Next-generation marker-free transplastomic plants: engineering the chloroplast genome without integration of marker genes in Solanum tuberosum (potato).

IF 5.3 2区 生物学 Q1 PLANT SCIENCES
Alessandro Occhialini, Andrew C Reed, Stacee A Harbison, Megan J Sichterman, Aaron Baumann, Alexander C Pfotenhauer, Li Li, Gabriella King, Aaron G Vincent, Ashley D Wise-Mitchell, C Neal Stewart, Scott C Lenaghan
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Abstract

Key message: This study describes an optimized plastid genetic engineering platform to produce full marker-free transplastomic plants with transgene integrated at homoplasmy in one step in tissue culture. Plastid engineering is attractive for both biotechnology and crop improvement due to natural bio-confinement from maternal inheritance, the absence of transgene positional effects and silencing, the ability to express transgenes in operons, and unparalleled production of heterologous proteins. While plastid engineering has had numerous successes in the production of high-value compounds, no transplastomic plants have been approved for use in agriculture. In order for transplastomic plants to be used in agriculture, the removal of antibiotic selection genes is required. In this work, we developed an optimized strategy to generate homoplasmic marker-free lines of potato (Solanum tuberosum) in a single transformation event. To achieve marker-free transplastomic lines, vectors were redesigned to enable integration of the transgene cassette into the plastid genome, while maintaining the selection cassette on the vector backbone. After an initial round of tissue culture with selection, the selective pressure was removed, leading to the elimination of the vector backbone, while retaining the integrated transgene cassette at homoplasmy. Marker-free transplastomic lines produced using this strategy had a normal phenotype, and transgene integration was stable across generations. The new vectors developed in this work for the generation of marker-free transplastomics will represent a valuable alternative platform for routine plastid genetic engineering in higher plants. It is also anticipated that this approach will contribute to speed the path to commercialization of these novel transplastomic plant varieties.

下一代无标记转殖体植物:在不整合马铃薯(Solanum tuberosum)标记基因的情况下进行叶绿体基因组工程。
关键信息:本研究描述了一种优化的质粒基因工程平台,它能在组织培养中一步生产出同源整合转基因的无标记转质粒植株。质体工程对生物技术和作物改良都很有吸引力,因为它具有母系遗传的天然生物一致性,没有转基因的位置效应和沉默,能在操作子中表达转基因,并能生产出无与伦比的异源蛋白。虽然质体工程在生产高价值化合物方面取得了许多成功,但还没有转质体植物被批准用于农业。要使转质粒植物用于农业,就必须去除抗生素选择基因。在这项工作中,我们开发了一种优化策略,在一次转化事件中产生无同质标记的马铃薯(Solanum tuberosum)品系。为了获得无标记转质粒系,我们对载体进行了重新设计,以便将转基因盒整合到质粒基因组中,同时将选择盒保留在载体骨架上。经过第一轮组织培养和选择后,选择压力被去除,从而消除了载体骨架,同时保留了同源的整合转基因盒。用这种方法培育出的无标记转殖系具有正常的表型,而且转基因整合在各代之间是稳定的。这项工作中开发的用于产生无标记转质粒组的新载体将为高等植物的常规质粒遗传工程提供一个有价值的替代平台。预计这种方法还将有助于加快这些新型转殖体植物品种的商业化进程。
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来源期刊
Plant Cell Reports
Plant Cell Reports 生物-植物科学
CiteScore
10.80
自引率
1.60%
发文量
135
审稿时长
3.2 months
期刊介绍: Plant Cell Reports publishes original, peer-reviewed articles on new advances in all aspects of plant cell science, plant genetics and molecular biology. Papers selected for publication contribute significant new advances to clearly identified technological problems and/or biological questions. The articles will prove relevant beyond the narrow topic of interest to a readership with broad scientific background. The coverage includes such topics as: - genomics and genetics - metabolism - cell biology - abiotic and biotic stress - phytopathology - gene transfer and expression - molecular pharming - systems biology - nanobiotechnology - genome editing - phenomics and synthetic biology The journal also publishes opinion papers, review and focus articles on the latest developments and new advances in research and technology in plant molecular biology and biotechnology.
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