Yang Xiaoyu, Li Jianhui, Chen Lei, Louzada Eliezer S, He Junxian, Yu Weichang
School of Life Sciences, State Key Laboratory of Agrobiotechnology, The Chinese University of Hong Kong, Sha Tin, New Territories, Hong Kong.
Plant Cell Rep. 2015 Jun;34(6):929-41. doi: 10.1007/s00299-015-1755-3. Epub 2015 Feb 3.
Suspension cell cultures of rice minichromosomes were established. The minichromosomes in suspension cultured cells were mitotically stable and had active gene expression, thus have the potential to be used as gene expression vectors to produce valuable bioactive products. The plant artificial chromosome (PAC) is a novel vector for plant genetic engineering to produce genetically modified crops with multiple transgenes, or to produce valuable bioactive products through the expression of multiple genes or biochemical pathways as a bioreactor. PAC is mainly constructed by engineered minichromosomes through telomere-mediated chromosome truncations. We have constructed rice minichromosomes in a previous study. Thus, the understanding of rice minichromosome inheritance under different culture conditions has potential importance for their utility in future studies and applications. In this study, we performed suspension cultures of three rice minichromosome-containing cell lines, 1004-111, 1008-100 and 1004-011. Two cell lines, 1004-111 and 1008-100, showed typical S growth pattern consisting of a lag phase, an active growing exponential phase and a stationary phase, whereas cell line 1004-011 grew very slowly and eventually died. Both 1004-111 and 1008-100 minichromosomes were stably transmitted in cell suspension cultures without any abnormality. Foreign gene expression was verified from 1004-111 and 1008-100 minichromosomes in suspension cultures. The stable mitotic inheritance of minichromosomes and gene expression from them indicated that rice minichromosomes could be maintained and propagated in cell suspension cultures. This study tested key parameters for suspension cultures of rice cell lines with minichromosomes, and proved in concept the potential for industrial use of PAC vectors as bioreactors.
建立了水稻小染色体的悬浮细胞培养体系。悬浮培养细胞中的小染色体在有丝分裂过程中稳定且具有活跃的基因表达,因此有潜力用作基因表达载体来生产有价值的生物活性产物。植物人工染色体(PAC)是一种用于植物基因工程的新型载体,可用于培育携带多个转基因的转基因作物,或作为生物反应器通过多个基因或生化途径的表达来生产有价值的生物活性产物。PAC主要通过端粒介导的染色体截短由工程化小染色体构建而成。我们在之前的研究中构建了水稻小染色体。因此,了解不同培养条件下水稻小染色体的遗传情况对于其在未来研究和应用中的实用性具有潜在重要意义。在本研究中,我们对三个含有水稻小染色体的细胞系1004 - 111、1008 - 100和1004 - 011进行了悬浮培养。两个细胞系1004 - 111和1008 - 100呈现出典型的S型生长模式,包括延迟期、活跃生长的指数期和稳定期,而细胞系1004 - 011生长非常缓慢,最终死亡。1004 - 111和1008 - 100的小染色体在细胞悬浮培养中均稳定传递,无任何异常。在悬浮培养中验证了1004 - 111和1008 - 100小染色体的外源基因表达。小染色体的稳定有丝分裂遗传及其基因表达表明水稻小染色体可以在细胞悬浮培养中维持和增殖。本研究测试了含小染色体水稻细胞系悬浮培养的关键参数,并从概念上证明了PAC载体作为生物反应器用于工业生产的潜力。
