CNS 7065 is a high-affinity and selective ligand for the benzodiazepine site on the GABAA receptor. CNS 7056 does not show selectivity between GABAA receptor subtypes. CNS 7056 is a potent sedative in rodents with a short duration of action. Inhibition of substantia nigra pars reticulata firing and the inhibition of the effects of CNS 7056 by flumazenil show that it acts at the brain benzodiazepine receptor.
Bupropion (BW 323U66) has been considered a dopaminergic antidepressant based on its ability to inhibit the uptake of dopamine (DA) somewhat more selectively than it inhibits uptake of norepinephrine (NE) or serotonin (5-HT). This report describes new evidence that bupropion selectively inhibits firing rates of NE cells in the locus coeruleus (LC) at doses significantly lower than those that inhibit activity of midbrain DA cells or dorsal raphe 5-HT cells. The ICso dose (13 mglkg IP) for inhibition of LC firing produced plasma concentrations !hat were not significantly different from those generated by the EDso in the Porsolt test (10 mglkg IP). The fourfold higher dose needed to inhibit DA cell firing (ICso = 42 mglkg IP) was similar to the dose associated with locomotor stimulation in freely moving rats. Bupropion did not change the firing rates of 5-HT cells in the dorsal raphe nucleus at any dose. In both in vitro and in vivo tests, the metabolite 306U73 (hydroxy bupropion), a weak inhibitor of NE uptake, was approximately equipotent to bupropion with regard to inhibition of LC cells. Another metabolite, 494U73, had no effect on LC firing rates over a wide range of doses. Because of species variation in metabolism, 306U73 was not detected in plasma of rats after IV doses of bupropion that inhibited LC firing. Only trace amounts of 306U73 were detected after bupropion dosing for the Porsolt test. Pretreatment with reserpine markedly depleted catecholamines and reduced (by 30-fold) the potency of bupropion to inhibit LC firing. The effects of clonidine, a direct acting U2 agonist, were not significantly changed by reserpine. Likewise, a reduction in the effect of bupropion on LC firing was observed in vitro after depletion of catecholamines with reserpine or tetrabenazine. These results suggest that bupropion preferentially affects NE neurons in locus coeruleus at doses that are active in animal antidepressant tests. The doses of bupropion required to inhibit DA cell firing were associated with inhibition of DA uptake and behavioral stimulation and were significantly higher than those selectively producing behavioral effects in animal antidepressant tests. The acute electrophysiological actions of bupropion on NE cells require a reserpine sensitive store of NE and occur at doses having activity in antidepressant screening tests. [Neuropsychopharmacology 11:133-141, 1994J KEY WORDS: Antidepressive agents; Dopamine; Electrophysiology; Norepinephrine; Rats Bupropion is a novel antidepressant with an undefIned mechanism of action. Studies have shown that it weakly inhibits the uptake of dopamine in vitro (Ferris et al.
The calcitonin receptor is a member of the class B family of G protein-coupled receptors, which contains numerous potentially important drug targets. Delineation of themes for agonist binding and activation of these receptors will facilitate the rational design of receptor-active drugs. We reported previously that a photolabile residue within the carboxyl-terminal half (resi- Calcitonin (CT), 1 secreted by the thyroid gland in response to elevations in blood calcium levels, is a peptide hormone that regulates calcium by inhibition of osteoclast-mediated bone resorption (1, 2). CT acts on bone and kidney to maintain calcium homeostasis and is also present in the central nervous system, where it has anorectic and analgesic effects (3). It has been used therapeutically for the treatment of Paget's disease, the hypercalcemia associated with certain types of tumors, and osteoporosis (1, 2).dueCT is a relatively large peptide that contains 32 amino acids and has a diffuse pharmacophoric domain. Although residues throughout the entire length have been demonstrated to be critical for its biological activity, the amino-terminal residues of CT contain key determinants for its receptor agonist selectivity (1, 2). Truncation of the first seven amino-terminal residues that includes a disulfide bond between residues 1 and 7 results in antagonist action (4, 5). Residues 8 through 22 tend to form an amphiphilic ␣-helical structure that is important for high affinity binding (1).CT exhibits its agonist activities through binding to the CT receptor, a member of the class B family of guanine nucleotidebinding protein (G protein)-coupled receptors that have the seven-transmembrane-domain structure. Although they have topology similar to that of class A receptors, members of class B family share less than 12% amino acid identity with the more extensively studied receptors in the class A family. Class B receptors have distinct signature sequences, including a long complex amino-terminal domain with six conserved cysteine residues that are believed to be involved in intradomain disulfide bonds critical for establishing functional receptor conformation (6 -10). Members included in this family are receptors for moderately large peptides having diffuse pharmacophoric domains, such as secretin, calcitonin, glucagon, vasoactive intestinal polypeptide, pituitary adenylate cyclase-activating polypeptide, and parathyroid hormone, sharing 30 to 50% homology with each other.The unique amino-terminal domain of the CT receptor has been shown to be critical for agonist binding and receptor activation using chimeric receptor studies (11)(12)(13). This represents a consistent theme for other class B family members (14 -19). Photoaffinity labeling is a more direct approach for exploration of spatial approximations between residues within a ligand and within its receptor. Using this approach, we have recently demonstrated that probes incorporated a photolabile p-benzoyl-L-phenylalanine (Bpa) residue in the carboxyl-terminal half and mid-region of the ...
Miniaturization of Raman instruments has created a new genre of devices for qualitative analysis of materials. These new devices are introducing Raman spectroscopy to a diverse range of applications.
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