Irreversible inhibition of monoamine oxidase by some components of cigarette smoke

Inhibitory activity towards monoamine oxidase has been found in a solution of cigarette smoke. The inhibition was irreversible. When tissue slices of rat lung were incubated in the cigarette smoke solution or alternatively, exposed directly to cigarette smoke, monoamine oxidase activities were reduced drastically. Similarly, human saliva after cigarette smoking also exhibits considerable MAO inhibitory activity. When the amine substrates p-tyramine, serotonin and beta-phenylethylamine were incubated with the cigarette smoke solution, lipophilic adducts were formed non-enzymatically. The irreversible inhibition of MAO by cigarette smoke may well be related to the low platelet MAO associated with cigarette smokers as previously reported. The implication of such cigarette smoke-caused reduction of MAO activity in relation to Parkinsonism is discussed.     

Possible mechanism of selective inhibition of rat liver mitochondrial monoamine oxidase by chlorgiline and deprenyl]

The inhibition of the deamination of serotonin (the main substrate of monoamine oxidase (MAO) type A) by chlorgiline and deprenyl and of beta-phenylethylamine (the main substrate of the B type MAO) by fragments of rat liver mitochondrial membrane as well as the influence of 4-ethylpyridine on this process were studied. It was shown that the MAO activity of the mitochondrial membrane fragments was highly sensitive to chlorgiline, when serotonin was used as substrate, whereas a high sensitivity toward deprenyl was observed with beta-phenylethylamine as substrate. 4-Ethylpyridine (5.10(-3) M), a competitive and reversible inhibitor of the MAO activity, inhibited deamination of serotonin and beta-phenylethylamine by 34 and 30%, respectively. In experiments with chlorgiline (the specific inhibitor of MAO type A) 4-ethylpyridine (5.10(-3) M) introduced into the samples after preincubation of mitochondria with increasing concentrations of chlorgiline (30 min, 23 degrees C) decreased the inhibition by chlorgiline of the deamination of beta-phenylethylamine, but sharply increased the inhibitory effect of chlorgiline on the oxidation of serotonin. In analogous experiments with deprenyl (the specific inhibitor of MAO type B) 4-ethylpyridine (5.10(-3) M) decreased the inhibitory effect of deprenyl not only on the deamination of serotonin (substrate of MAO A), but also on the oxidation of beta-phenylethylamine (the main substrate of MAO type B). The decrease in the inhibitory effect of deprenyl on the deamination of beta-phenylethylamine after the addition of 4-ethylpyridine may be intensified upon preincubation of deprenyl with mitochondria in the presence of 4-ethylpyridine. The data obtained demonstrate the difference in the type and mechanism of inhibition of the deamination of serotonin by chlorgiline as well as in the type and mechanism of oxidation of beta-phenylethylamine by deprenyl. The possible mechanism of selective blocking of MAO activity by chlorgiline and deprenyl was discussed in terms of our previous data on the existence in the active center of mitochondrial MAO of specific sites for substrate binding, differing in their structure-functional characteristics.     

2-Naphthylamine, a compound found in cigarette smoke, decreases both monoamine oxidase A and B catalytic activity

Cigarette smokers exhibit a lower monoamine oxidase (MAO; EC 1.4.3.4) activity than nonsmokers. MAO is located in the outer membrane of mitochondria and exists as two isoenzymes, MAO A and B. MAO A prefers 5-hydroxytryptamine (serotonin), and MAO B prefers phenylethylamine (PEA) as substrate. Dopamine is a substrate for both forms. 2-Naphthylamine is a carcinogen found in high concentrations in cigarette smoke. The results of this study show that 2-naphthylamine has the ability to inhibit mouse brain MAO A and B in vitro by mixed type inhibition (competitive and non-competitive). The Ki for MAO A was determined to be 52.0 microM and for MAO B 40.2 microM. The inhibitory effect of 2-naphthylamine on both MAO A and B catalytic activity, supports the hypothesis that smoking decreases MAO activity in vivo, instead that smokers with lower MAO activity are more prone to become a smoker.     

Modulators of monoamine oxidase in plasma

Addition of small amounts of plasma activated the deamination of tryptamine by platelet monoamine oxidase (MAO). At higher concentrations, plasma inhibited the deamination instead. The inhibition was increased with increasing amounts of plasma added. The inhibition was uncompetitive in nature, partially reversed by prior ultrafiltration of the plasma through PM30 membranes and completely reversed by protein precipitation of plasma with perchloric acid. Addition of high amounts of plasma $\text{in}$$\text{vitro}$ also inhibited the activity of bovine striatal MAO. The inhibition of striatal deamination of tryptamine by plasma was noncompetitive in nature, completely reversed by ultrafiltration through PM30 membranes and partially reversed by perchloric acid treatment. The inhibition of striatal deamination of serotonin was noncompetitive in nature, not reversed by ultrafiltration but completely reversed by perchloric acid treatment. The pattern of inhibition of platelet or striatal MAO by plasma was different from that induced by addition of bovine serum albumin (BSA). Low concentrations of BSA added $\text{in}$$\text{vitro}$ activated the deamination of tryptamine or serotonin by platelet or striatal MAO by decreasing the K_m, while higher concentrations also decreased the V_max. The presence of protein, non-albumin circulating modulators of platelet or striatal MAO in plasma is discussed.     

Development of monoamine oxidase activity and monoamine effects on glutamate release in cerebellar neurons and astrocytes

Activities of monoamine oxidase (MAO) A and B were measured during the first month of postnatal development in mouse cerebellum and in primary cultures of either cerebellar granule cells or cerebellar astrocytes, derived from 7-day-old cerebella. In addition, effects of the two monoamines, serotonin (a MAO A substrate) and phenylethylamine (a MAO B substrate) on the release of glutamate under resting conditions and in a transmitter related fashion (i.e., potassium-induced, calcium-dependent glutamate release) were studied during the same period. Both MAO A and MAO B activities increased during in vivo development (beginning around postnatal day 14) and in cultured astrocytes (during a comparable time period and to a similar extent), but remained constant at a low level in granule cells. In 4-day-old cerebellar granule cell cultures there was no potassium-induced glutamate release but serotonin as well as phenylethylamine reduced the release in both the presence and absence of excess potassium. In 8- and 12-day-old granule cell cultures and in 8- and 18-day old astrocyte cultures there was a pronounced glutamate release during superfusion with 50 mM K⁺. In both neurons and astrocytes this response was inhibited by 1 nM of either serotonin or phenylethylamine. In the astrocytes the inhibition was followed by an increased release of glutamate in both the presence and absence of the high potassium concentration, whereas the 8-day-old neurons showed only a slight increase in glutamate release after the with-drawal of the monoamine and only in the absence of excess potassium. The response was almost identical in 8-and 18-day-old astrocytes in spite of the marked difference in MAO activities.Special issue dedicated to Dr. Paola S. Timiras.     

Inhibition of pancreatic islet monoamine oxidase by adrenergic antagonists and ethanol.

Although the alpha-adrenergic antagonist phentolamine potentiates glucose-stimulated insulin secretion of intact animals, it either does not alter, or it inhibits in vitro insulin secretion. This may be because in the higher concentration used in in vitro studies, phentolamine exerts a second pharmacological effect that counterbalances its primary effect of blocking monoamine action. We recently demonstrated that pancreatic islets contain substantial amounts of monoamine oxidase (MAO), and that MAO inhibitors such as iproniazid and tranylcypromine can alter insulin secretion. In the present study, we determined if other drugs that affect insulin secretion, alter the MAO activity of homogenates of rabbit pancreatic islets (collagenase technique) or liver. Phentolamine, phenoxybenzamine and propranolol (10 muM and 100 muM) inhibit islet and hepatic MAO. Haloperidol (10muM) inhibits hepatic but not islet MAO, while haloperidol (10muM) does not inhibit MAO in either tissue. Ethanol (270 to 2.7mM) inhibits islet MAO. Hepatic MAO is inhibited by high (270 to 180mM) but not by low (27 to 2.7mM) concentrations of ethanol. Collagenase digestion does not increase the sensitivity of islet and liver MAO to inhibition by phentolamine or ethanol. In the absence of added monoamines, phentolamine and phenoxybenzamine do not alter basal or glucose-stimulated insulin secretion from rabbit pancreas. Preincubation of rabbit pancreas with the serotonin precursor 5-hydroxytryptophan (5-HTP) increases the beta cell serotonin content and inhibits glucose-stimulated insulin secretion. Alpha adrenergic antagonists not only fail to block, but actually potentiate the serotonin inhibition of insulin secretion. We conclude that inhibition of islet MAO may cause an increase in islet monoamine content and these monoamines may alter in vitro insulin secretion. One mechanism through which adrenergic antagonists and ethanol modify in vitro insulin secretion may be by inhibiting pancreatic islet MAO.     

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.     

Specificity of endogenous substrates for types A and B monoamine oxidase in rat striatum

Abstract: Studies were designed to evaluate specificity of the transmitter amines serotonin (5-hydroxytryptamine, 5-HT) and dopamine (DA), as well as the trace amines p -tyramine ( p -TA) and β -phenylethylamine (PEA) for types A and B monoamine oxidase (MAO) in rat striatum. 5-HT was found to be a specific substrate for the type A enzyme. However, the specificity of PEA for the type B enzyme was found to be concentration-dependent. When low concentrations of PEA and 5-HT were used to measure type B and type A activities, respectively, both clorgyline and deprenyl were highly selective for the sensitive form of MAO in vivo. However, as the concentration of PEA was increased, the type B inhibitor deprenyl became less effective in preventing deamination of PEA. Conversely, the type A inhibitor clorgyline became more effective in this regard. Kinetic analysis following selective in vivo inhibition showed PEA deamination by both forms of MAO with a 13-fold greater affinity for the type B enzyme. In vivo dose-response curves obtained with the common substrates DA and p -TA showed approximately 20% deamination by the B enzyme. Kinetic values for DA and p -TA deamination in in vivo -treated tissue possessing only type A or type B MAO activity, revealed a 2.5-fold greater affinity for the type A enzyme. These studies show the importance of concentration on substrate specificity in striatal tissue. The results obtained characterize the common substrate properties of DA and p -TA as well as of PEA in rat striatum. In addition, the presence of regional specificity for 5-HT deamination by only type A MAO is demonstrated.     

On the characteristics of mitochondrial monoamine oxidase in pancreas and adipose tissues from genetically obese mice.

The substrate specificity of mitochondrial monoamine oxidase (MAO) in pancreatic and adipose tissues of obese mice and their lean counterparts was determined. The pancreatic MAO of obese mice had a greater specific activity than that of the lean mice. The white adipose tissue MAO was found to be more active than the brown adipose MAO in both groups of mice. While there was no appreciable difference in the MAO activities of brown adipose tissues between obese and lean mice, the enzyme from the white adipose tissue of obese mice had a higher specific activity than that of the lean mice. The higher MAO activity in white adipose tissue was observed when tyramine or serotonin was employed as substrate but not with benzylamine. Examination of mitochondrial MAO from epididymal adipocytes revealed marked differences in the properties of the enzyme between whole adipose tissue and isolated adipocytes. The inhibition characteristics of MAO from these tissues were studied with the specific inhibitors clorgyline and deprenyl.     

Effect of adafenoxate on different rat brain structures monoamine oxidase activity in vitro

1. The effect of the nootropic drug adafenoxate on monoamine oxidase (MAO) activity in rat brain cortex, striatum, hypothalamus and hippocampus has been studied using the following substrates: tyramine (total MAO), serotonin (MAO A) and beta-phenylethylamine (MAO B). 2. In a series of increased concentrations (from 5 x 10(-4) up to 1 x 10(-5) M) adafenoxate inhibits total MAO, MAO A and MAO B in the brain structures studied. 3. The adafenoxate IC50 values obtained illustrate its inhibitory properties and its lack of selectivity toward MAO in the brain structures isolated. 4. The results of our research prove the participation of MAO in the mechanisms through which adafenoxate affects the brain monoaminergic systems and realises its central effects.     

Chlorphentermine inhibits pulmonary mitochondrial monoamine oxidase

Oxidation of six amine substrates by rat, rabbit and guinea-pig lung mitochondrial monoamine oxidase (MAO) was investigated polarographically with a Clark oxygen electrode in the presence of chlorphentermine (CP). This amphiphilic drug decreased the deamination of serotonin, norepinephrine, tyramine and dopamine significantly in all three species. However, the oxidation of tryptamine and benzylamine was unchanged. Amine oxidation by MAO in guinea-pig lung mitochondria was much more sensitive to the CP-mediated inhibition than rat or rabbit. A kinetic study of serotonin oxidation in the absence and presence of CP showed that both Vmax and Km were affected. These combined data indicate that CP is a specific inhibitor of pulmonary, mitochondrial monoamine oxidase form A with mixed-type inhibition.     

Some parameters affecting the activity of monoamine oxidase in purified bovine brain mitochondria.

Abstract— Some parameters affecting the activity of monoamine oxidase (MAO) in purified beef brain mitochondria were investigated, and diversities in enzyme properties were found as a function of substrate. The deamination of the biogenic amines: serotonin, dopamine, tyramine, tryptamine, phenylethylamine and two non-physiological amines, kynuramine and m-iodobenzylamine, was studied. Anions in high concentrations inhibited enzyme activity with kynuramine being the substrate most affected. Among the biogenic amines, the activity with the indolalkylamines showed greater sensitivity to mono-valent anions such as chloride than to polyvalent ions such as phosphate whereas the opposite was true with the phenylalkylamines. However, pyrophosphate ion had little or no effect on MAO activity, regardless of substrate. The inhibition of kynuramine and serotonin deamination was non-competitive but mixed competitive inhibition was found with tyramine and phenylethylamine. The activity of MAO was markedly affected by pH, and it had been previously reported that the substrates showed different pH optima in their oxidation. The effect of pH on activity has been attributed in part to changes in the ionization of the substrate and the hypothesis that the true substrate is the non-protonated amine. This was reflected in kinetic studies showing high substrate inhibition with increased pH. It was calculated that phenylethylamine would have the highest percentage of un-ionized amine at pH 8.2 and 9.1. At these pHs, there was more pronounced inhibition with high substrate concentrations of phenylethylamine than with the other substrates. In contrast, there was little inhibition with high substrate concentrations of tyramine which was the most ionizable of the substrates tested. When K_m values obtained at pH 7.4, 8.2 and 9.1 were corrected for ionization of the substrate, the corrected K_m was lowest at pH 7.4 for all substrates. Less than 50% of MAO activity was lost when beef brain mitochondria was heated at 50°C for 20 min. However, there was only a slight variation with substrate in the thermal inactivation experiments. It is concluded that the mitochondrial membrane environment surrounding the enzyme imposes certain restrictions on the enzymatic activity with respect to the different substrates which, in turn, are also affected by such parameters as pH and ions. The results are discussed in terms of the relationship of these factors to the question of enzyme multiplicity.     

Inhibition of monoamine oxidase activity by antidepressants and mood stabilizers

OBJECTIVE: Monoamine oxidase (MAO), the enzyme responsible for metabolism of monoamine neurotransmitters, has an important role in the brain development and function, and MAO inhibitors have a range of potential therapeutic uses. We investigated systematically in vitro effects of pharmacologically different antidepressants and mood stabilizers on MAO activity. Methods: Effects of drugs on the activity of MAO were measured in crude mitochondrial fraction isolated from cortex of pig brain, when radiolabeled serotonin (for MAO-A) or phenylethylamine (for MAO-B) was used as substrate. The several antidepressants and mood stabilizers were compared with effects of well known MAO inhibitors such as moclobemide, iproniazid, pargyline, and clorgyline. Results: In general, the effect of tested drugs was found to be inhibitory. The half maximal inhibitory concentration, parameters of enzyme kinetic, and mechanism of inhibition were determined. MAO-A was inhibited by the following drugs: pargyline > clorgyline > iproniazid > fluoxetine > desipramine > amitriptyline > imipramine > citalopram > venlafaxine > reboxetine > olanzapine > mirtazapine > tianeptine > moclobemide, cocaine > lithium, valproate. MAO-B was inhibited by the following drugs: pargyline > clorgyline > iproniazid > fluoxetine > venlafaxine > amitriptyline > olanzapine > citalopram > desipramine > reboxetine > imipramine > tianeptine > mirtazapine, cocaine > moclobemide, lithium, valproate. The mechanism of inhibition of MAOs by several antidepressants was found various. Conclusions: It was concluded that MAO activity is acutely affected by pharmacologically different antidepressants at relatively high drug concentrations; this effect is inhibitory. There are differences both in inhibitory potency and in mechanism of inhibition between both several drugs and the two MAO isoforms. While MAO inhibition is not primary biochemical effect related to their therapeutic action, it can be supposed that decrease of MAO activity may be concerned in some effects of these drugs on serotonergic, noradrenergic, and dopaminergic neurotransmission.     

Different effects of monoamine oxidase inhibition on MPTP depletion of heart and brain catecholamines in mice

Pargyline, an inhibitor of monoamine oxidase type B (MAO-B), did not prevent the depletion of heart norepinephrine 24 hr after a single dose of MPTP (1-methyl-4-phenyl-1,2,3,6-tetrahydropyridine) in mice. In mice killed 24 hr after the last of 4 daily doses of MPTP, the depletion of dopamine in the striatum and of norepinephrine in the frontal cortex was completely prevented by pargyline, but the depletion of heart norepinephrine was not prevented. These results with pargyline are the same as results obtained earlier with deprenyl, another selective inhibitor of MAO-B. The doses of pargyline and of deprenyl that were used resulted in almost complete inhibition of MAO-B activity (phenylethylamine as substrate) in brain, heart and liver of mice. Deprenyl did not inhibit MAO-A activity (serotonin as substrate) in brain, but pargyline caused some inhibition of MAO-A in brain. In heart and liver, serotonin was oxidized only at about 1/10 the rate of phenylethylamine oxidation, suggesting that MAO-B predominates in these tissues. Both pargyline and deprenyl caused some inhibition of serotonin deamination in heart and liver, suggesting that the oxidation may have been due partly to MAO-B. Experiments with selective MAO inhibitors in vitro showed that only about 20% of the oxidation of serotonin was occurring via MAO-B in heart and liver. The in vitro oxidation of MPTP by MAO in mouse brain, heart and liver was almost completely inhibited by pretreatment with either pargyline or deprenyl. Neither pargyline nor deprenyl had any significant effect on the concentrations of MPTP in brain or heart one-half hr after injection of MPTP into mice. The concentrations of the metabolite, MPP+ (1-methyl-4-phenyl-pyridinium), were markedly reduced in brain and in heart by pretreatment with either pargyline or deprenyl. The data suggest that MPP+ formation, which is necessary for the depletion of brain catecholamines after MPTP injection, may not be necessary for depletion of norepinephrine in heart. Since the oxidation of MPTP in vitro was inhibited more by pargyline or deprenyl pretreatment than was the appearance of MPP+ in vivo, the possibility exists that some MPP+ formation might occur by an enzyme other than MAO.     

Multiple catalytic sites of rat brain mitochondrial monoamine oxidase

We compared the inhibitory and catalytic effects of various monoamines on forms A and B of monoamine oxidase (MAO) on mitochondrial preparations from rat brain in mixed substrate experiments. MAO activity was determined by a radioisotopic assay. MAO showed lower K_m values for tryptamine and β-phenylethylamine than for tyramine and serotonin. The K_m values of the untreated preparation for tyramine, tryptamine, and β-phenylethylamine obtained were the same as those of the form B enzyme and the K_m value for serotonin was the same as that of the form A enzyme. Tyramine and tryptamine were competitive inhibitors of serotonin oxidation and β-phenylethylamine did not bind with form A enzyme or inhibit the oxidation of serotonin, while tyramine and tryptamine were competitive inhibitors of β-phenylethylamine oxidation. Although serotonin was not oxidized by form B enzyme, serotonin was a competitive inhibitor of β-phenylethylamine oxidation. It is suggested that rat brain mitochondrial MAO is characterized by two kinds of binding sites.     

Brain monoamine oxidase in schizophrenia

The content of SH-groups and substrate specificity have been studied in purified preparations of monoamine oxidase (MAO) from human brain. It has been shown that both in schizophrenic and mentally normal persons MAO occurs in a partially oxidized state. The enzyme contains 2 SH-groups per 10(5) daltons of protein and deaminates MAO substrates (serotonin, beta-phenylethylamine) along with histamine, diamine oxidase substrate. Reduction of the partially oxidized SH-groups of MAO in schizophrenics up to 15 SH-groups per 10(5) daltons of protein (the normal value for human brain MAO) does not eliminate the histamine deaminase activity as is the case in experiments with MAO from the normal brain but, on the contrary, considerably potentiates it. The data suggest certain structural alteration of MAO in schizophrenia.     

Low platelet monoamine oxidase activity and chronic marijuana use

Mean platelet monoamine oxidase (MAO) activity in 26 consecutively-studied male marijuana smokers was significantly lower than in a comparable group of non-marijuana smoking males. In addition, the level of current marijuana use reported by the subjects was significantly and inversely correlated with MAO activity. No acute reduction in MAO activity was found in response to smoking a marijuana cigarette containing 15 mg of delta-9-THC. Significant $\text{in vitro}$ inhibition of MAO activity by THC was detected only at THC concentrations above 10^?5M, approximately 100 times the peak plasma concentrations seen $\text{in vivo}$ following smoking.     

Phenylethanolamine is a specific substrate for type B monoamine oxidase

The characteristics of phenylethanolamine as both a competitive inhibitor and as a substrate for monoamine oxidase (MAO) were studied using rat brain and liver homogenates. Although phenylethanolamine, even at high concentrations (1 mM), produced minimal inhibition of MAO when serotonin (a substrate for type A MAO) was used as the substrate, it was a potent competitive inhibitor (K_i=11 μM) of the deamination of phenylethylamine (a substrate for type B MAO). When phenylethanolamine was used as a substrate, deprenyl, a selective inhibitor of type B MAO, was found to produce a single sigmoid inhibition curve at low concentrations of the inhibitor (pI₅₀=7.5). These results indicate that phenylethanolamine is a specific substrate for type B MAO. Identification of the products formed under the assay conditions show that phenylethanolamine is converted to both mandelic acid and phenylethylene glycol by liver homogenates but only to the latter, neutral metabolite by brain homogenates.     

Localization of rat striatal monoamine oxidase activities towards dopamine,serotonin and kynuramine by gradient centrifugation and nigro-striatal lesions

Subfractionation of the crude synaptosomal-mitochondrial fraction of rat striatum in a continuous sucrose gradient in a zonal rotor led to the following results. The distribution pattern of monoamine oxidase (MAO) activity towards dopamine (DA) was very similar to the pattern of MAO activity towards serotonin (5HT), but differed from the pattern of MAO activity towards kynuramine (KYN). As 5HT is specifically deaminated by MAO-A while KYN is a common MAO substrate, this supports earlier suggestions that in rat striatal preparations DA is deaminated preferentially by MAO-A. The patterns of the MAO activities towards DA and 5HT were clearly dissimilar, despite considerable overlap, to the patterns of tyrosine hydroxylase (TH) and DOPA decarboxylase (DD) activity, both marking the presence of striatal dopaminergic synaptosomes. The peak activities were separated and all patterns were symmetrical without showing a shoulder. This indicates that rat striatal MAO activity towards DA and 5HT is not specifically or for the greater part localized in dopaminergic terminals. We also investigated the effects of electrolytic and 6-hydroxydopamine lesions of the substantia nigra, both causing extensive degeneration of striatal dopaminergic terminals as appeared from the large decrease of striatal TH and DD activity. However, neither type of lesion induced a reduction of the MAO activity towards any of the substrates used. It is concluded towards DA and 5HT (probably MAO-A activity) present in dopaminergic terminals is very low compared with the total activity of this enzyme in rat striatal tissue.     

Calcium disodium edetate enhances type A monoamine oxidase activity in monkey brain

The effects of metal chelators on monoamine oxidase (MAO) isozymes, MAO-A and MAO-B, in monkey brain mitochondria were investigated in vitro. MAO-A activity increased to about 40% with 0.1 μM calcium disodium edetate (CaNa₂EDTA) using serotonin as a substrate, and this activation was proportional to the concentration of CaNa₂EDTA. On the other hand, MAO-A activities were decreased gradually with an increasing concentration of o-phenanthroline and diethyldithiocarbamic acid, but these metal chelators had no effect on MAO-B activity in monkey brain. The activation of MAO-A activity by CaNa₂EDTA was reversible. CaNa₂EDTA did not activate both MAO-A and MAO-B activities in rat brain mitochondria. Zn and Fe ions were found in the mitochondria of monkey brain. Zn ions potently inhibited MAO-A activity, but Fe ions did not inhibit either MAO-A or MAO-B activity in monkey brain mitochondria. These results indicate that the activating action of CaNa₂EDTA on MAO-A was the result of the chelating of Zn ions contained in mitochondria by CaNa₂EDTA. These results also indicate the possibility that Zn ions may regulate physiologically the level of serotonin and norepinephrine content in brain by inhibiting a MAO-A activity.