花青素
基因
盐度
生物
转基因作物
亚科
甘薯
异位表达
转基因
转录因子
基因家族
植物
多叶的
植物生理学
生物化学
旋花科
候选基因
抗氧化剂
食品科学
调节基因
氧化应激
遗传学
活性氧
功能性食品
非生物胁迫
细胞生物学
基因表达
基因表达调控
烟草
作者
Chen Chen,Qing Zhang,Ying Peng,Chao Liu,Tayachew Admas,Lianjun Wang,Xinsun Yang,Wenying Zhang
出处
期刊:Agronomy
[Multidisciplinary Digital Publishing Institute]
日期:2026-02-08
卷期号:16 (4): 408-408
标识
DOI:10.3390/agronomy16040408
摘要
Sweet potato (Ipomoea batatas L.) is a vital dual-use crop, with some varieties being used as leafy vegetables that are rich in anthocyanins. Nevertheless, salinity stress is a challenge to their production. Homeodomain-leucine zipper (HD-ZIP) gene family members encode proteins participating in the regulation of plant defense and secondary metabolism, while the functional study of HD-ZIP genes in sweet potato is still limited. Herein, a total of 66 IbHD-ZIP genes were identified, which were expanded by segmental duplication. Based upon promoter cis-element information and precedent evidence, IbHD-ZIP61, belonging to subfamily I, was selected for functional studies. Functional characterization was conducted via ectopic expression in transgenic Nicotiana benthamiana. The overexpression of IbHD-ZIP61 significantly increased anthocyanin production under normal growth conditions by promoting anthocyanin biosynthetic genes AN1a, AN2, and DFR. Furthermore, transgenic plants displayed better salinity tolerance, which exhibited reduced growth inhibition, increased water status, decreased oxidative injury, as well as elevated activity of antioxidant enzymes. This study validated the coordinated regulation of anthocyanin pathway genes as well as pivotal pathways (NHX2, NCED1, P5CS) during salinity adaptation. These findings demonstrate that IbHD-ZIP61 is a transcription factor linking anthocyanin synthesis and salinity adaptation, thus making it a potential candidate for improving breeding in nutritionally superior and salinity-adapted edible crops such as sweet potato.
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