The interplay of hematite and photic biofilm triggers the acceleration of biotic nitrate removal

The soil-water interface is replete with photic biofilm and iron minerals; however, the potential of how iron minerals promote biotic nitrate removal is still unknown. This study investigates the physiological and ecological responses of photic biofilm to hematite (Fe2O3), in order to explore a prac...

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Bibliographic Details
Published in:Chemosphere (Oxford) 2024-06, Vol.358, p.142136-142136, Article 142136
Main Authors: Zhang, Xiguo, Zhao, Yanhui, Wang, Yimin, Qian, Haoliang, Xing, Jun, Joseph, Akaninyene, Rene, Eldon R., Li, Jizhou, Zhu, Ningyuan
Format: Article
Language:English
Subjects:
EPS
Hematite
Nitrate reductase
Nitrate removal
Reactive oxygen species
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Summary:The soil-water interface is replete with photic biofilm and iron minerals; however, the potential of how iron minerals promote biotic nitrate removal is still unknown. This study investigates the physiological and ecological responses of photic biofilm to hematite (Fe2O3), in order to explore a practically feasible approach for in-situ nitrate removal. The nitrate removal by photic biofilm was significantly higher in the presence of Fe2O3 (92.5%) compared to the control (82.8%). Results show that the presence of Fe2O3 changed the microbial community composition of the photic biofilm, facilitates the thriving of Magnetospirillum and Pseudomonas, and promotes the growth of photic biofilm represented by the extracellular polymeric substance (EPS) and the content of chlorophyll. The presence of Fe2O3 also induces oxidative stress (•O2−) in the photic biofilm, which was demonstrated by electron spin resonance spectrometry. However, the photic biofilm could improve the EPS productivity to prevent the entrance of Fe2O3 to cells in the biofilm matrix and mitigate oxidative stress. The Fe2O3 then promoted the relative abundance of Magnetospirillum and Pseudomonas and the activity of nitrate reductase, which accelerates nitrate reduction by the photic biofilm. This study provides an insight into the interaction between iron minerals and photic biofilm and demonstrates the possibility of combining biotic and abiotic methods to improve the in-situ nitrate removal rate. [Display omitted] •The interaction between hematite and photic biofilm promoted nitrate removal.•The majority of Fe2O3 was distributed in the EPS matrix in particle form.•Hematite resulted in enhanced growth of biofilm with higher EPS productivity.•Hematite promoted the growth of denitrified biofilm to accelerate nitrate removal.
ISSN:0045-6535
1879-1298
DOI:10.1016/j.chemosphere.2024.142136