Abstract
The taproot of radish (Raphanus sativus L.) is an important sink organ; it is morphologically diverse and contains large amounts of secondary metabolites. Sucrose metabolism is believed to be important in the development of sink organs. We measured the amounts of glucose, fructose, and sucrose in the roots of sixty three radish accessions and analyzed the association between the sugar content and the root phenotype. Fructose content correlated with the root color and length characteristics, glucose was the most abundant sugar in the roots, and the sucrose content was very low, compared to that of the hexoses in most of the accessions. Expression analysis of the genes involved in sucrose metabolism, transportation, starch synthesis, and cell wall synthesis was performed through RNA sequencing. The genes encoding sucrose synthases (SUSY) and the enzymes involved in the synthesis of cellulose were highly expressed, indicating that SUSY is involved in cell wall synthesis in radish roots. The positive correlation coefficient (R) between the sucrose content and the expression of cell wall invertase and sugar transporter proteins suggest that hexose accumulation could occur through the apoplastic pathway in radish roots. A positive R score was also obtained when comparing the expression of genes encoding SUSY and fructokinase (FK), suggesting that the fructose produced by SUSY is mostly phosphorylated by FK. In addition, we concluded that sucrose was the most metabolized sugar in radish roots.
Highlights
Radish (Raphanus sativus L.) is a nutritionally important root crop belonging to the Brassicaceae family, which includes cabbage, kale, and broccoli
Sucrose content did not show a significant correlation with the expression levels of any of the sugar transporters (Supplementary Figure 7C, upper). These results indicate that the sucrose content in radish roots was not influenced by the expression levels of genes involved in sucrose metabolism, including the sucrose transporters
sucrose synthase (SUSY) is directly associated with the synthesis of cellulose and callose in the plasma membrane and is involved in starch biosynthesis in the cytoplasm (Amor et al, 1995); and we identified seven genes involved in starch synthesis, 23 genes involved in callose synthesis, and 15 genes responsible for cellulose synthesis (Supplementary Table 5)
Summary
Radish (Raphanus sativus L.) is a nutritionally important root crop belonging to the Brassicaceae family, which includes cabbage, kale, and broccoli. Sucrose metabolism is considered essential for root growth and development in radish, because it is active when the tuberous roots begin to develop It is a signal molecule regulating the expression of transcription factors, microRNAs, plant hormones, and many other genes (Stokes et al, 2013; Xiong et al, 2013; Mitsui et al, 2015; Yu et al, 2016). F6P is used to resynthesize sucrose by combining it with UDP-G in the cytosol This complex is converted to sucrose-6-phosphate (S6P) by sucrose-6-phosphate synthase (SPS), S6P can be dephosphorylated by sucrosephosphate phosphatase (SPP) to form sucrose (Stein and Granot, 2019). G6P and F6P can be used for glycolytic respiration in the cytosol and plastids (Granot et al, 2013; Stein and Granot, 2018)
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