Catch crop diversity increases rhizosphere carbon input and soil microbial biomass

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Autoren

  • Norman Gentsch
  • Jens Boy
  • Juan Daniel Kennedy Batalla
  • Diana Heuermann
  • Nicolaus von Wirén
  • Dörte Schweneker
  • Ulf Feuerstein
  • Jonas Groß
  • Bernhard Bauer
  • Barbara Reinhold-Hurek
  • Thomas Hurek
  • Fabricio Camacho Céspedes
  • Georg Guggenberger

Organisationseinheiten

Externe Organisationen

  • Leibniz-Institut für Pflanzengenetik und Kulturpflanzenforschung (IPK)
  • Deutsche Saatveredelung AG (DSV)
  • Hochschule Weihenstephan-Triesdorf
  • Universität Bremen
  • University of Georgia
Forschungs-netzwerk anzeigen

Details

OriginalspracheEnglisch
Seiten (von - bis)943-957
Seitenumfang15
FachzeitschriftBiology and fertility of soils
Jahrgang56
Ausgabenummer7
Frühes Online-Datum23 Mai 2020
PublikationsstatusVeröffentlicht - Okt. 2020

Abstract

Catch crops increase plant species richness in crop rotations, but are most often grown as pure stands. Here, we investigate the impacts of increasing plant diversity in catch crop rotations on rhizosphere C input and microbial utilization. Mustard (Sinapis alba L.) planted as a single cultivar was compared to diversified catch crop mixtures of four (Mix4) or 12 species (Mix12). We traced the C transfer from shoots to roots towards the soil microbial community and the soil respiration in a 13C pulse labelling field experiment. Net CO2-C uptake from the atmosphere increased by two times in mix 4 and more than three times in mix 12. Higher net ecosystem C production was linked to increasing catch crop diversity and increased belowground transfer rates of recently fixed photoassimilates. The higher rhizosphere C input stimulated the growth and activity of the soil microbiome, which was investigated by phospholipid fatty acid (PLFA) analyses. Total microbial biomass increased from 14 to 22 g m−2 as compared to the fallow and was 18 and 8% higher for mix 12 and mix 4 as compared to mustard. In particular, the fungal and actinobacterial communities profited the most from the higher belowground C input and their biomass increased by 3.4 and 1.3 times as compared to the fallow. The residence time of the 13C pulse, traced in the CO2 flux from the soil environment, increased with plant diversity by up to 1.8 times. The results of this study suggest positive impacts of plant diversity on C cycling by higher atmospheric C uptake, higher transport rates towards the rhizosphere, higher microbial incorporation and prolonged residence time in the soil environment. We conclude that diversified catch crop mixtures improve the efficiency of C cycling in cropping systems and provide a promising tool for sustainable soil management.

ASJC Scopus Sachgebiete

Zitieren

Catch crop diversity increases rhizosphere carbon input and soil microbial biomass. / Gentsch, Norman; Boy, Jens; Batalla, Juan Daniel Kennedy et al.
in: Biology and fertility of soils, Jahrgang 56, Nr. 7, 10.2020, S. 943-957.

Publikation: Beitrag in FachzeitschriftArtikelForschungPeer-Review

Gentsch, N, Boy, J, Batalla, JDK, Heuermann, D, von Wirén, N, Schweneker, D, Feuerstein, U, Groß, J, Bauer, B, Reinhold-Hurek, B, Hurek, T, Céspedes, FC & Guggenberger, G 2020, 'Catch crop diversity increases rhizosphere carbon input and soil microbial biomass', Biology and fertility of soils, Jg. 56, Nr. 7, S. 943-957. https://doi.org/10.1007/s00374-020-01475-8
Gentsch, N., Boy, J., Batalla, J. D. K., Heuermann, D., von Wirén, N., Schweneker, D., Feuerstein, U., Groß, J., Bauer, B., Reinhold-Hurek, B., Hurek, T., Céspedes, F. C., & Guggenberger, G. (2020). Catch crop diversity increases rhizosphere carbon input and soil microbial biomass. Biology and fertility of soils, 56(7), 943-957. https://doi.org/10.1007/s00374-020-01475-8
Gentsch N, Boy J, Batalla JDK, Heuermann D, von Wirén N, Schweneker D et al. Catch crop diversity increases rhizosphere carbon input and soil microbial biomass. Biology and fertility of soils. 2020 Okt;56(7):943-957. Epub 2020 Mai 23. doi: 10.1007/s00374-020-01475-8
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abstract = "Catch crops increase plant species richness in crop rotations, but are most often grown as pure stands. Here, we investigate the impacts of increasing plant diversity in catch crop rotations on rhizosphere C input and microbial utilization. Mustard (Sinapis alba L.) planted as a single cultivar was compared to diversified catch crop mixtures of four (Mix4) or 12 species (Mix12). We traced the C transfer from shoots to roots towards the soil microbial community and the soil respiration in a 13C pulse labelling field experiment. Net CO2-C uptake from the atmosphere increased by two times in mix 4 and more than three times in mix 12. Higher net ecosystem C production was linked to increasing catch crop diversity and increased belowground transfer rates of recently fixed photoassimilates. The higher rhizosphere C input stimulated the growth and activity of the soil microbiome, which was investigated by phospholipid fatty acid (PLFA) analyses. Total microbial biomass increased from 14 to 22 g m−2 as compared to the fallow and was 18 and 8% higher for mix 12 and mix 4 as compared to mustard. In particular, the fungal and actinobacterial communities profited the most from the higher belowground C input and their biomass increased by 3.4 and 1.3 times as compared to the fallow. The residence time of the 13C pulse, traced in the CO2 flux from the soil environment, increased with plant diversity by up to 1.8 times. The results of this study suggest positive impacts of plant diversity on C cycling by higher atmospheric C uptake, higher transport rates towards the rhizosphere, higher microbial incorporation and prolonged residence time in the soil environment. We conclude that diversified catch crop mixtures improve the efficiency of C cycling in cropping systems and provide a promising tool for sustainable soil management.",
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author = "Norman Gentsch and Jens Boy and Batalla, {Juan Daniel Kennedy} and Diana Heuermann and {von Wir{\'e}n}, Nicolaus and D{\"o}rte Schweneker and Ulf Feuerstein and Jonas Gro{\ss} and Bernhard Bauer and Barbara Reinhold-Hurek and Thomas Hurek and C{\'e}spedes, {Fabricio Camacho} and Georg Guggenberger",
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T1 - Catch crop diversity increases rhizosphere carbon input and soil microbial biomass

AU - Gentsch, Norman

AU - Boy, Jens

AU - Batalla, Juan Daniel Kennedy

AU - Heuermann, Diana

AU - von Wirén, Nicolaus

AU - Schweneker, Dörte

AU - Feuerstein, Ulf

AU - Groß, Jonas

AU - Bauer, Bernhard

AU - Reinhold-Hurek, Barbara

AU - Hurek, Thomas

AU - Céspedes, Fabricio Camacho

AU - Guggenberger, Georg

N1 - Funding Information: Open Access funding provided by Projekt DEAL. The authors received funding from the German Federal Ministry of Education and Research (BMBF), project number 031A559C. Acknowledgments

PY - 2020/10

Y1 - 2020/10

N2 - Catch crops increase plant species richness in crop rotations, but are most often grown as pure stands. Here, we investigate the impacts of increasing plant diversity in catch crop rotations on rhizosphere C input and microbial utilization. Mustard (Sinapis alba L.) planted as a single cultivar was compared to diversified catch crop mixtures of four (Mix4) or 12 species (Mix12). We traced the C transfer from shoots to roots towards the soil microbial community and the soil respiration in a 13C pulse labelling field experiment. Net CO2-C uptake from the atmosphere increased by two times in mix 4 and more than three times in mix 12. Higher net ecosystem C production was linked to increasing catch crop diversity and increased belowground transfer rates of recently fixed photoassimilates. The higher rhizosphere C input stimulated the growth and activity of the soil microbiome, which was investigated by phospholipid fatty acid (PLFA) analyses. Total microbial biomass increased from 14 to 22 g m−2 as compared to the fallow and was 18 and 8% higher for mix 12 and mix 4 as compared to mustard. In particular, the fungal and actinobacterial communities profited the most from the higher belowground C input and their biomass increased by 3.4 and 1.3 times as compared to the fallow. The residence time of the 13C pulse, traced in the CO2 flux from the soil environment, increased with plant diversity by up to 1.8 times. The results of this study suggest positive impacts of plant diversity on C cycling by higher atmospheric C uptake, higher transport rates towards the rhizosphere, higher microbial incorporation and prolonged residence time in the soil environment. We conclude that diversified catch crop mixtures improve the efficiency of C cycling in cropping systems and provide a promising tool for sustainable soil management.

AB - Catch crops increase plant species richness in crop rotations, but are most often grown as pure stands. Here, we investigate the impacts of increasing plant diversity in catch crop rotations on rhizosphere C input and microbial utilization. Mustard (Sinapis alba L.) planted as a single cultivar was compared to diversified catch crop mixtures of four (Mix4) or 12 species (Mix12). We traced the C transfer from shoots to roots towards the soil microbial community and the soil respiration in a 13C pulse labelling field experiment. Net CO2-C uptake from the atmosphere increased by two times in mix 4 and more than three times in mix 12. Higher net ecosystem C production was linked to increasing catch crop diversity and increased belowground transfer rates of recently fixed photoassimilates. The higher rhizosphere C input stimulated the growth and activity of the soil microbiome, which was investigated by phospholipid fatty acid (PLFA) analyses. Total microbial biomass increased from 14 to 22 g m−2 as compared to the fallow and was 18 and 8% higher for mix 12 and mix 4 as compared to mustard. In particular, the fungal and actinobacterial communities profited the most from the higher belowground C input and their biomass increased by 3.4 and 1.3 times as compared to the fallow. The residence time of the 13C pulse, traced in the CO2 flux from the soil environment, increased with plant diversity by up to 1.8 times. The results of this study suggest positive impacts of plant diversity on C cycling by higher atmospheric C uptake, higher transport rates towards the rhizosphere, higher microbial incorporation and prolonged residence time in the soil environment. We conclude that diversified catch crop mixtures improve the efficiency of C cycling in cropping systems and provide a promising tool for sustainable soil management.

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KW - Agrobiodiversity

KW - Catch crops

KW - Cover crops

KW - Rhizosphere C-transfer

KW - Soil microbiome

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U2 - 10.1007/s00374-020-01475-8

DO - 10.1007/s00374-020-01475-8

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VL - 56

SP - 943

EP - 957

JO - Biology and fertility of soils

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