土壤干旱对冬小麦旗叶乙烯释放、多胺积累和细胞质膜的影响

土壤水分亏缺时,小麦旗叶的乙烯释放量增加,三种多胺（精胺、亚精胺、腐胺）的含量在小麦灌浆初期显著增加,而在小麦灌浆末期除腐胺外均降低。外施５００ｍｇ／Ｌ的亚精胺溶液能减弱小麦叶片的膜脂质过氧化程度。土壤水分亏缺时膜透性增大,膜脂过氧化物丙二醇含量升高,导致不饱和脂肪酸指数下降,亚麻酸含量下降。严重土壤水分胁迫下,过氧化物酶的活性升高。这些结果表明土壤干旱损害小麦旗叶质膜,促其衰老。研究表明,随着受旱程度的提高,小麦旗叶遭受的损伤逐渐加重,植株对土壤干旱的适应性亦逐渐降低。     

干旱高温及高浓度CO2复合胁迫对冬小麦生长的影响

研究了不同CO₂浓度、不同温度和水分条件及其组合对冬小麦产量、光合及水分的影响,以阐明气候变化对冬小麦的影响.结果表明: CO₂浓度升高对冬小麦光合速率没有影响,而升温和干旱均使光合速率显著下降.升高CO₂浓度与温度对冬小麦旗叶水分条件没有影响,干旱胁迫下旗叶相对含水量显著降低,而升温与干旱同时发生可降低旗叶水势.气温、CO₂浓度升高以及干旱胁迫共同作用下,冬小麦光合速率和旗叶水分条件显著降低,产量下降41.4%.CO₂浓度升高使冬小麦增产21.2%,温度升高使产量降低12.3%,CO₂浓度和温度同时升高对产量没有影响,干旱胁迫下产量下降程度更大.未来气候变化情景下,保持较高的土壤水分含量是减少气候变暖危害的重要手段.
     

干旱高温及高浓度CO2复合胁迫对冬小麦生长的影响

研究了不同CO₂浓度、不同温度和水分条件及其组合对冬小麦产量、光合及水分的影响,以阐明气候变化对冬小麦的影响.结果表明: CO₂浓度升高对冬小麦光合速率没有影响,而升温和干旱均使光合速率显著下降.升高CO₂浓度与温度对冬小麦旗叶水分条件没有影响,干旱胁迫下旗叶相对含水量显著降低,而升温与干旱同时发生可降低旗叶水势.气温、CO₂浓度升高以及干旱胁迫共同作用下,冬小麦光合速率和旗叶水分条件显著降低,产量下降41.4%.CO₂浓度升高使冬小麦增产21.2%,温度升高使产量降低12.3%,CO₂浓度和温度同时升高对产量没有影响,干旱胁迫下产量下降程度更大.未来气候变化情景下,保持较高的土壤水分含量是减少气候变暖危害的重要手段.
     

小麦旗叶和穗光合作用与耐旱性关系研究

研究了土壤干早胁迫下小麦（Triticum aestivum L.）旗叶和穗光合作用的差异及其与耐旱性的关系。结果表明,穗光合活性对干旱胁迫的敏感性低于旗叶叶片。干旱胁迫下。穗光合速率下降幅度远小于叶片,类胡萝卜素含世较高,色素含量、PSI活性下降幅度均小于叶片。且PEPC活性诱导增强,暗示穗器官较叶片有较强的耐逆性。     

干旱胁迫对小麦幼苗抗氰呼吸和活性氧代谢的影响

研究了干旱胁迫对抗旱性强弱不同的两种小麦幼苗的抗氰呼吸和活性氧代谢的影响。干旱胁迫导致了两种小麦抗氰呼吸活性及基因转录水平的下降,但抗旱品种在轻度干旱胁迫下表现出一定的适应能力,其抗氰呼吸活性及基因转录水平均高于不抗旱品种。干旱胁迫下,对干旱敏感的小麦幼苗叶片中活性氧含量高于抗旱小麦;3种抗氧化酶的活性低于抗旱小麦的3种抗氧化酶的活性。据此认为,严重的干旱胁迫引起活性氧含量的增加扰动了活性氧与抗氰呼吸之间的应答平衡,但抗氰呼吸可能通过清除活性氧等机制而起了抗旱的作用。     

小麦非结构性碳水化合物分配对水分胁迫的生理响应

以‘西旱2号’小麦为试材,采用水分胁迫和复水处理方法,研究了小麦发育过程中不同水分胁迫下非结构性碳水化合物(NSC)在小麦旗叶、茎、叶鞘等器官中的动态变化,以及籽粒中碳代谢相关酶(可溶性淀粉合成酶SSS和淀粉粒结合态合成酶GBSS)活性的变化.结果表明:不同程度水分胁迫对小麦旗叶、茎、叶鞘等器官中蔗糖含量无显著影响.随水分胁迫的深入,花后12～ 18 d旗叶中淀粉含量显著增加;水分胁迫缩短了花后茎和叶鞘中淀粉的积累时间,抑制了茎中淀粉的转化和分配;而叶鞘中淀粉的积累逐渐增大,在中度水分胁迫下积累提前终止.在水分胁迫初期,各营养器官中的NSC含量为旗叶＞茎＞叶鞘;随着水分胁迫的深入,各营养器官中的NSC含量为茎＞旗叶＞叶鞘.小麦主要营养器官中NSC的分配速率及主要代谢酶的变化可能是小麦对水分胁迫的一种生理调节反应.     

喀斯特石生反叶扭口藓活性氧代谢对干旱胁迫的动态响应

本文研究了喀斯特石面常见植物反叶扭口藓(Barbula fallax Hedw.)在干旱胁迫下活性氧代谢的变化。结果显示:早期干旱超氧化酶歧化酶(SOD)、过氧化氢酶(CAT)和过氧化物酶(POD)活性以及类胡萝卜素(Car)活性逐渐升高,胁迫后期活性下降;超氧阴离子(O-2.)、丙二醛(MDA)和可溶性蛋白含量呈现出先升后降的趋势;质膜相对透性呈现出"抛物线"的变化。干旱胁迫早期由于O-2等活性氧的增加而启动活性氧清除系统进行清除,是抵御干旱的一种协同反应;后期反叶扭口藓依然保持较强的自由基清除能力,具有极强的耐旱能力。     

干旱胁迫下小麦叶片微粒体活性氧自由基的产生及其对膜的伤害

从不同干旱胁迫时间下的小麦(Triticum aestivum L.)叶片中提取微粒体膜,测定活性氧自由基变化和膜伤害程度。结果表明,随着干旱胁迫时间的延长发生以下变化:(1)O_2~-和H_2O_2的产生速率在一定时间内逐渐加快然后下降;(2)膜脂过氧化产物丙二醛(MDA)的含量逐渐增加;(3)微粒体膜上的SOD活性逐渐下降;(4)—SH基的含量在一定时间内逐渐增多以后下降;(5)与膜伤害程度有关的生理指标如根系电导率、叶片水势及其含水量等均有变化。     

沙芥属植物活性氧清除系统对干旱胁迫的响应

以沙芥属植物沙芥和斧形沙芥幼苗为试材,采用盆栽控水干旱方法,分析其在不同干旱胁迫强度下根和叶的活性氧水平、抗氧化酶活性和抗氧化剂含量的变化,并利用隶属函数法和抗旱系数法综合评价沙芥和斧形沙芥的抗旱性。结果表明: （1）随着干旱胁迫程度的加剧,沙芥和斧形沙芥的根和叶中O^-·₂产生速率及·OH、H₂O₂、MDA含量总体呈逐渐升高的趋势,且干旱胁迫下沙芥比斧形沙芥产生了更多的ROS和MDA。（2）随着干旱胁迫程度的加剧,沙芥和斧形沙芥的根和叶中POD、APX、GST活性及叶中GR活性均先升高后降低,叶中的SOD活性以及根中GR、GPX活性均先降低后升高,根和叶中的CAT活性、叶中的GPX活性和根中SOD活性均逐渐升高;但根和叶中的SOD、POD、CAT活性在各干旱处理下均表现为斧形沙芥高于沙芥。（3）沙芥和斧形沙芥的根和叶中AsA含量随着干旱胁迫程度的加剧而先升高后降低,GSH含量逐渐升高,CAR含量逐渐降低,而VE含量在叶中逐渐升高,在根中却逐渐降低;但斧形沙芥比沙芥合成更多的AsA和GSH,其植物体内AsA GSH循环系统能清除更多的ROS。（4）沙芥和斧形沙芥的根和叶中总抗氧化能力（T AOC）均随着干旱加剧逐渐增强,且斧形沙芥的总抗氧化能力强于沙芥;活性氧清除系统的平均隶属度和综合抗旱系数显示,轻度干旱胁迫下沙芥抗旱性强于斧形沙芥,中度和重度干旱胁迫下斧形沙芥的抗旱性强于沙芥。研究认为,在干旱胁迫条件下,斧形沙芥根叶中ROS和MDA含量明显低于沙芥,而其大部分抗氧化酶活性和抗氧化剂含量高于沙芥,斧形沙芥植株体内抗氧化系统表现出更强的活性氧清除能力,从而表现出更强的抗旱性。     

NaCl胁迫下离体小鼠叶片内抗坏血酸与几种生理生化指标变化的…

随着ＮａＣｌ胁迫时间的延长和胁迫强度的增加，离体小麦叶片内抗坏血酸含量逐渐减少。活性氧清除剂处理可缓解由ＮａＣｌ胁迫所引起的抗坏血酸含量下降。ＮａＣｌ胁迫下，叶片内Ｏ＾－２和ＭＤＡ含量增加，叶绿素和类胡萝卜素含量，叶绿体的Ｈｉｌｌ反应活力，叶生光合速率，叶片和线粒体呼吸速率的下降，而外源抗坏血酸对这些过程均有缓解作用。     

六种藓类植物茎的比较解剖学研究

通过对6种藓类植物,即褶叶青藓(Brachythecium salebrosum(Web.et Mohr.)B.S.G.)、湿地匐灯藓(Plagiomnium acutum(Lindb.)Kop.)、侧枝匐灯藓(Plagiomnium maximoviczii(Lindb.)Kop.)、大凤尾藓(Fissidensnobilis Griff.)、大羽藓(Thuidium cymbifolium(Doz.et Molk.)B.S.G.)和大灰藓(Hypnum plumaeforme Wils.)嫩茎和老茎的石蜡切片和显微观察发现,同一藓类植株的嫩茎和老茎,茎结构稳定,不同种藓类植物茎横切面具有不同特征.植物体茎横切面形状、表层细胞的层数、细胞大小和细胞壁厚薄、皮层细胞大小和形状、中轴的有无以及比例等特征可以作为藓类植物的分科分类依据之一.     

Photoregulation of seed germination of wild-type and of an aurea-mutant of tomato

Seed germination of an aurea mutant of tomato ( Lycopersicon esculentum Mill.) is promoted by continuous irradiation with red, far-red or long-wavelength far-red (758 nm) light as well as by cyclic irradiations (5 min red or 5 min far-red/25 min darkness). Far-red light applied immediately after each red does not change the germination behaviour. Seed germination of the isogenic wild-type, cv. UC-105, is promoted by continuous and cyclic red light while it is inhibited by continuous and cyclic far-red light and by continious 758 nm irradiation. Far-red irradiation reverses almost completely the promoting effect of red light. The promoting effect (in the aurea mutant) and the inhibitory effect (in the wild-type) of continuous far-red light do not show photon fluence rate dependency above 20 nmol m⁻² s⁻¹. It is concluded that phytochrome controls tomato seed germination throgh low energy responses in both the wild type and the au mutant. The promoting effect of continuous and cyclic far-red light in the au mutant can be attributed to a greater sensitivity to P_fr.     

Cause of Senescence of Nine Sorts of Flowers

The levels of endogenous phytohormones and respiratory rate in nine sorts of flowers such as Cymbidium faberi Rolfe, Nopalxochia ackermannii Kunth and others were investigated both at full bloom and senescence and meanwhile the effect of exogenous phytohormones on prolonging the blossoms and promoting ethylene production were tested. There is a high content of endogenous ethylene in all the long-lived flowere, about 3–16 folds higer than the short-lived ones. There is a high level of ABA at full blooming flowers of short-lived flowers, in which there is no or only some cytokinins in it, but the ratio of CTK (6BA+zeatin)/ABA is smaller(l.7). The endogenous ABA reached a much higher level at senescence in all nine sorts of flowers, so it is reasonable to consider that it is ABA which plays an important role of regulation in controlling flower's senescence. There is a much higher level of GA3 and zeatin in the long-lived flowers which is not demonstrated in the shortlived ones. The respiratory rate is one of the factors controtling the longevity of flowers, but it does not play a decided role. Application of 6BA and zeatin prolongs distinctly orchid’s longevity, however exogenous IAA through the promotive action on ethylene production, evidently extends the longevity of the flowers of the Nopalxochia ackermannii Kunth.     

龙胆科药用植物化学成分的研究现状

龙胆科植物在我国的分布范围很广,且多数为药用植物,其多数种属的药用植物,至今其化学成分尚未被系统研究。综述了目前龙胆科药用植物的化学成分的研究现状及一般提取方法,对近年来发现的环烯醚萜及裂环烯醚萜类化合物进行了总结,为本科药用植物的更深入研究提供了参考。     

Interconnection of parameters of regulation system of lipid peroxidation and of morphophysiological parameters of mouse liver

A complex analysis of seasonal fluctuations of the mean group parameters of the system of regulation of lipid peroxidation has been performed in liver of Balb/c mice. Association of lipid characteristics and morphophysiological parameters is studied in the Balb/c mouse liver. An inter-connection is revealed between the liver index and the amount of lysoforms of phospholipids, the scale and character of the interconnection differing essentially depending on proportion of phos-phatidylcholine in mouse liver phospholipids.     

The effects of glutamine of the maintenance of embryogenic cultures of Cryptomeria japonica

Summary Embryogenic tissues of sugi (Cryptomeria japonica) were induced on a modified Campbell and Durzan (CD) medium containing 1 μM 2,4-dichlorophenoxyacetic acid (2,4-D) and 600 mg l⁻¹ glutamine, and subcultured in the medium of the same composition for over 1 yr. This resulted in a mixed culture of embryogenic and non-embryogenic cells. When embryogenic cells were isolated and cultured independently, their capacity to form embryogenic aggregates was lost. Thus, the non-embryogenic cells present within a mixed culture system were essential to the formation of embryogenic aggregates. When embryogenic tissues were isolated and cultured independently on a high glutamine-containing (2400 mg l⁻¹) medium, dry weights and endogenous levels of glutamine increased, and the tissue could generate a large number of embryogenic aggregates. Amino acid analysis of embryogenic and non-embryogenic cells from the maintenance culture indicated a higher level of glutamine was present in the latter. The high endogenous level of glutamine in the non-embryogenic portion of mixed cell masses may be the supplier of glutamine for maintaining the embryogenic property of the tissues.     

Specificity of action of piperidylcholine derivatives as substrates of cholinesterases of various origin

The review deals with study of enzymologic properties of a novel highly specific acetylcholinesterase substrate, N-(β-acetoxyethyl) piperidinium iodomethylate (“piperidylcholine”), and its 30 derivatives that were tested as effectors of cholinesterases of mammals and various species of Pacific squids. It was proven for the first time that responsible for specificity of action was structure of cyclic ammonium grouping of the alcohol part of molecule of the ester substrate. Analysis of specificity is performed based on enzymatic hydrolysis parameters—activity of catalytic center of cholinesterases and bimolecular constant of the reaction rate that are determined at optimal and low substrate concentrations. Among the specially synthesized group of thioester compounds there is revealed one more highly specific acetylcholinesterase substrate—N-(β-acetoxyethyl) piperidinium.     

Physiological characteristics of various species of strains of carboxydobacteria

Seven strains of aerobic carbon monoxide-oxidizing bacteria (carboxydebacteria) when growing on CO as sole source of carbon and energy had doubling times which ranged from 12–42 h. The activity profiles obtained after discontinuous sucrose density gradient centrifugation indicated that the CO-oxidizing enzymes are soluble and the hydrogenases are membrane-bound in all strains examined. The CO-oxidizing enzymes of Pseudomonas carboxydohydrogena, Pseudomonas carboxydoflava, Comamonas compransoris, and the so far unidentified strains OM2, OM3, and OM4 had a molecular weight of 230,000; that of Achromobacter carboxydus amounted to 170,000. The molecular weights of the CO-oxidizing and H₂-oxidizing enzymes turned out to be identical. The cell sonicates were shown to catalyze the oxidation of both CO and H₂ with methylene blue, thionine, phenazine methosulfate, toluylene blue, dichlorophenolindophenol, cytochrome c or ferricyanide as electron acceptors. Methyl viologen, benzyl viologen, FAD⁺, FMN⁺, and NAD(P)⁺ were not reduced. The spectrum of electron acceptors was identical for all strains tested. Neither free formate, hydrogen nor oxygen gas were involved in the CO-oxidation reaction. Methylene blue was reduced by CO at a 1:1 molar ratio. The results indicate that CO-oxidation by carboxydobacteria is catalyzed by identical or similar enzymes and that the reaction obeys the equation CO+H₂OCO₂+2H⁺+2e^- as previously shown for Pseudomonas carboxydovorans.Dedicated to Otto Kandler remembering almost three decades of enjoyable cooperation     

Modulation of allostery of pyruvate kinase by shifting of an ensemble of microstates

Since the introduction of the concepts of allostery about four decades ago, much advancement has been made in elucidating the structure-function correlation in allostery. However, there are still a number of issues that remain unresolved. In this review we used mammalian pyruvate kinase (PK) as a model system to understand the role of protein dynamics in modulating cooperativity. PK has a triosephosphate isomerase (TIM)(α/β)₈ barrel structural motif. PK is an ideal system to address basic questions regarding regulatory mechanisms about this common (α/β)₈ structural motif. The simplest model accounting for all of the solution thermodynamic and kinetic data on ligand-enzyme interactions involves two conformational states, inactive E^T and active E^R. These conformational states are represented by domain movements. Further studies provide the first evidence for a differential effect of ligand binding on the dynamics of the structural elements, not major secondary structural changes. These data are consistent with our model that allosteric regulation of PK is the consequence of perturbation of the distribution of an ensemble of states in which the inactive E^T and active E^R represent the two extreme end states. Sequence differences and ligands can modulate the distribution of states leading to alterations of functions. The future work includes: defining the network of functionally connected residues; elucidating the chemical principles governing the sequence differences which affect functions; and probing the nature of mutations on the stability of the secondary structural elements, which in turn modulate allostery.