Williamson SM et al. (2009), The nicotinic acetylcholine receptors of the pa...

XB-ART-40072

PLoS Pathog 2009 Jul 01;57:e1000517. doi: 10.1371/journal.ppat.1000517.

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The nicotinic acetylcholine receptors of the parasitic nematode Ascaris suum: formation of two distinct drug targets by varying the relative expression levels of two subunits.

Williamson SM , Robertson AP , Brown L , Williams T , Woods DJ , Martin RJ , Sattelle DB , Wolstenholme AJ .

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Parasitic nematodes are of medical and veterinary importance, adversely affecting human health and animal welfare. Ascaris suum is a gastrointestinal parasite of pigs; in addition to its veterinary significance it is a good model of the human parasite Ascaris lumbricoides, estimated to infect approximately 1.4 billion people globally. Anthelmintic drugs are essential to control nematode parasites, and nicotinic acetylcholine receptors (nAChRs) on nerve and muscle are the targets of cholinergic anthelmintics such as levamisole and pyrantel. Previous genetic analyses of nematode nAChRs have been confined to Caenorhabditis elegans, which is phylogenetically distinct from Ascaris spp. and many other important parasites. Here we report the cloning and expression of two nAChR subunit cDNAs from A. suum. The subunits are very similar in sequence to C. elegans UNC-29 and UNC-38, are expressed on muscle cells and can be expressed robustly in Xenopus oocytes to form acetylcholine-, nicotine-, levamisole- and pyrantel-sensitive channels. We also demonstrate that changing the stoichiometry of the receptor by injecting different ratios of the subunit cRNAs can reproduce two of the three pharmacological subtypes of nAChR present in A. suum muscle cells. When the ratio was 5:1 (Asu-unc-38ratioAsu-unc-29), nicotine was a full agonist and levamisole was a partial agonist, and oocytes responded to oxantel, but not pyrantel. At the reverse ratio (1:5 Asu-unc-38ratioAsu-unc-29), levamisole was a full agonist and nicotine was a partial agonist, and the oocytes responded to pyrantel, but not oxantel. These results represent the first in vitro expression of any parasitic nicotinic receptor and show that their properties are substantially different from those of C. elegans. The results also show that changing the expression level of a single receptor subunit dramatically altered the efficacy of some anthelmintic drugs. In vitro expression of these subunits may permit the development of parasite-specific screens for future anthelmintics.

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Species referenced: Xenopus
Genes referenced: chrna4 kidins220 tbx2

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	Figure 1. The translated sequence of Asu-UNC-29 and Asu-UNC-38 aligned with the C. elegans and B. malayi equivalents (UNC-29 only).In panel A), the conserved regions used in the design of the degenerate oligonucleotides are highlighted in blue. For both panels, the predicted signal peptide is in lower case, the transmembrane regions are highlighted in yellow, the ligand binding residues [39] in red, the glutamic acid and aspartic acid residues conferring cation specificity to the ion channel [40] are in highlighted in green. The N-terminal subunit-specific peptides used to raise antisera are highlighted in black. In panel B), the amino-acid residues identified by Rayes et al [24] as essential for levamisole activation are highlighted in purple.
	Figure 2. Immunolocalisation of nAChR subunits in isolated A. suum muscle cells.A) Confocal microscope images showing indirect immunofluorescent labelling of Ascaris suum muscle with primary antibody against Asu-UNC-38 and FITC conjugated secondary antibody. A whole muscle cell is shown, with Asu-UNC-38 localised to the cell membrane over the entire cell surface. Arrow A indicates the muscle cell arm, B the bag region of the cell, and C the contractile region. B) Asu-UNC-38 localised to the muscle arms where contact with the nerve cord is made to form the neuromuscular junction (indicated by arrows). No labelling of the nerve cord itself was observed. C) Co-localisation of Asu-UNC-29 and Asu-UNC-38 on the muscle cell arm (region A in panel A).
	Figure 3. Two-electrode voltage clamp electrophysiological experiments on Xenopus oocytes.A) Oocytes injected with Asu- unc-38 or Asu-unc-29 cRNAs alone produced no functional receptors, whereas oocytes injected with both subunit cRNAs in an equimolar ratio gave robust responses to application of 100 ÂµM acetylcholine (ACh). B) Oocytes injected with an equimolar ratio of Asu-unc-38 and Asu-unc-29 cRNA responded to 100 ÂµM acetylcholine (ACh), 100 ÂµM levamisole (lev) and 100 ÂµM nicotine (nic). These responses could all be reversibly blocked by application of 10 ÂµM mecamylamine. C) Dose-response relationships for the agonists levamisole (lev, grey circles), acetylcholine (ACh, black diamonds) and nicotine (nic, black triangles) from oocytes injected with an equimolar ratio of Asu-unc-38 and Asu-unc-29. Responses are all normalized to the response to 100 ÂµM acetylcholine. Nâ=â3 (where N is batches of oocytes) and nâ=â6 (where n is the number of individual oocytes) minimum for each data point.
	Figure 4. Levamisole and nicotine responses from oocytes injected with cRNAs at 5â¶1 and 1â¶5 ratios.A) Levamisole and nicotine responses from oocytes injected with a 1â¶5 ratio of Asu-unc-38 and Asu-unc-29. The currents evoked by levamisole application are larger than those produced by nicotine application. Agonist application is indicated by a bar above the trace, and the concentrations are indicated in ÂµM. The dose-response relationships for levamisole and nicotine are derived from Nâ=â3 nâ=â6 minimum for each data point, where nâ=ânumber of oocytes tested, Nâ=ânumber of frogs from which the oocytes were obtained. Levamisole acts as a full agonist on this receptor subtype, whereas nicotine acts as a partial agonist. All responses were normalized to the response to 100 ÂµM acetylcholine: an example of such a response is shown as the inset. B) Nicotine and levamisole responses from oocytes injected with a 5â¶1 Asu-unc-38â¶Asu- unc-29 ratio. The currents evoked by nicotine application are larger than those produced by levamisole application. Agonist application is indicated by a bar above the trace, concentrations are given in ÂµM. The dose-response relationships for levamisole and nicotine, where Nâ=â3 nâ=â6 minimum for each data point. Nicotine acts as a full agonist on this receptor subtype, whereas levamisole acts as a partial agonist. All responses were normalized to the response to 100 ÂµM acetylcholine, an example of which is shown.
	Figure 5. Responses to the anthelmintics pyrantel and oxantel.A) Electrophysiological recording from an oocyte injected with a 1â¶5 Asu-unc-38â¶Asu-unc-29 ratio in response to the application of pyrantel (upper trace) and oxantel (lower trace). Pyrantel clearly acts as an agonist at lower concentrations (<1 ÂµM) and a channel block effect reduces the response seen at higher concentrations; in comparison to this oxantel only produced small currents at any concentration. Agonist application is indicated by a bar above the trace and the concentrations are given in ÂµM. The dose-response relationships for pyrantel and oxantel from oocytes injected with a 1â¶5 ratio of Asu-unc-38 and Asu-unc-29 are shown: Nâ=â3 nâ=â6 minimum for each data point. All responses were normalized to the maximal response (i.e. to the response to 1 ÂµM pyrantel), which was comparable to the response to 100 ÂµM acetylcholine (not shown). B) Electrophysiological recording from oocytes injected with a 5â¶1 Asu-unc-38â¶Asu-_unc-29 ratio in response to the application of oxantel (upper trace) and pyrantel (lower trace). Oxantel clearly acts as an agonist at lower concentrations (<10 ÂµM) and a channel block effect reduces the response seen at higher concentrations; in comparison to this pyrantel only produced small currents at any concentration. Agonist application is indicated by a bar above the trace. Agonist concentrations and the concentrations are given in ÂµM. The Dose-response relationships for pyrantel and oxantel from oocytes injected with a 5â¶1 ratio of Asu-unc-38 and Asu-unc-29 are based on Nâ=â3 nâ=â6 minimum for each data point. All responses were normalized to the maximal response (i.e. to the response to 10 ÂµM oxantel), which was comparable to the response to 100 ÂµM acetylcholine (not shown).
	Figure 6. Possible combinations of the two subunits in the oocyte membrane.The possible combination of Asu-UNC-38 and Asu-UNC-29 that might be present in the injected oocytes are shown. Agonist binding sites, which, by analogy with mammalian receptors should be at an interface between the two subunits, [38] are indicated by black circles. The Figure is based on a similar discussion for mammalian receptors [32].

References [+] :

Bethony, Soil-transmitted helminth infections: ascariasis, trichuriasis, and hookworm. 2006, Pubmed

Bethony, Soil-transmitted helminth infections: ascariasis, trichuriasis, and hookworm. 2006, Pubmed
Blaxter, A molecular evolutionary framework for the phylum Nematoda. 1998, Pubmed
Boes, Animal models of intestinal nematode infections of humans. 2000, Pubmed
Boulin, Eight genes are required for functional reconstitution of the Caenorhabditis elegans levamisole-sensitive acetylcholine receptor. 2008, Pubmed , Xenbase
Brownlee, Immunocytochemical demonstration of neuropeptides in the peripheral nervous system of the roundworm Ascaris suum (Nematoda, Ascaroidea). 1993, Pubmed
Buckingham, Oocytes as an expression system for studying receptor/channel targets of drugs and pesticides. 2006, Pubmed , Xenbase
Celie, Nicotine and carbamylcholine binding to nicotinic acetylcholine receptors as studied in AChBP crystal structures. 2004, Pubmed
Changeux, Nicotinic receptors, allosteric proteins and medicine. 2008, Pubmed
Colquhoun, The pharmacology of cholinoceptors on the somatic muscle cells of the parasitic nematode Ascaris suum. 1991, Pubmed
Corringer, Mutational analysis of the charge selectivity filter of the alpha7 nicotinic acetylcholine receptor. 1999, Pubmed , Xenbase
Crompton, Ascaris and ascariasis. 2001, Pubmed
Culetto, The Caenorhabditis elegans unc-63 gene encodes a levamisole-sensitive nicotinic acetylcholine receptor alpha subunit. 2004, Pubmed
Dale, Oxantel-activated single channel currents in the muscle membrane of Ascaris suum. 1995, Pubmed
Delany, Cloning and localisation of an avermectin receptor-related subunit from Haemonchus contortus. 1998, Pubmed
Fincham, Could control of soil-transmitted helminthic infection influence the HIV/AIDS pandemic. 2003, Pubmed
Fleming, Caenorhabditis elegans levamisole resistance genes lev-1, unc-29, and unc-38 encode functional nicotinic acetylcholine receptor subunits. 1997, Pubmed , Xenbase
Ghedin, Draft genome of the filarial nematode parasite Brugia malayi. 2007, Pubmed
Johnson, GABA-immunoreactivity in inhibitory motor neurons of the nematode Ascaris. 1987, Pubmed
Jones, The cys-loop ligand-gated ion channel gene superfamily of the nematode, Caenorhabditis elegans. 2008, Pubmed
Kaminsky, A new class of anthelmintics effective against drug-resistant nematodes. 2008, Pubmed
Kopp, Acetylcholine receptor subunit genes from Ancylostoma caninum: altered transcription patterns associated with pyrantel resistance. 2009, Pubmed
Kuryatov, Roles of accessory subunits in alpha4beta2(*) nicotinic receptors. 2008, Pubmed
Laughton, Cloning of a putative inhibitory amino acid receptor subunit from the parasitic nematode Haemonchus contortus. 1994, Pubmed , Xenbase
Le Hesran, Severe malaria attack is associated with high prevalence of Ascaris lumbricoides infection among children in rural Senegal. 2004, Pubmed
Levandoski, Single-channel properties of N- and L-subtypes of acetylcholine receptor in Ascaris suum. 2005, Pubmed
Lewis, The genetics of levamisole resistance in the nematode Caenorhabditis elegans. 1980, Pubmed
Martin, Oxantel is an N-type (methyridine and nicotine) agonist not an L-type (levamisole and pyrantel) agonist: classification of cholinergic anthelmintics in Ascaris. 2004, Pubmed
Moroni, alpha4beta2 nicotinic receptors with high and low acetylcholine sensitivity: pharmacology, stoichiometry, and sensitivity to long-term exposure to nicotine. 2006, Pubmed , Xenbase
Nejsum, Ascariasis is a zoonosis in denmark. 2005, Pubmed
Qian, Pharmacology of N-, L-, and B-subtypes of nematode nAChR resolved at the single-channel level in Ascaris suum. 2006, Pubmed
Rayes, Molecular basis of the differential sensitivity of nematode and mammalian muscle to the anthelmintic agent levamisole. 2004, Pubmed
Rosenbluth, Ultrastructure of somatic muscle cells in Ascaris lumbricoides. II. Intermuscular junctions, neuromuscular junctions, and glycogen stores. 1965, Pubmed
Stewart, Losses to internal parasites in swine production. 1988, Pubmed
Tapia, Ca2+ permeability of the (alpha4)3(beta2)2 stoichiometry greatly exceeds that of (alpha4)2(beta2)3 human acetylcholine receptors. 2007, Pubmed , Xenbase
Touroutine, acr-16 encodes an essential subunit of the levamisole-resistant nicotinic receptor at the Caenorhabditis elegans neuromuscular junction. 2005, Pubmed
Towers, The Caenorhabditis elegans lev-8 gene encodes a novel type of nicotinic acetylcholine receptor alpha subunit. 2005, Pubmed
Williamson, The cys-loop ligand-gated ion channel gene family of Brugia malayi and Trichinella spiralis: a comparison with Caenorhabditis elegans. 2007, Pubmed
Zwart, Four pharmacologically distinct subtypes of alpha4beta2 nicotinic acetylcholine receptor expressed in Xenopus laevis oocytes. 1998, Pubmed , Xenbase