Absence of diamine oxidase activity from rabbit and rat lungs.

To study the presence of diamine oxidase (DAO) activity in any tissue with putrescine as the substrate, it is necessary to use inhibitors to block all pathways that could further metabolize gamma-aminobutyraldehyde, which is the product of enzyme reaction. It is also necessary to inhibit any enzyme that may convert putrescine into higher polyamines. By this approach it was observed that lung tissue of both rat and rabbit exhibited no DAO activity. DAO activity was observed in the rat and rabbit intestine, the former showing 3 times as much activity as the latter. The other potential pathways of putrescine metabolism are of no consequence in the rat and rabbit intestine and lungs.     

GABA and its relationship to putrescine metabolism in the rat brain and pancreas

The possibility that GABA may have its origin in putrescine was investigated in the rat pancreas, relative to the brain. These studies show that radioactive putrescine is converted to GABA at a similar rate in both the pancreas and brain, but that putrescine accounts for only a small fraction of the GABA found in these organs. Inhibitors of diamine and monoamine oxidases do not significantly change the GABA level in the pancreas. In contrast to the brain, where putrescine is catabolized to GABA via monoamine oxidase, the primary catabolic pathway of putrescine to GABA in the pancreas is via diamine oxidase. In vivo studies show that AOAA inhibits GABA-T activity to the same degree in the pancreas as in the brain, elevating GABA levels more than 2-fold in 4 h. GABA is metabolized more rapidly in the brain than the pancreas. Turnover times of GABA in the pancreas and brain are 1.9 and 1.0 h, respectively. The slower turnover of GABA in the pancreas than in the brain may relate to a neuromodulatory role for GABA, similar to that for neuropeptides. Developmental studies in the postnatal pancreas suggest a role for GABA in the maturation of insulin secretion.     

Distribution of leucine 2,3-aminomutase activity in various organs of the rat and in subcellular organelles of rat liver

Leucine 2,3-aminomutase, the cobalamine-dependent enzyme involved in the conversion of β-leucine to leucine, has been shown to be widely distributed in rat organs. The activity is highest in skeletal and cardiac muscle, lower in brain, liver, and kidney, and very low in small intestine. In rat liver, the activity is nearly all in the cytosolic fraction.     

Alkaline phosphodiesterase I release from eucaryotic plasma membranes by phosphatidylinositol-specific phospholipase C. I. The release from rat organs

From various rat organs, alkaline phosphodiesterase I was liberated by the action of phosphatidylinositol-specific phospholipase C obtained from Bacillus thuringiensis. Especially, a large amount of alkaline phosphodiesterase I was released from slices of small intestine, testis, lung, and kidney, but not from pancreas and liver. The release of the enzyme induced by phospholipase C was dependent on, or proportional to, the reaction time and the concentrations of the phospholipase C and the weight of the slices of small intestine or testis. Furthermore, little enzyme was released from the homogenate of pancreas. These results suggest an important role of phosphatidylinositol in the binding of alkaline phosphodiesterase I to the plasma membranes of rat small intestine and pancreas. The alkaline phosphodiesterase I released from slices of rat small intestine and testis had a molecular weight of about 240,000, and was activated by Mg2+ and Ca2+ but inhibited by EDTA. The enzyme hydrolyzed the phosphodiester linkage of p-nitrophenyl-thymidine 5'-monophosphate at pH 8.9, having the Km values of 0.36 mM (small intestine) and 0.25 mM (testis). The intestinal enzyme differed from the testis enzyme in pI values, thermostability, and Arrhenius plot having a single breakpoint.     

Putrescine, a source of gamma-aminobutyric acid in the adrenal gland of the rat.

Putrescine is the major source of gamma-aminobutyric acid (GABA) in the rat adrenal gland. Diamine oxidase, and not monoamine oxidase, is essential for GABA formation from putrescine in the adrenal gland. Aminoguanidine, a diamine oxidase inhibitor, decreases the GABA concentration in the adrenal gland by more than 70% after 4 h, and almost to zero in 24 h. Studies using [14C]putrescine confirm that [14C]GABA is the major metabolite of putrescine in the adrenal gland. Inhibition of GABA transaminase by amino-oxyacetic acid does not change the GABA concentration in the adrenal gland, as compared with the brain, where the GABA concentration rises. With aminoguanidine, the turnover time of GABA originating from putrescine in the adrenal gland is 5.6 h, reflecting a slower rate of GABA metabolism compared with the brain. Since GABA in the adrenal gland is almost exclusively derived from putrescine, the role of GABA may relate to the role of putrescine as a growth factor and regulator of cell metabolism.     

Spontaneous Release of γ-Aminobutyric Acid Formed from Putrescine and Its Enhanced Ca2+-Dependent Release by High K+ Stimulation in the Brains of Freely Moving Rats

The spontaneous release of [3H] gamma-aminobutyric acid ([3H]GABA) in various areas of rat brain injected with [3H]putrescine was examined using a push-pull perfusion technique. The release in a 25-min perfusate was highest in the caudate-putamen. The effect of high K+ stimulation on the release of [3H]GABA formed from [3H]putrescine was examined in the caudate-putamen. The release was enhanced by high K+ solution in a Ca2+-dependent manner.     

Purification and characterization of a rat brain aldehyde dehydrogenase able to metabolize gamma-aminobutyraldehyde to gamma-aminobutyric acid.

An enzyme which catalyses dehydrogenation of gamma-aminobutyraldehyde (ABAL) to gamma-aminobutyric acid (GABA) was purified to homogeneity from rat brain tissues by using DEAE-cellulose and affinity chromatography on 5'-AMP-Sepharose, phosphocellulose and Blue Agarose, followed by gel filtration. Such an enzyme was first purified from mammalian brain tissues, and was identified as an isoenzyme of aldehyde dehydrogenase. It has an Mr of 210,000 determined by polyacrylamide-gradient-gel electrophoresis, and appeared to be composed of subunits of Mr 50,000. The close similarity of substrate specificity toward acetaldehyde, propionaldehyde and glycolaldehyde between the enzyme and other aldehyde dehydrogenases previously reported was observed. But substrate specificity of the enzyme toward ABAL was higher than those of aldehyde dehydrogenases from human liver (E1 and E2), and was lower than those of ABAL dehydrogenases from human liver (E3), Escherichia coli and Pseudomonas species. The Mr and relative amino acid composition of the enzyme are also similar to those of E1 and E2. The existence of this enzyme in mammalian brain seems to be related to a glutamate decarboxylase-independent pathway (alternative pathway) for GABA synthesis from putrescine.     

Luminal and basolateral polyamine uptake by rat small intestine stimulated to grow by Phaseolus vulgaris lectin phytohaemagglutinin in vivo

Luminal and basolateral uptake of polyamines by the rat small intestine was studied in vivo. In the concentration range studied (0.1-5 mg per rat) 23-47% of the individual polyamines given intragastrically were found in the body after 1 h, with the small intestine retaining 4-12% of the dose. With spermidine or spermine, labelled polyamines accounted for 85-96% of the counts in the small intestine and between 72-82% were in the form given. However, with putrescine only 29-39% of the label found in the tissue remained in polyamine form and even less, 11-15%, as putrescine. Luminal uptake of polyamines was linear, non-saturable and was not stimulated when small intestinal growth was stimulated by phytohaemagglutinin (PHA). On the basolateral side of the gut, polyamine uptake was stimulated by PHA in a time-dependent way in advance of detectable growth. Overall polyamine recoveries were high (89-99%) with intraperitoneally administered spermidine and spermine. Moreover, a large proportion of the counts in the tissue (63-89%) were still in the original form. Even with putrescine, total recoveries of polyamines (72-88%) and putrescine (24-33%) were elevated in comparison with those from the lumen. Treatment of rats with alpha-difluoromethylornithine (DFMO), an inhibitor of ornithine decarboxylase, reduced tissue polyamine content, although it had slight effects only on basolateral polyamine transport. The PHA-stimulated increase of polyamine uptake was not abolished in the presence of DFMO.     

Glutamic acid decarboxylase in tubules and glomeruli isolated from rat kidney cortex

4-Aminobutyric acid (GABA) synthesis was examined in purified glomeruli and tubules of rat kidney cortex that were incubated in the presence of [2,3-3H2]glutamate. The GABA that was formed was separated from glutamate using anion-exchange resin, and identified by means of an automatic amino acid analyser. In the renal cortex only the tubules were able to form GABA (35.0 nmol mg-1 h-1); the remaining GABA synthesis found in the glomerular preparations can most probably be attributed to a contamination by cortical tubules (9%), as shown by determination of a known tubular marker enzyme (L-gamma-glutamyltransferase). Hydroxylamine (1 mM) and ethanolamine-O-sulfate (10 mM), well-known inhibitors of cerebral GABA formation and GABA catabolism respectively, inhibited renal tubular GABA formation at 100% and 44% respectively.     

Lysolecithinase activity in subcellular fractions of rat organs.

Lysolecithinase activity was measured in subcellular fractions of rat liver, kidney, lung and intestine and compared to similar findings in brain. To obtain optimal assay conditions, each fraction was subjected to a kinetic analysis in the absence and presence of albumin. Among the particulate preparations, lysolecithinase activity of the intestine exceeded by far similar fractions of other organs. Among the soluble fractions, the 100,000xg supernatant of lung had the highest activity. Under the assay conditions used, most of the lysolecithinase activity of all organs was particulate.     

Intracellular distribution of GABA in the rat anterior pituitary. An electron microscopic autoradiographic study

We studied the internalization and intracellular distribution of [3H] GABA in rat anterior pituitary cells. Electron microscopic autoradiography of anterior pituitary fragments or dispersed pituitary cells incubated with [3H] GABA showed that lactotrophs and, to a lesser extent, somatotrophs were the only cells that contained radioactive grains. Grain density analysis performed on dispersed pituitary cells after a pulse-chase experiment (10 min pulse and then change to a medium without radioactive GABA for various periods up to 2 h) revealed that GABA internalized by lactotrophs was distributed in various intracellular membranous organelles. Of the cell compartments examined, plasma membrane, Golgi apparatus, mitochondria and secretory granules had different time-dependent labeling patterns. The highest grain density values were associated with plasma membrane (at the first chase time) and the Golgi apparatus. Mitochondria and secretory granules also showed significant grain density values. A similar pattern of distribution was observed when fragments of prolactin-secreting pituitary adenomas were incubated with [3H] GABA. These results provide morphological data on the cellular specificity and intracellular distribution of GABA in anterior pituitary cells.     

Aldehyde dehydrogenase from rat intestinal mucosa: purification and characterization of an isozyme with high affinity for gamma-aminobutyraldehyde.

In rat adrenal gland and gastric mucosa putrescine is efficiently oxidized to GABA via gamma-aminobutyraldehyde (ABAL) by action of diamine oxidase and aldehyde dehydrogenase. Having turned our attention on the rat intestinal mucosa, where putrescine uptake and diamine oxidase are active, we have purified and characterized an aldehyde dehydrogenase optimally active on gamma-aminobutyraldehyde. A dimer with a subunit molecular weight of 52,000, the native enzyme binds ABAL and NAD+ with high affinity: at pH 7.4, Km values are equal to 18 and 14 microM, respectively. Affinity for betaine aldehyde is much lower (Km = 285 microM), but the efficiency is equally good, thanks to a high value of V. Unaffected by disulfiram and Mg2+, the enzyme is activated by high NAD+ concentrations (Vnn = 1.6 x Vn) and is competitively inhibited by NADH. According to the best fitting model, the dimeric enzyme only binds one NADH and the mixed complex enzyme-NAD(+)-NADH is inactive. The increase of activity promoted by NAD+ can therefore be ascribed to an allosteric effect, rather than to the activation of a second reaction center. Highly stable at pH 6.8 in the presence of dithiothreitol and high phosphate concentrations, ABALDH is inactivated by ion-exchange resins and by cationic buffers. Our results show that the enzyme can be effectively involved in the metabolism of biogenic amines and, with a K(m) for ABAL lower than 20 microM, in the synthesis of GABA.     

Eosinophilic leucocytes and phospholipase B of rat tissues

The correlation between the eosinophilic leucocyte population and the phospholipase B activity of rat tissues has been tested with isolated cell preparations from intestine, lung, blood, bone marrow and spleen containing eosinophils in varying proportions and with pure eosinophil fractions separated by centrifugation on discontinuous metrizoate and metrizamide gradients. A uniform value of activity per cell was found in all these tissues extending previous histochemical and biochemical evidence that the eosinophil is the carrier cell for the phospholipase B to all major sites of distribution. The enzyme marker approach has been used for estimating the normal eosinophil population of rat organs and show the distribution pattern of the eosinophils in peripheral organs in the wake of increased production and release from the marrow.     

Characterization of a membrane-bound arginine-specific serine protease from rat intestinal mucosa

Previously we isolated and characterized a membrane-bound, arginine-specific serine protease from pig intestinal mucosa [J. Biol. Chem. 269, 32985-32991 (1994)]. For further characterization of this type of enzyme, we cloned a cDNA from rat intestinal mucosa encoding the precursor of a similar protease. The partial amino acid sequences determined for the pig enzyme were found to be shared almost completely by the rat enzyme. The serine protease domain of the rat enzyme, heterologously expressed in Escherichia coli, specifically cleaved Arg (or Lys)-X bonds with a marked preference for Arg-Arg or Arg-Lys, similar to the pig enzyme. The mRNA for the rat enzyme was shown to be distributed mainly in intestine, and the enzyme was detected in the duodenal mucosa as a 70 kDa protein. Immunohistochemical analysis of the small intestinal tissue showed that the enzyme is localized mainly on brushborder membranes.     

Studies on a peptidase acting on a synthetic collagenase substrate Developmental pattern in rat granuloma tissue and distribution of enzyme in the tissues of various animals

The developmental pattern in experimental rat granuloma tissue and the distribution in the tissues of a few animals (monkey, rabbit, guinea pig anrat) of a peptidase acting on a synthetic collagenase substrate, 4-phenylazobenzyloxycarbonyl-L-Pro-L-Leu-Gly-L-Pro-D-Arg (Pz-peptide) has been studied. Maximum enzyme activity was found in 4-month-old rats and on the fourth day of implantation of the cotton wick. Pz-peptidase appears to have a ubiquitous distribution in animal tissues; the highest enzyme activity was generally found in liver, intestine and kidney of the animals. The total activity in other organs (spleen, heart, lungs and brain) was much less compared to that of liver, intestine or kidney.     

Oxidative deamination of biogenic amines by intestinal amine oxidases: histamine is specifically inactivated by diamine oxidase.

The ability of the gut to inactivate various amines by oxidative deamination was tested with a 130-fold purified amine oxidase preparation from dog small intestine. Of 34 amines tested, putrescine, benzylamine, cadaverine, and serotonin were the most favourable substrates. Histamine was inactivated rapidly by this enzyme preparation, too. Histamine derivatives methylated at the imidazole nucleus were also deaminated, whereas Nalpha-methylhistamine was only a poor substrate and Nalpha, Nalpha-dimethylhistamine was not a substrate at all. Using a second procedure for the purification of amine oxidases from gut, the separation of a soluble monoamine oxidase from diamine oxidase was achieved by gel filtration on Sephadex G-200. The diamine oxidase deaminated putrescine (Km = 1.3 x 10(-4)M) and histamine (Km = 6.6 x 10(-5)M), but not serotonin, and was inhibited by aminoguanidine, but not by pargyline. The soluble monoamine oxidase inactivated serotonin (Km = 4.5 x 10(-4)M), but not histamine and putrescine and was inhibited by pargyline, but not by aminoguanidine. It was concluded that in dog small intestine (as well as in rabbit small intestine) only diamine oxidase was capable of inactivating histamine by oxidative deamination.     

Tryptophan 5-hydroxylase in rat intestine

Tryptophan 5-hydroxylase was partially purified from rat small intestine and characterized. The enzyme activity was mainly localized in the distal one-fourth of the small intestine. The enzyme required Fe(2+), 2-amino-4-hydroxy-6,7-dimethyl-5,6,7,8-tetrahydropteridine and oxygen for full activity. The pH optimum of the reaction was 8.0. The hydroxylation rate of d-tryptophan by the enzyme was one-third that of l-tryptophan. l-Phenylalanine and l-tyrosine could not serve as substrates. The physiological significance of the enzyme is discussed.     

Gamma-aminobutyric acid (GABA) formation from putrescine in guinea-pig liver during ontogenesis

1. The changes in hepatic diamine oxidase (DAO) activity of the foetal and maternal origin and their relations to GABA formation during pregnancy in guinea-pigs are described. 2. Foetal DAO activity continuously increased while the maternal enzyme from the 45th day of gestation onwards decreased. 3. Conversion of putrescine to GABA via oxidative deamination has been detected in the earliest studied day i.e. the 34th.