Generating colorful carrot germplasm through metabolic engineering of betalains pigments.

IF 7.6 Q1 GENETICS & HEREDITY
园艺研究(英文) Pub Date : 2023-02-14 eCollection Date: 2023-04-01 DOI:10.1093/hr/uhad024
Yuan-Jie Deng, Ao-Qi Duan, Hui Liu, Ya-Hui Wang, Rong-Rong Zhang, Zhi-Sheng Xu, Ai-Sheng Xiong
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引用次数: 0

Abstract

Betalains are tyrosine-derived plant pigments exclusively found in the Caryophyllales order and some higher fungi and generally classified into two groups: red-violet betacyanins and yellow-orange betaxanthins. Betalains attract great scientific and economic interest because of their relatively simple biosynthesis pathway, attractive colors and health-promoting properties. Co-expressing two core genes BvCYP76AD1 and BvDODA1 with or without a glycosyltransferase gene MjcDOPA5GT allowed the engineering of carrot (an important taproot vegetable) to produce a palette of unique colors. The highest total betalains content, 943.2 μg·g-1 DW, was obtained in carrot taproot transformed with p35S:RUBY which produces all of the necessary enzymes for betalains synthesis. Root-specific production of betalains slightly relieved tyrosine consumption revealing the possible bottleneck in betalains production. Furthermore, a unique volcano-like phenotype in carrot taproot cross-section was created by vascular cambium-specific production of betalains. The betalains-fortified carrot in this study is thus anticipated to be used as functional vegetable and colorful carrot germplasm in breeding to promote health.

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通过β赖氨酸色素的代谢工程产生丰富多彩的胡萝卜种质。
Betalains是酪氨酸衍生的植物色素,仅存在于石竹目和一些高等真菌中,通常分为两组:红紫色β花青素和黄橙色β黄素。Betalains由于其相对简单的生物合成途径、诱人的颜色和促进健康的特性而引起了人们极大的科学和经济兴趣。将两个核心基因BvCYP76AD1和BvDODA1与糖基转移酶基因MjcDOPA5GT共表达或不与之共表达,使胡萝卜(一种重要的主根蔬菜)的工程化能够产生独特的颜色。用p35S:RUBY转化的胡萝卜主根中β赖氨酸总含量最高,为943.2μg·g-1 DW,它能产生合成β赖氨素所需的所有酶。β赖氨酸的根特异性生产略微缓解了酪氨酸消耗,揭示了β赖氨素生产的可能瓶颈。此外,胡萝卜主根横截面中独特的火山状表型是通过维管形成层特异性产生β赖氨酸而产生的。因此,本研究中的β赖氨酸强化胡萝卜有望作为功能蔬菜和丰富多彩的胡萝卜种质用于育种,以促进健康。
本文章由计算机程序翻译,如有差异,请以英文原文为准。
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CiteScore
12.90
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