Nitrite-dependent anaerobic methane oxidation (n-damo), performed by the bacteria associated with Candidatus Methylomirabilis oxyfera, acts as a novel methane sink in coastal wetlands. Conversion of coastal wetlands i...Nitrite-dependent anaerobic methane oxidation (n-damo), performed by the bacteria associated with Candidatus Methylomirabilis oxyfera, acts as a novel methane sink in coastal wetlands. Conversion of coastal wetlands into paddy fields is a common land-use change that has profound effects on methane emissions, but its impact on n-damo process is nearly unknown. Our study adopted a space-for-time substitution method to compare n-damo activity and community of Methylomirabilis-like bacteria between natural vegetation covered by Phragmites australis, Kandelia candek, or Bruguiera sexangula and adjacent converted paddy fields in six China’s coastal wetlands. Generalized linear mixed model indicated that the activity of n-damo significantly increased by 43.6% and 165.8% after conversion of K. candek and B. sexangula wetlands into rice paddies, respectively, while the activity exhibited no significant change after conversion of P. australis wetlands. Furthermore, the abundance of Methylomirabilis-like bacteria significantly increased by 90.2%, 210.0%, and 110.1% following the conversion in wetlands covered by K. candek, B. sexangula, and P. australis, respectively. Principal co-ordinates analysis revealed significant changes in community structure of Methylomirabilis-like bacteria among vegetation types, with K. candek and B. sexangula showing a greater divergence than P. australis when compared to respective paddy fields. Path analysis indicated that land conversion resulted in changes in soil moisture content, organic carbon content, bulk density, and salinity and further affected the abundance of Methylomirabilis-like bacteria and ultimately n-damo activity. Overall, this is the first study to reveal the impact of conversion of coastal wetlands into paddy fields on n-damo activity and Methylomirabilis-like bacteria, and the impact was closely associated with the original native plant types. The results can enhance our understanding of the microbial-driven mechanisms of the impact of land conversion on methane emissions.展开更多
Nitrogen-cycling microorganisms play key roles at the intersection of microbiology and wastewater engineering.In addition to the well-studied ammonia oxidizing bacteria,nitrite oxidizing bacteria,heterotrophic denitri...Nitrogen-cycling microorganisms play key roles at the intersection of microbiology and wastewater engineering.In addition to the well-studied ammonia oxidizing bacteria,nitrite oxidizing bacteria,heterotrophic denitrifiers,and anammox bacteria,there are some other N-cycling microorganisms that are less abundant but functionally important in wastewater nitrogen removal.These microbes include,but not limited to ammonia oxidizing archaea(AOA),complete ammonia oxidation(comammox)bacteria,dissimilatory nitrate reduction to ammonia(DNRA)bacteria,and nitrate/nitrite-dependent anaerobic methane oxidizing(NO_(x)-DAMO)microorganisms.In the past decade,the development of high-throughput molecular technologies has enabled the detection,quantification,and characterization of these minor populations.The aim of this review is therefore to synthesize the current knowledge on the distribution,ecological niche,and kinetic properties of these“overlooked”N-cycling microbes at wastewater treatment plants.Their potential applications in novel wastewater nitrogen removal processes are also discussed.A comprehensive understanding of these overlooked N-cycling microbes from microbiology,ecology,and engineering perspectives will facilitate the design and operation of more efficient and sustainable biological nitrogen removal processes.展开更多
基金supported by the National Natural Science Foundation of China(Grant Nos.41977037,42377116,and 42077086)the 333 High-level Talents Training Project of Jiangsu Province(Grant No.BRA2022023)Fujian Natural Science Foundation(Grant No.2021J06019).
文摘Nitrite-dependent anaerobic methane oxidation (n-damo), performed by the bacteria associated with Candidatus Methylomirabilis oxyfera, acts as a novel methane sink in coastal wetlands. Conversion of coastal wetlands into paddy fields is a common land-use change that has profound effects on methane emissions, but its impact on n-damo process is nearly unknown. Our study adopted a space-for-time substitution method to compare n-damo activity and community of Methylomirabilis-like bacteria between natural vegetation covered by Phragmites australis, Kandelia candek, or Bruguiera sexangula and adjacent converted paddy fields in six China’s coastal wetlands. Generalized linear mixed model indicated that the activity of n-damo significantly increased by 43.6% and 165.8% after conversion of K. candek and B. sexangula wetlands into rice paddies, respectively, while the activity exhibited no significant change after conversion of P. australis wetlands. Furthermore, the abundance of Methylomirabilis-like bacteria significantly increased by 90.2%, 210.0%, and 110.1% following the conversion in wetlands covered by K. candek, B. sexangula, and P. australis, respectively. Principal co-ordinates analysis revealed significant changes in community structure of Methylomirabilis-like bacteria among vegetation types, with K. candek and B. sexangula showing a greater divergence than P. australis when compared to respective paddy fields. Path analysis indicated that land conversion resulted in changes in soil moisture content, organic carbon content, bulk density, and salinity and further affected the abundance of Methylomirabilis-like bacteria and ultimately n-damo activity. Overall, this is the first study to reveal the impact of conversion of coastal wetlands into paddy fields on n-damo activity and Methylomirabilis-like bacteria, and the impact was closely associated with the original native plant types. The results can enhance our understanding of the microbial-driven mechanisms of the impact of land conversion on methane emissions.
基金supported by the National Natural Science Foundation of China(Grant No.41701269)the National Key R&D Program of China(No.2019YFC0408800)the Fundamental Research Funds for the Central Universities(No.2020FZZX001-06).
文摘Nitrogen-cycling microorganisms play key roles at the intersection of microbiology and wastewater engineering.In addition to the well-studied ammonia oxidizing bacteria,nitrite oxidizing bacteria,heterotrophic denitrifiers,and anammox bacteria,there are some other N-cycling microorganisms that are less abundant but functionally important in wastewater nitrogen removal.These microbes include,but not limited to ammonia oxidizing archaea(AOA),complete ammonia oxidation(comammox)bacteria,dissimilatory nitrate reduction to ammonia(DNRA)bacteria,and nitrate/nitrite-dependent anaerobic methane oxidizing(NO_(x)-DAMO)microorganisms.In the past decade,the development of high-throughput molecular technologies has enabled the detection,quantification,and characterization of these minor populations.The aim of this review is therefore to synthesize the current knowledge on the distribution,ecological niche,and kinetic properties of these“overlooked”N-cycling microbes at wastewater treatment plants.Their potential applications in novel wastewater nitrogen removal processes are also discussed.A comprehensive understanding of these overlooked N-cycling microbes from microbiology,ecology,and engineering perspectives will facilitate the design and operation of more efficient and sustainable biological nitrogen removal processes.
