Seasonal dynamics of soil microbial growth, respiration, biomass, and carbon use efficiency in temperate soils

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autoren

  • Jörg Schnecker
  • Ludwig Baldaszti
  • Philipp Gündler
  • Michaela Pleitner
  • Taru Sandén
  • Eva Simon
  • Felix Spiegel
  • Heide Spiegel
  • Carolina Urbina Malo
  • Sophie Zechmeister-Boltenstern
  • Andreas Richter

Organisationseinheiten

Externe Organisationen

  • Universität Wien
  • University of Edinburgh
  • Agentur für Gesundheit und Ernährungssicherheit GmbH (AGES)
  • Austrian Competence Centre for Feed and Food Quality, Safety and Innovation GmbH (FFoQSI)
  • Veterinärmedizinische Universität Wien
  • Universität für Bodenkultur Wien (BOKU)
Forschungs-netzwerk anzeigen

Details

OriginalspracheEnglisch
Aufsatznummer116693
Seitenumfang12
FachzeitschriftGEODERMA
Jahrgang440
Frühes Online-Datum6 Nov. 2023
PublikationsstatusVeröffentlicht - Dez. 2023

Abstract

Soil microbial growth, respiration, and carbon (C) use efficiency (CUE) are essential parameters to understand, describe and model the soil carbon cycle. While seasonal dynamics of microbial respiration are well studied, little is known about how microbial growth and CUE change over the course of a year, especially outside the plant growing season. In this study, we measured soil microbial respiration, gross growth via 18O incorporation into DNA, and biomass in an agricultural field and a deciduous forest 16 times over the course of two years. We sampled soils to a depth of 5 cm from plots at which harvest residues or leaf litter remained on the plot or was removed. We observed strong seasonal variations of microbial respiration, growth, and biomass. All these microbial parameters were significantly higher at the forest site, which contained 4.3 % organic C compared to the agricultural site with 0.9 % organic C. CUE also varied strongly (0.1 to 0.7) but was overall significantly higher at the agricultural site compared to the forest site. We found that microbial respiration and to a lesser extent microbial growth followed the seasonal dynamics of soil temperature. Microbial growth was further affected by the presence of plants in the agricultural system or foliage in the forest. At low temperatures in winter, both microbial respiration and gross growth showed the lowest rates, whereas CUE (calculated from both respiration and growth) showed amongst the highest values determined during the two years, due to the higher temperature sensitivity of microbial respiration. Microbial biomass C strongly increased in winter. Surprisingly, this winter peak was not connected to high microbial growth or an increase in DNA content. This suggests that microorganisms accumulated C and N, potentially in the form of osmo- or cryoprotectants or increased in cell size but did not divide. This microbial winter bloom and following decline, where C is released from microbial biomass and freely available, might constitute a highly dynamic time in the annual C cycle in temperate soil systems. Highly variable CUE, which was observed in our study, and the fact that CUE is calculated from independently controlled microbial respiration and microbial growth, ask for great caution when CUE is used to describe soil microbial physiology, soil C dynamics or C sequestration. Instead, microbial respiration, microbial growth, and microbial biomass C should be investigated individually in combination to better understand the soil C cycle.

ASJC Scopus Sachgebiete

Zitieren

Seasonal dynamics of soil microbial growth, respiration, biomass, and carbon use efficiency in temperate soils. / Schnecker, Jörg; Baldaszti, Ludwig; Gündler, Philipp et al.
in: GEODERMA, Jahrgang 440, 116693, 12.2023.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Schnecker, J, Baldaszti, L, Gündler, P, Pleitner, M, Sandén, T, Simon, E, Spiegel, F, Spiegel, H, Urbina Malo, C, Zechmeister-Boltenstern, S & Richter, A 2023, 'Seasonal dynamics of soil microbial growth, respiration, biomass, and carbon use efficiency in temperate soils', GEODERMA, Jg. 440, 116693. https://doi.org/10.1016/j.geoderma.2023.116693
Schnecker, J., Baldaszti, L., Gündler, P., Pleitner, M., Sandén, T., Simon, E., Spiegel, F., Spiegel, H., Urbina Malo, C., Zechmeister-Boltenstern, S., & Richter, A. (2023). Seasonal dynamics of soil microbial growth, respiration, biomass, and carbon use efficiency in temperate soils. GEODERMA, 440, Artikel 116693. https://doi.org/10.1016/j.geoderma.2023.116693
Schnecker J, Baldaszti L, Gündler P, Pleitner M, Sandén T, Simon E et al. Seasonal dynamics of soil microbial growth, respiration, biomass, and carbon use efficiency in temperate soils. GEODERMA. 2023 Dez;440:116693. Epub 2023 Nov 6. doi: 10.1016/j.geoderma.2023.116693
Schnecker, Jörg ; Baldaszti, Ludwig ; Gündler, Philipp et al. / Seasonal dynamics of soil microbial growth, respiration, biomass, and carbon use efficiency in temperate soils. in: GEODERMA. 2023 ; Jahrgang 440.
Download
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title = "Seasonal dynamics of soil microbial growth, respiration, biomass, and carbon use efficiency in temperate soils",
abstract = "Soil microbial growth, respiration, and carbon (C) use efficiency (CUE) are essential parameters to understand, describe and model the soil carbon cycle. While seasonal dynamics of microbial respiration are well studied, little is known about how microbial growth and CUE change over the course of a year, especially outside the plant growing season. In this study, we measured soil microbial respiration, gross growth via 18O incorporation into DNA, and biomass in an agricultural field and a deciduous forest 16 times over the course of two years. We sampled soils to a depth of 5 cm from plots at which harvest residues or leaf litter remained on the plot or was removed. We observed strong seasonal variations of microbial respiration, growth, and biomass. All these microbial parameters were significantly higher at the forest site, which contained 4.3 % organic C compared to the agricultural site with 0.9 % organic C. CUE also varied strongly (0.1 to 0.7) but was overall significantly higher at the agricultural site compared to the forest site. We found that microbial respiration and to a lesser extent microbial growth followed the seasonal dynamics of soil temperature. Microbial growth was further affected by the presence of plants in the agricultural system or foliage in the forest. At low temperatures in winter, both microbial respiration and gross growth showed the lowest rates, whereas CUE (calculated from both respiration and growth) showed amongst the highest values determined during the two years, due to the higher temperature sensitivity of microbial respiration. Microbial biomass C strongly increased in winter. Surprisingly, this winter peak was not connected to high microbial growth or an increase in DNA content. This suggests that microorganisms accumulated C and N, potentially in the form of osmo- or cryoprotectants or increased in cell size but did not divide. This microbial winter bloom and following decline, where C is released from microbial biomass and freely available, might constitute a highly dynamic time in the annual C cycle in temperate soil systems. Highly variable CUE, which was observed in our study, and the fact that CUE is calculated from independently controlled microbial respiration and microbial growth, ask for great caution when CUE is used to describe soil microbial physiology, soil C dynamics or C sequestration. Instead, microbial respiration, microbial growth, and microbial biomass C should be investigated individually in combination to better understand the soil C cycle.",
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author = "J{\"o}rg Schnecker and Ludwig Baldaszti and Philipp G{\"u}ndler and Michaela Pleitner and Taru Sand{\'e}n and Eva Simon and Felix Spiegel and Heide Spiegel and {Urbina Malo}, Carolina and Sophie Zechmeister-Boltenstern and Andreas Richter",
note = "Funding Information: This research was funded by the Austrian Science Fund (FWF P30970-B32). We would like to acknowledge Harald Bock, Sonja Leitner, Josef Gasch, and Eugenio Diaz-Pines for their support at the field sites and Margarete Watzka and Ludwig Seidl for their support with sample analyses. ",
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Download

TY - JOUR

T1 - Seasonal dynamics of soil microbial growth, respiration, biomass, and carbon use efficiency in temperate soils

AU - Schnecker, Jörg

AU - Baldaszti, Ludwig

AU - Gündler, Philipp

AU - Pleitner, Michaela

AU - Sandén, Taru

AU - Simon, Eva

AU - Spiegel, Felix

AU - Spiegel, Heide

AU - Urbina Malo, Carolina

AU - Zechmeister-Boltenstern, Sophie

AU - Richter, Andreas

N1 - Funding Information: This research was funded by the Austrian Science Fund (FWF P30970-B32). We would like to acknowledge Harald Bock, Sonja Leitner, Josef Gasch, and Eugenio Diaz-Pines for their support at the field sites and Margarete Watzka and Ludwig Seidl for their support with sample analyses.

PY - 2023/12

Y1 - 2023/12

N2 - Soil microbial growth, respiration, and carbon (C) use efficiency (CUE) are essential parameters to understand, describe and model the soil carbon cycle. While seasonal dynamics of microbial respiration are well studied, little is known about how microbial growth and CUE change over the course of a year, especially outside the plant growing season. In this study, we measured soil microbial respiration, gross growth via 18O incorporation into DNA, and biomass in an agricultural field and a deciduous forest 16 times over the course of two years. We sampled soils to a depth of 5 cm from plots at which harvest residues or leaf litter remained on the plot or was removed. We observed strong seasonal variations of microbial respiration, growth, and biomass. All these microbial parameters were significantly higher at the forest site, which contained 4.3 % organic C compared to the agricultural site with 0.9 % organic C. CUE also varied strongly (0.1 to 0.7) but was overall significantly higher at the agricultural site compared to the forest site. We found that microbial respiration and to a lesser extent microbial growth followed the seasonal dynamics of soil temperature. Microbial growth was further affected by the presence of plants in the agricultural system or foliage in the forest. At low temperatures in winter, both microbial respiration and gross growth showed the lowest rates, whereas CUE (calculated from both respiration and growth) showed amongst the highest values determined during the two years, due to the higher temperature sensitivity of microbial respiration. Microbial biomass C strongly increased in winter. Surprisingly, this winter peak was not connected to high microbial growth or an increase in DNA content. This suggests that microorganisms accumulated C and N, potentially in the form of osmo- or cryoprotectants or increased in cell size but did not divide. This microbial winter bloom and following decline, where C is released from microbial biomass and freely available, might constitute a highly dynamic time in the annual C cycle in temperate soil systems. Highly variable CUE, which was observed in our study, and the fact that CUE is calculated from independently controlled microbial respiration and microbial growth, ask for great caution when CUE is used to describe soil microbial physiology, soil C dynamics or C sequestration. Instead, microbial respiration, microbial growth, and microbial biomass C should be investigated individually in combination to better understand the soil C cycle.

AB - Soil microbial growth, respiration, and carbon (C) use efficiency (CUE) are essential parameters to understand, describe and model the soil carbon cycle. While seasonal dynamics of microbial respiration are well studied, little is known about how microbial growth and CUE change over the course of a year, especially outside the plant growing season. In this study, we measured soil microbial respiration, gross growth via 18O incorporation into DNA, and biomass in an agricultural field and a deciduous forest 16 times over the course of two years. We sampled soils to a depth of 5 cm from plots at which harvest residues or leaf litter remained on the plot or was removed. We observed strong seasonal variations of microbial respiration, growth, and biomass. All these microbial parameters were significantly higher at the forest site, which contained 4.3 % organic C compared to the agricultural site with 0.9 % organic C. CUE also varied strongly (0.1 to 0.7) but was overall significantly higher at the agricultural site compared to the forest site. We found that microbial respiration and to a lesser extent microbial growth followed the seasonal dynamics of soil temperature. Microbial growth was further affected by the presence of plants in the agricultural system or foliage in the forest. At low temperatures in winter, both microbial respiration and gross growth showed the lowest rates, whereas CUE (calculated from both respiration and growth) showed amongst the highest values determined during the two years, due to the higher temperature sensitivity of microbial respiration. Microbial biomass C strongly increased in winter. Surprisingly, this winter peak was not connected to high microbial growth or an increase in DNA content. This suggests that microorganisms accumulated C and N, potentially in the form of osmo- or cryoprotectants or increased in cell size but did not divide. This microbial winter bloom and following decline, where C is released from microbial biomass and freely available, might constitute a highly dynamic time in the annual C cycle in temperate soil systems. Highly variable CUE, which was observed in our study, and the fact that CUE is calculated from independently controlled microbial respiration and microbial growth, ask for great caution when CUE is used to describe soil microbial physiology, soil C dynamics or C sequestration. Instead, microbial respiration, microbial growth, and microbial biomass C should be investigated individually in combination to better understand the soil C cycle.

KW - Carbon use efficiency

KW - Microbial growth

KW - Microbial processes

KW - Seasonal dynamics

KW - Winter

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