Resource Concentration Modulates the Fate of Dissimilated Nitrogen in a Dual-Pathway Actinobacterium
Respiratory ammonification and denitrification are two evolutionarily unrelated dissimilatory nitrogen (N) processes central to the global N cycle, the activity of which is thought to be controlled by carbon (C) to nitrate (NO3−) ratio. Here we find that Intrasporangium calvum C5, a novel dual-pathw...
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| Language: | English |
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Frontiers Media S.A.
2019-01-01
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| Series: | Frontiers in Microbiology |
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| Online Access: | https://www.frontiersin.org/article/10.3389/fmicb.2019.00003/full |
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doaj-fca40d40a5d74b868faeca9a605408882020-11-24T22:02:37ZengFrontiers Media S.A.Frontiers in Microbiology1664-302X2019-01-011010.3389/fmicb.2019.00003430066Resource Concentration Modulates the Fate of Dissimilated Nitrogen in a Dual-Pathway ActinobacteriumDavid C. Vuono0David C. Vuono1Robert W. Read2James Hemp3Benjamin W. Sullivan4John A. Arnone5Iva Neveux6Robert R. Blank7Evan Loney8David Miceli9Mari-Karoliina H. Winkler10Romy Chakraborty11David A. Stahl12Joseph J. Grzymski13Division of Earth and Ecosystem Sciences, Desert Research Institute, Reno, NV, United StatesDepartment of Civil and Environmental Engineering, University of Washington, Seattle, WA, United StatesDivision of Earth and Ecosystem Sciences, Desert Research Institute, Reno, NV, United StatesDivision of Geological and Planetary Sciences, California Institute of Technology, Pasadena, CA, United StatesDepartment of Natural Resources and Environmental Science, University of Nevada, Reno, Reno, NV, United StatesDivision of Earth and Ecosystem Sciences, Desert Research Institute, Reno, NV, United StatesDivision of Earth and Ecosystem Sciences, Desert Research Institute, Reno, NV, United StatesAgricultural Research Service, United States Department of Agriculture, Reno, NV, United StatesDivision of Earth and Ecosystem Sciences, Desert Research Institute, Reno, NV, United StatesDivision of Earth and Ecosystem Sciences, Desert Research Institute, Reno, NV, United StatesDepartment of Civil and Environmental Engineering, University of Washington, Seattle, WA, United StatesEarth and Environmental Sciences Area, Lawrence Berkeley National Laboratory, Berkeley, CA, United StatesDepartment of Civil and Environmental Engineering, University of Washington, Seattle, WA, United StatesDivision of Earth and Ecosystem Sciences, Desert Research Institute, Reno, NV, United StatesRespiratory ammonification and denitrification are two evolutionarily unrelated dissimilatory nitrogen (N) processes central to the global N cycle, the activity of which is thought to be controlled by carbon (C) to nitrate (NO3−) ratio. Here we find that Intrasporangium calvum C5, a novel dual-pathway denitrifier/respiratory ammonifier, disproportionately utilizes ammonification rather than denitrification when grown under low C concentrations, even at low C:NO3− ratios. This finding is in conflict with the paradigm that high C:NO3− ratios promote ammonification and low C:NO3− ratios promote denitrification. We find that the protein atomic composition for denitrification modules (NirK) are significantly cost minimized for C and N compared to ammonification modules (NrfA), indicating that limitation for C and N is a major evolutionary selective pressure imprinted in the architecture of these proteins. The evolutionary precedent for these findings suggests ecological importance for microbial activity as evidenced by higher growth rates when I. calvum grows predominantly using its ammonification pathway and by assimilating its end-product (ammonium) for growth under ammonium-free conditions. Genomic analysis of I. calvum further reveals a versatile ecophysiology to cope with nutrient stress and redox conditions. Metabolite and transcriptional profiles during growth indicate that enzyme modules, NrfAH and NirK, are not constitutively expressed but rather induced by nitrite production via NarG. Mechanistically, our results suggest that pathway selection is driven by intracellular redox potential (redox poise), which may be lowered when resource concentrations are low, thereby decreasing catalytic activity of upstream electron transport steps (i.e., the bc1 complex) needed for denitrification enzymes. Our work advances our understanding of the biogeochemical flexibility of N-cycling organisms, pathway evolution, and ecological food-webs.https://www.frontiersin.org/article/10.3389/fmicb.2019.00003/fulldissimilatory nitrate reductiondenitrificationammonificationredox poisecost minimizationmaximum power principle |
| collection |
DOAJ |
| language |
English |
| format |
Article |
| sources |
DOAJ |
| author |
David C. Vuono David C. Vuono Robert W. Read James Hemp Benjamin W. Sullivan John A. Arnone Iva Neveux Robert R. Blank Evan Loney David Miceli Mari-Karoliina H. Winkler Romy Chakraborty David A. Stahl Joseph J. Grzymski |
| spellingShingle |
David C. Vuono David C. Vuono Robert W. Read James Hemp Benjamin W. Sullivan John A. Arnone Iva Neveux Robert R. Blank Evan Loney David Miceli Mari-Karoliina H. Winkler Romy Chakraborty David A. Stahl Joseph J. Grzymski Resource Concentration Modulates the Fate of Dissimilated Nitrogen in a Dual-Pathway Actinobacterium Frontiers in Microbiology dissimilatory nitrate reduction denitrification ammonification redox poise cost minimization maximum power principle |
| author_facet |
David C. Vuono David C. Vuono Robert W. Read James Hemp Benjamin W. Sullivan John A. Arnone Iva Neveux Robert R. Blank Evan Loney David Miceli Mari-Karoliina H. Winkler Romy Chakraborty David A. Stahl Joseph J. Grzymski |
| author_sort |
David C. Vuono |
| title |
Resource Concentration Modulates the Fate of Dissimilated Nitrogen in a Dual-Pathway Actinobacterium |
| title_short |
Resource Concentration Modulates the Fate of Dissimilated Nitrogen in a Dual-Pathway Actinobacterium |
| title_full |
Resource Concentration Modulates the Fate of Dissimilated Nitrogen in a Dual-Pathway Actinobacterium |
| title_fullStr |
Resource Concentration Modulates the Fate of Dissimilated Nitrogen in a Dual-Pathway Actinobacterium |
| title_full_unstemmed |
Resource Concentration Modulates the Fate of Dissimilated Nitrogen in a Dual-Pathway Actinobacterium |
| title_sort |
resource concentration modulates the fate of dissimilated nitrogen in a dual-pathway actinobacterium |
| publisher |
Frontiers Media S.A. |
| series |
Frontiers in Microbiology |
| issn |
1664-302X |
| publishDate |
2019-01-01 |
| description |
Respiratory ammonification and denitrification are two evolutionarily unrelated dissimilatory nitrogen (N) processes central to the global N cycle, the activity of which is thought to be controlled by carbon (C) to nitrate (NO3−) ratio. Here we find that Intrasporangium calvum C5, a novel dual-pathway denitrifier/respiratory ammonifier, disproportionately utilizes ammonification rather than denitrification when grown under low C concentrations, even at low C:NO3− ratios. This finding is in conflict with the paradigm that high C:NO3− ratios promote ammonification and low C:NO3− ratios promote denitrification. We find that the protein atomic composition for denitrification modules (NirK) are significantly cost minimized for C and N compared to ammonification modules (NrfA), indicating that limitation for C and N is a major evolutionary selective pressure imprinted in the architecture of these proteins. The evolutionary precedent for these findings suggests ecological importance for microbial activity as evidenced by higher growth rates when I. calvum grows predominantly using its ammonification pathway and by assimilating its end-product (ammonium) for growth under ammonium-free conditions. Genomic analysis of I. calvum further reveals a versatile ecophysiology to cope with nutrient stress and redox conditions. Metabolite and transcriptional profiles during growth indicate that enzyme modules, NrfAH and NirK, are not constitutively expressed but rather induced by nitrite production via NarG. Mechanistically, our results suggest that pathway selection is driven by intracellular redox potential (redox poise), which may be lowered when resource concentrations are low, thereby decreasing catalytic activity of upstream electron transport steps (i.e., the bc1 complex) needed for denitrification enzymes. Our work advances our understanding of the biogeochemical flexibility of N-cycling organisms, pathway evolution, and ecological food-webs. |
| topic |
dissimilatory nitrate reduction denitrification ammonification redox poise cost minimization maximum power principle |
| url |
https://www.frontiersin.org/article/10.3389/fmicb.2019.00003/full |
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