Properties and regional distribution of histidine decarboxylase in rat brain

Histaminergic neurons in the tuberomammillary nucleus as a control centre for wakefulness

Histamine plays pleiotropic roles as a neurotransmitter in the physiology of brain function, this includes the maintenance of wakefulness, appetite regulation and memory retrieval. Since numerous studies have revealed an association between histaminergic dysfunction and diverse neuropsychiatric disorders, such as Alzheimer's disease and schizophrenia, a large number of compounds acting on the brain histamine system have been developed to treat neurological disorders. In 2016, pitolisant, which was developed as a histamine H₃ receptor inverse agonist by Schwartz and colleagues, was launched for the treatment of narcolepsy, emphasising the prominent role of brain histamine on wakefulness. Recent advances in neuroscientific techniques such as chemogenetic and optogenetic approaches have led to remarkable progress in the understanding of histaminergic neural circuits essential for the control of wakefulness. In this review article, we summarise the basic knowledge about the histaminergic nervous system and the mechanisms underlying sleep/wake regulation that are controlled by the brain histamine system. LINKED ARTICLES: This article is part of a themed issue on Neurochemistry in Japan. To view the other articles in this section visit http://onlinelibrary.wiley.com/doi/10.1111/bph.v178.4/issuetoc.

Metabolism of Amino Acids in the Brain and Their Roles in Regulating Food Intake

Amino acids (AAs) and their metabolites play an important role in neurological health and function. They are not only the building blocks of protein but are also neurotransmitters. In the brain, glutamate and aspartate are the major excitatory neurotransmitters, whereas γ-aminobutyrate (GABA, a metabolite of glutamate) and glycine are the major inhibitory neurotransmitters. Nitric oxide (NO, a metabolite of arginine), H₂S (a metabolite of cysteine), serotonin (a metabolite of tryptophan) and histamine (a metabolite of histidine), as well as dopamine and norepinephrine (metabolites of tyrosine) are neurotransmitters to modulate synaptic plasticity, neuronal activity, learning, motor control, motivational behavior, emotion, and executive function. Concentrations of glutamine (a precursor of glutamate and aspartate), branched-chain AAs (precursors of glutamate, glutamine and aspartate), L-serine (a precursor of glycine and D-serine), methionine and phenylalanine in plasma are capable of affecting neurotransmission through the syntheses of glutamate, aspartate, and glycine, as well as the competitive transport of tryptophan and tyrosine across from the blood-brain barrier. Adequate consumption of AAs is crucial to maintain their concentrations and the production of neurotransmitters in the central nervous system. Thus, the content and balance of AAs in diets have a profound impact on food intake by animals. Knowledge of AA transport and metabolism in the brain is beneficial for improving the health and well-being of humans and animals.

The histamine H3 receptor: from discovery to clinical trials with pitolisant

The third histamine receptor was discovered in 1983 by a traditional pharmacological approach, consisting of assessing the inhibitory effect of histamine on its own release from depolarized rat brain slices. The same in vitro test was used to design, in 1987, the first highly selective and potent H3-autoreceptor ligands, the antagonist thioperamide and the agonist (R)alphamethylhistamine which enhances and inhibits, respectively, the activity of histaminergic neurons in brain. The use of these research tools was instrumental in establishing the main functions of cerebral histaminergic neurons, namely their role in maintenance of wakefulness, attention, learning and other cognitive processes. In 1990, the cloning of the gene of the H3-receptor, a member of the superfamily of heptahelical receptors coupled to G proteins, paved the way to the demonstration of the high constitutive activity of the receptor, including its native form, and its participation in the tonic control of histamine release; it also facilitated the development of H3-receptor inverse agonist programs in many drug companies. Pitolisant (BF2.649, 1-{3-[3-(4-chlorophenyl)propoxy]propyl}piperidine, hydrochloride) is the first inverse agonist to be introduced in the clinics. Its wake-promotion activity was evidenced in excessive diurnal sleepiness of patients with narcolepsy, Parkinson's disease or Obstructive Sleep Apnea/Hypopnea, in which this activity is characterized by a mean decrease of the Epworth Sleepiness Scale by about five units. The procognitive activity of this novel class of drugs may also find therapeutic applications in dementias, schizophrenia or attention deficit hyperactivity disorder.

Histamine and Schizophrenia

With the availability of an increased number of experimental tools, for example potent and brain-penetrating H1-, H2-, and H3-receptor ligands and mutant mice lacking the histamine synthesis enzyme or the histamine receptors, the functional roles of histaminergic neurons in the brain have been considerably clarified during the recent years, particularly their major role in the control of arousal, cognition, and energy balance. Various approaches tend to establish the implication of histaminergic neurons in schizophrenia. A strong hyperactivity of histamine neurons is induced in rodent brain by administration of methamphetamine or NMDA-receptor antagonists. Histamine neuron activity is modulated by typical and atypical neuroleptics. H3-receptor antagonists/inverse agonists display antipsychotic-like properties in animal models of the disease. Because of the limited predictability value of most animal models and the paucity of drugs affecting histaminergic transmission that were tried so far in human, the evidence remains therefore largely indirect, but supports a role of histamine neurons in schizophrenia.

A comparison of protective effects between l-histidine and hypothermia against ischemia-induced neuronal damage in gerbil hippocampus

An increase in the histamine concentration in the brain has been demonstrated to provide protective effects against ischemia/reperfusion brain injury. Since hypothermia and barbiturates are also regarded to protect ischemic brains, effects of postischemic treatments were compared in gerbils between mild hypothermia and intraperitoneal administration of L-histidine, a precursor of histamine. Furthermore, effects of thioperamide, a histamine H(3) receptor antagonist, were evaluated in histidine-treated gerbils after 60 days. Transient forebrain ischemia for 4 min at 37 degrees C provoked severe neuronal damage in the hippocampal CA1 pyramidal cells after 7 days. Postischemic hypothermia (33 degrees C) for 3 h under pentobarbital anesthesia alleviated neuronal death, and the number of preserved neurons was 77+/-56/mm (mean+/-S.D., n=14). The effect of L-histidine injected three times, immediately, 6 h, and 24 h after reperfusion (1,000 mg/kg, i.p., each), was more prominent than that of hypothermia, and the number of preserved neurons was 142+/-55/mm (n=14). When the histologic outcome was evaluated after 60 days, most neurons were damaged in both the hypothermic and histidine groups. The improvement of the histologic outcome was observed even after 60 days in animals injected with thioperamide, immediately and 6 h after reperfusion (5 mg/kg, s.c., each), with three injections of l-histidine. The number of preserved neurons was 133+/-88/mm (n=10), while that in the hypothermic group was 7+/-15 (n=10). Activation of the central histaminergic system provides beneficial effects against cerebral ischemia.

Dose- and duration-dependent effects of betahistine dihydrochloride treatment on histamine turnover in the cat

Drugs interacting with the histaminergic system are currently used for vertigo treatment and it was shown in animal models that structural analogues of histamine like betahistine improved the recovery process after vestibular lesion. This study was aimed at determining the possible dose and duration effects of betahistine treatment on histamine turnover in normal adult cats, as judged by the level of messenger RNA for histidine decarboxylase (enzyme synthesizing histamine) in the tuberomammillary nuclei. Experiments were conducted on betahistine-treated cats receiving daily doses of 2, 5, 10, or 50 mg/kg during 1 week, 3 weeks, 2 months, or 3 months. The 1-week, 3-week, and 2- and 3-month treatments correspond to the acute, compensatory, and sustained compensatory stages of vestibular compensation, respectively. The lowest dose (2 mg/kg) given the longest time (3 months) was close to the dosage for vestibular defective patients. Data from the experimental groups were compared to control, untreated cats and to placebo-treated animals. The results clearly show that betahistine dihydrochloride administered orally in the normal cat interferes with histamine turnover by increasing the basal expression level of histidine decarboxylase mRNA of neurons located in the tuberomammillary nuclei of the posterior hypothalamus. The effects were both dose- and time-dependent. In conclusion, compensation of both static and dynamic deficits is subtended by long-term adaptive mechanisms that could be facilitated pharmacologically using betahistine dihydrochloride.

Histamine and betahistine in the treatment of vertigo: elucidation of mechanisms of action

The aim of this review is to provide clinicians with a picture of the mechanisms by which: histamine and histaminergic agonists act on the vestibular system both peripherally and centrally; and histaminergic agonists and antagonists interfere with the recovery process after peripheral vestibular lesion. We have focused on betahistine, a structural analogue of histamine with weak histamine H(1) receptor agonist and more potent H(3) receptor antagonist properties, to review the currently available data on the role of the histaminergic system in the recovery process after peripheral vestibular deficits and the effects of histamine analogues in the clinical treatment of vertigo. This review provides new insights into the basic mechanisms by which betahistine improves vestibular compensation in animal models of unilateral vestibular dysfunction, and elucidates particularly the mechanisms of action of this substance at the level of the CNS. It is proposed that betahistine may reduce peripherally the asymmetric functioning of the sensory vestibular organs in addition to increasing vestibulocochlear blood flow by antagonising local H(3) heteroreceptors. Betahistine acts centrally by enhancing histamine synthesis within tuberomammillary nuclei of the posterior hypothalamus and histamine release within vestibular nuclei through antagonism of H(3) autoreceptors. This mechanism, together with less specific effects of betahistine on alertness regulation through cerebral H(1) receptors, should promote and facilitate central vestibular compensation. Elucidation of the mechanisms of action of betahistine is of particular interest for the treatment of vestibular and cochlear disorders and vertigo.

Quantitative radioisotopic determination of histidine decarboxylase using high-performance liquid chromatography

We have developed a procedure for the accurate measurement of histidine decarboxylase in tissues expressing low levels of enzymatic activity. Briefly, histamine is enzymatically synthesized from [3H]-labeled histidine, followed by purification using high-performance liquid chromatography (HPLC) and quantitation by liquid scintillation counting. This method presents three advantages over previous techniques. First, prior to HPLC purification, excess precursor [3H]histidine is removed on an anion-exchange resin. Second, purification by HPLC is considerably more selective than that of classical cation-exchange gravity columns or organic solvent extractions. Finally, the accuracy of this method is improved by including non-radiolabeled histamine as internal standard, which is quantified by ultraviolet detection. This simple procedure allows highly sensitive and accurate determinations of histamine synthesis.

Treadmill exercise-induced stress causes a rise of blood histamine in normotensive but not in primary hypertensive humans

We have previously shown an interaction between noradrenergic and histamine-containing neurons in the rat vas deferens. As a generalized phenomenon, this interaction is involved in a novel peripheral reflex that, in an inhibitory way, modulates sympathetic activity and arterial pressure. Consistent with this, an activation of postganglionic sympathetic neurons causes a rise in rat blood histamine. In the present study, we showed that enhanced sympathetic activity due to treadmill exercise in normotensive humans, is accompanied by a rise in blood histamine, suggesting the presence of a similar neuronal interaction in humans. In contrast, the rise in blood histamine does not occur in primary hypertensive humans during the same degree of physical exercise, suggesting that this interaction is faulty in such hypertensives and could be involved in the pathophysiology of the disease.

Footshock-induced rise of rat blood histamine depends upon the activation of postganglionic sympathetic neurons

We have previously shown the existence of a novel peripheral reflex inhibitorily modulating the vas deferens sympathetic activity. An interaction between noradrenergic and histamine-containing neurons is involved in this reflex. As an overall mechanism of sympathetic autoregulation, we found that enhanced sympathetic activity in the rat during the stress induced by brief inescapable footshocks caused a marked rise of blood histamine that was seemingly dependent upon sympathetic activity. This rise was prevented by either previous ganglionic blockade with hexamethonium or chronic guanethidine-induced sympathectomy. Previous adrenal demedullation did not impair this rise. Thus, it appears that only the sympathetic postganglionic neuron, interacting with a histamine-containing neuron, is involved in the rise of blood histamine induced by footshocks.

alpha-Fluoromethylhistidine-induced inhibition of brain histidine decarboxylase. Implications for the CO2-trapping enzymatic method

The actions of S-alpha-fluoromethylhistidine (FMH), an irreversible inhibitor of the histamine biosynthetic enzyme histidine decarboxylase (HD), were studied on rat brain HD, as measured by a recently developed CO2-trapping enzymatic method. As expected, FMH induced a virtually complete inhibition of HD in the hypothalamus both in vivo and in vitro. In the frontal cortex, however, maximal doses of FMH did not maximally inhibit HD, suggesting the existence of an FMH-resistant form of HD. Careful studies of the conditions under which the assays were performed (homogenate dilution, preincubation times, incubation times, temperatures), as well as experiments with inhibitors of other decarboxylases, were unable to provide an explanation for this. When comparable studies of the effects of FMH in these brain regions were performed by alternative methods for measuring HD activity, no evidence for the existence of an FMH-resistant form of HD could be found. Thus, even though the CO2-trapping method appears to be accurate for measuring HD activity in rat hypothalamic homogenates, the present results show that this method may not be specific when studying brain regions other than the hypothalamus.

Histidine decarboxylase measurement in brain by 14CO2 trapping

A method for measuring histidine decarboxylase (HDC) in crude rat brain homogenates was developed by modification of existing 14CO2-trapping methods. The addition of EDTA to tissue homogenates and assay buffer reduced non-enzymatic decarboxylation, and improved assay sensitivity and reliability. Addition of polyethylene glycol (molecular weight 300, PEG300) to the homogenizing buffer increased enzyme stability, permitting storage of crude homogenates. Studies of time course, tissue dilution and blanks showed that up to 8 mg of tissue could be assayed successfully with a 3.5-hr incubation. S-alpha-Fluoromethylhistidine (FMH) and alpha-hydrazinohistidine, specific inhibitors of HDC, induced concentration-dependent reductions of enzyme activity by up to 90%, whereas inhibitors of other decarboxylases had little or no effect. Kinetic studies of the enzyme in crude homogenates yielded Km and Vmax values similar to those found previously with other HDC methods, although a poor fit was found to a single enzyme model. When determined by the new method, the distribution of HDC in seven regions of the rat brain agreed well with previous results. The method is rapid, simple to perform, and requires no specialized equipment other than a scintillation counter.

Calcium effects on the solubilization of membrane-bound histidine decarboxylase in the rat brain

In a previous work we have shown that histidine decarboxylase (HD) activity is found in a soluble and a membrane-bound form. A major part (82%) of the membrane-bound HD activity in the crude mitochondrial fraction (P2) was present in the synaptic plasma membrane-containing subfraction. Physiological concentrations of Ca2+ had no direct effect on HD activity but caused a solubilization of approximately 50% of membrane-bound HD in the P2 fraction. Mg2+ had similar but lower effects (20% solubilization) than Ca2+. Incubation with depolarizing concentrations of K+ in the presence of 1 mM CaCl2 caused a significant (30%) solubilization of HD.

L-histidine attenuates the effects of pentazocine on rewarding brain-stimulation

Previous research has indicated that the antihistamine tripelennamine potentiates the threshold lowering effects of pentazocine on brain stimulation reward, a model of drug-induced euphoria. To determine the importance of histamine in this interaction, we studied the effects of co-administration of L-histidine and pentazocine on the threshold for brain stimulation reward. Pentazocine (2.5-10.0 mg/kg) lowered the threshold for rewarding stimulation to the medial forebrain bundle-lateral hypothalamus in male F344 rats. L-histidine (500 and 750 mg/kg) by itself had no significant effects, yet antagonized the threshold lowering effects of pentazocine. These doses of L-histidine are known to significantly raise brain histamine concentrations. Our results suggest that histamine may play a tonic inhibitory role, at least in part, on the neural systems responsible for the reinforcing properties of pentazocine.

Effect of microinjection of histamine into the brain on plasma levels of epinephrine and glucose in freely moving rats

The effect of histamine administered to the brain on the plasma levels of epinephrine, norepinephrine and glucose was investigated in freely moving rats. Histamine (10 micrograms) administered intracerebroventricularly (into the lateral ventricle) induced a hyperglycemic response with preceding increases in plasma catecholamines, especially epinephrine. When histamine (5 micrograms) was injected into three different levels of the ventricular system, the magnitude and duration of the resulting increases in plasma epinephrine and glucose were in the following rank order: the third ventricle greater than aqueduct much greater than fourth ventricle. These results suggest that the sites of action of histamine are located rostrally from the midbrain. Microinjections of histamine (1 microgram) into the hypothalamic nuclei including the medial preoptic area, paraventricular nucleus, ventromedial hypothalamic nucleus, posterior hypothalamic nucleus and mammillary body had no elevating effect on the plasma levels of epinephrine and glucose. Other brain regions, such as the lateral septum, medial amygdaloid nucleus and periaqueductal grey of the midbrain, were also excluded as possible sites of histamine action. From the present results, it seems that histamine stimulates plural sites close to the ventricular system to induce hyperglycemic responses.

Gestational ethanol consumption on tissue amino acid levels: decreased free histidine and tryptophan in fetal tissues with concomitant increase in urinary histamine excretion

The effects of ethanol consumption during pregnancy on maternal, placental, and fetal tissue amino acid levels and metabolism were investigated. Pregnant Sprague-Dawley rats were given 35% ethanol-calorie liquid diet, ad libitum, from gestation day 7 to 21. Control rats were pair-fed with isocaloric sucrose substituted for ethanol. Ethanol consumption decreased fetal body weight and increased placental weight. Twenty-four amino acids were determined in six tissues (maternal plasma and liver, placenta, fetal plasma, liver, and brain) by HPLC with orthophthalaldehyde derivatization. The effects of ethanol on free amino acid levels differed from tissue to tissue. In general, ethanol affected more amino acids in maternal plasma, fetal plasma, and liver. Maternal liver, placenta, and fetal brain amino acids were more resistant to ethanol effect. Two essential amino acids, histidine and tryptophan, were consistently decreased in fetal tissues by maternal ethanol consumption. The values (ethanol vs. control, nmole/ml or g, mean +/- SEM, N = 20) of fetal plasma, liver, and brain for histidine were 51.8 +/- 6.0 vs. 85.3 +/- 4.5 (p = 0.001), 269.0 +/- 26.4 vs. 503.7 +/- 47.3 (p = 0.0004), and 117.9 +/- 7.7 vs. 154.6 +/- 8.7 (p = 0.0055), respectively; and for tryptophan were 105.7 +/- 3.1 vs. 132.2 +/- 4.1 (p = 0.0001), 128.8 +/- 3.7 vs. 144.3 +/- 6.0 (p = 0.0407), and 83.4 +/- 7.2 vs. 103.6 +/- 3.2 (p = 0.0198), respectively. Histidine was also decreased in placenta by ethanol (138.1 +/- 6.6 vs. 189.1 +/- 11.8 nmole/g, p = 0.0014).(ABSTRACT TRUNCATED AT 250 WORDS)

Purification of dopa decarboxylase from bovine striatum

Pyridoxal phosphate-dependent DOPA decarboxylase has been purified from bovine striatum to a specific activity of 1.6 U/mg protein. After ammonium sulfate precipitation (30-60%) it was purified by DEAE-Sephacel, Sephacryl S-200, and TSK Phenyl 5 PW chromatography. The purified enzyme showed a single silver straining band with polyacrylamide gel electrophoresis under both denaturing and non-denaturing conditions. The bovine striatal DOPA decarboxylase is a dimer (subunit Mr = 56,000 by SDS-PAGE) with a native Mr of 106,000 as judged by chromatography on Sephacryl S-200 and by sedimentation analysis. Similar to the DOPA decarboxylase purified from non-CNS tissues, the bovine striatal enzyme requires free sulfhydryl groups for activity, is strongly inhibited by heavy metal ions, and can decarboxylate 5-hydroxytryptophan as well. It should be noted, however, that the final enzyme preparation is enriched in DOPA decarboxylase activity. The distribution of the DOPA decarboxylase and 5-HTP decarboxylase activities also varies among several bovine brain regions. In addition, heat treatment of the enzyme preparation inactivated the two decarboxylation activities at different rates.

Release of histamine in rat hypothalamus and corpus striatum in vivo

Histamine has remained a putative neurotransmitter for many years, partially because some of the criteria necessary to define it as a central nervous system neurotransmitter have not been established. The demonstration of in vitro release and the quantification of turnover as an indirect measure of release have been complicated by the histological evidence for multiple histamine pools in the central nervous system. In brain, there are multiple cell types which probably contain histamine. These cells include mast cells, neurolipomastocytoid cells, microvascular endothelial cells, and a histaminergic neuronal system which has been visualized using immunocytochemical methods. Using in situ brain microdialysis and a sensitive and specific radioenzymatic assay for histamine, we have identified histamine in the extracellular space of the rat hypothalamus and corpus striatum in vivo. Following neuronal selective stimuli, significant increases in extracellular histamine levels only were observed in the posterior hypothalamus, where dense histaminergic neuronal terminals have been described. However, after manipulations targeted towards histamine-containing mast cells, such increases were seen in both the posterior hypothalamus and corpus striatum. In summary, this study demonstrates that endogenous histamine can be released from the posterior hypothalamus by stimuli targeted towards histamine neurons and that histamine may also be released by non-neuronal mast cell elements.

Histidine decarboxylase from rat and rabbit brain: partial purification and characterization

Histidine decarboxylase, the synthetic enzyme for histamine, was partially purified from regions of rat or rabbit brain rich in the enzyme. The enzyme was purified using ion exchange and hydrophobic column chromatography and chromatofocusing. Approximately 70-fold and 110-fold enrichments were attained from rat and rabbit brain, respectively. Rat and rabbit brain histidine decarboxylase had isoelectric points of pH 5.4 and 5.6, Km values of 80 microM and 120 microM histidine and Vmax values of 210 and 625 pmol histamine formed/hr-mg protein, respectively. The partially purified histidine decarboxylase from both sources was dependent on pyridoxal phosphate for maximal activity and was inhibited by alpha-fluoromethylhistidine, nickel chloride and cobaltous chloride but was not inhibited by impromidine, alpha-methyldopa, DTNB, zinc chloride or mercuric chloride. The enzyme had a broad pH optimum between pH 7.2 and 8.0. These studies provide further information on the characteristics of mammalian histidine decarboxylase from brain.

Sensitive radioimmunoassays for histamine and tele-methylhistamine in the brain

Serum albumin conjugates of histamine or tele-methylhistamine, a major catabolite, were prepared using 1,4-benzoquinone as the coupling agent and used to raise polyclonal antibodies in rabbits. The same reagent was used to prepare the [125I]iodinated tracer and treat tissue extracts submitted to the radioimmunoassays. The IC50 values of prederivatized histamine and tele-methylhistamine in the radioimmunoassays were 0.3 nM and 0.5 nM, respectively, whereas nonderivatized histamine or tele-methylhistamine, histidine, a variety of histamine derivatives, amines, etc., had at least 1,000-fold higher IC50 values. Application of the radioimmunoassays to nonpurified extracts of rat brain allowed the quantification of the two amine immunoreactivities in samples corresponding to less than 1 mg of hypothalamus. The tissue immunoreactivity corresponded to authentic histamine or tele-methylhistamine, as shown by (a) the parallel 125I-tracer displacement curves, (b) the similar elution patterns from HPLC columns, (c) the regional levels of histamine and tele-methylhistamine in brain, similar to those obtained with other methods, and (d) the clearcut effects of treatments with inhibitors of L-histidine decarboxylase or monoamine oxidase. The two radioimmunoassays appear as simple and sensitive tools to evaluate steady-state levels and turnover rates of histamine and tele-methylhistamine.

The effect of protein or carbohydrate breakfasts on subsequent plasma amino acid levels, satiety and nutrient selection in normal males

Normal subjects were fed protein or carbohydrate breakfasts. Both meals were in the form of a chocolate pudding and had similar sensory qualities. At lunchtime subjects were allowed to select from a buffet. The protein breakfast had a greater satiating power than the carbohydrate breakfast, but there was no difference in overall selection of protein or carbohydrate at lunchtime. However, the carbohydrate breakfast did decrease selection of apple, the only pure carbohydrate food available at lunchtime. In a second experiment changes in plasma amino acid levels were studied after subjects received carbohydrate breakfasts containing 0, 4, 8 or 12% protein, or a danish pastry. Only the 0% protein breakfast increased tryptophan availability to the brain. These experiments were performed to test the hypothesis that alterations in brain 5-hydroxytryptamine, brought about by dietary alterations in brain tryptophan, regulate selection of protein and carbohydrate. The results suggest that this mechanism was not operating in our experiments.

Changes in histamine metabolism in the brains of mice with streptozotocin-induced diabetes

Histamine (HA) metabolism in the brain of mice with streptozotocin (STZ)-induced diabetes was examined. The levels of tele-methylhistamine (t-MH), a major metabolite of brain HA, significantly increased 3 and 4 weeks after STZ injection. However, the HA turnover rates in the diabetic mice, determined from the accumulation of t-MH after the administration of pargyline, were not different from the control values when the animals were allowed free access to food. When the mice were starved for 15 h 4 weeks after STZ treatment, the brain levels of L-histidine decreased significantly, whereas HA turnover increased significantly. Such changes were not observed in starved control mice. Histidine decarboxylase or HA N-methyltransferase activity did not change after starvation in either diabetic or control mice. These results show that the histaminergic (HAergic) activity in the brains of diabetic mice remains within normal range as long as the animals are allowed free access to food. However, they also indicate that a marked enhancement of HAergic activity accompanied by a decrease in the brain L-histidine level occurs in starved diabetic mice.

Properties and ontogenic development of membrane-bound histidine decarboxylase from rat brain

Histidine decarboxylase (HD) activity was determined in high-speed fractions (100,000 g for 60 min) obtained from whole rat brain homogenates. Twenty-eight percent of the HD activity was associated with membranes, and the remaining was soluble. Several properties of the soluble and membrane-bound HD were compared. No significant differences in the values of Km for histidine and pyridoxal 5'-phosphate were observed. The solubilization of membrane-bound HD with Triton X-100 resulted in an increase of 60% over the nonsolubilized activity with no changes in the Km for substrate and cofactor. The proportion of free pyridoxal 5'-phosphate-independent activity was identical in both fractions. The soluble and membrane-bound forms of the enzyme differ slightly in their pH-activity profiles, although both enzymes showed an optimum pH near 6.5. The HD activities present in soluble and membrane fractions were determined at different postnatal ages. The soluble activity increased until day 90, whereas the membrane-bound activity became stabilized from day 20.

A detailed mapping of histamine H1-receptors in guinea-pig central nervous system established by autoradiography with [125I]iodobolpyramine

[125I]Iodobolpyramine, a potent and selective histamine H1-receptor antagonist derived from mepyramine, was used to generate light microscopic autoradiograms on sections of guinea-pig brain and spinal cord. Histamine H1-receptors were labelled with high sensitivity over a low background as determined using mianserin or other H1-receptor antagonists as competing agents. An atlas of H1-receptors was established using five sagittal sections and 39 frontal sections, the latter serially prepared at 50 micron intervals. Labelled areas were identified by comparison with corresponding, classically stained sections and their density was rated according to an arbitrary scale. Autoradiographic grains were detected in a large variety of gray matter areas whereas they were generally absent from white matter areas. In the cerebral cortex, H1-receptors are present in all areas and layers with a higher density in lamina IV. In the hippocampal formation, H1-receptors display a laminated pattern of distribution and are the most abundant in the dentate gyrus (hilus and molecular layer) and in several areas of the subiculum and commissural complex. In the amygdaloid complex, the highest densities are found in the medial group of nuclei. In the basal forebrain, the striatum is moderately labelled whereas the nucleus accumbens, islands of Calleja and most septal nuclei are highly labelled. In the thalamus, H1-receptors are present in high density, particularly in the anterior, median and lateral groups of nuclei. In the hypothalamus the labelling is highly heterogeneous with high densities in, for example, medial preoptic area, dorsomedial, ventromedial and most posterior nuclei, including the tuberomammillary complex in which histaminergic perikarya and short axons are present.(ABSTRACT TRUNCATED AT 250 WORDS)

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.

The diffuse neuroendocrine system: a molecular perspective

This review seeks to illustrate that the concept of a 'diffuse neuroendocrine system' arises from a series of ontogenetic, phylogenetic and functional overlaps borne out at the molecular level, which engender an apparent global unit. Extrapolation from the overlaps should lead to the discovery of new facets in the relationships between molecular components of the DNES, and this approach will lead to a spectrum of markers and probes with a variety of clinical applications. Initial approaches progressed from cellular function toward molecular anatomy, but converse questions starting from anatomical markers are now arising.

Autoinhibition of histamine synthesis mediated by presynaptic H3-receptors

The regulation of histamine synthesis was studied on rat brain slices or synaptosomes labeled with L-[3H]histidine. Depolarization by increased extracellular K+ concentration enhanced by about twofold the [3H]histamine formation in slices of cerebral cortex. This stimulation was also observed, although to a lesser extent, in synaptosomes from cerebral cortex and slices from the posterior hypothalamus where most histaminergic cell-bodies are located, suggesting that it may occur in nerve endings as well as in perikarya. In the presence of exogenous histamine in increasing concentrations the K+-induced stimulation was progressively reduced by up to 60-70%. The effect of exogenous histamine appears to be receptor-mediated as shown by its saturable character, high pharmacological specificity and competitive reversal by histamine antagonists. The EC50 value of histamine for synthesis reduction (0.34 +/- 0.03 microM) was similar to its EC50 value for release inhibition known to be mediated by H3-receptors. In addition, whereas mepyramine and tiotidine, two potent antagonists at H1- and H2-receptors, respectively, were poorly effective, the H3-receptor antagonists burimamide and impromidine reversed the histamine effect in an apparently competitive manner. These effects were observed in slices of cerebral cortex or posterior hypothalamus as well as in cortical synaptosomes. Furthermore, even in the absence of added histamine, H3-receptor antagonists enhanced the depolarization-induced stimulation of [3H]histamine synthesis, indicating a participation of released endogenous histamine in the synthesis control process. The potencies of H3-receptor antagonists were similar to those of these agents at presynaptic autoreceptors controlling [3H]histamine release. It is concluded that H3-receptors control not only release but also synthesis of histamine at the level of nerve endings and also, presumably, of perikarya. A relationship between the two regulatory processes, possibly via intracellular calcium, seems likely but remains to be investigated at the molecular level.

Brain histamine metabolism in transmissible spongiform encephalopathy (scrapie)

The histamine (Hi) content and the activity of L-histidine decarboxylase (HD) in brains of scrapie infected hamsters were measured. No significant changes in Hi levels in particular brain areas were found when compared to controls. Decreased activity of HD was found in hypothalamus (p less than 0.02). Increased activity of the enzyme was observed in "rest of brain", which consisted mainly of thalamus and striatum (p less than 0.05).

Cerebellar histamine-H1 receptor distribution: an autoradiographic study of Purkinje cell degeneration, staggerer, weaver and reeler mutant mouse strains

The distribution of 3H-mepyramine binding sites in cerebellae of normal mice and Purkinje cell degeneration, staggerer, weaver and reeler mutant mice was studied by light microscopic autoradiography. The binding of 3H-mepyramine to 20 micron coronal sections through the cerebellum and medulla had the characteristics expected of histamine-H1 receptor labeling. In the cerebellar cortex of normal mice, a high density of 3H-mepyramine binding was observed over the molecular layer and an intermediate density over the Purkinje cell layer, while the granule cell layer and white matter were almost devoid of labeling. The deep cerebellar nuclei were labeled to an intermediate density. In the 54 day old Purkinje cell degeneration mutant cerebellum, which is depleted of Purkinje cells, a greatly reduced labeling of the cerebellar cortex was observed. Labeling in the deep cerebellar nuclei was unaffected. In the 27 day old staggerer cerebellum, a mutation characterized by Purkinje cells which are almost devoid of spines and which do not form synaptic contacts with granule cells, a higher than normal grain density was seen over the cerebellar cortex, while normal grain density was observed over the deep cerebellar nuclei. The cerebellar cortex of 81 day old weaver mice, which is almost devoid of granule cells, had a high grain density over medial regions of the cortex, while the portion of the granule cell layer which remained relatively unaffected in the lateral parts of the cerebellum was unlabeled. The deep cerebellar nuclei had grain densities similar to littermate controls. In the 29 day old reeler cerebellae, which contain malpositioned Purkinje cells, high grain density regions corresponding to the heterotopically located Purkinje cells were observed. The present observations suggest that cerebellar cortical histamine-H1 receptors are associated predominantly with Purkinje cells. Furthermore, the expression of these H1 receptors appears not to be adversely affected by several alterations in the Purkinje cell environment, which have previously been shown to dramatically influence Purkinje cell morphology.

Autoradiographic localization of receptors in the cochlear nucleus of the mouse

Light microscopic autoradiography of bound radiolabeled ligands was used to describe the distribution of six receptor types in the dorsal and ventral mouse cochlear nuclei: Glycine receptor ([3H]strychnine); GABA receptor ([3H]muscimol); benzodiazepine receptor ([3H]flunitrazepam); adenosine receptor ([3H]cyclohexyladenosine); muscarinic ACh receptor ([3H]quinuclidinyl benzilate); histamine receptor ([3H]mepyramine). The most intense [3H]strychnine labeling was observed in the deep region of the dorsal cochlear nucleus (DCN), with slightly lower levels in the molecular and pyramidal layers. Highest density of [3H]muscimol binding sites was observed in the granule cell layer of the posterior ventral nucleus (PVCN) and in the pyramidal layer of the DCN. Diffuse [3H]flunitrazepam labeling was distributed over all laminar regions of the DCN; the highest grain density was observed over the granule cell layer of the PVCN. Intense [3H]cyclohexyladenosine labeling was seen over the molecular layer, possibly extending into the pyramidal layer, of the DCN. The granule cell layer of the PVCN was also densely labeled. High concentrations of [3H]quinuclidinyl benzilate sites were seen in the molecular layer, possibly extending into the pyramidal layer, of the DCN. A thin band of high grain density was also visible over the granule cell layer of the PVCN. Moderate, diffuse [3H]mepyramine labeling was visible throughout the DCN, with slightly higher grain density over the molecular, and possibly the pyramidal layers, than over the deep region of the DCN.

[125I]Iodobolpyramine, a highly sensitive probe for histamine H1-receptors in guinea-pig brain

[125I]Iodobolpyramine is a novel 125I-ligand for histamine H1-receptors, synthesised using the 125I-Bolton Hunter reagent (2000 Ci/mmol) for acylation of an aminopentyl analogue of mepyramine. Its specific binding varied linearly with the concentration of guinea-pig cerebellar membranes and represented about 80% of the total. Selective interaction with H1-receptors was demonstrated by estimation of Ki values of known agonists and antagonists and confirmed by the low affinity of histamine H2- and H3-receptor antagonists and of non-histaminergic agents. At 25 degrees C, [125I]iodobolpyramine exhibited a slow association rate (180-240 min to reach equilibrium) and a slow dissociation rate (t1/2 = 201 min). Kinetic and saturation data yielded KD values of 0.05 and 0.15 nM, respectively, indicating that it is among the most potent H1-receptor antagonists known. The sensitivity for detecting H1-receptors in guinea-pig cerebellum using [125I]iodobolpyramine was increased 50-fold relative to use of [3H]mepyramine. Well-contrasted autoradiograms of guinea-pig brain, obtained after a short exposure time, confirmed previous H1-receptor localisation established with [3H]mepyramine and revealed new localisations, e.g. in cerebral cortex and nucleus accumbens.

Food intake suppression by histidine

Following injection of histidine (as 1-histidine monohydrochloride, 500 mg/kg, IP) rats showed a suppression of total food intake within the first 2 hours of a 12 hour daily feeding period but not if the rats were adapted to a 4 hour daily feeding period. Furthermore, rats adapted to a nocturnal as compared to a diurnal 12 hour feeding period showed a greater response (50% vs. 20% suppression of feeding) to histidine. Overall, within an experiment, food intake suppression correlated with the histidine dose (0, 125, 250, 375 and 500 mg/kg; for mean response r(3) = 0.90, p less than 0.05) although the lowest dose measured to be effective in a cross-over design experiment was 375 mg/kg. No differential effect upon protein or carbohydrate intake was observed in any of the studies. The effects of injections of 250 and 500 mg/kg histidine on food intake were associated with significant elevations of brain histidine and histamine. We conclude that histidine, possibly by changes in brain histidine, influences total food intake but not macronutrient selection.

Partial characterization of histidine decarboxylase in hamster and rat brain employing a new method

Histidine decarboxylase activity in hamster and rat brains were studied using a newly developed sensitive, direct radioenzymatic microassay. For our assay conditions, we determined a Km for L-histidine of 320 microM and a Vmax for histidine decarboxylase of 110 pmol histamine/hr/mg protein in rat hypothalamus. The regional distributions of both histidine decarboxylase and histamine levels were similar in the hamster and rat with the most activity in hypothalamus. Most of the histidine decarboxylase activity in rat hypothalamus was in the cytosol fraction. The developmental pattern of histidine decarboxylase in the fetal rat did not reveal a prenatal spike in activity. Histidine decarboxylase activity in rat brain reached adult levels by four weeks. Alpha-fluoromethylhistidine inhibited histidine decarboxylase activity almost totally in vitro at 10 microM and about 80% in vivo after six days of infusion (100 mg/kg/day) in all brain regions except the cerebellum. Likewise, histamine levels were depleted about 75% in all brain regions except the cerebellum.

Histidine transport into rat brain synaptosomes

Histidine transport and metabolism in rat brain synaptosomes were investigated to study the possible role of histidine uptake in the synthesis of the putative neurotransmitter histamine (HA). Histidine uptake was found to be regionally distributed and temperature sensitive, and was not totally independent of sodium or potassium ions. Transport was inhibited by metabolic inhibitors, as well as by promethazine and quinacrine. A number of other HA-related agents and several histidine metabolites had no effect. Kinetic analyses of histidine transport revealed the presence of both high- and low-affinity systems in cerebral cortex. Histidine uptake increased following preexposure of synaptosomes to depolarizing concentrations of potassium. This effect was dependent on the presence of calcium ions during the preincubation. No newly formed [3H]HA was detectable in rat brain synaptosomes following [3H]histidine transport. Lesions of the medial forebrain bundle did not alter histidine uptake in the hippocampus or cerebral cortex. Ontogenic studies indicated that the histidine uptake system developed rapidly and reached a peak during postnatal days 12-17. Overall, the present findings do not support a role for histidine transport in the regulation or maintenance of neurotransmitter pools of HA in rat brain.

Properties of N-acetylhistamine deacetylase in mammalian brain

Properties of N-acetylhistamine deacetylase in rat brain were studied, utilizing a sensitive coupled radioenzymatic assay. The Km for N-acetylhistamine for this deacetylase was 660 microM and its Vmax was 330 pmol/h/mg protein. N-Acetylhistamine deacetylase activity increased 80% in the presence of 1 mM Mn2+. The Km of Mn2+ was 40 microM. The enzyme is primarily a soluble enzyme with a relatively uniform regional distribution, unlike the distribution for histamine and histidine decarboxylase. Neonatal activity of this enzyme in rat brain is higher than in adult brain. alpha-Fluoromethylhistidine does not affect the activity of N-acetylhistamine, indicating that deacetylation probably does not play a regulatory role in the synthesis of brain histamine.

Autoregulation of histamine release in brain by presynaptic H3-receptors

Regulation of histamine release was studied mainly on brain slices prelabeled with L-[3H]-histidine and depolarized by increased extracellular K+ concentration or veratridine in a non-superfused system. The released 3H-labeled amines, isolated by ion-exchange chromatography from a large excess of 3H-labeled precursor consisted by more than 95% of unchanged [3H]histamine. Exogenous histamine reduced the release of neosynthesized [3H]histamine via stimulation of previously characterized H3-receptors whereas it did not modify the 3H-labeled amine release from slices prelabeled with preformed [3H]histamine. The maximal inhibitory effect of exogenous histamine progressively diminished as the strength of the depolarizing stimulus or the external Ca2+ concentration were elevated. On the contrary H3-receptor antagonists like impromidine or burimamide enhanced the depolarization-induced release of [3H]histamine, an effect which was particularly marked when slices were loaded with histamine by preincubation with [3H]histidine in high concentration. These results suggest that the inhibition of [3H]histamine release by exogenous histamine acting via H3-receptor stimulation is mediated by a restricted access of Ca2+ and that its extent is influenced by the degree of autostimulation by endogenous histamine as well as, possibly, by actual internal Ca2+ concentration. In addition the decrease in external Ca2+ concentration shifted rightwards the concentration-response curve to histamine. The autoinhibitory effect of exogenous histamine was found on slices from various regions, known from lesion studies to contain terminals of extrinsic histaminergic neurons. It did not apparently involve interneurones, not being prevented in slices in which the traffic of action potentials was blocked by tetrodotoxin. It also remained unaffected in striatal slices in which the neuronal cell-bodies were selectively destroyed by prior local infusion of kainic acid. Finally exogenous histamine inhibited [3H]histamine release from depolarized synaptosomes of rat cerebral cortex, with an EC50 value similar to that found with slices and was antagonised by impromidine with an apparent Ki value similar to that displayed at H3-receptors. It is concluded that histamine modulates its own release from cerebral neurones by interacting with H3-presynaptic autoreceptors and via mechanisms similar to those previously evidenced on other aminergic systems.

Aortic histamine synthesis and aortic albumin accumulation in diabetes: activity-uptake relationships

The relationship between inhibition of aortic histamine synthesis induced by varied dosages of alpha-hydrazinohistidine (alpha HH) and aortic uptake of fluorescein-labeled bovine serum albumin (FITCBSA) was examined in 40 male Wistar rats made diabetic by streptozotocin. Compared to nondiabetic animals, aortic uptake of FITCBSA in untreated diabetic animals was increased 43%. alpha HH administration produced essentially a complete inhibition of this accelerated histamine synthesis in diabetic animals at all dosages examined and likewise prevented an increase in aortic FITCBSA uptake among these animals. In diabetic animals, aortic histamine synthesis and aortic FITCBSA uptake showed a significant, strong positive correlation (r = 0.822, P less than 0.001) when examined in relation to the degree of inhibition of accelerated aortic histamine synthesis achieved among the individual animals. These data support the hypothesis that elevations in de novo aortic histamine formation, and thus elevations in the inducible histamine pool, are responsible, at least in part, for increased aortic uptake of macromolecules in diabetes. Since increases in various permeability characteristics occur early in atherogenesis, these data also indicate that expansion of the nascent histamine pool occurring in diabetes may be an important factor in the predisposition of diabetics to atherosclerotic vascular disease.

Histamine in the rabbit eye: distribution, synthesis, catabolism, and changes by light stimulation

Histamine (HI) is present in all studied ocular (retina, choroid, optic nerve) and brain structures of the albino rabbit. HI levels in neural eye elements (retina and optic nerve) are relatively low, i.e. 70-140 ng/g tissue, and comparable with those found in the brain; a typical vascular tissue, i.e. choroid, contained approximately 10 times more HI. Histadine decarboxylase (HD) activity was found only in brain tissue, while histamine-methyltransferase (HMT) activity was present in all the eye and brain structures. Light stimulation produced changes in HI content only in the retina (decrease) and in the optic nerve (increase).