Your search keyword '"Bontpart T"' showing total 5 results

1. Affordable and robust phenotyping framework to analyse root system architecture of soil-grown plants.

Author

Bontpart T, Concha C, Giuffrida MV, Robertson I, Admkie K, Degefu T, Girma N, Tesfaye K, Haileselassie T, Fikre A, Fetene M, Tsaftaris SA, and Doerner P

Subjects

Aging, Cicer anatomy & histology, Cicer genetics, Genotype, Hordeum anatomy & histology, Hordeum genetics, Phenotype, Soil, Plant Roots anatomy & histology

Abstract

The phenotypic analysis of root system growth is important to inform efforts to enhance plant resource acquisition from soils; however, root phenotyping remains challenging because of the opacity of soil, requiring systems that facilitate root system visibility and image acquisition. Previously reported systems require costly or bespoke materials not available in most countries, where breeders need tools to select varieties best adapted to local soils and field conditions. Here, we report an affordable soil-based growth (rhizobox) and imaging system to phenotype root development in glasshouses or shelters. All components of the system are made from locally available commodity components, facilitating the adoption of this affordable technology in low-income countries. The rhizobox is large enough (approximately 6000 cm 2 of visible soil) to avoid restricting vertical root system growth for most if not all of the life cycle, yet light enough (approximately 21 kg when filled with soil) for routine handling. Support structures and an imaging station, with five cameras covering the whole soil surface, complement the rhizoboxes. Images are acquired via the Phenotiki sensor interface, collected, stitched and analysed. Root system architecture (RSA) parameters are quantified without intervention. The RSAs of a dicot species (Cicer arietinum, chickpea) and a monocot species (Hordeum vulgare, barley), exhibiting contrasting root systems, were analysed. Insights into root system dynamics during vegetative and reproductive stages of the chickpea life cycle were obtained. This affordable system is relevant for efforts in Ethiopia and other low- and middle-income countries to enhance crop yields and climate resilience sustainably., (© 2020 The Authors. The Plant Journal published by Society for Experimental Biology and John Wiley & Sons Ltd.)

Published

2020

2. Two shikimate dehydrogenases, VvSDH3 and VvSDH4, are involved in gallic acid biosynthesis in grapevine.

Author

Bontpart T, Marlin T, Vialet S, Guiraud JL, Pinasseau L, Meudec E, Sommerer N, Cheynier V, and Terrier N

Subjects

Alcohol Oxidoreductases metabolism, Amino Acid Sequence, Escherichia coli genetics, Organisms, Genetically Modified growth & development, Phylogeny, Plant Proteins metabolism, Sequence Analysis, DNA, Vitis enzymology, Vitis metabolism, Alcohol Oxidoreductases genetics, Gallic Acid metabolism, Plant Proteins genetics, Vitis genetics

Abstract

In plants, the shikimate pathway provides aromatic amino acids that are used to generate numerous secondary metabolites, including phenolic compounds. In this pathway, shikimate dehydrogenases (SDH) 'classically' catalyse the reversible dehydrogenation of 3-dehydroshikimate to shikimate. The capacity of SDH to produce gallic acid from shikimate pathway metabolites has not been studied in depth. In grapevine berries, gallic acid mainly accumulates as galloylated flavan-3-ols. The four grapevine SDH proteins have been produced in Escherichia coli In vitro, VvSDH1 exhibited the highest 'classical' SDH activity. Two genes, VvSDH3 and VvSDH4, mainly expressed in immature berry tissues in which galloylated flavan-3-ols are accumulated, encoded enzymes with lower 'classical' activity but were able to produce gallic acid in vitro The over-expression of VvSDH3 in hairy-roots increased the content of aromatic amino acids and hydroxycinnamates, but had little or no effect on molecules more distant from the shikimate pathway (stilbenoids and flavan-3-ols). In parallel, the contents of gallic acid, β-glucogallin, and galloylated flavan-3-ols were increased, attesting to the influence of this gene on gallic acid metabolism. Phylogenetic analysis from dicotyledon SDHs opens the way for the examination of genes from other plants which accumulate gallic acid-based metabolites., (© The Author 2016. Published by Oxford University Press on behalf of the Society for Experimental Biology.)

Published

2016

3. BAHD or SCPL acyltransferase? What a dilemma for acylation in the world of plant phenolic compounds.

Author

Bontpart T, Cheynier V, Ageorges A, and Terrier N

Subjects

Acylation, Acyltransferases genetics, Multigene Family, Plants genetics, Secondary Metabolism, Acyltransferases metabolism, Phenols metabolism, Plants enzymology

Abstract

Phenolic compounds are secondary metabolites involved in several plant growth and development processes, including resistance to biotic and abiotic stresses. The biosynthetic pathways leading to the vast diversity of plant phenolic products often include an acylation step, with phenolic compounds being the donor or acceptor molecules. To date, two acyltransferase families using phenolic compounds as acceptor or donor molecules have been described, with each using a different 'energy-rich' acyl donor. BAHD-acyltransferases, named after the first four biochemically characterized enzymes of the group, use acyl-CoA thioesters as donor molecules, whereas SCPL (Serine CarboxyPeptidase Like)-acyltransferases use 1-O-β-glucose esters. Here, common and divergent specifications found in the literature for both enzyme families were analyzed to answer the following questions. Are both acyltransferases involved in the synthesis of the same molecule (or same group of molecules)? Are both acyltransferases recruited in the same plant? How does the subcellular localization of these enzymes impact metabolite trafficking in plant cells?, (© 2015 INRA. New Phytologist © 2015 New Phytologist Trust.)

Published

2015

4. Multivariate genetic analysis of plant responses to water deficit and high temperature revealed contrasting adaptive strategies.

Author

Vasseur F, Bontpart T, Dauzat M, Granier C, and Vile D

Subjects

Alleles, Ecotype, Environment, Factor Analysis, Statistical, Gene-Environment Interaction, Genotype, Models, Biological, Multivariate Analysis, Phenotype, Plant Development genetics, Principal Component Analysis, Quantitative Trait Loci genetics, Adaptation, Physiological genetics, Arabidopsis genetics, Arabidopsis physiology, Temperature, Water

Abstract

How genetic factors control plant performance under stressful environmental conditions is a central question in ecology and for crop breeding. A multivariate framework was developed to examine the genetic architecture of performance-related traits in response to interacting environmental stresses. Ecophysiological and life history traits were quantified in the Arabidopsis thaliana Ler × Cvi mapping population exposed to constant soil water deficit and high air temperature. The plasticity of the genetic variance-covariance matrix (G-matrix) was examined using mixed-effects models after regression into principal components. Quantitative trait locus (QTL) analysis was performed on the predictors of genotype effects and genotype by environment interactions (G × E). Three QTLs previously identified for flowering time had antagonistic G × E effects on carbon acquisition and the other traits (phenology, growth, leaf morphology, and transpiration). This resulted in a size-dependent response of water use efficiency (WUE) to high temperature but not soil water deficit, indicating that most of the plasticity of carbon acquisition and WUE to temperature is controlled by the loci that control variation of development, size, growth, and transpiration. A fourth QTL, MSAT2.22, controlled the response of carbon acquisition to specific combinations of watering and temperature irrespective of plant size and development, growth, and transpiration rate, which resulted in size-independent plasticity of WUE. These findings highlight how the strategies to optimize plant performance may differ in response to water deficit and high temperature (or their combination), and how different G × E effects could be targeted to improve plant tolerance to these stresses., (© The Author 2014. Published by Oxford University Press on behalf of the Society for Experimental Biology.)

Published

2014

5. The PGPR strain Phyllobacterium brassicacearum STM196 induces a reproductive delay and physiological changes that result in improved drought tolerance in Arabidopsis.

Author

Bresson J, Varoquaux F, Bontpart T, Touraine B, and Vile D

Subjects

Arabidopsis growth & development, Arabidopsis physiology, Biomass, Droughts, Phenotype, Photosynthesis physiology, Plant Leaves growth & development, Plant Leaves microbiology, Plant Leaves physiology, Plant Shoots growth & development, Plant Shoots microbiology, Plant Shoots physiology, Plant Stomata growth & development, Plant Stomata microbiology, Plant Stomata physiology, Reproduction, Arabidopsis microbiology, Carbon metabolism, Gene Expression Regulation, Plant, Phyllobacteriaceae physiology, Plant Transpiration physiology, Water physiology

Abstract

Understanding how biotic interactions can improve plant tolerance to drought is a challenging prospect for agronomy and ecology. Plant growth-promoting rhizobacteria (PGPR) are promising candidates but the phenotypic changes induced by PGPR under drought remain to be elucidated. We investigated the effects of Phyllobacterium brassicacearum STM196 strain, a PGPR isolated from the rhizosphere of oilseed rape, on two accessions of Arabidopsis thaliana with contrasting flowering time. We measured multiple morphophysiological traits related to plant growth and development in order to quantify the added value of the bacteria to drought-response strategies of Arabidopsis in soil conditions. A delay in reproductive development induced by the bacteria resulted in a gain of biomass that was independent of the accession and the watering regime. Coordinated changes in transpiration, ABA content, photosynthesis and development resulted in higher water-use efficiency and a better tolerance to drought of inoculated plants. Our findings give new insights into the ecophysiological bases by which PGPR can confer stress tolerance to plants. Rhizobacteria-induced delay in flowering time could represent a valuable strategy for increasing biomass yield, whereas rhizobacteria-induced improvement of water use is of particular interest in multiple scenarios of water availability., (© 2013 The Authors. New Phytologist © 2013 New Phytologist Trust.)

Published

2013