Monoamine oxidase and aspartate aminotransferase in cellular fractions of thyroid gland in rats after hypophysectomy and TSH stimulation

Monoamine oxidase (MAO) and aspartate aminotransferase activities in cellular fractions of thyroid gland in rats after hypophysectomy and TSH treatment were investigated. MAO and aspartate aminotransferase activities in thyroid mitochondria were decreased after hypophysectomy and significantly increased after daily injection of TSH during five days to hypophysectomized rats. In microsomes after hypophysectomy a similar decrease of MAO activity was found but TSH was without effect on this activity. In conclusion: it is evident that MAO and aspartate aminotransferase in thyroid mitochondria the enzymes which could be a source for hydrogen peroxide to catalyze thyroid hormone synthesis are under the regulatory influence of TSH.     

Monoamine oxidase A mediates iodotyrosine formation induced by monoamines in bovine thyroid particulate fraction

Monoamines are able to increase the thyroid iodine organification in vitro. A predominance of the A form of monoamine oxidase (MAO) has been previously demonstrated to exist in bovine thyroid tissue. In the present study we have investigated the form of MAO that could be involved in the iodotyrosine formation induced by tyramine, 5-hydroxytryptamine (5-HT) and beta-phenylethylamine (PEA) in a bovine thyroid subcellular fraction. The relative capacity of these monoamines to generate H2O2 and to incorporate iodine into tyrosine has also been studied. The MAO A inhibitor clorgyline (10(-9) M) produced a strong inhibition on the iodotyrosine formation induced by tyramine, 5-HT and PEA. In contrast, only a slight reduction was observed with deprenyl as MAO B inhibitor. Among the three monoamines, tyramine produced the highest H2O2 generation and iodotyrosine formation. The lowest Km value obtained was for 5-HT and the highest for PEA. Regarding the Vmax, the lowest value was for 5-HT and the highest for tyramine. The amount of iodine incorporated to tyrosine was not equivalent to the H2O2 generated by the monoamines nor to that exogenously added. Our results indicate that in bovine thyroid tissue mainly the A form of MAO is involved in the monoamine metabolism.     

Inhibitory Effect of Silkworm-Extract(SE) on Monoamine Oxidase Activity in Vitro and in Vivo

In vitro.MAO‐A activity was inhibited 16‐25%, and MAO‐B activity was inhibited 20‐50% by SE treatment (12.5, 25 and 50 μg), In vivo.male C57BL/6 mice Received intraperitoneal injection of SE (20 mg/kg/day) for 14 days. The results showed that MAO‐A activity of pre‐SE‐treatment mice brain was inhibited in whole brain, cerebral cortex, substantia nigra. MAO‐B activity of pre‐SE‐treatment mice brain was inhibited in substantia nigra and cerebellum than saline‐treated control group. These results suggest that SE inhibits MAO activity in vivo.which would be expected to results in anti‐depressive and neuroprotective effects.     

Quinoline and quninaldine as naturally occurring inhibitors specific for type A monoamine oxidase

Type A monoamine oxidase (MAO-A) in human placental mitochondria was competitively inhibited by naturally occurring substances, quinoline and quinaldine, using kynuramine as substrate. Quinoline had a higher affinity for MAO than kynuramine. MAO-A in human brain synaptosomal mitochondria was also competitively inhibited by quinoline, while type B MAO (MAO-B) was reversibly and non-competitively inhibited by quinoline. Quinoline inhibited MAO-A much more potently than MAO-B. Of several compounds structurally similar to quinoline, isoquinoline noncompetitively inhibited MAO-A and -B activity.     

Biochemistry and physiology of monoamine oxidase (MAO) activity in the ring dove (Streptopelia risoria). II. Distribution of MAO in different tissues

Monoamine oxidase (MAO) activity was measured fluorometrically in liver, kidney, intestine and brain of adult male and female ring doves. Liver MAO was inhibited in a concentration-related fashion by clorgyline and harmaline (MAO type A inhibitors) where a plateau in the inhibition curve occurred with about 15% activity remaining, and also by the type B inhibitor deprenyl, which produced a plateau when about 85% activity remained. Kidney, intestine and brain MAO were inhibited in a biphasic manner by harmaline. Results with inhibitors suggest that 85% of liver MAO, 86% of kidney MAO, 88% of intestine and 75% of brain MAO is type A. Using 10(-6) M harmaline to differentiate between MAO-A and MAO-B type activities, the apparent maximal velocities (Vmax) and Michaelis constants (Km) were determined in different tissues. Most activity occurred in the intestine, with proportionally lesser amounts of kidney, liver and brain. The majority of MAO present was in the A form. Except for kidney, Km of MAO-B was higher than that of MAO-A. Both MAO-A and -B activities were higher in the intestines of male birds, although sex differences in content and type of MAO activity were not observed in other tissues of the ring dove.     

The characteristics and distribution of monoamine oxidase (MAO) activity in different tissues of the rainbow trout, Salmo gairdneri

Monoamine oxidase (MAO) activity was determined fluorometrically in brain, intestine, kidney and liver tissues of the rainbow trout, Salmo gairdneri. MAO activity was inhibited by various drugs in a concentration-related manner, with single sigmoid inhibition curves, the inhibitors of type A MAO, harmaline and clorgyline being more effective than deprenyl, an inhibitor of type B MAO. Intestine exhibited greatest MAO activity followed by liver and brain with kidney showing least activity. The Michaelis constants (Km) also showed variability between tissues. Inhibition of MAO by harmaline was non-competitive and dependent on the concentration of substrate present.     

Enhanced selectivity of pargyline as an inhibitor of type B monoamine oxidase in harmaline-treated rats

Pargyline, a slightly selective inhibitor of type B monoamine oxidase (MAO), inhibited phenylethylamine oxidation by 88 ± 1% and 81 ± 1% in rat brain and liver, respectively, at 24 hrs after injection of a 30 mg/kg i.p. dose. Serotonin oxidation was inhibited to a lesser extent, 68 ± 4% and 68 ± 2%, respectively, in brain and liver. In rats treated with harmaline, a short-lasting reversible MAO inhibitor selective for type A MAO, the inhibition of phenylethylamine oxidation after pargyline injection still occurred but the inhibition of serotonin oxidation was prevented. These results illustrate that a selective MAO inhibitor can be used to enhance the selectivity of an irreversible inhibitor, presumably by occupying active sites on a certain form of MAO temporarily and thereby preventing its inactivation. In heart, inhibition of both phenylethylamine and serotonin oxidation by pargyline was prevented by harmaline; this finding supports other evidence that phenylethylamine is metabolized by type A MAO in rat heart.     

Characterization of the multiple forms of monoamine oxidase from chronic schizophrenic sera.

Either half or one hour incubation time was enough to get a constant production of benzylaldehyde and were proportional to the amount of enzyme added. The optimal temperature of MAO, I, II, III, IV are 60 degrees, 37 degrees, 60 degrees, 45 degrees, and 37 degrees C respectively, and they follow Arrhenius equation until these optimal temperatures. Each form have optimal pH depends on substrate concentration used and the buffer used. These forms were shown to be inhibited by high substrate concentration with formation of inactive enzyme-amine complex, whereas butyl- and octylamine was found to be competitive inhibitors. Isoniazid inhibit MAO II, III, IV and V forms in a non competitive fashion, whereas MAO I inhibited competitively with respect to the substrate. Semicarbazid inhibit MAO I. III, IV and V forms in a non competitive fashion, whereas MAO II inhibited competitively with respect to the substrate.     

A new type of mitochondrial monamine oxidase distinct from type-A and type-B

The characteristics of mitochondrial monoamine oxidase (MAO) in carp liver were studied with MAO inhibitors and substrates. This enzyme was thermolabile, but was stabilized in the presence of bovine serum albumin. With clorgyline and deprenyl, single-sigmoidal curves for inhibition of the activity towards tyramine or 5-hydroxytryptamine were obtained; the sensitivities to the two inhibitors were identical. The activity towards β-phenylethylamine was not completely inhibited by clorgyline or deprenyl, but the remaining activity was inhibited by semicarbazide and the inhibition curves by either clorgyline or deprenyl and semicarbazide were also identical to the curves with the other two substrates. These results suggest that carp liver mitochondria contain “classical” MAO and a clorgyline- and deprenyl-resistant amine oxidase and that the classical MAO does not seem to be MAO-A or MAO-B, which are present in mitochondria of most mammalian tissues.     

Characterization of mitochondrial monoamine oxidase of Ascaridia galli

Oxidative deamination of various biogenic monoamines by Ascaridia galli monoamine oxidase (MAO) was blocked by different mammalian MAO inhibitors, namely, iproniazid, trans-PcP, nialamide and pargyline and the blockade was observed to be time as well as concentration dependent. The binding of inhibitors with chick ascarid MAO was of the irreversible type and the nature of the inhibition was competitive. Pargyline showed lowest I50 (8 microM) and Ki (12 microM) values. Chlorgyline and deprenyl at 100 microM concentration inhibited MAO by about 60 and 40% respectively, indicating the presence of both type A and type B MAO in A. galli.     

MONOAMINE OXIDASE (EC 1.4.3.4): ISOLATION AND CHARACTERIZATION OF MULTIPLE FORMS OF THE BRAIN ENZYME

Monoamine oxidase (MAO) in crude mitochondrial preparations from rat brain was solubilized, and different MAO-active fractions were separated by agarose columns and by Sephadex electrophoresis. Any combination of these techniques yielded at least three fractions possessing MAO activity as measured by assays using radioactive serotonin and benzylamine as substrates. The molecular weight of one of the MAO forms was found to be approximately 400,000 daltons while another was at least 1.5 × 10⁶ daltons. The crude mitochondria1 MAO was inhibited by [¹⁴C]-labelled pargyline and then solubilized and the radioactivity of the soluble and particulate MAO was compared to the enzyme activity found in the soluble and particulate fractions. Our studies suggest that appreciable MAO activity is lost upon solubilization and that the conformation of MAO may be altered.     

Monoamine oxidase and catechol-O-methyl transferase activity in Tetrahymena.

Tetrahymena pyriformis strain HSM was found to have monomine oxidase (MAO) and a catechol-3-methyl transferase-like (COMT) activity. As in mammalian tissues, the MAO activity is predominantly localized in the mitochondrial pellet and COMT in the cytosol. The COMT-like activity was present in amounts comparable to several mouse tissues and was inhibited by tropolone. MAO activity was much lower than in any of the mouse tissues tested, and its activity varied greatly from preparation to preparation. The substrate preference of Tetrahymena MAO was tryptamine greater than serotonin greater than dopamine, and activity increased with increasing pH from pH 6.5 to pH 7.8, as does that of mouse liver MAO. Teh Km of Tetrahymena MAO for tryptamine was approximately 4 micrometer, an order of magnitude lower than that of mouse liver MAO. Sensitivity of inhibition by MAO inhibitors was variable. In some preparations, no inhibition was observed. In others clear inhibition was obtained, harmine and clorgyline being among the most potent inhibitors.     

Topological probes of monoamine oxidases A and B in rat liver mitochondria: inhibition by TEMPO-substituted pargyline analogues and inactivation by proteolysis

TEMPO-substituted pargyline analogues differentially inhibit recombinant human monoamine oxidase A (MAO A) and B (MAO B) in intact yeast mitochondria, suggesting these membrane-bound enzymes are located on differing faces of the mitochondrial outer membrane [Upadhyay, A., and Edmondson, D. E. (2009) Biochemistry 48, 3928]. This approach is extended to the recombinant rat enzymes and to rat liver mitochondria. The differential specificities exhibited for human MAO A and MAO B by the m- and p-amido TEMPO pargylines are not as absolute with the rat enzymes. Similar patterns of reactivity are observed for rat MAO A and B in mitochondrial outer membrane preparations expressed in Pichia pastoris or isolated from rat liver. In intact yeast mitochondria, recombinant rat MAO B is inhibited by the pargyline analogue whereas MAO A activity shows no inhibition. Intact rat liver mitochondria exhibit an inhibition pattern opposite to that observed in yeast where MAO A is inhibited and MAO B activity is unaffected. Protease inactivation studies show specificity in that MAO A is sensitive to trypsin whereas MAO B is sensitive to β-chymotrypsin. In intact mitochondrial preparations, MAO A is readily inactivated in rat liver but not in yeast upon trypsin treatment and MAO B is readily inactivated by β-chymotrypsin in yeast but not in rat liver. These data show MAO A is oriented on the cytosolic face and MAO B is situated on the surface facing the intermembrane space of the mitochondrial outer membrane in rat liver. The differential mitochondrial outer membrane topology of MAO A and MAO B is relevant to their inhibition by drugs designed to be cardioprotectants or neuroprotectants.     

PROPERTIES OF MONOAMINE OXIDASES IN SYMPATHETIC NERVE AND PINEAL GLAND

Abstract— The monoamine oxidases (MAO) of rat pineal gland and superior cervical ganglion were compared and found to have different characteristics. The predominant enzyme in the ganglion was inhibited by low concentrations of clorgyline (0.1 μM), exhibited a lower apparent K_m for tyramine than the enzyme in the pineal, was readily inactivated by trypsin, and was relatively heat-stable. In contrast, the MAO of the pineal was inhibited by 0.1 m m clorgyline, was not readily inactivated by trypsin, and was heat-labile. Moreover, these enzymes appeared to have different substrate specificities. Our results are consistent with the view that there may be multiple forms of MAO and that these forms may be associated with specific cell types.     

The effect of debrisoquin on MAO A and MAO B activities

To examine the mode of action of debrisoquin (DEB), we studied the effect of this drug in vitro on MAO A and MAO B enzyme activities. DEB was shown to be a competitive inhibitor of highly purified human MAO A and MAO B enzyme activities. DEB inhibited placental MAO A with a Ki value of 0.5 microM and liver MAO B with a Ki value of 8.8 microM, 18-fold greater effect on the A form. Kynuramine was used as substrate for both enzymes. Additional studies using a dilution technique showed that DEB was a reversible inhibitor of both forms of the enzyme. The results of this study show that DEB is a potent competitive and reversible inhibitor of both MAO A and MAO B enzymes.     

Biochemistry and physiology of monoamine oxidase (MAO) activity in the ring dove (Streptopelia risoria). I. Characteristics of MAO activity in vitro

Monoamine oxidase (MAO) activity was measured in ring dove (Streptopelia risoria) tissues using a fluorometric assay with kynuramine as substrate. Harmaline inhibited MAO activity in a time-dependent manner, and preincubation of enzyme with the drug did not affect its activity. Pargyline produced a slow-onsetting inhibition of activity which was enhanced by preincubation of enzyme and inhibitor. Harmaline displayed reversible non-competitive inhibition of MAO activity. Oxygen is also a substrate for dove MAO, and the reaction apparently involves "ping-pong", double-displacement kinetics. Dove MAO activity is temperature-dependent, with an activation energy of 13.1 kcal/mole.     

Effect of N-Methyl-4-Phenylpyridinium Ion on Monoamine Oxidase in a Clonal Rat Pheochromocytoma Cell Line, PC 12h

The effects of the neurotoxin N-methyl-4-phenylpyridinium ion (MPP+) on the enzymes involved in synthesis and catabolism of catecholamines were examined using a clonal rat pheochromocytoma cell line, PC12h, as a model of dopaminergic neurons. MPP+ added in the culture medium was found to be accumulated in PC12h cells after 30-min incubation. Monoamine oxidase (MAO) activity in PC12h cells was inhibited by MPP+ in a dose-dependent way from 10 nM to 10 microM, but concentrations of MPP+ higher than 100 microM were found to increase the MAO activity. At the lower concentrations MPP+ inhibited MAO noncompetitively with respect to the substrate, kynuramine, and at the higher concentrations it increased both the Km and the Vmax values of MAO toward the substrate. On the other hand, tyrosine hydroxylase activity and the dopamine concentrations in PC12 cells were not changed by incubation with MPP+ for 30 min, 60 min, or 24 h.     

Effect of L-tryptophan and restraint stress on hypothalmic and brain serotonin turnover, and pituitary TSH and prolactin release in rats.

The dose response and time course effects of L-tryptophan and restraint stress on the metabolism of serotonin and release of thyroid stimulating hormone (TSH) and prolactin (PRL) were tested in male rats. Both treatments increased serotonin turnover in the hypothalamus (H) and remaining brain tissue minus the cerebellum (brain) as determined by enhanced accumulation of serotonin following monoamine oxidase (MAO) inhibition. L-tryptophan but not restraint stress elevated levels of tryptophan in the cerebellum. Both L-tryptophan and restraint stress inhibited TSH release and stimulated PRL release. These findings indicate that enhanced rates of serotonin turnover produced by L-tryptophan and physical restraint are associated with inhibition of TSH and stimulation of PRL release from the anterior pituitary.     

4-(O-Benzylphenoxy)-N-Methylbutylamine (Bifemelane) and Other 4-(O-Benzylphenoxy)-N-Methylalkylamines as New Inhibitors of Type A and B Monoamine Oxidase

4-(O-Benzylphenoxy)-N-methylbutylamine (Bifemelane, BP-N-methylbutylamine), a new psychotropic drug, was found to inhibit monoamine oxidase (MAO) in human brain synaptosomes. It inhibited type A MAO (MAO-A) competitively and type B (MAO-B) noncompetitively. BP-N-methylbutylamine had a much higher affinity to MAO-A than an amine substrate, kynuramine, and it was a more potent inhibitor of MAO-A than of MAO-B. The Ki values of MAO-A and -B were determined to be 4.20 and 46.0 microM, respectively, while the Km values of MAO-A and -B with kynuramine were 44.1 and 90.0 microM, respectively. The inhibition of MAO-A and -B by BP-N-methylbutylamine was found to be reversible by dialysis of the incubation mixture. MAO-A in human placental and liver mitochondria and in a rat clonal pheochromocytoma cell line, PC12h, was inhibited competitively by BP-N-methylbutylamine, while MAO-B in human liver mitochondria was inhibited noncompetitively, as in human brain synaptosomes. BP-N-methylbutylamine was not oxidized by MAO-A and -B. The effects of other BP-N-methylalkylamines, such as BP-N-methylethylamine, -propylamine, and -pentanylamine, on MAO activity were examined. BP-N-methylbutylamine was the most potent inhibitor of MAO-A, and BP-N-methylethylamine and -propylamine inhibited MAO-B competitively, whereas BP-N-methylbutylamine and -pentanylamine inhibited it noncompetitively. Inhibition of these BP-N-methylalkylamines on MAO-A and -B is discussed in relation to their chemical structure.     

Peripheral and CNS Effects of the Pineal Gland: Target Enzymes Common to Tissues and Species

The pineal gland is an important transducer mediating environmentalinfluences on endocrine organs. It has direct effects on thehypothalamus and pancreas and indirect effects on the pituitary,adrenal, thyroid, and testes. Thus, specific endocrine rhythmsare affected by alterations in trophic hormone secretion bythe hypothalamus-pituitary complex, direct effects on biochemicaltransformations within target organs, or by alterations in metabolismand excretion of hormones by the liver. Target enzymes commonto the above organs for melatonin and arginine vasotocin (AVT)are 5-reductase, monoamine oxidase (MAO), and smooth muscleenzymes. Melatonin selectively inhibited 17rß ol-dehydrogenaseactivity and 5-reductase activity while 17rß ol-dehydrogenasewas stimulated by serotonin (5-HT). Other steroid biotransformationswere inhibited by both 5-HT and melatonin. Evidence from thepancreas and insulin secretion, liver and glucuronosyl transferaseactivity, and hypothalamic and pituitary studies indicate thatmelatonin mediated some of its effects on these organs throughMAO activity and 5-HT levels. There were some species and tissuedifferences with respect to the effects of melatonin and AVTon MAO activity and steroid biotransformations. Melatonin stimulatedsteroid biotransformations in the duck, while MAO activity and5-reductase activity in the hamster responded differently tomelatonin than did similar preparations from the rat.