Enhanced carbon emission driven by the interaction between functional microbial community and hydrocarbons: An enlightenment for carbon cycle

微生物种群生物学 环境化学 微生物 碳循环 盐单胞菌属 碳纤维 土壤碳 微生物代谢 化学 环境科学 生态学 土壤水分 生物 细菌 生态系统 生物化学 复合数 基因 复合材料 遗传学 材料科学 16S核糖体RNA
作者
Zelin Hou,Qixing Zhou,Fan Mo,Weilu Kang,Shaohu Ouyang
出处
期刊:Science of The Total Environment [Elsevier BV]
卷期号:867: 161402-161402 被引量:17
标识
DOI:10.1016/j.scitotenv.2023.161402
摘要

Soil microbial communities are usually regarded as one of the key players in the global element cycling. Moreover, an important consequence of oil contamination altering the structure of microbial communities is likely to result in an increased carbon emission. However, understanding of the complex interactions between environmental factors and biological communities is clearly lagging behind. Here it showed that the flux of carbon emissions increased in oil-contaminated soils, up to 13.64 g C·(kg soil)-1·h-1. This phenomenon was mainly driven by the enrichment of rare degrading microorganisms (e.g., Methylosinus, Marinobacter, Pseudomonas, Alcanivorax, Yeosuana, Halomonas and Microbulbifer) in the aerobic layer, rather than the anaerobic layer, which is more conducive to methane formation. In addition, petroleum hydrocarbons and environmental factors are equally important in shaping the structure of microbial communities (the ecological stability) and functional traits (e.g., fatty acid metabolism, lipid metabolism and amino acid metabolism) due to the different ecological sensitivities of microorganisms. Thus, it can be believed that the variability of rare hydrocarbon degrading microorganisms is of greater concern than changes in dominant microorganisms in oil-contaminated soil. Undoubtedly, this study could reveal the unique characterization of bacterial communities that mediate carbon emission and provide evidence for understanding the conversion from carbon stores to carbon gas release in oil-contaminated soils.
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