Determining the timepoint when super(14)C tracer accurately reflect photosynthate use in the plant-soil system

Determining the timepoint when super(14)C tracer accurately reflect photosynthate use in the plant-soil system

(ProQuest: ... denotes formulae and/or non-USASCII text omitted; see image).Background and aims: Only the carbon (C) isotope pulse labeling approach can provide time-resolved data concerning the input and turnover of plant-derived C in the soil, which are urgently needed to improve the performance o...

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Published in:Plant and soil Vol. 408; no. 1-2; pp. 457 - 474
Main Authors: Remus, Rainer, Hueve, Katja, Porschmann, Juergen, Augustin, Juergen
Format: Journal Article
Language:English
Published: 01-11-2016
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Summary:(ProQuest: ... denotes formulae and/or non-USASCII text omitted; see image).Background and aims: Only the carbon (C) isotope pulse labeling approach can provide time-resolved data concerning the input and turnover of plant-derived C in the soil, which are urgently needed to improve the performance of terrestrial C cycle models. However, there is currently very limited information about the point in time after pulse labeling at which the distribution of tracer C accurately represents the usage of photosynthates in different components of the plant-soil system. This should be the case as soon as the tracer has disappeared from the mobile C pool due to respiration, incorporation into the structural C pool of shoot and root tissue and exudation into the soil (rhizodeposition). Methods: Following ... pulse labeling in laboratory and outdoor experiments with spring rye, the super(14)C dilution rates of soluble fractions and different substances from the structural C pool of the shoot (molecular level), the release of labeled CO sub(2) by belowground respiration (component level), and the super(14)C kinetics of shoot respiration and super(14)C remaining in the plant-soil-soil gas continuum (system level) were analyzed during different stages of plant development. Results: At all three levels investigated, super(14)C kinetics indicated that the C tracer levels changed very little between 15 and 21 days after labeling. Results also showed increasing tracer depletion in the mobile C pool. Consequently, only 0.42 % and 0.06 % of all super(14)C was still available for shoot respiration 15 and 21 days after labeling, respectively. Conclusions: The similarities between super(14)C tracer kinetics at the three investigated levels indicate that tracer disappearance from the mobile pool and distribution throughout the plant-soil system was nearly complete between 15 and 21 days after labeling. Therefore, this appears to be the point at which the pulse labeling approach provides sufficiently precise data concerning the use of C (assimilated during labeling) for root growth, rhizodeposition, root respiration and the microbial turnover of rhizodeposits.
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ISSN:0032-079X
1573-5036
DOI:10.1007/s11104-016-3002-2