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Bell, Karen L.; Turo, Katherine J.; Lowe, Abigail; Nota, Kevin; Keller, Alexander; Encinas-Viso, Francisco; Parducci, Laura; Richardson, Rodney T.; Leggett, Richard M.; Brosi, Berry J.; Burgess, Kevin S.; Suyama, Yoshihisa und de Vere, Natasha (2022): Plants, pollinators and their interactions under global ecological change: The role of pollen DNA metabarcoding. In: Molecular Ecology, Bd. 32, Nr. 23: S. 6345-6362

Volltext auf 'Open Access LMU' nicht verfügbar.

Abstract

Anthropogenic activities are triggering global changes in the environment, causing entire communities of plants, pollinators and their interactions to restructure, and ultimately leading to species declines. To understand the mechanisms behind community shifts and declines, as well as monitoring and managing impacts, a global effort must be made to characterize plant-pollinator communities in detail, across different habitat types, latitudes, elevations, and levels and types of disturbances. Generating data of this scale will only be feasible with rapid, high-throughput methods. Pollen DNA metabarcoding provides advantages in throughput, efficiency and taxonomic resolution over traditional methods, such as microscopic pollen identification and visual observation of plant-pollinator interactions. This makes it ideal for understanding complex ecological networks and their responses to change. Pollen DNA metabarcoding is currently being applied to assess plant-pollinator interactions, survey ecosystem change and model the spatiotemporal distribution of allergenic pollen. Where samples are available from past collections, pollen DNA metabarcoding has been used to compare contemporary and past ecosystems. New avenues of research are possible with the expansion of pollen DNA metabarcoding to intraspecific identification, analysis of DNA in ancient pollen samples, and increased use of museum and herbarium specimens. 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 understanding the evolutionary and ecological processes that support biodiversity, and predicting and responding to the impacts of change.

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