Acetylcholine antagonizing

Remarkable is the fact that 73a and 73b, showing the greatest difference in sub-lethal activity and toxicity, exhibit the same action under invitro conditions. Both compounds were found to be antagonists of the muscarinic activity of acetylcholine and carbachol71. The dose-response curves of acetylcholine antagonized by 73a and 73b were identical within experimental error. 

Although the specificity of receptors is not so strict as that of the most important anabolic and catabolic enzymes, it is at least as strict as the degrad-ative enzymes of microsomes (see Section 3.5). Thus at ganglia, nicotine (but not muscarine) can take the place of acetylcholine, whereas at postganglionic parasympathetic synapses, muscarine (but not nicotine) can take its place (see Table 7.1). Further specificity is shown in acetylcholine antagonism, for which tubocurarine is specific at the neuromuscular junction, hexamethonium at ganglia, and atropine at parasympathetic postganglionic synapses. 

The nicotinic acetylcholine (nACh) receptor also displays sensitivity to inhalants (Bale et al. 2002). To varying degrees, toluene appeared to antagonize the function of nACh receptors that comprise different subunits. At concentrations of 50 pM to 10 mM, toluene produced a reversible, concentration-dependent inhibition of acetylcholine-induced current in Xenopus oocytes expressing various nicotinic receptor subtypes, with the ol — 2 d ct3—P2 subunit combinations being more sensitive to inhibition than other receptor... 

Compounds that affect activities of hepatic microsomal enzymes can antagonize the effects of methyl parathion, presumably by decreasing metabolism of methyl parathion to methyl paraoxon or enhancing degradation to relatively nontoxic metabolites. For example, pretreatment with phenobarbital protected rats from methyl parathion s cholinergic effects (Murphy 1980) and reduced inhibition of acetylcholinesterase activity in the rat brain (Tvede et al. 1989). Phenobarbital pretreatment prevented lethality from methyl parathion in mice compared to saline-pretreated controls (Sultatos 1987). Pretreatment of rats with two other pesticides, chlordecone or mirex, also reduced inhibition of brain acetylcholinesterase activity in rats dosed with methyl parathion (2.5 mg/kg intraperitoneally), while pretreatment with the herbicide linuron decreased acetylcholine brain levels below those found with methyl parathion treatment alone (Tvede et al. 1989). 

Another possibility is that the antagonist interferes with other post-receptor events that contribute to the tissue response. For example, calcium channel blockers such as verapamil block the influx of calcium necessary for maintained smooth muscle contraction hence, they reduce the contractile response to acetylcholine. Some pharmacologists prefer to describe this as a variant of functional antagonism (see above). 

FIGURE 1.17 Schild plot for the action of atropine in antagonizing the action of acetylcholine on guinea-pig ileum. Each point gives the mean the standard error of the mean of the number of observations shown. 

The effect of anisodine (91) on the release of acetylcholine has been investigated (211-213). Investigation of the pharmacological effects of anisodine (91) on the central nervous system in rabbits has shown a strong depressant effect (210). The effect was antagonized by physostigmine and... 

Intracerebroventricular infusion of CST-14 dramatically increases the amount of slow wave activity in rats, at the expense of wakefulness. The mechanism by which CST-14 enhances cortical synchronization has been established through the interaction of CST-14 with acetylcholine, a neurotransmitter known to be involved in the maintenance of cortical desynchronization. Application of acetylcholine (ACh) in the anesthetized animal increases fast activity, and this effect is blocked with the simultaneous addition of CST-14. These data suggest that CST-14 increases slow wave sleep by antagonizing the effects of ACh on cortical excitability. In addition to this mechanism, cortistatin may enhance cortical... 

Hopf2 concludes that although insect nerve tissues produce substances that simulate acetylcholine and a cholinesterase which is inhibited by organo-phosphorus insecticides, these substances (in locusts at any rate) are not antagonized by atropine. Furthermore, tubocurarine does not poison insects, although it is active in warm-blooded animals and affects the neuromuscular junctions (see pp. 36, 37). In short, different physiological mechanisms appear to be at work in insects. In particular, it seems that acetylcholine, when injected into a variety of insects, has no marked toxic action. It seems then that, in some... 

Areca may interact adversely with antipsychotic medications (Deahl 1989). Two cases have been reported of schizophrenic patients who were taking neuroleptics and developed severe extrapyramidal symptoms after areca chewing. Given the functional antagonism between dopamine and acetylcholine in the striatum, it is likely that arecoline amplified the dyskinetic effect of neuroleptic medications. 

Kulak JM, Nguyen TA, Olivera BM, McIntosh JM (1997) Alpha-conotoxin Mil blocks nicotine-stimulated dopamine release in rat striatal synaptosomes. J Neurosci 17 5263-5270 Kuryatov A, Gerzanich V, Nelson M, Olale F, Lindstrom J (1997) Mutation causing autosomal dominant nocturnal frontal lobe epilepsy alters Ca + permeabihty, conductance, and gating of human a4 32 nicotinic acetylcholine receptors, J Neurosci 17 9035-9047 Kuryatov A, Olale FA, Choi C, Lindstrom J (2000) Acetylchohne receptor extracellular domain determines sensitivity to nicotine-induced inactivation, Eur J Pharmacol 393 11-21 Langley JN (1880) On the antagonism of poisons. J Physiol 3 11-21... 

Neuroleptic activity profiles. The marked differences in action spectra of the phenothiazines, their derivatives and analogues, which may partially resemble those of butyrophenones, are important in determining therapeutic uses of neuroleptics. Relevant parameters include antipsychotic efficacy (symbolized by the arrow) the extent of sedation and the ability to induce ex-trapyramidal adverse effects. The latter depends on relative differences in antagonism towards dopamine and acetylcholine, respectively (p. 188). Thus, the butyrophenones carry an increased risk of adverse motor reactions because Lullmann, Color Atlas of Pharmacology 2000 Thieme All rights reserved. Usage subject to terms and oonditlons of lloense. 

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