Effect of protein denaturing reactions on retardation of the activity of rat liver mitochondrial monoamine oxidase by clorgyline and deprenyl

The denaturating effects of urea on clorgyline-produced inhibition of serotonin and tyramine deamination and deprenyl-produced inhibition of beta-phenylethylamine and tyramine oxidation were studied. It was shown that after preincubation of mitochondria with 1 and 2 M urea the intensity of inhibition by clorgyline and deprenyl of oxidation of these amines was not changed. With urea concentration of 3 and 4 M the inhibitory effect of clorgyline on deamination of serotonin and tyramine was increased, while that of deprenyl on oxidation of beta-phenylethylamine and tyramine was decreased. As a result of mitochondria treatment with 3 and 4 M urea the selectivity in inhibition by clorgyline of serotonin and tyramine deamination typical for intact mitochondria was reduced in the case of 3 M urea and eliminated in the case of 4 M urea. In intact mitochondria the intensity of inhibition by clorgyline of tyramine deamination in the presence of benzyl alcohol (competitive reversible MAO inhibitor) was increased, but the additive effect was not achieved. However, after preincubation of mitochondria with 3 M urea the summation of the inhibitory effects of clorgyline and benzyl alcohol was observed. The data obtained provide further evidence for the important role of spatial configuration of the monoamine oxidase molecule; the data are discussed in terms of arrangement on the protein molecule surface of the essential groups involved in the binding and deamination of amines for the inhibitory effects of clorgyline and deprenyl.     

Mechanism of inhibition by chlorgyline and deprenyl of tyramine deamination by mitochondrial monoamine oxidase of rat liver

The inhibition by chlorgyline and deprenyl of deamination of tyramine, i. e. substrate of two forms of monoamine oxidase (MAO) A and B, by fragments of rat liver mitochondrial membrane and the effects of competitive reversible inhibitors of the MAO activity, e. g. 4-ethylpyridine, benzyl alcohol, O-benzyl-hydroxylamine and 2-oxyquinoline, on this process were studied. It was shown that all the inhibitors used sharply increase the inhibiting effect of chlorgyline on tyramine deamination, the degree of the stimulating effect being the same irrespective of whether the inhibitors are added to the samples before or after a 30-min preincubation of chlorgyline with the enzyme at 23 degrees, i. e. after the onset of irreversible inhibition. The stimulating effect is due to the independent action of two inhibitors on the two different sites of the MAO active center: chlorgyline--on the isoalloxazine ring of FAD, that of 4-ethylpyridine, benzyl alcohol, O-benzylhydroxylamine, 2-oxyquinoline, respectively, on the hydrophobic region involved in tyramine binding. In similar experiments with deprenyl all the competitive inhibitors used, when added to the samples after a 30-min incubation of the inhibitor with the enzyme at 23 degrees, remove the inhibiting effect of deprenyl on tyramine deamination. The decrease of the inhibiting effect of deprenyl is indicative of an existence of competitive interactions between deprenyl and the above-mentioned compounds and of the reversible inhibition by deprenyl of tyramine deamination under the given experimental conditions. The data obtained revealed the differences in the type and mechanism of action of chlorgyline and deprenyl on tyramine deamination and showed that these inhibitors act on different sites of the MAO active center, responsible for tyramine oxidation. Chlorgyline blocks primarily the "flavin moiety" of the MAO molecule, essential for the catalytic act, while the effect of deprenyl is directed to the hydrophobic part of the enzyme active center essential for the enzyme binding to tyramine. In this case the irreversible inhibiting effect is achieved at a slower rate and the reversibility of tyramine oxidation by deprenyl is maintained for a longer period of time than the chlorgyline inhibition of deamination of this amine.     

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.     

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.     

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.     

Substrate and inhibitor specificities for human monoamine oxidase A and B are influenced by a single amino acid

Monoamine oxidase (MAO) is responsible for the oxidation of biogenic and dietary amines. It exists as two isoforms, A and B, which have a 70% amino acid identity and different substrate and inhibitor specificities. This study reports the identification of residues responsible for conferring this specificity in human MAO A and B. Using site-directed mutagenesis we reciprocally interchanged three pairs of corresponding nonconserved amino acids within the central portion of human MAO. Mutant MAO A-I335Y became like MAO B, which exhibits a higher preference for beta-phenylethylamine than for the MAO A preferred substrate serotonin (5-hydroxytryptamine), and became more sensitive to deprenyl (MAO B-specific inhibitor) than to clorgyline (MAO A-specific inhibitor). The reciprocal mutant MAO B-Y326I exhibited an increased preference for 5-hydroxytryptamine, a decreased preference for beta-phenylethylamine, and, similar to MAO A, was more sensitive to clorgyline than to deprenyl. These mutants also showed a distinct shift in sensitivity for the MAO A- and B-selective inhibitors Ro 41-1049 and Ro 16-6491. Mutant pair MAO A-T245I and MAO B-I236T and mutant pair MAO A-D328G and MAO B-G319D reduced catalytic activity but did not alter specificity. Our results indicate that Ile-335 in MAO A and Tyr-326 in MAO B play a critical role in determining substrate and inhibitor specificities in human MAO A and B.     

Comparative substrate-inhibitor analysis of liver monoamine oxidases of minks

Comparative substrate-inhibitor analysis of catalytic properties of liver monoamine oxidases (MAO) was performed in the mature males of the American mink Mustela vison and the European mink Mustela lutreola. The action on the MAO activity was studied of alkaloids of the benzo[c]phenanthridine group: sanguinarine and chelidonine, diisoquinoline alkaloid berberine, medication agents Ukrain and Sanguirythrin as well as derivatives of 2-propylamine: deprenyl and clorgylin. The latter turned out to be irreversible inhibitor of the MAO A form, whereas deprehyl--irreversible inhibitor of the MAO B form in both studied mink species. The selectivity of action of each inhibitor on the corresponding liver MAO form for the species M. vison was one order of magnitude stronger than for the species M. lutreola. All studied alkaloids as well medication agents on their basis have been shown to be specific irreversible inhibitors of the intermediate strength of the liver MAO A form of both mink species. They inhibit the enzymatic deamination of serotonin, tyramine, and tryptamine without affecting the deamination reaction of benzylamine and beta-phenylethylamine (at concentrations of 10 mM and lower). Out of the studied five isoquinoline agents, the medication Ukrain and alkaloid chelidonine have the highest inhibitory action; the agent Sanguirythrin and alkaloids berberine and sanguinarine produce the weaker monoamine oxidase effect. The revealed specificity of action of the studied inhibitors is an indirect evidence for the presence in the liver enzymes of both mink species, like in the rat liver enzyme, of several molecular forms.     

Brain region differences and some characteristics of monoamine oxidase type a and b activities in the vervet monkey

Monoamine oxidase in the vervet monkey showed greater variations in activity in six brain regions when tyramine or phenylethylamine was used as the substrate (3.8- to 4.1-fold differences) than when serotonin was the substrate (1.8-fold differences). With phenylethylamine and tyramine as substrates, the highest MAO specific activities were found in the hypothalamus and the lowest in the cerebellum and cortex. With serotonin as the substrate, the highest specific activities were in the mesencephalon and cortex. The inhibition of tyramine deamination by clorgyline and deprenyl yielded biphasic plots indicative of the presence of MAO-A and MAO-B enzyme forms in the vervet brain. On the basis of these inhibitor curves, the vervet brain could be estimated to contain approximately 85% MAO-B and 15% MAO-A, in contrast to rat brain which contains 45% MAO-B and 55% MAO-A. The inhibition of serotonin deamination by deprenyl in vervet brain yielded a biphasic plot, suggesting that some serotonin deamination in the vervet is accomplished by the MAO-B enzyme form. Estimations of the relative amounts of MAO-A and MAO-B based on inhibitor curves or based on substrate ratios yielded proportionate results which were in close agreement across the different brain regions, supporting the validity of these approaches to estimating MAO-A and MAO-B activities.     

Substrate-inhibitory analysis of monoamine oxidase from hepatopancreas of the octopus <Emphasis Type="Italic">Bathypolypus arcticus</Emphasis>

Study of the substrate-inhibitory specificity of mitochondrial monoamine oxidase (MAO) of hepatopancreas of the octopus Bathypolypus arcticus revealed distinctive peculiarities of catalytic properties of this enzyme. The studied enzyme, on one hand, like the classic MAO of homoiothermal animals, is able to deaminate tyramine, serotonin, benzylamine, tryptamine, b-phenylethylamine, while, on the other hand, it deaminates histamine and does not deaminate putrescine-classic substrates of diamine oxidase (DAO). Results of the substrate-inhibitory analysis with use of chlorgiline and deprenyl are indirect proofs for the existence in the octopus hepatopancreas of one molecular MAO form. Semicarbazide and pyronine G turned out to be weak irreversible inhibitors, four derivatives of acridine-irreversible inhibitors of the intermediate effectiveness with respect to the octopus hepatopancreas MAO; specificity of action of inhibitors at deamination of different substrates was equal.     

Modification of substrate-inhibitor affinities of human platelet monoamine oxidase B in vitro

The rate of benzylamine utilization by monoamine oxidase (MAO)-B from human blood platelets was 2-4 times higher than that for octopamine. Both activities were inhibited 100% by 10(-7) M deprenyl (a specific MAO-B inhibitor) and were not affected by clorgyline (a specific MAO-A inhibitor) or by polyclonal antibodies to MAO-A. The preincubation of platelet MAO-B with purified MAO-A from mitochondrial membranes of human placenta resulted in appearance of excess octopamine activity. This additional activity was not precipitated by antibodies to MAO-A or inhibited by deprenyl but was inhibited by clorgyline. Incubation of the MAO-A preparation from placenta at 45 degrees C for 15 min before its preincubation with MAO-B caused 50% loss of both activities. Protease inhibitors had no effect on the modification of MAO. These data indicate that MAO-A or a factor tightly bound to it can modify MAO-B yielding a form of the enzyme with both MAO-A and MAO-B substrate and inhibitor affinities and MAO-B immunospecificity.     

Substrate Selectivity of Type A and Type B Monoamine Oxidase in Rat Brain

Abstract: Use of the irreversible inhibitors clorgyline and deprenyl showed that rat brain mitochondria contain type A and type B monoamine oxidase (MAO). Tyramine is a substrate for both types of MAO, whereas serotonin is a preferential substrate for type A MAO. In contrast to MAO in other tissues, type A MAO in brain tissue oxidizes β-phenylethylamine (PEA) at high concentrations (0.5 and 1.0 mM). The proportions of type A and type B MAO activities in the mitochondria estimated from the double-sigmoidal inhibition curves of tyramine oxidation were about 70:30 irrespective of the concentration of tyramine. With PEA as substrate, the ratios of type A to type B activities were found to increase from low values at low concentrations to about 1 at 0.5-1.0 mM-PEA, and even higher at further increased concentrations of PEA. At very low (0.01 mM) and high (10.0 mM) concentrations of PEA, single-sigmoidal curves were obtained; with the high PEA concentration the activity was highly sensitive to clorgyline, whereas with the low concentration it was highly sensitive to deprenyl. In deprenyl-pretreated mitochondrial preparations, all the remaining activity towards 0.5-1.0 mM-PEA was shown to be highly sensitive to clorgyline, demonstrating that this activity was indeed due to oxidation by type A MAO. The opposite result was obtained with deprenyl as inhibitor of clorgyline-pretreated preparations, demonstrating that PEA at this concentration was also oxidized by type B MAO in rat brain mitochondria. The K₃ values of type A and type B MAO for PEA were significantly different. On Lineweaver-Burk analysis, plots with PEA as substrate for type A MAO in a deprenyl-treated preparation were linear over a wide concentration range, whereas those for type B MAO in a clorgyline-treated preparation were not linear, but showed substrate inhibition at higher concentrations of the substrate. It is concluded from the present findings that the effect of the substrate concentration must be considered in studies on the characteristics of multiple forms of MAO in various organs and species.     

Enzymologic characteristics of monoamine oxidase from liver of the skipjack tuna Katsuwonus pelamis

Substrate and inhibitory specificity of mitochondrial monoamine oxidase (MAO) from liver of skipjack tuna Katsuwonus pelamis was studied. The results of substrate—inhibitory analysis with application of chlorgilin and deprenyl might be indirect proofs of existence of one molecular MAO form in the tuna liver. Studied enzyme, as liver MAO of terrestrial mammals, deaminates tyramine, tryptamine, dopamine, serotonin, noradrenalin, benzylamine, β-phenylethylamine, N-methylhistamine and does not deaminate histamine, is not suppressed by 10 mM semicarbazide. Takrin, acriflavin, proflavin, acridine orange and pyronine G were established to be irreversible inhibitors of middle strength in respect to MAO of tuna liver. The specificity of inhibitors action upon deamination of various substrates was equal.     

Catalytical properties of liver monoamine oxidases of the Commander squid <Emphasis Type="Italic">Berryteuthis magister</Emphasis> from various habitation zones

There has been performed kinetic analysis of enzymatic reactions of deamination of tyramine, tryptamine, serotonin, benzylamine, β-phenylethylamine, and histamine under action of liver monoamine oxidase (MAO) of the Commander squid Berryteuthis magister from various habitation zones in the Bering and Japan Seas. A substrate inhibition by high concentrations of all studied substrates has been revealed, which seems to indicate mutual effect of various MAO forms present in liver of the studied squids. Analysis of kinetic parameters of enzymatic reactions of deamination of six studied substrates and the substrate-inhibitory analysis with use of two derivatives of acridine and deprenyl indicate the enzyme heterogeneity, the presence of at least two MAO-A forms, and the absence of intraspecies differences in MAO of the Commander squids from various habitation zones. The most active was the MAO form responsible for serotonin deamination. There were obtained quantitative difference in substrate specificity and reaction ability with respect to inhibitor of proflavin for the liver MAO of the Commander and Pacific squids.     

Guinea Pig Striatum as a Model of Human Dopamine Deamination: The Role of Monoamine Oxidase Isozyme Ratio, Localization, and Affinity for Substrate in Synaptic Dopamine Metabolism

The kinetic properties of type A and type B monoamine oxidase (MAO) were examined in guinea pig striatum, rat striatum, and autopsied human caudate nucleus using 3,4-dihydroxyphenylethylamine (dopamine, DA) as the substrate. MAO isozyme ratio in guinea pig striatum (28% type A/72% type B) was similar to that in human caudate nucleus (25% type A/75% type B) but different from that in rat striatum (76% type A/24% type B). Additional similarities between guinea pig striatum and human caudate nucleus were demonstrated for the affinity constants (Km) of each MAO) isozyme toward DA. Endogenous concentrations of DA, 3-methoxytyramine, 3,4-dihydroxyphenylacetic acid, and homovanillic acid were also measured in guinea pig and rat striatum following selective type A (clorgyline-treated) and type B (deprenyl-treated) MAO inhibition. In guinea pig, DA metabolism was equally but only partially affected by clorgyline or deprenyl alone. Combined treatment with clorgyline and deprenyl was required for maximal alterations in DA metabolism. By contrast, DA metabolism in rat striatum was extensively altered by clorgyline but unaffected by deprenyl alone. Finally, the deamination of DA in synaptosomes from guinea pig striatum was examined following selective MAO isozyme inhibition. Neither clorgyline nor deprenyl alone reduced synaptosomal DA deamination. However, clorgyline and deprenyl together reduced DA deamination by 94%. These results suggest that the isozyme localization and/or isozyme affinity for DA, rather than the absolute isozyme content, determines the relative importance of type A and type B MAO in synaptic DA deamination. Moreover, based on the enzyme kinetic properties of each MAO isozyme, guinea pig striatum may serve as a suitable model of human DA deamination.     

Monoamine Oxidase Activity in the Hepatopancreas of the Kamchatka Crab <Emphasis Type="Italic">Paralithodes camtschaticus</Emphasis>: a Substrate–Inhibitor Specificity

A study of substrate–inhibitor specificity of mitochondrial monoamine oxidase (MAO) in the hepatopancreas of the adult Kamchatka crab Paralithodes camtschaticus revealed specific catalytic properties of the enzyme. On the one hand, crab hepatopancreas MAO, like its classical hepatic counterpart, can deaminate tyramine, tryptamine, dopamine, serotonin, noradrenalin, benzylamine, β-phenylethylamine and N-methylhistamine but shows no sensitivity to 10 mM semicarbazide. On the other hand, MAO deaminates histamine but not putrescine, two classical diamine oxidase (DAO) substrates. It was established that MAO activity was several times higher toward benzylamine, β-phenylethylamine and N-methylhistamine than toward serotonin and noradrenalin. MAO was also found to be almost 500 times more sensitive to its selective inhibitor deprenyl than to chlorogilyn. A substrate–inhibitory analysis with the use of deprenyl and chloroginyl provides an indirect evidence for the existence of a sole MAO molecular form in the Kamchatka crab hepatopancreas.     

Some properties of monoamine oxidase in carp heart

Studies using clorgyline, deprenyl and semicarbazide as inhibitors showed that carp heart homogenate contained a new type of monoamine oxidase (MAO) and a clorgyline- and deprenyl-resistant amine oxidase (CRAO). The deamination of monoamines by carp heart MAO proceeded in two steps by a double-displacement (ping-pong) mechanism. The Km values of the MAO for oxygen (K0 values) with tyramine, 5-hydroxytryptamine (5-HT) and beta-phenylethylamine (PEA) as substrates were identical (59 microM).     

NONEXISTENCE OF A TYPE C MONOAMINE OXIDASE IN RAT BRAIN

Abstract— The possible existence of type C MAO, distinct from type A and type B, in circumventricular structures of rat brain was examined by histological studies on the inhibitory effects of clorgyline. a preferential type A MAO inhibitor and deprenyl, a preferential type B inhibitor, on enzyme. Brain slices were preincubated with the inhibitors and then incubated with 5-HT, the substrate for type A MAO, and stained for MAO activity. Deposits of the product formazan were detected in circumventricular structures of slices of brain preincubated with clorgyline and deprenyl at concentrations of 10^-7–10^-4m at room temperature for 5 min. When the slices were preincubated with either of these inhibitors at room temperature for 60 min, strong activity was observed in this region, whereas when they were preincubated with either 10^-5m -clorgyline or 10^-5m -deprenyl for 20 and 30 min at 37°C, no MAO activity was seen in any region of the brain. Thus, at the higher preincubation temperature, lower concentrations of each inhibitor and a shorter preincubation period were required for inhibition of the enzyme. Preincubation for 60 min at 37°C with a combination of 10^-7m -clorgyline and 10^-8m -deprenyl did not inhibit the enzyme in the circumventricular region completely, but at the same temperature, concentrations of 10^-7m of both inhibitors inhibited the enzyme completely in 10min, Thus the effects of the inhibitors are synergistic. These results indicate that the inhibitory effects of the two inhibitors on the enzyme in circumventricular structures of the brain is time- and temperature-dependent. Moreover, the activity seems to be sensitive to deprenyl even when 5-HT is used as substrate. The results do not support the idea of the existence of type C MAO, distinct from type A and type B MAO.     

Reactivity of liver monoamine oxidase in the seal Phoca hispida ladogensis

The goal of this work consisted in substrate and inhibitor specificity of liver monoamine oxidase (MAO) of the freshwater Ladoga subspecies of the ringed seal Phoca hispida ladogensis. The studied enzyme has been found to have the large substrate specificity by deaminating, apart from eight classic substrates of the terrestrial mammalian MAO, also histamine, the substrate of diamino oxidase. It has been revealed that the studied enzyme realizes wide substrate specificity by deaminating, apart from eight classic MAO substrates of terrestrial mammals, also histamine, the substrate of diamino oxidase. The deamination rates of benzylamine, β-phenylethylamine, and N-methylhistamine are found to be almost by one order higher than the deamination rates of serotonin and noradrenaline. The seal liver MAO did not deaminate putrescine and cadaverine and was insensitive to 10^?2 M semicarbaside. There were calculated bimolecular rate constants of interaction of inhibitors: chlorgyline, deprenyl, berberine, sanguinarine, chelidonine, and four derivatives of acridine with the enzyme at deamination of nine substrates. By the method of substrate-inhibitor analysis we have shown heterogeneity of the enzyme, i.e., the presence in the seal liver of at least of two different MAO.     

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.     

Human brain monoamine oxidase: solubilization and kinetics of inhibition by octylglucoside

Complete solubilization of both the A and B forms of human brain monoamine oxidase (MAO) occurred when crude mitochondria were incubated in the presence of 50 mM octylglucoside (OG). Upon removal of this nonionic detergent by dialysis, approximately 100% of the starting activity was present in the dialysate. The effects of solubilization were examined by comparison of several properties of the membrane-bound and OG-treated oxidases. The percentage inhibition of phenylethylamine (PEA) and the 5-hydroxytryptamine (5-HT) deamination by deprenyl and clorgyline were identical. The Km values obtained for the deamination of PEA, a B-selective substrate, 5-HT, an A-selective substrate, and tyramine (TYR), a nonselective substrate, were also comparable. OG was found to inhibit type A (I50 = 8.1 mM) and B (I50 = 4.7 mM) MAO activities at concentrations at least 10-fold below those used to solubilize the oxidases. Kinetic studies revealed that OG was an apparent competitive inhibitor of PEA deamination whereas OG produced a mixed-type pattern of inhibition when 5-HT was the variable substrate. Inhibition of TYR deamination by either the A or B form of MAO produced a mixed pattern of inhibition. The findings herein suggest that solubilization of the A and B forms of MAO by OG does not significantly alter the substrate and inhibitor specificity of the oxidases following removal of detergent. However, in the presence of concentrations of OG 50 times less than the critical micellar concentration of this detergent, marked inhibition of deamination by both forms of human brain MAO is observed. Accordingly, the usefulness of OG is limited to situations where the detergent is completely removed before quantitation of MAO activity.