Irreversible and specific inactivation by AH 22216 of histamine H2 receptors in the human gastric cancer cell line HGT-1

Molecular and cellular analysis of human histamine receptor subtypes

The human histamine receptors hH(1)R and hH(2)R constitute important drug targets, and hH(3)R and hH(4)R have substantial potential in this area. Considering the species-specificity of pharmacology of H(x)R orthologs, it is important to analyze hH(x)Rs. Here, we summarize current knowledge of hH(x)Rs endogenously expressed in human cells and hH(x)Rs recombinantly expressed in mammalian and insect cells. We present the advantages and disadvantages of the various systems. We also discuss problems associated with the use of hH(x)R antibodies, an issue of general relevance for G-protein-coupled receptors (GPCRs). There is much greater overlap in activity of 'selective' ligands for other hH(x)Rs than the cognate receptor subtype than generally appreciated. Studies with native and recombinant systems support the concept of ligand-specific receptor conformations, encompassing agonists and antagonists. It is emerging that for characterization of hH(x)R ligands, one cannot rely on a single test system and a single parameter. Rather, multiple systems and parameters have to be studied. Although such studies are time-consuming and expensive, ultimately, they will increase drug safety and efficacy.

Structure-activity characterization of an H2-receptor antagonist, 3-amino-4-[4-[4-(1-piperidinomethyl)-2-pyridyloxy]-cis-2-++ +butenylamino]- 3-cyclobutene-1,2-dione hydrochloride (T-066), involved in the insurmountable antagonism against histamine-induced positive chronotropic action in guinea pig atria

IT-066 (3-amino-4-[4-[4-(1-piperidinomethyl)-2-pyridyloxy]-cis-2- butenylamino]-3-cyclobutene-1,2-dione hydrochloride), an H2-receptor antagonist, shows highly potent, time-dependent, and irreversible antagonism at H2-receptors. We identified the structurally important parts of IT-066 involved in its interaction with the H2-receptor, and explored its unique mode of action by investigating the H2-receptor blocking action of IT-066 and related compounds in guinea pig isolated atria. IT-066 is structurally divided into three different parts: a tertiary amine and hydrophobic group, a connecting carbon chain, and a polar group. Though the replacement of its pyridine ring with a benzene ring maintained the mode of the H2-receptor blocking action of IT-066, the oxidation of the piperidine ring completely attenuated this blocking action. By replacing the connecting carbon chain of IT-066, cis-2-butene, with butane, trans-2-butene, or 2-butyne, the irreversible antagonism disappeared and the potency was reduced. On the other hand, BMY25368, whose connecting carbon chain is trimethylene, showed irreversible antagonism comparable to that of IT-066. Hydrolysis of the polar group of IT-066 completely attenuated the H2-receptor blocking activity. Among the compounds tested, only the compound that had 3,4-diamino-3-cyclobutene-1,2-dione as a polar group showed time-dependent and insurmountable H2-receptor blocking action. These data suggest the importance of the following structural features of IT-066: the piperidine ring of IT-066 and -NH2 in its polar group are essential for the interaction with the H2-receptor; and the 3,4-diamino-3-cyclobutene-1,2-dione group and the connecting carbon chain of IT-066 are crucial for determining the irreversibility of H2-receptor blocking action, though the connecting carbon chain is replaceable with another chain with appropriate length and configuration.

Pharmacological control of the human gastric histamine H2 receptor by famotidine: comparison with H1, H2 and H3 receptor agonists and antagonists

Histamine 0.1 microM-0.1 mM increased adenylate cyclase activity five- to ten-fold in human fundic membranes, with a potency Ka = 3 microM. The histamine dose-response curve was mimicked by the H3 receptor agonist (R) alpha-MeHA, but at 100 times lower potency, Ka = 0.3 mM. Histamine-induced adenylate cyclase activation was abolished by H2, H1 and H3 receptor antagonists, according to the following order of potency IC50: famotidine (0.3 microM) greater than triprolidine (0.1 mM) thioperamide (2 mM), respectively. Famotidine has no action on membrane components activating the adenylate cyclase system, including the Gs subunit of the enzyme stimulated by forskolin and cell surface receptors sensitive to isoproterenol (beta 2-type), PGE2 and VIP. The Schild plot was linear for famotidine (P less than 0.01) with a regression coefficient r = 0.678. The slope of the regression line was 0.64 and differs from unity. Accordingly, famotidine showed a slow onset of inhibition and dissociation from the H2 receptor in human cancerous HGT-1 cells. The results demonstrate that famotidine is a potent and selective H2 receptor antagonist with uncompetitive actions in human gastric mucosa. Consequently, famotidine might be a suitable drug with long-lasting actions in the treatment of Zollinger-Ellison syndrome. The results also confirm and extend the previous observations that (R) alpha-MeHA and thioperamide are two selective ligands at histamine H3 receptor sites. In the human gastric mucosa, these drugs are respectively 330 and 6700 times less potent than histamine and famotidine on the adenylate cyclase system. The possible involvement of histamine H3 receptors in the regulation of gastric secretion is proposed.

Pharmacological control of the histamine H2 receptor-adenylate cyclase system by famotidine and ranitidine in normal and cancerous human gastric epithelia

In human fundic glands, famotidine was about 17 times more potent than ranitidine as an inhibitor of histamine - stimulated cAMP generation. This H2-receptor antagonist had no effect on the receptor-adenylate cyclase systems sensitive to PGE2, isoproterenol (beta 2-receptor), VIP and on forskolin-induced activation of the Gs/catalytic units of the membrane-bound enzyme prepared from human fundic glands. In the HGT-1 human gastric cancer cell line, famotidine and ranitidine showed long lasting, irreversible actions probably related to a slow rate of dissociation from the histamine H2-receptor.

Pharmacological studies of 2-(3-(3-(1-piperidinylmethyl)-phenoxy)propylamino)-4 (3H)-quinazolinone (NO-794), a new histamine H2-receptor antagonist

The pharmacological profile of a new histamine H2-receptor antagonist, 2-(3-(3-(1-piperidinylmethyl)phenoxy)propylamino)-4 (3H)-quinazolinone (NO-794), was studied. NO-794 was a potent and selective histamine H2-receptor antagonist in the guinea-pig atria and gastric mucosal cells. NO-794 (1 X 10(-5) M) did not interact with H1-, muscarinic and beta 1-receptors. In guinea-pig atria, antagonism of NO-794 was unsurmountable. The onset of action of NO-794 was slow, and this antagonism was apparently irreversible not only on the guinea-pig atria but also on the gastric mucosal cells. In addition, NO-794 inhibited gastric acid secretion in pylorus ligated rats when administered intraduodenally. These results indicate that NO-794 is a powerful and unique histamine H2-receptor antagonist and may be useful in the treatment of peptic ulcer.

Pharmacology of histamine H2 receptor antagonists in the human gastric cancer cell line HGT-1. Structure-activity relationship of isocytosine-furan and imidazole derivatives related to cimetidine

Imidazole and isocytosine-furan derivatives inhibited H2 receptor activity in HGT-1 cells, in accordance with the following relative potencies (IC50 = 2.3 microM cimetidine as reference): SKF 93479 = cimetidine = 100 greater than metiamide = 62 greater than SKF 92408 = 2 greater than SKF 91581 = 0.07). The Schild plot for cimetidine was linear (slope = 0.97) with a pA2 value of 6.72 +/- 0.12 (Ki = 0.18 microM cimetidine), suggesting competitive inhibition. Preincubation of HGT-1 cells for 10 min with H2 antagonists at 2 microM concentration resulted in 90-100% inactivation (SKF 93479 and oxmetidine) and 65% inactivation (ranitidine) which persisted for 30 min, even after a washout period. Accordingly, the kinetics of 2 microM [3H] SKF 93479 binding to HGT-1 cells revealed a half-time for association of 10 min and a dissociation half-time of 120 min. There was a good correlation between the kinetics and relative potencies of cimetidine and SKF 93479 in inhibiting H2 receptor activity in purified plasma membranes (40 nM) as well as in intact HGT-1 cells preincubated for 2 hr with SKF 93479 before histamine addition (45 nM). Chronic treatment of HGT-1 cells for 6 days with 2 microM SKF 93479 specifically blocked H2 receptor activity since cyclic AMP generation induced by other hormones and agents such as VIP, glucagon, GIP and sodium fluoride was unaltered. In contrast, short term and chronic treatment by cimetidine was readily reversible. The isocytosine-furan derivative SKF 93479 differs from the imidazole analogue cimetidine by its apparent irreversible action, due to the slow onset of association from HGT-1 cells. The isocytosine ring in SKF 93479 and oxmetidine seems to play a preponderant role in their apparent long-lasting, irreversible actions.

VIP and histamine H2 receptor activity in human fetal gastric glands

Vasoactive intestinal peptide (VIP, EC50 = 6.4 X 10(-10)M) and histamine (EC50 = 3 X 10(-6)M) activated the cyclic AMP generating system in gastric glands isolated from two human fetuses at 23 weeks gestation. Histamine antagonism by the H2 receptor blockers cimetidine (Ki = 0.35 X 10(-6)M) and ranitidine (ki = 0.51 X 10(-7)M) clearly characterized the histaminic activation as being of the H2 type. It is suggested that these two vasoactive hormones may operate as neurocrine/paracrine regulators of the differentiation and/or function of the human gastric mucosa in utero.

Functional receptors for VIP, GIP, glucagon-29 and -37 in the HGT-1 human gastric cancer cell line

Three separate sets of receptors sensitive to VIP, GIP and pancreatic/entero-glucagons, have been characterized in HGT-1 cells. The order of relative potencies of VIP receptor agonists was VIP greater than rh GRF-43, rh GRF-29 greater than PHI greater than hp GRF-40, secretin. G-37 was about 4 times less potent than G-29 in HGT-1 cells (G-29 greater than G-37), whereas it was about 20 times more potent than G-29 in rat fundic glands (G-37 greater than G-29). Adenylate cyclase in HGT-1 cells was stimulated by VIP, G-29, G-37 and GIP, over a concentration from 3.16 X 10(-9) to 3.16 X 10(-7) M GIP. The experimental data: (1) support the enterogastrone activity of GIP, via adenylate cyclase activation and somatostatin release by gastric D cells; (2) demonstrate that HGT-1 cells originating from a human fundic tumor are sensitive to the glucagon-like peptides G-29 and -37, as rat fundic glands; (3) indicate that the pharmacological properties of the VIP receptor in this human gastric cell line are similar to those characterized in normal human gastric glands.

VIP inhibits histamine-induced ultrastructural changes related to acid secretion by parietal cells

We have studied the in vitro effect of VIP and histamine on ultrastructure of the parietal cells in isolated guinea pig fundic glands. The morphological changes induced by histamine in the parietal cells can be compared to those observed after histamine stimulation in vivo or in vitro on gastric mucosa preparations. In contrast, VIP incubation did not produce the ultrastructural changes related to gastric acid secretion, in resting parietal cells. Pretreatment of the glands by VIP resulted in a remarkable suppression of the histamine effect, since the parietal cells assumed an almost resting state. The data (1) indicate that the parietal cells in isolated gastric glands of the guinea pig retain in vitro the capacity to undergo the ultrastructural changes that are related to acid secretion in vivo after histamine or cAMP and (2) suggest that VIP is an inhibitor of histamine-induced gastric acid secretion in the guinea pig. It is proposed that VIP could act directly on the parietal cell via cAMP-phosphodiesterase activation, or indirectly via gastric somatostatin and/or prostaglandin secretions, inhibiting the H2 receptor-cAMP system of the parietal cell.