The Molecular Composition of Dissolved Organic Matter in Forest Soils as a Function of pH and Temperature

Roth, Vanessa-Nina; Dittmar, Thorsten; Gaupp, Reinhard; Gleixner, Gerd

doi:10.1371/journal.pone.0119188

Cited by 76 publications

(74 citation statements)

References 74 publications

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“…The high molecular diversity characteristic of SOM is often attributed to the chemistry of plant-derived compounds and their decomposition byproducts464748. Whether microbial metabolites, secretions and cellular material can also produce chemically heterogeneous SOM remains unclear4849.…”

Section: Discussionmentioning

confidence: 99%

Direct evidence for microbial-derived soil organic matter formation and its ecophysiological controls

2016

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Soil organic matter (SOM) and the carbon and nutrients therein drive fundamental submicron- to global-scale biogeochemical processes and influence carbon-climate feedbacks. Consensus is emerging that microbial materials are an important constituent of stable SOM, and new conceptual and quantitative SOM models are rapidly incorporating this view. However, direct evidence demonstrating that microbial residues account for the chemistry, stability and abundance of SOM is still lacking. Further, emerging models emphasize the stabilization of microbial-derived SOM by abiotic mechanisms, while the effects of microbial physiology on microbial residue production remain unclear. Here we provide the first direct evidence that soil microbes produce chemically diverse, stable SOM. We show that SOM accumulation is driven by distinct microbial communities more so than clay mineralogy, where microbial-derived SOM accumulation is greatest in soils with higher fungal abundances and more efficient microbial biomass production.

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Section: Discussionmentioning

confidence: 99%

Direct evidence for microbial-derived soil organic matter formation and its ecophysiological controls

2016

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“…Informative subsections of the DOM pool that potentially contain signaling information can be identified using nontargeted ultrahigh resolution mass spectrometry (HR-MS; Hertkorn et al, 2008Hertkorn et al, , 2013. HR-MS facilitates the analysis of the detailed molecular composition of DOM, generating information on individual molecular formulae and enabling the interpretation of molecular patterns across natural gradients (Jaffé et al, 2012;Ohno et al, 2014;Kellerman et al, 2015;Kothawala et al, 2015;Roth et al, 2015). Natural gradients of DOM age occur in groundwater following recharge events that lead to mixing or exchange of waters containing surface-sourced or in situ produced DOM (Sukhija et al, 2006;McMahon et al, 2011).…”

Section: Introductionmentioning

confidence: 99%

Fueling Diversity in the Subsurface: Composition and Age of Dissolved Organic Matter in the Critical Zone

et al. 2019

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Surface ecosystems are rapidly changing on a global scale and it is important to understand how this influences aquifers in the subsurface, as groundwater quality is a major concern for future generations. Dissolved organic matter (DOM) contains molecular and isotopic signals from surface-derived inputs as well as from the biotic and abiotic subsurface environment and is therefore ideal to study the connectivity between both environments. We evaluated a 3-year time series of DOM composition using ultrahigh resolution mass spectrometry and age using 14 C accelerator mass spectrometry along a hillslope well transect in the fractured bedrock of the Hainich Critical Zone Exploratory, Germany. We found a wide range of DOM 14 C depletion, from 14 C = −47.9 to 14 C = −782.4, within different zones of the shallow groundwater. The 14 C content of DOM mirrored the connectivity of the aquifers to the surface. The composition of DOM was highly interrelated with its 14 C age. The proportions of surface-derived DOM components decreased with DOM age, whereas microorganismderived DOM components increased. The intensity of surface-sourced DOM signals differed between the wells and likely reflected the hydrological complexity of fracturedrock environments. During recharge, DOM was more enriched in 14 C, contained more surface-derived molecular components and was more diverse. As a potential response to the varying DOM substrate, bacterial 16S rRNA gene analysis revealed community evolution and increased bacterial diversity during recharge. The influx of diverse, surface-derived DOM potentially fueled evolution within the autochthonous bacterial communities, as in contrast to DOM, the bacterial community did not retreat to the initial diversity and community composition during the recession period. Our results demonstrate on the one hand that combined analyses of the composition and age of groundwater DOM strongly contribute to the understanding of interconnections, community evolution and the functioning of subsurface ecosystems and on the other hand that changes in surface ecosystems have an imprint on subsurface ecosystems.

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“…The quantitative comparison of the occupation density of the six chemical class‐specific areas on the van Krevelen diagram (Figure ) enabled us to reveal the origin‐specific molecular features of the alkali‐extracted OM from the yedoma core versus the alas one. For HA representing the most abundant fraction of this OM (Table ), it was the presence of N‐containing saturated compounds usually referred to as aliphatic amines, peptides, and amino sugars (Roth et al, ), whose content increased with depth in the yedoma core, being negligibly small in the alas core. In addition, the much higher content of saturated CHO species (aliphatics) was observed in the yedoma HA fractions as compared to the alas ones.…”

Section: Discussionmentioning

confidence: 99%

The Molecular Composition of Humic Substances Isolated From Yedoma Permafrost and Alas Cores in the Eastern Siberian Arctic as Measured by Ultrahigh Resolution Mass Spectrometry

et al. 2019

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Ongoing climate change is making the large pool of organic matter (OM) stored in Arctic permafrost vulnerable to mobilization; thus, garnering a deeper understanding of molecular transformations within the abundant pool of soil OM, specifically humic substances, is crucial. Here we present the first high-resolution mass-spectrometry examination of molecular compositions of humic acid (HA) and fulvic acid (FA) isolated from organic-rich deep yedoma (Pleistocene age ice-rich permafrost) and alas (thermokarst deposit formed during permafrost thaw) cores. The FA fractions were dominated by oxygen-rich unsaturated compounds, whereas the HA fractions were mostly composed of relatively reduced saturated and aromatic moieties. A substantial increase in contribution of both CHO-only and N-containing aliphatic compounds was observed in the HA fractions of the yedoma OM with depth, whereas the alas HA fractions were depleted in aliphatics but enriched with condensed and hydrolyzable tannins. The observed differences in compositional space of the immobile OM stored in the deep yedoma versus alas deposits were consistent with evolution of OM during thermokarst lake genesis, implying intense microbial degradation of N-rich OM released from the yedoma deposits and accumulation of highly degraded, plant-derived OM. The patterns of molecular transformations of OM were apparent in compositional space of the least degraded HA fractions as compared to much more oxidized FA fractions. This shows great promise of molecular exploration of the alkali-extracted OM, comprising up to 50% of the total organic carbon in deep permafrost both for paleoreconstructions and predictions of climate feedback to released OM due to permafrost thaw.

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The Molecular Composition of Dissolved Organic Matter in Forest Soils as a Function of pH and Temperature

Cited by 76 publications

References 74 publications

Direct evidence for microbial-derived soil organic matter formation and its ecophysiological controls

Direct evidence for microbial-derived soil organic matter formation and its ecophysiological controls

Fueling Diversity in the Subsurface: Composition and Age of Dissolved Organic Matter in the Critical Zone

The Molecular Composition of Humic Substances Isolated From Yedoma Permafrost and Alas Cores in the Eastern Siberian Arctic as Measured by Ultrahigh Resolution Mass Spectrometry

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