Red Mud Potentially Alleviates Ammonia Nitrogen Inhibition in Swine Manure Anaerobic Digestion by Enhancing Phage-Mediated Ammonia Assimilation

Red Mud Potentially Alleviates Ammonia Nitrogen Inhibition in Swine Manure Anaerobic Digestion by Enhancing Phage-Mediated Ammonia Assimilation

Red mud has been demonstrated to improve the methane production performance of anaerobic digestion (AD). However, the influence of red mud on ammonia nitrogen inhibition during AD through the mediating role of bacteria–phages interactions in this process remains poorly understood. Thus, this study i...

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Main Authors: Yulong Peng, Luhua Jiang, Junzhao Wu, Jiejie Yang, Ziwen Guo, Manjun Miao, Zhiyuan Peng, Meng Chang, Bo Miao, Hongwei Liu, Yili Liang, Huaqun Yin, Qiang He, Xueduan Liu
Format: Article
Language:English
Published: MDPI AG 2025-03-01
Series:Microorganisms
Subjects:
anaerobic digestion
red mud
phage
microbiomics
ammonia assimilation
swine manure
Online Access:https://www.mdpi.com/2076-2607/13/3/690
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Summary:Red mud has been demonstrated to improve the methane production performance of anaerobic digestion (AD). However, the influence of red mud on ammonia nitrogen inhibition during AD through the mediating role of bacteria–phages interactions in this process remains poorly understood. Thus, this study investigated the impact of red mud on nitrogen metabolism in AD and characterized the phage and prokaryotic communities through a metagenomic analysis. The results showed that red mud significantly increased methane production by 23.1% and promoted the conversion of ammonia nitrogen into organic nitrogen, resulting in a 4.8% increase in total nitrogen. Simultaneously, it enriched the key microbial genera <i>Methanothrix</i>, <i>Proteinophilum</i>, and <i>Petrimonas</i> by 0.5%, 0.8%, and 2.7%, respectively, suggesting an enhancement in syntrophic acetate oxidation with greater ammonia tolerance. A viral metagenomic analysis identified seven nitrogen-metabolism-related auxiliary metabolic genes (AMGs), with <i>glnA</i> (encoding glutamine synthetase) being the most abundant. Compared to the control treatments, the red mud treatments led to a higher abundance of temperate phages and an increased number of AMGs. Furthermore, two new hosts carrying <i>glnA</i> (<i>Mycolicibacteria smegmatis</i> and <i>Kitasatopola aureofaciens</i>) were predicted, indicating that red mud expanded the host range of phages and promoted the spread of AMGs. Overall, our findings highlight the importance of phages in alleviating ammonia nitrogen inhibition and provide a novel understanding of the role of red mud in the AD of swine manure.
ISSN:2076-2607

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