生物
油菜素内酯
基因沉默
转录因子
转录组
细胞生物学
基因
抄写(语言学)
基因表达
基因表达调控
信号转导
生物化学
突变体
RNA干扰
酵母
表型
转录调控
遗传学
植物
拟南芥
同源染色体
电泳迁移率测定
酿酒酵母
冷应激
代谢途径
作者
Chao Wang,Jinyu Yang,Yichen Zhao,De-Gang Zhao
摘要
Abstract Camellia sinensis (L.) O. Kuntze exhibits severely restricted growth at low temperatures, resulting in reduced tea leaf yield and quality. BRI1-EMS-suppressor (BES) transcription factors, as key components of the brassinosteroids (BR) signaling pathway, are highly homologous to BZR and jointly regulate plants’ adaptation to environmental stress. In this study, the CsBES1-14 gene was successfully cloned and identified from the transcriptome database of tea plant. Biochemical analyses identified CsBES1-14 as a nuclear localized transcriptional activator, and BR and low temperature induced its expression. Arabidopsis thaliana plants overexpressing CsBES1-14 exhibited increased chilling tolerance by promoting root growth and increasing the expression of cold responsive genes. Conversely, the suppression of CsBES1-14 through virus-induced gene silencing (VIGS) in tea plant notably impaired cold tolerance. Transcription Factor-centered Yeast One-Hybrid screening identified CsCOR413 as a downstream target, and electrophoretic mobility shift assays confirmed the direct binding of CsBES1-14 to specific cis-elements in the CsCOR413 promoter. Exogenous application of brassinazole (BRZ) and VIGS silencing experiments verified that the ICE-CBF cold response pathway could regulate the low-temperature-regulated protein CsCOR413. In summary, these findings elucidate that CsCOR413 expression is modulated not only by the classic ICE-CBF signaling pathway but also directly regulated by CsBES1-14. These findings outline the key components of the cold resistance network in tea plant and provide novel molecular targets for genetic improvement strategies in perennial crops.
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