A 2-million-year-old ecosystem in Greenland uncovered by environmental DNA

Kjær, Kurt H.; Pedersen, Mikkel Winther; Sanctis, Bianca De; Cahsan, Binia De; Korneliussen, Thorfinn; Michelsen, Christian; Sand, Karina K.; Jelavić, Stanislav; Ruter, Anthony; Schmidt, Astrid A.; Kjeldsen, Kristian K.; Tesakov, Alexey S.; Snowball, Ian; Gosse, John C.; Alsos, Inger Greve; Wang, Yucheng; Dockter, Christoph; Rasmussen, Magnus Wohlfahrt; Jørgensen, Morten; Skadhauge, Birgitte; Prohaska, Ana; Kristensen, J. A.; Bjerager, Morten; Allentoft, Morten E.; Coissac, Éric; Rouillard, Alexandra; Simakova, A. P.; Fernàndez-Guerra, Antonio; Bowler, Chris; Macias‐Fauria, Marc; Vinner, Lasse; Welch, John J.; Hidy, Alan J.; Sikora, Martin; Collins, Matthew J.; Durbin, Richard; Larsen, Nicolaj K.; Willerslev, Eske

doi:10.1038/s41586-022-05453-y

Cited by 97 publications

(109 citation statements)

References 88 publications

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“…We recently recovered DNA from sediments dated to 2.4 Ma where the thermal age predicted no DNA survival. 12 Additionally, that study showed that the amount of DNA sediment adsorbs and retains depends on its mineralogic composition. In this communication, the term preservation is considered a function of DNA stabilization offered by the substrate (degree of immobilization and binding capacity) as well as resistance to biological, chemical and thermal degradation of the mineral-bound DNA.…”

Section: Introductionmentioning

confidence: 95%

“…Different surfaces will interact with DNA in different ways, depending on their composition and surface charge. For example, clay minerals, which adsorb an order of magnitude more DNA compared to other minerals, 12 are composed of layers of silica tetrahedra (T) and layers of magnesium or aluminum octahedra (O) (Fig. 1A)).…”

Section: Overview Of Interfacial Geochemical Conceptsmentioning

confidence: 99%

“…The Kap København formation is a 2.4 Ma marine sandy deposit that contains the oldest DNA recovered to date. 12 The sediment profile can be divided in two depositional environments with similar overall mineral composition but of varying ratios. Excluding the amorphous fraction (both organic and inorganic), the formation contains on average 69 wt% of quartz and 7.3 wt% of clay minerals: the rest of the major minerals are feldspars, pyroxene and amphiboles (Fig.…”

Section: Case Study: the Kap København Formationmentioning

confidence: 99%

“…Adsorption capacity of major minerals from Kap København formation. 12 The adsorbed DNA is shown as a function of the DNA equilibrium concentration, i.e. the concentration of DNA in solution once the equilibrium was reached.…”

Section: Case Study: the Kap København Formationmentioning

confidence: 99%

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Importance of eDNA taphonomy and provenance for robust ecological inference: insights from interfacial geochemistry

Sand

Jelavić

Kjær

et al. 2023

Preprint

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Context for and purpose: Retrieval of modern and ancient environmental DNA (eDNA) from sediments has revolutionized our ability to reconstruct present and past ecosystems. Little emphasis has been placed, however, on the fundamentals of the DNA-sediment associations and, consequently, our understanding of taphonomy and provenance of eDNA in sediments remains extremely limited. If we are to be able to accurately infer community dynamics across time and space from eDNA data, we need to understand how depositional processes and sedimentary associations of DNA molecules in different settings influence our interpretation. Approach and methods: Here, we introduce interfacial geochemical principles to the field of eDNA and discuss current interpretational biases. We outline a way to increase the scope and resolution of ecological interpretations from eDNA by combining mineralogic composition with experimental adsorption data. We apply distribution coefficients to assess the relationship between the DNA fraction in water columns and DNA fraction sequestered by suspended sediment particles. We further evaluate the challenges with drawing ecological inference using eDNA from sedimentary systems that receive input from different ecosystem types as a consequence of sedimentary processes. Main results: We show that: The retention of DNA in aqueous environments depends on the mineralogy of sediment particles and on the number of particles loaded in the water column. DNA attached to sediment particles from distal systems can be deposited in proximal systems and skew the interpretation of the proximal sediment samples. High particle loading in the water column can deplete suspended DNA and cause inaccurate interpretation of aqueous DNA samples. High particle loading in surface sediment pore waters enhances sequestration of DNA from benthic communities relative to that of water column communities, resulting in skewed estimates of species richness and abundance from sedimentary DNA. We discuss how to integrate taphonomy and provenance knowledge into the reconstruction of modern and past ecosystems, and ecosystem monitoring from eDNA data. Conclusions and the wider implications: Our findings demonstrate that integrating information about eDNA taphonomy and provenance into modern and past ecosystem reconstruction from eDNA data can enhance the scope, resolution and accuracy of our interpretations.

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Section: Introductionmentioning

confidence: 95%

Section: Overview Of Interfacial Geochemical Conceptsmentioning

confidence: 99%

Section: Case Study: the Kap København Formationmentioning

confidence: 99%

Section: Case Study: the Kap København Formationmentioning

confidence: 99%

See 2 more Smart Citations

Importance of eDNA taphonomy and provenance for robust ecological inference: insights from interfacial geochemistry

Sand

Jelavić

Kjær

et al. 2023

Preprint

Self Cite

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“…4–7 However, advances made in the field of sedimentary ancient DNA (SedaDNA) underlines that, DNA can be preserved for at least 2 Ma years, and the adsorption of the DNA to mineral surfaces are argued to be key for the preservation. 8 In principle, all sedimentary minerals all hold a potential to adsorb some amount of extracellular DNA. Currently there is about 0.45 Gt of extracellular DNA associated with sediments in the top 10 cm of the ocean floor, and more than 90% of that DNA extracellular.…”

Section: Introductionmentioning

confidence: 99%

Recurrence and propagation of past functions through mineral facilitated horizontal gene transfer

Verma

Hendiani

Andersen

et al. 2023

Preprint

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Horizontal gene transfer is the one of the most important drivers of bacterial evolution. Transformation by uptake of extracellular DNA is traditionally not considered to be an effective mode of gene acquisition, simply because extracellular DNA are considered to degrade in a matter of days when it is suspended in e.g. seawater. Mineral surfaces are, however, known to preserve DNA in the environment, and sedimentary ancient DNA studies have solidified there are considerable amounts of fragmented DNA stored in sediments world-wide. Recently the age of stored DNA was increased to at least 2 ma highlighting that sediments represent a rich resource of past traits. It is well established that bacteria can acquire large kilobase DNA molecules adsorbed to mineral surfaces. Here we show that Acinetobacter baylyi can incorporate 60 bp DNA fragments adsorbed to a wide range of common sedimentary minerals. Our recorded transformation frequencies vary with mineral types and scales inversely with mineral surface charge and the ability of the mineral to immobilize the DNA in a liquid environment. We argue that the influence of mineral surface properties introduces interfacial geochemical processes as drivers for evolution and provide sedimentologic processes a central role in the evolutionary avenue of selection.

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Assembly‐driven protection from hydrolysis as key selective force during chemical evolution

Edri,

Fisher,

Menor‐Salvan

et al. 2023

FEBS Letters

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The origins of biopolymers pose some of the most fascinating questions in prebiotic chemistry. The marvelous assembly proficiencies of biopolymers suggest they are winners of a competitive evolutionary process. Molecular assembly is ubiquitous in life and in abiotic systems and is often emergent upon polymerization. We focus on the influence of molecular assemblies on hydrolysis rates in aqueous media, and suggest that assembly was crucial for biopolymer selection. We suggest that incremental enrichment of some molecular species over others during chemical evolution was partially driven by interplay of kinetics of synthesis and hydrolysis. We document the general attenuation of hydrolysis by assembly of biopolymers and highlight the likely role of assembly in survival of the ‘fittest’ molecules during chemical evolution.

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A 2-million-year-old ecosystem in Greenland uncovered by environmental DNA

Cited by 97 publications

References 88 publications

Importance of eDNA taphonomy and provenance for robust ecological inference: insights from interfacial geochemistry

Importance of eDNA taphonomy and provenance for robust ecological inference: insights from interfacial geochemistry

Recurrence and propagation of past functions through mineral facilitated horizontal gene transfer

Assembly‐driven protection from hydrolysis as key selective force during chemical evolution

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