RNAi-mediated silencing of ARV1 in Setaria digitata impairs in-vitro microfilariae release, embryogenesis and adult parasite viability.

Setaria digitata is a nematode that resides in the peritoneal cavity of ruminants causing cerebrospinal nematodiasis disease affecting livestock and inflicting significant economic forfeitures in Asia. Further, this nematode can infect humans, causing abscesses, allergic reactions, enlarged lymph nodes, eye lesions and inflammation of the lungs. The 'ARE2 required for viability1' (ARV1) encodes for putative lipid transporter localized in the endoplasmic reticulum (ER) and Golgi complex membrane in humans and yeast. In the present study, the functional role of S. digitata ARV1 (SD-ARV1) was investigated using RNA interference (RNAi) reverse genetic tool. The targeted silencing SD-ARV1 transcripts by siRNA mediated RNAi resulted in a dramatic reduction of SD-ARV1 gene and protein expressions in S. digitata, which in turn modulated the parasitic motility, its production of eggs and microfilaria viability. Further, the same silencing caused severe phenotypic deformities such as distortion of eggs and embryonic development arrest in the intrauterine stages of adult female S. digitata. These results suggest that SD-ARV1 plays a pivotal role in worm embryogenesis, adult parasite motility and microfilariae viability. Finally, the ubiquitous presence of ARV1 in human filarial nematodes, its crucial functional roles in nematode biology and its remarkable diversity in primary protein structure compared to homologues in their hosts warrants further investigations to ascertain its candidacy in anthelmintic drug development.

Novel parasitic nematode-specific protein of Setaria digitata largely localized in longitudinal muscles, reproductive systems and developing embryos.

Parasitic nematodes may have common properties in parasitizing the host which are conferred by related parasitic proteins encoded by their genome. A novel protein characterized from bovine filarial nematode Setaria digitata was found to be present only in the parasitic nematodes and expressed at all the stages of the nematode's life. In immunohistochemical staining using polyclonal antibodies prepared against recombinant S. digitata protein, the highest expression of S. digitata novel protein (SDNP) was seen in the longitudinal muscles of the body wall of adult males and females indicating its possible involvement in parasite locomotion. Moderate expression was observed in the reproductive organs of both sexes while showing gradual increase in the expression as the development of the reproductive tissue progressed suggesting its role in tissue transformation in male and female reproduction. A low level of expression was observed in the cuticle, syncytial hypodermis region, lateral line and the intestinal wall. Further, the expression of SDNP was also seen in developing microfilaria within the uterus of female worms, developing spermatozoa of males and different developmental stages of embryos implicating its involvement in nematode growth and development. Subcellular localization of SDNP carried out in yeast, Pichia pastoris using green fluorescence construct revealed that this protein localized mainly in the nucleus and partly in the cytoplasm. Comprehensive bioinformatics analyses indicated that this protein contains a nuclear localization signal, RNAP_Rpb7_N_like domain, regions that are homologous to a part of the nuclear factor localization-like domain, interdomain linkers of muscle specific twitchin kinase of Caenorhabditis elegans and calcium-dependent protein kinase isoform CDPK1 of Arabidopsis thaliana. Therefore, considering all the outcomes together, it can be suggested that the SDNP is a parasitic nematode-specific, nuclear and cytoplasmic protein that is likely to be regulated by reversible phosphorylation-dephosphorylation reaction, expressed in all the stages of nematode's life having pivotal functional roles in muscle, reproductive systems, embryogenesis, and also in the growth and development.

Caspase dependent programmed cell death in developing embryos: a potential target for therapeutic intervention against pathogenic nematodes.

BACKGROUND: Successful embryogenesis is a critical rate limiting step for the survival and transmission of parasitic worms as well as pathology mediated by them. Hence, blockage of this important process through therapeutic induction of apoptosis in their embryonic stages offers promise for developing effective anti-parasitic measures against these extra cellular parasites. However, unlike in the case of protozoan parasites, induction of apoptosis as a therapeutic approach is yet to be explored against metazoan helminth parasites. METHODOLOGY/PRINCIPAL FINDINGS: For the first time, here we developed and evaluated flow cytometry based assays to assess several conserved features of apoptosis in developing embryos of a pathogenic filarial nematode Setaria digitata, in-vitro as well as ex-vivo. We validated programmed cell death in developing embryos by using immuno-fluorescence microscopy and scoring expression profile of nematode specific proteins related to apoptosis [e.g. CED-3, CED-4 and CED-9]. Mechanistically, apoptotic death of embryonic stages was found to be a caspase dependent phenomenon mediated primarily through induction of intracellular ROS. The apoptogenicity of some pharmacological compounds viz. DEC, Chloroquine, Primaquine and Curcumin were also evaluated. Curcumin was found to be the most effective pharmacological agent followed by Primaquine while Chloroquine displayed minimal effect and DEC had no demonstrable effect. Further, demonstration of induction of apoptosis in embryonic stages by lipid peroxidation products [molecules commonly associated with inflammatory responses in filarial disease] and demonstration of in-situ apoptosis of developing embryos in adult parasites in a natural bovine model of filariasis have offered a framework to understand anti-fecundity host immunity operational against parasitic helminths. CONCLUSIONS/SIGNIFICANCE: Our observations have revealed for the first time, that induction of apoptosis in developing embryos can be a potential approach for therapeutic intervention against pathogenic nematodes and flow cytometry can be used to address different issues of biological importance during embryogenesis of parasitic worms.