Stereoisomerism and muscarinic receptor agonists: synthesis and effects of the stereoisomers of 3-[5-(3-amino-1,2,4-oxadiazol)yl]-1- azabicyclo[2.2.1]heptane.

The preparation and the biological activities of the four stereoisomers of 3-[5-(3-amino-1,2,4-oxadiazol)yl]-1-azabicyclo[2.2.1]heptane are described. The most potent stereoisomer, 3a, has the 3R,4R configuration, and in vitro activities in (pD2(% efficacy): ileum 8.8 (87%), hippocampus 9.8 (116%) and ganglion 10.2 (36%)). 3b (3S,4S) was weaker (ileum 8.1 (121%), hippocampus 8.5 (107%), ganglion 9.0 (63%)). The other two stereoisomers, 4a (3S,4R; ileum 7.1 (108%), hippocampus 8.2 (116%), ganglion 7.3 (31%)) and 4b (3R,4S; ileum 7.0 (100%), hippocampus 7.0 (120%), ganglion 7.2 (67%)) are of comparable activity, with an analogous profile to that of the more potent stereoisomers. Thus, compounds 3a and 4a, possessing the 4R stereochemistry, showed selectivity for the hippocampus over the ileum. Compound 3a was, however, more potent in the ganglion than in the hippocampus. All four stereoisomers were full agonists in the hippocampus, indicating M1 activity; however, they were partial agonists in the depolarisation of the rat superior cervical ganglion, another M1-mediated response. This may be due to M2-mediated hyperpolarization. With 3a (0.01 mg/kg i.p.), expression of c-fos mRNA was observed in the hypothalamus and in brain areas involved in sensory processing; these effects were totally blocked by pretreatment with 2 mg/kg scopolamine. In particular, activation of the superior colliculus is consistent with potent M2 activity.

SDZ ENS 163 is a selective M1 agonist and induces release of acetylcholine.

In the present study some pharmacological properties of the new muscarinic agonist SDZ ENS 163; (+)-(3S,cis)-3-ethyldihydro-4-[(1-methyl-1H-imidazol-5-yl) methyl-2(3H)-thiophenonedihydrogenphosphate] have been investigated. In the rat superior cervical ganglion, a model for M1 muscarinic receptors, SDZ ENS 163 induced concentration-dependent depolarizations (pD2 = 6.5 +/- 0.3; efficacy = 128 +/- 4.2% compared to carbachol). SDZ ENS 163 was a very weak partial agonist with respect to M2 receptor-induced decrease in contractile force in rat left atria (efficacy = 14 +/- 2.9%). In addition, SDZ ENS 163 competitively antagonized the effect of carbachol in rat left atria (pA2 = 5.8 +/- 0.2). In the guinea-pig ileum SDZ ENS 163 was a partial agonist with respect to force of contraction mediated by M3 receptors (pD2 = 5.3 +/- 0.1; efficacy = 72 +/- 4.2%). The oxotremorine-induced inhibition of the electrically stimulated release of acetylcholine (ACh) in rat hippocampal slices was reversed by SDZ ENS 163 (pA2 = 5.5 +/- 0.1). In addition after oral administration SDZ ENS 163 (3-10 mumol/kg) reduced brain ACh levels, which is indicative of increased ACh turnover. Finally, increases in energy of the low frequency band (2-5 Hz) were observed in rat hippocampal EEG after intraperitoneal administration of SDZ ENS 163 (0.3-30 mumol/kg). We conclude that SDZ ENS 163 is a selective M1 agonist in vitro with an additional M2 antagonistic effect. The in vivo effects of SDZ ENS 163 may result both from postsynaptic M1 agonistic as well as M2 receptor antagonistic activity. The unique pharmacological profile of SDZ ENS 163 may prove clinically favourable for treatment of cognitive deficits.

Muscarinic activity of the thiolactone, lactam, lactol, and thiolactol analogues of pilocarpine and a hypothetical model for the binding of agonists to the m1 receptor.

Pilocarpine isosteres have been synthesized and characterized with regard to their in vitro muscarinic properties. The results indicate that the carbonyl oxygen of the lactone function of pilocarpine is of primary importance for agonist activity with the ether oxygen being of lesser or secondary importance. An X-ray structure determination for the hydrogen O,O'-ditoluoyltartrate salt of thiolactone pilocarpine isostere 2a has been performed. This compound has an unusual pharmacological profile exhibiting M1-agonist selectivity as well ass presynaptic antagonism. As a result this compound is also viewed as having therapeutic potential for Alzheimer's disease. A model for the binding of pilocarpine and other muscarinic agonists to the third transmembrane helix of the human m1 muscarinic receptor has been developed.

Dopamine D2 receptors in the rat brain: autoradiographic visualization using a high-affinity selective agonist ligand.

The non-catechol, selective dopamine D2-agonist compound 3H-205-502 was used to localize dopamine D2 receptors by autoradiography after in vitro labeling of brain sections. The characteristics of the binding of this ligand to tissue sections were those expected from the labeling of dopamine D2 receptors. The binding of 3H-205-502 was inhibited selectively and stereospecifically by dopamine D2 agents but not by dopamine D1 compounds. The autoradiographic localization of 3H-205-502 binding sites showed high densities of dopamine D2 receptors in areas such as the glomerular layer of the olfactory bulb, the nucleus accumbens, caudate-putamen, olfactory tubercle, the lateral septum, and the islands of Calleja. Besides these dopamine-innervated areas the substantia nigra and the ventral tegmental area also showed important receptor densities. Other areas where dopamine D2 receptor binding was found were the stratum lacunosum-moleculare of the hippocampus, bands of labeling in the molecular layer of the 9th and 10th lobules of the cerebellum, and several components of the visual system. This distribution presents similarities and differences with previously reported distributions of dopamine D2 receptors visualized autoradiographically using 3H-labeled agonists and antagonists. In view of the high affinity, guanine nucleotide insensitivity, and dopamine D2 selectivity of this agonist ligand, it is suggested that dopamine D2 receptors exist in different states in different areas. 3H-205-502 appears to be a new and useful tool for the study of dopamine D2 receptors.

Interaction of benzodiazepine receptor agonists and inverse agonists with the GABA benzodiazepine receptor complex.

The effects of the benzodiazepine receptor agonists, antagonists and inverse agonists on the in vitro binding of several ligands which label different recognition sites of the GABA benzodiazepine receptor complex are summarized. Also, results with a novel biochemical in vitro functional model of the GABA benzodiazepine receptor complex are presented. They are compatible with the concept that drugs which act on benzodiazepine receptors can lead to a bidirectional modulation of the gain of GABAergic neurotransmission.

Modulation of acetylcholine release from rat striatal slices by the GABA/benzodiazepine receptor complex.

GABA, THIP and muscimol enhance spontaneous and inhibit electrically induced release of tritium labelled compounds from rat striatal slices which have been pre-labelled with 3H-choline. Baclofen is inactive in this model. Muscimol can inhibit electrically induced release of tritiated material by approximately 75% with half maximal effects at 2 microM. The response to muscimol can be blocked by the GABA antagonists bicuculline methobromide, picrotoxin, anisatin, R 5135 and CPTBO (cyclopentylbicyclophosphate). Drugs which act on the benzodiazepine receptor (BR) require the presence of muscimol to be effective and they modulate the effects of muscimol in a bidirectional manner. Thus BR agonists enhance and inverse BR agonists attenuate the inhibitory effects of muscimol on electrically induced release. Ro15-1788, a BR antagonist, does not modulate the inhibitory effects of muscimol but antagonizes the actions of clonazepam, a BR agonist, and of DMCM, an inverse BR agonist. These results demonstrate that a GABA/benzodiazepine receptor complex can modulate acetylcholine release from rat striatal slices in vitro.

[35S]-t-butylbicyclophosphorothionate binding sites are constituents of the gamma-aminobutyric acid benzodiazepine receptor complex.

t- Butylbicyclophosphorothionate ( TBPS ), a derivative of potent GABA antagonistic cage convulsants, has recently been introduced ( Squires , R. F., J.E. Casida , M. Richardson, and E. Saederup (1983) Mol. Pharmacol. 13:326-336) as ligand for a GABA-A receptor-linked drug receptor. Using conventionally prepared washed membrane fractions from rat cerebral cortex, we have confirmed that in the presence of 200 mM NaBr [35S] TBPS binds to a high affinity population of binding sites (Kd 26 +/- 5 nM) and that muscimol inhibits [35S] TBPS binding (IC50 0.32 microM) allosterically. In 200 mM NaCl the apparent affinity of [35S] TBPS binding sites is lower (Kd 60 +/- 5 nM), and muscimol has biphasic effects with stimulation at low concentrations of muscimol (EC50 0.023 microM) followed by inhibition at high concentrations (IC50 0.72 microM). Both base line [35S] TBPS binding (in 200 mM NaCl) and muscimol inhibition of [35S] TBPS binding (in 200 mM NaBr) are bidirectionally modulated by the occupancy of benzodiazepine receptors with its ligands. Benzodiazepine receptor agonists, regardless of their structure, enhance and inverse benzodiazepine receptor agonists inhibit base line [35S] TBPS binding and muscimol inhibition of [35S] TBPS binding. Fourteen ligands for benzodiazepine receptors display a similar in vitro profile as benzodiazepine receptor agonists or inverse benzodiazepine receptor agonists on [35S] TBPS binding as their anti- or proconvulsive effects in vivo suggest (Jensen, L. H., E. N. Petersen, and C. Braestrup (1983) Life Sci. 33: 393-399). That [35S] TBPS binding sites are constituents of a GABA benzodiazepine receptor complex is also suggested by a number of membrane pretreatments.(ABSTRACT TRUNCATED AT 250 WORDS)

The interaction of [3H]PY 108-068 and of [3H]PN 200-110 with calcium channel binding sites in rat brain.

The binding properties of the tritiated calcium channel antagonists PY 108-068 and PN 200-110 were investigated in membrane fractions from rat brain in vitro. Both ligands reversibly interact with one apparent population of stereoselective binding sites which have pharmacological properties described for calcium channel binding sites. In a calcium buffer enhancement of [3H]PY 108-068 binding is observed with an EC50 at pCa 6.28 [3H]PN 200-110 binding is less sensitive to allosteric stimulation by diltiazem and to allosteric inhibition by verapamil and D 600 than [3H]PY 108-068 binding, suggesting that the former ligand may stabilize a high affinity configuration of the binding sites. After i.v. administration of [3H]PY 108-068 in vivo binding to membranes is observed in brain and heart, which, in contrast to total tissue radioactivity is sensitive to inhibition by unlabelled (+)PN 200-110. These observations suggest that PY 108-068 can interact with its binding sites also in vivo. The results of ex vivo binding studies in brain and heart with [3H]PY 108-068 confirm and extend these observations. It could be shown that all investigated 1,4-dihydropyridines (PY 108-068, PN 200-110, nifedipine, Bay K 8644) after i.p. administration can readily enter brain and heart tissue.

Calcium antagonist binding sites in the rat brain: quantitative autoradiographic mapping using the 1,4-dihydropyridines [3H]PN 200-110 and [3H]PY 108-068.

An in vitro autoradiographic technique has been used for the quantitative mapping of calcium antagonist binding sites (CABS) in the rat brain, using the 1,4-dihydropyridines [3H]PN 200-110 and [3H]PY 108-068 as ligands. CABS were distributed throughout the brain in a highly heterogeneous fashion. The highest densities of CABS were observed in the olfactory bulb, hippocampus and parts of the amygdala. The neocortex was also rich in CABS. The basal ganglia, thalamus and hypothalamus presented intermediate levels of CABS while low densities of sites were seen in areas such as the cerebellum, pons and white matter tracts. The distributions of CABS in brain does not correlate with indexes of brain blood flow, regional glucose utilization or the distributions of receptor binding sites for drugs and neurotransmitters analyzed until now. No correlation exists between CABS distribution and that of any neurotransmitter or brain enzyme described so far. The heterogeneous distributions of CABS is suggestive of a neuronal localization, an idea supported by lesion experiments.

Differential modulation of etazolate or pentobarbital enhanced [3H] muscimol binding by benzodiazepine agonists and inverse agonists.

Flunitrazepam, a benzodiazepine agonist increases, and DMCM, an inverse agonist decreases the stimulation by etazolate or pentobarbital of [3H] muscimol binding to membranes of rat cerebral cortex. Ro 15-1788 has no marked effects but antagonizes the action of both flunitrazepam and DMCM. The investigation of several drugs acting on benzodiazepine receptors on etazolate enhancement of [3H] muscimol binding suggests that their receptor interaction reflects a spectrum from agonists to inverse agonists.

The effects of lesions in the rat hippocampus suggest the association of calcium channel blocker binding sites with specific neuronal population.

The binding of calcium antagonists in the rat hippocampal formation was studied using autoradiography. Hippocampal slices were labeled in vitro with [3H]PN 200-110. High densities of binding sites for calcium antagonists were found in the molecular layer of the dentate gyrus and in the CA3 subfield of the hippocampus. After ablation of the granule cells by local injection of colchicine a marked decrease in the number of [3H]PN 200-110 binding sites density was observed on these areas, while binding to other parts of the hippocampal formation and brain was spared. These results strongly suggest the localization of high densities of calcium channels to the granule cells of the dentate gyrus.

Anion-dependent modulation of [3H]muscimol binding and of GABA-stimulated [3H]flunitrazepam binding by picrotoxin and related CNS convulsants.

Picrotoxin, isopropylbicyclophosphate (IPTBO) and related CNS-convulsants have allosteric effects on the binding of ligands to the GABA/benzodiazepine receptor complex. When binding experiments were performed at 23 degrees C and at 35 degrees C, these drugs inhibited [3H]muscimol binding and muscimol- or GABA-stimulated [3H]flunitrazepam binding, respectively. Both effects required the presence of C1-, Br-, I- but not of F- or SO4(2-). Picrotoxin and IPTBO could only partially inhibit [3H]muscimol binding. In contrast other GABA antagonists and convulsants like bicuculline, 3 alpha-hydroxy-16-imino-5 beta-17-aza-androstan-11-one (R 5135), strychnine and d-tubocurarine interferred completely with [3H]muscimol binding, also in the absence of those ions mentioned above which were essential for the effects of picrotoxin. Our results support the notion that drugs like picrotoxin and IPTBO which interfere with the GABA receptor effector system, may lead to an allosteric perturbation of GABA-recognition sites.

Distinction of benzodiazepine agonists from antagonists by photoaffinity labelling of benzodiazepine receptors in vitro.

When membranes of rat cerebellum are exposed to UV light in the presence of flunitrazepam this ligand can be incorporated into one of the assumed 4 benzodiazepine binding sites of the GABA-benzodiazepine receptor complex. This irreversible incorporation of flunitrazepam, in contrast to reversible binding of this substance, leads to conformational changes of the remaining 3 benzodiazepine binding sites which result in a decreased affinity of benzodiazepine agonists, but not of benzodiazepine antagonists. The investigation of the affinity of drugs for [3H]benzodiazepine antagonist binding before and after photoaffinity labelling of benzodiazepine receptors with flunitrazepam can therefore be used as a sensitive and simple test to distinguish between agonists and antagonists in vitro.

Modulation of GABA binding sites by CNS depressants and CNS convulsants.

[(3)H]Muscimol binding at 23 degrees C and muscimol stimulated [(3)H]flunitrazepam binding at 37 degrees C to membranes of rat cerebral cortex have been investigated. In washed membrane preparations, 2 apparent populations of [(3)H]muscimol binding sites can be observed. At 23 degrees C [(3)H]muscimol binding is more sensitive to inhibition by NaCl and by other salts than at 0 degrees C. The CNS depressants etazolate and pentobarbital reversibly enhance [(3)H]muscimol binding and they increase the affinity of muscimol as a stimulator of [(3)H]flunitrazepam binding. Conversely the CNS convulsants picrotoxin, picrotoxinin and isopropylbicyclophosphate (IPTBO) reversibly interfere with [(3)H]muscimol binding when NaCl is present and these drugs antagonize the effects of etazolate. In the presence of NaCl, picrotoxin, picrotoxinin and IPTBO also decrease the apparent affinity of muscimol or GABA as stimulator of [(3)H]flunitrazepam binding. Binding of [(3)H]muscimol to GABA recognition sites of rat cerebral cortex is enhanced by Ag(+), Hg(+) and Cu(2+) in ?M concentrations, Ag(+) being most potent. The effects of 100 ?M AgNO(3) persist after repeated washing of the membranes. When membranes are pretreated with AgNO(3) only one apparent population of [(3)H]muscimol binding sites with high affinity (K(d): 6-8 nM) is found. In AgNO(3) pretreated membranes, the affinity of muscimol as stimulator of [(3)H]flunitrazepam binding is increased 18 times (EC(50) 14 nM) when compared to control membranes, (EC(50) 253 nM). In AgNO(3) pretreated membranes, etazolate, pentobarbital and IPTBO fail to perturb either [(3)H]muscimol binding or baseline and muscimol stimulated [(3)H]flunitrazepam binding. The results demonstrate that the apparent sensitivity of GABA binding sites of the GABA-benzodiazepine-picrotoxin receptor complex can be increased by etazolate and pentobarbital and decreased by picrotoxin and IPTBO. These drugs have in common that they interfere with [(3)H]dihydropicrotoxinin binding.

Action of pyrazolopyridines as modulators of [3H]flunitrazepam binding to the gaba/benzodiazepine receptor complex of the cerebellum.

The pyrazolopyridines etazolate (SQ 20009) and cartazolate (SQ 65396) have strong modulatory effects on the GABA/benzodiazepine receptor complex of rate cerebellum. Thus, etazolate and cartazolate directly stimulate [3H]flunitrazepam binding (with EC50 values of 1.2 microM and 0.3 microM respectively) by increasing the apparent affinity of [3H]flunitrazepam for its binding sites. Stimulation of [3H]flunitrazepam binding by pyrazolopyridines is dependent on the presence of certain anions like chloride, bromide, iodide, nitrite, nitrate but not fluoride, acetate, formate or sulfate. If is inhibited by bicuculline-methiodide, and by the "chloride channel drugs' picrotoxinin and IPTBO. isoTHAZ, a GABA analogue with GABA antagonist properties in vivo, fails to inhibit binding stimulated by etazolate but antagonizes [3H]flunitrazepam binding stimulated by GABA. The pyrazolopyridines have also indirect effects on benzodiazepine receptor binding since they enhance the apparent sensitivity of those GABA recognition sites which are coupled to benzodiazepine binding sites. Thus, in the presence of 10 microM etazolate, GABA and muscimol enhance [3H]flunitrazepam binding, with EC50 values of 109 nM and 12 nM respectively. This sensitization effect is partially dependent on the presence of chloride ions. The pyrazolopyridines facilitate also the stimulation of benzodiazepine receptor binding by beta-alanine and taurine and by the rigid and flattened GABA analogues THIP and piperidine-4-sulfonic acid. Taken together, these results suggest that the pyrazolopyridines modulate [3H]flunitrazepam binding by acting at a site closely related to GABA receptor-regulated chloride ion channels.