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过表达PDH45的转基因烟草和水稻植株通过减少钠积累来提供耐盐胁迫能力。

PDH45 overexpressing transgenic tobacco and rice plants provide salinity stress tolerance via less sodium accumulation.

作者信息

Nath Manoj, Garg Bharti, Sahoo Ranjan Kumar, Tuteja Narendra

机构信息

a Plant Biology; Plant Molecular Biology Group; International Center for Genetic Engineering and Biotechnology ; Aruna Asaf Ali Marg; New Delhi , India.

出版信息

Plant Signal Behav. 2015;10(4):e992289. doi: 10.4161/15592324.2014.992289.

DOI:10.4161/15592324.2014.992289
PMID:25830863
原文链接:https://pmc.ncbi.nlm.nih.gov/articles/PMC4623307/
Abstract

Salinity stress negatively affects the crop productivity worldwide, including that of rice. Coping with these losses is a major concern for all countries. The pea DNA helicase, PDH45 is a unique member of helicase family involved in the salinity stress tolerance. However, the exact mechanism of the PDH45 in salinity stress tolerance is yet to be established. Therefore, the present study was conducted to investigate the mechanism of PDH45-mediated salinity stress tolerance in transgenic tobacco and rice lines along with wild type (WT) plants using CoroNa Green dye based sodium localization in root and shoot sections. The results showed that under salinity stress root and shoot of PDH45 overexpressing transgenic tobacco and rice accumulated less sodium (Na(+)) as compared to their respective WT. The present study also reports salinity tolerant (FL478) and salinity susceptible (Pusa-44) varieties of rice accumulated lowest and highest Na(+) level, respectively. All the varieties and transgenic lines of rice accumulate differential Na(+) ions in root and shoot. However, roots accumulate high Na(+) as compared to the shoots in both tobacco and rice transgenic lines suggesting that the Na(+) transport in shoot is somehow inhibited. It is proposed that the PDH45 is probably involved in the deposition of apoplastic hydrophobic barriers and consequently inhibit Na(+) transport to shoot and therefore confers salinity stress tolerance to PDH45 overexpressing transgenic lines. This study concludes that tobacco (dicot) and rice (monocot) transgenic plants probably share common salinity tolerance mechanism mediated by PDH45 gene.

摘要

盐分胁迫对全球作物产量产生负面影响,包括水稻产量。应对这些损失是所有国家的主要关切。豌豆DNA解旋酶PDH45是解旋酶家族中参与盐分胁迫耐受性的独特成员。然而,PDH45在盐分胁迫耐受性中的确切机制尚未明确。因此,本研究利用基于CoroNa Green染料的钠定位技术,在根和茎段中研究了转基因烟草和水稻品系以及野生型(WT)植株中PDH45介导的盐分胁迫耐受性机制。结果表明,在盐分胁迫下,过表达PDH45的转基因烟草和水稻的根和茎积累的钠(Na(+))比各自的野生型少。本研究还报告称,耐盐水稻品种(FL478)和盐敏感水稻品种(Pusa - 44)分别积累了最低和最高水平的Na(+)。水稻的所有品种和转基因系在根和茎中积累的Na(+)离子存在差异。然而,在烟草和水稻转基因系中,根积累的Na(+)比茎多,这表明茎中的Na(+)运输受到某种程度的抑制。有人提出,PDH45可能参与质外体疏水屏障的沉积,从而抑制Na(+)向茎的运输,因此赋予过表达PDH45的转基因系盐分胁迫耐受性。本研究得出结论,烟草(双子叶植物)和水稻(单子叶植物)转基因植株可能共享由PDH45基因介导的共同盐分耐受机制。

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