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Research on nitrogen transformation pathways of a thermophilic heterotrophic nitrifying bacterial consortium GW7

Yongqi Ma, Jiali Wang, Yindi Zhang, Weiping Guan, Wenbo Qi, Xisheng Tai, Dong Lin, Rong‐Rong He, Likun Sun, Aiwen Zhang

2025Frontiers in Microbiology8 citationsDOIOpen Access PDF

Abstract

Introduction: High-temperature heterotrophic nitrifying bacteria play a crucial role in the thermophilic phase of aerobic composting by effectively converting reduced ammonia sources. This process reduces ammonia emissions and contributes to nitrogen fixation, thus showcasing a high potential for application. The study aims to isolate and characterize a high-temperature-tolerant heterotrophic nitrifying bacterial consortium to enhance nitrogen transformation during aerobic composting. Methods: An excellent high-temperature-tolerant heterotrophic nitrifying bacterial consortium, designated GW7, was enriched from compost samples at elevated temperatures. The bacterial consortium was cultured under varying conditions to determine optimal cultivation parameters. Response surface methodology (RSM) experiments were conducted to find the best conditions for ammonia and nitrate nitrogen utilization. Enzymatic assays were carried out to measure the specific activities of key enzymes, including glutamine synthetase (GS), glutamate dehydrogenase (GDH), glutamate synthetase (GOGAT), ammonia monooxygenase (AMO), and hydroxylamine oxidoreductase (HAO). Results: -N utilization efficiency increased to 87.80%. Enzymatic assays showed that the specific activities of GS, GDH, and GOGAT were 0.392 U/mg, 0.926 U/mg, and 0.195 U/mg, respectively. Moreover, the specific activities of AMO and HAO were 1.459 U/mg and 0.701 U/mg, respectively. Discussion: The GW7 consortium demonstrated excellent nitrogen transformation capabilities, effectively utilizing ammonia nitrogen and contributing to the reduction of nitrogen losses in the aerobic composting process. The high enzymatic activities of key nitrogen-metabolizing enzymes, including AMO and HAO, support its role in heterotrophic nitrification. The proposed nitrogen conversion pathways, including ammonia assimilation, heterotrophic nitrification, and assimilatory nitrate reduction, highlight the versatile nitrogen metabolism of this bacterial consortium. The optimized cultivation conditions further enhance its practical application potential in mitigating nitrogen emissions during composting processes.

Topics & Concepts

Ammonia monooxygenaseHeterotrophGlutamate dehydrogenaseAmmoniaNitrogen cycleNitrogen fixationNitrifying bacteriaGlutamine synthetaseNitrificationChemistryNitrogenFood scienceEnvironmental chemistryBiologyBiochemistryBacteriaGlutamineAmino acidOrganic chemistryReceptorGlutamate receptorGeneticsComposting and Vermicomposting TechniquesWastewater Treatment and Nitrogen RemovalSoil Carbon and Nitrogen Dynamics
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