在猕猴桃早期果实发育过程中，抗坏血酸的生物合成是其积累的主要原因。

Ascorbate biosynthesis during early fruit development is the main reason for its accumulation in kiwi.

机构信息

College of Horticulture, Northwest A&F University, Yangling, China.

出版信息

PLoS One. 2010 Dec 9;5(12):e14281. doi: 10.1371/journal.pone.0014281.

DOI:10.1371/journal.pone.0014281

PMID:21151561

原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC3000333/

Abstract

BACKGROUND

Ascorbic acid (AsA) is a unique antioxidant as well as an enzyme cofactor. Although it has multiple roles in plants, it is unclear how its accumulation is controlled at the expression level, especially in sink tissues. Kiwifruit (Actinidia) is well-known for its high ascorbate content. Our objective was to determine whether AsA accumulates in the fruits primarily through biosynthesis or because it is imported from the foliage.

METHODOLOGY/PRINCIPAL FINDINGS: We systematically investigated AsA levels, biosynthetic capacity, and mRNA expression of genes involved in AsA biosynthesis in kiwi (A. deliciosa cv. Qinmei). Recycling and AsA localization were also monitored during fruit development and among different tissue types. Over time, the amount of AsA, with its capacity for higher biosynthesis and lower recycling, peaked at 30 days after anthesis (DAA), and then decreased markedly up to 60 DAA before declining more slowly. Expression of key genes showed similar patterns of change, except for L-galactono-1,4-lactone dehydrogenase and L-galactose-1-phosphate phosphatase (GPP). However, GPP had good correlation with the rate of AsA accumulation. The expression of these genes could be detected in phloem of stem as well as petiole of leaf and fruit. Additionally, fruit petioles had greater ascorbate amounts, although that was the site of lowest expression by most genes. Fruit microtubule tissues also had higher AsA. However, exogenous applications of AsA to those petioles did not lead to its transport into fruits, and distribution of ascorbate was cell-specific in the fruits, with more accumulation occurring in larger cells.

CONCLUSIONS

These results suggest that AsA biosynthesis in kiwi during early fruit development is the main reason for its accumulation in the fruits. We also postulate here that GPP is a good candidate for regulating AsA biosynthesis whereas GDP-L-galactose-1-phosphate phosphorylase is not.

摘要

背景

抗坏血酸（AsA）是一种独特的抗氧化剂和酶辅因子。尽管它在植物中有多种作用，但在表达水平上，其积累是如何控制的尚不清楚，特别是在汇组织中。猕猴桃以其高抗坏血酸含量而闻名。我们的目标是确定 AsA 是否主要通过生物合成在果实中积累，还是因为它是从叶片中输入的。

方法/主要发现：我们系统地研究了猕猴桃（A. deliciosa cv. Qinmei）中 AsA 水平、生物合成能力以及参与 AsA 生物合成的基因的 mRNA 表达。在果实发育过程中和不同组织类型中也监测了再循环和 AsA 定位。随着时间的推移，AsA 的含量及其更高的生物合成能力和更低的再循环能力在授粉后 30 天（DAA）达到峰值，然后在 60 DAA 之前明显下降，然后下降速度变慢。关键基因的表达也表现出相似的变化模式，除了 L-半乳糖酸-1,4-内酯脱氢酶和 L-半乳糖-1-磷酸磷酸酶（GPP）。然而，GPP 与 AsA 积累速率有很好的相关性。这些基因的表达可以在茎的韧皮部以及叶和果实的叶柄中检测到。此外，尽管大多数基因在叶柄中表达水平最低，但果实叶柄中的抗坏血酸含量更高。果实微管组织中的 AsA 含量也较高。然而，将外源 AsA 应用于这些叶柄并不会导致其运输到果实中，并且果实中的抗坏血酸分布是细胞特异性的，较大的细胞中积累更多。

结论

这些结果表明，猕猴桃在早期果实发育过程中 AsA 的生物合成是其在果实中积累的主要原因。我们还推测 GPP 是调节 AsA 生物合成的良好候选物，而 GDP-L-半乳糖-1-磷酸磷酸化酶则不是。

https://cdn.ncbi.nlm.nih.gov/pmc/blobs/6d1f/3000333/a875010a8f8d/pone.0014281.g002.jpg

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在猕猴桃早期果实发育过程中，抗坏血酸的生物合成是其积累的主要原因。

Ascorbate biosynthesis during early fruit development is the main reason for its accumulation in kiwi.

机构信息

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