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Main Authors: Lai, Anxing, Fan, Shiming, Xue, Jingya, Wang, Hongwei, Xie, Ke, Li, Huabing, Xu, Hai, Li, Biao, Wu, Qinglong L
Format: Artículo científico
Language:en
Published: Journal of environmental sciences (China) 2025
Subjects:
Online Access:https://pubmed.ncbi.nlm.nih.gov/39617544/
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author Lai, Anxing
Fan, Shiming
Xue, Jingya
Wang, Hongwei
Xie, Ke
Li, Huabing
Xu, Hai
Li, Biao
Wu, Qinglong L
author_facet Lai, Anxing
Fan, Shiming
Xue, Jingya
Wang, Hongwei
Xie, Ke
Li, Huabing
Xu, Hai
Li, Biao
Wu, Qinglong L
Lai, Anxing
Fan, Shiming
Xue, Jingya
Wang, Hongwei
Xie, Ke
Li, Huabing
Xu, Hai
Li, Biao
Wu, Qinglong L
collection PubMed - marine biology
contents Ammonium removal through anaerobic ammonium oxidation coupled to iron(III) reduction along the Yangtze river-estuary continuum. Lai, Anxing Fan, Shiming Xue, Jingya Wang, Hongwei Xie, Ke Li, Huabing Xu, Hai Li, Biao Wu, Qinglong L Ammonium Compounds Rivers Oxidation-Reduction Water Pollutants, Chemical Iron China Anaerobiosis Geologic Sediments Anaerobic ammonium oxidation coupled to iron(III) reduction (Feammox) process has recently been recognized as an important pathway for removing ammonium in various natural habitats. However, our understanding for Feammox in river-estuary continuum is limited. In this study, stable isotope tracers and high-throughput amplicon sequencing were employed to determine Feammox rates and identify associated microbial communities in sediments along the Yangtze river-estuary continuum. Feammox rates averaged 0.0058 ± 0.0069 mg N/(kg·d) and accounted for approximately 22.3% of the ammonium removed from the sediments. Sediment Fe(III), ammonium (NH), total organic carbon (TOC), and pH were identified as important factors influencing Feammox rates. Additionally, Spirochaeta, Caldilineaceae_uncultured, and Ignavibacterium were found potentially associated with Feammox, which had not been documented as Feammox-associated microbial taxa previously. This study demonstrates that Feammox plays a vital role in ammonium removal within the Yangtze river-estuary continuum, providing greater insight into nitrogen removal and cycling in aquatic ecosystems.
format Artículo científico
id pubmed_39617544
institution PubMed
language en
publishDate 2025
publisher Journal of environmental sciences (China)
record_format pubmed
spellingShingle Ammonium removal through anaerobic ammonium oxidation coupled to iron(III) reduction along the Yangtze river-estuary continuum.
Lai, Anxing
Fan, Shiming
Xue, Jingya
Wang, Hongwei
Xie, Ke
Li, Huabing
Xu, Hai
Li, Biao
Wu, Qinglong L
Ammonium Compounds
Rivers
Oxidation-Reduction
Water Pollutants, Chemical
Iron
China
Anaerobiosis
Geologic Sediments
Ammonium removal through anaerobic ammonium oxidation coupled to iron(III) reduction along the Yangtze river-estuary continuum. Lai, Anxing Fan, Shiming Xue, Jingya Wang, Hongwei Xie, Ke Li, Huabing Xu, Hai Li, Biao Wu, Qinglong L Ammonium Compounds Rivers Oxidation-Reduction Water Pollutants, Chemical Iron China Anaerobiosis Geologic Sediments Anaerobic ammonium oxidation coupled to iron(III) reduction (Feammox) process has recently been recognized as an important pathway for removing ammonium in various natural habitats. However, our understanding for Feammox in river-estuary continuum is limited. In this study, stable isotope tracers and high-throughput amplicon sequencing were employed to determine Feammox rates and identify associated microbial communities in sediments along the Yangtze river-estuary continuum. Feammox rates averaged 0.0058 ± 0.0069 mg N/(kg·d) and accounted for approximately 22.3% of the ammonium removed from the sediments. Sediment Fe(III), ammonium (NH), total organic carbon (TOC), and pH were identified as important factors influencing Feammox rates. Additionally, Spirochaeta, Caldilineaceae_uncultured, and Ignavibacterium were found potentially associated with Feammox, which had not been documented as Feammox-associated microbial taxa previously. This study demonstrates that Feammox plays a vital role in ammonium removal within the Yangtze river-estuary continuum, providing greater insight into nitrogen removal and cycling in aquatic ecosystems.
title Ammonium removal through anaerobic ammonium oxidation coupled to iron(III) reduction along the Yangtze river-estuary continuum.
topic Ammonium Compounds
Rivers
Oxidation-Reduction
Water Pollutants, Chemical
Iron
China
Anaerobiosis
Geologic Sediments
url https://pubmed.ncbi.nlm.nih.gov/39617544/