Grant WN et al. (2007) Expert Opin Drug Discov "Target identification and validation for anthelmintic discovery."

Grant WN, Behm CA

[Expert Opin Drug Discov, 2007]

Anthelmintics presently used in humans were discovered using empirical biological screening processes targeting helminths of veterinary importance. The modern approach to drug discovery is based on genetic, bioinformatic and genomic identification of protein targets followed by specific validation assays and high-throughput screening using chemical libraries. Existing broad-spectrum anthelmintics bind just three classes of molecular targets; more classes of targets are urgently needed. In the absence of robust functional genomics technologies for helminth parasites, the technology of RNA interference in parasites and in the model Caenorhabditis elegans is the best available for discovery and validation of new targets. This article outlines and critically discusses an idealised drug discovery pipeline for anthelmintic discovery in nematodes.

Grant WN (1992) Parasitol Today "Transformation of Caenorhabditis elegans with genes from parasitic nematodes."

Grant WN

[Parasitol Today, 1992]

Our knowledge of many aspects of the molecular biology of animal parasitic nematodes has rapidly expanded in recent years but the classical genetic analysis of this group of organisms has yet to emerge as a viable discipline. For example, it is not possible to routinely perform crosses between single males and females to examine the genetic basis of even simple phenotypes such as anthelmintic resistance. This has meant that the function of many cloned parasite genes can only be inferred from sequence comparison with genes from other organisms where the function is known, or by correlation of DNA polymorphisms linked to the gene with phenotypic differences between strains or individuals. In the absence of classical genetic techniques, a molecular solution is to transform a suitable host with the gene of interest, but what defines a suitable host? Here, Warwick Grant describes recent work that aims to provide such a host.

Crook M et al. (2013) Dev Dyn "Dominant negative mutations of Caenorhabditis elegans daf-7 confer a novel developmental phenotype."

Grant WN, Crook M

[Dev Dyn, 2013]

BACKGROUND: TGF- signaling pathways are involved in the control of development in every member of the animal kingdom. As such, TGF- ligands are widely divergent yet retain a set of core conserved features, specifically, a pre-protein cleavage site and several conserved ligand domain residues, the disruption of which produces a dominant negative phenotype. RESULTS: We have extended these observations into an invertebrate system by creating a series of loss-of-function Caenorhabditis elegans daf-7 transgenes. When we tested these mutant transgenes in a daf-7/+ background, we saw a molting and excretory canal phenotype. Members of both pathways downstream of daf-4 were required for this phenotype. CONCLUSIONS: Our results show that the basic mechanisms of TGF- function are conserved across the animal kingdom. A subset of our daf-7 mutations also produced an unexpected and novel phenotype. Epistasis experiments demonstrated that both daf-3/-5 and sma-4/-9 were downstream of our mutant daf-7 transgenes, which suggests not only a role for DAF-7 in the control of molting and the development of the excretory system but also that daf-7 and dbl-1 signaling may converge downstream of their shared Type II receptor, daf-4. Our approach may unveil new roles in development for other invertebrate TGF- ligands.

Crook M et al. (2010) Int J Parasitol "Failure of Parastrongyloides trichosuri daf-7 to complement a Caenorhabditis elegans daf-7 (e1372) mutant: implications for the evolution of parasitism."

Grant WN, Grant K, Crook M

[Int J Parasitol, 2010]

DAF-7 is the ligand of the TGF- pathway that, in conjunction with the insulin-like and guanylyl cyclase pathways, controls entry into dauer development in Caenorhabditis elegans. Proposed orthologues of Ce-daf-7 have been identified in several species of parasitic nematodes and demonstrate an expression pattern that is consistent between parasitic nematode genera but different to that of Ce-daf-7. This variation in expression pattern is consistent with the current paradigm in evolutionary developmental biology: that regulatory rather than functional change is the primary source of phenotypic diversity. In this work we investigated the proposed orthology of a daf-7 like sequence obtained from Parastrongyloides trichosuri, Pt-daf-7, to Ce-daf-7 via transformation rescue of a C. elegans daf-7 mutant with Pt-daf-7 coding regions. We also investigated further the difference in expression pattern of Pt-daf-7 both by fusing a Pt-daf-7 promoter to a Ce-daf-7 coding region and to a gfp reporter gene. We found that Pt-daf-7 was unable to complement a C. elegans daf-7 mutant, even when reduced to the smallest functional TGF- unit possible, the ligand domain, and that this failure appears to be the result of gene silencing. Furthermore, we show that although the Pt-daf-7 promoter is active later in development than the Ce-daf-7 promoter and most likely active in the correct neurons, a Ce-daf-7 coding region under control of a Pt-daf-7 promoter failed to rescue. Together, these results suggest that, if the free-living nematode developmental pathways, such as the DAF-7 TGF- pathway, have been co-opted during the evolution of parasitism, this co-option has been both at the protein level and in the control of their transcription.

Crook M et al. (2005) Mol Biochem Parasitol "daf-7 and the development of Strongyloides ratti and Parastrongyloides trichosuri."

Thompson FJ, Grant WN, Crook M, Viney ME

[Mol Biochem Parasitol, 2005]

daf-7 is a key ligand in one of the three pathways that control dauer larva development in Caenorhabditis elegans. Given the similarities between dauer larvae of free-living nematodes and third stage infective larvae of animal parasitic nematodes, we hypothesised that daf-7 may be involved in the development of these infective larvae. To investigate this, we cloned daf-7 orthologues from Strongyloides ratti and Parastrongyloides trichosuri and analysed their RNA level by semi-quantitative RT-PCR during the S. ratti and P. trichosuri life cycles and in a range of in vitro and in vivo conditions. We found that, in both species, the RNA level of daf-7 was low in free-living stages but peaked in the infective L3 (iL3) stage with little or no expression in the parasitic stages. This contrasts with the daf-7 RNA level in C. elegans, which peaks in L1, decreases thereafter, and is absent in dauer larvae. The RNA level of daf-7 in infective larvae was reduced by larval penetration of host skin or development in the host, but not by a shift to the body temperature of the host.

Viney ME et al. (2002) Int J Parasitol "Chemical mutagenesis of the parasitic nematode Strongyloides ratti to isolate ivermectin resistant mutants."

Viney ME, Grant WN, Green LD, Brooks JA

[Int J Parasitol, 2002]

We describe a strategy for the mutagenesis of the free-living adult generation of Strongyloides ratti and selection of worms carrying new mutations in the subsequent F2 generation of infective larvae. We demonstrate that this strategy is successful via the selection of infective larvae that are resistant to the anthelmintic ivermectin at a concentration of 10 ng/ml. The majority of these larvae were unable to give rise to patent infections when used to infect parasite naive rats, implying that the majority of the ivermectin resistance mutations confer pleiotropic defects on parasitic, but not on free-living, development.

Newton-Howes J et al. (2006) Int J Parasitol "Characterisation and expression of an Hsp70 gene from Parastrongyloides trichosuri."

Shoemaker CB, Heath DD, Grant WN, Newton-Howes J

[Int J Parasitol, 2006]

Parastrongyloides trichosuri is a nematode parasite of Australian brushtail possums that has an alternative free-living life cycle which can be readily maintained indefinitely in a laboratory setting. The ability to maintain this parasite in a free-living cycle and induce it to parasitism at the free-living L1 stage makes this an excellent model for the study of genes associated with parasitism. A 70kD protein from infective larvae of P. trichosuri that appears to be immunogenic in infected possums has been identified an heat shock protein (Hsp)70 homologue. The complete gene for Pt-Hsp70 was cloned and sequenced. The protein encoded by the Pt-Hsp70 gene is the likely orthologue of the Caenorhabditis elegans protein, Hsp70A, also known as hsp-1. Reverse transcriptase-PCR data indicate that Pt-Hsp70 (designated Pt-hsp-1) is expressed at readily detectable levels in all developmental stages of both the parasitic and free-living P. trichosuri life cycles and the promoter is mildly inducible by heat shock. Bioinformatic analysis of expressed sequence tag databases indicates that C. eleganshsp-1 homologues, together with C. eleganshsp-3 homologues, are the predominant members of the Hsp70 superfamily that are normally expressed in parasitic stages of the Strongyloididae family. Promoter fusions to a beta-galactosidase coding sequence were prepared and introduced into wild type C. elegans to produce transgenic nematodes. Reporter gene expression was clearly present within embryonic cells and within intestinal cells of larval and adult stages. Thus, the expression of the Pt-hsp-1 promoter within P. trichosuri and transgenic C. elegans appears similar to the known expression of C. elegans hsp-1. This promoter should be of value in efforts to develop genetic manipulation tools for P. trichosuri.

Kulkarni A et al. (2013) Parasitology "Parastrongyloides trichosuri suggests that XX/XO sex determination is ancestral in Strongyloididae (Nematoda)."

Kulkarni A, Dyka A, Grant WN, Nemetschke L, Streit A

[Parasitology, 2013]

The parasitic roundworms Strongyloides stercoralis (in man) and Strongyloides ratti (in rats) employ environmentally controlled XX/XO sex determination with a pair of X chromosomes and two pairs of autosomes. Strongyloides papillosus (in sheep) has only two pairs of chromosomes, one of which combines the genetic material homologous to the S. ratti chromosomes X and I. This species creates males through the elimination of one copy of the portion related to the X chromosome (chromatin diminution). It is not clear which one of these two sex-determining mechanisms is ancestral. We demonstrate that Strongyloides vituli (in cattle) has two pairs of chromosomes like its very close relative S. papillosus whereas Parastrongyloides trichosuri, a closely related out-group to Strongyloides spp. in Australian brushtail possums, has three chromosome pairs and employs XX/XO sex determination. The X chromosome of P. trichosuri is homologous to the X chromosome of S. ratti. Our data strongly suggest that the last common ancestor of Strongyloides spp. and Parastrongyloides spp. had two pairs of autosomes along with two or one X chromosome in females and males, respectively. The situation with two pairs of chromosomes is likely derived and occurred through the fusion of the X chromosome with an autosome.

Sirwani N et al. (2024) Cells "Levels of Amyloid Beta (Aβ) Expression in the Caenorhabditis elegans Neurons Influence the Onset and Severity of Neuronally Mediated Phenotypes."

Hedtke SM, Grant K, Sirwani N, McColl G, Grant WN

[Cells, 2024]

A characteristic feature of Alzheimer's disease (AD) is the formation of neuronal extracellular senile plaques composed of aggregates of fibrillar amyloid &#x3b2; (<i>A&#x3b2;</i>) peptides, with the <i>A&#x3b2;1-42</i> peptide being the most abundant species. These <i>A&#x3b2;</i> peptides have been proposed to contribute to the pathophysiology of the disease; however, there are few tools available to test this hypothesis directly. In particular, there are no data that establish a dose-response relationship between <i>A&#x3b2;</i> peptide expression level and disease. We have generated a panel of transgenic <i>Caenorhabditis elegans</i> strains expressing the human <i>A&#x3b2;1-42</i> peptide under the control of promoter regions of two pan-neuronal expressed genes, <i>snb-1</i> and <i>rgef-1</i>. Phenotypic data show strong age-related defects in motility, subtle changes in chemotaxis, reduced median and maximum lifespan, changes in health span indicators, and impaired learning. The <i>A&#x3b2;1-42</i> expression level of these strains differed as a function of promoter identity and transgene copy number, and the timing and severity of phenotypes mediated by <i>A&#x3b2;1-42</i> were strongly positively correlated with expression level. The pan-neuronal expression of varying levels of human <i>A&#x3b2;1-42</i> in a nematode model provides a new tool to investigate the in vivo toxicity of neuronal <i>A&#x3b2;</i> expression and the molecular and cellular mechanisms underlying AD progression in the absence of endogenous <i>A&#x3b2;</i> peptides. More importantly, it allows direct quantitative testing of the dose-response relationship between neuronal <i>A&#x3b2;</i> peptide expression and disease for the first time. These strains may also be used to develop screens for novel therapeutics to treat Alzheimer's disease.

Doyle SR et al. (2016) Parasit Vectors "Discrimination between Onchocerca volvulus and O. ochengi filarial larvae in Simulium damnosum (s.l.) and their distribution throughout central Ghana using a versatile high-resolution speciation assay."

Taylor MJ, Grant WN, Doyle SR, Armoo S, Renz A, Osei-Atweneboana MY

[Parasit Vectors, 2016]

BACKGROUND: Genetic surveillance of the human filarial parasite, Onchocerca volvulus, from onchocerciasis endemic regions will ideally focus on genotyping individual infective larval stages collected from their intermediate host, Simuliid blackflies. However, blackflies also transmit other Onchocerca species, including the cattle parasite O. ochengi, which are difficult to distinguish from the human parasite based on morphological characteristics alone. This study describes a versatile approach to discriminate between O. volvulus and O. ochengi that is demonstrated using parasite infective larvae dissected from blackflies. RESULTS: A speciation assay was designed based on genetic differentiation between O. volvulus and O. ochengi mitochondrial genome sequences that can be performed in high-throughput high-resolution melt (HRM)- or lower throughput conventional restriction fragment length polymorphism (RFLP) analyses. This assay was validated on 185 Onchocerca larvae dissected from blackflies captured from 14 communities in Ghana throughout 2011-2013. The frequency of O. ochengi was approximately 67% of all larvae analysed, which is significantly higher than previously reported in this region. Furthermore, the species distribution was not uniform throughout the study region, with 25%, 47% and 93% of O. volvulus being found in the western-most (Black Volta, Tain and Tombe), the central (Pru) and eastern-most (Daka) river basins, respectively. CONCLUSIONS: This tool provides a simple and cost-effective approach to determine the identity and distribution of two Onchocerca species, and will be valuable for future genetic studies that focus on parasites collected from blackflies. The results presented highlight the need to discriminate Onchocerca species in transmission studies, as the frequency of each species varied significantly between the communities studied.