Industrial Scale Gene Editing in Brassica napus

Q4 Agricultural and Biological Sciences

International Journal of Plant Biology Pub Date : 2023-11-19 DOI:10.3390/ijpb14040077

Andrew Walker, J. Narváez-Vásquez, Jerry J. Mozoruk, Zhixia Niu, Peter Luginbühl, Steve Sanders, Christian Schöpke, Noel J. Sauer, Jim Radtke, G. Gocal, Peter Beetham

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Abstract

In plants, an increasing number of traits and new characteristics are being developed using gene editing. Simple traits represented by a single gene can be managed through backcross breeding, but this is typically not the case for more complex traits which may result from the function of a large number of genes. Here, we demonstrate two case studies of improving oleic oil content and developing pod shatter reduction in Brassica napus by using gene editing tools on an industrial scale. There are four BnaFAD2 genes involved in oleic oil content and eight BnaSHP genes involved in pod shatter tolerance. In order to develop these two traits, we delivered nuclease ribonucleoproteins with Gene Repair OligoNucleotides (GRONs) into protoplasts, with subsequent regeneration into plants on an industrial scale, which encompassed robust tissue culture protocols, efficient gene editing, robotics sampling, and molecular screening, vigorous plant regeneration, growth, and phenotyping. We can produce precise loss-of-function-edited plants with two improved agronomically important complex traits, high oleic oil or pod shatter reduction, in elite canola varieties within 1–3 years, depending on the trait complexity. In the edited plants carrying loss of function of four BnaFAD2 genes, the seed fatty acid oleic acid content reached 89% compared to 61% in the non-edited wildtype control. The plants carrying eight edited BnaSHP genes achieved 51% pod shatter reduction in multiple year field testing in the target environment compared to the wildtype control.

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甘蓝型油菜的工业规模基因编辑

在植物中，越来越多的性状和新特性正在利用基因编辑技术开发出来。单个基因所代表的简单性状可以通过回交育种来管理，但对于由大量基因的功能所产生的更复杂的性状来说，情况通常并非如此。在这里，我们展示了在工业规模上利用基因编辑工具提高油酸油含量和开发减少豆荚破碎的甘蓝型油菜的两个案例研究。有四个 BnaFAD2 基因涉及油酸油含量，八个 BnaSHP 基因涉及豆荚抗破碎性。为了开发这两个性状，我们将核酸酶核糖核蛋白与基因修复寡核苷酸（GRONs）一起导入原生质体，随后以工业化规模将其再生为植株，其中包括稳健的组织培养方案、高效的基因编辑、机器人采样和分子筛选、旺盛的植株再生、生长和表型分析。根据性状的复杂程度，我们可以在 1-3 年内培育出精确的功能缺失编辑植株，这些植株具有两个改进的、具有重要农艺意义的复合性状，即高油酸油或减少豆荚破碎。在携带 4 个 BnaFAD2 基因功能缺失的编辑植株中，种子脂肪酸油酸含量达到 89%，而未编辑的野生型对照为 61%。在目标环境下进行的多年田间试验中，携带 8 个经过编辑的 BnaSHP 基因的植株与野生型对照相比，豆荚破碎率降低了 51%。

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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来源期刊

International Journal of Plant Biology Agricultural and Biological Sciences-Plant Science

CiteScore

2.00

自引率

0.00%

发文量

审稿时长

10 weeks

期刊介绍： The International Journal of Plant Biology is an Open Access, online-only, peer-reviewed journal that considers scientific papers in all different subdisciplines of plant biology, such as physiology, molecular biology, cell biology, development, genetics, systematics, ecology, evolution, ecophysiology, plant-microbe interactions, mycology and phytopathology.