Living quarters of a living fossil—Uncovering the current distribution pattern of the rediscovered Hula painted frog (<i>Latonia nigriventer</i>) using environmental <scp>DNA</scp>

Renan, Sharon; Gafny, Sarig; Perl, R. G. Bina; Malka, Yoram; Vences, Miguel

doi:10.1111/mec.14420

Cited by 20 publications

(23 citation statements)

References 56 publications

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“…eDNA techniques are theoretically capable of detecting even a single copy of target DNA (Jerde et al 2011), so the potential applications of eDNA techniques are substantial (Goldberg et al 2016). Such methods have been used to detect rare and endangered freshwater species whose presence cannot be confirmed easily by more conventional means (Laramie et al 2015, Sigsgaard et al 2015, Eva et al 2016, Renan et al 2017), and to monitor the colonization of new habitat by invasive species (Jerde et al 2013, Nathan et al 2014, Rees et al 2014). The high sensitivity of eDNA, relative to more traditional survey methods (Goldberg et al 2013, Takahara et al 2013), has contributed to its increasing prevalence as a research tool (Goldberg et al 2016).…”

Section: Introductionmentioning

confidence: 99%

Pitfalls during in silico prediction of primer specificity for eDNA surveillance

Fong²,

Lam³

et al. 2020

Ecosphere

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While high efficiency and cost‐effectiveness are two merits of environmental DNA (eDNA) techniques for detecting aquatic organisms, the difficulty of designing species‐specific primers can result in significant expenditure of time and money. During the in silico stage of primer development, primer specificity is predicted with alignment techniques such as BLAST that is based on the number and position of the primer/nontarget template mismatches. However, we speculate that nonspecific amplification is influenced by additional parameters, which lead to inaccuracies of in silico prediction. We performed in vitro specificity tests for 38 species‐specific primers selected for seven fishes and six turtles, using single‐plex conventional PCR (cPCR). A subset of 12 primer pairs were further tested with SYBR Green‐based or TaqMan‐based single‐plex quantitative PCR (qPCR). We disentangle the relative importance of mismatch properties (types and positions), primer properties (length, GC content, and 3′ end stability), PCR conditions (template concentrations and annealing temperatures), and PCR technique (cPCR, TaqMan‐based, or SYBR Green‐based qPCR) in determining the occurrence of amplifications. We then compared the PCR outcomes with the specificity check under two stringency scenarios based on alignment (i.e., BLAST search). We conducted a total of 679 cPCR and 226 qPCR analyses, with 90% of the reactions tested with nontarget templates. Primer pairs predicted by Primer‐BLAST to be specific rarely showed such specificity during the in vitro testing. BLAST searches correctly predicted the outcomes of around 67% of cPCR and qPCR, but had low sensitivity in detection of nontarget amplification (29–57%). Primer specificity increased significantly with total number of mismatches and annealing temperature, but decreased with higher GC content in the primer sequence. Mismatches that consisted of A‐A, G‐A, and C‐C pairings exerted 56% stronger reduction in nonspecific amplification effects than other mismatches. To conclude, we show that the prediction of primer specificity based only on the number and position of mismatches can be misleading. Our findings can be applied to increase the efficiency of the in silico primer selection process to maintain the relatively high efficiency and cost‐effectiveness of eDNA techniques.

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Section: Introductionmentioning

confidence: 99%

Pitfalls during in silico prediction of primer specificity for eDNA surveillance

Fong²,

Lam³

et al. 2020

Ecosphere

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“…While direct observations of E. irwini are needed to gather data on population size, age classes and female-male ratios (required for listing the species and developing management actions to protect the species), eDNA analysis provides valuable information on population distribution and potential changes over time. Environmental DNA has been suggested as the only efficient tool for rare and cryptic species detection [ 49 ]. In the case of E. irwini in the Burdekin River, we propose eDNA sampling as the most pragmatic detection method due to high water turbidity, the presence of crocodiles and the inability to reliably attract these turtles to traps.…”

Section: Discussionmentioning

confidence: 99%

Environmental DNA analysis confirms extant populations of the cryptic Irwin’s turtle within its historical range

et al. 2022

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Background Approximately 50% of freshwater turtles worldwide are currently threatened by habitat loss, rural development and altered stream flows. Paradoxically, reptiles are understudied organisms, with many species lacking basic geographic distribution and abundance data. The iconic Irwin’s turtle, Elseya irwini, belongs to a unique group of Australian endemic freshwater turtles capable of cloacal respiration. Water resource development, increased presence of saltwater crocodiles and its cryptic behaviour, have made sampling for Irwin’s turtle in parts of its range problematic, resulting in no confirmed detections across much of its known range for > 25 years. Here, we used environmental DNA (eDNA) analysis for E. irwini detection along its historical and contemporary distribution in the Burdekin, Bowen and Broken River catchments and tributaries. Five replicate water samples were collected at 37 sites across those three river catchments. Environmental DNA was extracted using a glycogen-aided precipitation method and screened for the presence of E. irwini through an eDNA assay targeting a 127 base pair-long fragment of the NADH dehydrogenase 4 (ND4) mitochondrial gene. Results Elseya irwini eDNA was detected at sites within its historic distribution in the lower Burdekin River, where the species had not been formally recorded for > 25 years, indicating the species still inhabits the lower Burdekin area. We also found higher levels of E. iriwni eDNA within its contemporary distribution in the Bowen and Broken Rivers, matching the prevailing scientific view that these areas host larger populations of E. irwini. Conclusions This study constitutes the first scientific evidence of E. irwini presence in the lower Burdekin since the original type specimens were collected as part of its formal description, shortly after the construction of the Burdekin Falls Dam. From the higher percentage of positive detections in the upper reaches of the Broken River (Urannah Creek), we conclude that this area constitutes the core habitat area for the species. Our field protocol comprises a user-friendly, time-effective sampling method. Finally, due to safety risks associated with traditional turtle sampling methods in the Burdekin River (e.g., estuarine crocodiles) we propose eDNA sampling as the most pragmatic detection method available for E. irwini.

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“…Suspended cells or other eDNA-containing particles are often concentrated on polycarbonate or glass fiber filters[14,33,34], which offer practical advantages over eDNA extraction from sediment. However, direct filtration at all sites was unfeasible in this study due to surface waters either being non-existent or extremely rich in organics which clogged filters almost immediately.…”

Section: Discussionmentioning

confidence: 99%

“…DNA is known to rapidly diffuse from the source in aquatic systems and, where flux is relatively high in streams or rivulets, DNA is transported out of the system relatively quickly[34]. Furthermore, most eDNA-containing particles including skin cells settle out of slow-moving water into the sediment[33] where eDNA has been shown to persist longer than in surface water[35]. Our findings suggest that these dynamics may also be controlling the fate, transport, and storage of eDNA in bogs where eDNA is stored mostly in sediment in or near hibernacula and a targeted sampling approach incorporating prior knowledge of the site as well as animal behavior may lead to higher detection rates.…”

Section: Discussionmentioning

confidence: 99%

Development and validation of rapid environmental DNA (eDNA) detection methods for bog turtle (Glyptemys muhlenbergii)

2019

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Bog turtles (Glyptemys muhlenbergii) are listed as Species of Greatest Conservation Need (SGCN) for wildlife action plans in every state it occurs and multi-state efforts are underway to better characterize extant populations and prioritize restoration efforts. However, traditional sampling methods can be ineffective due to the turtle’s wetland habitat, small size, and burrowing nature. Molecular methods, such as qPCR, provide the ability to overcome this challenge by effectively quantifying minute amounts of turtle DNA left behind in its environment (eDNA). Developing such methods for bog turtles has proved difficult partly because of the high sequence similarity between bog turtles and closely-related, cohabitating species, most often wood turtles (Glyptemys insculpta). Additionally, substrates containing bog turtle eDNA are often rich in organics or other substances that frequently inhibit both DNA extraction and qPCR amplification. Here, we describe the development and validation of a qPCR assay, BT3, targeting the mitochondrial cytochrome oxidase I gene that correctly identifies bog turtles with 100% specificity and sensitivity when tested on 201 blood samples collected from six species over a wide geographic range. We also developed a full-process internal control employing a genetically modified strain of Caenorhabditis elegans to improve DNA extraction methods, limit false negative results due to qPCR inhibition, and measure total DNA recovery from each sample. Using the internal control, we found that DNA recovery varied by over an order of magnitude between samples and likely explains the lack of bog turtle detection in some cases. Methods presented herein are highly-specific and may offer a more cost effective, non-invasive tool to supplement bog turtle population assessments in the Eastern United States. Poor or differential DNA recovery, which remains unmeasured in the vast majority of eDNA studies, significantly reduced the ability to detect bog turtle in their natural environment.

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Living quarters of a living fossil—Uncovering the current distribution pattern of the rediscovered Hula painted frog (Latonia nigriventer) using environmental DNA

Cited by 20 publications

References 56 publications

Pitfalls during in silico prediction of primer specificity for eDNA surveillance

Pitfalls during in silico prediction of primer specificity for eDNA surveillance

Environmental DNA analysis confirms extant populations of the cryptic Irwin’s turtle within its historical range

Development and validation of rapid environmental DNA (eDNA) detection methods for bog turtle (Glyptemys muhlenbergii)

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