Journal of Sustainable Agriculture and Environment (Jun 2022)
Biochemical mechanism of phosphorus limitation impairing nitrogen fixation in diazotrophic bacterium Klebsiella variicola W12
Abstract
Abstract Introduction Biological nitrogen (N) fixation (BNF) plays a key role in nitrogen supply in agricultural and natural ecosystems. Harnessing BNF can substantially reduce dependence on chemical fertilizer in agroecosystems and hence can contribute to sustainable agriculture. However, a number of field studies have demonstrated that BNF can be largely suppressed in phosphorus (P)‐deficient environments, while the underlying mechanism is not well understood. Materials & Methods In this study, comparative proteomics and lipidomics analyses were conducted on a diazotrophic bacterium Klebsiella variicola W12 under P‐deficient and P‐replete conditions to gain insight into how P availability affects N fixation. Results Under P deficiency, N fixation activity of K. variicola W12 was severely repressed. In response to P limitation, the bacterium synthesized P‐free ornithine lipids to replace glycerophospholipids in its membrane to reduce cellular demand for P. Comparative proteomics showed that P limitation resulted in upregulation of the PhoBR two‐component system, a range of organic and inorganic P uptake and transport systems, while nitrogenase and N‐fixation‐related transcriptional regulators NifL and NifA were downregulated. Conclusion These results revealed lipid renovation as an adaptation strategy for N2‐fixing microbes to survive under P stress and provided biochemical evidence on how P availability regulates BNF. A conceptual model of N–P coupling at the microbial metabolism level is therefore proposed. Our study provides a simple yet plausible explanation of how P deficiency suppresses BNF observed in the field and highlights the importance of regulating P availability to maximize the potential of BNF in agroecosystems for agriculture sustainable production.
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