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Autori principali: Yu, Huang, Liu, Shengwei, Zhang, Dandan, Hu, Ruiwen, Chen, Pubo, Liu, Huanping, Zhou, Qiang, Tan, Wenfa, Hu, Nan, He, Zhili, Ding, Dexin, Yan, Qingyun
Natura: Artículo científico
Lingua:en
Pubblicazione: Environmental science & technology 2025
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Accesso online:https://pubmed.ncbi.nlm.nih.gov/39810418/
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author Yu, Huang
Liu, Shengwei
Zhang, Dandan
Hu, Ruiwen
Chen, Pubo
Liu, Huanping
Zhou, Qiang
Tan, Wenfa
Hu, Nan
He, Zhili
Ding, Dexin
Yan, Qingyun
author_facet Yu, Huang
Liu, Shengwei
Zhang, Dandan
Hu, Ruiwen
Chen, Pubo
Liu, Huanping
Zhou, Qiang
Tan, Wenfa
Hu, Nan
He, Zhili
Ding, Dexin
Yan, Qingyun
Yu, Huang
Liu, Shengwei
Zhang, Dandan
Hu, Ruiwen
Chen, Pubo
Liu, Huanping
Zhou, Qiang
Tan, Wenfa
Hu, Nan
He, Zhili
Ding, Dexin
Yan, Qingyun
collection PubMed - marine biology
contents Specific Enrichment of Carrying Microorganisms with Nitrogen Fixation and Dissimilatory Nitrate Reduction Function Enhances Arsenic Methylation in Plant Rhizosphere Soil. Yu, Huang Liu, Shengwei Zhang, Dandan Hu, Ruiwen Chen, Pubo Liu, Huanping Zhou, Qiang Tan, Wenfa Hu, Nan He, Zhili Ding, Dexin Yan, Qingyun Rhizosphere Arsenic Nitrogen Fixation Soil Microbiology Methylation Nitrates Soil Soil Pollutants Plants can recruit microorganisms to enhance soil arsenic (As) removal and nitrogen (N) turnover, but how microbial As methylation in the rhizosphere is affected by N biotransformation is not well understood. Here, we used acetylene reduction assay, gene amplicon, and metagenome sequencing to evaluate the influence of N biotransformation on As methylation in the rhizosphere of , a potential As hyperaccumulator. was grown in mining soils (MS) and artificial As-contaminated soils (AS) over two generations in a controlled pot experiment. Results showed that the content of dimethylarsinic acid in the rhizosphere was significantly positively correlated with the rate of N fixation and the activity of nitrite reductase. The As-methylating species (e.g., and ) were significantly enriched in the root-associated compartments in the second generation of MS and AS. Notably, higher abundance of genes involved in N fixation (, ) and dissimilatory nitrate reduction to ammonium (/, ///) was detected in the second generation of MS than in the first generation. The metabolic pathway analysis further demonstrated that N fixing-stimulative and DNRA-stimulative As-methylating species could provide ammonium to enhance the synthesis of -adenosyl-l-methionine, serving as methyl donors for soil As methylation. This study highlights two important N conversion-stimulative As-methylating pathways and has important implications for enhancing phytoremediation in As-contaminated soils.
format Artículo científico
id pubmed_39810418
institution PubMed
language en
publishDate 2025
publisher Environmental science & technology
record_format pubmed
spellingShingle Specific Enrichment of Carrying Microorganisms with Nitrogen Fixation and Dissimilatory Nitrate Reduction Function Enhances Arsenic Methylation in Plant Rhizosphere Soil.
Yu, Huang
Liu, Shengwei
Zhang, Dandan
Hu, Ruiwen
Chen, Pubo
Liu, Huanping
Zhou, Qiang
Tan, Wenfa
Hu, Nan
He, Zhili
Ding, Dexin
Yan, Qingyun
Rhizosphere
Arsenic
Nitrogen Fixation
Soil Microbiology
Methylation
Nitrates
Soil
Soil Pollutants
Specific Enrichment of Carrying Microorganisms with Nitrogen Fixation and Dissimilatory Nitrate Reduction Function Enhances Arsenic Methylation in Plant Rhizosphere Soil. Yu, Huang Liu, Shengwei Zhang, Dandan Hu, Ruiwen Chen, Pubo Liu, Huanping Zhou, Qiang Tan, Wenfa Hu, Nan He, Zhili Ding, Dexin Yan, Qingyun Rhizosphere Arsenic Nitrogen Fixation Soil Microbiology Methylation Nitrates Soil Soil Pollutants Plants can recruit microorganisms to enhance soil arsenic (As) removal and nitrogen (N) turnover, but how microbial As methylation in the rhizosphere is affected by N biotransformation is not well understood. Here, we used acetylene reduction assay, gene amplicon, and metagenome sequencing to evaluate the influence of N biotransformation on As methylation in the rhizosphere of , a potential As hyperaccumulator. was grown in mining soils (MS) and artificial As-contaminated soils (AS) over two generations in a controlled pot experiment. Results showed that the content of dimethylarsinic acid in the rhizosphere was significantly positively correlated with the rate of N fixation and the activity of nitrite reductase. The As-methylating species (e.g., and ) were significantly enriched in the root-associated compartments in the second generation of MS and AS. Notably, higher abundance of genes involved in N fixation (, ) and dissimilatory nitrate reduction to ammonium (/, ///) was detected in the second generation of MS than in the first generation. The metabolic pathway analysis further demonstrated that N fixing-stimulative and DNRA-stimulative As-methylating species could provide ammonium to enhance the synthesis of -adenosyl-l-methionine, serving as methyl donors for soil As methylation. This study highlights two important N conversion-stimulative As-methylating pathways and has important implications for enhancing phytoremediation in As-contaminated soils.
title Specific Enrichment of Carrying Microorganisms with Nitrogen Fixation and Dissimilatory Nitrate Reduction Function Enhances Arsenic Methylation in Plant Rhizosphere Soil.
topic Rhizosphere
Arsenic
Nitrogen Fixation
Soil Microbiology
Methylation
Nitrates
Soil
Soil Pollutants
url https://pubmed.ncbi.nlm.nih.gov/39810418/