Actions of cholinergic drugs in the nematode Ascaris suum. Complex pharmacology of muscle and motorneurons.

Segerberg, Marsha A.; Stretton, A. O. W.

doi:10.1085/jgp.101.2.271

Cited by 29 publications

(17 citation statements)

References 31 publications

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“…In an isolated muscle bag preparation of A. suum, Martin and Valkanov (1996) observed evidence of a mecamylamineresistant cholinergic receptor, stimulation of which increased the opening of a non-selective cation channel, an effect that was not blocked by atropine, mecamylamine or tubocurarine. In addition Segerberg and Stretton (1993) reported that pilocarpine, a muscarinic agonist, produced a concentration-dependent depolarization in A. suum muscle that was not antagonized by a muscarinic antagonist (N-methyl-scopolamine) nor the nicotinic antagonist, tubocurarine. The lack of effect of oxtremorine and atropine in previous A. suum studies, together with the modest effect of atropine in our studies, suggests that a GAR-3-like receptor is not involved in mediating the effects of MFI.…”

Section: Discussionmentioning

confidence: 99%

“…Colquhoun et al (1991) have tested a range of cholinergic agonists on the electrophysiology of A. suum muscle cells and found furtrethonium to be one of the more potent muscarinic agonists. Segerberg and Stretton (1993) have also found evidence of muscarinic-like receptors on A. suum muscle mediating depolarization and contraction; and Martin and Valkanov (1996) have described effects of acetylcholine potentiating the opening of mecamylamineresistant non-selective cation channel currents (I bcat ) in isolated A. suum muscle bags. In Caenorhabditis elegans three G-protein coupled acetylcholine receptors (GAR-1, GAR-2 and GAR-3) have been reported (Hwang et al, 1999;Lee et al, 2000).…”

Section: Introductionmentioning

confidence: 99%

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Effects of the muscarinic agonist, 5-methylfurmethiodide, on contraction and electrophysiology of Ascaris suum muscle

Trailovic

Verma

Clark

et al. 2008

International Journal for Parasitology

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Contraction and electrophysiological effects of 5-methylfurmethiodide (MFI), a selective muscarinic agonist in mammals, were tested on Ascaris suum muscle strips. In a contraction assay, MFI produced weak contraction and was less potent than levamisole and acetylcholine. Atropine (3 µM) a nonselective muscarinic antagonist in mammalian preparations, did not affect contractions produced by MFI. Mecamylamine (3 µM) a nicotinic antagonist in A. suum preparations, blocked the MFI contractions indicating that MFI had weak nicotinic agonist actions. In two-micropipette currentclamp experiments MFI, at concentrations greater than 10 µM, produced concentration-dependent depolarizations and small increases in membrane conductance. The depolarizing effects were not abolished by perfusing the preparation in a calcium-free Ascaris Ringer solution to block synaptic transmission, suggesting that MFI effects were mediated by receptors on the muscle and were calcium-independent. A high concentration of mecamylamine, 30 µM, only reduced the depolarizing responses by 42%, indicating that MFI also had effects on non-nicotinic receptors. Three nonnicotinic effects in the presence of 30 µM mecamylamine were identified using voltage-clamp techniques: i) MFI produced opening of mecamylamine-resistant non-selective-cation channel currents; ii) MFI inhibited opening of voltage-activated potassium currents; and iii) MFI increased the threshold of voltage-activated calcium currents. We suggest that a drug that is more selective for voltage-activated potassium currents, without effects on other channels like MIF, may be exploited pharmacologically as a novel anthelmintic or as an agent to potentiate the action of levamisole. In a larval migration assay we demonstrated that 4-aminopyridine (4-AP: a potassium channel blocker) potentiated the effects of levamisole but MFI did not.

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Section: Discussionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

Effects of the muscarinic agonist, 5-methylfurmethiodide, on contraction and electrophysiology of Ascaris suum muscle

Trailovic

Verma

Clark

et al. 2008

International Journal for Parasitology

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“…Like GABA, glutamate has been proposed to play roles in the nervous system of the most primitive animals. Antagonistic to GABA, glutamate increases the outputs of ectodermal and endodermal impulse generating systems in the phylogenetically basal hydrozoan Hydra vulgaris (Kass-Simon et al, 2003), and acts as an excitatory neurotransmitter in cestode and aplysiidae nervous systems (Davis & Stretton, 1995;Verma et al, 2010;Gerschenfeld, 1973;Kehoe & Marder, 1976;Segerberg & Stretton, 1993). Glutamate is the main excitatory neurotransmitter in the nervous systems of nematodes and fruit fly (Devaud et al, 2008).…”

Section: Gaba and Glutamate As Neurotransmitters Exist In Early Animamentioning

confidence: 99%

Evolution of neurotransmitter gamma-aminobutyric acid, glutamate and their receptors

Gou

Wang²,

Wang³

2013

Zoological Research

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Gamma-aminobutyric acid (GABA) and glutamate are two important amino acid neurotransmitters widely present in the nervous systems of mammals, insects, round worm, and platyhelminths, while their receptors are quite diversified across different animal phyla. However, the evolutionary mechanisms between the two conserved neurotransmitters and their diversified receptors remain elusive, and antagonistic interactions between GABA and glutamate signal transduction systems, in particular, have begun to attract significant attention. In this review, we summarize the extant results on the origin and evolution of GABA and glutamate, as well as their receptors, and analyze possible evolutionary processes and phylogenetic relationships of various GABAs and glutamate receptors. We further discuss the evolutionary history of Excitatory/Neutral Amino Acid Transporter (EAAT), a transport protein, which plays an important role in the GABA-glutamate "yin and yang" balanced regulation. Finally, based on current advances, we propose several potential directions of future research.

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“…ACh acts at muscarinic receptors, encoded in nematodes by the gar genes Lee et al, 1999Lee et al, , 2000. These are present in parasitic species, and have atypical muscarinic pharmacology (Segerberg and Stretton, 1993;Kimber et al, 2009), which again suggest that helminth-specific molecules could be developed.…”

Section: G Protein-coupled Receptorsmentioning

confidence: 99%

Ion channels and receptor as targets for the control of parasitic nematodes

Wolstenholme

2011

International Journal for Parasitology: Drugs and Drug Resistan

103

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Many of the anthelmintic drugs in use today act on the nematode nervous system. Ion channel targets have some obvious advantages. They tend to act quickly, which means that they will clear many infections rapidly. They produce very obvious effects on the worms, typically paralyzing them, and these effects are suitable for use in rapid and high-throughput assays. Many of the ion channels and enzymes targeted can also be incorporated into such assays. The macrocyclic lactones bind to an allosteric site on glutamate-gated chloride channels, either directly activating the channel or enhancing the effect of the normal agonist, glutamate. Many old and new anthelmintics, including tribendimidine and the amino-acetonitrile derivatives, act as agonists at nicotinic acetylcholine receptors; derquantel is an antagonist at these receptors. Nematodes express many different types of nicotinic receptor and this diversity means that they are likely to remain important targets for the foreseeable future. Emodepside may have multiple effects, affecting both a potassium channel and a pre-synaptic G protein-coupled receptor; although few other current drugs act at such targets, this example indicates that they may be more important in the future. The nematode nervous system contains many other ion channels and receptors that have not so far been exploited in worm control but which should be explored in the development of effective new compounds.

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Actions of cholinergic drugs in the nematode Ascaris suum. Complex pharmacology of muscle and motorneurons.

Cited by 29 publications

References 31 publications

Effects of the muscarinic agonist, 5-methylfurmethiodide, on contraction and electrophysiology of Ascaris suum muscle

Effects of the muscarinic agonist, 5-methylfurmethiodide, on contraction and electrophysiology of Ascaris suum muscle

Evolution of neurotransmitter gamma-aminobutyric acid, glutamate and their receptors

Ion channels and receptor as targets for the control of parasitic nematodes

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