Investigating the function and possible biological role of an acetylcholine-gated chloride channel subunit (ACC-1) from the parasitic nematode Haemonchus contortus.

The cys-loop superfamily of ligand-gated ion channels are well recognized as important drug targets for many invertebrate specific compounds. With the rise in resistance seen worldwide to existing anthelmintics, novel drug targets must be identified so new treatments can be developed. The acetylcholine-gated chloride channel (ACC) family is a unique family of cholinergic receptors that have been shown, using Caenorhabditis elegans as a model, to have potential as anti-parasitic drug targets. However, there is little known about the function of these receptors in parasitic nematodes. Here, we have identified an acc gene (hco-acc-1) from the sheep parasitic nematode Haemonchus contortus. While similar in sequence to the previously characterized C. elegans ACC-1 receptor, Hco-ACC-1 does not form a functional homomeric channel in Xenopus oocytes. Instead, co-expression of Hco-ACC-1 with a previously characterized subunit Hco-ACC-2 produced a functional heteromeric channel which was 3x more sensitive to acetylcholine compared to the Hco-ACC-2 homomeric channel. We have also found that Hco-ACC-1 can be functionally expressed in C. elegans. Overexpression of both cel-acc-1 and hco-acc-1 in both C. elegans N2 and acc-1 null mutants decreased the time for worms to initiate reversal avoidance to octanol. Moreover, antibodies were generated against the Hco-ACC-1 protein for use in immunolocalization studies. Hco-ACC-1 consistently localized to the anterior half of the pharynx, specifically in pharyngeal muscle tissue in H. contortus. On the other hand, expression of Hco-ACC-1 in C. elegans was restricted to neuronal tissue. Overall, this research has provided new insight into the potential role of ACC receptors in parasitic nematodes.

A molecular characterization of the agonist binding site of a nematode cys-loop GABA receptor.

BACKGROUND AND PURPOSE: Cys-loop GABA receptors represent important targets for human chemotherapeutics and insecticides and are potential targets for novel anthelmintics (nematicides). However, compared with insect and mammalian receptors, little is known regarding the pharmacological characteristics of nematode Cys-loop GABA receptors. Here we have investigated the agonist binding site of the Cys-loop GABA receptor UNC-49 (Hco-UNC-49) from the parasitic nematode Haemonchus contortus. EXPERIMENTAL APPROACH: We used two-electrode voltage-clamp electrophysiology to measure channel activation by classical GABA receptor agonists on Hco-UNC-49 expressed in Xenopus laevis oocytes, along with site-directed mutagenesis and in silico homology modelling. KEY RESULTS: The sulphonated molecules P4S and taurine had no effect on Hco-UNC-49. Other classical Cys-loop GABAA receptor agonists tested on the Hco-UNC-49B/C heteromeric channel had a rank order efficacy of GABA > trans-4-aminocrotonic acid > isoguvacine > imidazole-4-acetic acid (IMA) > (R)-(-)-4-amino-3-hydroxybutyric acid [R(-)-GABOB] > (S)-(+)-4-amino-3-hydroxybutyric acid [S(+)-GABOB] > guanidinoacetic acid > isonipecotic acid > 5-aminovaleric acid (DAVA) (partial agonist) > ß-alanine (partial agonist). In silico ligand docking revealed some variation in binding between agonists. Mutagenesis of a key serine residue in binding loop C to threonine had minimal effects on GABA and IMA but significantly increased the maximal response to DAVA and decreased twofold the EC50 for R(-)- and S(+)-GABOB. CONCLUSIONS AND IMPLICATIONS: The pharmacological profile of Hco-UNC-49 differed from that of vertebrate Cys-loop GABA receptors and insect resistance to dieldrin receptors, suggesting differences in the agonist binding pocket. These findings could be exploited to develop new drugs that specifically target GABA receptors of parasitic nematodes.

Characterization of cys-loop receptor genes involved in inhibitory amine neurotransmission in parasitic and free living nematodes.

We have isolated two genes, Hco-lgc-53 and Hco-mod-1, from the parasitic nematode Haemonchus contortus, which are orthologs of previously characterized genes that encode dopamine and serotonin-gated chloride channels, respectively, in Caenorhabditis elegans. A search of transcriptome data for the filarial nematode parasites Loa loa, Brugia malayi, and Wucheria bancrofti revealed predicted coding sequences for orthologs of acetylcholine, serotonin and dopamine-gated chloride channels, which correspond to the C. elegans clades acc-1, mod-1 and ggr-3, respectively. Genome data for the more distantly related nematode parasite, Trichinella spiralis, contain genes predicted to encode members of the acc-1 clade only, but all three clades were absent from the trematode Schistosoma mansoni. Analysis of the ratio of non-synonymous to synonymous substitutions (ω) for receptor subunit sequences revealed strong selective constraint over the entire protein, consistent with the known highly conserved 3D structure of cys-loop receptors. This constraint was significantly greater for binding loop residues that are predicted to contact bound ligand and residues of the transmembrane domains. The substitution rate for ligand binding residues was significantly higher for branches leading to the acc-1 and mod-1 clades, where the convergent evolution for binding acetylcholine and serotonin, respectively, is thought to have occurred. Homology models of both Hco-MOD-1 and Hco-LGC-53 channels revealed the presence of binding structures typical of the cys-loop receptor family, including the presence of an aromatic box that is important for the formation of the binding pocket. Both receptors contain a tryptophan in loop C that appears to be a key residue important for the binding of amines to ligand-gated chloride channels. As additional ligand-gated chloride-channel sequences become available for a wider range of species the combination of molecular modeling and analysis of sequence evolution should provide an effective tool to understand the wide diversity of neurotransmitters that bind to this unique group of receptors.