Novel histamine H3 receptor antagonists: affinities in an H3 receptor binding assay and potencies in two functional H3 receptor models

Abstract

1 We determined the affinities of ten novel H₃ receptor antagonists in an H₃ receptor binding assay and their potencies in two functional H₃ receptor models. The novel compounds differ from histamine in that the aminoethyl side chain is replaced by a propyl or butyl chain linked to a polar group (amide, thioamide, ester, guanidine, guanidine ester or urea) which, in turn, is connected to a hexocyclic ring or to an alicyclic ring containing an alkyl residue. 2 The specific binding of [³H]-N^α-methylhistamine to rat brain cortex membranes was monophasically displaced by each of the ten compounds at pK_i values ranging from 7.56 to 8.68. 3 Inhibition by histamine of the electrically evoked tritium overflow from mouse brain cortex slices preincubated with [³H]-noradrenaline was antagonized by the ten compounds and the concentration-response curve was shifted to the right with apparent pA₂ values ranging from 7.07 to 9.20. 4 The electrically induced contraction in guinea-pig ileum strips (which was abolished by atropine) was inhibited by the H₃ receptor agonists R-(−)-α-methylhistamine (pEC₅₀ 7.76), N^α-methylhistamine (7.90) and imetit (8.18). The concentration-response curve of R-(−)-α-methylhistamine was shifted to the right by thioperamide (apparent pA₂ 8.79) and by the ten novel compounds (range of pA₂ values 6.64–8.81). 5 The affinities and potencies were compared by linear regression analysis. This analysis was extended to thioperamide, the standard H₃ receptor antagonist, which is also capable of differentiating between H_3A and H_3B sites. Comparison of the apparent pA₂ values in the two functional H₃ receptor models yielded a regression coefficient of 0.77 (P < 0.02). When the pA₂ of the drugs in the mouse brain cortex were compared to the pK_i for H₃ sites (ten novel compounds) and for H_3A sites (thioperamide), a significant correlation (r = 0.87; P < 0.001) was obtained. There was, however, no significant correlation when the pK_i of thioperamide for H_3B sites was used instead (r = 0.52). In a similar manner, comparison of the pA₂ in the guinea-pig ileum with the pK_i in the binding assay yielded a significant correlation (r = 0.70, P < 0.05) only when the pK_i of thioperamide for H_3A sites was used but not when its pK_i for H_3B sites was considered (r = 0.17, NS). 6 On the basis of these results, structure-activity relationships for the novel H₃ receptor antagonists, and the nature of the H₃ receptors in the guinea-pig ileum and mouse brain, are considered.