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Enhancing microbial superoxide generation and conversion to hydroxyl radicals for enhanced bioremediation using iron-binding ligands

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Enhancing microbial superoxide generation and conversion to hydroxyl radicals for enhanced bioremediation using iron-binding ligands
Harnessing bacteria for superoxide production in bioremediation holds immense promise,yet its practical application is hindered by slow production rates and the relatively weak redox potential of superoxide.This study delves into a cost-effective approach to amplify superoxide production using an Arthrobacter strain,a prevalent soil bacterial genus.Our re-search reveals that introducing a carbon source along with specific iron-binding ligands,in-cluding deferoxamine(DFO),diethylenetriamine pentaacetate(DTPA),citrate,and oxalate,robustly augments microbial superoxide generation.Moreover,our findings suggest that these iron-binding ligands play a pivotal role in converting superoxide into hydroxyl radi-cals by modulating the electron transfer rate between Fe(Ⅲ)/Fe(Ⅱ)and superoxide.Remark-ably,among the tested ligands,only DTPA emerges as a potent promoter of this conversion process when complexed with Fe(Ⅲ).We identify an optimal Fe(Ⅲ)to DTPA ratio of ap-proximately 1:1 for enhancing hydroxyl radical production within the Arthrobacter culture.This research underscores the efficacy of simultaneously introducing carbon sources and DTPA in facilitating superoxide production and its subsequent conversion to hydroxyl rad-icals,significantly elevating bioremediation performance.Furthermore,our study reveals that DTPA augments superoxide production in cultures of diverse soils,with various soil mi-croorganisms beyond Arthrobacter identified as contributors to superoxide generation.This emphasizes the universal applicability of DTPA across multiple bacterial genera.In conclu-sion,our study introduces a promising methodology for enhancing microbial superoxide production and its conversion into hydroxyl radicals.These findings hold substantial impli-cations for the deployment of microbial reactive oxygen species in bioremediation,offering innovative solutions for addressing environmental contamination challenges.

SuperoxideHydroxyl radicalIron-binding ligandBioremediationDTPA

Yuhan Wang、Xue Ning、Jinsong Liang、Aijie Wang、Jiuhui Qu

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School of Civil and Environmental Engineering,Harbin Institute of Technology,Shenzhen 518055,China

SFI MaREI Centre for Energy,Climate and Marine,Environmental Research Institute,University College Cork,Cork,Ireland

Center for Water and Ecology,Tsinghua University,Beijing 100084,China

Superoxide Hydroxyl radical Iron-binding ligand Bioremediation DTPA

2025

10.1016/j.jes.2023.11.023

环境科学学报(英文版)
中科院生态环境研究中心

环境科学学报(英文版)

影响因子:0.862
ISSN:1001-0742
年,卷(期):2025.147(1)