Sedimentary ancient DNA in paleoecology across climate zones
Sedimentary ancient DNA is becoming more widely used in paleoeocology, as methods for sampling of sediments, as well as for extraction and sequencing of sedimentary ancient DNA have become more efficient and retrieval success has increased. To date, investigations of ancient DNA have concentrated on...
| Main Authors: | , , , , , , |
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| Format: | Conference Object |
| Language: | unknown |
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2017
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| Subjects: | |
| Online Access: | https://epic.awi.de/id/eprint/45158/ http://pastglobalchanges.org/osm2017/downloads/osm-abstract-book-zaragoza-2017.pdf https://hdl.handle.net/10013/epic.51343 |
| Summary: | Sedimentary ancient DNA is becoming more widely used in paleoeocology, as methods for sampling of sediments, as well as for extraction and sequencing of sedimentary ancient DNA have become more efficient and retrieval success has increased. To date, investigations of ancient DNA have concentrated on sites with low temperatures, as these display optimal preservation conditions. Remote, high latitude sites are ideal to track environmental changes that are not directly induced by human activity. Current climate changes are causing particularly strong ecosystem perturbations in the Arctic, and sedimentary archives allow a comparison of the current situation with past changes throughout the Holocene. Sites from temperate and tropical regions have been studied to a lesser extent, but are important for the analysis of human history and anthropogenic ecosystem modifications. Preservation conditions are less optimal, but ancient DNA has been retrieved on centennial to millenial timescales - corresponding to a period of time, in which anthropogenic impact has been strongest. Given good preservation conditions coupled with adequate precautions to ensure clean subsampling of the inside of sediment cores and for work with ancient DNA, a high diversity of authentic taxa can be retrieved. Plant DNA metabarcoding of Arctic lake sediment cores and ancient permafrost from Siberia can yield, for example, up to over 90 or 100 plant taxa from single samples, including both terrestrial and aquatic taxa, as well as bryophytes. Inferences of spatial and temporal vegetation change correspond very well to those from pollen, and DNA can potentially offer a higher degree of resolution. Using the same approaches as for Arctic samples, we are currently investigating a sediment core from Lake Barombi Mbo in Cameroon, concentrating on samples spanning the Holocene. Here, we give an overview of our approaches and comparatively assess the potential of sedimentary DNA as a paleoecological tool in different settings. |
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