Transcriptome analysis of the pulp of citrus fruitlets suggests that domestication enhanced growth processes and reduced chemical defenses increasing palatability

Pérez-Román, Estela; Borredá, Carles; Tadeo, Francisco R.; Talón, Manuel

doi:10.3389/fpls.2022.982683

Cited by 3 publications

(1 citation statement)

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“…Major contributions about the analysis of natural variation of plant development and physiology highlighted genes involved in domestication traits (Perez‐Roman et al., 2022), such as those related to plant architecture, fruit and seed structure and morphology, as well as yield and quality traits for crop plants and Arabidopsis thaliana (Alonso‐Blanco et al., 2009). Natural variation has been used to study growth traits (e.g., biomass accumulation, morphology), primary metabolism and mineral nutrition especially in the agronomical context.…”

Section: Introductionmentioning

confidence: 99%

Comparative constraint‐based modelling of fruit development across species highlights nitrogen metabolism in the growth‐defence trade‐off

et al. 2023

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SUMMARYAlthough primary metabolism is well conserved across species, it is useful to explore the specificity of its network to assess the extent to which some pathways may contribute to particular outcomes. Constraint‐based metabolic modelling is an established framework for predicting metabolic fluxes and phenotypes and helps to explore how the plant metabolic network delivers specific outcomes from temporal series. After describing the main physiological traits during fruit development, we confirmed the correlations between fruit relative growth rate (RGR), protein content and time to maturity. Then a constraint‐based method is applied to a panel of eight fruit species with a knowledge‐based metabolic model of heterotrophic cells describing a generic metabolic network of primary metabolism. The metabolic fluxes are estimated by constraining the model using a large set of metabolites and compounds quantified throughout fruit development. Multivariate analyses showed a clear common pattern of flux distribution during fruit development with differences between fast‐ and slow‐growing fruits. Only the latter fruits mobilise the tricarboxylic acid cycle in addition to glycolysis, leading to a higher rate of respiration. More surprisingly, to balance nitrogen, the model suggests, on the one hand, nitrogen uptake by nitrate reductase to support a high RGR at early stages of cucumber and, on the other hand, the accumulation of alkaloids during ripening of pepper and eggplant. Finally, building virtual fruits by combining 12 biomass compounds shows that the growth‐defence trade‐off is supported mainly by cell wall synthesis for fast‐growing fruits and by total polyphenols accumulation for slow‐growing fruits.

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Section: Introductionmentioning

confidence: 99%