Variations in microbial isotopic fractionation during soil organic matter decomposition

Lerch, Thomas Z.; Nunan, Naoise; Dignac, Marie-France; Chenu, Claire; Mariotti, André

doi:10.1007/s10533-010-9432-7

Cited by 82 publications

(68 citation statements)

References 70 publications

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“…3). However, Lerch et al (2011) found fractionation to vary over time when calculated in this manner, and while changes in substrate could account for this pattern it is also likely that the active microbial community is changing. Fast changes in microbial composition have been documented after addition of labile substrate (Cleveland et al, 2007), rapidly changing environmental conditions (Gordon et al, 2008), and other environmental stresses (Schimel et al, 2007).…”

Section: Fractionation Due To Microbial Metabolismmentioning

confidence: 89%

“…For example, the use of positional labeling of carbon in glucose has given metabolic insight into carbon pathways in mycorrizhae (Scandellari et al, 2009). Studies that assess the isotopic composition of soil microbial biomass usually treat soil microbes as a single C pool without differentiating between metabolically active and dormant microorganisms (Santrûcková et al, 2000;Lerch et al, 2011). Soil microbial biomass is composed of both active and dormant microorganisms, yet, CO 2 respired from microorganisms derives solely from those that are metabolically active (Stenstrom et al, 2001;Kuzyakov, 2008, 2009;Millard et al, 2010;Werth and Kuzyakov, 2010).…”

Section: Synthesis/ Remobilizationmentioning

confidence: 99%

“…For example, Kramer et al (2010) showed that the source of carbon in the biomarkers present in their incubation studies did not originate from litter or SOM, leaving only roots as the primary source. Using fatty acid methyl ester isotopic composition, Lerch et al (2011) found a switch in the active microbial community from Gram-negative bacteria initially, which consumed the easily degradable and water-soluble substrates, to Grampositive bacteria and fungi later. Based on their isotopic measurements, Lerch et al (2011) also suggested that there is a potential lag between changes in the bacteria actually consuming carbon belowground, and the community structure as a whole.…”

Section: Transfer Of C From Leaf Litter and Doc To Soil And Microbesmentioning

confidence: 99%

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Carbon allocation and carbon isotope fluxes in the plant-soil-atmosphere continuum: a review

Brüggemann¹,

et al. 2011

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Abstract. The terrestrial carbon (C) cycle has received increasing interest over the past few decades, however, there is still a lack of understanding of the fate of newly assimilated C allocated within plants and to the soil, stored within ecosystems and lost to the atmosphere. Stable carbon isotope studies can give novel insights into these issues. In this review we provide an overview of an emerging picture of plant-soil-atmosphere C fluxes, as based on C isotopeCorrespondence to: N. Brüggemann (n.brueggemann@fz-juelich.de) studies, and identify processes determining related C isotope signatures. The first part of the review focuses on isotopic fractionation processes within plants during and after photosynthesis. The second major part elaborates on plantinternal and plant-rhizosphere C allocation patterns at different time scales (diel, seasonal, interannual), including the speed of C transfer and time lags in the coupling of assimilation and respiration, as well as the magnitude and controls of plant-soil C allocation and respiratory fluxes. Plant responses to changing environmental conditions, the functional relationship between the physiological and phenological status of plants and C transfer, and interactions between Published by Copernicus Publications on behalf of the European Geosciences Union. 3458 N. Brüggemann et al.: Plant-soil-atmosphere C fluxes C, water and nutrient dynamics are discussed. The role of the C counterflow from the rhizosphere to the aboveground parts of the plants, e.g. via CO 2 dissolved in the xylem water or as xylem-transported sugars, is highlighted. The third part is centered around belowground C turnover, focusing especially on above-and belowground litter inputs, soil organic matter formation and turnover, production and loss of dissolved organic C, soil respiration and CO 2 fixation by soil microbes. Furthermore, plant controls on microbial communities and activity via exudates and litter production as well as microbial community effects on C mineralization are reviewed. A further part of the paper is dedicated to physical interactions between soil CO 2 and the soil matrix, such as CO 2 diffusion and dissolution processes within the soil profile. Finally, we highlight state-of-the-art stable isotope methodologies and their latest developments. From the presented evidence we conclude that there exists a tight coupling of physical, chemical and biological processes involved in C cycling and C isotope fluxes in the plant-soil-atmosphere system. Generally, research using information from C isotopes allows an integrated view of the different processes involved. However, complex interactions among the range of processes complicate or currently impede the interpretation of isotopic signals in CO 2 or organic compounds at the plant and ecosystem level. This review tries to identify present knowledge gaps in correctly interpreting carbon stable isotope signals in the plant-soil-atmosphere system and how future research approaches could contribute to closing these gaps.

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Section: Fractionation Due To Microbial Metabolismmentioning

confidence: 89%

Section: Synthesis/ Remobilizationmentioning

confidence: 99%

Section: Transfer Of C From Leaf Litter and Doc To Soil And Microbesmentioning

confidence: 99%

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Carbon allocation and carbon isotope fluxes in the plant-soil-atmosphere continuum: a review

Brüggemann¹,

et al. 2011

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“…Indeed, numerous observations showed that plant compounds are slightly depleted in 13 C and 15 N compared to bulk SOM. Lerch et al (2011) tested the assumption according to which fractionation accompanying microbial metabolism may be at the origin of this enrichment of SOM (Balesdent and Mariotti 1996;Bird et al 2003;Dijkstra et al 2006). They quantified 13 C and 15 N fractionation factors between soil and microbial biomass and confirmed that microbial isotopic fractionation leads to the enrichment of SOM in heavy isotopes.…”

mentioning

confidence: 97%

From land to water, an overview of organic matter research in France––proceedings of the Sainte-Maxime 2009 symposium organized by the French network on organic matter research

Derrien¹,

Dignac²,

Dudal

2011

Biogeochemistry

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A Research Network focusing on organic matter (Réseau MO) was established in 2004 in France. Its overall goal was to encourage discussions between French speaking scientists originating from a wide range of disciplines (soil science, hydrology, oceanography, sedimentology, cosmochemistry, waste management, etc.) studying the same subject: organic matter (OM). The various scientific communities working on OM often ignore each other. However, they focus on the same issues regarding sources, transformations and interactions of OM with other compounds. They use similar techniques and methodologies to address these issues, and face similar limitations regarding the understanding of this complex matrix. In order to improve scientific synergy between the various OM approaches, the ''Réseau MO'' intends to stimulate interactions between scientists from all communities working on OM. Workshops, summer schools and conferences are organised regularly to facilitate the sharing of recent analytical tools, to present emerging methods, to relate the latest scientific findings, to identify crosscutting and uniting themes, and to stimulate creativity.This special issue of Biogeochemistry presents a selection of the results from the Second Conference organised by this network, which took place on 25-28 January, 2009 at Sainte Maxime, in the south of France. The conference was attended by 140 delegates and focused on the impact of human activities on OM dynamics. Five sessions were held during the Conference, four of them dedicated to a research theme and the last one specifically focusing on methodological advances for OM study. Presentations and debates addressed the storage of carbon in soils and wetlands, the impact of anthropogenic activities on this storage, the sources of OM in aquatic systems, and the affinity of dissolved organic matter for hazardous compounds. Outcomes of these topics are summarised below.Storage of carbon in soils and wetlands: contribution of plant versus microbial OM Terrestrial ecosystems, if properly managed, are expected to sequester a part of the increased

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“…The depletion in carbon isotope values may be due to 482 several factors, including changes in the ratio of C 3 and C 4 plants on the landscape, changes in 483 the growing conditions of plants (such as canopy structure, and water or nutrient stress), changes 484 in the ratios of isotopically distinct organic fractions in the sediment organic matter, and changes 485 in organic inputs from microorganisms in soils (Tieszen 1991 cooler/dryer conditions indicated by a decrease in magnetic susceptibility occurring at KTC at 504 the same time. However, the trend in δ 13 C values at KTC is relatively low magnitude, and 505 isotopic fractionation and microbial activity cannot be fully dismissed as contributing factors 506 (Lerch et al 2011;Schweizer et al 1999;Tieszen 1991;Wynn 2007). Carbon isotope values of 507 leaf wax n-alkanes may help to overcome these ambiguities because these are more diagnostic 508 than those from bulk sediments, which contain materials of both terrestrial and aquatic origin.…”

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confidence: 99%

Adaptations to sea level change and transitions to agriculture at Khao Toh Chong rockshelter, Peninsular Thailand

Marwick

Vlack

Conrad

et al. 2017

Journal of Archaeological Science

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This study reports on an analysis of human adaptations to sea level changes in the tropical monsoonal environment of Peninsula Thailand. We excavated Khao Toh Chong rockshelter in Krabi and recorded archaeological deposits spanning the last 13,000 years. A suite of geoarchaeological methods suggest largely uninterrupted deposition, against a backdrop of geological data that show major changes in sea levels. Although there is a small assemblage of mostly undiagnostic ceramics and stone artefacts, there are some distinct changes in stone artefact technology and ceramic fabric. There is a substantial faunal assemblage, with changes in both the mammalian and shellfish taxa during the Pleistocene-Holocene transition that correlate with local sea level fluctuation. This assemblage provides an opportunity to explore subsistence behaviours leading up to the transition to the Neolithic. We explore the implications for current debates on the prehistoric origins of agricultural subsistence in mainland Southeast Asia. The data highlight the importance of local contingencies in understanding the mechanisms of change from foragers to agriculturalists. Disciplines Medicine and Health Sciences | Social and Behavioral Sciences Publication DetailsMarwick, B., Van Vlack, H. G., Conrad, C., Shoocongdej, R., Thongcharoenchaikit, C. & Kwak, S. (2017

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Variations in microbial isotopic fractionation during soil organic matter decomposition

Cited by 82 publications

References 70 publications

Carbon allocation and carbon isotope fluxes in the plant-soil-atmosphere continuum: a review

Carbon allocation and carbon isotope fluxes in the plant-soil-atmosphere continuum: a review

From land to water, an overview of organic matter research in France––proceedings of the Sainte-Maxime 2009 symposium organized by the French network on organic matter research

Adaptations to sea level change and transitions to agriculture at Khao Toh Chong rockshelter, Peninsular Thailand

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