Abstract
Methane is a potent greenhouse gas in the atmosphere, and its concentration has continued to increase in recent decades. Aerobic methanotrophs, bacteria that use methane as the sole carbon source, are an important biological sink for methane, and they are widely distributed in the natural environment. However, relatively little is known on how methanotroph activity is regulated by nutrients, particularly phosphorus (P). P is the principal nutrient constraining plant and microbial productivity in many ecosystems, ranging from agricultural land to the open ocean. Using a model methanotrophic bacterium, Methylosinus trichosporium OB3b, we demonstrate here that this bacterium can produce P-free glycolipids to replace membrane phospholipids in response to P limitation. The formation of the glycolipid monoglucuronic acid diacylglycerol requires plcP-agt genes since the plcP-agt mutant is unable to produce this glycolipid. This plcP-agt-mediated lipid remodeling pathway appears to be important for M. trichosporium OB3b to cope with P stress, and the mutant grew significantly slower under P limitation. Interestingly, comparative genomics analysis shows that the ability to perform lipid remodeling appears to be a conserved trait in proteobacterial methanotrophs; indeed, plcP is found in all proteobacterial methanotroph genomes, and plcP transcripts from methanotrophs are readily detectable in metatranscriptomics data sets. Together, our study provides new insights into the adaptation to P limitation in this ecologically important group of bacteria.
IMPORTANCE Methane is a potent greenhouse gas in the atmosphere, and its concentration has continued to increase steadily in recent decades. In the natural environment, bacteria known as methanotrophs help mitigate methane emissions at no cost to human beings. However, relatively little is known regarding how methane oxidation activity in methanotrophs is regulated by soil nutrients, particularly phosphorus. Here, we show that methanotrophs can modify their membrane in response to phosphorus limitation and that the ability to change membrane lipids is important for methanotroph activity. Genome and metatranscriptome analyses suggest that such an adaptation strategy appears to be strictly conserved in all proteobacterial methanotrophs and is used by these bacteria in the natural environment. Together, our study provides a plausible molecular mechanism for better understanding the role of phosphorus on methane oxidation in the natural environment.
IMPORTANCE Methane is a potent greenhouse gas in the atmosphere, and its concentration has continued to increase steadily in recent decades. In the natural environment, bacteria known as methanotrophs help mitigate methane emissions at no cost to human beings. However, relatively little is known regarding how methane oxidation activity in methanotrophs is regulated by soil nutrients, particularly phosphorus. Here, we show that methanotrophs can modify their membrane in response to phosphorus limitation and that the ability to change membrane lipids is important for methanotroph activity. Genome and metatranscriptome analyses suggest that such an adaptation strategy appears to be strictly conserved in all proteobacterial methanotrophs and is used by these bacteria in the natural environment. Together, our study provides a plausible molecular mechanism for better understanding the role of phosphorus on methane oxidation in the natural environment.
Original language | English |
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Article number | e00247-22 |
Number of pages | 14 |
Journal | mBio |
Volume | 13 |
Issue number | 3 |
Early online date | 16 May 2022 |
DOIs | |
Publication status | Published - Jun 2022 |
Bibliographical note
Acknowledgments:We are grateful for a joint Royal Society/National Natural Science Foundation of China (RS-NSFC) Newton Advanced Fellowship Award (NAF/R1/180191, 41861130357). J.S., R.G., and M.A.M. were funded by a European Research Council (ERC) award under the European Union’s Horizon 2020 research and innovation program (grant agreement 726116). M.R.C. was funded by a Department for Economy PhD studentship.
We thank E. Silvano for help with liquid chromatography-mass spectrometry, the Advanced Bioimaging Research Technology Platform for training on TEM to R.G., and the Proteomics Research Technology Platform at the University of Warwick for assistance with the Orbitrap Fusion mass spectrometer. We acknowledge the Midlands Regional Cryo-EM Facility, hosted at the Warwick Advanced Bioimaging Research Technology Platform, for the use of the JEOL 2100Plus, supported by a Medical Research Council award (MC_PC_17136).
We declare that we have no conflicts of interest.
Keywords
- Methylosinus
- lipid remodeling
- methanotroph