高尔基糖脂生物碱转运蛋白对于防止番茄变苦是不可或缺的。

The GORKY glycoalkaloid transporter is indispensable for preventing tomato bitterness.

机构信息

Department of Plant and Environmental Sciences, Weizmann Institute of Science, Rehovot, Israel.

Robert H. Smith Institute of Plant Sciences and Genetics in Agriculture, Hebrew University of Jerusalem, Rehovot, Israel.

出版信息

Nat Plants. 2021 Apr;7(4):468-480. doi: 10.1038/s41477-021-00865-6. Epub 2021 Mar 11.

DOI:10.1038/s41477-021-00865-6

PMID:33707737

Abstract

Fruit taste is determined by sugars, acids and in some species, bitter chemicals. Attraction of seed-dispersing organisms in nature and breeding for consumer preferences requires reduced fruit bitterness. A key metabolic shift during ripening prevents tomato fruit bitterness by eliminating α-tomatine, a renowned defence-associated Solanum alkaloid. Here, we combined fine mapping with information from 150 resequenced genomes and genotyping a 650-tomato core collection to identify nine bitter-tasting accessions including the 'high tomatine' Peruvian landraces reported in the literature. These 'bitter' accessions contain a deletion in GORKY, a nitrate/peptide family transporter mediating α-tomatine subcellular localization during fruit ripening. GORKY exports α-tomatine and its derivatives from the vacuole to the cytosol and this facilitates the conversion of the entire α-tomatine pool to non-bitter forms, rendering the fruit palatable. Hence, GORKY activity was a notable innovation in the process of tomato fruit domestication and breeding.

摘要

水果的味道取决于糖、酸，在某些物种中，还取决于苦味化学物质。在自然界中，吸引种子传播者和培育消费者喜爱的品种都需要降低果实的苦味。在成熟过程中，一个关键的代谢转变可以通过消除α-茄碱来防止番茄果实变苦，α-茄碱是一种著名的与防御相关的茄属生物碱。在这里，我们结合精细图谱和来自 150 个重测序基因组的信息，对 650 个番茄核心品种进行了基因分型，鉴定出了 9 个口感苦涩的品种，包括文献中报道的秘鲁地方品种“高茄碱”。这些“苦”品种中包含一个 GORKY 基因的缺失，该基因是一种硝酸盐/肽家族转运蛋白，在果实成熟过程中调节α-茄碱的亚细胞定位。GORKY 将α-茄碱及其衍生物从液泡中运出到细胞质中，这有助于将整个α-茄碱池转化为非苦味形式，使果实变得可口。因此，GORKY 的活性是番茄果实驯化和培育过程中的一个显著创新。

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高尔基糖脂生物碱转运蛋白对于防止番茄变苦是不可或缺的。

The GORKY glycoalkaloid transporter is indispensable for preventing tomato bitterness.

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