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Adding siderophores: A new strategy to reduce greenhouse gas emissions in composting

Liyan Jiang, Yuting Zhao, Yuqing Yao, Jingxuan Lou, Yuxiang Zhao, Baolan Hu

2023Bioresource Technology32 citationsDOIOpen Access PDF

Abstract

Microbial community is the primary driver causing the greenhouse gas emissions in composting. Thus, regulating the microbial communities is a strategy to reduce them. Here, two different siderophores (enterobactin and putrebactin) were added, which could bind and translocate iron by specific microbes, to regulate the composting communities. The results showed that adding enterobactin enriched Acinetobacter and Bacillus with specific receptors by 6.84-fold and 6.78-fold. It promoted carbohydrate degradation and amino acid metabolism. This resulted in a 1.28-fold increase in humic acid content, as well as a 14.02% and 18.27% decrease in CO 2 and CH 4 emissions, respectively. Meanwhile, adding putrebactin boosted the microbial diversity by 1.21-fold and enhanced potential microbial interactions by 1.76-fold. The attenuated denitrification process led to a 1.51-fold increase in the total nitrogen content and a 27.47% reduction in N 2 O emissions. Overall, adding siderophores is an efficient strategy to reduce greenhouse gas emissions and promote the compost quality.

Topics & Concepts

SiderophoreEnterobactinCompostGreenhouse gasChemistryMicrobial population biologyFood scienceMicrobial inoculantMicroorganismMethaneEnvironmental chemistryBacteriaBiochemistryBiologyAgronomyEcologyOrganic chemistryGeneticsGeneComposting and Vermicomposting TechniquesNematode management and characterization studiesPharmaceutical and Antibiotic Environmental Impacts
Adding siderophores: A new strategy to reduce greenhouse gas emissions in composting | Litcius