Maize bioengineering with c-repeat binding factor 1 (CBF1) as a technique for desiccation toleration

Eric K Kuria, J. Machuka, S. Runo
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Abstract

Abstract. Kuria EK, Machuka J, Runo S. 2019. Maize bioengineering with c-repeat binding factor 1 (CBF1) as a technique for desiccation toleration. Trop Drylands 3: 1-10. Africa is a desiccation inclined continent leading to riskful cultivation particularly to small-scale cultivators who rely on rain-fed agriculture. Maize is the most widely cultivated main crop in Africa with more than 300 million people relying on it as their principal dietdiet fount. Desiccation causes crop fiasco, famine and poverty and this is being aggravated by climate change. There is therefore an obligation to flourish desiccation tolerablish maize. Traditional propagation techniques have been implementedcarried out in the establishment of desiccation tolerablish plants but are restricted by their requirement for labour, time and space, suggesting a limited genetic diversity within genotypes and transition of undesired traits along with the wanted ones. These restrictions are handled by utilizing these techniques along with bioengineering. Desiccation triggers a range of physiological and biochemical reactions in plants at cellular and molecular levels. These reactions include initiation of genes with several usefulness. Plant alteration for expanded desiccation toleration is generally based on the administration of either transcription and/or signaling factors or genes that directly secure plant cells contra water shortage. C-repeat binding factor (CBF) is a transcriptional factor that interacts with the desiccation responsive element (DRE), a cis-acting promoter element that governs gene expression in reaction to desiccation, brine and freezing stress. Over expression of these transcription factors, escalates stress toleration to freezing, desiccation and high brininess. In this study, three maize inbred lines and one hybrid were altered with CBF1 gene and appointed with mannose utilizing the Phosphomannose isomerase (PMI) gene. Genetic alteration was conducted through Agrobacterium tumefaciens and PCR was utilized to ascertain altered plants. Alteration frequency, alteration effectiveness and regeneration effectiveness were equated among the distinct genotypes altered. There were no remarkable dissimilarities in alteration frequency among the four maize genotypes. CML216 had the highest alteration effectiveness and regeneration effectiveness followed by A188. No alleged transgenic plants were regenerated from TL27 and A188×TL18 under the circumstances implemented on acount of their low regenerability. Further molecular analysis and desiccation stress tentatives on the expanded transgenic maize are significant prior to commercial release. Availability of desiccation tolerablish maize would bear a considerable positive collision contra famine particularly in Africa.
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用c-重复结合因子1 (CBF1)作为玉米耐干燥技术的生物工程研究
摘要张建军,张建军,张建军。2019。用c-重复结合因子1 (CBF1)作为玉米耐干燥技术的生物工程研究。热带旱地3:1 -10。非洲是一个倾向于干旱的大陆,这导致了高风险的种植,特别是对依赖雨养农业的小规模种植者。玉米是非洲种植最广泛的主要作物,有3亿多人依靠玉米作为主要的饮食来源。干旱导致作物歉收、饥荒和贫困,而气候变化又加剧了这种情况。因此,我们有义务培育耐干燥的玉米。传统的繁殖技术已被用于建立耐干燥植物,但受其对劳动力、时间和空间的要求的限制,表明基因型内的遗传多样性有限,不需要的性状与需要的性状一起过渡。这些限制是通过利用这些技术以及生物工程来解决的。干燥在细胞和分子水平上触发植物的一系列生理和生化反应。这些反应包括一些有用基因的启动。植物对扩大干燥耐受性的改变通常基于转录和/或信号因子或基因的管理,这些因子或基因直接确保植物细胞对抗缺水。C-repeat binding factor (CBF)是一种与干燥反应元件(DRE)相互作用的转录因子,DRE是一种顺式启动子元件,控制基因在干燥、盐水和冷冻胁迫下的表达。这些转录因子的过度表达,增加了对冰冻、干燥和高盐度的应激耐受性。本研究利用磷酸甘露糖异构酶(PMI)基因对3个玉米自交系和1个杂交种进行CBF1基因改造,并配以甘露糖。通过农杆菌进行遗传改变,并利用PCR确定改变的植株。不同基因型的变异频率、变异有效性和再生有效性相等。4个玉米基因型的变异频率无显著差异。CML216的改变效能和再生效能最高,A188次之。由于TL27和A188×TL18的可再生性较低,在这种情况下没有所谓的转基因植株再生。进一步的分子分析和干燥胁迫试验对扩大转基因玉米在商业释放前是重要的。耐干燥玉米的供应将对对抗饥荒产生相当大的积极影响,特别是在非洲。
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