Comparative Study of Immunological Properties on Glutamine Synthetase Isozymes in Rice Plants

In rice (Oryza sativa L.) roots two glutamine synthetase (GS) isozymes, GSra and GSrb, were identified recently in the author's experiments, but the homology of both GSra and GSrb as well as their localization in the rice roots are unclear. In the present study, the purified GSra and GSrb from rice roots were used to immunize rabbits to obtain the respective antibodies. The immunodiffusion and immunoblotting experiments showed that the antibody against GSra or GSrb was specific for GS and its isozymes. The immunoprecipitation test indicated that the antibody of GSra or GSrb not only recognized its respective antigen, but also well recognized each other's antigen. GSra or GSrb antibody recognized also better cytosolic GS1 of rice leaves, but the recognization for chloroplast GS2 from rice or spinach (Spinacia oleracea Mill.) leaves was weaker. Our results indicate that GSra and GSrb from rice roots are quite similar in antigenicity and are extremely similar proteins and that both GSra and GSrb may also be a form of cytosolic GS just as the cytosolic GS1 of rice leaves.

Effect of Exogenous Ammonium on GlutamineSynthetase, Glutamate Synthase, and Glutamate Dehydrogenase in the Root of Rice Seedling

Root biomass of rice seedlings was increased at lower concentration of exogenous NH 4 + , but it was decreased at higher concentration of exogenous NH 4 + . The level of free NH 4 + in the roots was accumulated gradually with the increase of NH 4 + concentration in the nutrient solution. The content of the soluble proteins was essentially constant at higher NH 4 + . The activities of glutamine synthetase (GS), NADH-dependent glutamate synthase (NADH-GOGAT), and NADH-dependent glutamate dehydrogenase (NADH-GDH) were risen with exogenous NH 4 + concentration at the lower NH 4 + concentration range. But the activities of GS and NADH-GOGAT were declined, and the level of NADH-GDH activity was kept constant under higher NH 4 + concentration. The GS/GDH ratio suggested that NH 4 + was assimilated by GS-GOGAT cycle under lower NH 4 + concentration, but NADH-GDH was more important for NH 4 + assimilation and detoxifying NH 4 + to the tissue cells at the higher NH 4 + level. According to the growth and the activity changes of these ammonium-assimilating enzymes of rice seedling roots, 10. 0 μg/mL NH 4 + -N in nutrient solution was more suitable to the rice growth.

低氮条件下超级杂交稻苗期根系特征的变化及与其高氮素积累的关系

作物根系在氮素吸收与分配中起着重要作用。本研究选用2个根系特征具有差异的水稻品种黄华占(Huanghuazhan, HHZ,常规稻)和扬两优6号(Yangliangyou 6, YLY6,超级杂交稻),在水培条件和2个氮素浓度(低氮,lownitrogen,LN;高氮,highnitrogen,HN)处理下,研究根系形态和解剖结构特征的变化及其与LN下氮素积累的关系。与HN处理相比, LN处理下HHZ总氮积累量显著下降了19.7%, YLY6没有显著下降;YLY6根干重、总根长、根表面积、根尖数分别显著增加了41.3%、57.1%、74.9%和20.6%,而HHZ没有显著变化。与HN处理相比, LN处理下YLY6的根直径和根皮层面积分别显著增加了12.4%和24.2%,而HHZ根直径和根皮层面积、中柱直径分别显著降低了12.0%、21.9%和11.4%。LN处理下,YLY6根系铵转运蛋白基因AMT2;1、AMT2;3、AMT3;1、AMT3;2的表达量分别显著增加了195.6%、29.3%、314.9%和388.9%,谷氨酰胺合成酶基因GS1;1表达量增加了158.2%, HHZ中这5个基因的表达量没有显著变化。LN下总氮积累量与根系性状显著正相关(根厚壁组织厚度除外),与部分铵转运和同化相关基因的表达量显著正相关。这些结果表明超级杂交稻YLY6幼苗在LN下根系特征变化有利于增加氮积累。选育根系对减氮表现出有利变化的水稻品种应是绿色水稻生产的一个重要途径。

温度对水稻谷氨酰胺合成酶和NADH-谷氨酸合酶表达的影响

测定了不同温度（32℃和23℃）培养下水稻幼苗根和叶的谷氨酰胺合成酶（GS）同工酶以及依赖于NADH的谷氨酸合酶（NADH-GOGAT）的活性变化.结果表明,温度对水稻根和叶的GS活性具有相反的作用.23℃下生长的水稻根的GS活性明显高于32℃下生长的活性,而23℃下生长的叶的GS活性显著低于生长在32℃下的叶的活性.Native-PAGE和活性染色以及蛋白质印迹表明,根和叶的GS活性变化主要是由于GSrb和GS2活性及其相应蛋白质水平变化所致.23℃下生长的水稻根的NADH-GOGAT活性显著高于32℃下生长的活性,而叶的活性则基本保持恒定.

NaCl对水稻谷氨酰胺合成酶活性及同工酶的影响

在营养液中 Ｎａ Ｃｌ的胁迫下，水稻根和叶的谷氨酰胺合成酶（ Ｇ Ｓ）的活性降低，但叶的 Ｇ Ｓ活性对 Ｎａ Ｃｌ浓度的敏感性大于根根和叶中的 Ｇ Ｓ活性变化与根和叶的平均质量和可溶性蛋白水平的变化是一致的 Ｎａｔｉｖｅ Ｐ Ａ Ｇ Ｅ活性染色以及 Ｉｍ ｍ ｕｎｏｂｌｏｔｔｉｎｇ 检测表明，根和叶的 Ｇ Ｓ活性的降低主要是由于 Ｇ Ｓｒｂ 和 Ｇ

不同氮效率水稻的生长特性

以氮高效水稻4007和氮低效水稻Elio为材料,在水培条件下设置高(5.72 mmol.L-1)、低(1.43 mmol.L-1)2个供氮处理,研究2个水稻品种的籽粒产量及不同生育期的干物重、吸氮量和根系形态以及功能叶片硝酸还原酶活性(NRA)、功能叶片和根系谷氨酰胺合成酶活性(GSA)的差异。结果表明:2个处理4007的籽粒产量均高于Elio。在分蘖期,Elio的地上、下部生物量及氮积累量均大于4007,至拔节期两者差距减小,齐穗期Elio的地上部氮积累量只有4007的86.4%,且差异显著。高氮条件下,在分蘖期4007的根系特征参数显著低于Elio,而在拔节期两品种却没有显著差异,在齐穗期4007的总根长、根表面积和根尖数已经显著高于Elio。高氮处理的叶片NRA、叶片和根系GSA均显著高于低氮处理;在拔节期和齐穗期,Elio叶片NRA极显著下降,而4007叶片则保持NRA的稳定;在齐穗期4007的GSA显著高于Elio。

水稻种子萌发期间谷氨酰胺合成酶和NADH-谷氨酸合酶的变化

测定了水稻种子不同萌发时期胚乳、胚芽鞘和幼根的谷氨酰胺合成酶 (GS)和依赖于NADH的谷氨酸合酶 (NADH GOGAT)活性变化。胚乳和胚芽鞘的GS活性在萌发过程中升高 ,幼根的GS活性则有所降低。NADH GOGAT的活性变化趋势与GS相同。Native PAGE活性染色表明 ,在萌发阶段的水稻种子胚乳和幼根里 ,始终只观察到一种GS活性带。但是 ,在水稻种子萌发 3d后 ,在胚芽鞘中除继续检测到GS1的活性外 ,还可以观察到GS2的活性。蛋白质印迹显示 ,水稻种子胚乳中的GS(GSe)与GS1和GSra一样是一种胞质型GS。实验结果提示 ,这些不同组织中的GS与NADH

光对水稻非光合组织谷氨酰胺合成酶同工酶表达的影响(英文)

以前的研究表明 ,高等植物叶绿体谷氨酰胺合成酶 (GS2 )受光调节 ,但叶片胞液 GS(GS1 )和非光合作用组织中的 GS很少受光的影响。在本报道中 ,笔者运用 GS活性染色和Western blotting研究了光对非光合作用组织水稻根 GS同工酶表达的影响。在阳光的直接照射下以及在室内不同光照强度下 ,可以很清楚地观察到 GSra和 GSrb的活性带及其蛋白质带。但是 ,当用尼龙网挡住阳光的直接照射时 ,GSrb的活性带和蛋白质带消失 ;当阳光被尼龙网遮挡住后 ,其光强度仍然比室内光照强度大得多 ,表明光照强度不是影响 GSrb表达的主要因素。当分析生长在暗处以及生长在光 /暗转换下的水稻幼苗根 GS同工酶变化时 ,仍然可以观察到 GSrb的存在。在所有实验条件下 ,GSra都未发生明显变化。这些结果提示 。

水稻根谷氨酰胺合成酶同工酶某些性质研究

对水稻根两种不同形式的谷氨酰胺合成酶（ＧＳｒａ和ＧＳｒｂ）进行了动力学性质研究．ＧＳｒａ对热比较稳定，而ＧＳｒｂ比较敏感；ＧＳｒａ的最适温度为５５℃，ＧＳｒｂ为４３℃．ＧＳｒａ和ＧＳｒｂ的最适ｐＨ都为７．５．ＧＳｒａ对Ｌ－谷氨酸、羟胺和ＡＴＰ的表观Ｋｍ分别为４．１６、０．６０和０．３４，而ＧＳｒｂ分别为１５．７３、０．６０和０．５８．