Central Metabolism Is Tuned to the Availability of Oxygen in Developing Melon Fruit

Overview

Journal Front Plant Sci

Date 2019 Jun 4

PMID 31156666

Citations 3

Authors

Kentaro Mori

Bertrand P Beauvoit

Benoit Biais

Maxime Chabane

J William Allwood

Catherine Deborde

Mickael Maucourt

Royston Goodacre

Cecile Cabasson

Annick Moing

Dominique Rolin

Yves Gibon

Affiliations

Soon will be listed here.

Abstract

Respiration of bulky plant organs such as fleshy fruits depends on oxygen (O) availability and often decreases with O concentration to avoid anoxia, but the relationship between O diffusional resistance and metabolic adjustments remains unclear. Melon fruit ( L.) was used to study relationships between O availability and metabolism in fleshy fruits. Enzyme activities, primary metabolites and O partial pressure were quantified from the periphery to the inner fruit mesocarp, at three stages of development. Hypoxia was gradually established during fruit development, but there was no strong oxygen gradient between the outer- and the inner mesocarp. These trends were confirmed by a mathematical modeling approach combining O diffusion equations and O demand estimates of the mesocarp tissue. A multivariate analysis of metabolites, enzyme activities, O demand and concentration reveals that metabolite gradients and enzyme capacities observed in melon fruits reflect continuous metabolic adjustments thus ensuring a timely maturation of the mesocarp. The present results suggest that the metabolic adjustments, especially the tuning of the capacity of cytochrome c oxidase (COX) to O-availability that occurs during growth development, contribute to optimizing the O-demand and avoiding the establishment of an O gradient within the flesh.

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