Physiology of phototrophic iron(II)-oxidizing bacteria: Implications for modern and ancient environments

Florian Hegler; Nicole R. Posth; Jie Jiang; Andreas Kappler

doi:10.1111/j.1574-6941.2008.00592.x

Physiology of phototrophic iron(II)-oxidizing bacteria: Implications for modern and ancient environments

Florian Hegler, Nicole R. Posth, Jie Jiang, Andreas Kappler

Geology

127 Citations (Scopus)

Abstract

Phototrophic iron(II) [Fe(II)]-oxidizing bacteria are present in modern environments and evidence suggests that this metabolism was present already on early earth. We determined Fe(II) oxidation rates depending on pH, temperature, light intensity, and Fe(II) concentration for three phylogenetically different phototrophic Fe(II)-oxidizing strains (purple nonsulfur bacterium Rhodobacter ferrooxidans sp. strain SW2, purple sulfur bacterium Thiodictyon sp. strain F4, and green sulfur bacterium Chlorobium ferrooxidans strain KoFox). While we found the overall highest Fe(II) oxidation rates with strain F4 (4.5 mmol L(-1) day(-1), 800 lux, 20 degrees C), the lowest light saturation values [at which maximum Fe(II) oxidation occurred] were determined for strain KoFox with light saturation already below 50 lux. The oxidation rate per cell was determined for R. ferrooxidans strain SW2 to be 32 pmol Fe(II) h(-1) per cell. No significant toxic effect of Fe(II) was observed at Fe(II) concentrations of up to 30 mM. All three strains are mesophiles with upper temperature limits of c. 30 degrees C. The main pigments were identified to be spheroidene, spheroidenone, OH-spheroidenone (SW2), rhodopinal (F4), and chlorobactene (KoFox). This study will improve our ecophysiological understanding of iron cycling in modern environments and will help to evaluate whether phototrophic iron oxidizers may have contributed to the formation of Fe(III) on early earth.

Original language	English
Title of host publication	FEMS Microbiology Ecology
Number of pages	11
Publication date	Nov 2008
Pages	250-260
ISBN (Print)	1574-6941
DOIs	https://doi.org/10.1111/j.1574-6941.2008.00592.x
Publication status	Published - Nov 2008

Keywords

Banded iron formations
Ferrous iron
Iron cycling
Phototrophic Fe(II) oxidation

Access to Document

10.1111/j.1574-6941.2008.00592.x

http://www.mendeley.com/research/physiology-phototrophic-ironiioxidizing-bacteria-implications-modern-ancient-environments

Cite this

@inbook{b0c66a63a4d740d6b89a336f75a8cfbe,

title = "Physiology of phototrophic iron(II)-oxidizing bacteria: Implications for modern and ancient environments",

abstract = "Phototrophic iron(II) [Fe(II)]-oxidizing bacteria are present in modern environments and evidence suggests that this metabolism was present already on early earth. We determined Fe(II) oxidation rates depending on pH, temperature, light intensity, and Fe(II) concentration for three phylogenetically different phototrophic Fe(II)-oxidizing strains (purple nonsulfur bacterium Rhodobacter ferrooxidans sp. strain SW2, purple sulfur bacterium Thiodictyon sp. strain F4, and green sulfur bacterium Chlorobium ferrooxidans strain KoFox). While we found the overall highest Fe(II) oxidation rates with strain F4 (4.5 mmol L(-1) day(-1), 800 lux, 20 degrees C), the lowest light saturation values [at which maximum Fe(II) oxidation occurred] were determined for strain KoFox with light saturation already below 50 lux. The oxidation rate per cell was determined for R. ferrooxidans strain SW2 to be 32 pmol Fe(II) h(-1) per cell. No significant toxic effect of Fe(II) was observed at Fe(II) concentrations of up to 30 mM. All three strains are mesophiles with upper temperature limits of c. 30 degrees C. The main pigments were identified to be spheroidene, spheroidenone, OH-spheroidenone (SW2), rhodopinal (F4), and chlorobactene (KoFox). This study will improve our ecophysiological understanding of iron cycling in modern environments and will help to evaluate whether phototrophic iron oxidizers may have contributed to the formation of Fe(III) on early earth.",

keywords = "Banded iron formations, Ferrous iron, Iron cycling, Phototrophic Fe(II) oxidation",

author = "Florian Hegler and Posth, {Nicole R.} and Jie Jiang and Andreas Kappler",

year = "2008",

month = nov,

doi = "10.1111/j.1574-6941.2008.00592.x",

language = "English",

isbn = "1574-6941",

pages = "250--260",

booktitle = "FEMS Microbiology Ecology",

}

TY - CHAP

T1 - Physiology of phototrophic iron(II)-oxidizing bacteria: Implications for modern and ancient environments

AU - Hegler, Florian

AU - Posth, Nicole R.

AU - Jiang, Jie

AU - Kappler, Andreas

PY - 2008/11

Y1 - 2008/11

N2 - Phototrophic iron(II) [Fe(II)]-oxidizing bacteria are present in modern environments and evidence suggests that this metabolism was present already on early earth. We determined Fe(II) oxidation rates depending on pH, temperature, light intensity, and Fe(II) concentration for three phylogenetically different phototrophic Fe(II)-oxidizing strains (purple nonsulfur bacterium Rhodobacter ferrooxidans sp. strain SW2, purple sulfur bacterium Thiodictyon sp. strain F4, and green sulfur bacterium Chlorobium ferrooxidans strain KoFox). While we found the overall highest Fe(II) oxidation rates with strain F4 (4.5 mmol L(-1) day(-1), 800 lux, 20 degrees C), the lowest light saturation values [at which maximum Fe(II) oxidation occurred] were determined for strain KoFox with light saturation already below 50 lux. The oxidation rate per cell was determined for R. ferrooxidans strain SW2 to be 32 pmol Fe(II) h(-1) per cell. No significant toxic effect of Fe(II) was observed at Fe(II) concentrations of up to 30 mM. All three strains are mesophiles with upper temperature limits of c. 30 degrees C. The main pigments were identified to be spheroidene, spheroidenone, OH-spheroidenone (SW2), rhodopinal (F4), and chlorobactene (KoFox). This study will improve our ecophysiological understanding of iron cycling in modern environments and will help to evaluate whether phototrophic iron oxidizers may have contributed to the formation of Fe(III) on early earth.

AB - Phototrophic iron(II) [Fe(II)]-oxidizing bacteria are present in modern environments and evidence suggests that this metabolism was present already on early earth. We determined Fe(II) oxidation rates depending on pH, temperature, light intensity, and Fe(II) concentration for three phylogenetically different phototrophic Fe(II)-oxidizing strains (purple nonsulfur bacterium Rhodobacter ferrooxidans sp. strain SW2, purple sulfur bacterium Thiodictyon sp. strain F4, and green sulfur bacterium Chlorobium ferrooxidans strain KoFox). While we found the overall highest Fe(II) oxidation rates with strain F4 (4.5 mmol L(-1) day(-1), 800 lux, 20 degrees C), the lowest light saturation values [at which maximum Fe(II) oxidation occurred] were determined for strain KoFox with light saturation already below 50 lux. The oxidation rate per cell was determined for R. ferrooxidans strain SW2 to be 32 pmol Fe(II) h(-1) per cell. No significant toxic effect of Fe(II) was observed at Fe(II) concentrations of up to 30 mM. All three strains are mesophiles with upper temperature limits of c. 30 degrees C. The main pigments were identified to be spheroidene, spheroidenone, OH-spheroidenone (SW2), rhodopinal (F4), and chlorobactene (KoFox). This study will improve our ecophysiological understanding of iron cycling in modern environments and will help to evaluate whether phototrophic iron oxidizers may have contributed to the formation of Fe(III) on early earth.

KW - Banded iron formations

KW - Ferrous iron

KW - Iron cycling

KW - Phototrophic Fe(II) oxidation

U2 - 10.1111/j.1574-6941.2008.00592.x

DO - 10.1111/j.1574-6941.2008.00592.x

M3 - Book chapter

C2 - 18811650

SN - 1574-6941

SP - 250

EP - 260

BT - FEMS Microbiology Ecology

ER -

Physiology of phototrophic iron(II)-oxidizing bacteria: Implications for modern and ancient environments

Abstract

Keywords

Access to Document

Fingerprint

Cite this