F-box蛋白质在植物生长发育中的功能

在真核生物中, 泛素介导的蛋白降解途径参与了许多生物学过程。SCF复合体是一种非常重要的E3泛素连接酶, 在植物中研究的最为深入。F-box蛋白包含一个F-box 基序, 是SCF复合体的一个亚基, 它决定了底物识别的特异性。目前, 从各种植物中已鉴定出大量的F-box蛋白质, 它们参与了植物激素(乙烯, 生长素, GA, JA)的信号传导以及自交不亲和、花器官发育等生物学过程, F-box蛋白还参与了植物的胁迫反应。最新研究结果显示, 一个F-box蛋白TIR1是生长素的受体。因此, F-box蛋白质介导的泛素化蛋白质降解途径可能是植物基因表达调控的重要机制。     

Studies on Genetic Male-Sterile Soybeans: I. Distribution of Plant Carbohydrate and Nitrogen during Development

Soybeans (Glycine max [L.] Merr. cv. NC 69-2774) were used to study the nonstructural carbohydrate and nitrogen content of plant tissues, and nitrogenase activity throughout the development of male-sterile and male-fertile plants. Male-sterile plants set approximately 85% fewer pods plus seed than the male-fertile siblings and retained green leaves until a killing frost at 145 days after emergence. Reduced pod set caused increased carbohydrate accumulation in the leaf and root systems of male-sterile plants. Total carbohydrate in roots of male-sterile plants increased from 1.7 to 7.6 times that in the male-fertile roots. A high proportion (60 to 70%) of the male-sterile root carbohydrate was starch. Apparently, root starch was not metabolized by the male-sterile plants. Late in plant development per cent nitrogen was higher in the male-sterile soybean tissues. However, no difference was found in the ability of the nodulated root systems from either genotype to fix nitrogen.     

Differential Protein Accumulation during Barley Grain Development

Barley grains were analysed during development for the presenceof salt-soluble proteins, hordeins and glutelins. Characteristictemporal differences between the fractions were observed withhordeins being produced relatively late during maturation. Analysisof this fraction by gel electrophoresis revealed differentialaccumulation of its component polypeptides. The C hordeins madeup a relatively higher percentage of total hordein at the earlystages, decreasing from 20% of the total at 33% final dry weightto 15% at maturity. The relative amount of the lowest molecularweight B hordein band (Bl) increased throughout developmentfrom 30% of the total at 33% final dry weight to about 45% atmaturity. Electrophoresis of the salt-soluble fraction showedthat a group of low molecular weight polypeptides appeared atthe same stage of development as did the hordeins. There wereonly relatively minor changes in the polypeptide compositionof the glutelin fraction.     

F-box蛋白在植物生长发育中的功能研究进展

在真核生物中,由泛素介导的蛋白降解途径与植物生长发育密切相关。F-box蛋白家族是一类含有Fbox基序(motif),在泛素介导的蛋白质水解过程中具有底物识别特性的蛋白质家族。目前,从各种植物中已鉴定出大量的F-box蛋白质,这类蛋白质在植物激素的信号转导、光信号转导、自交不亲和以及花器官发育等许多生理过程中都具有重要功能。研究发现F-box蛋白在调控植物生长发育过程中所发挥的功能与其结构及泛素蛋白酶体途径密切相关。     

Storage Protein Synthesis during Oat (Avena sativa L.) Seed Development

Oat (Avena sativa L.) seeds harvested at 2-day intervals from anthesis to maturity were tested for their ability to incorporate [³⁵S]sulfate into protein. Incorporation of [³⁵S]sulfate into TCA-insoluble material began 2 to 4 days postanthesis (DPA), reached a peak 14 to 16 DPA, and was barely detectable by 24 DPA. Incorporation of label into globulin was parallel to total protein accumulation, and averaged about 85% of the total protein synthesis. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of total protein extracted from developing seeds indicated that some polypeptides coinciding with the α and β globulin subunits were present 2 to 4 DPA, but the full complement of globulin polypeptides was not present until 10 DPA. Immunoprecipitation of in vivo labeled seed extracts showed that globulin polypeptides and the 59 kilodalton precursor were present at early stages of development (4 DPA). Quantitation of dot blot analysis, using an oat globulin cDNA clone as a probe, indicated that one species of oat globulin mRNA was most abundant 15 DPA, which is during the peak time of storage protein synthesis.     

平茬高度对香椿生长及其光合特性和非结构性碳水化合物含量的影响

该研究以4年生香椿为试验材料,设置平茬20 cm(T₁)、50 cm(T₂)、80 cm(T₃)和不平茬(CK)4种处理,观测其萌枝和叶片生长情况,以及叶片的气体交换参数、光合色素含量、非结构性碳水化合物(NSC)含量的变化,分析不同平茬高度的生长生理响应差异,以明确平茬措施下香椿植株更新复壮再生的生理机制。结果表明：(1)平茬能够显著提高香椿的萌枝能力,促进侧枝和叶片生长,其萌枝数、侧枝长度在T₃处理下最高,成枝数、叶长、叶宽、叶面积及侧枝粗度在T₂处理下达到最大值。(2)随着平茬高度的增加,香椿叶片净光合速率、蒸腾速率、气孔导度和水分利用效率均先升后降,并在T₂处理达到最大,较CK分别显著提高了17.33%、10.00%、13.51%和6.98%;平茬也提高了叶片光合色素含量,叶绿素a、叶绿素b、总叶绿素含量和类胡萝卜素含量在T₂处理下分别比CK显著提高了18.34%、27.07%、21.11%和23.05%。(3)不同平茬高度处...     

植物类受体蛋白参与植物生长与发育的研究进展

类受体蛋白(receptor-like protein,RLP)广泛存在于高等植物中,其家族在拟南芥中有57个成员。研究表明RLP蛋白参与了植物茎尖分生组织(shoot apical meristem,SAM)、根尖分生组织(root apical meristem,RAM)和维管分生组织等器官的生长与发育过程,例如CLV2(CLAVATA2)和FEA2(FASCINATED EAR2)参与了分生组织的维持与分化和其他器官的发育、TMM(TOO MANY MOUTHS)则介导了植物表皮细胞的分裂和气孔分布。另一方面,RLP蛋白在植物抗病中发挥着重要作用,包括番茄抗叶霉菌Cf类蛋白、番茄抗黑白轮枝菌Ve1和Ve2以及番茄应答非致病绿色木霉菌激发子的抗病蛋白LeEix等。同时,研究表明RLP蛋白在细胞间信号的接受与传递过程中起着极为重要的作用。本文综述了近年来对植物类受体蛋白参与植物生长与发育的功能、信号识别、传输与转导等方面的研究进展。     

DELLA家族蛋白与植物生长发育的关系

赤霉酸(GA)同细胞膜上的受体结合后,通过一系列信号分子,把信号传递到下游,以调节植物的生长发育.在已发现的植物GA信号传递分子中,有一类的N端具有高度保守的DELLA结构域,称之为DELLA家族蛋白.文中介绍了此类蛋白作为阻遏蛋白,对植物生长发育的调控作用及其行使阻遏作用的分子机制.     

Regrowth by Swards of Subterranean Clover after Defoliation. 1. Growth, Non-structural Carbohydrate and Nitrogen Content

Swards of subterranean clover (Trifolium subterraneum L.) atLAl 6 grown in N-free nutrient solution were subjected to threedefoliation treatments which removed 30, 70 and 80% of shootdry weight. Subsequent regrowth and changes in the concentrationsof carbohydrate and nitrogen in plant components were measuredat 0, 1, 5, 9 and 13 d after defoliation and compared with thosein uncut swards. The rate of shoot regrowth declined with increasing severilyof defoliation. In all defoliation treatments, growth was confinedto leaves for up to 5 d. Root growth ceased in all treatmentsfor a longer period. Reestablishment of the leaf area in severely-defoliatedswards was facilitated by the rapid opening of developing leavesand by changes in the allocation of carbon which favoured leafover branch and root, and lamina over petiole growth. Loss of carbohydrate and nitrogen from roots and branches lasting5–9 d was observed in the more severe defoliation treatments.Loss of protein (N x 6.25) exceeded that of total non-structuralcarbohydrate, and could have accounted for the nitrogen contentof new leaf during this period. Branches lost 62% of their initialcarbohydrate content compared with 25% from roots in the 80%cut swards. In contrast, roots, by virtue of their greater mass,were the principle source of mobilized nitrogen. Nitrogen accumulationceased in 80% cut swards for 9 d. However, carbohydrate levelsin the crown nodules were not severely depleted. It was concluded that partitioning of growth to lamina and themobilization of carbohydrates and nitrogen were important forrecovery from defoliation. Carbohydrates, carbon partitioning, defoliation, nitrogen, mobilization, regrowth, subterranean clover, Trifolium subterraneum L     

Effect of High Temperature on Plant Growth and Carbohydrate Metabolism in Potato

This study was undertaken to determine the role of sucrose-metabolizing enzymes in altered carbohydrate partitioning caused by heat stress. Potato (Solanum tuberosum L.) genotypes characterized as susceptible and tolerant to heat stress were grown at 19/17[deg]C, and a subset was transferred to 31/29[deg]C. Data were obtained for plant growth and photosynthesis. Enzyme activity was determined for sucrose-6-phosphate synthase (SPS) in mature leaves and for sucrose synthase, ADP-glucose pyrophosphorylase, and UDP-glucose pyrophosphorylase in developing tubers of plants. High temperatures reduced growth of tubers more than of shoots. Photosynthetic rates were unaffected or increased slightly at the higher temperature. Heat stress increased accumulation of foliar sucrose and decreased starch accumulation in mature leaves but did not affect glucose. SPS activity increased significantly in mature leaves of plants subjected to high temperature. Changes in SPS activity were probably not due to altered enzyme kinetics. The activity of sucrose synthase and ADP-glucose pyrophosphorylase was reduced in tubers, albeit less quickly than leaf SPS activity. There was no interaction of temperature and genotype with regard to the enzymes examined; therefore, observed differences do not account for differences between genotypes in heat susceptibility.     

类脂对植物生长和发育的作用

简述了类脂在植物生长和发育中的作用,特别是类脂中脂肪酸的饱和度对植物生长发育的影响,植物固醇对植物的表型和在低温下的生长、胚胎的发育以及可育性中的作用.     

膨胀素在植物生长发育中的作用

膨胀素是一类具有非水解活性的细胞壁松弛蛋白,参与植物生长发育过程中细胞壁的修饰。大多数植物中都发现有膨胀素基因家族成员存在,其功能涉及植物生长发育的各个方面,包括营养生长、形态发生、受精授粉、果实成熟等,并表现出高度的组织、器官和细胞特异性。本文综述膨胀素在种子萌发、叶的发育、根茎生长、花的发育等生长发育过程中的作用。     

燕麦植株生长及叶片生理活性对土壤镉胁迫的响应

该研究以燕麦品种‘燕科2号’(籽粒镉积累量高,Yh)和‘200919 7 1’(籽粒镉积累量低,Yl)为材料,采用盆栽试验,在土壤Cd胁迫条件下测定两种类型燕麦植株生长、叶片光合生理参数及抗氧化酶活性的变化,探讨两品种对Cd胁迫的响应差异。结果表明：(1)Cd胁迫条件下,燕麦品种Yh和Yl植株生长、气体交换参数及叶绿素荧光参数均受到抑制,并以单株干重、叶片净光合速率(P_n)、光化学淬灭系数(qP)表现最为突出,Yh的降幅分别为38.2%、35.0%、14.7%,Yl降幅分别为40.8%、57.1%、27.3%。(2)镉胁迫均诱导增强了两个类型燕麦品种叶片抗氧化酶活性,尤其是SOD活性得到显著增强,Yh和Yl的增幅分别为41.9%和44.9%; Cd胁迫也显著提高了MDA含量,Yh和Yl的增幅分别达到22.2%和18.1%。研究发现,在Cd胁迫条件下,与低Cd积累燕麦品种相比,高Cd积累燕麦品种具有较高的生物量和抗氧化酶活性,以及较强的净光合速率和优异的叶绿素荧光特性,从而表现出较强的耐Cd性。     

不同小麦品种植株地上部Cu的积累和分配规律研究

以'长5864'、'济麦20'和'中普绿麦1号'3个小麦品种为材料,研究了常规大田种植条件下植株地上部Cu的积累分配规律.结果表明:(1)随生育期推进,小麦叶片和叶鞘Cu含量在前期呈波动变化,于起身期(或拔节期)出现峰值之后逐渐降低,其茎秆、穗部和籽粒中Cu含量则持续下降.(2)小麦植株地上部Cu的积累量在三叶期-返青期增长缓慢,返青期-抽穗期急剧增长,抽穗期-灌浆末期缓慢增加,并以拔节期-抽穗期为Cu积累高峰期;叶片、叶鞘、茎秆及穗轴+颖壳中Cu的积累量在抽穗期(或灌浆初期)达到峰值,籽粒Cu积累量则持续增加.(3)灌浆末期,植株地上部各器官Cu含量以叶片最高,穗轴+颖壳最低;Cu积累量以籽粒最高,穗轴+颖壳最低;籽粒中Cu的分配比例为51.20%,其主要来自营养器官的转移,并以茎秆Cu对籽粒的贡献率最高.(4)小麦植株地上部Cu的含量和积累量存在品种间差异,其中'中普绿麦1号'植株Cu含量较高,而'长5864'植株Cu积累量较高.     

文心兰花芽分化过程中糖类和蛋白质的组织化学定位

以文心兰‘milliongolds’不同发育阶段的花芽为试材,研究糖类和蛋白质在文心兰花芽分化过程中的变化。经石蜡切片高碘酸席夫反应法（PAS法）和汞溴酚蓝组织化学染色观察发现,糖类和蛋白质主要以颗粒状分布在各器官的原基顶端及其周围。在花序原基分化期,细胞中糖含量较少,而蛋白质含量丰富且整体分布均匀。随着花芽的继续分化,糖和蛋白质含量在花萼原基分化期最为丰富,在花瓣原基时期含量明显减少;进入合蕊柱及花粉块分化期时,糖和蛋白质在合蕊柱及花粉块着生处最为集中。在文心兰花发育过程中,对不同分化时期中花芽的糖和蛋白质含量进行测定,表明糖和蛋白质含量的变化趋势与组织化学定位相一致。     

白掌新品种的引进与栽培管理

本文阐述5个白掌新品种形态特征及生长习性,同时介绍其栽培管理技术。     

The Metabolism of Oat Leaves during Senescence: I. Respiration, Carbohydrate Metabolism, and the Action of Cytokinins

When the detached first leaves of green or etiolated oat (Avena sativa cv. Victory) seedlings senesce in the dark, their oxygen consumption shows a large increase, beginning after 24 hours and reaching a peak of up to 2.5 times the initial rate by the 3rd day. This effect takes place while the chlorophyll of green leaves, or the carotenoid of etiolated leaves, is steadily decreasing. Kinetin, at a concentration which inhibits the decrease in pigment, completely prevents the respiratory rise; instead, the oxygen consumption drifts downwards. Lower kinetin concentrations have a proportional effect, 50% reduction of respiration being given by about 0.1 mg/l. About one-fifth of the respiratory rise may be attributed to the free amino acids which are liberated during senescence; several amino acids are shown to cause increases of almost 50% in the oxygen consumption when supplied at the concentrations of total amino acid present during senescence. A smaller part of the rise may also be due to soluble sugars liberated during senescence, largely coming from the hydrolysis of a presumptive fructosan. The remainder, and the largest part, of the increase is ascribed to a natural uncoupling of respiration from phosphorylation. This is deduced from the fact that dinitrophenol causes a similar large rise in the oxygen consumption of the fresh leaves or of leaf segments kept green with kinetin, but causes only a very small rise when the oxygen consumption is near its peak in senescent controls. The respiration of these leaves is resistant to cyanide, and 10 mm KCN even increases it by some 30%; in contrast, etiolated leaves of the same age, which undergo a similar rise in oxygen consumption over the same time period, show normal sensitivity to cyanide. The respiratory quotient during senescence goes down as low as 0.7, both with and without kinetin, though it is somewhat increased by supplying sugars or amino acids; glucose or alanine at 0.3 m bring it up to 1.0 and 0.87, respectively.     

Effect of Restricted Root Growth on Carbohydrate Metabolism and Whole Plant Growth of Cucumis sativus L

The effects of varied rooting volumes on root growth and source leaf carbohydrate metabolism were studied in greenhouse-grown cucumber (Cucumis sativus L cv Calypso) plants. Plants were grown for 7 weeks in container volumes that ranged from 0.4 to 5.9 liters. Plants grown in the smaller containers exhibited less leaf expansion, lower root and shoot weight, and fewer lateral stems than plants grown in the 5.9 liter containers. Shoot/root ratio was not altered by the container volume, suggesting coordination of root and shoot growth due to rooting volume. Source leaf carbon exchange rates, assimilate export rates, and starch accumulation rates for plants grown in 0.4 liter containers were approximately one-half or less in comparison to those for plants grown in 5.9 liter containers. Starch concentrations per unit leaf area were maintained at high levels in source leaves of plants grown in 0.4 liter containers over the entire day/night cycle. Lower extractable galactinol synthase activities and higher galactinol concentrations occurred in leaves of plants grown in 0.4 liter container volumes. The reduced sink demand, induced by restricted root growth, may have led to increased starch concentrations and to a reduction in stachyose biosynthesis in cucumber source leaves.     

The Development of Wheat Grain in Relation to Endogenous Growth Substances

Changes in the endogenous gibberellins and abscisic acid ofthe developing grains of Triticum aestivum L. have been studiedin relation to growth of the grain. The maximum grain volumeis inversely related to temperature and is reached while thedry weight is still small. This stage is associated with a sharpincrease in gibberellins. Starch formation is the principalfeature of the next stage of development and this ceases shortlyafter the beginning of a period of rapid water loss. This waterloss is preceded by an increase in the abscisic acid content.Changes in the endosperm are associated with changes in thebiochemical and physical attributes of the pericarp; these alsohave been correlated with changes in growth substances. Theresults are related to the ripening process and the final dryweight of the grain.