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Auteurs principaux: Guo, Shuju, Shuai, Hui, Zhang, Litao, Yang, Na
Format: Artículo científico
Langue:en
Publié: Microbiological research 2026
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Accès en ligne:https://pubmed.ncbi.nlm.nih.gov/41905332/
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author Guo, Shuju
Shuai, Hui
Zhang, Litao
Yang, Na
author_facet Guo, Shuju
Shuai, Hui
Zhang, Litao
Yang, Na
Guo, Shuju
Shuai, Hui
Zhang, Litao
Yang, Na
collection PubMed - marine biology
contents Mn(II) oxidation is associated with improved growth and metabolic reconfiguration under nutrient restriction in Sphingopyxis sp. MAB15: Implications for deep-sea ferromanganese nodule formation. Guo, Shuju Shuai, Hui Zhang, Litao Yang, Na Manganese Oxidation-Reduction Sphingomonadaceae Manganese Compounds Oxidoreductases Oxides Bacterial Proteins Reactive Oxygen Species Oxidative Stress Proteomics Nutrients Biomass Seawater Phylogeny Although microbial Mn(II) oxidation has been implicated in the formation of deep-sea ferromanganese nodules, the physiological benefits that this process confers on indigenous bacteria remain poorly understood. While Sphingopyxis species are ubiquitous in nodule environments, their capacity for Mn(II) oxidation in pure culture has not been demonstrated. In this study, we identified Sphingopyxis sp. MAB15, isolated from abyssal nodules, as a Mn(II)-oxidizing bacterium and characterized two multicopper oxidases (encoded by ge000511 and ge001504) involved in this activity. Recombinant proteins GE000511 and GE001504 catalyzed manganese oxide formation in vitro in a Cu-dependent assay. Under nutrient-restricted conditions, MnCO addition led to biogenic Mn oxide formation and was associated with higher biomass accumulation and lower specific oxygen consumption. Comparative proteomics revealed broad changes in protein abundance suggestive of altered cellular resource allocation, including reduced abundance of multiple respiratory- and oxidative-stress-related proteins and increased abundance of biosynthetic and translational components. MnCO-supplemented cultures also showed lower intracellular reactive oxygen species levels and reduced abundance of several antioxidant enzymes, consistent with lower oxidative stress in the presence of Mn(II) and/or biogenic Mn oxides. Collectively, these findings support the hypothesis that Mn(II) oxidation may be associated with improved physiological performance under nutrient restriction and suggest that such responses could contribute to biogenic Mn oxide accumulation relevant to deep-sea ferromanganese nodule formation.
format Artículo científico
id pubmed_41905332
institution PubMed
language en
publishDate 2026
publisher Microbiological research
record_format pubmed
spellingShingle Mn(II) oxidation is associated with improved growth and metabolic reconfiguration under nutrient restriction in Sphingopyxis sp. MAB15: Implications for deep-sea ferromanganese nodule formation.
Guo, Shuju
Shuai, Hui
Zhang, Litao
Yang, Na
Manganese
Oxidation-Reduction
Sphingomonadaceae
Manganese Compounds
Oxidoreductases
Oxides
Bacterial Proteins
Reactive Oxygen Species
Oxidative Stress
Proteomics
Nutrients
Biomass
Seawater
Phylogeny
Mn(II) oxidation is associated with improved growth and metabolic reconfiguration under nutrient restriction in Sphingopyxis sp. MAB15: Implications for deep-sea ferromanganese nodule formation. Guo, Shuju Shuai, Hui Zhang, Litao Yang, Na Manganese Oxidation-Reduction Sphingomonadaceae Manganese Compounds Oxidoreductases Oxides Bacterial Proteins Reactive Oxygen Species Oxidative Stress Proteomics Nutrients Biomass Seawater Phylogeny Although microbial Mn(II) oxidation has been implicated in the formation of deep-sea ferromanganese nodules, the physiological benefits that this process confers on indigenous bacteria remain poorly understood. While Sphingopyxis species are ubiquitous in nodule environments, their capacity for Mn(II) oxidation in pure culture has not been demonstrated. In this study, we identified Sphingopyxis sp. MAB15, isolated from abyssal nodules, as a Mn(II)-oxidizing bacterium and characterized two multicopper oxidases (encoded by ge000511 and ge001504) involved in this activity. Recombinant proteins GE000511 and GE001504 catalyzed manganese oxide formation in vitro in a Cu-dependent assay. Under nutrient-restricted conditions, MnCO addition led to biogenic Mn oxide formation and was associated with higher biomass accumulation and lower specific oxygen consumption. Comparative proteomics revealed broad changes in protein abundance suggestive of altered cellular resource allocation, including reduced abundance of multiple respiratory- and oxidative-stress-related proteins and increased abundance of biosynthetic and translational components. MnCO-supplemented cultures also showed lower intracellular reactive oxygen species levels and reduced abundance of several antioxidant enzymes, consistent with lower oxidative stress in the presence of Mn(II) and/or biogenic Mn oxides. Collectively, these findings support the hypothesis that Mn(II) oxidation may be associated with improved physiological performance under nutrient restriction and suggest that such responses could contribute to biogenic Mn oxide accumulation relevant to deep-sea ferromanganese nodule formation.
title Mn(II) oxidation is associated with improved growth and metabolic reconfiguration under nutrient restriction in Sphingopyxis sp. MAB15: Implications for deep-sea ferromanganese nodule formation.
topic Manganese
Oxidation-Reduction
Sphingomonadaceae
Manganese Compounds
Oxidoreductases
Oxides
Bacterial Proteins
Reactive Oxygen Species
Oxidative Stress
Proteomics
Nutrients
Biomass
Seawater
Phylogeny
url https://pubmed.ncbi.nlm.nih.gov/41905332/