The New Zealand Institute for Plant and Food Research Limited (PFR), Private Bag 92169, Auckland, 1142, New Zealand.
School of Biological Sciences, University of Auckland, Private Bag 92019, Auckland, 1142, New Zealand.
BMC Plant Biol. 2021 Sep 8;21(1):411. doi: 10.1186/s12870-021-03154-8.
The phytohormone ethylene controls many processes in plant development and acts as a key signaling molecule in response to biotic and abiotic stresses: it is rapidly induced by flooding, wounding, drought, and pathogen attack as well as during abscission and fruit ripening. In kiwifruit (Actinidia spp.), fruit ripening is characterized by two distinct phases: an early phase of system-1 ethylene biosynthesis characterized by absence of autocatalytic ethylene, followed by a late burst of autocatalytic (system-2) ethylene accompanied by aroma production and further ripening. Progress has been made in understanding the transcriptional regulation of kiwifruit fruit ripening but the regulation of system-1 ethylene biosynthesis remains largely unknown. The aim of this work is to better understand the transcriptional regulation of both systems of ethylene biosynthesis in contrasting kiwifruit organs: fruit and leaves.
A detailed molecular study in kiwifruit (A. chinensis) revealed that ethylene biosynthesis was regulated differently between leaf and fruit after mechanical wounding. In fruit, wound ethylene biosynthesis was accompanied by transcriptional increases in 1-aminocyclopropane-1-carboxylic acid (ACC) synthase (ACS), ACC oxidase (ACO) and members of the NAC class of transcription factors (TFs). However, in kiwifruit leaves, wound-specific transcriptional increases were largely absent, despite a more rapid induction of ethylene production compared to fruit, suggesting that post-transcriptional control mechanisms in kiwifruit leaves are more important. One ACS member, AcACS1, appears to fulfil a dominant double role; controlling both fruit wound (system-1) and autocatalytic ripening (system-2) ethylene biosynthesis. In kiwifruit, transcriptional regulation of both system-1 and -2 ethylene in fruit appears to be controlled by temporal up-regulation of four NAC (NAM, ATAF1/2, CUC2) TFs (AcNAC1-4) that induce AcACS1 expression by directly binding to the AcACS1 promoter as shown using gel-shift (EMSA) and by activation of the AcACS1 promoter in planta as shown by gene activation assays combined with promoter deletion analysis.
Our results indicate that in kiwifruit the NAC TFs AcNAC2-4 regulate both system-1 and -2 ethylene biosynthesis in fruit during wounding and ripening through control of AcACS1 expression levels but not in leaves where post-transcriptional/translational regulatory mechanisms may prevail.
植物激素乙烯控制着植物发育的许多过程,并作为响应生物和非生物胁迫的关键信号分子发挥作用:它会被水淹、创伤、干旱和病原体攻击以及脱落和果实成熟迅速诱导。在猕猴桃(Actinidia spp.)中,果实成熟分为两个明显的阶段:以缺乏自催化乙烯为特征的早期 1 型乙烯生物合成阶段,随后是自催化(2 型)乙烯的晚期爆发,伴随着香气的产生和进一步的成熟。人们在理解猕猴桃果实成熟的转录调控方面取得了进展,但 1 型乙烯生物合成的调控仍知之甚少。本工作的目的是更好地理解在对比猕猴桃器官(果实和叶片)中两种乙烯生物合成系统的转录调控。
在猕猴桃(A. chinensis)中的详细分子研究表明,机械创伤后,叶片和果实中的乙烯生物合成受到不同的调控。在果实中,伤口乙烯生物合成伴随着 1-氨基环丙烷-1-羧酸(ACC)合成酶(ACS)、ACC 氧化酶(ACO)和 NAC 类转录因子(TFs)成员的转录增加。然而,与果实相比,猕猴桃叶片中伤口特异性的转录增加几乎不存在,尽管乙烯产生的诱导更为迅速,这表明猕猴桃叶片中更为重要的是转录后调控机制。一个 ACS 成员 AcACS1 似乎发挥着主导的双重作用;控制果实伤口(1 型)和自催化成熟(2 型)乙烯生物合成。在猕猴桃中,果实中 1 型和 2 型乙烯的转录调控似乎受到四个 NAC(NAM、ATAF1/2、CUC2)TFs(AcNAC1-4)的时间上调控制,这些 TFs 通过直接结合 AcACS1 启动子,如凝胶迁移(EMSA)所示,以及通过基因激活测定与启动子缺失分析相结合,在体内激活 AcACS1 启动子,从而诱导 AcACS1 的表达。
我们的结果表明,在猕猴桃中,NAC TFs AcNAC2-4 通过控制 AcACS1 表达水平来调节果实创伤和成熟过程中 1 型和 2 型乙烯的生物合成,但在叶片中则不然,可能存在转录后/翻译调控机制。
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