Megan M. Foley, Bram W. G. Stone, Tristan A. Caro, Noah W. Sokol, Benjamin J. Koch, Steven J. Blazewicz, Paul Dijkstra, Michaela Hayer, Kirsten Hofmockel, Brianna K. Finley, Michelle Mack, Jane Marks, Rebecca L. Mau, Victoria Monsaint-Queeney, Ember Morrissey, Jeffrey Propster, Alicia Purcell, Egbert Schwartz, Jennifer Pett-Ridge, Noah Fierer, Bruce A. Hungate
{"title":"生长速度是微生物多样性与土壤生物地球化学之间的纽带","authors":"Megan M. Foley, Bram W. G. Stone, Tristan A. Caro, Noah W. Sokol, Benjamin J. Koch, Steven J. Blazewicz, Paul Dijkstra, Michaela Hayer, Kirsten Hofmockel, Brianna K. Finley, Michelle Mack, Jane Marks, Rebecca L. Mau, Victoria Monsaint-Queeney, Ember Morrissey, Jeffrey Propster, Alicia Purcell, Egbert Schwartz, Jennifer Pett-Ridge, Noah Fierer, Bruce A. Hungate","doi":"10.1038/s41559-024-02520-7","DOIUrl":null,"url":null,"abstract":"Measuring the growth rate of a microorganism is a simple yet profound way to quantify its effect on the world. The absolute growth rate of a microbial population reflects rates of resource assimilation, biomass production and element transformation—some of the many ways in which organisms affect Earth’s ecosystems and climate. Microbial fitness in the environment depends on the ability to reproduce quickly when conditions are favourable and adopt a survival physiology when conditions worsen, which cells coordinate by adjusting their relative growth rate. At the population level, relative growth rate is a sensitive metric of fitness, linking survival and reproduction to the ecology and evolution of populations. Techniques combining omics and stable isotope probing enable sensitive measurements of the growth rates of microbial assemblages and individual taxa in soil. Microbial ecologists can explore how the growth rates of taxa with known traits and evolutionary histories respond to changes in resource availability, environmental conditions and interactions with other organisms. We anticipate that quantitative and scalable data on the growth rates of soil microorganisms, coupled with measurements of biogeochemical fluxes, will allow scientists to test and refine ecological theory and advance process-based models of carbon flux, nutrient uptake and ecosystem productivity. Measurements of in situ microbial growth rates provide insights into the ecology of populations and can be used to quantitatively link microbial diversity to soil biogeochemistry. This Perspective discusses how recent developments in the ability to measure the growth of microbial populations, which provides an indicator of population fitness, can inform ecological and biogeochemical models.","PeriodicalId":18835,"journal":{"name":"Nature ecology & evolution","volume":"8 11","pages":"2018-2026"},"PeriodicalIF":13.9000,"publicationDate":"2024-09-18","publicationTypes":"Journal Article","fieldsOfStudy":null,"isOpenAccess":false,"openAccessPdf":"","citationCount":"0","resultStr":"{\"title\":\"Growth rate as a link between microbial diversity and soil biogeochemistry\",\"authors\":\"Megan M. Foley, Bram W. G. Stone, Tristan A. Caro, Noah W. Sokol, Benjamin J. Koch, Steven J. Blazewicz, Paul Dijkstra, Michaela Hayer, Kirsten Hofmockel, Brianna K. Finley, Michelle Mack, Jane Marks, Rebecca L. Mau, Victoria Monsaint-Queeney, Ember Morrissey, Jeffrey Propster, Alicia Purcell, Egbert Schwartz, Jennifer Pett-Ridge, Noah Fierer, Bruce A. 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Microbial ecologists can explore how the growth rates of taxa with known traits and evolutionary histories respond to changes in resource availability, environmental conditions and interactions with other organisms. We anticipate that quantitative and scalable data on the growth rates of soil microorganisms, coupled with measurements of biogeochemical fluxes, will allow scientists to test and refine ecological theory and advance process-based models of carbon flux, nutrient uptake and ecosystem productivity. Measurements of in situ microbial growth rates provide insights into the ecology of populations and can be used to quantitatively link microbial diversity to soil biogeochemistry. 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Growth rate as a link between microbial diversity and soil biogeochemistry
Measuring the growth rate of a microorganism is a simple yet profound way to quantify its effect on the world. The absolute growth rate of a microbial population reflects rates of resource assimilation, biomass production and element transformation—some of the many ways in which organisms affect Earth’s ecosystems and climate. Microbial fitness in the environment depends on the ability to reproduce quickly when conditions are favourable and adopt a survival physiology when conditions worsen, which cells coordinate by adjusting their relative growth rate. At the population level, relative growth rate is a sensitive metric of fitness, linking survival and reproduction to the ecology and evolution of populations. Techniques combining omics and stable isotope probing enable sensitive measurements of the growth rates of microbial assemblages and individual taxa in soil. Microbial ecologists can explore how the growth rates of taxa with known traits and evolutionary histories respond to changes in resource availability, environmental conditions and interactions with other organisms. We anticipate that quantitative and scalable data on the growth rates of soil microorganisms, coupled with measurements of biogeochemical fluxes, will allow scientists to test and refine ecological theory and advance process-based models of carbon flux, nutrient uptake and ecosystem productivity. Measurements of in situ microbial growth rates provide insights into the ecology of populations and can be used to quantitatively link microbial diversity to soil biogeochemistry. This Perspective discusses how recent developments in the ability to measure the growth of microbial populations, which provides an indicator of population fitness, can inform ecological and biogeochemical models.
Nature ecology & evolutionAgricultural and Biological Sciences-Ecology, Evolution, Behavior and Systematics
CiteScore
22.20
自引率
2.40%
发文量
282
期刊介绍:
Nature Ecology & Evolution is interested in the full spectrum of ecological and evolutionary biology, encompassing approaches at the molecular, organismal, population, community and ecosystem levels, as well as relevant parts of the social sciences. Nature Ecology & Evolution provides a place where all researchers and policymakers interested in all aspects of life's diversity can come together to learn about the most accomplished and significant advances in the field and to discuss topical issues. An online-only monthly journal, our broad scope ensures that the research published reaches the widest possible audience of scientists.