Histamine actions on activity of cultured hypothalamic neurons: evidence for mediation by H1- and H2-histamine receptors

Estrogenic regulation of histamine receptor subtype H1 expression in the ventromedial nucleus of the hypothalamus in female rats

Female sexual behavior is controlled by central estrogenic action in the ventromedial nucleus of the hypothalamus (VMN). This region plays a pivotal role in facilitating sex-related behavior in response to estrogen stimulation via neural activation by several neurotransmitters, including histamine, which participates in this mechanism through its strong neural potentiating action. However, the mechanism through which estrogen signaling is linked to the histamine system in the VMN is unclear. This study was undertaken to investigate the relationship between estrogen and histamine receptor subtype H1 (H1R), which is a potent subtype among histamine receptors in the brain. We show localization of H1R exclusively in the ventrolateral subregion of the female VMN (vl VMN), and not in the dorsomedial subregion. In the vl VMN, abundantly expressed H1R were mostly colocalized with estrogen receptor α. Intriguingly, H1R mRNA levels in the vl VMN were significantly elevated in ovariectomized female rats treated with estrogen benzoate. These data suggest that estrogen can amplify histamine signaling by enhancing H1R expression in the vl VMN. This enhancement of histamine signaling might be functionally important for allowing neural excitation in response to estrogen stimulation of the neural circuit and may serve as an accelerator of female sexual arousal.

Cholinergic nucleus basalis neurons are excited by histamine in vitro

Considerable evidence has shown that both cholinergic and histaminergic neurons in the brain may act to facilitate processes of cortical activation that occur during wakefulness. In the present study, the potential influence of histaminergic neurons upon cholinergic neurons of the basal forebrain was investigated in guinea-pig basal forebrain slices. We found that electrophysiologically identified and immunohistochemically verified cholinergic neurons of the nucleus basalis were depolarized and excited by histamine, as manifested by an increase in tonic firing. The depolarization was associated with an increase in membrane input resistance. The effect of histamine persisted in the presence of either tetrodotoxin or a high-magnesium/low-calcium solution, indicating that it is postsynaptic. By a process of elimination, the participation in this response of the three described histamine receptors was examined. Involvement of H3 receptors was excluded on the basis that the H3 agonist (R)-alpha-methyl-histamine had no direct effect, and the H3 antagonist, thioperamide, did not block the effect of histamine. In contrast, the presence of a small response to impromidine, a selective agonist of H2 receptors, and the partial block of the response to histamine by the H2 receptor antagonist, cimetidine, indicated the participation of H2 receptors. Finally, the complete elimination of histamine's effect occurred when low doses of the H1 antagonist, mepyramine, were added to the H2 antagonist, cimetidine, indicating the involvement and predominance of H1 receptors in the response. Our data thus suggest that histamine excites nucleus basalis cholinergic neurons by a concomitant activation of H1 and H2 receptors. Histaminergic tuberomammillary neurons may accordingly facilitate tonic firing of cholinergic neurons during wakefulness. Cholinergic basalis neurons could thus act in tandem with histaminergic neurons during periods of arousal to collectively promote widespread cortical activation.

Mechanisms of antihistamine-induced sedation in the human brain: H1 receptor activation reduces a background leakage potassium current

Antihistamines, more formally termed H1 receptor antagonists, are well known to exert sedative effects in humans, yet their locus and mechanism of action in the human brain remains unknown. To better understand this phenomenon, the effects of histamine upon human cortical neurons were studied using intracellular recordings in brain slices maintained in vitro. Bath application of 50 microM histamine induced a depolarization which could be attributed to reduction of a background voltage-independent "leakage" potassium current: the depolarization was associated with an increase in apparent input resistance, under voltage clamp its reversal potential approximated the potassium reversal potential, and the histamine-induced current exhibited little voltage dependence. The pharmacology of the histamine-induced depolarization of human cortical neurons was studied by use of both agonists and antagonists. Depolarizing responses were blocked by the H1 antagonist mepyramine, but not by the H2 antagonist cimetidine nor the H3 antagonist thioperamide. The H3 receptor agonist R-alpha-methyl-histamine did not mimic the effects of histamine. Thus, histamine depolarizes human cortical neurons via action at an H1 receptor. These effects of neuronal histamine upon cortical neurons are likely to affect synaptic transmission in several ways. The depolarization per se should increase the likelihood that excitatory synaptic potentials will evoke an action potential. The increase in whole-cell input resistance evoked by H1 receptor activation should make the cell more electrotonically compact, thereby altering its integrative properties. We hypothesize that these mechanisms would allow histamine, acting at cortical H1 receptors, to enhance behavioral arousal. During waking when histamine release is highest, blockade of H1 receptors by systemically administered H1 receptor antagonists would be sedating.

Hypothalamo-preoptic histaminergic projections in sleep-wake control in the cat

Cats were chronically implanted with electrodes for polygraphic recordings and cannulae for intracerebral microinjections in order to study the functional role of histaminergic innervation of the preoptic-anterior hypothalamus in sleep-wake control. alpha-Fluoromethylhistidine (alpha FMH, 50 micrograms in 1 microliter), a specific inhibitor of the histamine-synthesizing enzyme, when injected bilaterally into the preoptic area, where numerous histaminergic fibres and terminal-like structures are present, caused a significant increase in deep slow wave sleep (S2) and paradoxical sleep (PS) and a decrease in wakefulness. In contrast, microinjections of histamine (5 or 30 micrograms in 1 microliter) in the same area dose-relatedly increased wakefulness and decreased both slow wave sleep and paradoxical sleep. The effects of histamine were reduced by pretreatment with mepyramine (1 mg/kg i.p.), a well known histamine H1 receptor antagonist, and were mimicked by a local injection of impromidine (1 microgram in 1 microliter), a potent histamine H2 receptor agonist. Microinjections of mepyramine alone (120 micrograms in 1 microliter) caused an increase in slow wave sleep. These results suggest that preoptic histaminergic innervation is involved in sleep-wake control and that the action might be mediated via both H1 and H2 receptors.

Histamine modulates heat stress-induced changes in blood-brain barrier permeability, cerebral blood flow, brain oedema and serotonin levels: an experimental study in conscious young rats

The possibility that endogenous histamine plays an important role in modulating the pathophysiology of heat stress was examined in young rats using a pharmacological approach. Subjection of young animals (six to seven weeks old) to heat stress at 38 degrees C for 4 h in a biological oxygen demand incubator (relative humidity 47-50%, wind velocity 20-25 cm/s) resulted in a profound increase in blood-brain barrier permeability to Evans Blue albumin (whole brain 375%) and [131I]sodium (whole brain 478%) along with a significant reduction in the cerebral blood flow (mean 34%). The water content of the whole brain was elevated by 4.5% (about 19% volume swelling) from the control. At this time-period, the plasma and whole brain 5-hydroxytryptamine levels were elevated by 656% and 328%, respectively, from the control group. Pretreatment with cimetidine (a histamine H2 receptor antagonist) significantly thwarted the increases in the brain water content and the blood-brain barrier permeability. In cimetidine-pretreated animals, the cerebral blood flow was significantly elevated and the plasma and brain 5-hydroxytryptamine (serotonin) levels were slightly but significantly reduced as compared with the untreated stressed group. However, prior treatment with mepyramine (a histamine H1 receptor antagonist) neither attenuated the changes in water content and the blood-brain barrier permeability nor altered the cerebral blood flow and 5-hydroxytryptamine levels. In fact, there was a significantly higher permeation of the tracers across the cerebral vessels in these drug-treated animals along with a greater accumulation of the brain water content as compared with the untreated stressed group. The cerebral blood flow and 5-hydroxytryptamine levels showed only minor changes from the untreated stressed group. These results show, probably for the first time, that (i) the endogenous histamine plays an important role in the pathophysiology of heat stress, and (ii) this effect appears to be mediated via specific histamine H2 receptors.

Histamine excites arcuate neurons in vitro through H1 receptors

The electrophysiological effects of histamine on neurons of the hypothalamic arcuate nucleus of the female rat were tested with extracellular single unit recordings in an in vitro slice preparation. Histamine increased the spontaneous neuronal firing rate in 63% of the arcuate cells tested. An inhibitory response to histamine was seen in only one of the 117 neurons tested. The excitatory response to histamine showed dose dependency and was stable during synaptic blockade (by high magnesium and low calcium concentrations) and across a temperature range of 29-37 degrees C. Administration of histaminergic type 1 (pyrilamine and chlorpheniramine) and type 2 (cimetidine) receptor blockers revealed that the excitatory responses to histamine were mediated by type 1 receptors. The same neurons were also tested for responses to norepinephrine, serotonin, acetylcholine and substance P. A significant correlation was found between responses to histamine and substance P: all units excited by substance P were also excited by histamine. This subclass of histamine-responsive arcuate neurons may play a role in the regulation of the anterior pituitary, since histamine and substance P have similar effects on LH and prolactin secretion.

Responses of hypothalamic paraventricular neurons in vitro to norepinephrine and other feeding-relevant agents

To investigate paraventricular hypothalamic neuronal actions responsible for the effects of neurotransmitters on feeding, and to test the notion that a single population of cells there could account for feeding effects, hypothalamic slices containing the paraventricular nucleus (PVN) were prepared from rats. Electrophysiological responses of individual PVN neurons to feeding-inducing agents norepinephrine (NE) and gamma-aminobutyric acid (GABA), and to anorexic agents serotonin (5-HT) and histamine (Hist) were examined. NE inhibited neuronal activity through alpha 2-adrenergic receptors, and excited through alpha 1-receptors. alpha 2-receptors are known to mediate the behavioral effect of NE. NE inhibited most clearly those neurons that otherwise fired continuously in this type of in vitro preparation. GABA affected the activity of 37% of the neurons tested, primarily by inhibition. The inhibitory action of GABA can be related to its feeding-inducing effect. GABA in PVN can also attenuate excitatory responses and enhance inhibitory responses to NE or 5-HT. 5-HT caused excitatory and inhibitory responses with the former action outnumbering the latter by approximately 3 to 1. Since this would result in a net excitation, it appears that 5-HT in PVN inhibits feeding mainly by exciting neuronal activity. Hist excited 72% and inhibited only 2% of PVN neurons. The excitation was blocked by H1-antagonists, which have been shown to mediate Hist effect on feeding. Comparing across neurons, the inhibitory response to NE was correlated with that to GABA, but not with any responses to 5-HT or Hist. The excitatory responses to Hist correlated with 5-HT responses.(ABSTRACT TRUNCATED AT 250 WORDS)

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.

Analysis of histamine as a hair-cell transmitter in the lateral line of Xenopus laevis

The actions of histamine and histamine antagonists on afferent nerve activity were investigated in the lateral line of Xenopus laevis. Histamine (0.002-2.0 mM) had no effect on spontaneous activity or excitatory responses to water motion. In contrast, pyrilamine, an H1 receptor antagonist, suppressed spontaneous activity beginning at 0.01-0.05 mM. Below 0.3 mM the suppression was often preceded by a small excitatory response and responses to high (24-30 dB re threshold), but not low (0-18 dB) levels of water motion were selectively suppressed. Higher concentrations (0.3-2.0 mM) abolished spontaneous activity and suppressed responses at all levels of water motion. Cimetidine, an H2 receptor antagonist, had similar actions but was one-tenth as potent as pyrilamine. Tetrodotoxin (0.001-0.1 microM), which blocks voltage-sensitive Na+ channels, mimicked the suppressive effects of the histamine antagonists. Histamine (2.0 mM) failed to block the actions of pyrilamine (0.1 mM) indicating its effects are mediated through a mechanism other than histamine receptors. In addition, pyrilamine (0.05-0.1 mM) non-selectively suppressed excitation to exogenously applied L-glutamate (1.0-2.0 mM), L-aspartate (1.0-2.0 mM), kainate (0.005-0.01 mM), and quisqualate (0.002-0.005 mM) and altered responses to N-methyl-D-aspartate (0.5-1.0 mM). The results are inconsistent with histamine being a transmitter in the Xenopus lateral line and reveal that the actions of histamine antagonists are nonspecific, possibly due, in part, to blockade of voltage-sensitive Na+ channels.

Origins of brainstem-spinal projections in the duck and goose

The purpose of this study was to determine the location of neuronal cell bodies with projections to the cervical or lumbar spinal cord in the adult duck and goose. Bilateral or unilateral injections (5-10 microliter) of the retrograde tracer dye True Blue (TB:5%) were made into the high cervical or high lumbar levels of the spinal cord. Similar results were obtained in both species. First, we found no evidence of retrogradely labelled cells in the telencephalon. In the brainstem, the distribution of TB cells was similar to those previously reported for the pigeon; however, the present study now demonstrates that some of these descending pathways project as far as the lumbar cord. We also discovered that there is a topographical representation of spinal projecting neurons within the avian medullary-pontine reticular formation.

Evidence for excitatory actions of histamine on supraoptic neurons in vitro: mediation by an H1-type receptor

The effects of histamine on the firing of supraoptic neurosecretory neurons in the rat were examined in vitro using acutely prepared, hypothalamo-neurohypophysial explants perifused with an artificial cerebrospinal fluid. Extracellular action potentials meeting the criteria of antidromic invasion from neurohypophysial stalk stimulation were recorded from 135 neurons in the tuberal portion of the supraoptic nucleus, which lies superficially along the tuber cinereum and consists of mostly vasopressin-containing neurons. Units could be classified as slow/silent (76.3%), phasic (21.5%) or continuous (2.2%) on the basis of their spontaneous activity. Histamine applied briefly to the perifusate excited approximately one-third of the slow silent neurons and approximately two-thirds of the phasic neurons, with a wide range (10(-3)-10(-9)) in the effective concentration across neurons. The H1-receptor agonists 2-pyridylethylamine and 2-thiazolylethylamine mimicked these excitations in 10 of 12 and 3 of 6 neurons tested, respectively. The H2-receptor agonists dimaprit (4 neurons) and impromidine (5 neurons) failed to excite any of the tested neurons previously excited by histamine. The H1-receptor antagonist promethazine antagonized histamine's excitatory effect in 8 of 9 cells, while the H2-receptor antagonist cimetidine had little effect on the 9 cells tested. Histamine also modified bursts of activity induced in some slow/silent neurons by antidromic stimulation without having an observable effect in the absence of an antidromic burst. In 10 of 18 neurons histamine produced an elongation of burst duration and a modest increase in intraburst firing rate when applied during an antidromically evoked burst. In an additional 5 of 17 neurons, which had neither previously responded to histamine nor shown an antidromically-evoked burst, the pairing of histamine application and antidromic shocks resulted in an antidromically evoked burst. The effects of histamine on evoked bursts also appeared to be mediated by an H1-receptor. Histamine's excitation of supraoptic neurons is thus dependent on the electrical activity expressed by the neuron at the time of testing. Conductances activated by depolarization of the neuron may be modified by histamine or this compound may alter the threshold for burst generation. Considered with data showing H1-receptor localization and histamine-immunoreactive fibers within the supraoptic nucleus, the present results, as well as those showing the potency of centrally applied histamine in releasing vasopressin, suggest histamine may act physiologically by altering the electrical activity of vasopressin-secreting neurons.

Histamine-induced depression of serotoninergic dorsal raphe neurons: antagonism by cimetidine, a reevaluation

Microiontophoretic application of the histamine H2-receptor antagonist cimetidine selectively attenuated the histamine-induced, but not the gamma-aminobutyric acid (GABA)-induced, depression of serotoninergic cells recorded in the dorsal raphe nucleus of the rat. These data support the view that an H2-receptor mediates the effects of histamine on these serotoninergic neurons. We also now ascribe a previous report of GABA-like properties of cimetidine and metiamide to an impurity in the lots of these compounds used originally.

Electrophysiological studies on benzodiazepine antagonists

The actions of the benzodiazepine (BDZ) antagonists 3-hydroxymethyl-beta-carboline (3-HMC), Ro 14-7437 and Ro 15-1788 were tested on single cell activity of rat hypothalamic neurons in tissue cultures and on membrane properties of CA1 hippocampal pyramidal neurons in transverse slices. In addition, we examined the interactions of some of these agents with inhibitions elicited by gamma-aminobutyric acid (GABA) as well as the ability of Ro 14-7437 to reverse the GABA-enhancing action of the BDZ agonist flurazepam. BDZ antagonists did not alter patterns of spontaneous activity of hypothalamic neurons and did not affect resting membrane potential or membrane conductance in CA1 pyramidal cells. Ro 14-7437 either partially or totally reversed the potentiation by flurazepam of GABA-elicited depression of hypothalamic neuronal activity. Small and inconsistent actions on GABA-mediated inhibitions of hypothalamic neurons were noted. Electrically-elicited inhibitions of hypothalamic neurons were either not altered or slightly reduced. In the hippocampal slice, the frequency of spontaneous IPSPs, the amplitude of stratum-radiatum evoked IPSPs and the conductance increase caused by stratum-radiatum stimulation were either not altered or slightly reduced. These findings demonstrate that non-convulsant BDZ antagonists block the action of BDZ agonists in facilitating GABA and further that the presence of a BDZ agonist is not required for these GABA-mediated events to occur. However, these experiments do not exclude a modulatory role for an endogenous BDZ agonist on GABA-mediated events.

Modulation of low calcium induced field bursts in the hippocampus by monoamines and cholinomimetics

The influence of monoamine transmitter candidates, acetylcholine and related substances on rhythmic depolarization shifts (field bursts) in the CA 1 area of hippocampal slices from rats in low calcium (0.2 mmol X 1(-1) ) high magnesium (4 mmol X 1(-1) ) was investigated. Acetylcholine (ACh), histamine (HA) and H2-agonists, noradrenaline (NA) and beta-agonists at nano- to micromolar concentrations as well as dopamine (DA) and 8-bromo-cyclic AMP at 100 mumol X 1(-1) accelerated the field bursts. H2-antagonists blocked HA actions, beta-antagonists blocked NA actions selectively; muscarinic antagonists blocked ACh, HA and NA actions. H1-agonists, serotonin, dopamine and adenosine slowed the field bursts at micromolar concentrations. These effects parallel the action of the tested substances on afterhyperpolarizations in CA 1 pyramidal cells. High sensitivity and specificity make this response of the field bursts an excellent model to study postsynaptic transmitter actions in the central nervous system.

Histamine and the hypothalamus

The chemical tools that could be used to examine the function of histamine in the brain are considered together with the evidence linking histamine specifically with the hypothalamus. The distribution of histamine and the enzymes responsible for its synthesis and metabolism is consistent with there being both mast cells and histaminergic nerve terminals within the hypothalamus. Iontophoresis, mepyramine binding and histamine-stimulated adenylate cyclase studies suggest that both histamine H1- and H2- receptors are present in the hypothalamus. In addition, intracerebroventricularly injected histamine receptor agonists and antagonists affect many functions associated with the hypothalamus such as cardiovascular control, food intake, body temperature control, and pituitary hormones whose release is mediated via the hypothalamus, such as corticotropin, growth hormone, thyroid stimulating hormone, prolactin, gonadotropins and vasopressin. However, only in the case of thyroliberin release, prolactin release, body fluid control and blood pressure control is there evidence yet that such effects are mediated via histamine receptors actually in the hypothalamus. The effects of enzyme inhibitors suggest endogenous histamine may be involved in the physiological control of thyroid stimulating hormone, growth hormone and blood pressure, and the effects of receptor antagonists support a role for endogenous histamine in prolactin control. Otherwise, there is little evidence for a physiological role for endogenous, as against exogenous, histamine whether it be from histaminergic terminals or mast cells. In addition, few studies have tried to distinguish possible effects on presynaptic receptors, postsynaptic receptors, hypothalamic blood vessels or the hypophyseal portal blood vessels. It is concluded that although there is good evidence now linking histamine and the hypothalamus more specific studies are required, for instance using microinjection or in vitro techniques and the more specific chemical tools now available, to enable a clearer understanding of the physiological role of histamine in the hypothalamus.

Regional effect of mepyramine on cerebral glucose utilization in conscious rats

We examined effects of the antihistamine, mepyramine, which occupies cerebral H1-receptors, on regional brain metabolism of glucose in conscious rats. Although glucose utilization by most structures was not significantly affected, in high doses, mepyramine did cause modest, localized reductions in brain areas with both high (ventromedial nucleus of hypothalamus) and low (medial forebrain bundle) densities of histamine H1-receptors.