微量营养素
番茄红素
生物
生物强化
类胡萝卜素
叶黄素
生物技术
维生素A缺乏
维生素
基因
B族维生素
抗坏血酸
维生素E
食品科学
突变体
作物
基因组
基因组编辑
多路复用
视黄醇
遗传学
营养不良
生物化学
必需营养素
代谢途径
细胞生长
植物
维生素C
β-胡萝卜素
作者
Yechun Hong,Zongjun Yu,Wenbo Zhu,Jialei Sun,Zeyao Zhu,Zhen Wang,Min-Jie Cao,Zhaobo Lang,Yu‐Xuan Lyu,Pengpeng Liu,Jian-Kang Zhu
标识
DOI:10.1073/pnas.2603937123
摘要
Dietary deficiencies in essential micronutrients and other phytonutrients represent a global health and economic burden, contributing to “hidden hunger” and chronic diseases. While genome editing has been employed to improve individual nutritional traits in crops, multibiofortification through simultaneous modification of multiple distinct metabolic pathways is more challenging. Here, we designed a multiplex CRISPR-Cas strategy to edit five key genes in tomato: Sl7-DR2 , SlGAD3 , SlSGR1 , SlGGP1 , and SlGGP2 . This approach successfully generated quintuple mutant ( 5m ) tomato lines simultaneously biofortified with seven health-promoting compounds: vitamin D 3 (from 0 to 0.70 μg/g dry weight), vitamin C (up to 2.53-fold), provitamin A/β-carotene (up to 3.86-fold), α-carotene (up to 2.47-fold), lutein (up to 3.26-fold), lycopene (up to 7.07-fold), and γ-aminobutyric acid (GABA, up to 5.26-fold). Notably, these multibiofortified tomatoes exhibited no significant trade-offs in plant growth or fruit quality. Extracts from 5m tomatoes showed enhanced suppression of colorectal cancer cell proliferation in vitro. This antiproliferative effect was validated in vivo, where dietary supplementation with 5m tomato powder significantly inhibited tumor growth in a mouse xenograft model. Our work demonstrates an effective strategy for developing a next generation of “functional foods” through multibiofortification, creating a single, nutrient-dense crop that combats both micronutrient malnutrition and chronic diseases.
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