Microorganisms in subarctic soils are depleted of ribosomes under short-, medium-, and long-term warming
Physiological responses of soil microorganisms to global warming are important for soil ecosystem function and the terrestrial carbon cycle. Here, we investigate the effects of weeks, years, and decades of soil warming across seasons and time on the microbial protein biosynthesis machineries (i.e. r...
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| creator | Söllinger, Andrea Ahlers, Laureen S Dahl, Mathilde Borg Sigurðsson, Páll Le Noir de Carlan, Coline Bhattarai, Biplabi Gall, Christoph Martin, Victoria S Rottensteiner, Cornelia Motleleng, Liabo L Breines, Eva Marie Verbruggen, Erik Ostonen, Ivika Sigurdsson, Bjarni D Richter, Andreas Tveit, Alexander T |
| description | Physiological responses of soil microorganisms to global warming are important for soil ecosystem function and the terrestrial carbon cycle. Here, we investigate the effects of weeks, years, and decades of soil warming across seasons and time on the microbial protein biosynthesis machineries (i.e. ribosomes), the most abundant cellular macromolecular complexes, using RNA:DNA and RNA:MBC (microbial biomass carbon) ratios as proxies for cellular ribosome contents. We compared warmed soils and non-warmed controls of 15 replicated subarctic grassland and forest soil temperature gradients subject to natural geothermal warming. RNA:DNA ratios tended to be lower in the warmed soils during summer and autumn, independent of warming duration (6 weeks, 8-14 years, and > 50 years), warming intensity (+3°C, +6°C, and +9°C), and ecosystem type. With increasing temperatures, RNA:MBC ratios were also decreasing. Additionally, seasonal RNA:DNA ratios of the consecutively sampled forest showed the same temperature-driven pattern. This suggests that subarctic soil microorganisms are depleted of ribosomes under warm conditions and the lack of consistent relationships with other physicochemical parameters besides temperature further suggests temperature as key driver. Furthermore, in incubation experiments, we measured significantly higher CO2 emission rates per unit of RNA from short- and long-term warmed soils compared to non-warmed controls. In conclusion, ribosome reduction may represent a widespread microbial physiological response to warming that offers a selective advantage at higher temperatures, as energy and matter can be reallocated from ribosome synthesis to other processes including substrate uptake and turnover. This way, ribosome reduction could have a substantial effect on soil carbon dynamics. |
| doi_str_mv | 10.1093/ismejo/wrae081 |
| format | Article |
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Here, we investigate the effects of weeks, years, and decades of soil warming across seasons and time on the microbial protein biosynthesis machineries (i.e. ribosomes), the most abundant cellular macromolecular complexes, using RNA:DNA and RNA:MBC (microbial biomass carbon) ratios as proxies for cellular ribosome contents. We compared warmed soils and non-warmed controls of 15 replicated subarctic grassland and forest soil temperature gradients subject to natural geothermal warming. RNA:DNA ratios tended to be lower in the warmed soils during summer and autumn, independent of warming duration (6 weeks, 8-14 years, and > 50 years), warming intensity (+3°C, +6°C, and +9°C), and ecosystem type. With increasing temperatures, RNA:MBC ratios were also decreasing. Additionally, seasonal RNA:DNA ratios of the consecutively sampled forest showed the same temperature-driven pattern. This suggests that subarctic soil microorganisms are depleted of ribosomes under warm conditions and the lack of consistent relationships with other physicochemical parameters besides temperature further suggests temperature as key driver. Furthermore, in incubation experiments, we measured significantly higher CO2 emission rates per unit of RNA from short- and long-term warmed soils compared to non-warmed controls. In conclusion, ribosome reduction may represent a widespread microbial physiological response to warming that offers a selective advantage at higher temperatures, as energy and matter can be reallocated from ribosome synthesis to other processes including substrate uptake and turnover. This way, ribosome reduction could have a substantial effect on soil carbon dynamics.</description><identifier>ISSN: 1751-7362</identifier><identifier>ISSN: 1751-7370</identifier><identifier>EISSN: 1751-7370</identifier><identifier>DOI: 10.1093/ismejo/wrae081</identifier><identifier>PMID: 38722823</identifier><language>eng</language><publisher>England: Oxford University Press</publisher><subject>Bacteria - classification ; Bacteria - genetics ; Bacteria - isolation & purification ; Bacteria - metabolism ; Carbon - metabolism ; Carbon Cycle ; Carbon Dioxide - metabolism ; Ecosystem ; Forests ; Global Warming ; Grassland ; Ribosomes - metabolism ; Seasons ; Soil - chemistry ; Soil Microbiology ; Temperature</subject><ispartof>The ISME Journal, 2024-01, Vol.18 (1)</ispartof><rights>The Author(s) 2024. 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Here, we investigate the effects of weeks, years, and decades of soil warming across seasons and time on the microbial protein biosynthesis machineries (i.e. ribosomes), the most abundant cellular macromolecular complexes, using RNA:DNA and RNA:MBC (microbial biomass carbon) ratios as proxies for cellular ribosome contents. We compared warmed soils and non-warmed controls of 15 replicated subarctic grassland and forest soil temperature gradients subject to natural geothermal warming. RNA:DNA ratios tended to be lower in the warmed soils during summer and autumn, independent of warming duration (6 weeks, 8-14 years, and > 50 years), warming intensity (+3°C, +6°C, and +9°C), and ecosystem type. With increasing temperatures, RNA:MBC ratios were also decreasing. Additionally, seasonal RNA:DNA ratios of the consecutively sampled forest showed the same temperature-driven pattern. This suggests that subarctic soil microorganisms are depleted of ribosomes under warm conditions and the lack of consistent relationships with other physicochemical parameters besides temperature further suggests temperature as key driver. Furthermore, in incubation experiments, we measured significantly higher CO2 emission rates per unit of RNA from short- and long-term warmed soils compared to non-warmed controls. In conclusion, ribosome reduction may represent a widespread microbial physiological response to warming that offers a selective advantage at higher temperatures, as energy and matter can be reallocated from ribosome synthesis to other processes including substrate uptake and turnover. This way, ribosome reduction could have a substantial effect on soil carbon dynamics.</description><subject>Bacteria - classification</subject><subject>Bacteria - genetics</subject><subject>Bacteria - isolation & purification</subject><subject>Bacteria - metabolism</subject><subject>Carbon - metabolism</subject><subject>Carbon Cycle</subject><subject>Carbon Dioxide - metabolism</subject><subject>Ecosystem</subject><subject>Forests</subject><subject>Global Warming</subject><subject>Grassland</subject><subject>Ribosomes - metabolism</subject><subject>Seasons</subject><subject>Soil - chemistry</subject><subject>Soil Microbiology</subject><subject>Temperature</subject><issn>1751-7362</issn><issn>1751-7370</issn><issn>1751-7370</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2024</creationdate><recordtype>article</recordtype><sourceid>EIF</sourceid><sourceid>3HK</sourceid><recordid>eNo9kD1PwzAQQC0EoqWwMoJHBtLacWInI6r4kopYYLac-Nq6SuziS1Tx7wnqx3Q3vHvSPUJuOZtyVoqZwxY2YbaLBljBz8iYq5wnSih2ftplOiJXiBvGciWluiQjUag0LVIxJusPV8cQ4sr4QYXUeYp9ZWLduZpicA1SE4Fa2DbQgaVhSaOrAoYWkPbeQqS4DrFLHmkL1vXtsBhvaRP8KukgtnRnYuv86ppcLE2DcHOYE_L98vw1f0sWn6_v86dFUguedYlIDdQstSK1daaKQpYs51UmC56VVqWK5yZnTBU5y2B42XArlzLjylSlKTkvxYTc7711dNg5r32IRnPGhNIiy5QYiIc9sY3hpwfsdOuwhqYxHkKPWrBclKqUkg_o9CgLiBGWehtda-LvINT__fW-vz70Hw7uDu6-Gnqc8GNw8QcvAYH0</recordid><startdate>20240108</startdate><enddate>20240108</enddate><creator>Söllinger, Andrea</creator><creator>Ahlers, Laureen S</creator><creator>Dahl, Mathilde Borg</creator><creator>Sigurðsson, Páll</creator><creator>Le Noir de Carlan, Coline</creator><creator>Bhattarai, Biplabi</creator><creator>Gall, Christoph</creator><creator>Martin, Victoria S</creator><creator>Rottensteiner, Cornelia</creator><creator>Motleleng, Liabo L</creator><creator>Breines, Eva Marie</creator><creator>Verbruggen, Erik</creator><creator>Ostonen, Ivika</creator><creator>Sigurdsson, Bjarni D</creator><creator>Richter, Andreas</creator><creator>Tveit, Alexander T</creator><general>Oxford University Press</general><scope>CGR</scope><scope>CUY</scope><scope>CVF</scope><scope>ECM</scope><scope>EIF</scope><scope>NPM</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>7X8</scope><scope>3HK</scope></search><sort><creationdate>20240108</creationdate><title>Microorganisms in subarctic soils are depleted of ribosomes under short-, medium-, and long-term warming</title><author>Söllinger, Andrea ; 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Here, we investigate the effects of weeks, years, and decades of soil warming across seasons and time on the microbial protein biosynthesis machineries (i.e. ribosomes), the most abundant cellular macromolecular complexes, using RNA:DNA and RNA:MBC (microbial biomass carbon) ratios as proxies for cellular ribosome contents. We compared warmed soils and non-warmed controls of 15 replicated subarctic grassland and forest soil temperature gradients subject to natural geothermal warming. RNA:DNA ratios tended to be lower in the warmed soils during summer and autumn, independent of warming duration (6 weeks, 8-14 years, and > 50 years), warming intensity (+3°C, +6°C, and +9°C), and ecosystem type. With increasing temperatures, RNA:MBC ratios were also decreasing. Additionally, seasonal RNA:DNA ratios of the consecutively sampled forest showed the same temperature-driven pattern. This suggests that subarctic soil microorganisms are depleted of ribosomes under warm conditions and the lack of consistent relationships with other physicochemical parameters besides temperature further suggests temperature as key driver. Furthermore, in incubation experiments, we measured significantly higher CO2 emission rates per unit of RNA from short- and long-term warmed soils compared to non-warmed controls. In conclusion, ribosome reduction may represent a widespread microbial physiological response to warming that offers a selective advantage at higher temperatures, as energy and matter can be reallocated from ribosome synthesis to other processes including substrate uptake and turnover. This way, ribosome reduction could have a substantial effect on soil carbon dynamics.</abstract><cop>England</cop><pub>Oxford University Press</pub><pmid>38722823</pmid><doi>10.1093/ismejo/wrae081</doi><oa>free_for_read</oa></addata></record> |
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| subjects | Bacteria - classification Bacteria - genetics Bacteria - isolation & purification Bacteria - metabolism Carbon - metabolism Carbon Cycle Carbon Dioxide - metabolism Ecosystem Forests Global Warming Grassland Ribosomes - metabolism Seasons Soil - chemistry Soil Microbiology Temperature |
| title | Microorganisms in subarctic soils are depleted of ribosomes under short-, medium-, and long-term warming |
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