Quantitative assessment of fish larvae community composition in spawning areas using metabarcoding of bulk samples

Ratcliffe, Frances C.; Webster, Tamsyn M. Uren; Rodríguez‐Barreto, Deiene; O’Rorke, Richard; Leániz, Carlos García de; Consuegra, Sofía

doi:10.1002/eap.2284

Cited by 11 publications

(19 citation statements)

References 47 publications

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“…Constraints affecting the quantitative performance of metabarcoding are due to bias introduced during the four main stages of its workflow: (1) sample collection and processing; (2) choice of target gene; (3) HTS DNA sequencing; and (4) bioinformatics (Figure 1). Numerous approaches have been implemented to mitigate bias during each stage in order to avoid constraints that hinder accurate quali‐quantitative DNA metabarcoding analysis (Deagle et al, 2018; Ratcliffe et al, 2021; Thomas et al, 2016).…”

Section: Figurementioning

confidence: 99%

“…Also, the authors were able to size fractionated specimens and extract DNA from individuals of similar size to minimize bias due to different initial amounts of DNA from each larva. Similarly, Ratcliffe et al (2021) used a standardized amount of tissue for each species to improve quantification accuracy. Instead, they used PCR and conserved primer binding sites to amplify the mitochondrial 12S gene and avoid bias due to differential amplification rates.…”

Section: Figurementioning

confidence: 99%

“…biomonitoring 2.0, DNA barcode, environmental genomics, high-throughput DNA sequencing, neotropical fish to mitigate bias during each stage in order to avoid constraints that hinder accurate quali-quantitative DNA metabarcoding analysis (Deagle et al, 2018;Ratcliffe et al, 2021;Thomas et al, 2016). Mariac et al (2021) addresses well the bias that may arise from ichthyoplankton sampling and the unequal body size of fish larvae that may lead to differences in cell and DNA quantity from each species/specimen per bulk sample.…”

Section: Introductionmentioning

confidence: 99%

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Ichthyoplankton DNA metabarcoding: Challenges and perspectives

Carvalho

2022

Molecular Ecology

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DNA metabarcoding has been widely used to access and monitor species. However, several challenges remain open for its mainstream application in ecological studies, particularly when dealing with a quantitative approach. In a From the Cover article in this issue of Molecular Ecology, Mariac et al. (2021) report species‐level ichthyoplankton dynamics for 97 fish species from two Amazon river basins using a clever quantitative metabarcoding approach employing a probe capture method. They clearly show that most species spawned during the floods, although ~20% also spawned mainly during the receding period and some other year‐round, but interestingly, species from the same genus reproduced in distinct periods (i.e., inverse phenology). Opportunistically, Mariac et al. (2021) reported that during an intense hydrological anomaly, several species had a sharp reduction in spawning activity, demonstrating a quick response to environmental cues. This is an interesting result since the speed at which fish species can react to environmental changes, during the spawning period, is largely unknown. Thus, this study brings remarkable insights into basic life history information that is imperative for proposing strategies that could lead to a realistic framework for sustainable fisheries management practices and conservation, fundamental for an understudied and threatened realm, such as the Amazon River basin.

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Section: Figurementioning

confidence: 99%

Section: Figurementioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Ichthyoplankton DNA metabarcoding: Challenges and perspectives

Carvalho

2022

Molecular Ecology

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show abstract

“…Constraints affecting the quantitative performance of metabarcoding are due to bias introduced during the four main stages of its workflow: (1) sample collection and processing, (2) choice of target gene, (3) HTS DNA sequencing and (4) bioinformatics (Figure 1). Numerous approaches have been implemented to mitigate bias during each stage in order to avoid constraints that hinder accurate quali-quantitative DNA metabarcoding analysis (Thomas et al 2016, Deagle et al 2018Ratcliffe et al 2021). Mariac et al (2021) addresses well the bias that may arise from ichthyoplankton sampling and the unequal body size of fish larvae that may lead to differences in cell and DNA quantity from each species/specimen per bulk sample.…”

mentioning

confidence: 99%

“…Also, the authors were able to size fractionated specimens and extract DNA from individuals of similar size to minimize bias due to different initial amounts of DNA from each larva. Similarly, Ratcliffe et al (2021) used a standardized amount of tissue for each species to improve quantification accuracy. But instead, they used PCR and conserved primer binding sites to amplify the mitochondrial 12S gene and avoid bias due to differential amplification rates.…”

mentioning

confidence: 99%

Ichthyoplankton DNA metabarcoding: challenges and perspectives

Carvalho

2021

Preprint

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DNA metabarcoding has been widely used to access and monitor species. However, several challenges remain open for its mainstream application in ecological studies, particularly when dealing with a quantitative approach. In a from the Cover article in this issue of Molecular Ecology, Cédric et al. (2021) report species-level ichthyoplankton dynamics for 97 fish species from two Amazon river basins using a clever quantitative metabarcoding approach employing a probe capture method. They clearly show that most species spawned during the rainy season when the floods started, but interestingly, species from the same genus reproduced in distinct periods (i.e., inverse phenology). Opportunistically, Cédric et al. (2021) reported that during an intense hydrological anomaly, several species had a sharp reduction in spawning activity, demonstrating a quick response to environmental cues. This is an interesting result since the speed at which fish species can react to environmental changes, during the spawning period, is largely unknown. Thus, this study brings remarkable insights into basic life history information that is imperative for proposing strategies that could lead to a realistic framework for sustainable fisheries management practices and conservation, fundamental for an under-studied and threatened realm, such as the Amazon River basin.

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Fecal matters: implementing classical Coleoptera species lists with metabarcoding data from passerine bird feces

et al. 2023

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Diversity inventories are critical to creating accurate species range maps and estimating population sizes, which in turn lead to better informed landscape and wildlife management decisions. Metabarcoding has facilitated large-scale environmental diversity surveys. However, the use of a metabarcoding approach with bird feces to survey arthropod diversity is still relatively undeveloped. The aim of this study was to see if and how a metabarcoding approach with bird feces could contribute to a saproxylic Coleoptera survey of traditional insect traps. We compared two methods of surveying saproxylic Coleoptera diversity (metabarcoding birds feces and deploying traditional traps) over two elevations in a mountain system. The two methods caught different species and different levels of functional guild richness. The metabarcoding method successfully recorded both distinct and overlapping portions of diversity from traditional collections, and the approach was also effective in signaling the presence of both rare species and nine country records. Our results show that metabarcoding Passerine bird feces can be successful when used alongside traditional collection methods to capture a broad diversity of saproxylic Coleoptera. This method, however, has quantitative and qualitative limitations, including the inability to produce species abundance data as well as the generation of false positives and negatives due to biases within the metabarcoding pipeline. Implications for insect conservation As many terrestrial ecosystems lose insect diversity, insect diversity surveys are essential to understand the scope of the loss. Despite metabarcoding approach shortcomings, the declining costs and shorter survey and processing time required for this approach compared to traditional survey methods indicate that it can be a valuable addition to the toolkit for saproxylic Coleoptera diversity surveys.

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Quantitative assessment of fish larvae community composition in spawning areas using metabarcoding of bulk samples

Cited by 11 publications

References 47 publications

Ichthyoplankton DNA metabarcoding: Challenges and perspectives

Ichthyoplankton DNA metabarcoding: Challenges and perspectives

Ichthyoplankton DNA metabarcoding: challenges and perspectives

Fecal matters: implementing classical Coleoptera species lists with metabarcoding data from passerine bird feces

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