Ascorbic acid metabolism is influenced by oxidation, recycling, synthesis and transport during fruit development of Malpighia emarginata

IF 2.2 4区 生物学 Q2 PLANT SCIENCES Theoretical and Experimental Plant Physiology Pub Date : 2023-12-12 DOI:10.1007/s40626-023-00297-x
João Alves Ferreira Pereira, Mônica Maria de Almeida Lopes, Carlos Farley Herbster Moura, Thais Andrade Germano, José Hélio Costa, Maria Raquel Alcântara de Miranda
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Abstract

This study evaluated gene expression and activity of key enzymes associated with L-ascorbic acid metabolism during the development of acerola. Acerola cv. Flor-branca shows a double sigmoid growth curve reaching physiological maturity at 17 days after anthesis (DAA) and is fully ripe at 21 DAA. Thus, fruits were analyzed at 15, 17, 19, 21 and 23 DAA. Total L-ascorbic acid (T-AsA) concentration declined 60% from immature green (15 DAA) to the fully ripe stage (21 DAA), with a relative increase in the content of the reduced form L-ascorbic acid (AsA). Regarding AsA biosynthesis, L-GalLDH activity increased during fruit development from 15 to 19 DAA. Oxidative enzyme activity patterns differed during ripening, APX was initially higher and decreased, while ascorbate oxidase (AO) activity was initially lower and then increased until 21 DAA. The activity patterns of recycling enzymes monodehydroascorbate reductase (MDHAR), dehydroascorbate reductase (DHAR) and glutathione reductase (GR) were similar and increased during fruit development. The genes associated with AsA biosynthesis (GalLDH, GMP and GME) showed similar expression profiles during fruit maturation (after 17 DAA) and may be related to the increase in L-GalLDH activity. The profile of genes linked to AsA degradation showed that AO isoform 2 is mainly involved in oxidation during fruit development. The high concentration of T-AsA in immature acerola seems related to cellular intake from phloem due to the high expression of the l-ascorbic acid transporter NAT3 gene. The data observed here gives an insight into the key points of regulation of AsA metabolism during acerola development that enables further fresh market and industrial uses, besides genetic manipulation efforts.

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果实发育过程中抗坏血酸代谢受氧化、循环、合成和运输的影响
本研究评估了针叶发育过程中与l -抗坏血酸代谢相关的关键酶的基因表达和活性。针叶简历。花枝呈双s型生长曲线,花后17 d生理成熟,21 d完全成熟。因此,在15、17、19、21和23 DAA对果实进行了分析。总l -抗坏血酸(T-AsA)浓度从未成熟青(15 DAA)到熟熟期(21 DAA)下降60%,还原型l -抗坏血酸(AsA)含量相对增加。在AsA生物合成方面,从15 DAA到19 DAA, L-GalLDH活性在果实发育过程中增加。氧化酶活性在成熟过程中表现为先升高后降低,抗坏血酸氧化酶(AO)活性先降低后升高,直至21 DAA。单脱氢抗坏血酸还原酶(MDHAR)、脱氢抗坏血酸还原酶(DHAR)和谷胱甘肽还原酶(GR)的活性模式相似,且在果实发育过程中呈增加趋势。与AsA生物合成相关的基因(GalLDH、GMP和GME)在果实成熟过程中(17 DAA后)表现出相似的表达谱,可能与L-GalLDH活性的增加有关。与AsA降解相关的基因图谱表明,AO异构体2主要参与果实发育过程中的氧化。由于l-抗坏血酸转运体NAT3基因的高表达,未成熟针叶中高浓度的T-AsA似乎与韧皮部的细胞摄入有关。这里观察到的数据为针叶生长过程中AsA代谢调节的关键点提供了深入的见解,除了基因操作之外,还可以进一步开发新的市场和工业用途。图形抽象
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来源期刊
CiteScore
4.20
自引率
7.70%
发文量
32
期刊介绍: The journal does not publish articles in taxonomy, anatomy, systematics and ecology unless they have a physiological approach related to the following sections: Biochemical Processes: primary and secondary metabolism, and biochemistry; Photobiology and Photosynthesis Processes; Cell Biology; Genes and Development; Plant Molecular Biology; Signaling and Response; Plant Nutrition; Growth and Differentiation: seed physiology, hormonal physiology and photomorphogenesis; Post-Harvest Physiology; Ecophysiology/Crop Physiology and Stress Physiology; Applied Plant Ecology; Plant-Microbe and Plant-Insect Interactions; Instrumentation in Plant Physiology; Education in Plant Physiology.
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