Chokri Mchergui scite author profile

The impact of the soil matric potential on the relationship between the relative abundance of degraders and their activity and on the spatial distribution of both at fine scales was determined to understand the role of environmental conditions in the degradation of organic substrates. The mineralization of (13) C-glucose and (13) C-2,4-dichlorophenoxyacetic acid (2,4-D) was measured at different matric potentials (-0.001, -0.01 and -0.316 MPa) in 6 × 6 × 6 mm(3) cubes excised from soil cores. At the end of the incubation, total bacterial and 2,4-D degrader abundances were determined by quantifying the 16S rRNA and the tfdA genes, respectively. The mineralization of 2,4-D was more sensitive to changes in matric potential than was that of glucose. The amount and spatial structure of 2,4-D mineralization decreased with matric potential, whilst the spatial variability increased. On the other hand, the spatial variation of glucose mineralization was less affected by changes in matric potential. The relationship between the relative abundance of 2,4-D degraders and 2,4-D mineralization was significantly affected by matric potential: the relative abundance of tfdA needed to be higher to reach a given level of 2,4-D mineralization in dryer than in moister conditions. The data show how microbial interactions with their microhabitat can have an impact on soil processes at larger scales.

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A comparison of permanent and fluctuating flooding on microbial properties in an ex-situ estuarine riparian system

Mchergui

Besaury

Langlois

et al. 2014

Applied Soil Ecology

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Real-time PCR for quantification in soil of glycoside hydrolase family 6 cellulase genes

Merlin

Besaury

Niepceron

et al. 2014

Lett Appl Microbiol

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Significance and impact of the study: Telluric micro-organisms able to use cellulose as carbon and energy sources for growth are widely distributed in the environment, but the factors controlling the rate of cellulose degradation are not well understood. The objective of our study was to develop a qPCR for rapid quantification of GH6 cellulase genes in soil. This qPCR could be applied to study the potential for cellulose degradation in different soils in order to better understand the factors controlling the stability of the soil organic matter. AbstractCellulose is the main structural component of the cell walls of higher plants, representing c. 35-50% of a plant's dry weight; after decomposition and transformation, and constituting a large part of soil organic matter. Telluric micro-organisms able to use cellulose as carbon and energy sources for growth are widely distributed in the environment, but the factors controlling the rate of cellulose degradation are not well understood. In this study, we have developed a quantitative real-time PCR (qPCR) primer set to quantify the glycoside hydrolase family 6 (GH6 family) cellulase genes in soil samples. The qPCR assays were linear over 8 orders of magnitude and sensitive down to 10 copies per assay. qPCR analysis of contrasted soil samples showed densities between 2Á47 9 10 7 and 1Á48 9 10 10 copies per gram of soil. Cloning and sequencing of the PCR products from environmental DNA confirmed both specific amplification (more than 96%) and the wide diversity targeted by the primer set, throughout nearly all the GH6 family, including sequences of bacteria and fungi.

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Chemical changes during composting of plant residues reduce their mineralisation in soil and cancel the priming effect

Lerch

Dignac

Thévenot

et al. 2019

Soil Biology and Biochemistry

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Chokri Mchergui

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

A comparison of permanent and fluctuating flooding on microbial properties in an ex-situ estuarine riparian system

Real-time PCR for quantification in soil of glycoside hydrolase family 6 cellulase genes

Chemical changes during composting of plant residues reduce their mineralisation in soil and cancel the priming effect

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