Two relatively recent studies have used a more systematic approach to RNAi to evaluate its use as a functional genomic profiling tool. Mourao et al. (76) selected 32 genes including antioxidants, transcription factors, cell signalling molecules and metabolic enzymes to determine whether gene knock-down by RNAi was associated with morphologically definable phenotypic changes in early larval development (miracidia/sporocyst). A ‘size-reducing’ phenotype was observed in 33% of the treated parasites. Interestingly, only six of the 11 Talazoparib mw phenotype-associated

genes showed a consistent knock-down of the corresponding transcript. In similar experiments using schistosomula, Stefanic and colleagues (77) LDK378 solubility dmso evaluated genes that are expressed in different tissues of the parasite.

Parameters that were investigated included transfection strategy, time and dose-dependency of RNAi, and dosing limits. The authors concluded that RNAi was best achieved by soaking parasites in dsRNA and that electroporation provided no added benefit, in contrast to an earlier report (75). Similar to the results reported by Mourão et al., the efficiency of RNAi was transcript dependent and varied from 40% to 75%. Together, these reports showed that gene-specific testing of RNAi might be necessary to achieve discernable phenotypic effects, which might limit the use of RNAi as a screening method. Liver flukes are responsible for substantial disease in humans and livestock in most countries around the world

(78). Although traditionally regarded as a disease of livestock, fascioliasis is now recognized as a serious, and neglected, emerging zoonotic disease. In spite of the major socioeconomic impact of fascioliasis, there are presently no nuclear genomic sequence datasets for Fasciola or related species. Until recently, <7000 ESTs representing adult Fasciola hepatica from two different hosts and two different countries have been generated (http://www.sanger.ac.uk/Projects/Helminths/ and ftp://ftp.sanger.ac.uk/pub/pathogens/Fasciola/hepatica/ESTs/) but these data have yet to 4-Aminobutyrate aminotransferase be annotated or analysed in detail. To date, two reports have been published (Tables 1 and 2) to evaluate the utility of RNAi in these parasites. Rinaldi et al. transformed newly excysted juveniles (NEJs) by electroporation with luciferase mRNA and were subsequently able to detect luciferase enzyme activity. The presence of an active RNAi pathway in F. hepatica was then shown by knocking down the exogenous luciferase activity by additional introduction of dsRNA specific to luciferase. The authors also tested the RNAi pathway by targeting LAP. They observed a significant reduction in specific mRNA levels (79). A few months later, McGonigle et al. reported successful silencing of the cysteine proteases cathepsin B and L in NEJs.