51 research outputs found
Pharyngeal Pumping and Tissue-Specific Transgenic P-Glycoprotein Expression Influence Macrocyclic Lactone Susceptibility in Caenorhabditis elegans
Macrocyclic lactones (MLs) are widely used drugs to treat and prevent parasitic nematode infections. In many nematode species including a major pathogen of foals, Parascaris univalens, resistance against MLs is widespread, but the underlying resistance mechanisms and ML penetration routes into nematodes remain unknown. Here, we examined how the P-glycoprotein efflux pumps, candidate genes for ML resistance, can modulate drug susceptibility and investigated the role of active drug ingestion for ML susceptibility in the model nematode Caenorhabditis elegans. Wildtype or transgenic worms, modified to overexpress P. univalens PGP-9 (Pun-PGP-9) at the intestine or epidermis, were incubated with ivermectin or moxidectin in the presence (bacteria or serotonin) or absence (no specific stimulus) of pharyngeal pumping (PP). Active drug ingestion by PP was identified as an important factor for ivermectin susceptibility, while moxidectin susceptibility was only moderately affected. Intestinal Pun-PGP-9 expression elicited a protective effect against ivermectin and moxidectin only in the presence of PP stimulation. Conversely, epidermal Pun-PGP-9 expression protected against moxidectin regardless of PP and against ivermectin only in the absence of active drug ingestion. Our results demonstrate the role of active drug ingestion by nematodes for susceptibility and provide functional evidence for the contribution of P-glycoproteins to ML resistance in a tissue-specific manner
Recent advances in candidate-gene and whole-genome approaches to the discovery of anthelmintic resistance markers and the description of drug/receptor interactions
Anthelmintic resistance has a great impact on livestock production systems
worldwide, is an emerging concern in companion animal medicine, and represents
a threat to our ongoing ability to control human soil-transmitted helminths.
The Consortium for Anthelmintic Resistance and Susceptibility (CARS) provides
a forum for scientists to meet and discuss the latest developments in the
search for molecular markers of anthelmintic resistance. Such markers are
important for detecting drug resistant worm populations, and indicating the
likely impact of the resistance on drug efficacy. The molecular basis of
resistance is also important for understanding how anthelmintics work, and how
drug resistant populations arise. Changes to target receptors, drug efflux and
other biological processes can be involved. This paper reports on the CARS
group meeting held in August 2013 in Perth, Australia. The latest knowledge on
the development of molecular markers for resistance to each of the principal
classes of anthelmintics is reviewed. The molecular basis of resistance is
best understood for the benzimidazole group of compounds, and we examine
recent work to translate this knowledge into useful diagnostics for field use.
We examine recent candidate-gene and whole-genome approaches to understanding
anthelmintic resistance and identify markers. We also look at drug
transporters in terms of providing both useful markers for resistance, as well
as opportunities to overcome resistance through the targeting of the
transporters themselves with inhibitors. Finally, we describe the tools
available for the application of the newest high-throughput sequencing
technologies to the study of anthelmintic resistance
Supramolecular assemblies of gold nanoparticles induced by hydrogen bond interactions
International audienc
Studies on glc-3, a potential target of Ivermectin in parasitic nematodes
International audienceThe free-living nematode Caenorhabditis elegans has been used for many years as an expression system for genes from parasitic species. We wished to further develop and improve this system by using CRISPR/Cas9 to delete specific genes from C. elegans and replace them with single copies of orthologous genes from the parasite, Haemonchus contortus. Initial experiments focussed on glc-3 which encodes a subunit of the glutamate-gated chloride channels, the target of the avermectin/milbemycin family of anthelmintics. We cloned the promoters from the glc-3 genes of both species and compared the expression patterns of mCherry under the control of both promoters. The C. elegans glc-3 promoter drove expression in a subset of head interneurons, as previously reported whereas the H. contortus promoter drove expression in a pharyngeal motoneuron, M4. We were able to generate heterozygous worms in which one copy of glc-3 was deleted, but we could never obtain homozygous knock-outs. Further investigation of the mRNAs encoded by glc-3 revealed a novel transcript, glc-3T, which encodes a severely truncated form of GLC-3. The presence of such truncated transcripts may explain the unexpected difficulties encountered in attempting to knock out ion channel genes in C. elegans
Nanocomposite systems based on gold nanoparticles and thiometalates. From colloids to networks
International audienc
Modelling organophosphate intoxication in C. elegans highlights nicotinic acetylcholine receptor determinants that mitigate poisoning.
Organophosphate intoxication via acetylcholinesterase inhibition executes neurotoxicity via hyper stimulation of acetylcholine receptors. Here, we use the organophosphate paraoxon-ethyl to treat C. elegans and use its impact on pharyngeal pumping as a bio-assay to model poisoning through these neurotoxins. This assay provides a tractable measure of acetylcholine receptor mediated contraction of body wall muscle. Investigation of the time dependence of organophosphate treatment and the genetic determinants of the drug-induced inhibition of pumping highlight mitigating modulation of the effects of paraoxon-ethyl. We identified mutants that reduce acetylcholine receptor function protect against the consequence of intoxication by organophosphates. Data suggests that reorganization of cholinergic signalling is associated with organophosphate poisoning. This reinforces the under investigated potential of using therapeutic approaches which target a modulation of nicotinic acetylcholine receptor function to treat the poisoning effects of this important class of neurotoxins
Allele specific PCR for a major marker of levamisole resistance in Haemonchus contortus
Haemonchus contortus is a haematophagous parasitic nematode that infects small ruminants and causes significant animal health concerns and economic losses within the livestock industry on a global scale. Treatment primarily depends on broad-spectrum anthelmintics, however, resistance is established or rapidly emerging against all major drug classes. Levamisole (LEV) remains an important treatment option for parasite control, as resistance to LEV is less prevalent than to members of other major classes of anthelmintics. LEV is an acetylcholine receptor (AChR) agonist that, when bound, results in paralysis of the worm. Numerous studies implicated the AChR sub-unit, ACR-8, in LEV sensitivity and in particular, the presence of a truncated acr-8 transcript or a deletion in the acr-8 locus in some resistant isolates. Recently, a single non-synonymous SNP in acr-8 conferring a serine-to-threonine substitution (S168T) was identified that was strongly associated with LEV resistance. Here, we investigate the role of genetic variation at the acr-8 locus in a controlled genetic cross between the LEV susceptible MHco3(ISE) and LEV resistant MHco18(UGA2004) isolates of H. contortus. Using single worm PCR assays, we found that the presence of S168T was strongly associated with LEV resistance in the parental isolates and F3 progeny of the genetic cross surviving LEV treatment. We developed and optimised an allele-specific PCR assay for the detection of S168T and validated the assay using laboratory isolates and field samples that were phenotyped for LEV resistance. In the LEV-resistant field population, a high proportion (>75%) of L3 encoded the S168T variant, whereas the variant was absent in the susceptible isolates studied. These data further support the potential role of acr-8 S168T in LEV resistance, with the allele-specific PCR providing an important step towards establishing a sensitive molecular diagnostic test for LEV resistance
Functional Characterization of a Novel Class of Morantel-Sensitive Acetylcholine Receptors in Nematodes
Acetylcholine receptors are pentameric ligandâgated channels involved in excitatory neuro-transmission in both vertebrates and invertebrates. In nematodes, they represent major targets for cholinergic agonist or antagonist anthelmintic drugs. Despite the large diversity of acetylcholine-receptor subunit genes present in nematodes, only a few receptor subtypes have been characterized so far. Interestingly, parasitic nematodes affecting human or animal health possess two closely related members of this gene family, acr-26 and acr-27 that are essentially absent in free-living or plant parasitic species. Using the pathogenic parasitic nematode of ruminants, Haemonchus contortus, as a model, we found that Hco-ACR-26 and Hco-ACR-27 are co-expressed in body muscle cells. We demonstrated that co-expression of Hco-ACR-26 and Hco-ACR-27 in Xenopus laevis oocytes led to the functional expression of an acetylcholine-receptor highly sensitive to the anthelmintics morantel and pyrantel. Importantly we also reported that ACR-26 and ACR-27, from the distantly related parasitic nematode of horses, Parascaris equorum, also formed a functional acetylcholine-receptor highly sensitive to these two drugs. In Caenorhabditis elegans, a free-living model nematode, we demonstrated that heterologous expression of the H. contortus and P. equorum receptors drastically increased its sensitivity to morantel and pyrantel, mirroring the pharmacological properties observed in Xenopus oocytes. Our results are the first to describe significant molecular determinants of a novel class of nematode body wall muscle AChR
Physical map and conceptual origin for different <i>unc-29</i> duplication events.
<p>Panels A) to F) correspond to different paralogous families. An idealized history for each family is indicated to the left. A physical map for different species is shown to the right, based on genome data from WormBase ParaSite (WBPS2) or the Sanger Center haemonchus_V1 genome build from 2012. Arrows indicate extent of the gene from start to stop codon, where differences in length occur in introns. Direction of transcription is indicated for each gene and maps are drawn to scale, as indicated.</p
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