Neuropeptide Y-Y2 receptor knockout mice: influence of genetic background on anxiety-related behaviors.

Neuropeptide Y (NPY) has been extensively studied in relation to anxiety and depression but of the seven NPY receptors known to date, it is not yet clear which one is mainly involved in mediating its effects in emotional behavior. Mice lacking the NPY-Y2 receptors were previously shown to be less anxious due to their improved ability to cope with stressful situations. In the present study, the behavioral phenotype including the response to challenges was analyzed in NPY-Y2 knockout (KO) mice backcrossed in to congenic C57BL/6 background. In the elevated plus-maze (EPM) and the forced swim test (FST), the anxiolytic-like or antidepressant-like phenotype of the NPY-Y2 KO mice could not be confirmed, although this study differs from the previous one only with regard to the genetic background of the mice. In addition, no differences in response to acute stress or to the antidepressant desipramine in the FST were detected between wild type (WT) and NPY-Y2 KO animals. These results suggest that the genetic background of the animals appears to have a strong influence on the behavioral phenotype of NPY-Y2 KO mice. Additionally, to further characterize the animals by their biochemical response to a challenge, the neurochemical changes induced by the anxiogenic compound yohimbine were measured in the medial prefrontal cortex (mPFC) of NPY-Y2 KO and compared to WT mice. Dopamine (DA) levels were significantly increased by yohimbine in the WT but unaffected in the KO mice, suggesting that NPY-Y2 receptor exerts a direct control over both the tonic and phasic release of DA and that, although the anxiety-like behavior of these NPY-Y2 KO mice is unaltered, there are clear modifications of DA dynamics. However, yohimbine led to a significant increase in noradrenaline (NA) concentration and a slight reduction in serotonin concentration that were identical for both phenotypes.

NK3 receptor blockade prevents hyperalgesia and the associated spinal cord substance P release in monoarthritic rats.

Previous studies in vitro have shown that NK3 receptors exist on primary afferent terminals in rat spinal cord and mediate potentiation of the depolarisation-evoked substance P (SP) release. In the present study we have investigated the role of the NK3 receptor-mediated SP release system in a model of inflammatory pain. Monoarthritis was induced in rats by unilateral injection of complete Freund's adjuvant (CFA); withdrawal latencies to a thermal stimulus were subsequently measured at various times following CFA. The CFA-treated paw displayed hyperalgesia as early as 4 h after CFA injection and hyperalgesia was maintained until day 4 but had disappeared by day 21. The thermal hyperalgesia was associated with an increase in basal SP release from spinal cord synaptosomes. The possible involvement of endogenous neurokinin B acting at NK3 receptors was tested by using SB 223412-A [(S)-(-)-N-(alpha-ethylbenzyl)-3-hydroxy-2-phenylquinoline-4-carbo xamide hydrochloride], a novel, potent (Ki=30 nM) and selective (Ki>10,000 nM for NK1 and NK2 receptors), non-peptidic NK3 receptor antagonist. In vitro SB 223412-A antagonised the potentiation of SP release produced by senktide in spinal cord synaptosomes. Administered systemically to monoarthritic rats (50 mg/kg, p.o., b.i.d., for 4 days), the NK3 receptor antagonist SB 223412-A significantly reduced thermal hyperalgesia and normalised the basal release of SP from spinal cord synaptosomes. The data suggest that neurokinin B acting at NK3 receptors that mediate SP release within the spinal cord play a role in inflammation. These NK3 receptors may represent, therefore, appropriate targets in the therapy of inflammatory pain.

Affinity profile of the novel muscarinic antagonist, guanylpirenzepine.

The study reports the functional affinity of an amidino derivative of pirenzepine, guanylpirenzepine, for muscarinic receptors mediating relaxation of rat duodenum, inhibition of rabbit vas deferens twitch contraction (both receptors previously classified as M1), guinea pig negative inotropism (M2) and ileal contraction (M3). Unlike pirenzepine, guanylpirenzepine discriminated between duodenum and vas deferens receptors, with a 30-fold greater affinity for the former subtype. The unique selectivity pattern of guanylpirenzepine (duodenum greater than vas deferens greater than ileum greater than atrium) renders it a promising tool for the classification of muscarinic receptor subtypes.