Ecological stoichiometry as a foundation for omics-enabled biogeochemical models of soil organic matter decomposition

Graham, Emily B.; Hofmockel, Kirsten

doi:10.1007/s10533-021-00851-2

Cited by 14 publications

(17 citation statements)

References 186 publications

(226 reference statements)

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“…34,71,72 However, the current understanding of the relationships between C, N, DOM quantity and quality, and metabolism in rivers has mostly been derived from batch reactors, flowthrough columns, or field-scale experiments and observations. Taking advantage of the elemental stoichiometry of C and N (C/N) as a proxy for microbial nutrient limitations, 29,30,34 this work investigates the spatiotemporal relationships between aerobic metabolism, DOM, and the importance of C and N in the HZ. While we acknowledge that other elements may also constrain biological processes, we focused on N limitations due to recent work highlighting its possible interactions with DOM cycling in the river corridor.…”

Section: ■ Results and Discussionmentioning

confidence: 99%

“…29−33 While we acknowledge that other elements such as phosphorus and sulfur may also limit biological activities, we focus on N because it is a predominant limiting nutrient in temperate inland rivers and because field observations of interactions between several limiting elements are exceedingly difficult without experimentally disrupting natural dynamics. 34 This is evident from a recent small-scale, short-duration study by Garayburu-Caruso et al, 35 which proposed that integrated DOM and nutrient cycles are critical to regulating aerobic respiration (AR) in hyporheic environments through a trade-off between C and N limitations. The authors suggest that under C limitation, AR is regulated by DOM thermodynamics and that under N limitation, AR is regulated by organic N availability.…”

Section: ■ Introductionmentioning

confidence: 99%

“…The role of microbial nutrient limitations in regulating C turnover in natural environments remains an active area of research, largely because they are challenging to measure in situ . Considering that true measurements of nutrient limitations involve assessing the abilities of individuals to adjust to nutrient availability, relative changes in the ratio of C/N (i.e., elemental stoichiometry) are often used to infer the balance of C and N limitations. − While we acknowledge that other elements such as phosphorus and sulfur may also limit biological activities, we focus on N because it is a predominant limiting nutrient in temperate inland rivers and because field observations of interactions between several limiting elements are exceedingly difficult without experimentally disrupting natural dynamics …”

Section: Introductionmentioning

confidence: 99%

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Rethinking Aerobic Respiration in the Hyporheic Zone under Variation in Carbon and Nitrogen Stoichiometry

Tureţcaia,

Garayburu-Caruso,

Kaufman

et al. 2023

Environ. Sci. Technol.

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Hyporheic zones (HZs)�zones of groundwater− surface water mixing�are hotspots for dissolved organic matter (DOM) and nutrient cycling that can disproportionately impact aquatic ecosystem functions. However, the mechanisms affecting DOM metabolism through space and time in HZs remain poorly understood. To resolve this gap, we investigate a recently proposed theory describing trade-offs between carbon (C) and nitrogen (N) limitations as a key regulator of HZ metabolism. We propose that throughout the extent of the HZ, a single process like aerobic respiration (AR) can be limited by both DOM thermodynamics and N content due to highly variable C/N ratios over short distances (centimeter scale). To investigate this theory, we used a large flume, continuous optode measurements of dissolved oxygen (DO), and spatially and temporally resolved molecular analysis of DOM. Carbon and N limitations were inferred from changes in the elemental stoichiometric ratio. We show sequential, depth-stratified relationships of DO with DOM thermodynamics and organic N that change across centimeter scales. In the shallow HZ with low C/ N, DO was associated with the thermodynamics of DOM, while deeper in the HZ with higher C/N, DO was associated with inferred biochemical reactions involving organic N. Collectively, our results suggest that there are multiple competing processes that limit AR in the HZ. Resolving this spatiotemporal variation could improve predictions from mechanistic models, either via more highly resolved grid cells or by representing AR colimitation by DOM thermodynamics and organic N.

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Section: ■ Results and Discussionmentioning

confidence: 99%

Section: ■ Introductionmentioning

confidence: 99%

Section: Introductionmentioning

confidence: 99%

See 1 more Smart Citation

Rethinking Aerobic Respiration in the Hyporheic Zone under Variation in Carbon and Nitrogen Stoichiometry

Tureţcaia,

Garayburu-Caruso,

Kaufman

et al. 2023

Environ. Sci. Technol.

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“…Interestingly, the relative equivalence of predicted CUE across PyOM and DOM pools suggests that PyOM decomposition in rivers could emit comparable amounts of CO2 per mole of C to extant DOM pools. CUE is used in many microbially-explicit decomposition models to constrain organic matter bioavailability (reviewed in Graham and Hofmockel, 2022). Therefore, predicted CUE offers a path for assimilating PyOM in microbially-explicit models.…”

Section: Potential Bioavailability Of Pyrogenic Organic Mattermentioning

confidence: 99%

Potential bioavailability of pyrogenic organic matter resembles natural dissolved organic matter pools

Graham

Song

Samantha

et al. 2022

Preprint

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Abstract. Pyrogenic materials generated by wildfires are negatively impacting many aquatic ecosystems. At least ~10 % of dissolved organic matter (DOM) pools may be comprised of pyrogenic organic matter (PyOM) that is generally considered to be more refractory than DOM from other sources. However, there has been no systematic evaluation of bioavailability across a full spectrum of PyOM chemistries. We assessed the potential bioavailability of PyOM in relation to measured and globally ubiquitous DOM compounds using a substrate-explicit model to predict the energy content, metabolic efficiency, and aerobic decomposition of representative PyOM compounds. Overall, we found similar potential bioavailability between PyOM and sediment and surface water DOM. Predicted thermodynamics and carbon use efficiencies of PyOM and DOM were statistically indistinguishable. Within PyOM, phenols and black carbon (BC, defined by Wagner et al. (2017)) had lower metabolic efficiency than other PyOM and DOM compounds, and oxygen limitation had less impact on BC metabolism than on other PyOM classes. Our work supports the recent paradigm shift where PyOM bioavailability may be more comparable to natural organic matter than previously thought, highlighting its potential role in global C emissions and providing a basis for targeted laboratory investigations into the bioavailability of various PyOM chemistries.

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“…Soil organic matter (SOM) is a critical part of the global carbon (C) cycle. Belowground ecosystems contain more C than stored in terrestrial vegetation and the atmosphere combined (Crowther et al, 2019; Crowther et al, 2016; Jobbágy and Jackson, 2000), and SOM is the largest and most biologically active portion of soil C. SOM decomposition is regulated by a complex and interacting set of factors including soil structure, moisture distribution, temperature, pH, and nutrient status; collectively, these factors determine accessibility, bioavailability, and rate kinetics of SOM (Graham and Hofmockel, 2022). Despite the importance of SOM in the global C cycle, the drivers of SOM decomposition from molecular to continental scales are not well understood.…”

Section: Introductionmentioning

confidence: 99%

One thousand soils for molecular understanding of belowground carbon cycling

Bowman

Heath

Varga

et al. 2022

Preprint

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While significant progress has been made in understanding global carbon (C) cycling, the mechanisms regulating belowground C fluxes and storage are still uncertain. New molecular technologies have the power to elucidate these processes, yet we have no widespread standardized implementation of molecular techniques. To help address this gap, we have developed a crowdsourced soil core research program for analyzing molecular and microstructural data that describe soil structure, soil organic matter (SOM) chemistry, and soil microbiology. Known as the 1,000 Soils Pilot and based at the Environmental Molecular Sciences Laboratory (EMSL), we use Fourier-transform ion cyclotron resonance-(FTICR) and liquid chromatography-(LC) mass spectrometry (MS); X-ray Computed Tomography (XCT), water retention curves; metagenomic sequencing; and standard biogeochemical measurements to enable new insights into soil C cycles. To emphasize cross-site comparability, we provide standardized sampling materials and protocols, and all data are generated on dedicated instruments with optimized settings. Here, we describe the 1000 Soils Pilot and present a use case describing differences in SOM chemistry, soil structure, and chemical and biological properties across forest soils exposed to differing wildfire regimes. Data and analytic workflows from the 1000 Soils Pilot will populate a unique continental-scale database of soil molecular properties, as part of the EMSL Molecular Observation Network (MONet) user program.

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Ecological stoichiometry as a foundation for omics-enabled biogeochemical models of soil organic matter decomposition

Cited by 14 publications

References 186 publications

Rethinking Aerobic Respiration in the Hyporheic Zone under Variation in Carbon and Nitrogen Stoichiometry

Rethinking Aerobic Respiration in the Hyporheic Zone under Variation in Carbon and Nitrogen Stoichiometry

Potential bioavailability of pyrogenic organic matter resembles natural dissolved organic matter pools

One thousand soils for molecular understanding of belowground carbon cycling

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