微生物分子生态学技术的不断发展,使得同时分析复杂生态系统中微生物的分布和功能特征成为可能.为了研究荧光原位杂交-纳米二次离子质谱技术(fluorescence in situ hybridization-Nano secondary ion mass spectroscopy,FISH-Nano SIMS...微生物分子生态学技术的不断发展,使得同时分析复杂生态系统中微生物的分布和功能特征成为可能.为了研究荧光原位杂交-纳米二次离子质谱技术(fluorescence in situ hybridization-Nano secondary ion mass spectroscopy,FISH-Nano SIMS)在环境微生物生态学上的应用,本研究采用稳定同位素标记的化合物13C-C6H12O6、15N-NH4Cl作为C源和N源,分别对纯培养锰氧化细菌假单胞菌Pseudomonas sp.QJX-1(培养基加锰及不加锰两种条件下),以及浅层土壤及厌氧污泥两种环境样品进行培养.利用FISH-NanoSIMS技术检测培养后样品中微生物体内12C-、13C-、12C14N-、12C15N-的分布特征及其丰度值,进而探讨纯菌及环境样品中微生物利用同位素碳氮源的情况.结果显示所有样品细菌分布区域对应的同位素碳氮(13C、15N)的含量均显著大于其自然丰度值,这表明Pseudomonas sp.QJX-1及环境样品中的微生物均能代谢13C-C6H12O6和15N-NH4Cl.研究进一步发现,Pseudomonas sp.QJX-1在碳氮源消耗至较低浓度时才进行锰氧化;浅层土壤和厌氧污泥中可能都存在同步硝化反硝化细菌群落.FISH和Nano SIMS技术联用能同时分析环境样品中特定微生物的分布特征及代谢功能,进而能更好地掌握环境样品中微生物群落的生理生态学特征.展开更多
The addition of traditional carbon sources(e.g.,acetate)could favor heterotrophic overgrowth in partial denitrification coupled with anammox(PD–A)systems,thus hindering the performance and stability of this novel was...The addition of traditional carbon sources(e.g.,acetate)could favor heterotrophic overgrowth in partial denitrification coupled with anammox(PD–A)systems,thus hindering the performance and stability of this novel wastewater nitrogen removal technology.Therefore,it is necessary to develop an effective,environmentally friendly,and inexpensive alternative.This study demonstrated the potential of formate to enhance the performance and community stability of PD–A under mainstream conditions.In a laboratory-scale biofilm reactor,formate addition(COD/NO_(3)^(–)–N=1.75)improved nitrogen removal efficiency(from 72.1±3.5%to 81.7±2.7%),EPS content(from 106.3±8.1 to 163.0±15.5 mg/gVSS)and increased anammox bacteria growth(predominantly Candidatus Brocadia,from 29.5±0.7%to 34.5±5.4%)while maintaining stable heterotrophs dominated by methylotrophic Desulfobacillus.FISH–NanoSIMS revealed a formate uptake using Ca.Brocadia and Desulfobacillus,with Ca.Brocadia being the major contributor to partial nitrate reduction to nitrite.Desulfobacillus can synthesize diverse hydrophobic amino acids and provide key nutrients for Ca.Brocadia.To achieve comparable nitrogen removal,the cost of the formate-driven PD–A process should be 11.2%lower than that of acetate.These results greatly enrich our understanding of C1 metabolism represented by formate in anammox communities and its application in the context of coupling partial denitrification–anammox toward enhanced nitrogen removal in global wastewater treatment systems.展开更多
文摘微生物分子生态学技术的不断发展,使得同时分析复杂生态系统中微生物的分布和功能特征成为可能.为了研究荧光原位杂交-纳米二次离子质谱技术(fluorescence in situ hybridization-Nano secondary ion mass spectroscopy,FISH-Nano SIMS)在环境微生物生态学上的应用,本研究采用稳定同位素标记的化合物13C-C6H12O6、15N-NH4Cl作为C源和N源,分别对纯培养锰氧化细菌假单胞菌Pseudomonas sp.QJX-1(培养基加锰及不加锰两种条件下),以及浅层土壤及厌氧污泥两种环境样品进行培养.利用FISH-NanoSIMS技术检测培养后样品中微生物体内12C-、13C-、12C14N-、12C15N-的分布特征及其丰度值,进而探讨纯菌及环境样品中微生物利用同位素碳氮源的情况.结果显示所有样品细菌分布区域对应的同位素碳氮(13C、15N)的含量均显著大于其自然丰度值,这表明Pseudomonas sp.QJX-1及环境样品中的微生物均能代谢13C-C6H12O6和15N-NH4Cl.研究进一步发现,Pseudomonas sp.QJX-1在碳氮源消耗至较低浓度时才进行锰氧化;浅层土壤和厌氧污泥中可能都存在同步硝化反硝化细菌群落.FISH和Nano SIMS技术联用能同时分析环境样品中特定微生物的分布特征及代谢功能,进而能更好地掌握环境样品中微生物群落的生理生态学特征.
基金funded by the Zhejiang Provincial Natural Science Foundation of China(No.LR23B070002)the General Program of the National Natural Science Foundation of China(No.22276165).
文摘The addition of traditional carbon sources(e.g.,acetate)could favor heterotrophic overgrowth in partial denitrification coupled with anammox(PD–A)systems,thus hindering the performance and stability of this novel wastewater nitrogen removal technology.Therefore,it is necessary to develop an effective,environmentally friendly,and inexpensive alternative.This study demonstrated the potential of formate to enhance the performance and community stability of PD–A under mainstream conditions.In a laboratory-scale biofilm reactor,formate addition(COD/NO_(3)^(–)–N=1.75)improved nitrogen removal efficiency(from 72.1±3.5%to 81.7±2.7%),EPS content(from 106.3±8.1 to 163.0±15.5 mg/gVSS)and increased anammox bacteria growth(predominantly Candidatus Brocadia,from 29.5±0.7%to 34.5±5.4%)while maintaining stable heterotrophs dominated by methylotrophic Desulfobacillus.FISH–NanoSIMS revealed a formate uptake using Ca.Brocadia and Desulfobacillus,with Ca.Brocadia being the major contributor to partial nitrate reduction to nitrite.Desulfobacillus can synthesize diverse hydrophobic amino acids and provide key nutrients for Ca.Brocadia.To achieve comparable nitrogen removal,the cost of the formate-driven PD–A process should be 11.2%lower than that of acetate.These results greatly enrich our understanding of C1 metabolism represented by formate in anammox communities and its application in the context of coupling partial denitrification–anammox toward enhanced nitrogen removal in global wastewater treatment systems.
