Down regulation of StGA3ox genes in potato results in altered GA content and affect plant and tuber growth characteristics

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• 作者：Efstathios Roumeliotis ; Bjorn Kloosterman ; Marian Oortwijn ; Theo Lange ; Richard G.F. Visser ; Christian W.B. Bachem
• 关键词：Gibberellins ; Potato ; StGA30x2 ; Tuberization
• 刊名：Journal of Plant Physiology
• 出版年：2013
• 出版时间：15 September, 2013
• 年：2013
• 卷：170
• 期：14
• 页码：1228-1234
• 全文大小：1289 K

文摘

GA biosynthesis and catabolism has been shown to play an important role in regulating tuberization in potato. Active GAs are inactivated in the stolon tips shortly after induction to tuberization. Overexpression of a GA inactivation gene results in an earlier tuberization phenotype, while reducing expression of the same gene results in delayed tuberization. In addition, overexpression of genes involved in GA biosynthesis results in delayed tuberization, while decreased expression of those genes results in earlied tuberization. The final step in GA biosynthesis is catalysed by StGA3ox1 and StGA3ox2 activity, that convert inactive forms of GA into active GA₁ and GA₄. In this study we cloned StGA3ox2 gene in an RNAi construct and used this construct to transform potato plants. The StGA3ox2 silenced plants were smaller and had shorter internodes. In addition, we assayed the concentrations of various GAs in the transgenic plants and showed an altered GA content. No difference was observed on the time point of tuber initiation. However, the transgenic clones had increased number of tubers with the same yield, resulting in smaller average tuber weight. In addition, we cloned the promoter of StGA3ox2 to direct expression of the GUS reporter gene to visualize the sites of GA biosynthesis in the potato plant. Finally, we discuss how changes of several GA levels can have an impact on shoot, stolon and tuber development, as well as the possible mechanisms that mediate feed-forward and feed-back regulation loops in the GA biosynthetic pathway in potato.