Environmental DNA shedding and decay rates from diverse animal forms and thermal regimes

Allan, Elizabeth Andruszkiewicz; Zhang, Weifeng G.; Lavery, Andone C.; Govindarajan, Annette F.

doi:10.1002/edn3.141

Cited by 140 publications

(155 citation statements)

References 85 publications

(93 reference statements)

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“…In summary, these results demonstrate how incorporating eRNA quantification into existing eDNA protocols can both increase detection probability by targeting highly concentrated rRNAs and improve interpretation of positive detections by modeling the ratio of eRNA:eDNA, or assessing detection of low abundant mitosisassociated mRNAs. The release and degradation relationships between genomic fragments found here might change due to physiological differences between life-histories 51 or between organisms 19 , and thus these genomic relationships should be investigated for other taxonomic groups. We found a significant decrease in the Ratio R:D over time, allowing us to predict the age of genomic material, and thus reduce error from legacy genomic signal.…”

Section: Discussionmentioning

confidence: 98%

“…The decay rates of the exponential decay models were estimated as dC′/dt = − kC′, where C′ = C t /C 0 was used to normalize eDNA/eRNA concentration. Previous decay studies have demonstrated biphasic eDNA decay 19,37 , and as such we analyze the log-linear decay rates over the initial 72-h. The decay rates were estimated by fitting a linear mixed-effect model with the values of log e (C t /C 0 ) as the response variable.…”

Section: Discussionmentioning

confidence: 99%

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Environmental (e)RNA advances the reliability of eDNA by predicting its age

Marshall

Vanderploeg

Chaganti

2021

Sci Rep

137

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Environmental DNA (eDNA) analysis has advanced conservation biology and biodiversity management. However, accurate estimation of age and origin of eDNA is complicated by particle transport and the presence of legacy genetic material, which can obscure accurate interpretation of eDNA detection and quantification. To understand the state of genomic material within the environment, we investigated the degradation relationships between (a) size of fragments (long vs short), (b) genomic origins (mitochondrial vs nuclear), (c) nucleic acids (eDNA vs eRNA), and (d) RNA types (messenger (m)RNA vs ribosomal (r)RNA) from non-indigenous Dreissena mussels. Initial concentrations of eRNA followed expected transcriptional trends, with rRNAs found at > 1000 × that of eDNA, and a mitosis-associated mRNA falling below detection limits within 24 h. Furthermore, the ratio of eRNA:eDNA significantly decreased throughout degradation, potentially providing an estimate for the age of genomic material. Thus, eRNA quantification can increase detection due to the high concentrations of rRNAs. Furthermore, it may improve interpretation of positive detections through the eRNA:eDNA ratio and/or by detecting low abundant mitosis-associated mRNAs that degrade within ~ 24 h.

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Section: Discussionmentioning

confidence: 98%

Section: Discussionmentioning

confidence: 99%

Environmental (e)RNA advances the reliability of eDNA by predicting its age

Marshall

Vanderploeg

Chaganti

2021

Sci Rep

137

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“…Instead, our findings strongly reinforce the conclusion that eDNA can discriminate communities at fine spatial scales as first established by Port et al 27 , even within habitats. Fish abundance estimated from eDNA data depends on several factors, including eDNA shedding, degradation and dispersion [45][46][47][48] . The persistence of eDNA can vary among aquatic organisms, but a growing body of evidence suggest that eDNA decay rates are faster in marine compared to freshwater environments and that once shed eDNA may only be detectable for hours to a few days [46][47][48] .…”

Section: Taxa Richnessmentioning

confidence: 99%

“…Fish abundance estimated from eDNA data depends on several factors, including eDNA shedding, degradation and dispersion [45][46][47][48] . The persistence of eDNA can vary among aquatic organisms, but a growing body of evidence suggest that eDNA decay rates are faster in marine compared to freshwater environments and that once shed eDNA may only be detectable for hours to a few days [46][47][48] . For instance, both Andruszkiewicz et al 47 and Collins et al 46 compiled previous findings on eDNA half-lives, showing they were relatively short in temperate marine environments, ranging from 6.9 h for the northern anchovy 45 to 63 h for the Maugean skate 49 .…”

Section: Taxa Richnessmentioning

confidence: 99%

“…The persistence of eDNA can vary among aquatic organisms, but a growing body of evidence suggest that eDNA decay rates are faster in marine compared to freshwater environments and that once shed eDNA may only be detectable for hours to a few days [46][47][48] . For instance, both Andruszkiewicz et al 47 and Collins et al 46 compiled previous findings on eDNA half-lives, showing they were relatively short in temperate marine environments, ranging from 6.9 h for the northern anchovy 45 to 63 h for the Maugean skate 49 . Another study found similar eDNA decay rates in anchovy, sardine, and mackerel, with first-order rate constants on the order of 10 −1 per hour 45 .…”

Section: Taxa Richnessmentioning

confidence: 99%

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Environmental DNA reveals the fine-grained and hierarchical spatial structure of kelp forest fish communities

Lamy

Pitz

Chávez

et al. 2021

Sci Rep

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Biodiversity is changing at an accelerating rate at both local and regional scales. Beta diversity, which quantifies species turnover between these two scales, is emerging as a key driver of ecosystem function that can inform spatial conservation. Yet measuring biodiversity remains a major challenge, especially in aquatic ecosystems. Decoding environmental DNA (eDNA) left behind by organisms offers the possibility of detecting species sans direct observation, a Rosetta Stone for biodiversity. While eDNA has proven useful to illuminate diversity in aquatic ecosystems, its utility for measuring beta diversity over spatial scales small enough to be relevant to conservation purposes is poorly known. Here we tested how eDNA performs relative to underwater visual census (UVC) to evaluate beta diversity of marine communities. We paired UVC with 12S eDNA metabarcoding and used a spatially structured hierarchical sampling design to assess key spatial metrics of fish communities on temperate rocky reefs in southern California. eDNA provided a more-detailed picture of the main sources of spatial variation in both taxonomic richness and community turnover, which primarily arose due to strong species filtering within and among rocky reefs. As expected, eDNA detected more taxa at the regional scale (69 vs. 38) which accumulated quickly with space and plateaued at only ~ 11 samples. Conversely, the discovery rate of new taxa was slower with no sign of saturation for UVC. Based on historical records in the region (2000–2018) we found that 6.9 times more UVC samples would be required to detect 50 taxa compared to eDNA. Our results show that eDNA metabarcoding can outperform diver counts to capture the spatial patterns in biodiversity at fine scales with less field effort and more power than traditional methods, supporting the notion that eDNA is a critical scientific tool for detecting biodiversity changes in aquatic ecosystems.

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Quantifying impacts of an environmental intervention using environmental DNA

Allan,

Kelly,

D'Agnese

et al. 2023

Ecological Applications

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Environmental laws around the world require some version of an environmental‐impact assessment surrounding construction projects and other discrete instances of human development. Information requirements for these assessments vary by jurisdiction, but nearly all require an analysis of the biological elements of ecosystems. Amplicon‐sequencing—also called metabarcoding—of environmental DNA (eDNA) has made it possible to sample and amplify the genetic material of many species present in those environments, providing a tractable, powerful, and increasingly common way of doing environmental‐impact analysis for development projects. Here, we analyze an 18‐month time series of water samples taken before, during, and after two culvert removals in a salmonid‐bearing freshwater stream. We also sampled multiple control streams to develop a robust background expectation against which to evaluate the impact of this discrete environmental intervention in the treatment stream. We generate calibrated, quantitative metabarcoding data from amplifying the 12s MiFish mtDNA locus and complementary species‐specific quantitative PCR data to yield multispecies estimates of absolute eDNA concentrations across time, creeks, and sampling stations. We then use a linear mixed effects model to reveal patterns of eDNA concentrations over time, and to estimate the effects of the culvert removal on salmonids in the treatment creek. We focus our analysis on four common salmonid species: cutthroat trout (Oncorhynchus clarkii), coho salmon (Oncorhynchus kisutch), rainbow trout (Oncorhynchus mykiss), and sockeye salmon (Oncorhynchus nerka). We find that one culvert in the treatment creek seemed to have no impact while the second culvert had a large impact on fish passage. The construction itself seemed to have only transient effects on salmonid species during the two construction events. In the context of billions of dollars of court‐mandated road culvert replacements taking place in Washington State, USA, our results suggest that culvert replacement can be conducted with only minimal impact of construction to key species of management concern. Furthermore, eDNA methods can be an effective and efficient approach for monitoring hundreds of culverts to prioritize culverts that are required to be replaced. More broadly, we demonstrate a rigorous, quantitative method for environmental‐impact reporting using eDNA that is widely applicable in environments worldwide.

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Environmental DNA shedding and decay rates from diverse animal forms and thermal regimes

Cited by 140 publications

References 85 publications

Environmental (e)RNA advances the reliability of eDNA by predicting its age

Environmental (e)RNA advances the reliability of eDNA by predicting its age

Environmental DNA reveals the fine-grained and hierarchical spatial structure of kelp forest fish communities

Quantifying impacts of an environmental intervention using environmental DNA

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