The depression of the synthesis of pea diamine oxidase due to light and the verification of its participation in growth processes using competitive inhibitors

The time courses of the synthesis of diamine oxidase in pea plants grown for 14 days either in the light or in the dark are similar with the highest increase in activity occurring in the cotyledons and in the shoots during the first 6 to 8 days. Plants grown in the dark showed a 2- to 3-fold higher enzyme activity than plants grown in the light. Pea diamine oxidase could bein vivo efficiently inhibited by substrate analogues 1,4-diamino-2-butanone and 1,5-diamino-3-pentanone. The first compound inhibited proportionally to its concentration the growth of etiolated pea plants, but its instability makes an unequivocal interpretation of the results difficult. On the other hand, 1,5-diamino-3-pentanone a stable and more efficient diamine oxidase inhibitor depressed the growth of pea seedlings only at concentrations as high as 5 mM and 10 mM, at which the growth of cress seedlings not containing diamine oxidase was also strongly depressed. The results obtained indicate that tryptamine oxidation catalyzed by diamine oxidase is not involved in the main metabolic pathway leading from tryptophan to indoleacetate in pea plants.     

Pathological changes in platelet histamine oxidases in atopic eczema

Increased plasma histamine levels were associated with significantly lowered diamine and type B monoamine oxidase activities in platelet-rich plasma of atopic eczema (AE) patients. The diamine oxidase has almost normal cofactor levels (pyridoxal phosphate and Cu(2+)) but the cofactor levels for type B monoamine oxidase (flavin adenine dinucleotide and Fe(2+)) are lowered. The biogenic amines putrescine, cadaverine, spermidine, spermine, tyramine and serotonin in the sera, as well as dopamine and epinephrine in EDTA-plasma were found to be normal. It is unlikely, therefore, that these amines are responsible for the decreased activities of monoamine and diamine oxidase in these patients. The most likely causative factors for the inhibition of the diamine oxidase are nicotine, alcohol, food additives and other environmental chemicals, or perhaps a genetic defect of the diamine oxidase.     

Occurrence of diamine oxidase in the apoplast of pea epicotyls

Most of the diamine oxidase (EC 1.4.3.6) present in pea (Pisum sativum L. cv. Rondo) epicotyls is found in the fluid obtained by centrifuging pea epicotyl sections previously infiltrated under vacuum with a buffer solution. No detectable amount of the cytoplasmic enzyme glucose-6-phosphate dehydrogenase is present in this fluid, showing that there is very little contamination by cell contents. Polyacrylamide-gel electrophoresis and specific-activity data indicate that diamine oxidase is the most plentiful protein in the extracellular solution obtained from pea epicotyl sections and that an active process is involved in the selective transfer of the enzyme outside the cell. The possible involvement of diamine oxidase in the supply of H₂O₂ to peroxidase-catalyzed reactions occurring inside the cell wall is discussed.Abbreviations DAO diamine oxidase - Glc6P glucose-6-phosphate     

The significance of the cotyledons for the formation of diamine oxidase in pea plants

The effect of the removal of cotyledons on the growth of etiolated pea plants and on the changes in diamine oxidase activity were followed. Plants with removed cotyledons showed higher diamine oxidase activity both in the shoots and in the roots when expressed per fresh weight unit. Higher diamine oxidase activity can be found also in the remaining cotyledon when one of the two cotyledons is removed (when expressed per fresh weight unit and per cotyledon). The plants belonging to those experimental variants in which a higher diamine oxidase activity was established (plants without cotyledons) had simultaneously a high content of its substrates. These plants at the same time contained in the shoots and in the roots smaller amounts of potassium. On the other hand, these findings cannot be applied when comparing individual organs (shoots and roots), as higher diamine oxidase activity can be found in the shoots than in the roots, but the content of its substrates is in the shoots lower. These data indicate that the relationship between the activity of diamine oxidase and the content of its substrates is probably rather complicated. In the connection with the fact that a high diamine oxidase activity can occur in the plant simultaneously with a high content of its substrates, it is possible to assume that (a) changes in the pattern of substrates may occur after the removing of the cotyledons, (b) the synthesis of diamine oxidase may be induced owing to a higher accumulation of substrates, (c) the enzyme may be spacially separated from the substrates in the cells.     

Inhibition of plant and mammalian diamine oxidases by hydrazine and guanidine compounds

1. Pig kidney and pea seedling diamine oxidases have similar sensitivity to methylhydrazine and phenylhydrazine as inhibitors. 2. Inhibition of pig kidney and pea seedling enzymes by hydrazine and guanidine compounds is time dependent. To reveal full inhibitory potency, methylhydrazine and aminoguanidine need longer preincubation with plant diamine oxidase as compared with mammalian diamine oxidase. 3. Impromidine, a known H2 histamine receptor agonist with guanidine and imidazole structures, and aminoguanidine have higher inhibitory activity towards pig kidney enzyme in comparison with the pea seedling one. 4. Impromidine inhibits pig kidney diamine oxidase in a noncompetitive manner. The Ki value is 6.6 muM. 5. The 24 hr dialysis of rat intestinal diamine oxidase preincubated with phenylhydrazine or impromidine only partially recovered the enzymic activities. 6. Impromidine inhibits mouse intestinal diamine oxidase in vivo.     

Regulation of diamine oxidase expression by beta 2-adrenoceptors in normal and hypertrophic rat kidney

The administration of preferential adrenergic receptor antagonists to uninephrectomized rats revealed the beta 2-adrenergic mediation in diamine oxidase activity increase that occurs in the remaining kidney undergoing compensatory hypertrophy. In fact, beta 1, beta 2- or beta 2, but not alpha 1-, alpha 2-, or beta 1-receptor-blocking agents prevented this enzyme enhancement. Further studies with adrenoceptor agonists, such as epinephrine (alpha 1, alpha 2, beta 1, beta 2), isoproterenol (beta 1, beta 2) or terbutaline (beta 2) showed that also in normal rat kidney diamine oxidase activity is under the control of catecholamine-beta 2-receptors through a mechanism that involves new synthesis of mRNA and protein. Theophylline, an inhibitor of phosphodiesterase, or forskolin, an activator of adenyl cyclase, increased diamine oxidase activity as does epinephrine or nephrectomy. Thus, catecholamine-triggered beta 2-receptors coupled to adenyl cyclase are involved in the regulation of diamine oxidase activity in normal and hypertrophic rat kidney.     

Induction of diamine oxidase activity in rat kidney during compensatory hypertrophy

Diamine oxidase (EC 1.4.3.6) activity, measured as [¹⁴C]Δ¹-pyrroline formation from [¹⁴C] putrescine, was studied in homogenates of rat kidney during compensatory hypertrophy after unilateral nephrectomy. Acetaldehyde and to a lesser degree phenobarbital, at concentrations which did not modify the activity of a preparation of hog kidney diamine oxidase, increased Δ¹-pyrroline formation in kidney homogenate, which suggests that aldehyde-metabolizing enzymes present in this tissue may interfere with yield of Δ¹-pyrroline and that the use of acetaldehyde may give better information on kidney diamine oxidase activity. Other inhibitors of aldehyde-metabolizing enzymes such as chloral hydrate, disulfiram, and pyrazole cannot be used for diamine oxidase determination since they stimulated or depressed this enzyme activity. In rat kidney undergoing compensatory hypertrophy the levels of putrescine, spermidine, and spermine increased rapidly and were followed by an increase in diamine oxidase activity that presented a first peak on day 2 and a second peak on day 6. The administration of cycloheximide or actinomycin D to nephrectomized rats prevented the increase in diamine oxidase activity. The study of the turnover rate of diamine oxidase with cycloheximide demonstrated that the half-life of this enzyme was about 14 h in normal and hypertrophic kidney. These results suggest that the increase in diamine oxidase activity in renal hypertrophy was due to the synthesis of new enzyme rather than to a slowing of its degradation.     

Diamine Oxidase in Cotyledons of Pisum sativum Develops as a Result of the Supply of Oxygen through the Embryonic Axis during Germination

The activity of diamine oxidase (EC 1.4.3.6.) in pea, Pisum sativum cv Alaska, cotyledons was studied. The rapid hydration caused by soaking seeds in water, the excision of the embryonic axis, and the suppression of the elongation of the embryonic axis by indoleacetic acid generate anaerobic conditions in these cotyledons that suppress diamine oxidase activity. These results show that oxygen is essential for the induction of diamine oxidase activity in pea cotyledons. During germination cotyledonary diamine oxidase develops as a result of the supply of oxygen through the embryonic axis of the intact pea seedling.     

The amine oxidases of human placenta and pregnancy plasma

1. The purification of monoamine oxidase and diamine oxidase from normal human term placental tissue is described. 2. The properties of these enzymes are reported and compared with the properties of unpurified human pregnancy plasma. 3. This comparison shows that the amine oxidase of pregnancy plasma has properties corresponding to purified placental diamine oxidase, suggesting a placental origin for the plasma enzyme system. 4. Detailed kinetic study of the purified placental diamine oxidase suggests that it has a Ping Pong sequence, a mechanism of action and rate-limiting step similar to the diamine oxidase of pig kidney. 5. It is suggested that the enzyme system is important in protecting the foeto-placental unit from excesses of biogenic amines.     

Polyamine levels and diamine oxidase activity in hypertrophic heart of spontaneously hypertensive rats and of rats treated with isoproterenol

Polyamine levels and diamine oxidase (EC 1.4.3.6) activity were studied in hypertrophic heart of spontaneously hypertensive rats as well as in the heart of Wistar rats during the development and regression of cardiac hypertrophy induced by isoproterenol administration. In spontaneously hypertensive rats, putrescine content and diamine oxidase activity were higher than those found in normotensive Kyoto-Wistar control rats. During the development of cardiac hypertrophy induced by isoproterenol, there was an increase in polyamine content and diamine oxidase activity. The administration of cycloheximide or actinomycin D prevented the increase in diamine oxidase activity during the first 24 h after isoproterenol administration, demonstrating that the rise in diamine oxidase activity was due to synthesis of new enzyme. Following the cessation of isoproterenol treatment, cardiac hypertrophy regressed and polyamine levels and diamine oxidase activity diminished toward control values. The administration of aminoguanidine to isoproterenol-treated rats caused in the heart an inhibition of diamine oxidase activity that led to an increase in putrescine level beyond the values found in animals given isoproterenol alone. The results suggest that the enhancement of diamine oxidase activity plays a role in the regulation of putrescine level in hypertrophic heart.     

Involvement of superoxide in the catalytic cycle of diamine oxidase.

The reaction of pig kidney diamine oxidase (amine:oxygen oxidoreductase (deaminating) (pyridoxal-containing), EC 1.4.3.6) could be significantly inhibited by superoxide dismutase active copper chelates but not by native 2Cu,2Zn-superoxide dimutase (cuprein). The ligands alone as well as Cd2+, a heavy metal of similar toxicity to Cu2+, showed no inhibition whatsoever. This indicates that .O-2 participates in the catalytic cycle and is produced at a site scarcely accessible to such a large molecule as cuprein. A mechanism for the second, aerobic step of the diamine oxidase reaction is suggested.     

Release of intestinal diamine oxidase by histamine in rats

Diamine oxidase activity was measured in the intestinal mucosa, lymph, and in the serum of rats, to determine whether histamine, a substrate of diamine oxidase, liberates this enzyme from its mucosal storage site(s). Histamine induced a sharp rise in intestinal lymph flow, lymph protein, and lymph diamine oxidase, lasting less than 1 h after the histamine injection. The rise in lymph diamine oxidase activity was dose dependent over a narrow concentration range (0.05-0.2 mmol/kg, i.v. and 0.15-0.6 mmol/kg i.d.). It did not correlate with the dose dependent increase in lymph flow or lymph protein. A single maximal intraduodenal dose of histamine caused a 41.6-fold increase in the lymph diamine oxidase activity and a 2.4-fold increase in the serum enzyme level temporarily. A second injection of histamine, 2 h after the first, resulted in a comparatively smaller increase in the lymph enzyme. The extent of the reduction was dependent on the magnitude of the first injection. The results suggest that histamine causes a limited liberation of diamine oxidase from the intestinal mucosa. The function of this enzyme release may be a protective response by the mucosa to reduce toxic levels of free histamine, either liberated by the mucosal tissue or absorbed from the intestinal lumen.     

Light promotes the synthesis of lignin through the production of H2O2 mediated by diamine oxidases in soybean hypocotyls

In order to analyze the relationship between polyamine oxidative degradation induced by light and the lignin synthesis in cell walls, the activities of diamine oxidases and peroxidase, the contents of H₂O₂ and lignin, and the growth of hypocotyls in soybean [Glycine max (Linn.) Merr.] grown under light or in darkness were investigated. In comparison with the dark treatment, light irradiation significantly inhibited the growth of soybean hypocotyls and promoted the activities of diamine oxidases and peroxidase as well as the accumulation of H₂O₂ and lignin. Treatments with the different concentrations of diamine oxidase inhibitors (2-hydroxyethylhydrazine and aminoguanidine) under the light condition inhibited diamine oxidase activity, and decreased the contents of H₂O₂ and lignin. The results provide evidence for the hypothesis that light irradiation could promote the accumulation of H₂O₂ and lignin in cell walls by activating polyamine oxidative degradation mediated by diamine oxidases.     

Isotopically sensitive regioselectivity in the oxidative deamination of a homologous series of diamines catalyzed by diamine oxidase.

The equivalence of aminomethylene groups in selected diamine substrates of diamine oxidase was exploited for the determination of intramolecular isotope effects. In the series of substrates, [1,1-2H2]-1,3-diaminopropane, [1,1-2H2]-1,5-diaminopentane, [1,1-2H2]-1,6-diaminohexane, [1,1-2H2]-1,7-diaminoheptane and [alpha,alpha-2H2]-4-(aminomethyl)benzylamine, the preference of the enzyme for reaction at the unlabeled methylene was found to vary from 1.45 to 10.5-fold. The observed partitioning ratios go through a minimum value with 1,5-diaminopentane, the best substrate of diamine oxidase of the compounds tested. The results suggest that fast substrates have less opportunity to reorient into alternate binding conformations while bound to the active site of the enzyme. On the other hand, diamine substrates tested that cannot exist in energetically favorable conformations with internitrogen distances of about 7-8 A showed larger intramolecular isotope effects.     

Spermidine oxidase in human pregnancy serum. Probable identity with diamine oxidase.

Diamine oxidase was previously measured in human pregnancy serum with putrescine or histamine as substrate. We have now documented the presence of spermidine oxidase activity in pregnancy serum by means of a specific radioactive assay with [14C]spermidine as substrate and Dowex 50 cation-exchange chromatography to separate products from substrate. The apparent Km of a partially purified preparation of this enzyme for spermidine was 10.9 microM and the Ki for aminoguanidine was 0.8 microM. The pH optimum (pH 9.0) and temperature optimum (55 degrees C) were identical with those for diamine oxidase. Spermidine oxidase activity and diamine oxidase activity eluted in a concerted fashion when pregnancy serum was subjected to cadaverine-Sepharose chromatography, gel filtration and ion-exchange chromatography. Spermidine oxidase became detectable in serum during pregnancy in the human approx. 8 weeks after the last menstrual period and increased with gestational age in concert with the increase in diamine oxidase activity, reaching a plateau at 20 weeks of gestation. Foetal-cord serum displayed virtually no activity of either enzyme. A 400-fold-purified preparation of diamine oxidase retained the same diamine oxidase/spermidine oxidase ratio as exhibited by crude pregnancy serum. These data suggest that in pregnancy serum, unlike foetal bovine serum, spermidine oxidase and diamine oxidase activity may be a single enzyme protein.     

Inhibition of bovine plasma amine oxidase by 1,4-diamino-2-butenes and -2-butynes

Bovine plasma amine oxidase (BPAO) was previously shown to be irreversibly inhibited by propargylamine and 2-chloroallylamine. 1,4-Diamine versions of these two compounds are here shown to be highly potent inactivators, with IC50 values near 20 microM. Mono-N-alkylation or N,N-dialkylation greatly lowered the inactivation potency in every case, whereas the mono-N-acyl derivatives were also weaker inhibitors and enzyme activity was recoverable. The finding that the bis-primary amines 1,4-diamino-2-butyne (a known potent inhibitor of diamine oxidases) and Z-2-chloro-1,4-diamino-2-butene are potent inactivators of BPAO is suggestive of unexpected similarities between plasma amine oxidase and the diamine oxidases and implies that it may be unwise to attempt to develop selective inhibitors of diamine oxidase using a diamine construct.     

The inactivation of pea-seedling diamine oxidase by peroxidase and 1,5-diaminopentane

1. The rate of oxidative deamination of 1,5-diaminopentane by pea-seedling extracts, which contain diamine oxidase [diamine-oxygen oxidoreductase (deaminating), EC 1.4.3.6], was increased by adding pyridoxal or pyridoxal phosphate. 2. Evidence was obtained that pyridoxal does not activate the apoenzyme of diamine oxidase, but prevents the inactivation of the enzyme. 3. This inactivation only occurred when 1,5-diaminopentane was the substrate and depended on a second thermolabile factor in the extract besides the diamine oxidase. 4. Purified diamine oxidase, when catalysing the oxidation of 1,5-diaminopentane, was rapidly inactivated in the presence of peroxidase. 5. The inactivation was prevented not only by pyridoxal and pyridoxal phosphate but also by several unrelated compounds including alpha-oxoglutarate, catechol and o-aminobenzaldehyde. 6. It is suggested that peroxidase catalyses the further oxidation of the product of the oxidative deamination of 1,5-diaminopentane to a compound that inactivates diamine oxidase. 7. The results diminish the relevance of previous evidence that plant diamine oxidase contains pyridoxal phosphate.     

Stimulation of hepatic and renal diamine oxidase activity after acute ethanol administration

The effect of a single administration of ethanol (2 g/kg body weight) on hepatic and renal diamine oxidase activity was studied in fasted rats. Diamine oxidase activity significantly increased in liver and kidney 6 h after ethanol intubation. Pyrazole (an inhibitor of alcohol dehydrogenase), cycloheximide or actinomycin D (inhibitors of macromolecular syntheses), as well as prior adrenalectomy, prevented the ethanol-induced stimulation of diamine oxidase in the liver, but not in the kidney. The results demonstrated that the enhancement of diamine oxidase activity in the liver was due to an enzyme induction mediated by alcohol metabolism as well as by adrenals. In contrast, the stimulation of diamine oxidase activity in the kidney did not depend on synthesis of new enzyme molecules and was not mediated by ethanol metabolism or adrenal hormones.     

Purification of human placenta diamine oxidase.

Diamine oxidase (histaminase) is produced at very high levels by the decidual cells of the placenta. The presence of diamine oxidase has been demonstrated in human neutrophils. Purification of human placenta diamine oxidase was performed by four subfractionation steps and led to the isolation of one polypeptide whose molecular weight was 84,000, as assessed by SDS PAGE. Using polyclonal antibodies raised against the purified enzyme, we have demonstrated that the neutrophil diamine oxidase is immunochemically identical to the placental diamine oxidase. Development of immunological methods will be useful for detection and quantitation of diamine oxidase in neutrophils during the inflammation process.     

Monoamine and diamine oxidative deamination in the longitudinal smooth muscle of guinea pig ileum

The longitudinal smooth muscle of guinea pig ileum contains three different types of oxidative deaminating enzymes: monoamine oxidase types A and B, diamine oxidase and a soluble clorgyline-deprenyl-resistant benzylamine oxidase. These enzymes have different subcellular locations. The longitudinal smooth muscle of guinea pig ileum oxidatively deaminates beta-phenylethylamine at a much higher rate than benzylamine. beta-Phenylethylamine is a good substrate for monoamine oxidase type B but also for the soluble clorgyline-deprenyl-resistant benzylamine oxidase. On the other hand, benzylamine is oxidised by mitochondrial monoamine oxidase, by the clorgyline-deprenyl-resistant enzyme and by diamine oxidase.