Effect of the TRPV1 antagonist SB-705498 on the nasal parasympathetic reflex response in the ovalbumin sensitized guinea pig.

BACKGROUND AND PURPOSE: Nasal sensory nerves play an important role in symptoms associated with rhinitis triggered by environmental stimuli. Here, we propose that TRPV1 is pivotal in nasal sensory nerve activation and assess the potential of SB-705498 as an intranasal therapy for rhinitis. EXPERIMENTAL APPROACH: The inhibitory effect of SB-705498 on capsaicin-induced currents in guinea pig trigeminal ganglion cells innervating nasal mucosa was investigated using patch clamp electrophysiology. A guinea pig model of rhinitis was developed using intranasal challenge of capsaicin and hypertonic saline to elicit nasal secretory parasympathetic reflex responses, quantified using MRI. The inhibitory effect of SB-705498, duration of action and potency comparing oral versus intranasal route of administration were examined. KEY RESULTS: SB-705498 concentration-dependently inhibited capsaicin-induced currents in isolated trigeminal ganglion cells (pIC50 7.2). In vivo, capsaicin ipsilateral nasal challenge (0.03-1 mM) elicited concentration-dependent increases in contralateral intranasal fluid secretion. Ten per cent hypertonic saline initiated a similar response. Atropine inhibited responses to either challenge. SB-705498 inhibited capsaicin-induced responses by ∼50% at 10 mg·kg⁻¹ (oral), non-micronized 10 mg·mL⁻¹ or 1 mg·mL⁻¹ micronized SB-705498 (intranasal) suspension. Ten milligram per millilitre intranasal SB-705498, dosed 24 h prior to capsaicin challenge produced a 52% reduction in secretory response. SB-705498 (10 mg·mL⁻¹, intranasal) inhibited 10% hypertonic saline responses by 70%. CONCLUSIONS AND IMPLICATIONS: The paper reports the development of a guinea pig model of rhinitis. SB-705498 inhibits capsaicin-induced trigeminal currents and capsaicin-induced contralateral nasal secretions via oral and intranasal routes; efficacy was optimized using particle-reduced SB-705498. We propose that TRPV1 is pivotal in initiating symptoms of rhinitis.

Antagonism of human CC-chemokine receptor 4 can be achieved through three distinct binding sites on the receptor.

Chemokine receptor antagonists appear to access two distinct binding sites on different members of this receptor family. One class of CCR4 antagonists has been suggested to bind to a site accessible from the cytoplasm while a second class did not bind to this site. In this report, we demonstrate that antagonists representing a variety of structural classes bind to two distinct allosteric sites on CCR4. The effects of pairs of low-molecular weight and/or chemokine CCR4 antagonists were evaluated on CCL17- and CCL22-induced responses of human CCR4(+) T cells. This provided an initial grouping of the antagonists into sets which appeared to bind to distinct binding sites. Binding studies were then performed with radioligands from each set to confirm these groupings. Some novel receptor theory was developed to allow the interpretation of the effects of the antagonist combinations. The theory indicates that, generally, the concentration-ratio of a pair of competing allosteric modulators is maximally the sum of their individual effects while that of two modulators acting at different sites is likely to be greater than their sum. The low-molecular weight antagonists could be grouped into two sets on the basis of the functional and binding experiments. The antagonistic chemokines formed a third set whose behaviour was consistent with that of simple competitive antagonists. These studies indicate that there are two allosteric regulatory sites on CCR4.

Evidence for an enhancement of excitatory transmission in adult CNS by Wnt signaling pathway modulation.

The role for Wnt signaling modulation during synaptogenesis, neurogenesis and cell fate specification have been well characterized. In contrast, the roles for Wnt signaling pathways in the regulation of synaptic plasticity and adult physiology are only starting to be elucidated. Here, we have identified a novel series of Wnt pathway small molecule modulators, and report that these and other small molecules targeting the Wnt pathway acutely enhance excitatory transmission in adult hippocampal preparations. Our findings are consistent with a pre- and postsynaptic site of action, leading to both increased spontaneous and evoked neurotransmission that occurs in a transcription-independent fashion.

Discovery of functionally selective 7,8,9,10-tetrahydro-7,10-ethano-1,2,4-triazolo[3,4-a]phthalazines as GABA A receptor agonists at the alpha3 subunit.

We have previously identified the 7,8,9,10-tetrahydro-7,10-ethano-1,2,4-triazolo[3,4-a]phthalazine (1) as a potent partial agonist for the alpha(3) receptor subtype with 5-fold selectivity in binding affinity over alpha(1). This paper describes a detailed investigation of the substituents on this core structure at both the 3- and 6-positions. Despite evaluating a wide range of groups, the maximum selectivity that could be achieved in terms of affinity for the alpha(3) subtype over the alpha(1) subtype was 12-fold (for 57). Although most analogues showed no selectivity in terms of efficacy, some did show partial agonism at alpha(1) and antagonism at alpha(3) (e.g., 25 and 75). However, two analogues tested (93 and 96), both with triazole substituents in the 6-position, showed significantly higher efficacy for the alpha(3) subtype over the alpha(1) subtype. This was the first indication that selectivity in efficacy in the required direction could be achieved in this series.

2,5-Dihydropyrazolo[4,3-c]pyridin-3-ones: functionally selective benzodiazepine binding site ligands on the GABAA receptor.

2,5-Dihydropyrazolo[4,3-c]pyridin-3-ones are GABAA receptor benzodiazepine binding site ligands with functional selectivity for the alpha3 subtype over the alpha1 subtype. SAR studies to optimise this functional selectivity are described.

Activity of chlormethiazole at human recombinant GABA(A) and NMDA receptors.

1. Investigation into the modulatory effects of chlormethiazole at human recombinant gamma-aminobutyric acid A receptor (GABAA) and N-methyl-d-aspartate (NMDA) receptors was undertaken to gain insight into its mechanism of action and determine if the drug exhibited any subtype-selective activity. 2. Despite a structural similarity to the beta-subunit-selective compound loreclezole, chlormethiazole did not show any difference in maximum efficacy and only a slight difference in EC50 in its potentiating action at alpha1beta1gamma2 and alpha1beta2gamma2 GABAA receptor subtypes with preference for alpha1beta1gamma2. 3. Similar to the previously reported subtype-dependent activity of pentobarbital, chlormethiazole elicited a significantly greater degree of maximum potentiation on receptors lacking a gamma2 subunit, and also those receptors containing an alpha4 or alpha6 subunit. This also demonstrates that chlormethiazole does not act via the benzodiazepine binding site. 4. Unlike pentobarbital and propofol, chlormethiazole elicited only a slight direct GABAA receptor activation at concentrations up to 1 mm. In addition, the drug did not potentiate anaesthetic-mediated currents elicited by pentobarbital or propofol, suggesting that chlormethiazole may be acting via an anaesthetic binding site. 5. Chlormethiazole produced weak nonselective inhibition of human NMDA NR1a+NR2A and NR1a+NR2B receptors. IC50's were approximately 500 microm that likely exceed the therapeutic dose range for chlormethiazole, indicating that the primary mechanism of the compounds in vivo activity is via GABAA receptors.

Tracazolate reveals a novel type of allosteric interaction with recombinant gamma-aminobutyric acid(A) receptors.

Tracazolate, a pyrazolopyridine, is an anxiolytic known to interact with gamma-aminobutyric acid (GABA)(A) receptors, adenosine receptors, and phosphodiesterases. Its anxiolytic effect is thought to be via its interaction with GABA(A) receptors. We now report the first detailed pharmacological study examining the effects of tracazolate on a range of recombinant GABA(A) receptors expressed in Xenopus laevis oocytes. Replacement of the gamma2s subunit within the alpha1beta3gamma2s receptor with the epsilon subunit caused a dramatic change in the functional response to tracazolate from potentiation to inhibition. The gamma2s subunit was not critical for potentiation because alpha1beta3 receptors were also potentiated by tracazolate. gamma2/epsilon chimeras revealed a critical N-terminal domain between amino acids 206 and 230 of gamma2, governing the nature of this response. Replacement of the beta3 subunit with the beta1 subunit within alpha1beta3gamma2s and alpha1beta3epsilon receptors also revealed selectivity of tracazolate for beta3-containing receptors, determined by asparagine at position 265 within transmembrane 2. Replacement of gamma2s with gamma1 or gamma3 revealed a profile intermediate to that of alpha1beta1epsilon and alpha1beta1gamma2s. alpha1beta1delta receptors were also potentiated by tracazolate; however, the maximum potentiation of the EC(20) was much greater than on alpha1beta1gamma2. Concentration-response curves to GABA in the presence of tracazolate for alpha1beta1epsilon and alpha1beta1gamma2s revealed a concentration-related decrease in maximum current amplitude, but a leftward shift in the EC(50) only on alpha1beta1gamma2. Like alpha1beta1gamma2s, GABA concentration-response curves on alpha1beta1delta receptors were shifted to the left with increased maximum responses. Tracazolate has a unique pharmacological profile on recombinant GABA(A) receptors: its potency (EC(50)) is influenced by the nature of the beta subunit; but more importantly, its intrinsic efficacy, potentiation, or inhibition is determined by the nature of the third subunit (gamma1-3, delta, or epsilon) within the receptor complex.