Integration of multiple metabolic pathways supports high rates of carbon precipitation in living microbialites

Rachel E. Sipler; Eric W. Isemonger; Samantha C. Waterworth; Steffen H. Büttner; Thomas G. Bornman; Ross Lynne A. Gibb; Xavier Siwe Noundou; Siddarthan Venkatachalam; Rosemary A. Dorrington

doi:10.1038/s41467-025-66552-8

Integration of multiple metabolic pathways supports high rates of carbon precipitation in living microbialites

Rachel E. Sipler
, Eric W. Isemonger
, Samantha C. Waterworth
, Steffen H. Büttner
, Thomas G. Bornman
, Ross Lynne A. Gibb
, Xavier Siwe Noundou
, Siddarthan Venkatachalam
, Rosemary A. Dorrington^*

^*Corresponding author for this work

Pharmaceutical Sciences

Research output: Contribution to journal › Article › peer-review

Abstract

Microbialites are lithifying microbial mats that form multi-layered structures via biological carbon (C) uptake and carbonate precipitation. Here we relate C uptake and precipitation rates to taxonomic diversity and functional capacity of bacterial communities in supratidal freshwater microbialites. Diel assays and analysis of functional gene capacity reveal that photosynthesis is bolstered by light-independent, biological C uptake mechanisms, including biomineralization and chemoautotrophy. Through integration of these mechanisms, microbialites can capture inorganic C over a 24-hour cycle at a rate of 7-12 g C m^-2 24 h^-1. Notably, up to 87 % of the C taken up is precipitated as inorganic carbon, capturing 2.4 − 4.3 kg C m^-2 year^-1. Based on observed porosity and laboratory-based accretion rates, this equates to 13-23 mm of vertical calcium carbonate accumulation per year. Hence, contemporary microbialites provide a highly effective biological mechanism to precipitate dissolved CO₂ as geologically stable carbonate mineral deposits.

Original language	English
Article number	11
Pages (from-to)	11
Journal	Nature Communications
Volume	17
Issue number	1
DOIs	https://doi.org/10.1038/s41467-025-66552-8
Publication status	Published - Jan 2026

Keywords

Bacteria/metabolism
Calcium Carbonate/metabolism
Carbon Dioxide/metabolism
Carbon/metabolism
Carbonates/metabolism
Chemical Precipitation
Fresh Water/microbiology
Geologic Sediments/microbiology
Metabolic Networks and Pathways
Photosynthesis

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title = "Integration of multiple metabolic pathways supports high rates of carbon precipitation in living microbialites",

abstract = "Microbialites are lithifying microbial mats that form multi-layered structures via biological carbon (C) uptake and carbonate precipitation. Here we relate C uptake and precipitation rates to taxonomic diversity and functional capacity of bacterial communities in supratidal freshwater microbialites. Diel assays and analysis of functional gene capacity reveal that photosynthesis is bolstered by light-independent, biological C uptake mechanisms, including biomineralization and chemoautotrophy. Through integration of these mechanisms, microbialites can capture inorganic C over a 24-hour cycle at a rate of 7-12 g C m-2 24 h-1. Notably, up to 87 \% of the C taken up is precipitated as inorganic carbon, capturing 2.4 − 4.3 kg C m-2 year-1. Based on observed porosity and laboratory-based accretion rates, this equates to 13-23 mm of vertical calcium carbonate accumulation per year. Hence, contemporary microbialites provide a highly effective biological mechanism to precipitate dissolved CO2 as geologically stable carbonate mineral deposits.",

keywords = "Bacteria/metabolism, Calcium Carbonate/metabolism, Carbon Dioxide/metabolism, Carbon/metabolism, Carbonates/metabolism, Chemical Precipitation, Fresh Water/microbiology, Geologic Sediments/microbiology, Metabolic Networks and Pathways, Photosynthesis",

author = "Sipler, \{Rachel E.\} and Isemonger, \{Eric W.\} and Waterworth, \{Samantha C.\} and B{\"u}ttner, \{Steffen H.\} and Bornman, \{Thomas G.\} and Gibb, \{Ross Lynne A.\} and \{Siwe Noundou\}, Xavier and Siddarthan Venkatachalam and Dorrington, \{Rosemary A.\}",

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doi = "10.1038/s41467-025-66552-8",

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AU - Sipler, Rachel E.

AU - Isemonger, Eric W.

AU - Waterworth, Samantha C.

AU - Büttner, Steffen H.

AU - Bornman, Thomas G.

AU - Gibb, Ross Lynne A.

AU - Siwe Noundou, Xavier

AU - Venkatachalam, Siddarthan

AU - Dorrington, Rosemary A.

PY - 2026/1

Y1 - 2026/1

N2 - Microbialites are lithifying microbial mats that form multi-layered structures via biological carbon (C) uptake and carbonate precipitation. Here we relate C uptake and precipitation rates to taxonomic diversity and functional capacity of bacterial communities in supratidal freshwater microbialites. Diel assays and analysis of functional gene capacity reveal that photosynthesis is bolstered by light-independent, biological C uptake mechanisms, including biomineralization and chemoautotrophy. Through integration of these mechanisms, microbialites can capture inorganic C over a 24-hour cycle at a rate of 7-12 g C m-2 24 h-1. Notably, up to 87 % of the C taken up is precipitated as inorganic carbon, capturing 2.4 − 4.3 kg C m-2 year-1. Based on observed porosity and laboratory-based accretion rates, this equates to 13-23 mm of vertical calcium carbonate accumulation per year. Hence, contemporary microbialites provide a highly effective biological mechanism to precipitate dissolved CO2 as geologically stable carbonate mineral deposits.

AB - Microbialites are lithifying microbial mats that form multi-layered structures via biological carbon (C) uptake and carbonate precipitation. Here we relate C uptake and precipitation rates to taxonomic diversity and functional capacity of bacterial communities in supratidal freshwater microbialites. Diel assays and analysis of functional gene capacity reveal that photosynthesis is bolstered by light-independent, biological C uptake mechanisms, including biomineralization and chemoautotrophy. Through integration of these mechanisms, microbialites can capture inorganic C over a 24-hour cycle at a rate of 7-12 g C m-2 24 h-1. Notably, up to 87 % of the C taken up is precipitated as inorganic carbon, capturing 2.4 − 4.3 kg C m-2 year-1. Based on observed porosity and laboratory-based accretion rates, this equates to 13-23 mm of vertical calcium carbonate accumulation per year. Hence, contemporary microbialites provide a highly effective biological mechanism to precipitate dissolved CO2 as geologically stable carbonate mineral deposits.

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KW - Calcium Carbonate/metabolism

KW - Carbon Dioxide/metabolism

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KW - Chemical Precipitation

KW - Fresh Water/microbiology

KW - Geologic Sediments/microbiology

KW - Metabolic Networks and Pathways

KW - Photosynthesis

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JO - Nature Communications

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ER -

Integration of multiple metabolic pathways supports high rates of carbon precipitation in living microbialites

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