Expression of Functional Human Monoamine Oxidase A and B cDNAs in Mammalian Cells

Monoamine oxidase (MAO) A and B are important enzymes that metabolize biogenic amines throughout the body. Previous studies had suggested that both MAO A and B consist of two subunits of molecular masses of 63 and 60 kilodaltons, respectively. The cDNAs encoding one subunit of human liver MAO A and B have been expressed in mammalian cells by transfection of the individual clones. The proteins expressed from these cDNAs are shown to be catalytically active. Similar to the endogenous enzymes, the expressed MAO A prefers serotonin as a substrate and is sensitive to the inhibitor clorgyline. In contrast, the expressed MAO B prefers phenylethylamine as a substrate and is sensitive to the inhibitor deprenyl. These results suggest that a single polypeptide of MAO A (or B), existing as either a monomer or homodimer, is enzymatically active. The ability to obtain functional MAO A and B from their respective cDNA clones allows us to study further the structure and function relationships of these important enzymes.     

Ganglioside GM1 Causes Expression of Type B Monoamine Oxidase in a Rat Clonal Pheochromocytoma Cell Line, PC12h

The effects of ganglioside supplementation of culture medium on monoamine oxidase (MAO) type A and B activities in a rat clonal pheochromocytoma cell line, PC12h, were examined. The MAO activity in PC12h cells proved to be mainly due to type A MAO, and type B MAO activity was negligible. After supplementation of the culture medium with ganglioside GM1, the PC12 cells were found to express type B MAO activity after 4 days of culture, and the amount of type B activity increased with the number of days of culture. After 3 weeks of culture in the presence of GM1, type B activity was about 10% of the total, whereas in control cells type B MAO activity was only about 0.6% of the total. By kinetic analyses of type A and B MAO in PC12h cells after 3 weeks of culture, the increase of type B MAO activity was found to be due to the increase in amount of type B MAO; the Km values were almost the same and only the Vmax values were increased in the cells supplemented with GM1. Among gangliosides tested GM1 was the most effective in causing expression of type B MAO activity, whereas nerve growth factor was not effective. These results suggest that GM1 and other gangliosides may be involved in the expression of type B MAO in nerve cells and in the regulation of levels of the biogenic amines in the brain.     

Nonselective Inhibition of Monoamine Oxidases A and B by Activators of Soluble Guanylate Cyclase

Several activators of soluble guanylate cyclase were investigated as potential inhibitors of rat liver mitochondrial monoamine oxidases (MAO) A and B. They all fitted into the previously designed molds of substrate–inhibitor binding sites of these enzymes. However, only two of them, NO donors (7-nitro-benzotetrazine-1,3-dioxide (7-NBTDO) and benzodifuroxan), caused nonselective inhibition of MAO A and MAO B with IC ₅₀ values of 1.3-1.6 and 6.3-6.8 M, respectively. The inhibitory effect on both MAO A and MAO B was reduced by mitochondria wash suggesting reversible mode of the enzyme inhibition. There was no correlation between potency of MAO inhibition and activation of human platelet soluble guanylate cyclase. The NO scavenger 2-(4-carboxyphenyl)-4,4,5,5-tetramethylimidazoline-1-oxyl-3-oxide (carboxy-PTIO) had no effect on the manifestation of MAO inhibition by benzodifuroxan and 7-NBTDO; however, at 50 M concentration carboxy-PTIO caused potent inhibition of MAO A with minor effect on MAO B activity. The data suggest that nonselective inhibition of MAO A and MAO B by benzodifuroxan and 7-NBTDO can be attributed to the properties of the chemical structures of these compounds. The results of the present study demonstrate a real possibility for the development of a new generation of effective reversible nonselective MAO inhibitors exhibiting equal inhibitory activity with respect to both MAO A and MAO B.     

Effects of intrastriatal kainic acid injection on [3H]dopamine metabolism in rat striatal slices: evidence for postsynaptic glial cell metabolism by both the type A and B forms of monoamine oxidase

Abstract: Intrastriatal injections of kainic acid (KA) were utilized to investigate the cellular localization of postsynaptic dopamine (DA) metabolism by type A and B monoamine oxidase (MAO) in rat striatum. At 2 days postinjection, maximal degeneration of cholinergic and γ-aminobutyric acid (GABA)ergic neurons was observed and found to be associated with a significant decrease in both type A and B MAO activity. However, over the next 8-day period, when only the process of gliosis appeared to be occurring, a selective return to control of type B MAO activity was seen. When the metabolism of [³H]DA (10^?7 M) was examined in 8-day KA-lesioned rat striatal slices, an increase in [³H]dihydroxyphenylacetic acid (DOPAC) and [³H]homovanillic acid (HVA) formation was observed. The KA-induced elevation of [³H]DOPAC formation (but not [³H]HVA) was abolished by the DA neuronal uptake inhibitor nomifensine. This is consistent with earlier findings suggesting that HVA is formed exclusively within sites external to DA neurons. Experiments with clorgyline and/or deprenyl revealed that the relative roles of type A and B MAO in striatal DA deamination remained unchanged following KA (90% deamination by type A MAO) even though total deamination was substantially enhanced. At high concentrations of [³H]DA (10^?5 M), deamination by type B MAO could be increased to 30% of the total MAO activity; however, this was observed in both control and KA-lesioned striata. These results suggest that KA-sensitive neurons contain type A and/or type B MAO. Moreover, whereas these neurons may metabolize DA, a major portion of postsynaptic DA deamination appears to occur within glial sites of rat striatal tissue. Furthermore, glial cells would appear to contain functionally important quantities of both type A and B MAO.     

Influence of culture conditions on monoamine oxidase A and B activity in rat astrocytes

Astroglial cells dispersed from newborn rat hemispheres were established in medium supplemented with 20 per cent fetal calf serum (FBS) and then grown to a confluent monolayer in the presence of 10 per cent FBS or charcoal-stripped FBS (CS). Type 1 astrocytes were subcultured and either maintained under the same conditions of the primary cultures or converted to serum-free chemically defined medium (CDM). No differences were found in either MAO A or MAO B activity of astrocytes grown in the presence of FBS or CS after 15 and 21 days in vitro (day 1 and 6 of subculture). In contrast, on day 21 both MAO A and MAO B activities were markedly higher in astrocytes subcultured in CDM compared with cells maintained in serum-supplemented medium. This difference appeared to be due to increased number of enzyme molecules, since kinetic analysis showed an increase in V_max of both MAO isoenzymes in serum-free medium, but no change in K_m. Consistently, the recovery of MAO A and MAO B activity after irreversible enzyme inhibition by clorgyline and deprenyl was faster in CDM than in FBS-supplemented medium, indicating enhanced enzyme synthesis under serum-free condition. Estimates of half-lives for the recovery of MAO A and MAO B activity indicated that, under both culture conditions, type A activity had a higher turnover rate than type B. The effect of CDM on astrocyte MAO does not appear to be due to selection of a subpopulation of cells, but rather linked to a morphological change (differentiation) with increased synthesis of both MAO isoenzymes.     

The Deduced Amino Acid Sequences of Human Platelet and Frontal Cortex Monoamine Oxidase B Are Identical

Abstract: Monoamine oxidases (MAOs) A and B play important roles in the metabolism of neuroactive, vasoactive amines. Human platelets contain only MAO B, often used as an indicator of brain MAO B. The validity of this model remained to be evaluated. This report describes the molecular cloning of human MAO B from frontal cortex and platelets. Two overlapping PCR-amplified clones of human platelet MAO B and four PCR-amplified clones of human frontal cortex MAO B covering the entire coding region were sequenced using five internal oligomers and M13 reverse and forward primers. The nucleotide sequences of human MAO B cDNA from platelet and frontal cortex were identical to that of human liver MAO B except for three nucleotides that differed in frontal cortex: nucleotides 440 A → G, 794 C → T, and 825 C → T. Whether or not these differences are artifactual, all three represent silent mutations, which would not alter the amino acid of the encoded polypeptides. Thus, the deduced amino acid sequences of MAO B from frontal cortex, platelet, and liver are identical. These findings indicate the validity of using platelet MAO B mRNA as a marker for brain MAO B and provide a new approach to study the role of brain MAO B in humans.     

Crystal structure of human monoamine oxidase B, a drug target enzyme monotopically inserted into the mitochondrial outer membrane

Monoamine oxidase B (MAO B) is an outer mitochondrial membrane protein that oxidizes arylalkylamine neurotransmitters and has been a valuable drug target for many neurological disorders. The 1.7 angstrom resolution structure of human MAO B shows the enzyme is dimeric with a C-terminal transmembrane helix protruding from each monomer and anchoring the protein to the membrane. This helix departs perpendicularly from the base of the structure in a different way with respect to other monotopic membrane proteins. Several apolar loops exposed on the protein surface are located in proximity of the C-terminal helix, providing additional membrane-binding interactions. One of these loops (residues 99-112) also functions in opening and closing the MAO B active site cavity, which suggests that the membrane may have a role in controlling substrate binding.     

Non-MAO A binding of clorgyline in white matter in human brain

Clorgyline is an irreversible inhibitor of monoamine oxidase (MAO A) which has been labeled with carbon-11 (C-11) and used to measure human brain MAO A with positron emission tomography (PET). In this study we compared [11C]clorgyline and deuterium-substituted [11C]clorgyline ([11C]clorgyline-D2) to better understand the molecular link between [11C]clorgyline binding and MAO A. In PET studies of five normal healthy volunteers scanned with [11C]clorgyline and [11C]clorgyline-D2 2 h apart, deuterium substitution generally produced the expected reductions in the brain uptake of [11C]clorgyline. However, the reduction was not uniform with the C-11 binding in white matter being significantly less sensitive to deuterium substitution than other brain regions. The percentages of the total binding attributable to MAO A is largest for the thalamus and smallest for the white matter and this is clearly seen in PET images with [11C]clorgyline-D2. Thus deuterium-substituted [11C]clorgyline selectively reduces the MAO A binding component of clorgyline in the human brain revealing non-MAO A binding which is most apparent in the white matter. The characterization of the non-MAO A binding component of this widely used MAO A inhibitor merits further investigation.     

单胺氧化酶

单胺氧化酶（monoamine oxidase,MAO）是生物体内一种十分重要的酶,它在大脑和周围神经组织中催化一些生物体产生的胺,氧化脱氨产生过氧化氢（H₂O₂）.单胺氧化酶A和B基因的克隆清楚地证明了这些酶是由不同的多肽组成的.单胺氧化酶A和B的基因定位于X染色体（Xp11.23）,都由15个外显子组成,而且它们的内含子-外显子组织是完全一致的.这些事实表明单胺氧化酶A和B的基因很可能从同一个祖先进化而来.单胺氧化酶A和B具有不同的底物和抑制剂专一性,在生物神经递质代谢和行为方面具有不同的作用.     

Inhibition of Monoamine Oxidase by 3,4-Dihydroxyphenylserine

The effects of diastereomers of 3,4-dihydroxyphenylserine (DOPS) on the enzyme activity of monoamine oxidase (MAO) in human placenta and liver mitochondria were examined. Both L- and D-threo-DOPS were found to inhibit MAO-A in human placental mitochondria in competition with the substrate, and the Ki values for L- and D-threo-DOPS obtained were 68.3 and 125 microM, respectively. The inhibitory effect of L-threo-DOPS on both MAO-A and -B activity was confirmed in human liver mitochondria, and MAO-A was found to be more sensitive to the inhibitor. Other isomers of DOPS, L- and D-erythro-DOPS, were found to inhibit MAO activity, but the inhibition was noncompetitive with the substrate. The inhibitory effects of DOPS isomers were not affected by the presence of NSD-1055, an inhibitor of aromatic L-amino acid decarboxylase, suggesting that the inhibition is the direct effect of DOPS, and not of norepinephrine produced by the decarboxylase.     

Inhibition of Type A Monoamine Oxidase by Methylquinolines and Structurally Related Compounds

Abstract: A series of methylquinolines (MQ) were found to inhibit markedly type A monoamine oxidase (MAO) in human brain synaptosomal mitochondria. 4-MQ and 6-MQ inhibited type A MAO (MAO-A) competitively and 7- and 8-MQ inhibited MAO-A noncompetitively. Among these four isomers of MQ, 6-MQ was the most potent inhibitor; the K _i value toward MAO-A was 23.4 ± 1.8 μ M , which was smaller than the K _m value toward kynuramine, ± amine substrate, 46.2 ± 2.8 μ M . On the other hand, MQ were very weak inhibitors of type B MAO (MAO-B) and 8-MQ did not inhibit MAO-B in brain synaptosomal mitochondria. The inhibition of MAO-A proved to be reversible; by dialysis the inhibition of MQ was completely reversible. The affinity of these isomers of MQ toward MAO-A or -B was confirmed further with human liver mitochondria as sources of MAO-A and -B and with human placental mitochondria and rat pheochromocytoma PC12h cell line as sources of MAO-A. The relationship of the chemical structure of structurally related quinoline and isoquinoline derivatives to inhibition of the activity of type A or B MAO was examined.     

Immunocytochemical localization of monoamine oxidases A and B in human peripheral tissues and brain

Monoamine oxidases (MAO; EC 1.4.3.4.) A and B occur in the outer mitochondrial membrane and oxidize a number of important biogenic and xenobiotic amines. Monoclonal antibodies specific for human MAO A or B and immunocytochemical techniques were used to visualize the respective enzymes in human placenta, platelets, lymphocytes, liver, brain, and a human hepatoma cell line. MAO A was observed in the syncytiotrophoblast layer of term placenta, liver, and a subset of neurons in brain, but was not observed in platelets or lymphocytes, which are known to lack type A enzyme. MAO B was observed in platelets, lymphocytes, and liver, but not in placenta, which contains little or no MAO B. MAO B was also observed in a subset of neurons in the brain that was distinct from that which contained MAO A. MAO A and MAO B were also observed in some glia. Unlike most tissues examined, liver cells appeared to contain both forms of the enzyme. These studies show that MAO A and MAO B can be specifically visualized by immunocytochemical means in a variety of human cells and tissues and can provide a graphic demonstration of the high degree of cell specificity of expression of the two forms of the enzyme.     

Evidence that the methylation state of the monoamine oxidase A (MAOA) gene predicts brain activity of MAO A enzyme in healthy men

Human brain function is mediated by biochemical processes, many of which can be visualized and quantified by positron emission tomography (PET). PET brain imaging of monoamine oxidase A (MAO A)—an enzyme metabolizing neurotransmitters—revealed that MAO A levels vary widely between healthy men and this variability was not explained by the common MAOA genotype (VNTR genotype), suggesting that environmental factors, through epigenetic modifications, may mediate it. Here, we analyzed MAOA methylation in white blood cells (by bisulphite conversion of genomic DNA and subsequent sequencing of cloned DNA products) and measured brain MAO A levels (using PET and [¹¹C]clorgyline, a radiotracer with specificity for MAO A) in 34 healthy non-smoking male volunteers. We found significant interindividual differences in methylation status and methylation patterns of the core MAOA promoter. The VNTR genotype did not influence the methylation status of the gene or brain MAO A activity. In contrast, we found a robust association of the regional and CpG site-specific methylation of the core MAOA promoter with brain MAO A levels. These results suggest that the methylation status of the MAOA promoter (detected in white blood cells) can reliably predict the brain endophenotype. Therefore, the status of MAOA methylation observed in healthy males merits consideration as a variable contributing to interindividual differences in behavior.