Study reveals relationship between nitrogen-cycling microbial communities and nitrogen removal

08 Oct 2024, 16:43 by Chinese Academy of Sciences

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Metagenomic insights into nitrogen-cycling microbial communities and their relationships with nitrogen removal potential in the Yangtze River. Credit: DENG Danli

Excess nitrogen (N) input to the inland water bodies and marine ecosystem has contributed to a cascade of environmental issues, so N removal pathways are critical in aquatic and terrestrial ecosystems for maintaining homeostasis. Associated functional microbes are of great importance for developing N management to protect downstream water bodies.

Researchers from Wuhan Botanical Garden, led by Professor Liu Wenzhi and Professor Xiong Xiang, recently conducted metagenomic sequencing and genome binning to examine the abundance and diversity of N-cycling genes in surface water, channel sediments, and riparian soils along the Yangtze River suffered from severe N pollution.

This study, published in Water Research, is titled "Metagenomic insights into nitrogen-cycling microbial communities and their relationships with nitrogen removal potential in the Yangtze River."

They obtained 121 metagenome-assembled genomes (MAGs) involved in N-cycling pathways, in which the key MAGs belonged to the Proteobacteria. Alphaproteobacteria and Gammaproteobacteria were identified as the main contributors of N-cycling genes at the class level, suggesting that those taxonomic groups may be the most dominant pollutants in the Yangtze River.

Significant differences of the abundance and diversity of most N-cycling genes were observed between soil/sediment and water, as well as between upstream and mid-downstream sites, implying that geographical factors or dispersal limitations play an essential role in shaping the biogeographic patterns of N-cycling genes.

The rates of N removal process significantly correlated with the abundance or diversity of several genes involved in N-cycling processes. Climate variables and soil physicochemical properties regulated denitrification and anammox rates both directly and indirectly through their effects on microbial genes, the study showed.

The results fill a critical knowledge gap regarding the biogeographic patterns and environmental drivers of N-cycling microorganisms in river ecosystems from the metagenomic perspective.

More information: Danli Deng et al, Metagenomic insights into nitrogen-cycling microbial communities and their relationships with nitrogen removal potential in the Yangtze River, Water Research (2024). DOI: 10.1016/j.watres.2024.122229

Journal information: Water Research

Provided by Chinese Academy of Sciences