Proton nuclear magnetic resonance studies of mast cell histamine

The state of histamine in mast cells was studied by 1H NMR spectroscopy. Spectra were measured for histamine in situ in intact mast cells, for histamine in suspensions of mast cell granule matrices that had been stripped of their membranes, and for histamine in solutions of heparin. The 1H NMR spectrum of intact mast cells is relatively simple, consisting predominantly of resonances for intracellular histamine superimposed on a weaker background of resonances from heparin and proteins of the cells. All of the intracellular histamine contributes to the NMR signals, indicating it must be relatively mobile and not rigidly associated with the negatively charged granule matrix. Spectra for intracellular histamine and for histamine in granule matrices are similar, indicating the latter to be a reasonable model for the in situ situation. The dynamics of binding of histamine by granule matrices and by heparin are considerably different; exchange of histamine between the bulk water and the granule matrices is slow on the 1H NMR time scale, whereas exchange between the free and bound forms in heparin solution is fast. The chemical shifts of resonances for histamine in mast cells are pH dependent, decreasing as the intragranule pH increases without splitting or broadening. The results are interpreted to indicate that histamine in mast cells is relatively labile, with rapid exchange between bound histamine and pools of free histamine in water compartments confined in the granule matrix.     

Changes in Histamine Content in Fish Products for Animal Feeds and in Aqueous Solution by Gamma-Irradiation

The irradiation effects on histamine in fish meals and fish solubles for animal feeds and in aqueous solution were investigated. The amount of histamine in fish meal (0.4mg/100g) was not changed by up to 5.0 Mrad (50kGy), while the histamine content in fish soluble (45.7 mg/100 g) decreased ca. 16% at 5.0 Mrad. There occurred no accumulation of histamine by irradiation or during storage.

The G values of histamine formation from histidine solution and histamine decomposition by irradiation in deoxygenated neutral solutions were 0.077 and 1.90, respectively. Oxygen inhibited the formation of histamine from histidine but it had little effect on histamine decomposition. Nitrous oxide accelerated the decomposition of histamine and inhibited the accumulation of histamine in histidine solution by irradiation. These results show that there is no problem of histamine accumulation in feedstuffs caused by irradiation since the decomposition of histamine is preferred to its formation.     

Uptake and methylation of histamine by dispersed gastric mucosal cells and its possible influence on acid secretion

Inactivation of histamine by gastric mucosal tissue was examined in dispersed rabbit gastric mucosal cells. Mucosal cells were incubated with [14C]histamine. The formed radioactive metabolites were separated and identified by thin layer co-chromatography and quantitated, in both the cellular and extracellular mediums. Gastric mucosal cells internalized histamine, most of which was immediately methylated primarily to N tau-methylhistamine and released. Cellular histamine product accumulation reached a plateau. The rate of histamine methylation increased with increasing extracellular histamine concentration, moving towards a plateau above 5 microM. Histamine methylation was greatly decreased but not abolished at 4 degrees C, in the absence of Na+ and by phlorizin (0.5 mM), an inhibitor of Na(+)-dependent co-transport. Inhibition of histamine N-methyltransferase decreased intracellular methylhistamine content dose dependently without increasing intracellular histamine. The secretagogues pentagastrin and carbachol did not influence histamine metabolism but ethanol inhibited methylation. The data suggest that gastric mucosal cells take up histamine by a Na(+)-dependent and Na(+)-independent process. The histamine uptake capacity appears to be linked to the methylation activity within the cell. The decrease in histamine uptake and metabolism caused by ethanol could potentially increase histamine concentrations near the target cells and be the reason for the stimulatory effect of ethanol on acid secretion.     

The subcellular localization of histamine and histamine methyltransferase in rat brain

Abstract— We have examined the subcellular localization of histamine and histamine methyl-transferase (S-adenosylmethionine: histamine 7V-methyltransferase; EC 2.1.1.8) in rat brain. The highest levels of histamine and histamine methyltransferase activity were found in the hypothalamus. A large proportion of hypothalamic histamine and histamine methyltransferase activity was found in particles with sedimentation properties in sucrose gradients similar to synaptosomes storing norepinephrine and serotonin. Histamine displayed a bimodal distribution in sucrose gradients. A substantial amount of a tracer dose of [³H]histamine added to hypothalamic homogenates at 4°C was bound to particulate fractions, suggesting that endogenous histamine may redistribute and bind to subcellular fractions during homogenization. The second, lighter peak of histamine in sucrose gradients was thought to be due to histamine that redistributed during homogenization.     

Characterization of Extracellular Histamine in the Striatum and Bed Nucleus of the Stria Terminalis of the Rat: An In Vivo Microdialysis Study

The intracerebral microdialysis technique, coupled with a sensitive radioenzymatic assay, was employed to study histamine release in the striatum and in the bed nucleus of the stria terminalis (BNST) in conscious, freely moving rats. In these brain regions, extracellular histamine concentrations decreased by 20% when calcium was omitted from the perfusion solution. Extracellular histamine was insensitive to the addition of tetrodotoxin to the perfusion medium. In striatum, extracellular histamine concentrations declined in an apparent biexponential manner after the administration of alpha-fluoromethylhistidine, an inhibitor of histamine synthesis. The half-lives for the disappearance of histamine were 32 min and 7.7 h, indicating the presence of at least two histamine pools. Histidine loading resulted in a nearly twofold increase in histamine outflow in striatum. In the BNST, yohimbine increased the extracellular histamine content by 50%, suggesting that histamine release is subject to alpha 2-adrenergic regulation in vivo. The extent to which histamine detected in cerebral microdialysis samples is of neurogenic origin remains to be established.     

Histamine metabolism in the visual system of the horseshoe crab Limulus polyphemus

There is now strong evidence that arthropod photoreceptors use histamine as a neurotransmitter. The synthesis, storage and release of histamine from arthropod photoreceptors have been demonstrated, and the postsynaptic effects of histamine and the endogenous neurotransmitter are similar. However, a full understanding of these photoreceptor synapses also requires knowledge of histamine inactivation and metabolism. Relatively little is known about histamine metabolism in the nervous system of arthropods, and mechanisms appear to differ with the species. This study focuses on histamine metabolism in visual tissues of the horseshoe crab Limulus polyphemus, a chelicerate. We present two major findings: (1) histamine is metabolized to imidazole acetic acid and to gamma-glutamyl histamine. (2) relatively low levels of histamine metabolites accumulate in Limulus visual tissues.     

Dynamics of the regulation of histamine levels in mouse brain

Abstract— The intraperitoneal administration of L-histidine in a dose of 1000 mg/kg increased threefold the whole brain levels of histamine in the mouse. This increase was evident in all brain regions except the medulla oblongata-pons. The subcellular localization of histamine and histidine was the same in mice administered bhistidine as in salinetreated animals. Cold exposure and restraint further augmented the elevation of histamine elicited by histidine treatment. a-Hydrazino-histidine and 4-bromo-3-hydroxybenzyloxyamine (NSD-1055) but not a-methyl-DOPA inhibited histidine decarboxylase [EC 4.1.1.221 activity in mouse brain homogenates and prevented the increase in brain histamine after histidine administration. NSD-1055 and a-hydrazino-histidine also lowered brain levels of histamine by 50 per cent. NSD-1055 lowered whole brain levels of histamine rapidly, with a half-life for the depletable histamine pool of about 5 min. Assuming that inhibition of histidine decarboxylase accounted for the reduction in histamine, then the rate of histamine decline reflects the rate of histamine turnover, and our results suggest that a portion of mouse brain histamine turns over quite rapidly. Reserpine lowered brain levels of histamine by about 50 per cent, whereas the antihistaminic agent, dexbrompheniramine, and sodium pentobarbital elevated histamine levels.     

Possible role of histamine in brain function: neurochemical, physiological, and pharmacological indications

Recently accumulated neurochemical, physiological, and pharmacological evidence strongly supports a role for histamine as a central neurotransmitter. Neurochemical methods, which became available within the last years, allow determination of small amounts of histamine and its metabolites in the brain and make possible future studies of central histamine regulation. The demonstration of histamine H1 and H2 receptors in the brain of several species suggests a possible role for histamine in brain function. Microelectrophysiological studies on single central neurones suggest both excitatory and depressant effects of histamine which are receptor mediated. In addition, brain histamine has been demonstrated to be subject to cyclic variations, to play a role in hormonal regulation, and to be altered by stressful conditions. Several psychotropic drugs significantly affect brain histamine regulation and elicit inhibitory effects on central histamine receptors. These findings bring new approaches and stimulus to further research on the significance of brain histamine.     

Histamine in the Insect Nervous System: Distribution, Synthesis and Metabolism

Abstract: The distribution of histamine in the nervous systems of the locust, the cockroach, and the sphinx moth was mapped and the capacity of locust nervous tissue to synthesise and metabolise histamine was assessed. In all three species the highest levels of histamine were present in the retina and in the lamina neuropil of the optic lobe. Lower levels of histamine were detectable throughout the nervous system. In the locust the retina was shown to synthesise considerable quantities of histamine. The optic lobe and metathoracic ganglion synthesised smaller, though significant, amounts of histamine. Metabolic in activation of histamine in locust nervous tissue was shown to occur primarily via oxidation to imidazole-4-acetic acid and via N-acetylation to N -acetyl histamine. Whereas the retina and the optic lobe formed the two metabolic products in approximately equal proportions, the metathoracic ganglion produced almost three times as much N- acetyl histamine as imidazole-4-acetic acid.     

Histamine dependence of pentagastrin-stimulated gastric acid secretion in rats.

Does gastrin stimulate gastric acid secretion by direct action on oxyntic cells, by releasing histamine, or by being potentiated by histamine? Previous studies in the mouse pointed to gastrin-regulated histamine release. Guinea pig and rat are well known to vary in their sensitivity to histamine. Therefore, the effects of histamine and pentagastrin were compared quantitatively on isolated, lumen-perfused, stomach preparations from these species in the absence and presence of histamine H2-receptor blockade. The loss of potency of histamine in the rat was mirrored by a loss of potency of pentagastrin consistent with the idea that pentagastrin acts by releasing histamine. In the rat, a well-defined pentagastrin curve was obtained in the presence of histamine H2-receptor block as though pentagastrin acts both directly on the oxyntic cell and indirectly by releasing histamine. It was not necessary to invoke a potentiating interaction between histamine and pentagastrin at the oxyntic cell; the two effects appeared simply to add. Potentiation was observed, however, between other combinations of stimuli, for example, between vagal nerve and pentagastrin stimulation. The physiological consequences of these results are discussed.     

Ontogeny and Subcellular Distribution of Rat Brain Tele-Methylhistamine

Abstract: The whole brain content and subcellular distribution of histamine and its metabolite, tele-methylhistamine, were studied during postnatal development of the rat. Brain methylhistamine levels were similar to or greater than histamine levels, indicating that histamine methylation is a major metabolic pathway in neonatal brain, as it is in adults. When calculated per brain, histamine, methylhistamine, and histamine methyltransferase were all maximal 10 days after birth. In neonates, brain histamine was found almost entirely in nuclear fractions, whereas methylhistamine was found almost exclusively in supernatant fractions. By day 20, however, a greater proportion of both amines was localized in subcellular fractions containing synaptosomes, a finding consistent with histamine's suggested transmitter role. The ontogenic pattern of brain methylhistamine questions the mast cell origin of neonatal histamine, but may be consistent with a role for histamine in brain development.     

Influence of blood sampling conditions upon histamine concentrations in rat plasma: a study of a complex relationship with plasma epinephrine

The concentrations of histamine reported vary considerably from species to species. The present studies sought to determine if blood sampling techniques were at least in part responsible for this large variability. Since plasma catecholamines are influenced by the stress associated with blood sampling, these biogenic amines also were measured. Finally, we explored the possible existence of a relationship between plasma histamine and plasma catecholamine concentrations.The present study confirms that concentrations of histamine in rat plasma are particularly large and establishes that the manner (e.g. awake, anesthetized) and site (e.g. intravenous, decapitation) of blood removal influence the concentrations obtained. The lowest histamine values were seen in samples taken from blood vessels in anesthetized rats. Blood obtained after decapitation showed increasing concentrations of plasma histamine in sequentially obtained samples.An inverse relationship appeared to exist between plasma histamine and plasma catecholamines (predominantly epinephrine). An inhibitory role of epinephrine upon decapitation-associated histamine release was suggested by the observation that both adrenalectomy and catecholamine depletion (alpha-methyl-para-tyrosine) elevated histamine concentrations. Our studies with propranolol, as well as work by other investigators, establish an inhibitory role of β-receptor stimulation on the release of histamine. On the other hand, histamine injected into the perfused rat adrenal caused a marked release of adrenomedullary catecholamines.In summary our study suggests the presence of a complex interaction between catecholamines and histamine in the regulation of the release of the individual amines. Our findings point to the existence of a histamine-adrenal axis in which the release of histamine may facilitate the release of epinephrine which in turn may restrict further release of histamine.     

Localization of histamine in uterine structures

By means of luminescent-histochemical method of Cross, Even, Rost histamine is revealed in all uterine structures. Visual and fluorometric data demonstrate uneven distribution of histamine in the organ's structures. A high content of histamine is specific for macrophages and mast cells, less high--in tegmental epithelium and endometrial glands. A low level of histamine have endometrial stroma, smooth myocytes, cells of the serous membrane and vessels. Basing on the literature data, concerning various sensitivity of the uterine tissues to estrogens and regarding effect of the estrogens upon histamine metabolism in the uterine and regarding interconnection of the histamine receptors in the uterus and the estrogens, a suggestion is made that various contents of histamine in the uterine structures depend on various amount of the histamine receptors in them and on different abilities of the uterine tissues to inactivate histamine. The ability of macrophages to accept free forms of bioamines, as it is described in the literature, evidently can be spread to the uterine macrophages, where a high content of histamine is revealed.     

Refractoriness for ultrasonically nebulized distilled water and histamine after histamine challenge

Refractoriness for bronchial provocation frequently occurs after different challenge tests used to assess bronchial hyperresponsiveness in asthmatic patients. We investigated whether histamine inhalation could cause refractoriness for bronchoconstriction induced by ultrasonically nebulized distilled water (UNDW) and whether histamine causes tachyphylaxis for a subsequent histamine challenge in nine stable asthmatic patients. Preinhalation of histamine induced a significant diminished bronchoconstrictor response to UNDW cumulative dose of inhaled UNDW causing a 20% fall in forced expired volume in 1 s. The mean increased from 3.5 +/- 0.8 to 11.8 +/- 2.6 (SE) ml after histamine challenge (P less than 0.01). However, repeated inhalation of histamine did not change the bronchoconstrictor response to histamine within 1 h after rechallenge (P greater than 0.5). The magnitude of refractoriness for UNDW inhalation after preinhalation of histamine was correlated to the bronchoconstrictor response to histamine (r = 0.73, P less than 0.05). We conclude that inhaled histamine can induce refractoriness for UNDW, which seems to be related to the degree of bronchial hyperresponsiveness.     

Histamine release and SOD, allopurinol and ranitidine pretreatment in haemorrhagic shock in the rat.

Histamine release have been demonstrated in haemorrhagic shock. There are some observations that oxygen free radicals can cause histamine release. Oxygen free radicals play a role in the pathogenesis of gastric mucosal lesions. The goal of this study was to determine whether ranitidine or SOD and allopurinol pretreatment modify the histamine release during and after the haemorrhagic shock in the rat. In the anaesthetized rat 0.1 N HCl was instilled into the stomach and the rat was bled to reduce the blood pressure to 30 mmHg for 20 min. The shed blood was reinfused. Twenty min later the stomach was removed. The area of gastric mucosal lesions were measured, histological grading was made. Blood samples taken from the carotid artery were examined by radioimmunoassay (IMMUNOTECH) to determine the plasma histamine level. Plasma histamine level did not change significantly during the preparative surgery, but there was a significant increase of histamine level by the end of shock period. After the reinfusion of the blood the plasma histamine remained essentially at the same level for five min. Oxygen free radicals did not cause an important histamine release. By the end of the experiment the histamine level decreased dramatically. Ranitidine, allopurinol and SOD pretreatment provided significant protection against the gastric mucosal lesions. Allopurinol and SOD did not influence significantly the histamine level. Ranitidine caused significant histamine release immediately after the injection and every histamine value was significantly higher in this group except for the final value which was lower than the control one. The oxygen free radicals were not found as endogenous histamine releasers in this study.     

H3-Receptors Control Histamine Release in Human Brain

The regulation of histamine release was studied on slices prepared from pieces of human cerebral cortex removed during neurosurgery and labeled with L-[3H]histidine. Depolarization by increased extracellular K+ concentration induced [3H]histamine release, although to a lesser extent than from rat brain slices. Exogenous histamine reduced by up to 60% the K+-evoked release, with an EC50 of 3.5 +/- 0.5 X 10(-8) M. The H3-receptor antagonists impromidine and thioperamide reversed the histamine effect in an apparently competitive manner and enhanced the K+-evoked release, indicating a participation of endogenous histamine in the release control process. The potencies of histamine and the H3-receptor antagonists were similar to those of these agents at presynaptic H3-autoreceptors controlling [3H]histamine release from rat brain slices. It is concluded that H3-receptors control histamine release in the human brain.     

Biosynthesis and metabolism of histamine in the central nervous system of Carcinus maenas

The central nervous system of Carcinus maenas synthesizes radioactive histamine when incubated in the presence of [14C] histidine and pyridoxal-5' phosphate. This biosynthesis increases linearly as a function of the amount of enzyme and the incubation time. It is not effected by heart, muscle or hepatopancreas extracts nor by haemolymph. Thus histamine appears to be synthesized mainly in the nervous system. The latter is also the seat of carcinine (beta-alanylhistamine) biosynthesis. Since carcinine seems to be a product of histamine neutralization, histamine metabolism should take place in its entirety in the nervous system. Thus histamine appears to be implicated in the neuronal activity of Carcinus. Different areas of the crustacean central nervous system: brain, eyestalks and thoracic ganglionic mass biosynthesize and metabolize histamine. Thus they all could contain sites of action for histamine. The nervous systems of two other Decapodes, Cancer and Astacus also effect histamine biosynthesis but don't metabolize it into carcinine.     

Release of non-mast cell histamine from rat aorta

We previously reported that A23187 induces release of histamine from bovine intrapulmonary vein and provided pharmacological evidence against an involvement of mast cells as the source of histamine. This study was conducted to test more definitively the hypothesis that histamine is released from non-mast cell sources in blood vessels. The effects of A23187 on release of histamine were determined using rat aorta which does not contain mast cells. Aortic rings were mounted for recording of isometric tension, and following exposure to A23187 or vehicle, histamine in the bathing media was measured using enzyme immunoassay. A23187 (100 nmol/l - 10 micromol/l) induced concentration-related release of histamine from rings with endothelium. The accumulation of histamine in the bathing media induced by 10 microM A23187 reached plateau at 60 min (6.2 +/- 1.1 pmol/mg) and was markedly and significantly higher than vehicle control (0.4 +/- 0.1 pmol/mg, p < 0.05). Destruction of endothelium significantly inhibited A23187-induced histamine release (5.5 +/- 1.5 pmol/mg with endothelium, 1.1 +/- 0.3 pmol/mg without endothelium, p < 0.05). The results demonstrate that A23187 induces release of histamine from rat aorta which does not contain mast cells and that the release of histamine is largely dependent on the presence of endothelium.     

Modulation of cellular immune function in vitro by histamine receptor-bearing lymphocytes: mechanism of action.

When soluble histamine is added to guinea pig lymphocytes in vitro, antigen-induced cellular proliferation and the production of migration inhibitory factor is suppressed. The inhibitory effects that are produced by histamine have been shown to be mediated by the histamine-type 2 receptors of the involved cells, but the exact nature of this suppression has not been fully explored. The present studies have evaluated, following immunization, the effect of histamine on macrophage function in vitro, and affinity chromatography to delete a subpopulation of cells bearing histamine receptors. When we treated monolayers of peritoneal exudate cells with histamine (up to 10^?3M) we found that histamine did not interfere with antigen binding by macrophages, macro phage presentation of antigen to lymphocytes, nor the antigen-independent or antigen-dependent lymphocyte-macrophage rosetting. Columns containing insolubilized conjugates of histamine and rabbit serum albumin depleted a subpopulation of cells responsive to histamine i.e., the non-adherent cells made migration inhibitory factor and proliferated in the presence of histamine. The latter finding suggested that the retained cells might have suppressor function and if so, might mediate their effect through the release of a soluble factor. Preliminary data obtained in these studies supports this hypothesis. We conclude that cells bearing histamine receptors may serve a regulatory role in cellular immunity after their activation by histamine by producing a non-dialyzable factor with immunosuppressive properties.     

Effects of H1 and H2 receptor antagonists on Tetrahymena.

In Tetrahymena pyriformis the phagocytotic rate increases in response to histamine, but neither the H1 antagonist phenindamine nor the H2 antagonist metiamide stimulate phagocytosis. The H1 antagonist counteracts the effect of histamine, whereas the H2 antagonist does not. The histamine receptor of Tetrahymena is of H1-type, since it cannot distinguish between histamine and antagonists which are closely related to it chemically. It does, however, distinguish between histamine and the chemically unrelated H1 antagonist, phenindamine. The H2 antagonist does not interact with the receptor.