ARPHA Conference Abstracts :
Conference Abstract
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Corresponding author: Cristina Escudero Parada (c.escudero@uni-tuebingen.de)
Received: 16 Jun 2023 | Published: 13 Oct 2023
© 2023 Cristina Escudero Parada, Andreas Kappler
This is an open access article distributed under the terms of the Creative Commons Attribution License (CC BY 4.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Citation:
Escudero Parada C, Kappler A (2023) Nitrate-Reducing Fe(II)-Oxidizing microorganisms: linking Fe, C and N Cycles in subsurface environments. ARPHA Conference Abstracts 6: e108089. https://doi.org/10.3897/aca.6.e108089
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The discovery of the Nitrate-Reducing Fe(II)-Oxidizing (NRFeOx) microbial metabolism, which couples the oxidation of Fe(II) to the reduction of nitrate (NO3-) using organic matter or carbon dioxide (CO2) as carbon source, was a major milestone in microbial ecology (
A plethora of NRFeOx microorganisms have been described in the last decades. However, most of these microorganisms have been reclassified as chemodenitrifiers. That is to say, Fe(II) is not enzymatically oxidized but indirectly by the reactive nitrogen species produced during denitrification (Fig.
Overview of the three different types of interaction between nitrate-reducing bacteria and Fe(II). (A) Autotrophic NRFeOx obtain carbon from CO2 and oxidize Fe(II) enzymatically. (B) Mixotrophic NRFeOx require additional organic carbon as a carbon source, and Fe(II) oxidation has some enzymatic component (although there may also be some abiotic component). (C) Chemodenitrifiers require organic carbon and have no enzymatic component of Fe(II) oxidation. The position of the minerals (orange) relative to cells (black) indicates whether or not cell encrustation is expected. Image from
Cultures KS, BP and AG have been studied thoroughly in the past years, analyzing the rate and mechanism by which these communities carry out autotrophic NRFeOx. Different omics studies have revealed that cultures KS, BP and AG consist of a mixture of bacterial species, which collaborate in order to grow under autotrophic NRFeOx conditions. Each culture is dominated by a novel candidate species of the genus Ferrigenium (
Interestingly, these communities not only carry out NRFeOx using dissolved Fe(II) as energy source (
Here, we will present a review of the insights learned from the three NRFeOx autotrophic cultures and discuss their ecological role, their importance in biogeochemical cycles, and their potential biotechnological applications.
geomicrobiology, biogeochemical cycles, bioremediation
Cristina Escudero Parada
ISEB-ISSM 2023
Teach@Tübingen program
Eberhard-Karls-University of Tübingen