Satoshi Toki

Protective effect of sulfhydryl compounds on acute toxicity of morphinone.

The ability of sulfhydryl compounds to provide protection against the acute toxicity of morphinone was investigated in mice. Subcutaneous administration of morphinone produced a reduction of hepatic non-protein sulfhydryl concentration. Pretreatments of mice with glutathione or cysteine significantly increased the survival rate of mice given a lethal dose of morphinone, whereas morphinone lethality was markedly potentiated by diethyl maleate. On the other hand, the administration of morphine produce a dose dependent reduction of hepatic non-protein sulfhydryl contents. However, neither glutathione nor cysteine protected mice from the acute toxicity of morphine. A possible explanation for these observations was proposed as follows: morphine is oxidized by morphine 6-dehydrogenase to morphinone, and the morphinone thus produced decreases the sulfhydryl contents in the liver. This mechanism is supported by the fact that morphinone reacts easily with glutathione and cysteine in vitro.

In vivo and in vitro formation of morphinone from morphine in rat

1. Morphinone, a toxic metabolite, and its glutathione adduct (MO-GSH) were identified in the bile of rat after subcutaneous injection of morphine (25 mg/kg) by hplc procedures. The amounts of morphinone and MO-GSH excreted in the 12-h bile were 0.8 +/- 0.3 and 8.4 +/- 4.3% respectively. 2. The 9000 g supernatants of rat, guinea pig, rabbit, mouse, hamster and bovine livers produced morphinone from morphine in the presence of either NAD+ or NADP+, NAD+ was a more efficient cofactor than NADP+ except in the guinea pig which equally utilized both cofactors. With NAD+ as cofactor, the amounts of morphinone formed in rat and guinea pig were 5.70 and 5.82 mumol/g liver/30 min respectively and were three-to-four times those in other species. 3. The enzyme activity responsible for formation of morphinone from morphine in the rat was almost exclusively distributed in the microsomal fraction, whereas guinea pig, hamster and bovine expressed the enzyme activity mainly in the cytosolic fraction. Rabbit and mouse gave higher activity in the cytosolic and microsomal fractions respectively, but other fractions of both species contained considerable activity. 4. The enzyme activities in male and female rat microsomes were characterized with respect to developmental pattern, kinetic parameters, pH dependency and susceptibility to inhibitors. 5. In conclusion the metabolism of morphine to morphinone in rat was confirmed by in vivo and in vitro experiments. It is also suggested that this pathway is a common route in morphine metabolism in several mammalian species.

In vitro formation of codeinone from codeine by rat or guinea pig liver homogenate and its acute toxicity in mice.

In vitro metabolism of codeine was investigated by using a 9000 g supernatant fraction of rat or guinea pig liver homogenate. When a mixture of [N-14CH3] and [C-6-3H]codeine was incubated with the rat liver 9000 g supernatant fraction in the presence of NAD, formation of codeinone, morphine and norcodeine was detected. Replacement of NAD with NADP abolished only the formation of codeinone. On the other hand, when the guinea pig liver homogenate was used in the presence of NAD, codeinone was the main metabolite of codeine. NADP was also ineffective in forming codeinone with the guinea pig liver homogenate. The acute toxicity of codeinone was thirty times higher than that of codeine. The roles of codeinone as a metabolic intermediate and in the acute toxicity of codeine are discussed.

Effect of morphinone on opiate receptor binding and morphine-elicited analgesia

Specific binding of 3H-naloxone to opiate receptors was found to be irreversibly inactivated by morphine. This inactivation exhibited pseudo-first-order kinetics. The presence of sulfhydryl compounds or morphine during incubation with morphinone proved good protection. Morphinone-pretreated mice blocked the analgesic effect of morphine. The possible mechanism for these observations is proposed as follows: morphinone binds covalently to sulfhydryl group of opiate receptors, and inactivates irreversibly opiate binding sites, thus blocking the analgesic effect of morphine.

Effects of glutathione and phenobarbital on the toxicity of codeinone.

The ability of sulfhydryl compounds to provide protection against the acute toxicity of codeinone, a toxic metabolite of codeine, was investigated in mice. Subcutaneous administration of codeinone produced a slight reduction in hepatic glutathione concentration. Pretreatment of the mice with glutathione or cysteine significantly increased the survival rate for mice given a lethal dose of codeinone (10 mg/kg). The lethality of codeine was lowered by naloxone, whereas that of codeinone was not blocked by naloxone. The strychnine-like convulsant action of codeinone could be prevented by phenobarbital pretreatment. Glutathione pretreatment reduced the amounts of radioactivity in tissues of mice injected with [N-methyl-3-H]codeinone. A possible explanation for these observations is that glutathione reacts in vivo with codeinone and plays a role as a scavenger of this compound. This assumption is supported by the observation that codeinone reacts non-enzymatically with glutathione under physiological conditions.

Guinea-pig liver morphine 6-dehydrogenase as a naloxone reductase

Elution profiles of guinea-pig liver naloxone reductase and morphine 6-dehydrogenase on Matrex green A, Sephadex G-100 and DEAE-cellulose (DE32) column chromatography used sequentially in the purification procedure were identical. The ratios of the two enzyme activities were almost constant throughout all the purification steps. The two enzymes were similarly more stable at pH 6.0 than at pH 8.0 on storage at 4 degrees. The reversible inactivation of the two enzymes by the removal of 2-mercaptoethanol from the enzyme solution was the same. Inhibitory effects of lithocholic acid, CuSO4, quercitrin, phenylarsine oxide, and prostaglandin E1 on the two enzymes were almost the same. These results indicated that naloxone reductase is identical to morphine 6-dehydrogenase in the guinea-pig liver. For the reduction of naloxone, the enzyme utilized either NADPH or NADH as cofactor, and pH optima were 6.8 with NADPH and 6.2 with NADH. The Km values for NADPH and NADH were 6.5 and 2.2 microM respectively. The Vmax values for naloxone were 1.2 units/mg protein with NADPH and 0.5 unit/mg protein with NADH. The Km values for naloxone were 0.27 mM with NADPH and 0.44 mM with NADH. The reaction product formed by the enzyme was identified as 6 alpha-naloxol by thin-layer and gas-liquid chromatographic analyses. Accordingly, it is clear that the enzyme catalyzes the stereospecific reduction of naloxone to form the 6 alpha-hydroxyl congener.

Hydroxyl radical-mediated conversion of morphine to morphinone

1. The hydroxyl radical-mediated conversion of morphine to morphinone (MO) was examined as an alternative to the enzymic reaction. 2. Hydroxyl radicals were generated by autoxidation of ascorbate in the presence of iron and EDTA. This system oxidized morphine to MO which was identified by h.p.l.c. and t.l.c. The reaction was dependent on the concentration of added Fe2+ and required the addition of ascorbate when Fe3+ was used. 3. Catalase inhibited production of MO whereas superoxide dismutase (SOD) had no effect. Addition of a large amount of H2O2 to the system resulted in a significant decrease in production of MO. No MO production was initiated by H2O2 itself. The oxidation of morphine was inhibited by typical hydroxyl radical-scavenging agents. These results indicate that morphine undergoes oxidation to MO by hydroxyl radical.

Guinea pig liver 3-hydroxyhexabarbital dehydrogenase as a 17β-hydroxysteroid dehydrogenase

Abstract In order to confirm the identity of guinea pig liver 3-hydroxyhexobarbital dehydrogenase with 17β-hydroxysteroid dehydrogenase (17β-hydroxysteroid: NADP+ 17-oxidoreductase, EC 1.1.1.64), several experiments were attempted. 1. 1. During the purification steps, the ratios of the two enzyme activities were almost constant after another newly discovered 17β-hydroxysteroid dehydrogenase was eliminated by DEAE-cellulose DE-32 column chromatography. 2. 2. The two enzymes showed the same susceptibility to thermal inactivation, and were activated similarly by phosphate ion when NAD+ was used as cofactor. 3. 3. K i values for p- chloromercuribenzoate were almost the same between the two enzymes. 4. 4. Results of mixed substrate method indicated that 3-hydroxyhexobarbital and testosterone were metabolized by a single enzyme, and kinetic studies gave the information that 3-hydroxyhexobarbital and testosterone were inhibited competitively each other, and that the active sites of the two enzymes were identical. These results indicated that 3-hydroxyhexobarbital dehydrogenase is identical with 17β-hydroxysteroid dehydrogenase in guinea pig liver.

New aspect of guinea pig liver 17β-hydroxysteroid (testosterone) dehydrogenase

Abstract The 17β-hydroxysteroid (testosterone) dehydrogenase prepared from guinea pig liver soluble fraction has been separated into two fractions, A and B, by ammonium sulfate precipitation followed by DEAE-cellulose chromatography. Fraction B also contains dehydrogenase activity for 3-hydroxyhexobarbital. Both NAD and NADP are cofactors for either fraction.

Purification and characterization of rat liver naloxone reductase that is identical to 3alpha-hydroxysteroid dehydrogenase

1. Rat liver cytosol produced exclusively 6beta-naloxol from naloxone in the presence of either NADPH or NADH at pH 7.4. The amount of 6beta-naloxol formed with NADPH was about four times that with NADH. The enzyme responsible for this reaction, termed naloxone reductase, was purified to a homogeneous protein by various chromatographic techniques. 2. The purified enzyme is a monomeric protein with a molecular weight of 34000 and an isoelectric point of 5.9, and it has a dual co-factor specificity for NADPH and NADH. The enzyme catalysed the reduction of various carbonyl compounds as well as naloxone analogues, and the dehydrogenation of 3alpha-hydroxysteroids and alicyclic alcohols. Indomethacin, quercetin and sulphhydryl reagents potently inhibited the enzyme, but pyrazole and barbital had no effect on the enzyme activity. 3. Identity of naloxone reductase and 3alpha-hydroxysteroid dehydrogenase in rat liver was demonstrated by comparing the elution profiles of the two enzyme activities during purification, the ratios of the two enzyme activities at each purification steps, and thermal stability and susceptibility to inhibitors for the two enzyme activities. 4. Amino acid sequences of five peptides obtained by proteolytic digestion of the purified enzyme were completely identical to the corresponding regions of previously reported 3alpha-hydroxysteroid dehydrogenase.