The possible role of brain histamine in neuroendocrine and cardiovascular regulation

The tuberomammillary nucleus region as a reinforcement inhibiting substrate: facilitation of ipsihypothalamic self-stimulation by unilateral ibotenic acid lesions

The tuberomammillary nucleus (TM), located in the posterior hypothalamic region, consists of five subgroups and is the only known source of brain histamine. Knowledge about the function of this nucleus is still scarce. In a previous study we found an increase in the rate of ipsihemispheric hypothalamic self-stimulation following a dc lesion in the rostroventral part of this nucleus, suggesting that this region has an inhibitory action on a neuronal reward system or on the brain's reinforcement mechanism. In the present study we examined whether this facilitating effect on reinforcement was due to the destruction of fibers passing through the lesion area or of intrinsic cells, by lesioning subgroups of the TM with ibotenic acid, an excitatory amino acid, that selectively destroys neural cell bodies, leaving fibers largely intact. Following such lesions in the rostroventral part of the TM the operant response rates increased over the six days of testing when the animals stimulated themselves in the lateral hypothalamus in the hemisphere located ipsilateral but not contralateral to the lesion. No significant changes in response rate occurred following the lesion in the caudal part of the ventral TM. The results indicate that the region influenced by the lesion exerts inhibitory control over lateral hypothalamic self-stimulation, and that it is possible that histamine-containing neurons are involved in this effect.

Interactions of mast cells with the nervous system ?Recent advances

This article reviews recent advances in the understanding of mast cell-nervous system interactions. It is drawn largely from work published within the last ten years, and discusses the anatomical and biochemical evidence of a functional connection between mast cells and the nervous system, and the implications that such a relationship may have for normal and abnormal physiological functioning. Mast cells are found at varying levels of association with the nervous system; in CNS parenchyma (mainly thalamus), in connective tissue coverings (e.g. meninges, endoneurium), and in close apposition to peripheral nerve endings in a variety of tissues. There is, as yet, no clearly defined role for mast cells in nervous system function, or vice-versa, and it seems most likely that their interactions fulfil mutually modulatory roles. By extension, pathological situations where one of the partners in this relationship is overly stimulated may lead to a dysregulation of the other, and contribute to disease symptomatology.

Effects of intracerebroventricular histamine injection on circadian activity phase entrainment during rapid illumination changes

Histamine is reported to have different effects on shifting the circadian activity phase depending on its circadian administration time (CT). The delay-sensitive period is CT 12-15, and the advance-sensitive period is CT 0-3. The activity phase of rats was entrained by a new light-dark cycle within a week in groups treated with either saline or i.c.v. histamine at CT 12-15. However, on treatment at CT 0-3 the activity phase of the group treated with histamine was entrained by the new light-dark cycle in half the period required for entrainment in the control group.

The participation of histaminergic receptors of the rostral hypothalamus on the tonic release of luteinizing hormone (LH) in adult spayed rats under estrogen and progesterone treatment

The influence of histaminergic sites in the preoptic-anterior hypothalamic area (POA-AHA) on the basal release of luteinizing hormone (LH) under a continuous regimen of estradiol, progesterone, or both was studied in ovariectomized rats. Different groups of animals were subjected to the following experimental schedule: at day 1, rats received a s.c. silastic implant filled with oil, estradiol, progesterone, or estradiol plus progesterone. Seven days later (day 7), animals were implanted into the POA-AHA with microinjection cannulae. At day 8 and 9, the different groups of rats were microinjected with 1 microliter of saline solution containing 35 nMol of pyrilamine or metiamide, or 20 nMol of alpha-fluoro-methyl-histidine. At day 10, blood samples were taken through a permanent jugular cannulae implanted in situ the day before. LH concentrations were determined in plasma by RIA. Results showed that the increase of LH plasma levels induced by the ovariectomy was inhibited by the estrogen implant, as expected. Treatment of metiamide or alpha-fluoro-methyl-histidine did not affect the pattern of LH secretion. Nevertheless, treatment of metiamide induced a transient increase in the gonadotropin concentrations that extended for two hours (16:00 and 17:00 H). No change in LH plasma levels was observed in rats bearing the progesterone implant. Treatments (pyrilamine, metiamide, or alpha-fluoro-methyl-histidine into the POA-AHA) had no effect. The transient increase in the hormone levels observed in rats treated with pyrilamine in the estrogen-implanted rats was absent in rats bearing the estrogen-progesterone implant.(ABSTRACT TRUNCATED AT 250 WORDS)

Intraocular hypothalamic transplants containing histaminergic neurons: innervation of host iris and hippocampal cografts

Hypothalamic tissue containing the tuberomammillary nucleus was dissected from fetuses of Embryonic Day 17 and inserted into the anterior chamber of the eye of young adult recipient rats. The growth of hypothalamic grafts was monitored through the translucent cornea and transplants were found to double in size over the 8 first weeks in oculo. After 4 weeks fetal hippocampal formation (Embryonic Day 18) was inserted into the eye chamber in half of the previously grafted animals and placed in contact with the first grafts. Double grafts were allowed to mature for up to 18 weeks before sacrifice. Recipient rats were anesthetized and superfused with carbodiimide and paraformaldehyde, after which transplants were removed, frozen, sectioned on a cryostat, and incubated with histamine antibodies. Immunohistochemical evaluations revealed a large number of histamine-positive nerve cell bodies with processes innervating the entire hypothalamic graft with a dense plexus of varicose fibers. Such histamine-positive fibers were also seen to invade the surrounding host iris in some cases with thick axon bundles as well as with single fibers. When hypothalamic transplants were combined with hippocampal grafts numerous histamine-immunoreactive fibers invaded the hippocampal tissue to form a plexus of varicose terminals throughout the cografts. After 4 weeks in oculo only a sparse histamine-positive innervation of hippocampal grafts was found, while 18-week-old double grafts contained a considerably larger amount of immunoreactive neurites.(ABSTRACT TRUNCATED AT 250 WORDS)

Histaminergic neurons receive substance P-ergic inputs in the posterior hypothalamus of the rat

The synaptic connections between histaminergic neurons and substance P (SP) afferents in the caudal magnocellular nucleus (CM) of the hypothalamus were examined using an immunoelectron microscopic mirror method. SP-immunoreactive (SP-IR) terminals made synaptic contacts with the somata, somatic spines and dendrites of histidine decarboxylase immunoreactive (HDC-IR) neurons. This suggests that SP afferents exert monosynaptic influence on the central histaminergic neuronal system.

The probable role of histamine in the rostral hypothalamus on the prolactin and luteinizing hormone release induced by estrogen in conscious spayed rats

The participation of histamine (HA) sensitive sites in the preoptic-anterior hypothalamic area (POA-AHA) on prolactin (PRL) and luteinizing hormone (LH) surge induced by estrogen was studied in ovariectomized rats. Different groups of animals were subjected to the following experimental schedule: On day "0" rats were stereotaxically implanted into the POA-AHA with microinjection cannulae. On day "1", rats were injected s.c. with estrogen. On days "2" and "3", animals were microinjected into the POA-AHA with different drugs, according to the type of experiment, and at day "4", through a silastic cannula implanted previously in the jugular vein, blood samples were taken each hour between 15:00-21:00 h. In the plasma, PRL and LH concentrations were measured by RIA. Four experiments were performed. In Experiment 1, animals at 12:00 h were injected into the POA-AHA with pyrilamine maleate (an H 1-histamine antagonist), metiamide (an H2-histamine antagonist) or saline as control. In Experiment 2, rats at 12:00 h were injected into the POA-AHA with alpha-fluormethyl-histidine (an inhibitor of histamine synthesis) or the combined administration of pyrilamine and metiamide. In Experiment 3, rats previously microinjected with the histamine synthesis inhibitor were microinjected with 4-methyl-histamine (an H 2-histamine agonists) or 2-pyridilethyl-amine (an H 1-histamine agonist) and in Experiment 4, rats were microinjected at 09:00 h with metiamide, pyrilamine, fluor-methyl-histidine or saline as control. Results showed that in animals treated with pyrilamine or metiamide at noon the prolactin surge induced by estrogen was affected (inhibited by metiamide and shortened by pyrilamine, Experiment 1) and LH surge slightly affected. Rats that received FMH or the combined administration of the histamine antagonists the prolactin and LH surge were abolished (Experiment 2). Only the treatment of the H 2-histamine agonist was able to reproduce the prolactin increase in rats treated with FMH. Nor the H 1 or H 2-histamine agonists were effective in reproducing the LH surge in these animals (Experiment 3). Animals that received saline at 09:00 h into the POA-AHA, the prolactin and LH surges were abolished. Results confirm that histamine in the POA-AHA is important for the expression of prolactin and LH surge induced by estrogen and suggest that H 1- and H 2-histamine receptors are involved in the complex timing mechanisms of the rostral hypothalamus that control both hormone release in rats.

Inhibition of histamine release from rat hypothalamic slices by omega-conotoxin GVIA, but not by nilvadipine, a dihydropyridine derivative

Histamine release in response to 40 mM high K+-stimulation from the rat hypothalamic slice preparations perifused in vitro was significantly inhibited by 1.0 nM-1.0 microM omega-conotoxin GVIA, a peptide modulator of N- and L-type voltage-sensitive calcium channels, but not by similar concentrations of nilvadipine, a dihydropyridine derivative of L-type calcium channel antagonist. These results indicate that the voltage-sensitive calcium channel controlling histamine release from hypothalamic slices is omega-conotoxin-sensitive but dihydropyridine-insensitive.

Effects of histamine on thermosensitive neurons in rat preoptic slice preparations

Single neuronal activities were recorded extracellularly from slice preparations of the rat preoptic area and effects of histamine (0.01 10 microM) on the activities were examined with regard to thermosensitivies of the neurons. Superfusion of histamine increased the firing rate in 52 of 75 warm-sensitive neurons and in 22 of 41 thermally insensitive neurons in a dose-dependent manner. Ten (3%) warm-sensitive neurons and 6 (15%) thermally insensitive neurons were inhibited by histamine. Mepyramine (10 microM) (H1-antagonist), but not famotidine (H2-antagonist), blocked the histamine (10 microM) induced excitation in 19 (76%) of 25 warm-sensitive neurons and in 6 (75%) of 8 thermally insensitive neurons. These results suggest that histamine excites both warm-sensitive and thermally insensitive neurons in the preoptic area mainly via the H1-receptor.

Organization of histaminergic fibers in the rat brain

Detailed information on innervation of the histaminergic system in the brain is essential to an understanding of the physiological roles of this system. In a previous immunocytochemical study with antihistidine decarboxylase (HDC) antibody, we detected extensive networks of histaminergic fibers in many areas of the rat brain (Watanabe et al., '84). In the present study, we improved the immunocytochemical procedure and examined the detailed distribution of histaminergic innervation in the rat brain with anti-HDC antibody. As reported previously, the highest concentrations of fibers were found in the hypothalamic nuclei and medial forebrain bundle. With the modified procedure, we detected more dense networks of HDC-immunoreactive (HDCI) fibers. Furthermore, we demonstrated for the first time the existence of HDCI fibers in other regions, namely, the thalamic nuclei, median eminence, fimbria of the hippocampus, habenular nuclei, superior colliculus, nucleus of the optic tract, parabrachial nuclei, mesencephalic trigeminal nucleus, superior, lateral, and spinal vestibular nuclei, posterior lobe of the hypophysis, and vascular organ of the lamina terminalis. We also found dense transverse fibers in the retrochiasmatic area and supraoptic decussation, which suggests bilateral innervation of the histaminergic system. These results indicate that innervation of the rat brain by the histaminergic system is more extensive than observed previously.

Histaminergic nerve fibers in the median eminence and hypophysis of rats demonstrated immunocytochemically with antibodies against histidine decarboxylase and histamine

Histaminergic fibers in the median eminence and hypophysis of rats were examined immunocytochemically with antibodies against histidine decarboxylase (HDC), the sole histamine-synthesizing enzyme, and against histamine itself. A similar distribution of immunoreactive fibers was observed with these two antibodies. In the median eminence, immunoreactive fibers were mainly located in the internal layer and could be traced to the posterior lobe of the hypophysis. A few fibers were detected in the external layer of the median eminence, but none in the anterior or intermediate lobe of the hypophysis. These observations suggest that neuronal histamine may take part in regulation of the hypothalamo-neurohypophysial neuroendocrine system in rats.

Histamine sensitive sites in hippocampus: their probable role on prolactin release in male rats

The effect of histamine (HA), 3-methyl-histamine (3MHA), HA antagonists or drugs interfering with HA synthesis, microinjected into the hippocampus (HPC), on prolactin (PRL) secretion were studied in rats. Three experiments were performed. In Experiment 1, increasing doses of HA or 3-MHA (9-90 nmol) were microinjected stereotaxically into the ventral HPC of adult male rats. In Experiment 2, 135 nmol of pyrilamine (PYR, an H1-HA-antagonist) or ranitidine (RAN, an H2-HA-antagonist) were administered locally into the ventral HPC. Fifteen min later, the rats were microinjected again with 45 nmol of HA. In Experiment 3, rats were microinjected with different doses of HA-antagonists or with 20 nmol of alpha-fluormethyl-histidine (FMH, an inhibitor of the enzyme of HA synthesis) and later subjected to an immobilization stress of 15 min duration. In all cases, the PRL plasma concentrations were measured in blood samples taken at different time intervals (0-120 min) after the last brain injection. Results showed that HA applied locally in ventral HPC induced an increase in PRL levels which was statistically significant from saline-injected rats between 5-30 min after the HPC stimulation. On the contrary, local applications of 3-MHA did not change significantly the PRL blood levels (Experiment 1). Only PYR did block partially the PRL response due to HA in basal conditions. RAN in these later conditions had no effect (Experiment 2). When animals were subjected to stress neither PYR nor RAN, alone or in combination, locally applied were able to block the PRL increase due to stress. Only FMH blunted significantly the hormone response.(ABSTRACT TRUNCATED AT 250 WORDS)