Insights into the evolutionary and ecological adaption strategies of nirS- and nirK-type denitrifying communities

Mol Ecol. 2024 Sep;33(18):e17507. doi: 10.1111/mec.17507. Epub 2024 Aug 19.

Abstract

Denitrification is a crucial process in the global nitrogen cycle, in which two functionally equivalent genes, nirS and nirK, catalyse the critical reaction and are usually used as marker genes. The nirK gene can function independently, whereas nirS requires additional genes to encode nitrite reductase and is more sensitive to environmental factors than nirK. However, the ecological differentiation mechanisms of those denitrifying microbial communities and their adaptation strategies to environmental stresses remain unclear. Here, we conducted metagenomic analysis for sediments and bioreactor samples from Lake Donghu, China. We found that nirS-type denitrifying communities had a significantly lower horizontal gene transfer frequency than that of nirK-type denitrifying communities, and nirS gene phylogeny was more congruent with taxonomy than that of nirK gene. Metabolic reconstruction of metagenome-assembled genomes further revealed that nirS-type denitrifying communities have robust metabolic systems for energy conservation, enabling them to survive under environmental stresses. Nevertheless, nirK-type denitrifying communities seemed to adapt to oxygen-limited environments with the ability to utilize various carbon and nitrogen compounds. Thus, this study provides novel insights into the ecological differentiation mechanism of nirS and nirK-type denitrifying communities, as well as the regulation of the global nitrogen cycle and greenhouse gas emissions.

Keywords: denitrification; ecological differentiation; environmental stresses; metabolic versatility; nirS and nirK.

MeSH terms

  • Adaptation, Physiological / genetics
  • Bacteria / classification
  • Bacteria / genetics
  • Bacteria / metabolism
  • Bioreactors / microbiology
  • China
  • Denitrification* / genetics
  • Gene Transfer, Horizontal
  • Geologic Sediments / microbiology
  • Lakes / microbiology
  • Metagenome* / genetics
  • Metagenomics
  • Microbiota / genetics
  • Nitrite Reductases* / genetics
  • Nitrogen / metabolism
  • Phylogeny*

Substances

  • Nitrite Reductases
  • Nitrogen