of 100mM-KF, whereas 'total' activities were measured in microsomes prepared from the same homogenates but washed free of KF and incubated with exogenous partially purified rat liver protein phosphatase. The initial/total-activity ratio for HMG-CoA reductase underwent a diurnal cycle, which had a nadir 4h into the light phase (when initial activity was 28% of total activity) and a peak 12h later, i.e. 4h into the dark phase (when initial activity was 80% of total activity). These low and high points of the cycle were separated by gradual steady changes in the ratio. The characteristics of this diurnal cycle were different from those of the cycle observed for total activity, which had a plateau of high activity between 2 and 10h into the dark cycle preceded and succeeded by a very rapid increase and decrease, respectively, in the total activity of HMG-CoA reductase. The combination of the two cycles resulted in the dampening of the resultant cycle for the initial or effective activity of HMG-CoA reductase, such that the changes in initial activity around the beginning and and end of the dark phase were more gradual than would otherwise have been the case if the initial/total-activity ratio for HMG-CoA reductase were constant throughout the diurnal cycle. The physiological implications of the observed diurnal variation in the fraction of hepatic HMG-CoA reductase in the active form are discussed.     

NAD (P) H-dependent reduction of nicotinamide N-oxide by an unique enzyme system consisting of liver microsomal NADPH-cytochrome C reductase and cytosolic aldehyde oxidase

NAD (P) H-dependent reduction of nicotinamide N-oxide was investigated with rabbit liver preparations. Microsomes, microsomal NADPH-cytochrome c reductase or cytosolic aldehyde oxidase alone exhibited no nicotinamide N-oxide reductase activity in the presence of NADPH or NADH. However, when the microsomal preparations were combined with the cytosolic enzyme, a significant N-oxide reductase activity was observed in the presence of the reduced pyridine nucleotide. The activity was enhanced by FAD or methyl viologen. Cytosol alone supplemented with NADPH or NADH exhibited only a slight, but when combined with microsomes, a significant N-oxide reductase activity. Based on these facts, we propose a new electron transfer system consisting of NADPH-cytochrome c reductase and aldehyde oxidase, which exhibits nicotinamide N-oxide reductase activity in the presence of the reduced pyridine nucleotide.     

Quantification of NADPH: cytochrome P-450 reductase in liver microsomes by a specific radioimmunoassay technique.

We have developed a specific radioimmunoassay to quantify NADPH: cytochrome P-450 reductase. The assay is based on the use of 125I-labelled NADPH: cytochrome P-450 reductase as the radiolabelled antigen and can detect quantities of this protein in amounts as low as 30 pg. The results of the radioimmunoassay demonstrates that the 2.7-fold increase in enzyme activity in rat liver microsomal membranes after phenobarbital treatment is due to increased amounts of the protein. beta-Naphthoflavone treatment, however, did not alter the activity or the quantity of this enzyme in microsomes. The quantification of NADPH: cytochrome P-450 reductase in the microsomes isolated from control and phenobarbital- and beta-naphthoflavone-treated animals permits the calculation of the ratio of this protein to that of total cytochromes P-450. A molar ratio of 15:1 (cytochromes P-450/NADPH: cytochrome P-450 reductase) was calculated for control and phenobarbital-treated animals. This ratio increased to 21:1 after beta-naphthoflavone treatment. Thus the molar ratio of these proteins in liver microsomes can vary with exposure of the animals to particular xenobiotics.