Attracting Common Carp to a bait site with food reveals strong positive relationships between fish density, feeding activity, environmental <scp>DNA</scp>, and sex pheromone release that could be used in invasive fish management

Ghosal, Ratna; Eichmiller, Jessica J.; Witthuhn, Bruce A.; Sorensen, Peter W.

doi:10.1002/ece3.4169

Cited by 37 publications

(55 citation statements)

References 57 publications

(95 reference statements)

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“…The activity variation of organisms may also influence the seasonal fluctuation of eDNA. eDNA emission increases by feeding [12,73] and reproduction [24,74,75], and is dependent on the lifestyle of the target species [69]. In the present study, the detection rate of eDNA was different between fish species having different lifestyles (e.g., Fig 2).…”

Section: Accuracy Of Estimating Biomass Of Marine Species By Ednamentioning

confidence: 47%

Comparing the efficiency of open and enclosed filtration systems in environmental DNA quantification for fish and jellyfish

et al. 2020

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Water sampling and filtration of environmental DNA (eDNA) analysis have been performed by several different methods, and each method may yield a different species composition or eDNA concentration. Here, we investigated the eDNA of seawater samples directly collected by SCUBA to compare two widely used filtration methods: open filtration with a glass filter (GF/F) and enclosed filtration (Sterivex). We referred to biomass based on visual observation data collected simultaneously to clarify the difference between organism groups. Water samples were collected at two points in the Sea of Japan in May, September and December 2018. The respective samples were filtered through GF/F and Sterivex for eDNA extraction. We quantified the eDNA concentration of five fish and two cnidarian species by quantitative polymerase chain reaction (qPCR) using species-specific primers/probe sets. A strong correlation of eDNA concentration was obtained between GF/F and Sterivex; the intercepts and slopes of the linear regression lines were slightly different in fish and jellyfish. The amount of eDNA detected using the GF/F filtration method was higher than that detected using Sterivex when the eDNA concentration was high; the opposite trend was observed when the eDNA concentration was relatively low. The concentration of eDNA correlated with visually estimated biomass; eDNA concentration per biomass in jellyfish was approximately 700 times greater than that in fish. We conclude that GF/F provides an advantage in collecting a large amount of eDNA, whereas Sterivex offers superior eDNA sensitivity. Both filtration methods are effective in estimating the spatiotemporal biomass size of target marine species.

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Section: Accuracy Of Estimating Biomass Of Marine Species By Ednamentioning

confidence: 47%

Comparing the efficiency of open and enclosed filtration systems in environmental DNA quantification for fish and jellyfish

et al. 2020

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“…Further studies are required to understand the quantitative effect and mechanisms of eDNA flow in lotic water (Seymour et al, 2018); however, our findings would support the use of quantitative eDNA analysis in lotic environments. In contrast, the use of eDNA for the quantification in the lake was not validated in this study, because the depth gradient makes counting fish by eye difficult and also because unpredictable water currents and eDNA diffusion may have made the eDNA analysis inaccurate, as stated above (Dunker et al, 2016;Eichmiller et al, 2014;Ghosal et al, 2018).…”

Section: Individual Counts By Visual Inspectionmentioning

confidence: 90%

“…In addition, the regression analysis showed a higher probability of visual detection in the river than in the lake by one order in eDNA concentration. Since the depth gradient makes visual detection difficult in the lake, and unpredictable water current and eDNA diffusion may have made eDNA analysis inaccurate in the lake (Dunker et al, ; Eichmiller, Bajer, & Sorensen, ; Ghosal, Eichmiller, Witthuhn, & Sorensen, ), this difference is not surprising. Researchers should pay attention to the unreliability of conventional data as well as to that of eDNA data (Chambert et al, ).…”

Section: Discussionmentioning

confidence: 99%

Environmental DNA analysis as a non‐invasive quantitative tool for reproductive migration of a threatened endemic fish in rivers

Maruyama

Sugatani

Watanabe

et al. 2018

Ecology and Evolution

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Quantitative information regarding reproduction is essential for conserving endangered animals; however, some conventional quantitative methods can be damaging to the target population and their habitats. In the present study, the reproductive migration of a threatened endemic fish, three‐lips (Opsariichthys uncirostris uncirostris), was non‐invasively monitored by quantitative PCR of species‐specific environmental DNA (eDNA), the usefulness of which has been not sufficiently explored. Water sampling and from‐shore visual inspection were performed weekly along a tributary of Lake Biwa (Japan), where adult fish seasonally migrate upstream to reproduce as well as at lake sites near the river mouth. Species‐specific eDNA was collected at all locations at times when the fish were visually observed and at certain sites where the fish were not observed. Log‐transformed individual counts from visual inspection were positively correlated with log‐transformed eDNA concentration in the river sites, indicating that eDNA analysis can be a reliable quantitative tool for fish abundance in rivers. Furthermore, distance from the lake did not influence eDNA concentration, suggesting that eDNA transport by river flow had a negligible effect on eDNA quantification. Both eDNA concentration and individual counts gradually increased from May–July, and decreased in August. Importantly, eDNA analysis showed that the fish occupied more habitats in the peak reproductive season and stayed for longer time at any given site. An additional underwater survey confirmed unexpected eDNA detections as true positives. eDNA analysis has great potential to quantitatively monitor reproductive fish migrations under certain conditions.

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“…When the water has low turbidity, number of samples is small, and portable pump has enough power to process samples, we recommend on-site filtration [36,49]. When sampling turbid water or the sample number is large, water samples should be transported back to the laboratory in a sterile bottle for filtration [50,51]. Additionally, we recommend water sample transport under dark conditions because ultraviolet (UV) light is damaging to DNA.…”

Section: Methods Of Edna Concentrationmentioning

confidence: 99%

Standards for Methods Utilizing Environmental DNA for Detection of Fish Species

Shu

Ludwig

Peng

2020

Genes

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Environmental DNA (eDNA) techniques are gaining attention as cost-effective, non-invasive strategies for acquiring information on fish and other aquatic organisms from water samples. Currently, eDNA approaches are used to detect specific fish species and determine fish community diversity. Various protocols used with eDNA methods for aquatic organism detection have been reported in different eDNA studies, but there are no general recommendations for fish detection. Herein, we reviewed 168 papers to supplement and highlight the key criteria for each step of eDNA technology in fish detection and provide general suggestions for eliminating detection errors. Although there is no unified recommendation for the application of diverse eDNA in detecting fish species, in most cases, 1 or 2 L surface water collection and eDNA capture on 0.7-μm glass fiber filters followed by extraction with a DNeasy Blood and Tissue Kit or PowerWater DNA Isolation Kit are useful for obtaining high-quality eDNA. Subsequently, species-specific quantitative polymerase chain reaction (qPCR) assays based on mitochondrial cytochrome b gene markers or eDNA metabarcoding based on both 12S and 16S rRNA markers via high-throughput sequencing can effectively detect target DNA or estimate species richness. Furthermore, detection errors can be minimized by mitigating contamination, negative control, PCR replication, and using multiple genetic markers. Our aim is to provide a useful strategy for fish eDNA technology that can be applied by researchers, advisors, and managers.

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Attracting Common Carp to a bait site with food reveals strong positive relationships between fish density, feeding activity, environmental DNA, and sex pheromone release that could be used in invasive fish management

Cited by 37 publications

References 57 publications

Comparing the efficiency of open and enclosed filtration systems in environmental DNA quantification for fish and jellyfish

Comparing the efficiency of open and enclosed filtration systems in environmental DNA quantification for fish and jellyfish

Environmental DNA analysis as a non‐invasive quantitative tool for reproductive migration of a threatened endemic fish in rivers

Standards for Methods Utilizing Environmental DNA for Detection of Fish Species

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