Heat-Induced Increase in the Stability of Nitrate Reductase from Wheat Leaves against Inactivating Factors

Heating of wheat seedlings (Triticum aestivum L.) for 3 h at 41–42°C (heat hardening) increased the thermal stability of nitrate reductase (NR). After transferring hardened plants to normal temperature, the higher level of thermal stability persisted for 6 days. The heat hardening increased the enzyme stability against the proteolytic effect of trypsin and reduced the rate of NR degradation in extracts. Inhibition of the NR synthesis by transferring plants to a nitrate-free medium resulted in a much lower rate of enzyme degradation in the cells of hardened, as compared to unhardened plants. A short-term heating of seedlings (10 min at 36, 40, and 44°C) increased the ability of NR to reactivate after heat damage. The thermal stability of NR increased only in seedlings that had been hardened at 40 and 44°C, whereas hardening at 36°C did not result in enzyme stabilization. It is concluded that heat hardening (hyperthermia) increases NR stability against a number of inactivating factors (heating, proteolysis,in vitroand in vivo enzyme degradation) and enhances its ability to repair damage induced by heating.     

NO_3~-上运和液泡内NO_3~-外流对小麦叶内硝酸还原酶活性的调节

NO_3~-亏缺能使叶片硝酸还原酶活性(NRA)和NO_3~-总量降低,而根部NO_3~-吸收及上运能力提高,以亏缺2d的幼苗最为明显,该幼苗经12hNO_3~-吸收,叶片的NRA高于未经亏缺的幼苗,但NO_3~-含量以后者为高,代谢库中NO_3~-含量前者高于后者。提高营养液中NO_3~-浓度,NO_3~-上运速率升高,叶片内NRA增加。叶片组织暗中无氧保温40min后,代谢库体积渐大,液泡内NO_3~-有外流产生;Cl~-可促使液泡内NO_3~-外流,代谢库中NO_3~-量增加,NRA升高。NRA在体内测定条件下,保温3h后,NO_2~-产生趋于稳值,NRA降至最低;系统中加KCl或KNO_3使NO_2~-产生趋于稳值的时间延长,且能提高NO_2~-积累总量。     

硝酸盐对硝酸还原酶活性的诱导及硝酸还原酶基因的克隆

硝酸盐在植物体内的积累过多已成为影响蔬菜品质并影响人类健康的重要因素。硝酸还原酶（NR）是硝酸盐代谢中的关键酶,提高其活性有利于硝酸盐的降解。为了解植物不同组织中NR的活性,用活体测定法检测了经50mmol/L的KNO₃诱导不同时间后的油菜、豌豆和番茄幼苗根茎叶中NR活性,同时为了明确外源诱导剂浓度与植物体内NR活性的关系,检测了经不同浓度KNO₃诱导2h后的矮脚黄、抗热605、小白菜和番茄叶片中的NRA。结果表明,不同植物组织NR活性有很大差异,叶中NR活性较高,根其次,茎最低;不同植物的NR活性随诱导时间呈不同的变化趋势,相同植物不同组织的NR活性变化趋势相似;不同植物叶片NRA为最高时KNO₃浓度不同。用30mmol/L的KNO3诱导番茄苗2h后,从番茄根和叶中提取总RNA,用RT-PCR方法获得NR cDNA,全长2736bp,编码911个氨基酸。为进一步利用该基因提高植物对硝酸盐的降解能力打下基础。     

Inhibition of Wheat Nitrate Reductase Activity by Zinc

The effect of Zn^2- on nitrate reductase (NR, EC 1.6.6.1) activity was studied in botá wheat (Triticum aestivum cv. Oasis) leaves and in the NR enzyme partially purified from wheat leaves. Leaf segments were floated on 0 to 5 mM ZnSO₄ solutions (pH 6.0) for 24 h under continuous light. Zn^2- at 250 M decreased NR activity and increased membrane permeability. However, parameters of cellular oxidative damage were scarcely affected by Zn^2- treatments. Accordingly, the decrease of NR activity induced by Zn^2- was not prevented by benzoate (a scavenger of oxygen radicals). The effect of Zn^2- was dependent on leaf age: it decreased NR activity in mature but not in young leaves. Zn² inhibited the partially purified NR. This inhibition was not reversed by either co- or post-incubation with cysteine, and the amount of -SH groups of the purified NR was not affected by Zn²⁺ indicating that Zn^2- inhibition does not involve key -SH groups of the enzyme. However, o-phenantroline both prevented and reversed Zn²⁺-induced NR inhibition. We concluded that the effect of Zn²⁺ on NR activity in vivo is not associated with an increase in active oxygen generation and involves a direct and reversible inhibition of the enzyme.     

Proline Metabolism and Cross-Tolerance to Salinity and Heat Stress in Germinating Wheat Seeds

Germination/growth of wheat (Triticum aestivum L., cv. Zimai 1) seeds and changes in the levels of proline and protein as well as in activities of key enzymes involved in proline metabolism in response to salinity-, heat-stresses and their cross-stress were studied. With decreasing water potential caused by increasing concentrations of NaCl, germination percentage, fresh weight of seedlings and protein amount markedly decreased, whereas proline amount slightly increased. The activities of pyrroline-5-carboxylate synthetase (P5CS), ornithine aminotransferase (OAT), and proline dehydrogenase (PDH) peaked at ?0.2 MPa water potential. Germination percentage and amounts of proline and protein increased as germination temperature elevated to 25°C from 15°C, and decreased above 25°C; fresh weight of seedlings increased to 30°C from 15°C, and decreased above 30°C. However, the activities of P5CS, OAT and PDH gradually decreased with elevaing temperature. Seeds pretreated at 33°C or in ?0.8 MPa NaCl solution for various time length increased tolerance to subsequent salt + water stress or heat stress, as measured by germination percentage and fresh weight of seedlings 5 days after beginning of experiment. The acquisition of cross-tolerance resulting in limitation of negative stress effects does not relate directly to proline level and activities of P5CS, OAT and PDH involved in proline metabolism. Proline amount as measured four days or later after stress imposition cannot be considered a symptom of salt-, water- and heat-stress injury or an indicator of the resistance.     

植物中硝酸还原酶和亚硝酸还原酶的作用

植物通过硝酸盐同化途径以硝酸盐和氨的形式吸收氮元素。硝酸盐的同化是一个受到严格控制的过程,其中两个先后参加反应的酶——硝酸还原酶(NR)和亚硝酸还原酶(NiR)对初级氮的同化起主要调控。在高等植物中,NR和NiR基因的转录及转录后加工受到各种内在和外在因素的影响,翻译后调控是消除亚硝酸盐积累的重要机制。随着分子生物学技术的发展,可以更容易地通过突变体和转基因方式来研究NR和NiR基因的调控。     

高温胁迫下葡萄叶片蛋白激酶的诱导形成与活性变化

以"京秀"葡萄(Vitis vinifera L.cv.Jingxiu)幼苗为试材,研究了高温胁迫激活的蛋白激酶的类型和活性.结果表明,高温胁迫10～60min明显地激活了一个分子量约为52 kD的蛋白激酶,该蛋白激酶能将凝胶中所嵌入的髓鞘碱性蛋白(MBP)磷酸化,在放射自显影中表现出很高的放射活性,而对凝胶中的组蛋白-Ⅲ(histone-Ⅲ)则没有这样的作用.在溶液反应体系中该蛋白激酶对MBP也表现出很高的磷酸化活性,而对histone-Ⅲ却无作用.Ca2 对其活性变化无显著影响.酪氨酸特异性蛋白磷酸酶(YOP)对该激酶的活性有显著的钝化作用.结果表明该52 kD蛋白激酶是MAPK家族中的一种.     

渗透胁迫下小麦叶片蛋白质合成与降解的示踪研究

渗透胁迫降低了叶片、特别是生长叶片蛋白质中固定~(14)CO_2及由根系吸收的~(14)C-Gly的掺入率,但同等程度胁迫处理,抗旱品种的掺入率降低幅度小于敏感品种;轻度胁迫后复水,抗旱品种生长叶蛋白质的放射性高于对照,而敏感品种仍低于对照。Poly(A~+)-mRNA的体外翻译测定证明,胁迫时蛋白质合成能力降低的主要原因是Poly(A~+)-mRNA翻译活性的降低。渗透胁迫也促进了叶片蛋白质降解,但与蛋白质合成不同,在成熟叶片中表现得更突出。     

盐胁迫对盐芥生长及硝酸还原酶活性的影响

盐胁迫处理导致盐芥植株鲜重、干重、含水量、肉质化程度和根冠比都下降;根中有机物含量上升,而无机物含量下降,叶的变化与根的相反;渗透调节能力、Na 含量和根系活力上升;硝酸还原酶活性显著增加;超氧阴离子(O2-)含量先降低后升高.表面扫描电镜图像显示:盐芥叶片表面没有盐腺或盐囊泡,所以它不是泌盐盐生植物.盐芥生长状况、Na 含量和Na X-ray微区分析结果表明:盐芥也不是拒盐盐生植物,而很可能是稀盐盐生植物.     

硝酸盐对球形棕囊藻生长和硝酸还原酶活性的影响

以我国南海海域分离的赤潮原因种——球形棕囊藻(Phaeocystisglobosa)为材料,研究了不同硝酸盐浓度下藻细胞生长及硝酸还原酶活性的变化。当培养基中不含硝酸盐时,藻细胞内硝酸还原酶的活性保持在非常低的水平,藻细胞的生长受到限制,不能形成正常的生长曲线:当培养基中硝酸盐浓度为3.62μmol.L-1时,藻细胞的硝酸还原酶活性和比生长速率达到最大。在含有硝酸盐的培养基中,接种培养后第9天藻细胞硝酸还原酶活性达到最大值,并且在4种不同硝酸盐浓度下,藻细胞硝酸还原酶活性的差异性达到极显著水平(P<0.01)。在接种培养第16天藻细胞密度达到最大值,并且4种不同硝酸盐浓度培养的藻细胞密度之间的差异性也达到极显著水平(P<0.01)。实验结果表明,在培养基中添加不同浓度的硝酸盐,对球形棕囊藻细胞硝酸还原酶的活性和藻细胞的生长有极显著的影响,含有较高硝酸盐的富营养化海域有利于球形棕囊藻细胞的持续生长。     

氰酸钾对Chlamydomonas reinhardii硝酸还原酶的诱导

单胞绿藻和高等植物一样通过硝酸还原酶(NAD(P)H-NR,EC 1,6.6.2)和亚硝酸还原酶(EC 1.7.7.1)同化硝酸盐(Florencio和Vega1982)。一般来说,硝酸盐是诱导NR活力所必需的。在某些情况下,6-RA等激素、NO_2~-、氯霉素、低pH、某些有机酸和含氮化合物和氮饥饿也     

小麦中两个肉桂酰辅酶A还原酶基因的分离和表达分析

肉桂酰辅酶A还原酶（CCR）负责催化木质素单体生物合成中最重要的代谢反应,它将类苯丙酸类代谢物转移到木质素的合成途径中,为了更好地了解木质素在小麦生长发育中的作用,从小麦（Triticum aestivum L.ev,H4564)中克隆了两个肉桂酰辅酶A还原酶的cDNA,相似性和进化关系的分析表明这两个cDNA片段分别属于不同的肉桂酰辅酶A还原酶,这两个cDNA片段分别命名为W－cr6和W-cr19,RT-PCR和Northen杂交结果证明,W－cr6基因主要在小麦的茎和叶中表达,W－cr19基因主要在根和茎中表达,上述结果表明在小麦的基因组中至少存在两类肉桂酰辅酶A还原酶基因。     

施氮对不同品种冬小麦植株硝态氮和硝酸还原酶活性的影响

以黄土高原南部半湿润区土垫旱耕人为土为供试土壤进行盆栽试验,以NR 9405、9430、偃师9号、小偃6号、陕229号和西农2208冬小麦品种为供试材料,研究施氮对不同品种冬小麦植株硝态氮含量和硝酸还原酶活性(NRA)的影响.结果表明,施氮能明显增加叶片NRA.不施氮时除小偃6号和偃师9号外,其余品种NRA在全生育时期的动态变化均呈双峰曲线,2个高峰期分别在返青期和开花期,且开花期高峰值(36.17 NO2-μg.-g 1FW.h-1)明显比返青期峰值(15.407 NO2-μg.-g 1FW.h-1)大;施氮时不同品种叶片NRA在全生育期呈单峰曲线变化,最高峰在开花期,平均峰值为80.93 NO2-μg.-g 1FW.h-1),比同期不施氮处理增加1倍以上.施氮后地上部硝态氮含量在各时期均显著提高,在小麦生育前期(出苗到拔节)表现最为显著.氮肥对不同品种硝态氮含量的影响程度基本上与对NRA的影响程度相反,即施氮后硝态氮增加幅度小的品种,NRA却增加幅度大.     

Nitrate Reductase Activity in an Eutrophic Reservoir duringthe Stratification Cycle

Nitrate reductase activity was measured during the stratification cycle of the eutrophic reservoir La Concepción. Nitrate was consumed in the epilimnion mainly through assimilatory reduction, and in the hypolimnion through dissimilatory reduction triggered by anoxic conditions. Nitrate reductase activity (NR) scaled to particulate nitrogen (PN) was positively correlated with the external nitrate concentration and the NO₃^–/NH₄⁺ ratio. Using NR as a tool for the assessment of the N cycle dynamics, it can be suggested that at the beginning of the stratification cycle, the phytoplanktonic community was mainly using NO₃^– as N source; and since N was not likely the limiting nutrient at that time of the year, NR was close to its maximum possible.     

Nitrate reductase is inhibited in leaves of Triticum aestivum treated with high levels of copper

Copper is a potent sulfhydryl reagent which can also catalyse the generation of active oxygen. Since nitrate reductase (EC 1.6.6.1) is an SH-enzyme sensitive to oxidative environments, the relations among copper, active oxygen species and nitrate reductase (NR) activity are of interest. Foliar segments of wheat ( Triticum aestivum cv. Oasis) were floated on CuSO₄ solutions (up to 250 μ M ) for 24 h under continuous light. Copper decreased NR activity before affecting active oxygen generation as estimated by changes in oxidative parameters, including malondialdehyde, K⁺ leakage and chlorophyll degradation. Cysteine and Na-benzoate counteracted this decrease, suggesting an oxidative damage of the enzyme in leaves exposed to high copper levels. Copper-induced NR inactivation was further studied in the partially purified enzyme. Preincubation with CuSO₄ inhibited NR. Copper inhibition was reversed by subsequent incubation with EDTA, indicating that the metal bonded to key -SH groups of the enzyme. In addition, an ^˙OH-generating system (composed of CuSO₄, ascorbate and H₂O₂) irreversibly decreased the activity of purified NR to a greater extent than copper alone. Our results show that copper affects nitrogen metabolism by diminishing NR activity, involving a direct effect on key SH-groups and an indirect effect via attack by active oxygen species induced by the metal.     

Cloning and Expression Analysis of Two Wheat cDNAs Encoding Cinnamoyl-CoA Reductase

Cinnamoyl-CoA reductase (CCR) is responsible for the first committed reaction in monolignol biosynthesis, which diverts phenylpropanoid-derived metabolites into the biosynthesis of lignin. To gain a better understanding of the lignin biosynthesis in wheat development, two cDNAs encoding CCR were identified from wheat ( Triticum aestivum L. cv. H4564). DNA sequence analyses indicated that the two cDNAs represent two classes of CCR. RT-PCR and Northern blot hybridization demonstrated that one of them, W-cr6, was expressed actively in stem and leaf tissue, the other one, W-cr19, was expressed in root and stem tissue. The results suggested that there are at least two genes encoded for CCR existing in wheat genome.     

Possible Involvement of Anti-Oxidant Enzymes in the Cross-Tolerance of the Germination/Growth of Wheat Seeds to Salinity and Heat Stress

The germination/growth of wheat （Triticum aestivum L. cv. Zimai 1） seeds and changes in the activities of superoxide dismutase （SOD）, ascorbate peroxidase （APX）, and catalase （CAT）, as well as in the content of thiobarbituric acid-reactive substances （TBARS）, in response to salt and heat stress, as well as cross-stress, were investigated in the present study. With increasing temperature and decreasing water potential caused by NaCI solution, the germination percentage of seeds and the fresh weight of seedlings decreased markedly, SOD activity increased, activities of APX and CAT decreased distinctly, and the TBARS content increased gradually. Seeds pretreated at 33℃ for different times displayed increased tolerance to subsequent salt stress, enhanced SOD, APX, and CAT activities, and decreased TBARS content. Seeds pretreated at -0.8 MPa NaCI for different times displayed increased tolerance to subsequent heat stress and marked increases in SOD, APX, and CAT activities, which were associated with decreased TBARS content. It is considered that the common component in the cross-tolerance of the germination and growth of wheat seeds to salinity and heat stress is the anti-oxidant enzyme system.     

小麦NO3-转运蛋白基因TaNRT2.3的克隆和表达分析

用RT-PCR和RACE技术在NO3-诱导处理的小麦(Triticum aestivum L.)根中克隆到一个硝酸根转运蛋白基因的cDNA,命名为TaNRT2.3(GenBank登录号AY053452).序列分析表明,TaNRT2.3全长1 744 bp,其中含有1 521bp的ORF,编码507个氨基酸,具有12个跨膜区,属于MFS超基因家族中的NNP家族.TaNRT2.3与其他植物中已知的NRT2具有很高的同源性.Northern杂交表明:TaNRT2具有在根中表达的组织特异性,而在叶中未检测到.TaNRT2的表达受NO3-诱导,在含NH4 介质中不表达.NO3-在低浓度(5～200μmol/L)和高浓度(2.0 mmol/L)时均起作用.通过研究小麦在0.2 mmol/LNO3-条件下TaNRT2的表达水平及对NO3-的吸收效率,表明TaNRT2在小麦高效吸收NO3-方面起着重要的作用.分根实验表明植物中N循环本身可以作为吸收N的调节信号.     

水稻硝酸还原酶的RNA干涉及其酶活性分析

分析水稻硝酸还原酶（NR）基因生物信息学的结果显示：水稻基因纽中有2个NR基因成员：一个为NR[NADH]（NR1）：另一个为NR[NAD（P）H]（NR2）。两者的蛋白序列相似性为70％。用RT—PCR技术从水稻cDNA中获得了NR1和NR2的cDNA片段,其大小分别为1086bp和892bp。构建RNA干涉载体（称pRNAi—NR1和pRNAi-NR2）转化水稻愈伤组织后检测转基因后代酶活性的结果表明：两种干涉植株的根叶中的NR活性均大幅度下降,并且根叶中的活性变化呈线性正相关关系。表明2个基因可能均有调控根叶中NR活性的作用。