Biosilicification drives a decline of dissolved si in the oceans through geologic time

Conley, Daniel J.; Frings, Patrick J.; Fontorbe, Guillaume; Clymans, Wim; Stadmark, Johanna; Hendry, Katharine R.; Marron, Alan O.; De La Rocha, Christina L.

Biosilicification drives a decline of dissolved si in the oceans through geologic time

Mark

Conley, Daniel J. ^LU ; Frings, Patrick J. ^LU ; Fontorbe, Guillaume ^LU ; Clymans, Wim ^LU ; Stadmark, Johanna ^LU ; Hendry, Katharine R. ; Marron, Alan O. and De La Rocha, Christina L. ^LU (2017) In Frontiers in Marine Science 4(DEC).

Abstract: Biosilicification has driven variation in the global Si cycle over geologic time. The evolution of different eukaryotic lineages that convert dissolved Si (DSi) into mineralized structures (higher plants, siliceous sponges, radiolarians, and diatoms) has driven a secular decrease in DSi in the global ocean leading to the low DSi concentrations seen today. Recent studies, however, have questioned the timing previously proposed for the DSi decreases and the concentration changes through deep time, which would have major implications for the cycling of carbon and other key nutrients in the ocean. Here, we combine relevant genomic data with geological data and present new hypotheses regarding the impact of the evolution of biosilicifying... (More); Biosilicification has driven variation in the global Si cycle over geologic time. The evolution of different eukaryotic lineages that convert dissolved Si (DSi) into mineralized structures (higher plants, siliceous sponges, radiolarians, and diatoms) has driven a secular decrease in DSi in the global ocean leading to the low DSi concentrations seen today. Recent studies, however, have questioned the timing previously proposed for the DSi decreases and the concentration changes through deep time, which would have major implications for the cycling of carbon and other key nutrients in the ocean. Here, we combine relevant genomic data with geological data and present new hypotheses regarding the impact of the evolution of biosilicifying organisms on the DSi inventory of the oceans throughout deep time. Although there is no fossil evidence for true silica biomineralization until the late Precambrian, the timing of the evolution of silica transporter genes suggests that bacterial silicon-related metabolism has been present in the oceans since the Archean with eukaryotic silicon metabolism already occurring in the Neoproterozoic. We hypothesize that biological processes have influenced oceanic DSi concentrations since the beginning of oxygenic photosynthesis.
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Please use this url to cite or link to this publication: https://lup.lub.lu.se/record/292df7c7-d8e5-4226-a1e5-18ff304beded

author

Conley, Daniel J. ^LU ; Frings, Patrick J. ^LU ; Fontorbe, Guillaume ^LU ; Clymans, Wim ^LU ; Stadmark, Johanna ^LU ; Hendry, Katharine R. ; Marron, Alan O. and De La Rocha, Christina L. ^LU

organization

Quaternary Sciences

publishing date

2017-12-11

type

Contribution to journal

publication status

published

subject

keywords

Biogeochemical cycles, Cyanobacteria, Diatoms, Silicates, Sponges

in

Frontiers in Marine Science

volume

4

issue

DEC

article number

397

publisher

Frontiers Media S. A.

external identifiers

scopus:85037642863

ISSN

2296-7745

DOI

10.3389/fmars.2017.00397

language

English

LU publication?

yes

id

292df7c7-d8e5-4226-a1e5-18ff304beded

date added to LUP

2018-01-05 08:34:57

date last changed

2022-04-25 04:45:39

@article{292df7c7-d8e5-4226-a1e5-18ff304beded,
  abstract     = {{<p>Biosilicification has driven variation in the global Si cycle over geologic time. The evolution of different eukaryotic lineages that convert dissolved Si (DSi) into mineralized structures (higher plants, siliceous sponges, radiolarians, and diatoms) has driven a secular decrease in DSi in the global ocean leading to the low DSi concentrations seen today. Recent studies, however, have questioned the timing previously proposed for the DSi decreases and the concentration changes through deep time, which would have major implications for the cycling of carbon and other key nutrients in the ocean. Here, we combine relevant genomic data with geological data and present new hypotheses regarding the impact of the evolution of biosilicifying organisms on the DSi inventory of the oceans throughout deep time. Although there is no fossil evidence for true silica biomineralization until the late Precambrian, the timing of the evolution of silica transporter genes suggests that bacterial silicon-related metabolism has been present in the oceans since the Archean with eukaryotic silicon metabolism already occurring in the Neoproterozoic. We hypothesize that biological processes have influenced oceanic DSi concentrations since the beginning of oxygenic photosynthesis.</p>}},
  author       = {{Conley, Daniel J. and Frings, Patrick J. and Fontorbe, Guillaume and Clymans, Wim and Stadmark, Johanna and Hendry, Katharine R. and Marron, Alan O. and De La Rocha, Christina L.}},
  issn         = {{2296-7745}},
  keywords     = {{Biogeochemical cycles; Cyanobacteria; Diatoms; Silicates; Sponges}},
  language     = {{eng}},
  month        = {{12}},
  number       = {{DEC}},
  publisher    = {{Frontiers Media S. A.}},
  series       = {{Frontiers in Marine Science}},
  title        = {{Biosilicification drives a decline of dissolved si in the oceans through geologic time}},
  url          = {{http://dx.doi.org/10.3389/fmars.2017.00397}},
  doi          = {{10.3389/fmars.2017.00397}},
  volume       = {{4}},
  year         = {{2017}},
}

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Biosilicification drives a decline of dissolved si in the oceans through geologic time