Browsing by Author "Wickramatunga, P.G.T.S."

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An ARV1 homologue from a filarial nematode is functional in yeast
(London School Of Hygiene And Tropical Medicine, 2019) Herath, H.M.L.P.B.; Gunawardene, Y.I.N.S.; Pathiranage, M.; Wickramasinghe, P.D.S.U.; Wickramatunga, P.G.T.S.; Dassanayake, R.S.
The transmembrane protein, ARV1, plays a key role in intracellular sterol homeostasis by controlling sterol distribution and cellular uptake. To date, only the ARV1s from yeast and humans have been characterized to some extent. In this study, the ARV1 of an animal filarial parasite, Setaria digitata (SdARV1), was characterized; its cDNA was 761 bp and encoded a protein of 217 amino acids, with a predicted molecular weight of 25 kDa, containing a highly conserved ARV1 homology domain and three transmembrane domains in the bioinformatic analyses. Information required to cluster members belonging to a particular taxon has been revealed in phylogenetic analyses of ARV1 sequences derived from different organisms. Reverse transcription-polymerase chain reaction (RT-PCR) analyses indicated that SdARV1 was expressed in different developmental stages - microfilariae and adult male and female worms. Experiments carried out with a single copy of the SdARV1 under the control of the PMA-1 promoter in a temperature-sensitive Saccharomyces cerevisiae mutant strain indicated full complementation of the mutant phenotype, with growth at a non-permissive temperature (37°C). Microscopic observations of cellular morphology with Gram staining revealed alteration of the shape from shrunken to oval, in mutant and complemented strains, respectively. Assessment of free sterol levels extracted from mutant yeast and complemented strains indicated that the level of sterol was significantly higher in the former compared to the latter, which had sterol levels similar to those of the wild type. Thus, the results of the current study suggest that SdARV1 is ubiquitously expressed in different developmental stages of S. digitata, and that it is a true functional homologue of mammalian and yeast ARV1s, which have crucial phylogenetic information that follows classical evolutionary trends. Finally, this is the first study to report the biological function of nematode ARV1.
Genome organization, in-silico structure, and cellular localization of putative lipid transporter, ARV1 from parasitic nematode Setaria digitata
(Elsevier Inc., 2022) Wickramatunga, P.G.T.S.; Gunawardene, Y.I.N.S.; Chandrasekharan, N.V.; Dassanayake, R.S.
Setaria digitata, a nematode that lives in the peritoneal cavity of ruminants is the causative agent of cerebrospinal nematodiasis affecting livestock health. The ‘ACAT related enzyme 2 required for viability 1’ (arv-1) gene encodes putative lipid transporter that is essential in eukaryotes. The molecular characterization of nematode arv-1 has scarcely been studied and putative arv-1 isolated from S. digitata was used for this purpose. Docking and computer simulation studies using a modeled 3D structure of S. digitata ARV1 (Sd-ARV-1) with ceramide ligands revealed that the amino acid residues, Ile182, Leu56, Ala61, Gln186 and Gln146 are likely involved in the formation of potential sphingolipid binding sites having the same conserved residues in other nematodes. Sd-arv-1, a single copy gene, genomic region (1676 bp) had five exons encoding 217 amino acids, being interspersed by four introns showing a similar gene organization to other nematodes. Sd-ARV-1 is expressed ubiquitously at all development stages of the S. digitata life cycle. Tissue localization analyses revealed that Sd-ARV-1 was significantly expressed in the longitudinal muscle layer, endodermis, uterine wall, eggs, growing embryos inside the uterus, microfilariae, intestinal wall, esophagus lumen, dorsal nerve cord and ventral nerve cord. Therefore, ARV1 is a structurally conserved, ubiquitously expressed protein, which may be involved in development, reproduction, tissue remodeling, muscle contraction etc., in nematodes.
RNAi-mediated silencing of ARV1 in Setaria digitata impairs in-vitro microfilariae release, embryogenesis and adult parasite viability
(Elsevier Scientific Pub. Co., 2020) Wickramatunga, P.G.T.S.; Gunawardene, Y.I.N.S.; Wijesinghe, K.J.; Ellepola, A.N.B.; Dassanayake, R.S.
ABSTRACT: 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. KEYWORDS: ARV1; Morphological deformities; RNA interference; Setaria digitata.