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Literature DB >> 31015299

Modeling Protein Destiny in Developing Fruit.

Isma Belouah¹, Christine Nazaret², Pierre Pétriacq¹, Sylvain Prigent¹, Camille Bénard¹, Virginie Mengin³, Mélisande Blein-Nicolas⁴, Alisandra K Denton⁵, Thierry Balliau⁴, Ségolène Augé¹, Olivier Bouchez⁶, Jean-Pierre Mazat⁷, Mark Stitt³, Björn Usadel⁵, Michel Zivy⁴, Bertrand Beauvoit¹, Yves Gibon¹, Sophie Colombié⁸.

Abstract

Protein synthesis and degradation are essential processes that regulate cell status. Because labeling in bulky organs, such as fruits, is difficult, we developed a modeling approach to study protein turnover at the global scale in developing tomato (Solanum lycopersicum) fruit. Quantitative data were collected for transcripts and proteins during fruit development. Clustering analysis showed smaller changes in protein abundance compared to mRNA abundance. Furthermore, protein and transcript abundance were poorly correlated, and the coefficient of correlation decreased during fruit development and ripening, with transcript levels decreasing more than protein levels. A mathematical model with one ordinary differential equation was used to estimate translation (kt ) and degradation (kd ) rate constants for almost 2,400 detected transcript-protein pairs and was satisfactorily fitted for >1,000 pairs. The model predicted median values of ∼2 min for the translation of a protein, and a protein lifetime of ∼11 d. The constants were validated and inspected for biological relevance. Proteins involved in protein synthesis had higher kt and kd values, indicating that the protein machinery is particularly flexible. Our model also predicts that protein concentration is more strongly affected by the rate of translation than that of degradation.

Entities: Species

Year: 2019 PMID： 31015299 PMCID： PMC6752906 DOI： 10.1104/pp.19.00086

Source DB: PubMed Journal: Plant Physiol ISSN： 0032-0889 Impact factor: 8.340

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