2023
DOI: 10.1002/edn3.393
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Using environmental DNA to investigate avian interactions with flowering plants

Abstract: Animal pollination is an important and highly valued ecosystem function and the role of birds as pollinators is increasingly acknowledged. However, such interactions can be challenging to document and often require extensive field programs. Over the last decade, environmental DNA (eDNA) has been analyzed from several different contemporary sample types, such as water, soil, flowers, and air. The applications of these studies include biodiversity monitoring, detection of endangered species, community compositio… Show more

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Cited by 9 publications
(8 citation statements)
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“…This disparity among species‐specific detections of Lepidoptera as a whole, the Papilionoidea superfamily, and pollinating bee species (Hymenoptera) most likely is the result of primer limitations or sample collection methods. Future research should take into account recent research that indicates it is possible for small portions of residual arthropod eDNA to be depositied on flowers via airborne contamination (Johnson et al, 2023; Jonsson et al, 2023; Klepke et al, 2022; Roger et al, 2022). Lastly, our eDNA metabarcoding survey did not amplify eDNA across all flower samples (see explanations below).…”
Section: Discussionmentioning
confidence: 99%
See 1 more Smart Citation
“…This disparity among species‐specific detections of Lepidoptera as a whole, the Papilionoidea superfamily, and pollinating bee species (Hymenoptera) most likely is the result of primer limitations or sample collection methods. Future research should take into account recent research that indicates it is possible for small portions of residual arthropod eDNA to be depositied on flowers via airborne contamination (Johnson et al, 2023; Jonsson et al, 2023; Klepke et al, 2022; Roger et al, 2022). Lastly, our eDNA metabarcoding survey did not amplify eDNA across all flower samples (see explanations below).…”
Section: Discussionmentioning
confidence: 99%
“…For example, it is unclear why the arthropod communities detected via eDNA versus camera trapping differed so substantially and how external factors, such as rain and flower type, impacted eDNA collection. Although our work was focused on arthropod pollinators, this work is applicable for the detection of vertebrate species (e.g., birds and bats; Jonsson et al, 2023; Newton et al, 2023; Walker et al, 2022) and should be explored further. In combination, our results suggest that eDNA represents a useful tool for monitoring arthropod communities associated with specific flowers and assessing their functional diversity, while future refinement should only improve its efficacy.…”
Section: Discussionmentioning
confidence: 99%
“…While the ability to detect insect visits to flowers using eDNA shows promise (Evans & Kitson, 2020; Gamonal Gomez et al, 2022; Harper et al, 2022; Thomsen & Sigsgaard, 2019), the technique has only recently been used to identify vertebrate flower visitors (Jønsson et al, 2023; Walker et al, 2022). Furthermore, while eDNA metabarcoding surveys have been shown to outperform the use of both visual (Barata et al, 2020) and camera trap (Leempoel et al, 2020) techniques in other contexts, there are limitations of the method, including limited knowledge on the deposition and persistence of eDNA on floral surfaces (Barnes & Turner, 2016; Harrison et al, 2019; Valentin et al, 2021).…”
Section: Introductionmentioning
confidence: 99%
“…For instance, deploying cameras and machine learning to identify flowers and even pollinators at very fine temporal scales (Besson et al 2022) can significantly help reduce the workforce needed to collect this type of data. Similarly, DNA approaches can quantify phenologies and even interactions at similar or even finer temporal scales than direct observation (e.g., metabarcoding of airborne pollen DNA, pollinator DNA in flowers, or eDNA analysis in freshwater and marine systems) (Besson et al 2022;Jensen et al 2022;Jønsson et al 2023). Importantly, phenology data provide essential information about the temporal structure of communities by documenting when species are present and active in a given community.…”
Section: Building Time-ordered Co-occurrence Network From Phenology Datamentioning
confidence: 99%