Department of Genetic Engineering and Graduate School of Biotechnology, College of Life Sciences, Kyung Hee University, Yongin 17104, Republic of Korea.
Division of Life Sciences and Bio-Resource and Environmental Center, Incheon National University, Incheon 22012, Republic of Korea.
Metab Eng. 2019 Mar;52:178-189. doi: 10.1016/j.ymben.2018.11.012. Epub 2018 Nov 29.
Carotenoid pigments are valuable components of the human diet. A notable example is β-carotene, or provitamin A, which is converted into the derivatives astaxanthin and capsanthin, via the common intermediate zeaxanthin. To generate rice varieties producing diverse carotenoids beyond β-carotene, we specifically used a Capsicum β-carotene hydroxylase gene, B (CaBch) and a codon optimized version of the same gene, stB (stBch) to increase zeaxanthin synthesis. We also used a recombinant BAK gene (CaBch-2A-HpBkt), consisting of the CaBch sequence and a Haematococcus β-carotene ketolase gene (HpBkt) linked by a bicistronic 2 A sequence, as well as a codon optimized recombinant stBAK gene (stBch-2A-stBkt) to create astaxanthin synthesis. The four cassettes to seed-specifically express the B, stB, BAK and stBAK genes were individually combined with a PAC gene (CaPsy-2A-PaCrtI) cassette to previously impart β-carotene-enriched trait in rice endosperm. The single T-DNA vectors of B-PAC, stB-PAC, BAK-PAC and stBAK-PAC resulted in the accumulation of zeaxanthin and astaxanthin in the endosperm of the transgenic rice seeds. In addition, an extended version on the carotenoid pathway was introduced into rice to allow the production of capsanthin, by intercrossing a B-PAC rice line with a Ccs rice line, which harbors a Capsicum capsanthin-capsorubin synthase gene. Ultimately, we developed three functional rice varieties: B-PAC (0.8 μg/g zeaxanthin, deep yellow), stBAK-PAC (1.4 μg/g ketocarotenoids, including astaxanthin, pinkish red) and B-PAC x Ccs (0.4 μg/g of ketoxanthophylls, including capsanthin, orange-red) with the similar levels of total carotenoids to PAC rice, suggesting the capacity was dependent on β-carotene levels. Collectively, a combination of genetic engineering and conventional breeding is effective for multi-step metabolic engineering and biochemical pathway extension.
类胡萝卜素色素是人类饮食中的有价值成分。一个显著的例子是β-胡萝卜素,或维生素 A 前体,它通过共同的中间产物玉米黄质转化为虾青素和辣椒红素。为了生成产生除 β-胡萝卜素以外的各种类胡萝卜素的水稻品种,我们专门使用了辣椒β-胡萝卜素羟化酶基因 B(CaBch)和该基因的密码子优化版本 stB(stBch)来增加玉米黄质的合成。我们还使用了由 CaBch 序列和血球藻 β-胡萝卜素酮化酶基因(HpBkt)组成的重组 BAK 基因(CaBch-2A-HpBkt),通过双顺反子 2A 序列连接,以及密码子优化的重组 stBAK 基因(stBch-2A-stBkt)来合成虾青素。将四个盒式基因(B、stB、BAK 和 stBAK)分别与 PAC 基因(CaPsy-2A-PaCrtI)盒式基因组合,用于在水稻胚乳中赋予富含 β-胡萝卜素的特性。B-PAC、stB-PAC、BAK-PAC 和 stBAK-PAC 的单个 T-DNA 载体导致转基因水稻种子胚乳中玉米黄质和虾青素的积累。此外,通过与含有辣椒辣椒红素-辣椒玉红素合酶基因的 Ccs 水稻品系杂交,在水稻中引入了一个扩展的类胡萝卜素途径,以生产辣椒红素。最终,我们开发了三种功能性水稻品种:B-PAC(0.8μg/g 玉米黄质,深黄色)、stBAK-PAC(1.4μg/g 酮类胡萝卜素,包括虾青素,粉红色)和 B-PAC x Ccs(0.4μg/g 酮类叶黄素,包括辣椒红素,橙红色),其总类胡萝卜素水平与 PAC 水稻相似,表明这种能力取决于 β-胡萝卜素水平。总的来说,遗传工程和常规育种的结合对于多步骤代谢工程和生化途径的扩展是有效的。
