Model-Assisted Analysis of Sugar Metabolism throughout Tomato Fruit Development Reveals Enzyme and Carrier Properties in Relation to Vacuole Expansion

Beauvoit, Bertrand; Colombié, Sophie; Monier, Antoine; Andrieu, Marie-Hélène; Biais, Benoît; Bénard, Camille; Chéniclet, Catherine; Dieuaide-Noubhani, Martine; Nazaret, Christine; Mazat, Jean‐Pierre; Gibon, Yves

doi:10.1105/tpc.114.127761

Cited by 101 publications

(96 citation statements)

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“…Biochemically, VIN activity may regulate reproductive development by modulating cytoplasmic hexose levels and sugar signaling. Flux analysis and modeling of sugar metabolism in tomato pericarp indicate that VIN-catalyzed sucrolytic activity in the vacuole induces hexose efflux from the vacuole into cytoplasm, coupled with Suc influx during cell division of fruit development (Beauvoit et al, 2014). Thus, VINs are able to regulate not only vacuolar sugar homeostasis but also cytosolic hexose levels through coupling with the activities of tonoplast sugar transporters.…”

Section: Vin Is Required For Floral Morphogenesis and The Formation Omentioning

confidence: 99%

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Critical Roles of Vacuolar Invertase in Floral Organ Development and Male and Female Fertilities Are Revealed through Characterization of GhVIN1-RNAi Cotton Plants

Wang

Ruan

2016

Plant Physiol.

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Seed number and quality are key traits determining plant fitness and crop yield and rely on combined competence in male and female fertilities. Sucrose metabolism is central to reproductive success. It remains elusive, though, how individual sucrose metabolic enzymes may regulate the complex reproductive processes. Here, by silencing vacuolar invertase (VIN) genes in cotton (Gossypium hirsutum) reproductive organs, we revealed diverse roles that VIN plays in multiple reproductive processes. A set of phenotypic and genetic studies showed significant reductions of viable seeds in GhVIN1-RNAi plants, attributed to pollination failure and impaired male and female fertilities. The former was largely owing to the spatial mismatch between style and stamen and delayed pollen release from the anthers, whereas male defects came from poor pollen viability. The transgenic stamen exhibited altered expression of the genes responsible for starch metabolism and auxin and jasmonic acid signaling. Further analyses identified the reduction of GhVIN expression in the seed coat as the major cause for the reduced female fertility, which appeared to disrupt the expression of some key genes involved in trehalose and auxin metabolism and signaling, leading to programmed cell death or growth repression in the filial tissues. Together, the data provide an unprecedented example of how VIN is required to synchronize style and stamen development and the formation of male and female fertilities for seed development in a crop species, cotton.

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Section: Vin Is Required For Floral Morphogenesis and The Formation Omentioning

confidence: 99%

“…9). Pertinently, VIN is the major enzyme hydrolyzing Suc in tomato pericarp at the cell division stage (Beauvoit et al, 2014), when unloading occurs symplasmically (Palmer et al, 2015).…”

Section: Vin Contributes To Male Fertility Probably By Impacting Starmentioning

confidence: 99%

Critical Roles of Vacuolar Invertase in Floral Organ Development and Male and Female Fertilities Are Revealed through Characterization of GhVIN1-RNAi Cotton Plants

Wang

Ruan

2016

Plant Physiol.

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“…Kinetic modelling of plant metabolism was used to unravel local and global system features, such as flux and concentration control coefficients and regulation patterns [44] in relation to different external or internal states, stimuli and conditions [31]. A kinetic model of sugar metabolism throughout tomato Solanum lycopersicum fruit development revealed importance of different enzymes on different development stages, as well as importance of sugar accumulation in vacuole together with organic acids to enable osmotic-driven vacuole expansion during the cell division [45]. Also, different regulatory scenarios of starch turnover by the circadian clock through dynamic adjustment of starch turnover to changing environmental conditions were suggested based on mathematical modelling [4].…”

Section: Introductionmentioning

confidence: 99%

Metabolic model of central carbon and energy metabolisms of growing Arabidopsis thaliana in relation to sucrose translocation

et al. 2016

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BackgroundSucrose translocation between plant tissues is crucial for growth, development and reproduction of plants. Systemic analysis of these metabolic and underlying regulatory processes allow a detailed understanding of carbon distribution within the plant and the formation of associated phenotypic traits. Sucrose translocation from ‘source’ tissues (e.g. mesophyll) to ‘sink’ tissues (e.g. root) is tightly bound to the proton gradient across the membranes. The plant sucrose transporters are grouped into efflux exporters (SWEET family) and proton-symport importers (SUC, STP families). To better understand regulation of sucrose export from source tissues and sucrose import into sink tissues, there is a need for a metabolic model that takes in account the tissue organisation of Arabidopsis thaliana with corresponding metabolic specificities of respective tissues in terms of sucrose and proton production/utilization. An ability of the model to operate under different light modes (‘light’ and ‘dark’) and correspondingly in different energy producing modes is particularly important in understanding regulatory modules.ResultsHere, we describe a multi-compartmental model consisting of a mesophyll cell with plastid and mitochondrion, a phloem cell, as well as a root cell with mitochondrion. In this model, the phloem was considered as a non-growing transport compartment, the mesophyll compartment was considered as both autotrophic (growing on CO2 under light) and heterotrophic (growing on starch in darkness), and the root was always considered as heterotrophic tissue dependent on sucrose supply from the mesophyll compartment. In total, the model includes 413 balanced compounds interconnected by 400 transformers. The structured metabolic model accounts for central carbon metabolism, photosynthesis, photorespiration, carbohydrate metabolism, energy and redox metabolisms, proton metabolism, biomass growth, nutrients uptake, proton gradient generation and sucrose translocation between tissues. Biochemical processes in the model were associated with gene-products (742 ORFs). Flux Balance Analysis (FBA) of the model resulted in balanced carbon, nitrogen, proton, energy and redox states under both light and dark conditions. The main H+-fluxes were reconstructed and their directions matched with proton-dependent sucrose translocation from ‘source’ to ‘sink’ under any light condition.ConclusionsThe model quantified the translocation of sucrose between plant tissues in association with an integral balance of protons, which in turn is defined by operational modes of the energy metabolism.Electronic supplementary materialThe online version of this article (doi:10.1186/s12870-016-0868-3) contains supplementary material, which is available to authorized users.

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“…Just like summer's best tomatoes in August (with all Model of carbohydrate metabolism in developing tomato fruit. For abbreviations, chemical reactions, rate equations, and kinetic parameters, see Beauvoit et al (2014). (Reprinted from Beauvoit et al [2014], Figure 2. …”

mentioning

confidence: 99%

“…Such modeling has examined the effects of increasing atmospheric CO 2 and the fluxes of carbohydrate metabolism in sugarcane (Saccharum officinarum) stem parenchyma and potato (Solanum tuberosum) tubers. In a new study, Beauvoit et al (2014) applied kinetic mathematical models to examine tomato (Solanum lycopersicum) fruit development.…”

mentioning

confidence: 99%

Modeling Sugar Metabolism in Tomato Fruit

Mach

2014

Plant Cell

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Model-Assisted Analysis of Sugar Metabolism throughout Tomato Fruit Development Reveals Enzyme and Carrier Properties in Relation to Vacuole Expansion

Cited by 101 publications

References 69 publications

Critical Roles of Vacuolar Invertase in Floral Organ Development and Male and Female Fertilities Are Revealed through Characterization of GhVIN1-RNAi Cotton Plants

Critical Roles of Vacuolar Invertase in Floral Organ Development and Male and Female Fertilities Are Revealed through Characterization of GhVIN1-RNAi Cotton Plants

Metabolic model of central carbon and energy metabolisms of growing Arabidopsis thaliana in relation to sucrose translocation

Modeling Sugar Metabolism in Tomato Fruit

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