Localization of monoamine oxidase A and B in human pancreas, thyroid, and adrenal glands.

We studied monoamine oxidase (MAO) A and B localization in human pancreas, thyroid gland, and adrenal gland by immunohistochemistry. The primary antibodies used were mouse monoclonal anti-human MAO-A (6G11/E1) and anti-human MAO-B (3F12/G10/2E3). Samples were obtained from six routine autopsy cases and fixed in 2% paraformaldehyde. Exocrine pancreas showed a widespread distribution of MAO-A, whereas MAO-B was present only in centroacinar cells and epithelial cells of pancreatic ducts. In endocrine pancreas, MAO-A was observed in around 50% of islet cells, whereas MAO-B was less abundant and was restricted to the periphery of islets. Thyroid gland showed strong MAO-A immunoreactivity in all cell types and was MAO-B-negative. In adrenal gland, the capsule displayed MAO-A but not MAO-B immunoreactivity, whereas the cortex showed widespread MAO-A staining but was MAO-B-negative in interstitial cells. Finally, in the medulla only a few scattered cells showed either MAO-A or MAO-B immunoreactivity. To our knowledge, these data represent the first study of the cellular distribution of MAO-A and MAO-B in the three human tissues included.     

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.     

Inhibition of Monoamine Oxidase by 7-Chloro-4-Nitrobenzofurazan

7-Chloro-4-nitrobenzofurazan (NBD-Cl) is a potent inhibitor of both types of monoamine oxidase (MAO). NBD-Cl competitively inhibited the oxidative deamination of kynuramine catalyzed by human placenta MAO-A, the oxidative deamination of benzylamine catalyzed by bovine liver MAO-B, the oxidative deamination of serotonin catalyzed by rat brain MAO-A, and the oxidative deamination of phenylethylamine catalyzed by rat brain MAO-B. In addition, a time-dependent inactivation of MAOs by NBD-Cl has been demonstrated upon incubation of the enzyme preparations with NBD-Cl at pH 9, but not at pH 7.5. The time-dependent inhibition of MAO by NBD-Cl could be prevented by the addition of 4-nitrophenyl azide, an active site-directed label of MAO, during incubation of the enzyme with NBD-Cl. On the basis of these findings, it is suggested that at pH 9, NBD-Cl modifies one (or more) essential lysine residue(s) in the active sites of the two types of MAO.     

Deamination of Aliphatic Amines by Monoamine Oxidase A and B Studied Using a Bioluminescence Technique

Deamination of n-octylamine and n-decylamine has been studied in various tissues using a new bioluminescence technique. Selectivity of n-octylamine and n-decylamine as substrates for monoamine oxidase (MAO) A or B has been determined using both clorgyline and (-)-deprenyl inhibition curves and kinetic parameters. Homogenates of rat brain, liver and heart containing predominantly MAO-A or -B were prepared by preincubation for 60 min with (-)-deprenyl or clorgyline (30 nM), respectively. Human placenta (MAO-A) and platelet (MAO-B) were used as reference tissues containing only one MAO form. In tissues (rat liver, brain) containing both MAO forms in equal proportion, inhibition curve studies showed a preference of both substrates for the B form of the enzyme; however, where MAO-A was the major form (rat heart, human placenta), clorgyline was the more effective inhibitor. In the beef brain cortex n-octylamine showed marked preference for MAO-B, whereas n-decylamine was selective toward-MAO-A. Kinetic studies in general supported the picture of greater selectivity of the aliphatic amine substrates for deamination by MAO-B, as reflected by lower Km values for this enzyme type. However, n-octylamine was more selective for MAO-B than n-decylamine in both kinetic and inhibition curve studies. The deamination of these aliphatic amine substrates cannot be explained only by reference to the binary classification of MAO into types A and B.     

Differential substrate specificity of monoamine oxidase in the rat heart and renal cortex

Although it is known that substrate specificities differ with species and within each species with the tissues, in the rat heart no natural substrate was found for MAO-B. beta-phenylethylamine (beta-PEA) has always been considered the "endogenous" substrate of MAO B. We thought worthwide to evaluate the effect of Ro 41-1049 and lazabemide, both members of a class of highly selective, mechanism-based and reversible inhibitors for MAO-A and MAO B, respectively on the metabolization of beta-PEA by the rat heart. Also the lack of molecular data on rat heart MAOs, prompted us to better characterize rat heart MAOs, both kinetically and using molecular biology techniques. K(m) values for deamination of beta-PEA in the rat heart were 13-fold those in the kidney, by contrast, K(m) values for deamination of 5-HT were quite similar in both tissues. Unexpectedly, the selective MAO-A inhibitor Ro 41-1049 was by far the most potent inhibitor of beta-PEA (20 microM) deamination in the rat heart, while clorgyline, another MAO A inhibitor, and lazabemide, a MAO B inhibitor, had intermediate efficacy; selegiline was found unable to inhibit deamination of beta-PEA. In the rat renal cortex lazabemide and selegiline both inhibited beta-PEA deamination. The reduction of beta-PEA concentration to just 200 nM, the use of heart membranes instead of tissue homogenates or the use of heart membranes pre-treated with 1% digitonine failed to change this pattern of inhibition. Semicarbazide was found not to alter deamination of beta-PEA. Western blot showed the presence of both isoforms (55 kd and 61 kd) in the renal cortex. In the heart there was a predominance of the A form, the B form being undetected. The RT-PCR products for both MAO-A and MAO-B, were found to have the expected sizes. In conclusion, we found mRNA for MAO-B but were unable to detect the protein itself or its activity when using beta-PEA as the substrate.     

Distribution of the Two Forms of Monoamine Oxidase Within Monoaminergic Neurons of the Guinea Pig Brain

The relative distribution of type A and type B monoamine oxidase (MAO) inside and outside the monoaminergic synaptosomes in preparations from hypothalamus and striatum of the guinea pig was determined by incubation of synaptosomal preparations of these regions with low concentrations of [14C]5-hydroxytryptamine (5-HT), noradrenaline, and dopamine. The deamination within the monoaminergic synaptosomes was hindered by selective amine uptake inhibitors. In the absence of these inhibitors, both intra- and extraneuronal deamination was measured. The two forms of the enzyme were differentiated with the irreversible and selective MAO-A and MAO-B inhibitors clorgyline and selegiline (l-deprenyl), respectively. [14C]5-HT was deaminated greater than 90% by MAO-A both inside and outside the 5-hydroxytryptaminergic synaptosomes prepared from the guinea pig hypothalamus. The deamination of [14C]noradrenaline within the noradrenergic synaptosomes of the hypothalamic preparation was in the ratio 75:25% for MAO-A:MAO-B; the corresponding ratio outside these synaptosomes was 45:55%. The deamination of [14C]dopamine within dopaminergic synaptosomes in the striatal preparation was 65% type A:35% type B, whereas outside these synaptosomes the ratio was 35:65%. Because the relative amounts and the distribution of the two forms of MAO in the guinea pig brain seem to be similar to those previously detected for the human brain, the MAO in the guinea pig brain may be a good model for the MAO in the human brain.     

A and B Forms of Monoamine Oxidase Within the Monoaminergic Neurons of the Rat Brain

The inhibition of the A and B forms of monoamine oxidase (MAO) inside and outside serotonergic, noradrenergic, and dopaminergic synaptosomes in homogenates of rat hypothalamus or striatum by clorgyline, a selective and irreversible MAO-A inhibitor, and selegiline, a selective and irreversible MAO-B inhibitor, was examined. Intrasynaptosomal deamination at low concentrations of the substrates [14C]5-hydroxytryptamine ([14C]5-HT; 0.1 microM), [14C]noradrenaline (0.25 microM), [14C]3,4-dihydroxyphenylethylamine ([14C]dopamine; 0.25 microM), and [14C]tyramine (0.25 microM) was hindered by selective uptake inhibitors (citalopram, maprotiline, and amfonelic acid) in the incubation media. Thus, the difference between the deamination of 14C-amine in the absence and presence of the appropriate selective uptake inhibitor provided a measure of deamination in the specific aminergic synaptosomes. This was verified by determining the loss of MAO activity within noradrenergic and serotonergic systems after degeneration of the nerve terminals by the neurotoxins N-chloroethyl-N-ethyl-2-bromobenzylamine and p-chloroamphetamine. Results with the two inhibitors revealed that the A and B forms were responsible for 80 and 20%, respectively, of the deamination of [14C]5-HT within serotonergic synaptosomes from the hypothalamus. The deamination of [14C]noradrenaline within the noradrenergic synaptosomes from the hypothalamus and that of [14C]dopamine and [14C]tyramine within the striatal dopaminergic synaptosomes were due to MAO-A. About 10% of the deamination of [14C]noradrenaline, [14C]dopamine, and [14C]tyramine outside the noradrenergic or dopaminergic synaptosomes was brought about by the B form, with the remainder being deaminated by MAO-A.     

Inhibition of rat brainstem monoamine oxidase activity by CGP 6085 A

CGP 6085 A [4-(5,6-dimethyl-2-benzofuranyl)piperidine] HCl, a known serotonin inhibitor, also inhibits rat brainstem monoamine oxidase A (MAO-A) and monoamine oxidase B (MAO-B) in both in vivo and in vitro experiments. Serotonin (5-HT) deamination by MAO-A is inhibited 35% at a dose of 100 mg/kg i.p. in vivo. Similar experiments show a maximal 20% decrease in phenylethylamine (PEA) deamination by MAO-B at a dosage of 30 mg/kg i.p. Over the range of 0.1 to 10 mg/kg i.p., CGP 6085 A decreases 5-HIAA levels in the brainstem. This in vivo inhibition of MAO activity is confirmed by in vitro experiments. In vitro studies in rat brainstem mitochondrial preparations show a dose-dependent, reversible, inhibition of MAO using tyramine as the substrate for the enzyme reaction. With an in vitro IC50 of 2-3 microM, the potency of CGP 6085 A is comparable to pargyline.     

Characterization of rat pulmonary monoamine oxidase.

The substrate specificities and kinetics of rat lung monoamine oxidase (MAO) have been studied. Utilizing the irreversible MAO inhibitors, clorgyline and deprenyl, rat lung was shown to possess at least two types of MAO, A and B. Tyramine was a substrate for both forms of the enzyme, whereas 5-hydroxytryptamine (5-HT) was a preferred substrate for the A-form. In contrast to most other tissues, 2-phenylethylamine was not solely a B-type substrate for the rat lung MAO and some metabolism by the A-type was apparent $\text{(}\text{B}\text{A}\text{=}\text{80}\text{20}\text{)}$. Using tyramine as substrate the ratio A/B was shown to be $\text{55}\text{45}$. Rat pulmonary MAO-B was inhibited by deprenyl and the kinetics of MAO-A studied. The Km values for the A-form for tyramine, phenylethylamine and 5-HT were relatively similar and were 270, 244 and 170 μM respectively. Whereas, when the A-form was inhibited by clorgyline, the Km values for the B-form were found to differ considerably: 330, 42 and 850 μM for tyramine, phenylethylamine and 5-HT respectively.     

Cytochemical localization of type-A and -B monoamine oxidase in the rat pineal gland

Summary In the mammalian pineal gland, serotonin (5-HT) is located both in the pinealocytes and in the noradrenergic nerve terminals. Pineal 5-HT can be metabolized by three different routes, one of these being its deamination, catalized by monoamine oxidase (MAO). MAO is known to exist as two isozymes, MAO-A and MAO-B. Using two different cytochemical methods at the ultrastructural level, we have localized the presence of MAO in the pineal gland of the rat. The use of selective inhibitors of A-type (clorgyline) and B-type (deprenyl) has shown that MAO-A is localized in the noradrenergic nerve terminals, while pinealocytes contain MAO-B. Taking into account that 5-HT is only deaminated by MAO-A, the specific association of each MAO isozyme with a defined cell type implicates that two cellular compartments are needed in the pineal gland for the biosynthesis of 5-methoxytryptophol and 5-methoxyindole acetic acid, while for the synthesis of melatonin and 5-methoxytryptamine just one cellular compartment, the pinealocyte, is appropriate.     

SUBSTRATE AND INHIBITOR-RELATED CHARACTERISTICS OF MONOAMINE OXIDASE IN C6 RAT GLIAL CELLS

Cultured C6 rat glial cells preferentially deaminated 5-hydroxytryptamine, tryptamine, dopamine and tyramine in comparison to phenylethylamine and benzylamine. Deamination of all substrates was uniformly sensitive to inhibition by clorgyline and relatively insensitive to deprenyl. These data together with the observations of simple sigmoid curves for the inhibition of tyramine deamination by both inhibitors suggest that C6 glial cells contain mainly monoamine oxidase type A, which previously had been suggested to be primarily an intraneuronal MAO type. As these findings are in agreement with other studies of brain MA0 activity in mitochondria separated from neuronal vs glial cell preparations, they help explain why MA0 activity measured with some substrates may be little affected by lesions or by drugs producing nerve ending degeneration.     

Formation of the Neurotransmitter Glycine from the Anticonvulsant Milacemide Is Mediated by Brain Monoamine Oxidase B

Milacemide (2-n-pentylaminoacetamide) is a secondary monoamine that in the brain is converted to glycinamide and glycine. This oxidative reaction was suspected to involve the reaction of monoamine oxidase (MAO). Using mitochondrial preparations from tissues that contain MAO-A and -B (rat brain and liver), MAO-A (human placenta), and MAO-B (human platelet and bovine adrenal chromaffin cell), it has been established that mitochondria containing MAO-B rather than MAO-A oxidize (H2O2 production and glycinamide formation) milacemide. The apparent Km (30-90 microM) for milacemide oxidation by mitochondrial MAO-B preparations is significantly lower than that for milacemide oxidation by mitochondrial MAO-A (approximately 1,300 microM). In vitro MAO-B (l-deprenyl and AGN 1135) rather than MAO-A (clorgyline) selectively inhibited the oxidation of milacemide. These in vitro data are matched by ex vivo experiments where milacemide oxidation was compared to oxidation of serotonin (MAO-A) and beta-phenylethylamine (MAO-B) by brain mitochondria prepared from rats pretreated with clorgyline (0.5-10 mg/kg) and l-deprenyl (0.5-10 mg/kg). Furthermore, in vivo experiment demonstrated that l-deprenyl selectively increased the urinary excretion of [14C]milacemide and the total radioactivity with a concomitant decrease of [14C]glycinamide. Such changes were not observed after clorgyline treatment, but were evident only at doses beyond clorgyline selectivity. The present data therefore demonstrate that milacemide is a substrate for brain MAO-B, and its conversion to glycinamide, further transformed to the inhibitory neurotransmitter, glycine, mediated by this enzyme may contribute to its pharmacological activities.     

The Metabolism of Dopamine by Both Forms of Monoamine Oxidase in the Rat Brain and Its Inhibition by Cimoxatone

In the rat brain, dopamine is metabolised by both A and B forms of monoamine oxidase (MAO), although the A form of the enzyme is the major component. The Km of MAO-A toward dopamine (120 microM) is lower than the Km of MAO-B toward this substrate (340 microM). The activity of MAO-A was lower in old rats than in young rats, and the same degree of decrease was found for 5-hydroxytryptamine as for dopamine as substrates for this enzyme form. The activity of MAO-B was higher in the old rats, the degree of increase being the same for dopamine as for beta-phenethylamine as substrates for this enzyme form. The Ki values of the inhibition of MAO-A by cimoxatone and MD770222 (the principal plasma metabolite of cimoxatone) were independent of the substrate used to assay for activity, but were lower than the Ki values for the inhibition of MAO-B by these compounds.     

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.     

Serotonin Metabolism by Monoamine Oxidase in Rat Primary Astrocyte Cultures

The oxidative deamination of serotonin (5-HT) to 5-hydroxyindoleacetic acid (5-HIAA) by rat primary astrocyte cultures was investigated in intact cells using HPLC. All detectable 5-HIAA accumulated in the extracellular medium, and its rate of production was proportional to the 5-HT concentration over the tested range of 5 x 10(-7) to 10(-4) M. At 5 x 10(-7) M 5-HT, intracellular 5-HT was detectable only in astrocytes treated with monoamine oxidase (MAO) inhibitors. These findings are consistent with the idea that 5-HT taken up into astrocytes is not stored for re-release, but is rapidly metabolized to 5-HIAA, which is then extruded from the cell. At 5 x 10(-7) M 5-HT, 5-HIAA formation in intact cells was blocked 63% by the selective high-affinity 5-HT uptake inhibitor fluoxetine. 5-HT oxidation to 5-HIAA is carried out principally by MAO-A, because clorgyline was more effective at inhibiting the production of 5-HIAA than was pargyline. Radioenzymatic determinations of MAO activity in cell homogenates supported these findings, because under these conditions clorgyline was 1,000-fold more effective than pargyline at inhibiting MAO activity toward 14C-labelled 5-HT. However, the relatively selective MAO-B substrate beta-phenylethylamine (PEA) was also oxidized, showing that these cultures also contained MAO-B activity; the Km values for MAO-A oxidation of 5-HT and MAO-B oxidation of PEA were 135 and 45 microM, and Vmax values were 88 and 91 nmol/mg of total cell protein/h, respectively. Higher concentrations of PEA (greater than 20 microM) were oxidized by both MAO-A and MAO-B isozymes.(ABSTRACT TRUNCATED AT 250 WORDS)     

Deamination of 5-methoxytryptamine, serotonin and phenylethylamine by rat MAO in vitro and in vivo.

Pretreatment of rats with clorgyline, a selective inhibitor of MAO-A, significantly inhibited the $\text{in vivo}$ deamination of intraventricularly administered serotonin (5-HT) and 5-methoxytryptamine (5-MT), but not phenylethylamine (PEA). Pretreatment with d, l-deprenyl, a selective inhibitor of MAO-B, significantly inhibited the $\text{in vivo}$ deamination of all three substrates. Brain and liver homogenates from rats pretreated with clorgyline showed a decreased ability to deaminate ($\text{in vitro}$) 5-MT and 5-HT, but not PEA. Homogenates from animals pretreated with d,l-deprenyl showed a decreased capacity to deaminate PEA, but not 5-MT or 5-HT. Clorgyline, when added to brain and liver homogenates, selectively blocked the deamination of 5-MT and 5-HT, but not PEA, whereas, d,l-deprenyl blocked the deamination of PEA without affecting that of 5-MT or 5-HT. In addition, 5-MT was found to be 100 X more potent than PEA at inhibiting the $\text{in vitro}$ deamination of 5-HT. These findings suggest that 5-MT and 5-HT are favored substrates for MAO-A $\text{in vitro}$ and $\text{in vivo}$. However, $\text{in vivo}$, significant amounts of 5-MT and 5-HT can also be deaminated by MAO-B.     

Inhibition of brain monoamine oxidase activity by the generation of hydroxyl radicals: potential implications in relation to oxidative stress

Monoamine oxidase (MAO) is an enzyme involved in brain catabolism of monoamine neurotransmitters whose oxidative deamination results in the production of hydrogen peroxide. It has been documented that hydrogen peroxide derived from MAO activity represents a special source of oxidative stress in the brain. In this study we investigated the potential effects of the production of hydroxyl radicals (*OH) on MAO-A and MAO-B activities using mitochondrial preparations obtained from rat brain. Ascorbic acid (100 microM) and Fe2+ (0.2, 0.4, 0.8, and 1.6 microM) were used to induce the production of *OH. Results showed that the generation of *OH significantly reduced both MAO-A (85-53%) and MAO-B (77-39%) activities, exhibiting a linear correlation between both MAO-A and MAO-B activities and the amount of *OH produced. The reported inhibition was found to be irreversible for both MAO-A and MAO-B. Assuming the proven contribution of MAO activity to brain oxidative stress, this inhibition appears to reduce this contribution when an overproduction of *OH occurs.     

The oxidation of adrenaline and noradrenaline by the two forms of monoamine oxidase from human and rat brain

The selective monoamine oxidase inhibitors clorgyline and (−)-deprenyl were used to study the distribution of monoamine oxidase-A and -B (MAO-A, MAO-B) activities towards (−)-noradrenaline and (+),(−)-adrenaline in homogenates from seven different regions of human brain. The activities towards 5-hydroxytryptamine and 2-phenethylamine, which are essentially specific substrates for the A- and B-forms, respectively, under the conditions used in this work, were also determined. Noradreanline and adrenaline were substrates for both forms of the enzyme in all regions studied. The total MAO activity was found to be highest in the hypothalamus and lowest in the cerebellar cortex. Use of the selective MAO inhibitors clorgyline and (−)-deprenyl also showed adrenaline and noradrenaline to be substrates for both forms of the enzyme in rat brain. In human cerebral cortex and rat brain the two forms were found to have similar K_m-values and maximum velocities towards adrenaline. These values for the two forms were also found to be similar in human cerebral cortex when noradrenaline was used as the substrate. In contrast MAO-A showed a significantly lower K_m and a higher maximum velocity towards noradrenaline in rat brain. These results suggest that the rat may not provide a close model of the human for studies on the effects of MAO inhibitors on brain noradrenaline metabolism.     

Tissue distribution of smg p25A, a ras p21-like GTP-binding protein, studied by use of a specific monoclonal antibody

We made a monoclonal antibody specifically recognizing smg p25A among many ras p21-like GTP-binding proteins and investigated the tissue distribution of smg p25A by use of this antibody. By immunoblot analysis, smg p25A was detected in rat brain and bovine adrenal medulla but not in bovine adrenal cortex or other rat tissues including thymus, spleen, lung, heart, liver and kidney. However, by immunocytochemical studies, smg p25A was detected not only in the synaptic areas of rat brain and the chromaffin cells of bovine adrenal medulla but also in the endocrine cells of rat pancreatic islets, the acinar cells of rat exocrine pancreas and the exocrine cells of rat submaxillary gland. These results suggest that smg p25A is involved in the regulation of secretory processes not only in synapses but also in other endocrine and exocrine secretory cells.     

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.