Your search keyword '"Nazaret, Christine"' showing total 2 results

1. Respiration climacteric in tomato fruits elucidated by constraint-based modelling.

Author

Colombié, Sophie, Beauvoit, Bertrand, Nazaret, Christine, Bénard, Camille, Vercambre, Gilles, Le Gall, Sophie, Biais, Benoit, Cabasson, Cécile, Maucourt, Mickaël, Bernillon, Stéphane, Moing, Annick, Dieuaide‐Noubhani, Martine, Mazat, Jean‐Pierre, and Gibon, Yves

Subjects

TOMATOES, PLANT metabolism, PLANT physiology, RESPIRATION in plants, GAS exchange in plants, PHYSIOLOGY

Abstract

Tomato is a model organism to study the development of fleshy fruit including ripening initiation. Unfortunately, few studies deal with the brief phase of accelerated ripening associated with the respiration climacteric because of practical problems involved in measuring fruit respiration., Because constraint-based modelling allows predicting accurate metabolic fluxes, we investigated the respiration and energy dissipation of fruit pericarp at the breaker stage using a detailed stoichiometric model of the respiratory pathway, including alternative oxidase and uncoupling proteins. Assuming steady-state, a metabolic dataset was transformed into constraints to solve the model on a daily basis throughout tomato fruit development., We detected a peak of CO2 released and an excess of energy dissipated at 40 d post anthesis ( DPA) just before the onset of ripening coinciding with the respiration climacteric. We demonstrated the unbalanced carbon allocation with the sharp slowdown of accumulation (for syntheses and storage) and the beginning of the degradation of starch and cell wall polysaccharides. Experiments with fruits harvested from plants cultivated under stress conditions confirmed the concept., We conclude that modelling with an accurate metabolic dataset is an efficient tool to bypass the difficulty of measuring fruit respiration and to elucidate the underlying mechanisms of ripening. [ABSTRACT FROM AUTHOR]

Published

2017

2. Modelling central metabolic fluxes by constraint-based optimization reveals metabolic reprogramming of developing Solanum lycopersicum (tomato) fruit.

Author

Colombié, Sophie, Nazaret, Christine, Bénard, Camille, Biais, Benoît, Mengin, Virginie, Solé, Marion, Fouillen, Laëtitia, Dieuaide‐Noubhani, Martine, Mazat, Jean‐Pierre, Beauvoit, Bertrand, and Gibon, Yves

Subjects

*TOMATOES, *PLANT metabolism, *SYSTEMS biology, *GLYCOLYSIS, *PLANT metabolites, *PLANTS, FRUIT physiology

Abstract

Modelling of metabolic networks is a powerful tool to analyse the behaviour of developing plant organs, including fruits. Guided by our current understanding of heterotrophic metabolism of plant cells, a medium-scale stoichiometric model, including the balance of co-factors and energy, was constructed in order to describe metabolic shifts that occur through the nine sequential stages of Solanum lycopersicum (tomato) fruit development. The measured concentrations of the main biomass components and the accumulated metabolites in the pericarp, determined at each stage, were fitted in order to calculate, by derivation, the corresponding external fluxes. They were used as constraints to solve the model by minimizing the internal fluxes. The distribution of the calculated fluxes of central metabolism were then analysed and compared with known metabolic behaviours. For instance, the partition of the main metabolic pathways (glycolysis, pentose phosphate pathway, etc.) was relevant throughout fruit development. We also predicted a valid import of carbon and nitrogen by the fruit, as well as a consistent CO2 release. Interestingly, the energetic balance indicates that excess ATP is dissipated just before the onset of ripening, supporting the concept of the climacteric crisis. Finally, the apparent contradiction between calculated fluxes with low values compared with measured enzyme capacities suggest a complex reprogramming of the metabolic machinery during fruit development. With a powerful set of experimental data and an accurate definition of the metabolic system, this work provides important insight into the metabolic and physiological requirements of the developing tomato fruits. [ABSTRACT FROM AUTHOR]

Published

2015