Decision making and best practices for taxonomy-free eDNA metabarcoding in biomonitoring using Hill numbers

Mächler, Elvira; Walser, Jean‐Claude; Altermatt, Florian

doi:10.1101/2020.03.31.017723

Cited by 10 publications

(9 citation statements)

References 64 publications

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“…The lack of a significant result for the non-curated COI dataset indicates the importance of adapting bioinformatics parameters for reliable species diversity estimation (Brandt et al 2020). While we note that estimating species richness is very sensitive to bioinformatics strategy (Froslev et al 2017;Calderón-Sanou et al 2020), the similar community structure resolved with our LULU-curated datasets demonstrates a robust metric in spite of current limitations in DNA metabarcoding (Brandt et al 2020;Mächler et al 2020).…”

Section: Coi Dna Metabarcodingmentioning

confidence: 62%

DNA metabarcoding captures subtle differences in forest beetle communities following disturbance

Liu

Baker

Burridge

et al. 2020

Restoration Ecology

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DNA metabarcoding is an emerging approach for monitoring biodiversity, but uncertainties remain about its capacity to detect subtle differences in invertebrate community composition comparable to those achievable based on conventional morphological identification. In this study, DNA metabarcoding and morphology-based approaches were compared as tools for investigating whether logging history impacted beetle communities in Tasmanian wet eucalypt forests. We compared 12 unlogged mature forest sites with 12 neighboring regeneration sites that had been logged approximately 55 years previously. The number of species identified based on morphology (173) was close to the number of zero-radius operational taxonomic units (ZOTUs) identified by DNA metabarcoding of cytochrome c oxidase subunit I (COI, 176) and 16S ribosomal RNA (16S, 156) markers. Subtle but significant differences in beetle species composition between regeneration and unlogged mature forests were captured by both morphology-based and COI DNA metabarcoding approaches, but not by 16S DNA metabarcoding. Our results support the suitability of mitochondrial COI for studying invertebrate biodiversity. A slight loss of signal compared to the morphology-based approach may be resolved by developing more comprehensive DNA reference databases. While confirming forest recovery of 48-58 years did not fully restore mature forest beetle communities, we suggest that DNA metabarcoding can be used for monitoring biodiversity and probing subtle differences in community composition.

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Section: Coi Dna Metabarcodingmentioning

confidence: 62%

DNA metabarcoding captures subtle differences in forest beetle communities following disturbance

Liu

Baker

Burridge

et al. 2020

Restoration Ecology

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show abstract

“…Collecting more samples at fixed downstream locations would also be beneficial because, due to a dilution effect, eDNA concentrations at the downstream sites are likely not high even in the presence of a local taxon hotspot (see Figure 3), and hence more prone to result in non‐detections. This is especially important in the context of many metabarcoding studies setting thresholds of read numbers below which the signal is no longer accepted as a true positive (Deiner et al., 2017; Mächler, Walser, & Altermatt, 2020). In this perspective, collecting larger water volumes at the downstream sites is likely to help minimize the risk of non‐detection.…”

Section: Discussionmentioning

confidence: 99%

How to design optimal eDNA sampling strategies for biomonitoring in river networks

2020

Self Cite

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The current biodiversity crisis calls for appropriate methods for assessing biodiversity. In this respect, environmental DNA (eDNA) holds great promise, especially for aquatic ecosystems. While initial eDNA studies assessed biodiversity at single sites, technology now allows analyzing samples from many points simultaneously. However, the selection of these sites has been mostly motivated on an ad‐hoc basis. To this end, hydrology‐based models might offer a unique guidance on where to sample eDNA to most effectively reconstruct spatial patterns of biodiversity. Here, we performed computer simulations to identify best‐practice criteria for the choice of positioning of eDNA sampling sites in river networks. To do so, we combined a hydrology‐based eDNA transport model with a virtual river network reproducing the scaling features of real rivers. In particular, we conducted simulations investigating scenarios of different number and location of eDNA sampling sites in a riverine network, different spatial taxon distributions, and different eDNA measurement errors. We found that, due to hydrological controls, non‐uniform patterns of eDNA concentration arise even if the taxon distribution is uniform and decay is neglected. Best practices for sampling site selection depend on the taxon's spatial distribution: when taxa are concentrated in some hotspots and only few sampling sites can be placed, it is better to preferentially locate them in the downstream part of the catchment; when taxa are more evenly distributed, and/or many sites can be placed, these should be preferentially located upstream. We also found that uncertainties in eDNA concentration estimates do not necessarily hamper model predictions. Knowledge of eDNA decay rates improves model predictions, highlighting the need for empirical estimates of these rates under relevant environmental conditions. Our simulations help define strategies for designing eDNA sampling campaigns in river networks and can guide the sampling effort of field ecologists and environmental authorities.

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“…Collecting more samples at fixed downstream locations would also be beneficial because, due to a dilution effect, eDNA concentrations at the downstream sites are likely not high even in the presence of a local taxon hotspot (see Figure 3), and hence more prone to result in non-detections. This is especially important in the context of many metabarcoding studies setting thresholds of read numbers below which the signal is no longer accepted as a true positive [Deiner et al, 2017;Mächler et al, 2020]. In this perspective, collecting larger water volumes at the downstream sites is likely to help minimize the risk of non-detection.…”

Section: Discussionmentioning

confidence: 99%

How to design optimal eDNA sampling strategies for biomonitoring in river networks

Carraro

Stauffer

Altermatt

2020

Preprint

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The current biodiversity crisis calls for appropriate and timely methods to assess state and change of biodiversity. In this respect, environmental DNA (eDNA) is a highly promising tool, especially for aquatic ecosystems. While initial eDNA studies assessed biodiversity at a few sites, technology now allows analyses of samples from many points at a time. However, the selection of these sites has been mostly motivated on an ad-hoc basis, and it is unclear where to position sampling sites in a river network to most effectively sample biodiversity. To this end, hydrology-based models might offer a unique guidance on where to sample eDNA to reconstruct the spatial patterns of taxon density based on eDNA data collected across a watershed.Here, we performed computer simulations to identify best-practice criteria for the choice of positioning of eDNA sampling sites in river networks. To do so, we combined a hydrology-based eDNA transport model with a virtual river network reproducing the scaling features of real rivers. In particular, we conducted simulations investigating scenarios of different number and location of eDNA sampling sites in a riverine network, different spatial taxon distributions, and different eDNA measurement errors.We identified best practices for sampling site selection for taxa that have a scattered versus an even distribution across the network. We observed that, due to hydrological controls, non-uniform patterns of eDNA concentration arise even if the taxon distribution is uniform and decay is neglected. We also found that uncertainties in eDNA concentration estimates do not necessarily hamper model predictions. Knowledge of eDNA decay rates improves model predictions, highlighting the need for empirical estimates of these rates under relevant environmental conditions. Our simulations help define strategies for the design of eDNA sampling campaigns in river networks, and can guide the sampling effort of field ecologists and environmental authorities.

show abstract

Decision making and best practices for taxonomy-free eDNA metabarcoding in biomonitoring using Hill numbers

Cited by 10 publications

References 64 publications

DNA metabarcoding captures subtle differences in forest beetle communities following disturbance

DNA metabarcoding captures subtle differences in forest beetle communities following disturbance

How to design optimal eDNA sampling strategies for biomonitoring in river networks

How to design optimal eDNA sampling strategies for biomonitoring in river networks

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