Binding studies with [3H]cis-methyldioxolane in different tissues. Under certain conditions [3H]cis-methyldioxolane labels preferentially but not exclusively agonist high affinity states of muscarinic M2 receptors

In vitro and in vivo evaluation of the subtype-selective muscarinic agonist PD 151832

PD 151832 is a potent partial muscarinic agonist that displays a high level of functional selectivity for the muscarinic m1 receptor subtype, as evidenced by its selective stimulation of PI turnover and cellular metabolic activity in transfected Hm1-CHO cells at concentrations that produce minimal stimulation of other cloned human muscarinic receptors. PD 151832 enhanced the amplification of Hm1-transfected NIH-3T3 cells at concentrations lower than those required to produce similar effects in Hm2 or Hm3-transfected cells. The functional m1 selectivity of PD 151832 is consistent with its improvement of mouse water maze performance at doses far lower than those required to produce peripheral parasympathetic side effects.

SDZ PSD 958, a novel D1 receptor antagonist with potential limbic selectivity

SDZ PSD 958, a novel benzo[g]quinoxaline derivative exhibits the properties of a potent orally active selective D1 receptor antagonist. It has high affinity for D1-like receptors (D1, D5; pKi = 9.7-9.8) labelled by [3H]SCH23390 and is at least 400 fold less active at D2-like receptors (i.e. D2, D4) labelled by [3H]spiperone. Effects in functional tests are consistent with D1 receptor antagonist properties. SDZ PSD 958 inhibited apomorphine-induced rearing in mice and prevented prolongation of novelty-induced locomotion in rats elicited by the selective D1 receptor agonist CY 208-243. By contrast, SDZ PSD 958 did not induce catalepsy and only weakly inhibited apomorphine-induced stereotyped gnawing in rats. This suggests that SDZ PSD 958 preferentially inhibits responses mediated by dopamine systems innervating the limbic system.

Organophosphorus compounds preferentially affect second messenger systems coupled to M2/M4 receptors in rat frontal cortex

Recent reports indicate that organophosphate insecticides, in addition to inhibiting acetylcholinesterase activity, can bind directly at a subset of muscarinic receptors, which also bind cis-methyldioxolane with high affinity. Muscarinic receptors are known to act through at least two second messenger systems, either the stimulation of phosphoinositide turnover (mediated through the M1 and M3 receptor subtypes) or the inhibition of cAMP formation (mediated through the M2 and M4 receptor subtypes). We have investigated the action of the active forms of parathion, malathion, and chlorpyrifos (paraoxon, malaoxon, and chlorpyrifos oxon, respectively) on these second messenger systems in cortical slices from adult male Long-Evans rats. Paraoxon, malaoxon, and chlorpyrifos oxon (10(-8) to 10(-4) M) inhibited forskolin-stimulated cAMP formation in a concentration-dependent manner. The effect on cAMP formation was blocked by the muscarinic antagonist atropine (10 microM). These results suggest that paraoxon, malaoxon, and chlorpyrifos oxon can act as agonists at the M2 and/or M4 subset of muscarinic receptors. In addition, chlorpyrifos may have another site of action. In contrast, none of the organophosphates had any effect on basal or carbachol-stimulated phosphoinositide hydrolysis. The differential activity on these two second messenger systems make it unlikely that the observed effects on cAMP formation are due to increases in endogenous acetylcholine resulting from inhibition of acetylcholinesterase.

The pharmacology of SDZ EAA 494, a competitive NMDA antagonist

SDZ EAA 494 (D-CPPene) was characterized as a competitive NMDA antagonist, having a pA2 value against NMDA depolarizations in frog spinal cord and rat neocortex of 6.7-6.8 and a pKi of 7.5 in a [3H]CGP39653 binding assay, with no action on other receptors or amine reuptake. The compound was orally active in rodent maximal electroshock models with an ED50 of around 16 mg/kg, was protective in rats even 24 hours after oral application and had an oral therapeutic index of around 8. Muscle relaxation, ataxia, flattened body posture and reduced acquisition of a passive avoidance task, suggesting potential effects on memory formation, occurred at supra-anticonvulsant doses in rodents, with PCP-like stimulatory effects produced only by high i.p. doses or constant i.v. infusions. This favourable profile is discussed in relation to the negative outcome of a recent trial of the compound in patients with intractable epilepsy. The conclusion is drawn that standard models for screening new anticonvulsants are inappropriate to seeking drugs active in patients with a protracted convulsive history. The anti-ischaemic action of SDZ EAA 494 encourages further testing in brain trauma, in which the anticonvulsant action of the compound may be an added benefit.

Characterization of muscarinic agonists in recombinant cell lines

Using recombinant CHO cells that express Hm1-Hm5 receptors, reference muscarinic agonists have been characterized with respect to their activity in receptor binding and second messenger assays. In whole cell [3H]-N-methyl scopolamine binding, no agonist was found to be truly subtype selective, although some showed marked differences between several of the subtypes (e.g. m1 vs. m2). As a functional index of receptor activation, phosphatidyl-inositol (PI) turnover was measured for m1, m3, and m5 receptors while inhibition of forskolin-stimulated cAMP accumulation was measured for m2 and m4 receptors. Both full and partial agonists were delineated in PI turnover, but all agonists showed similar responses on cAMP. Alkylation studies with propylbenzylcholine mustard showed that both efficacy and potency were markedly affected in the functional assays by the number of free receptors. Thus, receptor reserve appears to play a major role in the determination of subtype selectivity for agonists using functional measures. Even with these limitations, however, the use of transformed cell lines is playing a pivotal role in the discovery of selective agonists.

Species differences in the negative inotropic effect of acetylcholine and soman in rat, guinea pig, and rabbit hearts

1. Acetylcholine reduced atrial contractions by 82.5% in guinea pig, 50.8% in rat, and 41.5% in rabbit. 2. The EC50 values for the negative inotropic effect of acetylcholine were 3.3 x 10(-7) M in rat and guinea pig atria and 4.1 x 10(-6) M in rabbit atria. 3. There was no correlation between the species differences in the negative inotropic effect of acetylcholine in atria and the density or affinity of acetylcholinesterase or muscarinic receptors. 4. Inhibition of atrial acetylcholinesterase with soman reduced the EC50 of acetylcholine three-fold in all species, but did not change the maximal inotropic effect of acetylcholine. 5. Species differences in the negative inotropic effect of acetylcholine may be caused by differences in the coupling between myocardial muscarinic receptors and the ion channels that mediate negative inotropy.

CGP 35348: a centrally active blocker of GABAB receptors

The biochemical, electrophysiological and pharmacological properties of the new GABAB receptor blocker CGP 35348 are described. In a variety of receptor binding assays CGP 35348 showed affinity for the GABAB receptor only. CGP 35348 had an IC50 of 34 microM at the GABAB receptor. The compound antagonized (100, 300, 1000 microM) the potentiating effect of L-baclofen on noradrenaline-induced stimulation of adenylate cyclase in rat cortex slices. In electrophysiological studies CGP 35348 (10, 100 microM) antagonized the effect of L-baclofen in the isolated rat spinal cord. In the hippocampal slice preparation CGP 35348 (10, 30, 100 microM) blocked the membrane hyperpolarization induced by D/L-baclofen (10 microM) and the late inhibitory postsynaptic potential. CGP 35348 appeared to be 10-30 times more potent than the GABAB receptor blocker phaclofen. Ionophoretic and behavioural experiments showed that GABAB receptors in the brain were blocked after i.p. administration of CGP 35348. This compound may be of considerable value in elucidating the roles of brain GABAB receptors.

Distinct muscarinic receptor subtypes differentially modulate acetylcholine release from corticocerebral synaptosomes

The effect of McN-A-343 and oxotremorine on acetylcholine (ACh) release and choline (Ch) transport was studied in corticocerebral synaptosomes of the guinea pig. The synaptosomes were preloaded with [3H]Ch after treatment with the irreversible cholinesterase inhibitor, diisopropyl fluorophosphate, and then tested for their ability to release isotope-labeled ACh and Ch in the presence and absence of these agents. The kinetics of release were determined at the resting state (basal release) and in the presence of 50 mM K+. Under either condition, McN-A-343 enhanced the release of isotope-labeled ACh, whereas oxotremorine inhibited the K(+)-evoked release but had no effect on the basal release. The enhancing effect of McN-A-343 on basal ACh release was fully blocked by the selective M1 muscarinic antagonist, pirenzepine (100 nM). In contrast to its enhancing effect on ACh release, McN-A-343 potently inhibited Ch efflux as well as Ch influx. These effects were not blocked by atropine, a nonselective muscarinic antagonist. Oxotremorine had no effect on Ch transport. Binding studies showed that McN-A-343 was 3.6-fold more potent in displacing radiolabeled quinuclidinyl benzilate from cerebral cortex muscarinic receptors (mostly M1 subtype) than from cerebellar receptors (mostly M2 subtype), whereas oxotremorine was 2.6-fold more potent in the cerebellum. The displacements of radio-labeled pirenzepine and cis-dioxolane confirmed the M1 subtype preference of McN-A-343 and the M2 subtype preference of oxotremorine.(ABSTRACT TRUNCATED AT 250 WORDS)

Putative M2 muscarinic receptors of rat heart have high affinity for organophosphorus anticholinesterases

The M2 subtype of muscarinic receptor is predominant in heart, and such receptors were reported to be located in muscles as well as in presynaptic cholinergic and adrenergic nerve terminals. Muscarinic receptors of rat heart were identified by the high affinity binding of the agonist (+)-[3H]cis-methyldioxolane ([3H]CD), which has been used to label a high affinity population of M2 receptors. A single population of sites (KD 2.74 nM; Bmax of 82 fmol/mg protein) was detected and [3H]CD binding was sensitive to the M2 antagonist himbacine but much less so to pirenzepine, the M1 antagonist. These cardiac receptors had different sensitivities to NiCl2 and N-ethylmaleimide from brain muscarinic receptors, that were also labeled with [3H]CD and considered to be of the M2 subtype. Up to 70% of the [3H]CD-labeled cardiac receptors had high affinities for several organophosphate (OP) anticholinesterases. [3H]CD binding was inhibited by the nerve agents soman, VX, sarin, and tabun, with K0.5 values of 0.8, 2, 20, and 50 nM, respectively. It was also inhibited by echothiophate and paraoxon with K0.5 values of 100 and 300 nM, respectively. The apparent competitive nature of inhibition of [3H]CD binding by both sarin and paraoxon suggests that the OPs bind to the acetylcholine binding site of the muscarinic receptor. Other OP insecticides had lower potencies, inhibiting less than 50% of 5 nM [3H]CD binding by 1 microM of EPN, coumaphos, dioxathion, dichlorvos, or chlorpyriphos. There was poor correlation between the potencies of the OPs in reversibly inhibiting [3H]CD binding, and their anticholinesterase activities and toxicities. Acetylcholinesterases are the primary targets for these OP compounds because of the irreversible nature of their inhibition, which results in building of acetylcholine concentrations that activate muscarinic and nicotinic receptors and desensitize them, thereby inhibiting respiration. Nevertheless, the high affinities that cardiac muscarinic receptors have for these toxicants point to their extra vulnerability. It is suggested that the success of iv administration of the muscarinic receptor inhibitor atropine in initial therapy of poisoning by OP anticholinesterases may be related in part to the extra sensitivity of M2 receptors to certain OPs.

(+-)-cis-2-methyl-spiro(1,3-oxathiolane-5,3') quinuclidine (AF102B): a new M1 agonist attenuates cognitive dysfunctions in AF64A-treated rats

(+-)-cis-2-Methyl-spiro(1,3-oxathiolane-5,3')quinuclidine (AF102B), a new muscarinic agonist of utmost rigidity, exhibits a high selectivity for M1 muscarinic receptors. In rats having a cholinergic hypofunction induced by the intracerebroventricular administration of ethylcholine aziridinium (AF64A), AF102B reversed cognitive impairments in a step-through passive avoidance task and in an 8-arm radial maze. AF102B reversed cognitive impairments at significantly lower doses than those needed to induce side-effects. In addition, AF102B exhibited low toxicity. The results suggest that AF102B may prove useful for treatments of cholinergic deficiencies and cognitive impairments, like those reported in Alzheimer's disease.

Muscarinic M2 receptors in bovine tracheal smooth muscle: discrepancies between binding and function

Previous work showing that AF-DX 116, a cardioselective muscarinic antagonist in functional experiments, does not discriminate between muscarinic receptors in bovine cardiac and tracheal membranes has been extended. In addition to AF-DX 116 we used the muscarinic antagonists, atropine, pirenzepine, 4-DAMP methobromide, gallamine, hexahydrosiladifenidol and methoctramine, in radioligand binding experiments on bovine cardiac left ventricular and tracheal smooth muscle membranes. The functional antagonism of the methacholine-induced contraction of bovine tracheal smooth muscle strips was also evaluated. An excellent correlation was found for all compounds between the binding affinities for muscarinic receptors in cardiac and tracheal smooth muscle membranes; moreover, the affinities found in cardiac membranes correspond with the pA2 values reported for atrial preparations of rat and guinea pig. However, significant and occasionally marked discrepancies were found between binding and functional affinities of these muscarinic antagonists on bovine tracheal smooth muscle.

Direct actions of organophosphate anticholinesterases on nicotinic and muscarinic acetylcholine receptors

Four nerve agents and one therapeutic organophosphate (OP) anticholinesterase (anti-ChE) bind to acetylcholine (ACh) receptors, inhibit or modulate binding of radioactive ligands to these receptors, and modify events regulated by them. The affinity of nicotinic (n) ACh receptors of Torpedo electric organs and most muscarinic (m) ACh receptors of rat brain and N1E-115 neuroblastoma cultures for the OP compounds was usually two to three orders of magnitude lower than concentrations required to inhibit 50% (IC-50) of ACh-esterase activity. However, a small population of m-ACh receptors had an affinity as high as that of ACh-esterase for the OP compound. This population is identified by its high-affinity [3H]-cis-methyldioxolane ([3H]-CD) binding. Although sarin, soman, and tabun had no effect, (O-ethyl S[2-(diisopropylamino)ethyl)] methyl phosphonothionate (VX) and echothiophate inhibited competitively the binding of [3H]-quinuclidinyl benzilate ([3H]-QNB) and [3H]-pirenzepine ([3H]-PZ) to m-ACh receptors. However, VX was more potent than echothiophate in inhibiting this binding and 50-fold more potent in inhibiting carbamylcholine (carb)-stimulated [3H]-cGMP synthesis in N1E-115 neuroblastoma cells--both acting as m receptor antagonist. All five OPs inhibited [3H]-CD binding, with IC-50s of 3, 10, 40, 100, and 800 nM for VX, soman, sarin, echothiophate, and tabun, respectively. The OP anticholinesterases also bound to allosteric sites on the n-ACh receptor (identified by inhibition of [3H]-phencyclidine binding), but some bound as well to the receptor's recognition site (identified by inhibition of [125I]-alpha-bungarotoxin binding). Soman and echothiophate in micromolar concentrations acted as partial agonists of the n-ACh receptor and induced receptor desensitization. On the other hand, VX acted as an open channel blocker of the activated receptor and also enhanced receptor desensitization. It is suggested that the toxicity of OP anticholinesterases may include their action on n-ACh as well as m-ACh receptors if their concentrations in circulation rise above micromolar levels. At nanomolar concentrations their toxicity is due mainly to their inhibition of ACh-esterase. However, at these low concentrations, many OP anticholinesterases (eg, VX and soman) may affect a small population of m-ACh receptors, which have a high affinity for CD. Such effects on m-ACh receptors may play an important role in the toxicity of certain OP compounds.