Dynamics of litter carbon turnover and microbial abundance in a rye detritusphere

Factors determining C turnover and microbial succession at the small scale are crucial for understanding C cycling in soils. We performed a microcosm experiment to study how soil moisture affects temporal patterns of C turnover in the detritusphere. Four treatments were applied to small soil cores w...

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Veröffentlicht in:	Soil biology & biochemistry 2008-06, Vol.40 (6), p.1306-1321
Hauptverfasser:	Poll, Christian, Marhan, Sven, Ingwersen, Joachim, Kandeler, Ellen
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Sprache:	eng
Schlagworte:	Agronomy. Soil science and plant productions Biochemistry and biology biodegradation Biological and medical sciences biomass carbon Chemical, physicochemical, biochemical and biological properties Decomposition dissolved organic carbon enzyme activity Fundamental and applied biological sciences. Psychology K strategists Litter microbial ecology Microbial succession mineralization MUF Organic matter Physics, chemistry, biochemistry and biology of agricultural and forest soils plant litter plant residues r strategists rye Secale cereale Small scale Soil enzymes soil fungi soil microorganisms soil organic carbon Soil science soil water content soil-plant interactions Soil–litter interface stable isotopes Temporal pattern temporal variation Water content
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creator	Poll, Christian Marhan, Sven Ingwersen, Joachim Kandeler, Ellen
description	Factors determining C turnover and microbial succession at the small scale are crucial for understanding C cycling in soils. We performed a microcosm experiment to study how soil moisture affects temporal patterns of C turnover in the detritusphere. Four treatments were applied to small soil cores with two different water contents (matric potential of −0.0063 and −0.0316MPa) and with or without addition of 13C labelled rye residues (δ13C=299‰), which were placed on top. Microcosms were sampled after 3, 7, 14, 28, 56 and 84 days and soil cores were separated into layers with increasing distance to the litter. Gradients in soil organic carbon, dissolved organic carbon, extracellular enzyme activity and microbial biomass were detected over a distance of 3mm from the litter layer. At the end of the incubation, 35.6% of litter C remained on the surface of soils at −0.0063MPa, whereas 41.7% remained on soils at −0.0316MPa. Most of the lost litter C was mineralised to CO2, with 47.9% and 43.4% at −0.0063 and −0.0316MPa, respectively. In both treatments about 6% were detected as newly formed soil organic carbon. During the initial phase of litter decomposition, bacteria dominated the mineralisation of easily available litter substrates. After 14 days fungi depolymerised more complex litter compounds, thereby producing new soluble substrates, which diffused into the soil. This pattern of differential substrate usage was paralleled by a lag phase of 3 days and a subsequent increase in enzyme activities. Increased soil water content accelerated the transport of soluble substrates, which influenced the temporal patterns of microbial growth and activity. Our results underline the importance of considering the interaction of soil microorganisms and physical processes at the small scale for the understanding of C cycling in soils.
doi_str_mv	10.1016/j.soilbio.2007.04.002
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During the initial phase of litter decomposition, bacteria dominated the mineralisation of easily available litter substrates. After 14 days fungi depolymerised more complex litter compounds, thereby producing new soluble substrates, which diffused into the soil. This pattern of differential substrate usage was paralleled by a lag phase of 3 days and a subsequent increase in enzyme activities. Increased soil water content accelerated the transport of soluble substrates, which influenced the temporal patterns of microbial growth and activity. 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During the initial phase of litter decomposition, bacteria dominated the mineralisation of easily available litter substrates. After 14 days fungi depolymerised more complex litter compounds, thereby producing new soluble substrates, which diffused into the soil. This pattern of differential substrate usage was paralleled by a lag phase of 3 days and a subsequent increase in enzyme activities. Increased soil water content accelerated the transport of soluble substrates, which influenced the temporal patterns of microbial growth and activity. Our results underline the importance of considering the interaction of soil microorganisms and physical processes at the small scale for the understanding of C cycling in soils.</description><subject>Agronomy. 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Psychology</subject><subject>K strategists</subject><subject>Litter</subject><subject>microbial ecology</subject><subject>Microbial succession</subject><subject>mineralization</subject><subject>MUF</subject><subject>Organic matter</subject><subject>Physics, chemistry, biochemistry and biology of agricultural and forest soils</subject><subject>plant litter</subject><subject>plant residues</subject><subject>r strategists</subject><subject>rye</subject><subject>Secale cereale</subject><subject>Small scale</subject><subject>Soil enzymes</subject><subject>soil fungi</subject><subject>soil microorganisms</subject><subject>soil organic carbon</subject><subject>Soil science</subject><subject>soil water content</subject><subject>soil-plant interactions</subject><subject>Soil–litter interface</subject><subject>stable isotopes</subject><subject>Temporal pattern</subject><subject>temporal variation</subject><subject>Water content</subject><issn>0038-0717</issn><issn>1879-3428</issn><fulltext>true</fulltext><rsrctype>article</rsrctype><creationdate>2008</creationdate><recordtype>article</recordtype><recordid>eNqFkE2LFDEQhoMoOK7-BDEXvXVblXR3kpPI-gkLIrrnkE6qNUNPZ0y6F-bfm2EGr56Kguetj4exlwgtAg5v921JcR5jagWAaqFrAcQjtkOtTCM7oR-zHYDUDShUT9mzUvZQiR7ljn3_cFrcIfrC08TnuK6UuXd5TAtft7ykh9q7JfCK5DRGN3M3bktwiyceF-54PhEPtOa4buX4mzI9Z08mNxd6ca037P7Tx5-3X5q7b5-_3r6_a7w03doEGsZOaeNRBB_0KLu-FxgcTQGHMKJGMeghKAD0vVKKhJ-IlPIkTW-kkTfszWXuMac_G5XVHmLxNM9uobQVi0YbAeoM9hewflBKpskeczy4fLII9izQ7u1VoD0LtNDZqqfmXl8XuOLdPOX6dCz_wgI67AcNlXt14SaXrPuVK3P_QwBKACMU9mfi3YWg6uMhUrbFR6oKQ8zkVxtS_M8tfwFqEpL-</recordid><startdate>20080601</startdate><enddate>20080601</enddate><creator>Poll, Christian</creator><creator>Marhan, Sven</creator><creator>Ingwersen, Joachim</creator><creator>Kandeler, Ellen</creator><general>Elsevier Ltd</general><general>Elsevier Science</general><scope>FBQ</scope><scope>IQODW</scope><scope>AAYXX</scope><scope>CITATION</scope><scope>7QL</scope><scope>7SN</scope><scope>7T7</scope><scope>8FD</scope><scope>C1K</scope><scope>FR3</scope><scope>M7N</scope><scope>P64</scope></search><sort><creationdate>20080601</creationdate><title>Dynamics of litter carbon turnover and microbial abundance in a rye detritusphere</title><author>Poll, Christian ; Marhan, Sven ; Ingwersen, Joachim ; Kandeler, Ellen</author></sort><facets><frbrtype>5</frbrtype><frbrgroupid>cdi_FETCH-LOGICAL-c394t-de6b4789c12dcd8b345521daefd16db1812686d7001c5777e2cfee77ce3959393</frbrgroupid><rsrctype>articles</rsrctype><prefilter>articles</prefilter><language>eng</language><creationdate>2008</creationdate><topic>Agronomy. 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We performed a microcosm experiment to study how soil moisture affects temporal patterns of C turnover in the detritusphere. Four treatments were applied to small soil cores with two different water contents (matric potential of −0.0063 and −0.0316MPa) and with or without addition of 13C labelled rye residues (δ13C=299‰), which were placed on top. Microcosms were sampled after 3, 7, 14, 28, 56 and 84 days and soil cores were separated into layers with increasing distance to the litter. Gradients in soil organic carbon, dissolved organic carbon, extracellular enzyme activity and microbial biomass were detected over a distance of 3mm from the litter layer. At the end of the incubation, 35.6% of litter C remained on the surface of soils at −0.0063MPa, whereas 41.7% remained on soils at −0.0316MPa. Most of the lost litter C was mineralised to CO2, with 47.9% and 43.4% at −0.0063 and −0.0316MPa, respectively. In both treatments about 6% were detected as newly formed soil organic carbon. 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subjects	Agronomy. Soil science and plant productions Biochemistry and biology biodegradation Biological and medical sciences biomass carbon Chemical, physicochemical, biochemical and biological properties Decomposition dissolved organic carbon enzyme activity Fundamental and applied biological sciences. Psychology K strategists Litter microbial ecology Microbial succession mineralization MUF Organic matter Physics, chemistry, biochemistry and biology of agricultural and forest soils plant litter plant residues r strategists rye Secale cereale Small scale Soil enzymes soil fungi soil microorganisms soil organic carbon Soil science soil water content soil-plant interactions Soil–litter interface stable isotopes Temporal pattern temporal variation Water content
title	Dynamics of litter carbon turnover and microbial abundance in a rye detritusphere
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