Litcius/Paper detail

Soil microbial metabolism on carbon and nitrogen transformation links the crop-residue contribution to soil organic carbon

Zhihuang Xie, Zhenhua Yu, Yansheng Li, Guanghua Wang, Xiaobing Liu, Caixian Tang, Tengxiang Lian, Jonathan M. Adams, Junjie Liu, Judong Liu, Stephen Herbert, Jian Jin

2022npj Biofilms and Microbiomes108 citationsDOIOpen Access PDF

Abstract

Abstract The beneficial effect of crop residue amendment on soil organic carbon (SOC) stock and stability depends on the functional response of soil microbial communities. Here we synchronized microbial metagenomic analysis, nuclear magnetic resonance and plant- 15 N labeling technologies to gain understanding of how microbial metabolic processes affect SOC accumulation in responses to differences in N supply from residues. Residue amendment brought increases in the assemblage of genes involved in C-degradation profiles from labile to recalcitrant C compounds as well as N mineralization. The N mineralization genes were correlated with the C and N accumulation in the particulate and mineral-associated C pools, and plant-derived aliphatic forms of SOC. Thus, the combined C and N metabolic potential of the microbial community transforms residue into persistent organic compounds, thereby increasing C and N sequestration in stable SOC pools. This study emphasizes potential microbially mediated mechanisms by which residue N affects C sequestration in soils.

Topics & Concepts

Mineralization (soil science)Crop residueNitrogen cycleResidue (chemistry)AmendmentEnvironmental chemistryMicrobial population biologySoil carbonChemistryNitrogenCarbon sequestrationSoil waterBiodegradationSoil organic matterMicrobial biodegradationMetagenomicsAgronomyMicroorganismEnvironmental scienceSoil scienceBiologyEcologyBacteriaBiochemistryOrganic chemistryGenePolitical scienceLawGeneticsAgricultureSoil Carbon and Nitrogen DynamicsMicrobial Community Ecology and PhysiologyGenomics and Phylogenetic Studies