pyrantel and methyridine

Three pharmacological subtypes of cholinergic receptors have been distinguished in Ascaris suum using a muscle contraction assay and classical pharmacological techniques. The receptor subtypes are: a B-subtype (sensitive to bephenium); an L-subtype (sensitive to levamisole and pyrantel); and an N-subtype (sensitive to nicotine and methyridine). Oxantel is a cholinergic anthelmintic that was first introduced for the treatment of whipworm, Trichuris, infections in children. Here, we compare the subtype selectivity of oxantel with thenium and other cholinergic anthelmintics. We used the A. suum assay to derive pA(2) values for the agonists: oxantel, thenium, bephenium, levamisole, pyrantel, nicotine and methyridine with the antagonists: paraherquamide, 2-desoxyparaherquamide and methyllycaconitine. pA(2) values, rather than pK(B) values, were determined for all agonists when it was found that Schild slopes for some agonists were significantly less than 1.0. The pA(2) of oxantel was 6.58+/-0.25 for paraherquamide; 5.39+/-0.28 for 2-desoxyparaherquamide; 7.01+/-0.19 for methyllycaconitine. Comparison of pA(2) values using cluster analysis showed that oxantel was grouped with nicotine and methyridine, the N-subtype agonists. Thenium had pA(2)s of 7.84+/-0.41 for paraherquamide; 5.52+/-0.50 for 2-desoxyparaherquamide; 6.33+/-0.19 for methyllycaconitine. Cluster analysis placed thenium between the L-subtype agonists and the B-subtype agonist. The therapeutic significance of classification of cholinergic anthelmintics is discussed. Combination of oxantel and pyrantel would have therapeutic advantages, covering N- and L-subtypes, and so increasing spectrum of action and reducing the potential for development of resistance. Our results predict that oxantel may remain effective in some nematode isolates that have become levamisole- and pyrantel-resistant.

Topics: Animals; Anthelmintics; Ascaris suum; Cluster Analysis; Dose-Response Relationship, Drug; Levamisole; Nicotine; Nicotinic Agonists; Nicotinic Antagonists; Pyrantel; Pyridines; Receptors, Cholinergic

1. The development of resistance to all chemotherapeutic agents increases and needs to be addressed. We are interested in resistance in parasitic nematodes to the anthelmintic levamisole. During studies on methyridine, we found that it gave us a new insight into pharmacological changes associated with levamisole resistance. Initially, electrophysiological investigation using a two-micropipette current-clamp recording technique revealed that methyridine acts as a cholinergic agonist on nematode muscle receptors (Ascaris suum). Methyridine (>30 microm) produced reversible concentration-dependent depolarizations and increases in input conductance. Mecamylamine (30 microm) and paraherquamide (0.3 microm) produced reversible antagonism of the depolarization and conductance responses to methyridine. These observations suggest that methyridine, like acetylcholine and levamisole, gates ion channels on the muscle of parasitic nematodes. 2. The antagonistic effects of dihydro-beta-erythroidine and paraherquamide on methyridine-induced contractions of A. suum muscle flaps were then examined to determine if methyridine showed subtype selectivity for N-subtype (nicotine-sensitive) or L-subtype (levamisole-sensitive) acetylcholine receptors. Dihydro-beta-erythroidine weakly antagonized the effects of methyridine (but had no effect on levamisole responses). The antagonism of methyridine (pA2, 5.9) and nicotine (pA2, 6.1) by paraherquamide was similar, but was less than the antagonism of levamisole (pA2, 7.0). The antagonist profiles suggested that methyridine has a selective action on the N-subtype rather than on the L-subtype. 3. A novel use for a larval inhibition migration assay was made using L3 larvae of Oesophagostomum dentatum. Inhibitory effects of nicotine, levamisole, pyrantel and methyridine on the migration of larvae of levamisole-sensitive (SENS) and levamisole-resistant (LEV-R) isolates were tested at different concentrations. Levamisole and pyrantel (putative L-subtype-selective agonists) concentration-response plots were displaced to the right in LEV-R isolates. Nicotine (an N-subtype-selective agonist) and methyridine produced little shift in concentration-response plots in the LEV-R isolates. Resistance dose ratios were used to calculate the relative selectivity, rhoL, for the L-type receptor (levamisole rhoL=1.0; pyrantel rhoL=0.93; methyridine rhoL=0.17; nicotine rhoL=0.06). These observations reveal an N-subtype-selective action of methyridine and s

Topics: Animals; Antinematodal Agents; Ascaris suum; Bephenium Compounds; Dihydro-beta-Erythroidine; Dose-Response Relationship, Drug; Drug Resistance; Indolizines; Isometric Contraction; Larva; Levamisole; Mecamylamine; Membrane Potentials; Muscles; Nicotine; Nicotinic Antagonists; Protein Isoforms; Pyrantel; Pyridines; Receptors, Nicotinic; Spiro Compounds

Two homomer-forming nicotinic acetylcholine receptor subunits with 47% identity in their amino acid sequences were employed to compare the actions of cholinergic anthelmintics and ivermectin on expressed vertebrate and nematode nicotinic receptors of known molecular composition. Voltage-clamp electrophysiology was used to study recombinant nicotinic receptors expressed in Xenopus laevis oocytes following nuclear injection of cDNA encoding either chicken alpha7 or Caenorhabditis elegans ACR-16 (Ce21) subunits. Butamisole, morantel and metyridine were without agonist actions on either alpha7 or ACR-16 nicotinic receptors in the range 10nM-1mM. However, butamisole (pIC(50)=4.9 for both alpha7 and ACR-16) and morantel (pIC(50)=5.6 for alpha7 and 5.7 for ACR-16) antagonized responses of both alpha7 and ACR-16 receptors to acetylcholine. Metyridine (1mM) did not affect responses to acetylcholine of either receptor. Oxantel was without agonist actions on ACR-16, but was an acetylcholine antagonist (pIC(50)=5.4). In contrast, it was found to have low efficacy agonist action (pEC(50)=4.4) on alpha7 at concentrations in the range 10-300microM. In agreement with a previous study, ivermectin (30microM), an agonist of L-glutamate-gated chloride channels, enhanced the amplitude of responses to acetylcholine of alpha7 nicotinic receptors. However, this same concentration of ivermectin (30microM) did not potentiate the acetylcholine-induced responses of ACR-16, but rather resulted in a slight attenuation. We conclude that oxantel and ivermectin have identified new pharmacological differences between the chicken alpha7 nicotinic receptor and its C. elegans homologue ACR-16.

Topics: Acetylcholine; alpha7 Nicotinic Acetylcholine Receptor; Animals; Anthelmintics; Caenorhabditis elegans; Chickens; DNA, Complementary; Female; Ivermectin; Morantel; Oocytes; Pyrantel; Pyridines; Receptors, Nicotinic; Sequence Homology; Thiazoles; Xenopus laevis