Towards understanding the liver fluke transmission dynamics on farms: Detection of liver fluke transmitting snail and liver fluke-specific environmental DNA in water samples from an irrigated dairy farm in Southeast Australia.

Livestock production around the world is impacted by liver fluke (Fasciola spp.) infection resulting in serious economic losses to the beef, dairy and sheep industries with significant losses of about $90 million per annum in Australia. Triclabendazole (TCBZ) is the most effective anthelmintic treatment available to control liver fluke infections; however, the widespread emergence of TCBZ resistance in livestock threatens liver fluke control. Alternative control measures to lower exposure of livestock to liver fluke infection would help to preserve the usefulness of current anthelmintic treatments. Environmental DNA (eDNA) based identification of liver fluke and the intermediate snail host in the water bodies is a robust method to assess the risk of liver fluke infection on farms. In this study, we used a multiplex quantitative PCR assay of water samples to detect and quantify eDNA of Fasciola hepatica (F. hepatica) and Austropeplea tomentosa (A. tomentosa), a crucial intermediate snail host for liver fluke transmission in South-east Australia. Water samples were collected from an irrigation channel for a period of 7 months in 2016 (February, March, May, September, October, November and December) at a dairy farm located at Maffra, Victoria, South-east Australia. Using an effective eDNA extraction method, the multiplex qPCR assay allows for the independent but simultaneous detection of eDNA released from liver fluke life stages and snails using specific primers and a probe targeting the ITS-2 region of the liver fluke and snail, respectively, with minimal inhibition from contaminants in field collected water samples. The sensitivity of this assay to detect eDNA of liver fluke and snails was observed to be 14 fg and 50 fg, respectively, in the presence of field collected water samples. Differential levels of liver fluke and snail specific eDNA in water were observed at the time points analysed in this study. The successful detection of eDNA specific to liver fluke and snails from the field collected water samples provides a precedent for the use of this method as a monitoring tool to determine the prevalence of liver fluke and liver fluke-transmitting snails in irrigation regions. Further, this method has the enormous potential to allow an assessment of the liver fluke transmission zones on farms and to inform the application of effective control strategies.

[1]  C. Adams,et al.  A Brief Review of Non-Avian Reptile Environmental DNA (eDNA), with a Case Study of Painted Turtle (Chrysemys picta) eDNA Under Field Conditions , 2019, Diversity.

[2]  T. Beddoe,et al.  Development of a multiplex quantitative PCR assay for detection and quantification of DNA from Fasciola hepatica and the intermediate snail host, Austropeplea tomentosa, in water samples. , 2018, Veterinary parasitology.

[3]  Mark A. Davis,et al.  Evaluation of environmental DNA to detect Sistrurus catenatus and Ophidiomyces ophiodiicola in crayfish burrows , 2018, Conservation Genetics Resources.

[4]  Chelsea N. Davis,et al.  Detection of Galba truncatula, Fasciola hepatica and Calicophoron daubneyi environmental DNA within water sources on pasture land, a future tool for fluke control? , 2018, Parasites & Vectors.

[5]  T. Beddoe,et al.  A novel ex vivo immunoproteomic approach characterising Fasciola hepatica tegumental antigens identified using immune antibody from resistant sheep. , 2017, International journal for parasitology.

[6]  Megumi Sato,et al.  Application of environmental DNA analysis for the detection of Opisthorchis viverrini DNA in water samples. , 2017, Acta tropica.

[7]  L. Waits,et al.  Critical considerations for the application of environmental DNA methods to detect aquatic species , 2016 .

[8]  Lauren M. Sassoubre,et al.  Quantification of Environmental DNA (eDNA) Shedding and Decay Rates for Three Marine Fish. , 2016, Environmental science & technology.

[9]  T. Beddoe,et al.  Current Threat of Triclabendazole Resistance in Fasciola hepatica. , 2016, Trends in parasitology.

[10]  D. Lodge,et al.  Estimating species richness using environmental DNA , 2016, Ecology and evolution.

[11]  D. Serre,et al.  In silico assessment of primers for eDNA studies using PrimerTree and application to characterize the biodiversity surrounding the Cuyahoga River , 2016, Scientific Reports.

[12]  M. Nyindo,et al.  Fascioliasis: An Ongoing Zoonotic Trematode Infection , 2015, BioMed research international.

[13]  S. Whyard,et al.  Development and application of an eDNA method to detect and quantify a pathogenic parasite in aquatic ecosystems. , 2015, Ecological applications : a publication of the Ecological Society of America.

[14]  T. Spithill,et al.  High prevalence of fasciolosis and evaluation of drug efficacy against Fasciola hepatica in dairy cattle in the Maffra and Bairnsdale districts of Gippsland, Victoria, Australia. , 2015, Veterinary parasitology.

[15]  H. Toet,et al.  Liver fluke vaccines in ruminants: strategies, progress and future opportunities. , 2014, International journal for parasitology.

[16]  Helen C. Rees,et al.  REVIEW: The detection of aquatic animal species using environmental DNA – a review of eDNA as a survey tool in ecology , 2014 .

[17]  A. Piaggio,et al.  Detecting an elusive invasive species: a diagnostic PCR to detect Burmese python in Florida waters and an assessment of persistence of environmental DNA , 2014, Molecular ecology resources.

[18]  B. Losson,et al.  Morphological and Molecular Characterization of Lymnaeid Snails and Their Potential Role in Transmission of Fasciola spp. in Vietnam , 2013, The Korean journal of parasitology.

[19]  Adam J. Sepulveda,et al.  Environmental DNA as a new method for early detection of New Zealand mudsnails (Potamopyrgus antipodarum) , 2013, Freshwater Science.

[20]  Robert S. Arkle,et al.  Estimating occupancy and abundance of stream amphibians using environmental DNA from filtered water samples , 2013 .

[21]  C. Wiuf,et al.  Monitoring endangered freshwater biodiversity using environmental DNA. , 2012, Molecular ecology.

[22]  Z. Kawabata,et al.  Estimation of Fish Biomass Using Environmental DNA , 2012, PloS one.

[23]  T. Ren,et al.  Radiological Imaging Features of Fasciola hepatica Infection – A Pictorial Review , 2012, Journal of clinical imaging science.

[24]  J. Escobar,et al.  Morphological and molecular characterization of Neotropic Lymnaeidae (Gastropoda: Lymnaeoidea), vectors of fasciolosis. , 2011, Infection, genetics and evolution : journal of molecular epidemiology and evolutionary genetics in infectious diseases.

[25]  I. Fairweather Reducing the future threat from (liver) fluke: realistic prospect or quixotic fantasy? , 2011, Veterinary parasitology.

[26]  P. David,et al.  Bridging gaps in the molecular phylogeny of the Lymnaeidae (Gastropoda: Pulmonata), vectors of Fascioliasis , 2010, BMC Evolutionary Biology.

[27]  W. Ponder,et al.  Examining the phylogeny of the Australasian Lymnaeidae (Heterobranchia: Pulmonata: Gastropoda) using mitochondrial, nuclear and morphological markers. , 2009, Molecular phylogenetics and evolution.

[28]  S. Mas‐Coma,et al.  Climate change effects on trematodiases, with emphasis on zoonotic fascioliasis and schistosomiasis. , 2009, Veterinary parasitology.

[29]  I. Fairweather Triclabendazole progress report, 2005–2009: an advancement of learning? , 2009, Journal of Helminthology.

[30]  Peter J Hotez,et al.  Helminth infections: the great neglected tropical diseases. , 2008, The Journal of clinical investigation.

[31]  G. Anderson,et al.  The distribution of Fasciola hepatica in Queensland, Australia, and the potential impact of introduced snail intermediate hosts. , 2006, Veterinary parasitology.

[32]  J. Jokela,et al.  Tracing the quagga mussel invasion along the Rhine river system using eDNA markers: early detection and surveillance of invasive zebra and quagga mussels , 2017 .

[33]  J. Sheen,et al.  DNA purification from multiple sources in plant research with homemade silica resins. , 2012, Methods in molecular biology.

[34]  S. Mas‐Coma,et al.  Chapter 2. Fasciola, lymnaeids and human fascioliasis, with a global overview on disease transmission, epidemiology, evolutionary genetics, molecular epidemiology and control. , 2009, Advances in parasitology.

[35]  R. de Wachter,et al.  Extraction of high molecular weight DNA from molluscs. , 2002 .

[36]  J. Boray Experimental fascioliasis in Australia. , 1969, Advances in parasitology.