The biochemical and behavioral effects of a nonpeptidic, selective, and brain-penetrant agonist at the ORL1 receptor are reported herein. This low molecular weight compound {(1S,3aS)-8-(2,3,3a,4,5,6-hexahydro-1H-phenalen-1-yl)-1-phenyl-1,3,8-triazaspiro[4.5]decan-4-one} has high affinity for recombinant human ORL1 receptors and has 100-fold selectivity for ORL1 over other members of the opioid receptor family. It is a full agonist at these receptors and elicits dose-dependent anxiolytic-like effects in a set of validated models of distinct types of anxiety states in the rat (i.e., elevated plus-maze, fear-potentiated startle, and operant conflict). When given systemically, the compound has an efficacy and potency comparable to those of a benzodiazepine anxiolytic such as alprazolam or diazepam. However, this compound is differentiated from a classical benzodiazepine anxiolytic by a lack of efficient anti-panic-like activity, absence of anticonvulsant properties, and lack of effects on motor performance and cognitive function at anxiolytic doses (0.3 to 3 mg͞kg i.p.). No significant change in intracranial self-stimulation performance and pain reactivity was observed in this dose range. Higher doses of this compound (>10 mg͞kg) induced disruption in rat behavior. These data confirm the notable anxiolytic-like effects observed at low doses with the orphanin FQ͞nociceptin neuropeptide given locally into the brain and support a role for orphanin FQ͞nociceptin in adaptive behavioral fear responses to stress.T he ORL1 orphan receptor was identified from a human cDNA library on the basis of close homology (Ϸ65% in the transmembrane domains) with the -, ␦-, and -opioid receptors (1, 2). Classical opioid ligands do not bind to ORL1, but orphanin FQ͞nociceptin (OFQ͞N), a 17-amino acid neuropeptide purified from brain extracts, was found to be the natural ligand of the G protein-coupled receptor ORL1 (3, 4). OFQ͞N, its precursor peptide, and its receptor ORL1 are located in corticolimbic regions involved in the integration of the emotional components of fear and stress as well as in the spinal cord, with a pattern distinct from that of opioid peptides and receptors in rodents (5-9). The expression of OFQ͞N or its receptor in the amygdaloid complex, septohippocampal region, periaqueductal gray matter, locus coeruleus, and dorsal raphe nucleus suggests that major brain neuronal systems may be sensitive to the action of OFQ͞N. Such sensitivity has widespread implications for many aspects of behavior including arousal, attention, neuroendocrine control, fear, and anxiety (10). In brain slices, OFQ͞N has potent inhibitory actions on neurons in the dorsal raphe nucleus, the locus coeruleus, the periaqueductal gray matter, and the amygdala (11)(12)(13)(14). In general, OFQ͞N plays an inhibitory role on synaptic transmission in the central nervous system and thereby may contribute to a reduction in responsiveness to stress. When given intracerebroventricularly to rodents, OFQ͞N reduces elementary stress-induced physiological respon...
A model of the rmGlu1 seven-transmembrane domain complexed with a negative allosteric modulator, 1-ethyl-2-methyl-6-oxo-4-(1,2,4,5-tetrahydro-benzo[d]azepin-3-yl)-1,6-dihydro-pyrimidine-5-carbonitrile (EM-TBPC) was constructed. Although the mGlu receptors belong to the family 3 G-protein-coupled receptors with a low primary sequence similarity to rhodopsin-like receptors, the high resolution crystal structure of rhodopsin was successfully applied as a template in this model and used to select residues for site-directed mutagenesis. The mGlu 1 receptor family currently comprises eight receptors that are divided into three classes on the basis of their sequence similarities, signal transduction, and agonist rank order of potency. Group I (mGlu1 and -5) receptors are coupled to the stimulation of phosphoinositide hydrolysis; group II (mGlu2 and -3) and group III receptors (mGlu4, -6, -7, and -8) are negatively coupled to cAMP production (1-3). Many studies have demonstrated the involvement of mGlu receptors in the modulation of synaptic transmission, ion channel activity, and synaptic plasticity (4, 5), and dysfunction of these receptors has been implicated in psychiatric and neurological diseases (6). The mGlu receptors belong to the family 3 of G-protein-coupled receptors (GPCRs). Other members of this family include the GABA B , Ca 2ϩ -sensing, vomeronasal, pheromone, and putative taste receptors (7). The family 3 GPCRs shares a low sequence similarity with the other families. In contrast to family 1, the family 3 receptors are characterized by two distinctly separated topological domains: an exceptionally long extracellular amino-terminal domain (500 -600 amino acids), which forms the agonistbinding pocket (8 -10), and the 7TM helical segments involved in receptor activation and G-protein coupling (11).Compounds acting at group I mGlu receptors can be grouped into two categories. Category one comprises competitive agonists and antagonists. These compounds are phenylglycine derivatives or rigidified analogs of glutamate (12), which logically bind to the glutamate-binding domain. Competitive group I ligands have achieved only limited subtype selectivity and potency, perhaps due to the high sequence homology of the mGlu receptor family agonist-binding site supported by the threedimensional structure of mGlu1 amino-terminal domain (10). However, recent development of more sensitive technologies for functional screening of GPCRs has resulted in the discovery of a second category of compounds. These novel compounds, which interact within the 7TMD of group I mGlu receptor, act as positive or negative allosteric modulators (13). CPCCOEt was the first non-amino acid derivative, subtype-selective antagonist of the mGlu1 receptor (IC 50 ϭ 6.5 M at hmGlu1b) to
These studies have addressed the role of caspase-3 activation in neuronal death after cerebral ischemia in different animal models. The authors were unable to show activation of procaspase-3 measured as an induction of DEVDase (Asp-Glu-Val-Asp) activity after focal or transient forebrain ischemia in rats. DEVDase activity could not be induced in the cytosolic fraction of the brain tissue obtained from these animals by exogenous cytochrome c/dATP and Ca2+. However, the addition of granzyme B to these cytosolic fractions resulted in a significant activation of DEVDase, confirming that the conditions were permissive to analyze proteolytic cleavage of the DEVD-AMC (7-amino-4-methyl-coumarin) substrate. Consistent with these findings, zVal-Ala-Asp-fluoromethylketone administered after focal ischemia did not have a neuroprotective effect. In contrast to these findings, a large increase in DEVDase activity was detected in a model of hypoxic-ischemia in postnatal-day-7 rats. Furthermore, in postnatal-day-7 animals treated with MK-801, in which it has been suggested that excessive apoptosis is induced, the authors were unable to detect activation of DEVDase activity but were able to induce it in vitro by the addition of cytochrome c/dATP and Ca2+ to the cytosolic fraction. Analysis of cytochrome c distribution did not provide definitive evidence for selective cytochrome c release in the permanent focal ischemia model, whereas in the transient model a small but consistent amount of cytochrome c was found in the cytosolic fraction. However, in both models the majority of cytochrome c remained associated with the mitochondrial fraction. In conclusion, the authors were unable to substantiate a role of mitochondrially derived cytochrome c and procaspase-3 activation in ischemia-induced cell death in adult brain, but did see a clear induction of caspase-3 in neonatal hypoxia.
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