钙对黄瓜子叶愈伤组织中硝酸还原酶(NR)活性的影响

本文采用黄瓜子叶愈伤组织,研究了不同钙培养下,对愈伤组织生长、硝酸盐吸收,NR活性以及组织中钙、镁含量的影响。结果表明,缺钙后,愈伤组织生长、硝酸盐吸收、NR活性等都比正常钙培养下的愈伤组织降低。这与用整株植物所得结果基本一致,对此结果进行了讨论。     

光质对石刁柏愈伤组织培养中生长和过氧化物酶的影响

报道了在石刁柏愈伤组织培养中,采用５种不同光质处理,对愈伤组织生长及其过氧化物酶（ＰＯＤ）活性及同工酶的影响,实验表明,不同光质处理对生长有不同的效应,蓝光、红光下的培养物生长较快。不同光质对培养物质的ＰＯＤ活性亦有不同效应,ＰＯＤ同工酶谱亦有不同,蓝光、红光下的培养物,ＰＯＤ活性较高。ＰＯＤ活性变化与愈伤组织生长呈正相关。     

烟草愈伤组织继代培养与分化期间核酸代谢的比较研究

柳叶烟草愈伤组织在分化和芽原基形成期间,DNA 和RNA 含量均高于继代培养物;在芽原基形成后和幼芽生长期间(12天以后),DNA和RNA 含量持续上升,而同期继代培养物巳进入生长静止期,DNA 和RNA 含量基本不变或略有下降。根据RNA 电泳结果还进一步分析了两种愈伤组织培养物各RNA 组分变化与总RNA 含量变化的关系。分化培养物在芽原基形成时有明显升高的RNase 活性峰和持续上升的RNA 合成速率;而此时期继代培养物的RNase 活性及RNA 合成能力均较低;分化愈伤组织的DNA 合成速率在幼芽生长期间仍维持上升趋势,且显著高于同期继代愈伤组织的合成速率。这些结果表明,烟草愈伤组织分化培养物比继代培养物有更旺盛的核酸代谢能力。     

蓝光对绿豆下胚轴愈伤组织形成和生长过程中蛋白质代谢的影响

蓝光、白光和黑暗对绿豆下胚轴愈伤组织形成和生长过程中蛋白质代谢的影响不同。培养后３～１８ ｄ ,蓝光处理材料的可溶性蛋白质含量明显高于白光处理,更高于黑暗培养的材料。蓝光和白光明显促进３Ｈ亮氨酸掺入蛋白质,而蓝光和白光处理后游离氨基酸含量与黑暗对照相比,下降时间早,幅度大。在培养过程中,蛋白酶活性的变化与游离氨基酸相似。蛋白质合成抑制剂环己酰亚胺（ＣＨＭ） 抑制愈伤组织生长,其中以蓝光最大,白光次之,黑暗最小。在培养基中加入ＣＨＭ 愈早,抑制程度愈大。实验表明,ＣＨＭ 抑制愈伤组织蛋白质合成,也是以蓝光最甚。由此可见,蓝光促进绿豆下胚轴愈伤组织的形成、生长和蛋白质合成。     

海岛棉愈伤组织诱导和分化研究

以海岛棉无菌苗的胚根、下胚轴和子叶作外植体,对这３种器官在离体培养中愈伤组织诱导、分化以及影响因素进行了研究。结果表明：下胚轴作外植体效果最好,愈伤组织生长块、质地好,有芽的分化,进而可再生出植株。胚根效果很差,愈伤组织产生很少而且很易褐化死亡。子叶效果不好,愈伤组织少、生长慢无分化。外源激素中２．４－Ｄ与ＫＴ配合使用效果好,愈伤组织可以分化。无菌苗生长状态及培养基中非激素成分对愈伤组织诱导和分化     

烟草愈伤组织分化和芽原基形成期间呼吸代谢途径的改变

接种在继代培养基上的柳叶烟草愈伤组织,未观察到组织分化和芽原基形成。在分化培养基上生长的愈伤组织,接种后第6天可见拟分生组织和管胞分化,9—12天有芽原基形成,15—18天可观察到苗端结构。根据碘乙酸、Na_3PO_4和丙二酸抑制试验,以及3-磷酸甘油醛脱氢酶与琥珀酸脱氢酶活性测定结果,初步表明烟草愈伤组织呼吸中存在有EMP、HMP和TCAC代谢途径.在发生输导组织和芽原基分化的愈伤组织中(接种后第6—12天),HMP途径的运行程度较高;而芽原基的继续生长(培养12天以后),则与EMP途径的增加有关;分化培养基上生长的愈伤组织,始终较继代培养愈伤组织具有较高的FCAC活性水平。     

三七.人参和西洋参细胞悬浮培养的比较研究

用薄层层析对三七、人参和西洋参愈伤组织进行的初步鉴定表明,三种愈伤组织都含有皂甙和主要皂甙成分Rb_1、Rg_1,三七愈伤组织还含有一种抗癌皂甙Rh_1。对愈伤组织的生长,三七低于人参高于西洋参;对愈伤组织中总皂甙含量,三七均高于人参和西洋参。三种植物细胞悬浮培养结果类似于他们的愈伤组织培养,但生长又进一步提高。三七细胞悬浮培养中皂甙产生的时间进程几乎与生长平行,合适的收获期为培养30天。寡糖素不仅增强三七培养细胞的皂甙形成而且促进细胞生长,较合适的浓度为1.25 ppm。通过以上研究,使三七悬浮培养细胞的生长(干重增加178毫克)为最初培养愈伤组织的4倍以上,总皂甙产率高达20.6毫克,为最初培养愈伤组织的8.5倍。     

植物生长调节剂对南方红豆杉愈伤组织培养和紫杉醇合成的影响

通过不同种类和水平植物生长调节剂对南方红豆杉(Taxus chinensisvar.mairei)愈伤组织诱导、生长和紫杉醇合成能力影响的研究发现:诱导培养初期,以无植物生长调节剂的MS为基本培养基,在附加不同植物生长调节剂组合作用下愈伤组织产生的时间和生长、在相同植物生长调节剂组合作用下不同外植体愈伤组织的产生时间和生长均表现出较显著差异,2,4-D/NAA高于0.4时,不利于南方红豆杉愈伤组织的诱导。转换到附加不同植物生长调节剂组合的B5培养基上后,随培养继代次数的增加,生长差异逐渐缩小,直至不显著,表明参考不同文献报道最优配方所设计的各植物生长调节剂组合对南方红豆杉愈伤组织的生长均较适宜,有利南方红豆杉愈伤组织生长的植物生长调节剂优化组合没有唯一性。但不同调节剂组合作用下的同源愈伤组织中、相同调节剂作用下不同源愈伤组织中紫杉醇含量均存在着极显著差异,适当水平(2 mg/L)的2,4-D单用,或与适当水平的KT、6-BA、KT GA配合使用,对南方红豆杉愈伤组织紫杉醇的合成较有利,NAA则不太有利,幼茎和叶愈伤组织产紫杉醇的水平较其它愈伤组织为高。     

高压静电场(HVEF)对苜蓿叶片愈伤组织增殖的影响

苜蓿叶片来源的愈伤组织经一定的高压静电场处理后生长速率显著高于对照组,而且处理组愈伤组织的呼吸速率,元素吸收速率也高于对照组。进一步的测定结果比较表明：静电场处理组的愈伤组织中可溶性蛋白质含量、蔗糖酶活性高于对照组;而ＩＡＡ氧化酶和ＲＮＡ水解酶活性则低于对照组。显示静电场处理组愈伤组织有较高的代谢水平和旺盛的分裂生长状态。探讨了静电场处理剌激愈伤组织增殖的可能机理     

银杏叶愈伤组织和叶中超氧化物歧化酶、总黄酮类抗氧化活性剂活性的比较分析

以银杏（Ginkgo biloba L.）叶片为外植体进行愈伤组织的诱导和培养,筛选到适合银杏叶片愈伤组织诱导和继代的培养基。以此愈伤组织为研究材料,比较了叶片愈伤组织和叶片中两种活性成分超氧化物歧化酶（SOD）、黄酮的活性差异。结果表明,银杏叶片愈伤组织中SOD的活性明显比叶片中的SOD活性高,同时愈伤组织中SOD同工酶谱带也比叶中有更多表达,但愈伤组织中总黄酮含量却比叶片中的含量低。实验证实SOD和黄酮类物质具有清除超氧阴离子的作用,表明银杏叶片愈伤组织和叶片中具有不同的占主导作用的抗氧化活性的机制。     

Effect of Azotobacter strains on sugar beet callus proliferation and nitrogen metabolism enzymes

The effect of five Azotobacter chroococcum strains and nitrogen content in nutrient media on callus growth of two Beta vulgaris L. cultivars were investigated, as well as the activity of nitrate reductase (NR), glutamine synthetase (GS) and glutamate dehydrogenase (GDH) in inoculated callus tissue. On medium with full nitrogen content (1 N) the inoculation with A. chroococcum strain A2 resulted in the highest calli mass, while strains A8 and A14 maximally increased NR activity. On media with 1/8 N the highest effect on calli growth, GS and GDH activity had the strain A8. The strain A2/1 significantly increased callus proliferation on medium without N. Asymbiotic association between sugar beet calli and Azotobacter depended on genotype/strain interaction and was realised in presence of different nitrogen levels. This revised version was published online in July 2006 with corrections to the Cover Date.     

Isolation and characterization of transposon Tn5 mutants of Rhodobacter sphaeroides deficient in both nitrate and chlorate reduction.

Abstract The wild-type strain Rhodobacter sphaeroides DSM 158 is a nitrate-reducing bacterium with a periplasmic nitrate reductase. Addition of chlorate to the culture medium causes a stimulation of the phototrophic growth, indicating that this strain is able to use chlorate as an ancillary oxidant. Several mutant strains of R. sphaeroides deficient in nitrate reductase activity were obtained by transposon Tn5 mutagenesis. Mutant strain NR45 exhibited high constitutive nitrate and chlorate reductase activities and phototrophic growth was also increased by the presence of chlorate. In contrast, the stimulation of growth by chlorate was not observed in mutant strains NR8 and NR13, in which transposon Tn5 insertion causes the simultaneous loss of both nitrate and chlorate reductase activities. Tn5 insertion probably does not affect molybdenum metabolism since NR8 and NR13 mutants exhibit both xanthine dehydrogenase and nitrogenase activities. These results that a single enzyme could reduce both nitrate and chlorate in R. sphaeroides DSM 158.     

Effect of NaCI on nitrate reductase,glutamate dehydrogenase and glutamate synthase inVigna radiata calli

The effect of NaCI stress on the activities of nitrate reductase (NR), glutamate dehydrogenase (GDH) and glutamate synthase (GOGAT) in callus lines ofVigna radiata which differ in salt resistance, was studied at weekly intervals upto 28 d of growth. After 28 d, the NaCI resistant callus (selected at 300 mM NaCI) at NaCI concentrations higher than 200 mM maintained higher NR activity than non-selected line. NaCI stress also affects aminating and deaminating activities of GDH. The NADH-GDH activity in the presence of NaCI was higher in the resistant than non-selected line. On the other hand, NAD-GDH activity in both the lines was completely inhibited after 7 d of growth. The increased activity of NADH-GDH in resistant calli may play a vital role in protecting the cells from toxic effect of increased endogenous level of ammonia which probably accumulates due to efficient NO₃ ⁻ reduction. NADH-GOGAT activity was found to decrease under salt stress in both the callus lines. Nitrogen assimilation in salt-resistant calli under salt stress was found to be characterized by high NR and NADH-GDH activities, concomitantly with low GOGAT activity. The authors are grateful to DST and CSIR for financial assistance.     

RELATIONSHIPS BETWEEN NITRATE REDUCTASE ACTIVITY AND RATES OF GROWTH AND NITRATE INCORPORATION UNDER STEADY-STATE LIGHT OR NITRATE LIMITATION IN THE MARINE DIATOM THALASSIOSIRA PSEUDONANA (BACILLARIOPHYCEAE)1

Although activity of the enzyme nitrate reductase (NR) can potentially be used to predict the rate of nitrate incorporation in field assemblages of marine phytoplankton, application of this index has met with little success because the relationship between the two rates is not well established under steady-state conditions. To provide a basis for using NR activity measurements, the relationships among NR activity, growth rate, cell composition, and nitrate incorporation rate were examined in cultures of Thalassiosira pseudonana (Hustedt)Hasle and Heimdal, growing a) under steady-state light limitation, b) during transitions between low and high irradiance (15 or 90 μmol quanta.m^?2.s^?1), and c) under steady-state nitrate limitation. Using a modified assay for NR involving additions of bovine serum albumin to stabilize enzyme activity, NR activity in light-limited cultures was positively and quantitatively related to calculated rates of nitrate incorporation, even in cultures that were apparently starved of selenium. During transitions in irradiance, growth rates acclimated to new conditions within 1 day; through the transition, the relationship between NR activity and nitrate incorporation rate remained quantitative. In nitrate-limited chemostat cultures, NR activity was positively correlated with growth rate and with nitrate incorporation rates, but the relationship was not quantitative. NR activity exceeded nitrate incorporation rates at lower growth rates (<25% of nutrient-replete growth rates), but chemostats operating at such low dilution rates may not represent ecologically relevant conditions for marine diatoms. The strong relationship between NR activity and nitrate incorporation provides support for the idea that NR is rate-limiting for nitrate incorporation or is closely coupled to the rate-limiting step. In an effort to determine a suitable variable for scaling NR activity, relationships between different cell components and growth rate were examined. These relationships differed depending on the limiting factor. For example, under light limitation, cell volume and cell carbon content increased significantly with increased growth rate, while under nitrate limitation cell volume and carbon content decreased as growth rates increased. Despite the differences found between cell composition and growth rate under light and nitrate limitation, the relationships between NR activity scaled to different compositional variables and growth rate did not differ between the limitations. In field situations where cell numbers are not easily determined, scaling NR activity to particulate nitrogen content may be the best alternative. These results establish a strong basis for pursuing NR activity measurements as indices of nitrate incorporation in the field.     

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(Phaeocystis globosa)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3.62 mmol.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。     

Involvement of nitrate reduction in the tolerance of tomato (<Emphasis Type="Italic">Solanum lycopersicum</Emphasis> L.) plants to prolonged root hypoxia

The putative role of nitrate and nitrate reductase in the tolerance to prolonged hypoxia was investigated in tomato plants. Nitrogen nutrition has been modified either by deprivation of nitrate or by addition of tungstate—an inhibitor of nitrate reductase (NR)—in the culture medium. In the absence of nitrate as well as in the presence of tungstate, plant growth was significantly disturbed. In the presence of nitrate, the growth of hypoxic plants maintained, nitrate absorption and NR activity increased and a significant release of nitrite into the medium was observed. This mechanism of nitrate reduction, called nitrate respiration, could be an alternative pathway to oxygen-dependent respiration during root hypoxia and a transient adaptation of tomato roots to hypoxic conditions.