Impact of soil matric potential on the fine-scale spatial distribution and activity of specific microbial degrader communities

Monard, Cécile; Mchergui, Chokri; Nunan, Naoise; Martin-Laurent, Fabrice; Vieublé-Gonod, Laure

doi:10.1111/j.1574-6941.2012.01398.x

Cited by 27 publications

(43 citation statements)

References 53 publications

(88 reference statements)

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“…Our scenarios generated a high but still realistic variability in biodegradation response. The coefficient of variation of 44% found here for 10-days CO 2 emissions was close to values obtained in experimental studies exploring the effect of spatial heterogeneity on the mineralization of soluble substrates at the millimeter scale: Monard A C C E P T E D M A N U S C R I P T et al obtained slightly lower CV for glucose (14-22%) [8], while CV values ranging from 25 to 160% have been found for the soluble pesticide 2,4-D [3,4,8].…”

Section: Discussionsupporting

confidence: 85%

“…The combined effect of substrate location and water potential was illustrated by experimental works based on the incubation of soluble substrates, such as glucose and 2,4-D [8], and benzoate [7]. Dechesne et al found cumulative effects of the water potential and the biomass distribution, with high water potential and dispersed distribution both stimulating the mineralization of benzoate [7].…”

Section: Discussionmentioning

confidence: 98%

“…The heterogeneity of the arrangement of soil particles (inter-aggregate vs intra-aggregate porosity) and the variation of water saturation conditions contribute to maintain gradients in abiotic conditions (nutrients, pH and redox conditions) and therefore locally promote or not the growth of microorganisms [6]. The patchy distribution patterns of bacteria in soils can result in spatial disconnection between organic residues and decomposers and thereby influence the kinetics of decomposition of organic compounds, as has been shown experimentally by [7,8]. The sinuous water diffusion pathways in the soil pore space through which nutrients can be transported can thus play a major role in these situations [9,10] although this can be mitigated by cells migration mechanisms allowing the microorganisms to reach distant resources [11][12][13][14].…”

Section: Introductionmentioning

confidence: 92%

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Modeling the effect of soil meso- and macropores topology on the biodegradation of a soluble carbon substrate

Vogel

Makowski

Garnier

et al. 2015

Advances in Water Resources

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International audienceSoil structure and interactions between biotic and abiotic processes are increasingly recognized as important for explaining the large uncertainties in the outputs of macroscopic SOM decomposition models. We present a numerical analysis to assess the role of meso- and macropore topology on the biodegradation of a soluble carbon substrate in variably water saturated and pure diffusion conditions . Our analysis was built as a complete factorial design and used a new 3D pore-scale model, LBioS, that couples a diffusion lattice-Boltzmann model and a compartmental biodegradation model. The scenarios combined contrasted modalities of four factors: meso- and macropore space geometry, water saturation, bacterial distribution and physiology. A global sensitivity analysis of these factors highlighted the role of physical factors in the biodegradation kinetics of our scenarios. Bacteria location explained 28% of the total variance in substrate concentration in all scenarios, while the interactions among location, saturation and geometry explained up to 51% of it

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Section: Discussionsupporting

confidence: 85%

Section: Discussionmentioning

confidence: 98%

Section: Introductionmentioning

confidence: 92%

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Modeling the effect of soil meso- and macropores topology on the biodegradation of a soluble carbon substrate

Vogel

Makowski

Garnier

et al. 2015

Advances in Water Resources

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“…In this case, intermediary metabolites must move into the soil to come into contact with the different degraders. Monard et al (2012) showed that an increase in soil water content led to a reduction in the spatial heterogeneity of pesticide mineralization, presumably by increasing the probability of degrader and substrate encounters.…”

Section: Introductionmentioning

confidence: 98%

The millimetre-scale distribution of 2,4-D and its degraders drives the fate of 2,4-D at the soil core scale

Pinheiro¹,

Garnier²,

Beguet

et al. 2015

Soil Biology and Biochemistry

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“…At the plot scale, agricultural practices and plant species are the determinants of heterogeneity (Etema and Wardle 2002;Chevallier et al 2000). At the fine process scale, the degree of heterogeneity depends on the soil physical structure, which corresponds to the spatial arrangement of solid particles (mineral particles, OM) and pores in which fluids, decomposers and soluble compounds circulate (Chenu and Stotzky 2002;Monard et al 2012). Understanding how the soil physical structure affects OM dynamics is crucial with a view to preserving or even increasing organic C stocks in soils.…”

Section: Localisation In the Physical Structure Of Soilmentioning

confidence: 99%

Increasing soil carbon storage: mechanisms, effects of agricultural practices and proxies. A review

Dignac

Derrien

Barré

et al. 2017

Agron. Sustain. Dev.

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358

170

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The international 4 per 1000 initiative aims at supporting states and non-governmental stakeholders in their efforts towards a better management of soil carbon (C) stocks. These stocks depend on soil C inputs and outputs. They are the result of fine spatial scale interconnected mechanisms, which stabilise/destabilise organic matter-borne C. Since 2016, the CarboSMS consortium federates French researchers working on these mechanisms and their effects on C stocks in a local and global change setting (land use, agricultural practices, climatic and soil conditions, etc.). This article is a synthesis of this consortium's first seminar. In the first part, we present recent advances in the understanding of soil C stabilisation mechanisms comprising biotic and abiotic processes, which occur concomitantly and interact. Soil organic C stocks are altered by biotic activities of plants (the main source of C through litter and root systems), microorganisms (fungi and bacteria) and 'ecosystem engineers' (earthworms, termites, ants). In the meantime, abiotic processes related to the soil-physical structure, porosity and mineral fraction also modify these stocks. In the second part, we show how agricultural practices affect soil C stocks. By acting on both biotic and abiotic mechanisms, land use and management practices This synthesis of the CarboSMS French consortium's first seminar was already published in French: Derrien D, Dignac M-F, Basile-Doelsch I, Barot S, Cécillon L, Chenu C, Chevallier T, Freschet GT, Garnier P, Guenet B, Hedde M, Klumpp K, Lashermes G, Maron P-A, Nunan N, Roumet C, Barré P (2016) (choice of plant species and density, plant residue exports, amendments, fertilisation, tillage, etc.) drive soil spatiotemporal organic inputs and organic matter sensitivity to mineralisation. Interaction between the different mechanisms and their effects on C stocks are revealed by meta-analyses and long-term field studies. The third part addresses upscaling issues. This is a cause for major concern since soil organic C stabilisation mechanisms are most often studied at fine spatial scales (mm-μm) under controlled conditions, while agricultural practices are implemented at the plot scale. We discuss some proxies and models describing specific mechanisms and their action in different soil and climatic contexts and show how they should be taken into account in large scale models, to improve change predictions in soil C stocks. Finally, this literature review highlights some future research prospects geared towards preserving or even increasing C stocks, our focus being put on the mechanisms, the effects of agricultural practices on them and C stock prediction models.

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Impact of soil matric potential on the fine-scale spatial distribution and activity of specific microbial degrader communities

Cited by 27 publications

References 53 publications

Modeling the effect of soil meso- and macropores topology on the biodegradation of a soluble carbon substrate

Modeling the effect of soil meso- and macropores topology on the biodegradation of a soluble carbon substrate

The millimetre-scale distribution of 2,4-D and its degraders drives the fate of 2,4-D at the soil core scale

Increasing soil carbon storage: mechanisms, effects of agricultural practices and proxies. A review

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