An early-branching microbialite cyanobacterium forms intracellular carbonates

Estelle Couradeau; Karim Benzerara; Emmanuelle Gérard; David Moreira; Sylvain Bernard; Gordon E. Brown; Purificación López-García

doi:10.1126/science.1216171

An early-branching microbialite cyanobacterium forms intracellular carbonates

Estelle Couradeau, Karim Benzerara, Emmanuelle Gérard, David Moreira, Sylvain Bernard, Gordon E. Brown, Purificación López-García

Ecosystem Science and Management

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

178 Scopus citations

Abstract

Cyanobacteria have affected major geochemical cycles (carbon, nitrogen, and oxygen) on Earth for billions of years. In particular, they have played a major role in the formation of calcium carbonates (i.e., calcification), which has been considered to be an extracellular process. We identified a cyanobacterium in modern microbialites in Lake Alchichica (Mexico) that forms intracellular amorphous calcium-magnesium-strontium-barium carbonate inclusions about 270 nanometers in average diameter, revealing an unexplored pathway for calcification. Phylogenetic analyses place this cyanobacterium within the deeply divergent order Gloeobacterales. The chemical composition and structure of the intracellular precipitates suggest some level of cellular control on the biomineralization process. This discovery expands the diversity of organisms capable of forming amorphous calcium carbonates.

Original language	English (US)
Pages (from-to)	459-462
Number of pages	4
Journal	Science
Volume	336
Issue number	6080
DOIs	https://doi.org/10.1126/science.1216171
State	Published - Apr 27 2012

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abstract = "Cyanobacteria have affected major geochemical cycles (carbon, nitrogen, and oxygen) on Earth for billions of years. In particular, they have played a major role in the formation of calcium carbonates (i.e., calcification), which has been considered to be an extracellular process. We identified a cyanobacterium in modern microbialites in Lake Alchichica (Mexico) that forms intracellular amorphous calcium-magnesium-strontium-barium carbonate inclusions about 270 nanometers in average diameter, revealing an unexplored pathway for calcification. Phylogenetic analyses place this cyanobacterium within the deeply divergent order Gloeobacterales. The chemical composition and structure of the intracellular precipitates suggest some level of cellular control on the biomineralization process. This discovery expands the diversity of organisms capable of forming amorphous calcium carbonates.",

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AU - Couradeau, Estelle

AU - Benzerara, Karim

AU - Gérard, Emmanuelle

AU - Moreira, David

AU - Bernard, Sylvain

AU - Brown, Gordon E.

AU - López-García, Purificación

PY - 2012/4/27

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AB - Cyanobacteria have affected major geochemical cycles (carbon, nitrogen, and oxygen) on Earth for billions of years. In particular, they have played a major role in the formation of calcium carbonates (i.e., calcification), which has been considered to be an extracellular process. We identified a cyanobacterium in modern microbialites in Lake Alchichica (Mexico) that forms intracellular amorphous calcium-magnesium-strontium-barium carbonate inclusions about 270 nanometers in average diameter, revealing an unexplored pathway for calcification. Phylogenetic analyses place this cyanobacterium within the deeply divergent order Gloeobacterales. The chemical composition and structure of the intracellular precipitates suggest some level of cellular control on the biomineralization process. This discovery expands the diversity of organisms capable of forming amorphous calcium carbonates.

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An early-branching microbialite cyanobacterium forms intracellular carbonates

Abstract

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