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Salinity Impact on Composition and Activity of Nitrate-Reducing Fe(II)-Oxidizing Microorganisms in Saline Lakes

Jianrong Huang, Ming-Xian Han, Jian Yang, Andreas Kappler, Hongchen Jiang

2022Applied and Environmental Microbiology13 citationsDOIOpen Access PDF

Abstract

NRFeOx microorganisms are globally distributed in various types of environments and play a vital role in iron transformation and nitrate and heavy metal removal. However, most known NRFeOx microorganisms were isolated from freshwater and marine environments, while their identity and activity under hypersaline conditions remain unknown. Here, we demonstrated that salinity may affect the abundance, identity, and nutrition modes of NRFeOx microorganisms. Autotrophy was only detectable in a freshwater lake but not in the saline lake investigated. We enriched a mixotrophic culture capable of nitrate-reducing Fe(II) oxidation from hypersaline lake sediments. However, Fe(II) oxidation was probably caused by abiotic nitrite reduction (chemodenitrification) rather than by a biologically mediated process. Consequently, our study suggests that in hypersaline environments, Fe(II) oxidation is largely caused by chemodentrification initiated by nitrite formation by chemoheterotrophic bacteria, and additional experiments are needed to demonstrate whether or to what extent Fe(II) is enzymatically oxidized.

Topics & Concepts

SalinityOxidizing agentNitrateMicroorganismEnvironmental chemistryComposition (language)SalineChemistryEnvironmental scienceBiologyBacteriaEcologyPhilosophyEndocrinologyGeneticsLinguisticsOrganic chemistryMicrobial Fuel Cells and BioremediationWastewater Treatment and Nitrogen RemovalMicrobial Community Ecology and Physiology
Salinity Impact on Composition and Activity of Nitrate-Reducing Fe(II)-Oxidizing Microorganisms in Saline Lakes | Litcius