Nuclear Agriculture and Biotechnology Division, Bhabha Atomic Research Centre, Mumbai 400085, India.
Ann Bot. 2010 Nov;106(5):663-74. doi: 10.1093/aob/mcq163. Epub 2010 Aug 24.
Abiotic stresses including salinity are the major constraints to crop production. In this regard, the use of thiourea (TU) in imparting salinity-stress tolerance to Indian mustard (Brassica juncea) has been demonstrated earlier. To gain an insight into the mechanism of TU action, various molecular and biochemical studies were conducted.
Microarray analysis was performed in seeds subjected to distilled water (control), 1 m NaCl, 1 m NaCl + 6·5 mm TU and 6·5 mm TU alone for 1 h. Real-time PCR validation of selected genes and biochemical studies were conducted under similar treatments at 1 h and 6 h.
The microarray analysis revealed a differential expression profile of 33 genes in NaCl- and NaCl + TU-treated seeds, most of which are established markers of stress tolerance. The temporal regulation of eight selected genes by real-time PCR indicated their early and co-ordinated induction at 1 h in NaCl + TU only. Besides, NaCl + TU-treated seeds also maintained a higher level of abscisic acid, reduced to oxidized glutathione (GSH : GSSG) ratio and activities of catalase, phenylalanine ammonia lyase and glutathione-S-transferases, as compared with that of NaCl treatment. The addition of LaCl(3) (a specific calcium-channel blocker) restricted the responses of TU both at molecular and biochemical level suggesting the possible involvement of a cytosolic calcium burst in the TU-mediated response. The TU-alone treatment was comparable to that of the control; however, it reduced the expression of some transcription factors and heat-shock proteins presumably due to the stabilization of the corresponding proteins.
The TU treatment co-ordinately regulates different signalling and effector mechanisms at an early stage to alleviate stress even under a high degree of salinity. This also indicates the potential of TU to be used as an effective bioregulator to impart salinity tolerance under field conditions.
非生物胁迫,包括盐度,是作物生产的主要限制因素。在这方面,先前已经证明硫脲(TU)可用于赋予芥菜(Brassica juncea)耐盐胁迫。为了深入了解 TU 的作用机制,进行了各种分子和生化研究。
在种子中进行微阵列分析,这些种子分别用蒸馏水(对照)、1 m NaCl、1 m NaCl + 6.5 mm TU 和 6.5 mm TU 单独处理 1 小时。在相同处理下,在 1 小时和 6 小时进行了实时 PCR 验证选定基因和生化研究。
微阵列分析显示,在 NaCl 和 NaCl + TU 处理的种子中,有 33 个基因的表达谱存在差异,其中大多数是应激耐受的已有标记。通过实时 PCR 对 8 个选定基因的时间调节表明,它们仅在 NaCl + TU 中在 1 小时时早期且协调地诱导。此外,与 NaCl 处理相比,NaCl + TU 处理的种子还保持了较高水平的脱落酸、还原型谷胱甘肽与氧化型谷胱甘肽(GSH:GSSG)的比值以及过氧化氢酶、苯丙氨酸解氨酶和谷胱甘肽-S-转移酶的活性。添加 LaCl3(一种特定的钙通道阻滞剂)限制了 TU 在分子和生化水平上的反应,这表明 TU 介导的反应可能涉及细胞质钙爆发。TU 单独处理与对照相当,但它降低了一些转录因子和热休克蛋白的表达,大概是由于相应蛋白的稳定性。
TU 处理在早期协调调节不同的信号和效应机制,以减轻胁迫,即使在高盐度下也是如此。这也表明 TU 具有作为有效生物调节剂的潜力,可在田间条件下赋予耐盐性。