Histamine H2-binding on guinea pig cerebral cortex

Cherry-picked ligands at histamine receptor subtypes

Histamine, a biogenic amine, is considered as a principle mediator of multiple physiological effects through binding to its H1, H2, H3, and H4 receptors (H1-H4Rs). Currently, the HRs have gained attention as important targets for the treatment of several diseases and disorders ranging from allergy to Alzheimer's disease and immune deficiency. Accordingly, medicinal chemistry studies exploring histamine-like molecules and their physicochemical properties by binding and interacting with the four HRs has led to the development of a diversity of agonists and antagonists that display selectivity for each HR subtype. An overview on H1-R4Rs and developed ligands representing some key steps in development is provided here combined with a short description of structure-activity relationships for each class. Main chemical diversities, pharmacophores, and pharmacological profiles of most innovative H1-H4R agonists and antagonists are highlighted. Therefore, this overview should support the rational choice for the optimal ligand selection based on affinity, selectivity and efficacy data in biochemical and pharmacological studies. This article is part of the Special Issue entitled 'Histamine Receptors'.

Histamine receptor-independent muscle relaxation elicited by a series of histamine H2-receptor agonists on the isolated guinea pig duodenum: a study into the mechanism of action

1. The histamine H2 receptor agonists, dimaprit, impromidine, amthamine, and several dimaprit- and impromidine-analogues were investigated for their spasmolytic activity on the guinea pig duodenum, precontracted with acetylcholine or KCl. 2. Almost all the H2 receptor agonists exerted a histamine H2 receptor-independent muscle relaxation, which was more evident on acetylcholine- than on KCl-precontracted preparations. 3. The relaxing activity of these compounds was independent of inhibitory receptors, like beta-adrenergic, GABA-ergic, serotoninergic, etc. Similarly, modifications of cyclic nucleotide metabolism and nitric oxide production did not appear to be involved. 4. The behavior of histamine H2-receptor agonists was shared only by the Na+-blocker procaine, the intracellular Ca2+-antagonist ruthenium red and, at least in terms of efficacy, by the protein kinase C inhibitor, chelerithrine. 5. This spasmolytic effect is probably due to an impairment of receptor-mediated depolarization at the plasma membrane level and/or an inhibitory activity on the protein kinase C-dependent activation of the contractile machinery. 6. Finally, our findings suggest that the histamine H2 receptor-independent muscle relaxation is a general feature shown by H2 receptor agonists endowed with different chemical structure and the putative spasmolytic "receptor" prefers a (substituted) thiazole over a (substituted) imidazole.

Molecular pharmacological aspects of histamine receptors

In this article, we review the recent developments in the field of histamine research. Besides the description of pharmacological tools for the H1, H2 and H3 receptor, specific attention is paid to both the molecular aspects of the receptor proteins, including the recent cloning of the receptor genes, and their respective signal transduction mechanisms.

Structural modification patterns from agonists to antagonists and their application to drug design--a new serotonin (5-HT3) antagonist series

Structural variations from agonists to their selective antagonists seemed to follow certain patterns. To analyze the variation patterns in the structural modification processes in past examples as well as to utilize the "common" variation patterns as possible principles to design new selective antagonistic drugs, the structures of agonists and their antagonists were superimposed on a two-dimensional grid template composed of regular hexagons and the topological similarities and dissimilarities of substructural elements between agonists and antagonists were examined. Between several pairs of neurotransmitter amines and their "selective" antagonists, similar patterns were disclosed in their structural modification processes. The generalized structural modification patterns were successfully applied as guiding principles to design and identify a new prototype structure of the 5-HT3 antagonist. The prototype structure was optimized by use of QSAR procedures leading to a compound which shows a potent antiemetic activity as well as a powerful gastrointestinal-motility modulation.

Identification of adenylate cyclase-coupled histamine H2 receptors in guinea pig tracheal smooth muscle cells in culture and the effect of dexamethasone

Histamine acts on airway contractile elements through at least two different receptor subtypes: H1, which mediates Ca(2+)-dependent contraction, and H2, which stimulates cyclic adenosine monophosphate (cAMP) synthesis and possibly relaxation. The aim of this study was to determine the relative contribution of the different receptor subtypes to histamine-stimulated cAMP production by guinea pig tracheal smooth muscle (GPTSM) cells in primary culture. Histamine and N-alpha-methylhistamine induced concentration-dependent cAMP synthesis; these effects were entirely blocked by 10(-4) M cimetidine, an H2-receptor antagonist, whereas 10(-6) M thioperamide, a selective H3 blocker, was ineffective. The H3 agonist, R-(alpha)-methylhistamine, did not stimulate cAMP synthesis. Triprolidine, an H1 antagonist, did not modify histamine (10(-5) M)-stimulated cAMP synthesis. Histamine (10(-5) M) doubled [Ca2+]i in GPTSM. A 24-h pretreatment of GPTSM cells with 10(-6) M dexamethasone enhanced cAMP synthesized in response to 10(-5) M histamine and to 5 x 10(-6) M forskolin but did not significantly alter either the affinity or the binding capacity for [3H]-tiotidine, an H2-receptor antagonist. These results indicate that GPTSM cells in culture express H2 but not H3 receptors, which are linked to adenylate cyclase; their functional expression does not seem to be modulated by the concurrent activation of H1 receptors, whose presence in GPTSM is evidenced by a histamine-stimulated increase in [Ca2+]i. The most likely site of action of dexamethasone in enhancing histamine-stimulated cAMP synthesis is at the level of adenylate cyclase since the steroid had no effect on the H2 receptor itself.

Structure-activity relationships of histamine H2-agonists, a new class of positive inotropic drugs

The cimetidine-like moiety in impromidine was replaced by either alternative partial structures known from H2-antagonists or by H2-nonspecific lipophilic groups. The most potent H2-agonists were found in a series of compounds structurally derived from the H1-antagonist pheniramine. Arpromidine (N1-[3-(4-fluorophenyl)-3-(2-pyridinyl)propyl]-N2-[3-(1H-imidazol-4- yl)propyl]guanidine) may be considered a new lead for the development of "cardiohistaminergics". This guanidine combines both about 100 times the potency of histamine in the isolated guinea-pig atrium (pD2 = 8.0) and H1-antagonistic activity (pA2 = 7.65) in the range of pheniramine. Analogues difluorinated in 3,4-(BU-E-75) or 3,5-position (BU-E-76) or chlorinated in 3,4-position (BU-E-64) are up to 160 times more potent H2-agonists than histamine. In contrast to other types of guanidines, in the arpromidine series the order of potency found in guinea-pig atria was in good agreement with the results from isolated perfused guinea-pig hearts. In particular, the two-fold halogenated arpromidine analogues proved to be more potent positive inotropic agents than impromidine with lower stimulating effects on heart rate and reduced arrhythmogenic properties.

Histamine receptors: subclasses and specific ligands

In this review the three main types of histamine receptors are discussed together with their specific ligands. For the classical H1-receptors much emphasis is put on the mechanism by which the receptor is stimulated. For the H1- and H2-receptor the review includes information on the several models available for establishing agonistic or antagonistic activity. In the section on the H3-receptor the ligands are discussed as well as the possible physiological role of this receptor. In the final paragraphs some less well defined activities are presented.

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.

Histamine receptors in the central nervous system

The role of histamine in brain function is discussed. A brief review is presented on the three types of histamine receptors with regard to their biochemistry and functions, as well as on specific ligands, both agonists and antagonists. It is concluded that several aspects of the pharmacology of histamine in the central nervous system are still a matter of empirism and speculations. The recent publications on the brain-penetrating H2 antagonist zolantidine and the selective H3 agonists and antagonists are expected to contribute to the knowledge of the histaminergic pathways in the brain. Therapeutical areas within the central nervous system are related to behaviour (including wake-sleep), neuroendocrinal processes, the control of muscle activity and cerebral circulation.

Studies on histaminergic compounds, Part VII. Histamine H2-binding on guinea-pig cerebral cortex compared to histamine (ant)agonism

The pKD values of series of H2-active compounds, obtained from displacement curves of 3H-tiotidine from a guinea-pig cerebral cortex homogenate were compared with the pA2/pD2 values of these compounds on the right atrium of the same animal species. A good correlation was found between the cortex pKD value and the pharmacological activity on the right atrium, especially with the antagonists, the partial agonists and the agonistic impromidine analogues (guanidines). The poor correlation between cortex pKD and atrium pD2 of some other agonists (the amines) might be explained by the presence of spare receptors for these compounds. The different number of spare receptors for the guanidines and the amines might be explained by the differences in base strength of these compounds.

Relation between pharmacological response and receptor binding with histamine blocking drugs. Irreversible antagonism of three analogues of mifentidine on right atrium and cerebral cortex of the guinea-pig

The effects of the H2-receptor antagonists cimetidine, ranitidine, mifentidine and three analogues of mifentidine, were studied on the spontaneously beating right atrium (H2-antagonism) and membranes of the cerebral cortex (displacement of 3H-tiotidine), both obtained from the male guinea-pig. The choice of these compounds was based on preliminary experiments in which some mifentidine analogues were shown to displace tiotidine from the H2-receptor in a deviant manner. In the present study we investigated the relation between pharmacological response and receptor binding, also testing the degree of irreversible antagonism of these compounds in the atrium (functional) and cerebral cortex (binding) model. Our data indicate that a relation between the two different approaches for measuring the effect on the H2-receptor can be found, although some differences emerged as well.

H3 receptor assay in electrically-stimulated superfused slices of rat brain cortex; effects of N alpha-alkylated histamines and impromidine analogues

The release of the putative neurotransmitter histamine (HA) from rat brain cortex slices is under negative feedback control by an HA autoreceptor. This autoreceptor has been postulated to belong to a new class of HA receptors, H3. To verify this hypothesis we have developed an assay using superfused rat brain cortex slices. The HA transmitter pool is labelled by incubation of the slices with the precursor 3H-histidine; 3H-HA is estimated after separation by column chromatography. Release of HA was found both after K+-induced depolarization and electrical field stimulation. The latter resulted in higher and more reproducible HA release. Electrically induced HA release could be fully inhibited in a concentration dependent way by exogenous HA in the superfusion buffer. N alpha-alkylated histamines also showed agonistic activity. The action of exogenous HA was totally blocked by the potent H2 agonist impromidine and some of its analogues.