Monitoring a Norwegian freshwater crayfish tragedy: <scp>eDNA</scp> snapshots of invasion, infection and extinction

Strand, David; Johnsen, Stein Ivar; Rusch, Johannes C.; Agersnap, Sune; Larsen, William Brenner; Knudsen, Steen Wilhelm; Møller, Peter Rask; Vrålstad, Trude

doi:10.1111/1365-2664.13404

Cited by 55 publications

(69 citation statements)

References 35 publications

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“…Environmental DNA (eDNA), which is shed by all living organisms in the environment, is increasingly used for the detection of elusive or low abundant species and has been shown to be equally or more sensitive than traditional surveying methods [6, 7]. So far, the majority of developed eDNA single species detection methods have primarily focused on aquatic animals including mammalians [8, 9], fish [8, 10–17] Molluscs [18, 19], crustacea [20–22], amphibians [23, 24] reptiles [25–27] and insects [28–30]. Detection of aquatic plant eDNA has been scarce in comparison [31].…”

Section: Introductionmentioning

confidence: 99%

Detection of an invasive aquatic plant in natural water bodies using environmental DNA

et al. 2019

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The ability to detect founding populations of invasive species or rare species with low number of individuals is important for aquatic ecosystem management. Traditional approaches use historical data, knowledge of the species’ ecology and time-consuming surveys. Within the past decade, environmental DNA (eDNA) has emerged as a powerful additional tracking tool. While much work has been done with animals, comparatively very little has been done with aquatic plants. Here we investigated the transportation and seasonal changes in eDNA concentrations for an invasive aquatic species, Elodea canadensis , in Norway. A specific probe assay was developed using chloroplast DNA to study the fate of the targeted eDNA through space and time. The spatial study used a known source of Elodea canadensis within Lake Nordbytjern 400 m away from the lake outlet flowing into the stream Tveia. The rate of disappearance of E . canadensis eDNA was an order of magnitude loss over about 230 m in the lake and 1550 m in the stream. The time series study was performed monthly from May to October in lake Steinsfjorden harbouring E . canadensis , showing that eDNA concentrations varied by up to three orders of magnitude, peaking during fall. In both studies, the presence of suspended clay or turbidity for some samples did not hamper eDNA analysis. This study shows how efficient eDNA tools may be for tracking aquatic plants in the environment and provides key spatial and temporal information on the fate of eDNA.

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Section: Introductionmentioning

confidence: 99%

Detection of an invasive aquatic plant in natural water bodies using environmental DNA

et al. 2019

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“…It is thus clear that no massive sporulation occurred in the experimental tanks at or shortly before the time of filtration (24 and 48 hr after the excrement addition). Detection of very low amounts of A. astaci spores would nevertheless require filtering of substantially higher water volumes (as used in recent studies focusing on detection of this pathogen from environmental DNA; e.g., Strand et al, , ; Wittwer et al, ).…”

Section: Discussionmentioning

confidence: 99%

“…Crayfish plague caused by the oomycete Aphanomyces astaci Schikora is undoubtedly the most serious disease of crayfish (Diéguez‐Uribeondo et al, ), which drastically reduced European populations of these crustaceans in the 19th and early 20th century (Alderman, ). Although latent infections with the crayfish plague pathogen have been recently reported from various populations of several European indigenous crayfish species (see review in Svoboda, Mrugała, Kozubíková‐Balcarová, & Petrusek, ), mass mortalities caused by the pathogen are still widespread across Europe (e.g., Caprioli et al, , ; Filipová, Petrusek, Matasová, Delaunay, & Grandjean, ; Kozubíková‐Balcarová et al, ; Strand et al, ; Viljamaa‐Dirks et al, ), and crayfish plague is considered responsible for recent steep declines of native crayfish in various countries (Holdich, Reynolds, Souty‐Grosset, & Sibley, ). Furthermore, the presence of A. astaci has also been recently reported from crayfish populations introduced to Japan, Brazil, Indonesia and Madagascar (Andriantsoa et al, ; Martín‐Torrijos et al, ; Mrugała, Kawai, Kozubíková‐Balcarová, & Petrusek, ; Peiró et al, ; Putra et al, ), indicating a potential threat to crayfish species native to those regions.…”

Section: Introductionmentioning

confidence: 99%

Experimental evaluation of the potential for crayfish plague transmission through the digestive system of warm‐blooded predators

Svobodá

Fischer

Kozubíková‐Balcarová

et al. 2019

Journal of Fish Diseases

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The crayfish plague pathogen (Aphanomyces astaci) can be transmitted through the digestive system of fish, but its dispersal through mammalian and bird digestive tracts has been considered unlikely, and direct experimental evidence remains scarce. We present a small‐scale transmission experiment with European otter and American mink fed with infected crayfish, and experiments testing survival of cultures of five A. astaci strains at temperatures corresponding to those inside mammal and bird bodies. The pathogen was neither isolated from predator excrements nor transmitted to susceptible crayfish exposed to excrements. In agar‐based artificial media, it occasionally survived for 15 min at 40.5°C and for 45 min at 37.5°C, but not so when incubated at those temperatures for 45 min and 75 min, respectively. The five tested strains differed in resistance to high temperatures, two (of genotype groups E and D) being more susceptible than other three (of groups A, B and D). Their survival to some extent varied when exposed to the same temperature after several weeks or months, suggesting that some yet‐unknown factors may influence A. astaci resistance to temperature stress. Overall, we support the notion that passage through the digestive tract of warm‐blooded predators makes A. astaci transmission unlikely.

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“…Consequently, accurate, sensitive, non-invasive techniques are required to detect and monitor pathogens and pathogenic vectors outside of host systems 45,86 . eDNA approaches have been shown to detect aquatic pathogens earlier than traditional methods and provide advanced warning of infection and mass mortality events 40,45 . Recently, Ranaviruses, have been detected by eDNA analysis in environmental water samples from susceptible host species habitats, and demonstrated a strong relationship between environmentally-shed viral load and host tissue viral load 45 .…”

Section: Mechanisms Of Viral Exposurementioning

confidence: 99%

“…Environmental DNA is a forensics approach to the extraction and identification of organismal DNA fragments (genetic material) released into the environment and is a rapidly advancing, non-invasive approach capable of improving endangered species detection and early pathogen detection [35][36][37][38][39][40][41][42][43] . Environmental samples can be analyzed for micro-and macro-organisms by several eDNA methods including metabarcoding and species-specific quantitative PCR (qPCR) 38,40,44 . The development of a rapid and high throughput sampling scheme to detect virus shedding into the marine environment would benefit pathogen surveillance efforts, and consequently the performance of wildlife health status monitoring could be improved 31,45 .…”

Section: Introductionmentioning

confidence: 99%

Mutational, transcriptional and viral shedding dynamics of the marine turtle fibropapillomatosis tumor epizootic

Yetsko

Farrell

Stammnitz

et al. 2020

Preprint

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Sea turtle populations are directly and indirectly under threat from a range of anthropogenic processes. Perhaps the most visibly apparent of these is the disfiguring tumor disease epizootic (animal epidemic) known as fibropapillomatosis. Fibropapillomatosis continues to spread geographically, with prevalence of the disease also growing at a number of affected sites globally. Environmental exposures seem key to inducing tumor development, possibly through weakening host immune systems to the point of enabling pathogen-induced tumor formation. However, we do not yet understand the precise molecular and mutational events driving fibropapillomatosis tumor formation and progression. Similarly, many open questions remain about the role of the herpesvirus (chelonid herpesvirus 5, ChHV5) associated with the disease as a potential co-trigger, and whether its occurrence within tumors is causative or opportunistic. Without improved understanding of the basic biology of this disease epizootic, treatment, containment and mitigation options are severely hampered.To address fundamental questions relating to the oncogenic signaling, mutational spectrum, viral load, viral transcriptional status (lytic or latent) and spread, we employed transcriptomic profiling, whole genome sequencing, immunohistochemistry and environmental (e)DNAbased monitoring of viral shedding. In particular we focused on the mutational landscape of tumors and assessing the transcriptional similarity of external (skin) and internal (visceral organs) tumors, and the oncogenic signaling events driving early stage tumor growth and post-surgical tumor regrowth. These analyses revealed that internal fibropapillomatosis tumors are molecularly distinct from the more common external tumors. However, our molecular analyses also revealed that there are a small number of conserved potentially therapeutically targetable molecular vulnerabilities in common between internal and external tumors, such as the MAPK, Wnt, TGFβ and TNF oncogenic signaling pathways. We also determined that the tumor genomes can harbor copy number gains, indicating potentially viral-independent oncogenic processes. Genes within such mutated genomic regions have known roles in human skin cancer, including MAPK-associated genes. Turtles attempt to mount an immune response, but in some animals this appears to be insufficient to prevent tumor development and growth. ChHV5 was transcriptionally latent in all tumor stages sequenced, including early stage and recurrent tumors. We also revealed that the tumors themselves are the primary source of viral shedding into the marine environment and, if they are surgically removed, the level of ChHV5 in the water column drops.Together, these results offer an improved understanding of fibropapillomatosis tumorigenesis and provide insights into the origins, therapeutic treatment, and appropriate quarantine responses for this wildlife epizootic. Furthermore, they provide insights into human pathogen-induced cancers, particularly mechanisms which are difficult to s...

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Monitoring a Norwegian freshwater crayfish tragedy: eDNA snapshots of invasion, infection and extinction

Cited by 55 publications

References 35 publications

Detection of an invasive aquatic plant in natural water bodies using environmental DNA

Detection of an invasive aquatic plant in natural water bodies using environmental DNA

Experimental evaluation of the potential for crayfish plague transmission through the digestive system of warm‐blooded predators

Mutational, transcriptional and viral shedding dynamics of the marine turtle fibropapillomatosis tumor epizootic

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