Jin Seok Yoon scite author profile

Background Flavonoids can protect plants against extreme temperatures and ROS due to their antioxidant activities. We found that deep-purple seed coat color was controlled by two gene interaction (12:3:1) from the cross between yellow and deep-purple seed coat colored inbreds. F2:3 seeds were grouped in 3 by seed coat color and germinated under chilling (4 °C) and non-acclimated conditions (18 °C) for a week, followed by normal conditions (18 °C) for three weeks and a subsequent chilling stress (4 °C) induction. We analyzed mean daily germination in each group. Additionally, to study the acclimation in relationship to the different seed coat colors on the germination ability and seedling performances under the cold temperatures, we measured the chlorophyll content, ROS scavenging activity, and expression levels of genes involved in ROS scavenging, flavonoid biosynthetic pathway, and cold response in seedlings. Results The results of seed color segregation between yellow and deep purple suggested a two-gene model. In the germination study, normal environmental conditions induced the germination of yellow-seed, while under chilling conditions, the germination ratio of deep purple-seed was higher than that of yellow-colored seeds. We also found that the darker seed coat colors were highly responsive to cold acclimation based on the ROS scavenging enzymes activity and gene expression of ROS scavenging enzymes, flavonoid biosynthetic pathway and cold responsive genes. Conclusions We suggest that deep purple colored seed might be in a state of innate pre-acquired stress response state under normal conditions to counteract stresses in a more effective way. Whereas, after the acclimation, another stress should enhance the cold genes expression response, which might result in a more efficient chilling stress response in deep purple seed seedlings. Low temperature has a large impact on the yield of crops. Thus, understanding the benefit of seed coat color response to chilling stress and the identification of limiting factors are useful for developing breeding strategies in order to improve the yield of wheat under chilling stress.

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Characterization of 4 TaGAST genes during spike development and seed germination and their response to exogenous phytohormones in common wheat

Kim¹,

Kim²,

Yoon³

et al. 2016

Mol Biol Rep

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Gibberellic acid (GA) is involved in the regulation of plant growth and development. We defined GA-stimulated transcript (GAST) gene family and characterized its four members (TaGAST1, 2, 3, and 4) in wheat spikes. Triticum aestivum whole spikes were collected at ten developmental stages and dehulled spikelets were obtained at various days after flowering. Expression of TaGAST1, 2, 3, and 4 was analyzed using RT-PCR at inflorescence development stages, in different tissues, and after phytohormones application. To identify proteins interacting with TaGAST1, yeast two-hybridization was performed and BiFC analysis was used for verification. TaGAST1 was expressed at the inflorescence stage and only expressed in seedlings under abscisic acid (ABA) treatment after phytohormone treatment. TaGAST2 and TaGAST3 showed moderate expression in the spike, vigorous transcript accumulation in the seedling, and up-regulation by exogenous GA in early germination stages. TaGAST4 was predominantly expressed in the seedling. Wheat cyclophilin A-1 (TaCypA1), identified as a TaGAST1-interacting protein, showed opposite expression pattern in the developing spike to TaGAST1. TaCypA1 transcript was slightly up-regulated by GA, slightly down-regulated by paclobutrazol, and was maintained after ABA treatment. The interaction of TaGAST1 with TaCypA1 is targeted to the plasma membrane. TaGAST1 was specifically expressed in the wheat spike and was stimulated by exogenous GA treatment. TaGAST2 and TaGAST3 expression in germinating seeds and seedlings was higher than that in the spike stage. TaGAST4 was not expressed in all developmental stages. TaGAST1 and TaCypA1 might be expressed antagonistically during wheat spike development.

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Jin Seok Yoon

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Characterization of 4 TaGAST genes during spike development and seed germination and their response to exogenous phytohormones in common wheat

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