Pollen sleuthing for terrestrial plant surveys: Locating plant populations by exploiting pollen movement

Campbell, Lesley G.; Melles, Stephanie J.; Vaz, Eric; Parker, Rebecca J.; Burgess, Kevin S.

doi:10.1002/aps3.1020

Cited by 2 publications

(6 citation statements)

References 77 publications

(85 reference statements)

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“…Solitary insects and pollinators without floral constancy could also be investigated for their potential in detecting boneseed. A study using artificial pollen has shown that trapping of solitary insects could be used as a method to detect populations of invasive plants, and that these can be detected at low density although with decreased ability to track the detection to a source population (Campbell et al, 2018). Other studies have identified pollen on insects collected in traps, although not from low‐density plant populations (Gill & O'Neal, 2015).…”

Section: Discussionmentioning

confidence: 99%

Can honey bees be used to detect rare plants? Taking an eDNA approach to find the last plants in a weed eradication program

Batchelor,

Bell,

Campos

et al. 2023

Environmental DNA

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The detection of rare taxa, crucial to conservation and biosecurity, presents many challenges that emerging technologies have the potential to address or avoid. Analysis of environmental DNA (eDNA) is a promising tool for the detection of rare species, especially when applied in a way that exploits natural processes to accumulate biological material (natural aggregation). This study investigated the potential of using honey bees as aggregators of pollen eDNA to detect Chrysanthemoides monilifera subsp. monilifera (boneseed), an introduced species targeted for eradication in Western Australia. We developed a species‐specific polymerase chain reaction (PCR)‐based assay that detected boneseed pollen at levels as low as 70 grains per million in a constructed pollen mixture. The assay was successfully used on wild‐caught bees from large boneseed populations, confirming they collect boneseed pollen. However, our results did not detect boneseed DNA in honey bee pollen collected from hive pollen traps near isolated boneseed plants. We hypothesize that a combination of low abundance of boneseed individuals, vast alternative flower resources at the time of boneseed flowering, and honey bee behavior and ecology may have led to lack of detection. We propose ways in which future work using honey bees to detect rare species can be improved. We also outline how other eDNA substrates (e.g., air and water samples) could be used with the PCR assay we have developed. More broadly, our work highlights the potential of eDNA techniques to detect rare species in biosecurity and conservation contexts and contributes to the development of pollinator‐based detection.

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Section: Discussionmentioning

confidence: 99%

Can honey bees be used to detect rare plants? Taking an eDNA approach to find the last plants in a weed eradication program

Batchelor,

Bell,

Campos

et al. 2023

Environmental DNA

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“…Although these identifications often require specialist expertise and may achieve low taxonomic resolution due to the lack of morphological characters for species-level identification (Bell et al, 2016;Khansari et al, 2012;Rahl, 2008). Moreover, even when plant taxa are detected from pan traps, they are rarely used to infer species-specific flower visits or pollen transport (Popic et al, 2013); the primary reasons being that (1) pollen collected from pan traps represents foraging from the entire community of arthropods captured, and; (2) pan trap plant detections may include nontarget wind-pollinated species, which could result from contamination, either airborne pollen/plant material (Johnson et al, 2019b) or herbivorous regurgitant (Sword, 2001), rather than flower visits (Campbell et al, 2018;Popic et al, 2013). Such contributions may be significant considering that wind-pollinated species produce copious quantities of pollen (see Harrington & Metzger, 1963).…”

Section: Introductionmentioning

confidence: 99%

“…Such contributions may be significant considering that wind-pollinated species produce copious quantities of pollen (see Harrington & Metzger, 1963). Despite this potential for contamination, ambient pollen (pollen dispersed by air, not invertebrates) is rarely quantified, with studies instead relying upon alternative approaches, such as artificial pollen (see Campbell et al, 2018), to circumvent this issue. Plant surveys using passive traps may, therefore, benefit from alternative approaches, like those afforded by environmental DNA (eDNA) metabarcoding, to detect both pan trap-specific and ambient pollen, in order to generate high-throughput and high-resolution pollen datasets, which can help form robust conclusions about the plant resources used by pollinator communities.…”

Section: Introductionmentioning

confidence: 99%

“…Each array was placed at a height of 1.2 m above the ground to match the height of the P. americana trees in the study orchards. All of the pan traps were filled with ~200 mL of sterile MilliQ water, and one drop of detergent to disrupt the surface tension (Campbell et al, 2018;Gervais et al, 2018). Pan trap evaporation was minimal during the sample period due to the mild temperatures (average of 19.7°C), while, the water temperature of the pan traps did not exceed 25°C.…”

Section: Introductionmentioning

confidence: 99%

“…To date, these pollen‐centric studies have favored active sampling methods (e.g., sweep netting), followed by washing or swabbing arthropods to obtain animal‐collected pollen (Evans & Kitson, 2020; Pornon et al., 2017; Prendergast et al., 2020). Increasingly, however, microscopy‐based techniques are being combined with pan traps to identify foraging resources in both natural (Ladd et al., 2019) and agricultural systems (Bowie et al., 1999; Campbell et al., 2018; Gill & O'Neal, 2015). Although these identifications often require specialist expertise and may achieve low taxonomic resolution due to the lack of morphological characters for species‐level identification (Bell et al., 2016; Khansari et al., 2012; Rahl, 2008).…”

Section: Introductionmentioning

confidence: 99%

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Environmental DNA metabarcoding of pan trap water to monitor arthropod‐plant interactions

Kestel,

Field,

Bateman

et al. 2024

Environmental DNA

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Globally, the diversity of arthropods and the plants upon which they rely are under increasing pressure due to a combination of biotic and abiotic anthropogenic stressors. Unfortunately, conventional survey methods used to monitor ecosystems are often challenging to conduct on large scales. Pan traps are a commonly used pollinator survey method and environmental DNA (eDNA) metabarcoding of pan trap water may offer a high‐throughput alternative to aid in the detection of both arthropods and the plant resources they rely on. Here, we examined if eDNA metabarcoding can be used to identify arthropods and plant species from pan trap water, and investigated the effect of different DNA extraction methods. We then compared plant species identified by metabarcoding with observation‐based floral surveys and also assessed the contribution of airborne plant DNA (plant DNA not carried by arthropods) using marble traps to reduce putative false positives in the pan trap dataset. Arthropod eDNA was only detected in 17% of pan trap samples and there was minimal overlap between the eDNA results and morphological identifications. In contrast, for plants, we detected 64 taxa, of which 53 were unique to the eDNA dataset, and no differences were identified between the two extraction kits. We were able to significantly reduce the contribution of airborne plant DNA to the final dataset using marble traps. This study demonstrates that eDNA metabarcoding of pan trap water can detect plant resources used by arthropods and highlights the potential for eDNA metabarcoding to be applied to investigations of arthropod‐plant interactions.

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Pollen sleuthing for terrestrial plant surveys: Locating plant populations by exploiting pollen movement

Cited by 2 publications

References 77 publications

Can honey bees be used to detect rare plants? Taking an eDNA approach to find the last plants in a weed eradication program

Can honey bees be used to detect rare plants? Taking an eDNA approach to find the last plants in a weed eradication program

Environmental DNA metabarcoding of pan trap water to monitor arthropod‐plant interactions

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