Introduced bees (<i>Osmia cornifrons</i>) collect pollen from both coevolved and novel host-plant species within their family-level phylogenetic preferences

Vaudo, Anthony D.; Biddinger, David J.; Sickel, Wiebke; Keller, Alexander; López‐Uribe, Margarita M.

doi:10.1098/rsos.200225

Cited by 26 publications

(37 citation statements)

References 53 publications

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“…From the 42 reviewed studies, seven non filtered publicly available dataset were retrieved along with one unpublished dataset, produced by the authors, that was also included in the subsequent analysis (available upon request at http://doi/10.6084/m9.figshare.13637576, this data will be published after paper acceptance, ndr). Among these, four datasets were obtained by processing pollen found in nests or carried on insects bodies (Bell et al, 2017; Biella et al, 2019; Vaudo et al, 2020; along with the unpublished one, hereafter Tommasi et al, unpublished, that contains information about interactions between 249 insects and 156 plants). Three dataset comes from honey sample analysis (Lucek et al 2019; DeVere et al, 2017; Jones et al, 2021), and one was obtained from the analysis of pollen mock samples specially constructed for methodological assessments (Bell et al, 2019).…”

Section: Resultsmentioning

confidence: 99%

Harnessing the power of metabarcoding in the ecological interpretation of plant-pollinator DNA data: strategies and consequences of reads filtering

Tommasi

Ferrari

Galimberti

et al. 2021

Preprint

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DNA metabarcoding approaches to analyse complex mixtures of pollen has become the standard in pollination biology, especially in the light of recent threats affecting pollination. In spite of the increasing adoption of High Throughput Sequencing (HTS) approaches, these studies generate huge numbers of raw reads, some of which might be associated to false positives or infrequently recorded species with potentially little biological information. If these reads are not discarded (i.e. pruned), they can lead to changes in the ecological findings and lead to biased conclusions. In this study we reviewed 42 papers in the recent pollen DNA metabarcoding literature and focused on the type of pruning applied. We also tested whether the different types of those cut off threshold may leave a mark on the DNA metabarcoding data. To do so, we compared for the first time community composition, species richness and networks of species interactions (i.e. Connectace, Modularity, Connectivity and Shannon entropy) associated with the most relevant ways of treating HTS outputs: no cut (no reads filtering), or cutting levels obtained as proportional 1% of sample total reads, or as fixed amount of 100 reads, or from ROC (Receiver operator characteristic). Results clearly indicated that pruning type shapes species composition and that to apply or not a threshold dramatically impacts ecological indices, potentially increasing the risk of misinterpreting DNA metabarcoding data under an ecological point of view. Given the high methodological heterogeneity from the revised literature, we discuss in what conditions filtering types may be more appropriate, and also recommend to biologically justify the pruning threshold when analysing DNA metabarcoding raw reads, and to develop shared approaches to make future studies more comparable.

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Section: Resultsmentioning

confidence: 99%

Harnessing the power of metabarcoding in the ecological interpretation of plant-pollinator DNA data: strategies and consequences of reads filtering

Tommasi

Ferrari

Galimberti

et al. 2021

Preprint

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“…Alternatively, pollen may be identified by DNA metabarcoding: a process involving identifying all species in an environmental sample using DNA barcode markers and highthroughput sequencing [25][26][27]. DNA metabarcoding has been used to successfully identify pollen from provisions within nests [28][29][30], honey [31][32][33], proboscises [34,35], guts [36,37], and the legs or bodies of insects [38][39][40] (Supporting Information). Whilst the majority of DNA metabarcoding studies utilize pollen, some have identified raw plant material from within nests to identify the leaf preferences of solitary bees [41][42][43].…”

Section: Methods For Identifying Floral Visitation By Pollinatorsmentioning

confidence: 99%

Using DNA Metabarcoding to Identify Floral Visitation by Pollinators

Lowe¹,

Jones²,

Witter³

et al. 2022

Preprint

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The identification of floral visitation by pollinators provides an opportunity to improve our understanding of the fine-scale ecological interactions between plants and pollinators, contributing to biodiversity conservation and promoting ecosystem health. In this review we outline the various methods which can be used to identify floral visitation, providing a comparison between molecular and non-molecular methods. We review the literature covering the ways in which DNA metabarcoding has been used to answer ecological questions relating to plant use by pollinators and discuss the findings of this research. We present detailed methodological considerations for each step of the metabarcoding workflow, from sampling through to amplification and finally bioinformatic analysis. Detailed guidance is provided to researchers for utilization of these techniques, emphasizing the importance of standardization of methods and improving the reliability of results. Future opportunities and directions of using molecular methods to analyze plant-pollinator interactions are then discussed.

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“…In the US, there has been considerable reforestation and urbanisation (He et al, 2019;Song et al, 2018), at the expense of grassland and herbaceous areas (Lark, Meghan Salmon, & Gibbs, 2015;Otto, Roth, Carlson, & Smart, 2016). Pollen DNA metabarcoding has been used to understand the flexibility of pollinator species dietary niche in response to such changing environmental conditions (Vaudo et al, 2020) and to evaluate and improve conservation efforts (Gresty et al, 2018;Piko et al, 2021). Land-use change can also alter the diversity of resources available to pollinators, with decreased floral richness in agricultural monocultures and context-specific increases or decreases with urbanisation (da Rocha-Filho et al, 2021;Jones, Brennan, et al, 2021;Lucek et al, 2019;Richardson et al, 2021;Samuelson, Gill, & Leadbeater, 2020).…”

Section: Understanding Pollinator Responses To Land-use Changementioning

confidence: 99%

Pollen DNA metabarcoding and related methods in global change ecology: prospects, challenges, and progress

Bell

Turo

Lowe

et al. 2022

Preprint

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Anthropogenic activities are leading to changes in the environment at global scales, and understanding these changes requires rapid, high-throughput methods of assessment. Pollen DNA metabarcoding and related methods provide advantages in throughput and efficiency over traditional methods, such as microscopic identification of pollen and visual observation of plant-pollinator interactions. Pollen DNA metabarcoding is currently being applied to assessments of plant-pollinator interactions and their responses to land-use change such as increased agricultural intensity and urbanisation, surveillance of ecosystem change, and monitoring of spatiotemporal distribution of allergenic pollen. In combination with historical specimens, pollen DNA metabarcoding can compare contemporary and past ecosystems. Current technical challenges with pollen DNA metabarcoding include the need to understand the relationship between sequence read and species abundance, develop methods for determining confidence limits for detection and taxonomic classification, increase method standardisation, and improve of gaps in reference databases. Future research expanding the method to intraspecific identification, analysis of DNA in ancient pollen samples, and increased use of museum and herbarium specimens could open further avenues for research. Ongoing developments in sequencing technologies can accelerate progress towards these goals. Global ecological change is happening rapidly, and we anticipate that high-throughput methods such as pollen DNA metabarcoding are critical for assessing these changes and providing timely management recommendations to preserve biodiversity and the evolutionary and ecological processes that support it.

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Introduced bees (Osmia cornifrons) collect pollen from both coevolved and novel host-plant species within their family-level phylogenetic preferences

Cited by 26 publications

References 53 publications

Harnessing the power of metabarcoding in the ecological interpretation of plant-pollinator DNA data: strategies and consequences of reads filtering

Harnessing the power of metabarcoding in the ecological interpretation of plant-pollinator DNA data: strategies and consequences of reads filtering

Using DNA Metabarcoding to Identify Floral Visitation by Pollinators

Pollen DNA metabarcoding and related methods in global change ecology: prospects, challenges, and progress

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