乙烯
基因沉默
心理压抑
采后
生物合成
化学
生物化学
转录因子
抑制因子
芳香
基因表达
转录调控
基因表达调控
细胞生物学
抄写(语言学)
酰基转移酶
基因
蛋白质生物合成
葡萄酒的香气
脱落酸
代谢途径
糖
辅酶A
RNA干扰
油菜素甾醇
作者
Qing Cao,Jinyin Chen,Zhenyu Huang,Yupei Zhang,Congcong Yang,Kangyuan Xie,Huaxuan Hu,Chuying Chen,Yingying Yang,Wenbin Kai,Jiaoke Zeng,Ming Chen,Zengyu Gan
标识
DOI:10.1021/acs.jafc.5c16331
摘要
Aroma biosynthesis in postharvest kiwifruit is of great significance for fruit quality; yet, the underlying regulatory mechanisms remain unclear. This study investigated the dynamic changes and regulatory mechanisms governing ester aroma biosynthesis in postharvest kiwifruit. Ethylene accelerated fruit softening, sugar core formation, soluble solid accumulation, ethylene production, and ester biosynthesis, whereas 1-methylcyclopropene exerted the opposite effects. AcAAT1 was identified as a key acyltransferase gene responsible for ester biosynthesis. Functional analyses demonstrated that overexpression of AcAAT1 increased ester content, while its silencing reduced the ester compounds. Furthermore, transcription factor AcBBX19 was identified as a direct transcriptional repressor of AcAAT1. Ethylene signaling directly suppressed AcBBX19 expression. Protein interaction assays demonstrated that AcBBX19 physically interacts with AcbHLH153. Although AcbHLH153 cannot directly bind to the AcAAT1 promoter, it enhances the repressive activity of AcBBX19. Transient overexpression and silencing experiments confirmed that both proteins collaboratively inhibit AcAAT1 expression and ester biosynthesis. Collectively, our findings establish that ethylene promotes kiwifruit ester biosynthesis by suppressing the AcbHLH153-AcBBX19 transcriptional module, thereby alleviating the repression of the key gene AcAAT1. This study provides novel insights into the transcriptional regulatory network governing aroma formation in postharvest fruit.
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