L-Glutamate binding sites of parasitic nematodes: an association with ivermectin resistance?

M. V. HEJMADI; S. JAGANNATHAN; N. S. DELANY; G. C. COLES; A. J. WOLSTENHOLME

doi:10.1017/S0031182099005843

Abstract

Core share and HTML view are not available for this content. However, as you have access to this content, a full PDF is available via the ‘Save PDF’ action button.

Nematode membrane preparations contain high amounts of low-affinity specific L-glutamate binding sites. The numbers of these sites were increased in 2 isolates, one field-derived and the other laboratory-derived, of ivermectin-resistant Haemonchus contortus and a field isolate of ivermectin-resistant Telodorsagia circumcincta, when compared to control, drug- sensitive isolates. Specific [3H]ivermectin binding to these membrane preparations showed no differences between ivermectin-sensitive and resistant isolates and the number of ivermectin binding sites was approximately 100-fold less than the number of L-glutamate binding sites. Kinetic analysis of L-glutamate binding suggested the presence of at least 2 classes of binding site. L-Glutamate binding was blocked by ibotenic acid, kynurenic acid and β-hydroxyaspartate, but not by ivermectin, argiopine, kainate, quisqualate or NMDA. Competition assays with ibotenic acid suggested that there were 2 distinct populations of glutamate binding sites and that the site with the lower affinity for ibotenate was upregulated in the ivermectin-resistant nematodes. In the field isolate of resistant H. contortus we found no coding changes in the cDNAs encoding glutamate-gated chloride channel subunits HG2, HG3 and HG4, nor were any changes in channel expression detected using subunit-specific antibodies. The low-affinity binding site is unlikely to be associated with the ivermectin receptor in these nematodes.

Crossref Citations

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Prichard, RogerK. 2001. Genetic variability following selection of Haemonchus contortus with anthelmintics. Trends in Parasitology, Vol. 17, Issue. 9, p. 445.

Prichard, Roger and Tait, Andy 2001. The role of molecular biology in veterinary parasitology. Veterinary Parasitology, Vol. 98, Issue. 1-3, p. 169.

Geary, Timothy G. and Thompson, David P. 2001. Caenorhabditis elegans: how good a model for veterinary parasites?. Veterinary Parasitology, Vol. 101, Issue. 3-4, p. 371.

Griffith, Robert K. 2003. Burger's Medicinal Chemistry and Drug Discovery. p. 1090.

Yates, Darran M Portillo, Virginia and Wolstenholme, Adrian J 2003. The avermectin receptors of Haemonchus contortus and Caenorhabditis elegans. International Journal for Parasitology, Vol. 33, Issue. 11, p. 1183.

Wolstenholme, Adrian J. Fairweather, Ian Prichard, Roger von Samson-Himmelstjerna, Georg and Sangster, Nicholas C. 2004. Drug resistance in veterinary helminths. Trends in Parasitology, Vol. 20, Issue. 10, p. 469.

Reed, Stephen M. Bayly, Warwick M. and Sellon, Debra C. 2004. Equine Internal Medicine. p. 59.

Walker, Robert J. Rogers, Candida M. Franks, Christopher J. and Holden-Dye, Lindy 2004. Cell Signalling in Prokaryotes and Lower Metazoa. p. 243.

RUIZ, A. MOLINA, J. M. NJUE, A. and PRICHARD, R. K. 2004. Genetic variability in cysteine protease genes ofHaemonchus contortus. Parasitology, Vol. 128, Issue. 5, p. 549.

Bettinger, Jill C. Carnell, Lucinda Davies, Andrew G. and McIntire, Steven L. 2004. Vol. 62, Issue. , p. 195.

CrossRef

Coles, G.C. Rhodes, A.C. and Wolstenholme, A.J. 2005. Rapid selection for ivermectin resistance in Haemonchus contortus. Veterinary Parasitology, Vol. 129, Issue. 3-4, p. 345.

von Samson-Himmelstjerna, Georg and Blackhall, William 2005. Will technology provide solutions for drug resistance in veterinary helminths?. Veterinary Parasitology, Vol. 132, Issue. 3-4, p. 223.

Prichard, R.K. 2005. Is anthelmintic resistance a concern for heartworm control?. Veterinary Parasitology, Vol. 133, Issue. 2-3, p. 243.

WOLSTENHOLME, A. J. and ROGERS, A. T. 2006. Glutamate-gated chloride channels and the mode of action of the avermectin/milbemycin anthelmintics. Parasitology, Vol. 131, Issue. S1, p. S85.

Samson-Himmelstjerna, Georg von 2006. Molecular diagnosis of anthelmintic resistance. Veterinary Parasitology, Vol. 136, Issue. 2, p. 99.

SANGSTER, N. C. SONG, J. and DEMELER, J. 2006. Resistance as a tool for discovering and understanding targets in parasite neuromusculature. Parasitology, Vol. 131, Issue. S1, p. S179.

McCAVERA, S. WALSH, T. K. and WOLSTENHOLME, A. J. 2007. Nematode ligand-gated chloride channels: an appraisal of their involvement in macrocyclic lactone resistance and prospects for developing molecular markers. Parasitology, Vol. 134, Issue. 8, p. 1111.

Peterson, Randall T. Nass, Richard Boyd, Windy A. Freedman, Jonathan H. Dong, Ke and Narahashi, Toshio 2008. Use of non-mammalian alternative models for neurotoxicological study. NeuroToxicology, Vol. 29, Issue. 3, p. 546.

Prichard, Roger 2009. Antimicrobial Drug Resistance. p. 621.

Wolstenholme, Adrian J. 2010. Recent progress in understanding the interaction between avermectins and ligand-gated ion channels: putting the pests to sleep. Invertebrate Neuroscience, Vol. 10, Issue. 1, p. 5.

Download full list

Article contents

L-Glutamate binding sites of parasitic nematodes: an association with ivermectin resistance?

Abstract

Keywords

This article has been cited by the following publications. This list is generated based on data provided by Crossref.

Article contents

L-Glutamate binding sites of parasitic nematodes: an association with ivermectin resistance?

Abstract

Keywords

Save article to Kindle

Save article to Dropbox

Save article to Google Drive

Reply to: Submit a response

Your details

You have entered the maximum number of contributors

Conflicting interests