磷酸化酶mRNA在水稻雌蕊中表达的时空动态

利用RNA原位杂交技术, 对水稻受精前后雌蕊组织切片进行磷酸化酶基因表达的定位。结果显示, 磷酸化酶mRNA在柱头、花柱、子房壁以及维管束中大量表达, 而胚珠中除合点部位外表达很弱。受精前后的胚囊中各细胞磷酸化酶mRNA表达也很弱, 并且没有明显的时空变化。在积累淀粉的胚乳细胞中磷酸化酶mRNA大量分布。原胚中的磷酸化酶mRNA表达较弱, 到分化胚积累过渡性淀粉时才显著增加。本文首次对磷酸化酶mRNA在植物雌性器官发育过程中的时空分布动态作了初步研究。 Abstract:Phosphorylase gene expression was localized in tissue sections of rice pistils before and after fertilization byin situRNA hybridization. Phosphorylase mRNA was substantially expressed in the stigma, style, ovary wall and vascular bundle, but weakly in ovular tissues except chalazal portion. It was weakly expressed and did not show temporal and spatial changes in embryo sacs before and after fertilization. A great quantity of phosphorylase mRNA was distributed in endosperm cells accumulating starch grains. Phosphorylase mRNA was less in proembryos, but significantly increased in differentiation embryos accumulating transition starch. This report is, for the first time, a tentative investigation on the temporal and spatial expression patterns of phosphorylase mRNA in plant female organ development.     

钙调素mRNA在受精前后分离的烟草胚囊中的定位

建立了一种新的ｍＲＮＡ原位杂交方法,适用于微量材料的整体观察。应用这一方法定位烟草（ＮｉｃｏｔｉａｎａｔａｂａｃｕｍＬ．ｃｖ．Ｗ３８）受精前后胚囊成员细胞中的钙调素ｍＲＮＡ（ＣａＭｍＲＮＡ）。结果显示成熟胚囊中的ＣａＭｍＲＮＡ主要分布于珠孔极的卵器和合点极的反足细胞;中央细胞中较少。受精前后胚囊中ＣａＭｍＲＮＡ的分布发生显著变化,特别是授粉后到受精前极核与卵器之间出现一条暂时的钙调素ｍＲＮＡ条带。受精前不久该带消失,ＣａＭｍＲＮＡ扩展为占据胚囊珠孔端的扇形区域。受精后胚囊中钙调素ｍＲＮＡ主要集中于伸长的合子和原胚的合点端。讨论了钙调素ｍＲＮＡ表达与受精的关系。     

钙调素mRNA和蛋白在水稻花药和雌蕊发育过程中的原位定位

利用ＲＮＡ原位杂交和免疫组织化学定位技术分别检测了钙调素ｍＲＮＡ和钙调素蛋白在水稻（ＯｒｙｚａｓａｔｉｖａＬ．）花药和雌蕊发育过程中的时空分布特征。钙调素基因在绒毡层、柱头、花粉管生长途径、退化助细胞以及维管薄壁细胞中大量表达,也可在小孢子母细胞、小孢子、花粉、反足细胞、卵细胞以及中央细胞中检测到。钙调素基因的表达强度随不同的发育阶段而变化：花药发育早期表达强,以后逐渐减弱并向特定部位集中,如绒毡层和花粉萌发孔等。胚胎发育早期,钙调素基因在胚乳细胞中的表达比原胚中强,而后期则在分化胚中比胚乳细胞中强。推测在有性生殖过程中,钙调素可能通过Ｃａ２＋ＣａＭ信号途径调节小孢子发育、花粉萌发、花粉管生长、受精以及物质运输等生理过程     

与授粉有关的因子调节的乙烯生物合成基因在兰花花器官中的表达

分析了与授粉有关的因子调节的ＡＣＣ合酶和ＡＣＣ氧化酶基因在朵丽蝶兰（ＤｏｒｉｔａｅｎｏｐｓｉｓｈｙｂｒｉｄａＨｏｒｔ．）花中的表达。生长素和乙烯均可诱导ＡＣＣ合酶和ＡＣＣ氧化酶的ｍＲＮＡ在花器官中积累。然而,去雄却不能诱导这两个基因在花器官中表达。生长素和乙烯所诱导的ＡＣＣ合酶和ＡＣＣ氧化酶的ｍＲＮＡ在花器官中的积累模式相似。原位杂交结果表明,生长素和乙烯处理后ＡＣＣ氧化酶的ｍＲＮＡ在柱头的表皮和薄壁细胞中积累。根据ＡＣＣ合酶和ＡＣＣ氧化酶基因表达的结果,对生长素、乙烯和去雄在兰花授粉后乙烯生物合成过程中的作用进行了分析。     

间隙连接蛋白Cx43在人胚肺和肺癌细胞表达的研究

细胞与细胞之间通过细胞膜上的间隙连接通道交换小分子和离子进行细胞间通讯,对细胞增殖分化调控和机体内环境稳定有重要作用。用间隙连接蛋白Ｃｘ４３ｃＤＮＡ探针Ｎｏｒｔｈｅｒｎ印迹杂交,Ｃｘ４３抗体免疫荧光染色和罗氏黄荧光染料传输方法检查,正常人胚肺细胞的Ｃｘ４３在ｍＲＮＡ和蛋白水平有高表达,Ｃｘ４３蛋白免疫荧光分布在间隙连接的部位,细胞间隙连接通讯功能明显。与正常相反,人肺癌ＰＧ系细胞Ｃｋ４３无论在ｍＲＮＡ或蛋白质水平都无表达,细胞通讯功能缺陷。结果表明Ｃｘ４３在培养的人胚肺细胞有功能性表达。人肺癌ＰＧ细胞通讯功能缺陷与Ｃｘ４３基因转录抑制有关。对Ｃｘ基因的抑癌基因性质进行讨论。     

莴苣卵细胞、合子与原胚细胞中钙的分布

用焦锑酸盐沉淀法对莴苣开花前后的卵细胞、合子与原胚细胞中的钙颗粒分布变化进行了观察。结果表明,开花前三天,刚形成的卵细胞内钙颗粒很少,开花前二天的卵细胞内钙颗粒开始增多,开花前一天的卵细胞形成了大液泡,建立了极性,细胞内的钙颗粒又减少。开花后、受精前的卵细胞的钙颗粒主要聚集在细胞核中。受精后合子中的钙颗粒又明显增多,在核质中分布一些较大的钙颗粒,在珠孔端大液泡中聚集了较多的絮状钙。二胞原胚中的钙颗粒又开始减少,多胞原胚细胞中的钙进一步减少,但原胚表面分布一层丰富的钙颗粒。探讨了钙在卵细胞分化成熟、受精以及原胚发育初期中的作用。     

着床期小鼠子宫内膜中EGF及其受体转录和表达状况的研究

为探讨表皮生长因子（epidermal growth factor,EGF)在胚泡着床过程中的作用。本文应用原位杂交和免疫组织化学方法,检测了EGE及其受体在胚泡着床前后小鼠子宫内膜中的转录和表达。结果显示：未孕和受精后第4-5天,子宫内膜表面上皮和腺上皮细胞仍呈EGF,EGFR原位杂交和免疫组化阴性着色,受精后第4-5天子宫内膜基质细胞EGF及其受体转录和表达较未孕期增强,受精后第6天,EGF及其受体免疫组化和原位杂交阳性着色主要分布于初级蜕膜带（primary decidual zone,PDZ);随着胚泡植入的进行,PDZ区蜕膜细胞EGF及其受体的转录和表达明显减少,而PDZ周围蜕膜细胞EGF及其受体的转录和表达增强,结果提示,EGF是小鼠胚泡着床过程中的一个重要调节因子。     

阿拉伯半乳糖蛋白在被子植物有性生殖中的作用

阿拉伯半乳糖蛋白(arabinogalactan-proteins,AGPs)是一类主要分布在细胞表面和胞外基质中的糖蛋白.它们在植物的雄性器官(花粉、花粉管、精细胞)、雌性器官(柱头、花柱、子房)和胚胎(合子胚和体细胞胚)等组织和细胞中均有大量的表达.大量研究表明AGPs在被子植物有性生殖过程中起着非常重要的作用,既可能参与花粉管粘附、营养、传导或提供信号的作用,也可能参与受精过程中配子识别和受精后胚胎的发育与分化等过程.该文就其分子结构、特性以及在植物有性生殖过程中各种器官和组织内的表达和功能研究进展做了较为全面的概述.     

白杄体细胞胚胎发生的细胞组织学和淀粉积累动态的研究

以白木千（ＰｉｃｅａｍｅｙｅｒｉＲｅｈｄ．ｅｔＷｉｌｓ．）的成熟种胚为外植体,诱导体细胞胚胎发生。整体染色封片和组织切片的观察结果表明,白木千体细胞胚起源于胚性愈伤组织的单个细胞。胚性细胞经过一次不均等分裂产生两个细胞,即胚细胞和胚柄细胞。然后依次经过胚性胚柄团、球形胚、心形胚及鱼雷形胚阶段,最后发育成具有子叶的成熟胚。通过ＰＡＳ反应研究后发现,在体细胞胚发育过程中,淀粉粒在胚性胚柄团时期开始积累,至心形胚时期达到积累高峰,且淀粉粒的分布主要集中于胚柄细胞、分裂旺盛的胚细胞、器官原基及其附近细胞。据此结果推测淀粉的消长与体细胞胚发生的能量供应有关。     

石刁柏非胚性细胞与体细胞胚胚体细胞的超微结构研究

对石刁柏（Ａｓｐａｒａｇｕｓｏｆｆｉｃｉｎａｌｉｓ）体细胞胚发生过程中细胞的超微结构进行了观察,非胚性细胞内液泡大,大量的自体吞噬泡出现,胚性细胞内细胞核大,核移中,核仁结构明显,线粒体、质体、核糖体、高尔基体、内质网等细胞器增多,淀粉、脂滴积累,有较活跃的自体吞噬现象,梨形细胞内质体向叶绿体转变。     

Inhibitory Effects of Diltiazem and Verapamil, Calcium Antagonists, on Fertilization-Induced Increase in the Phosphorylase Reaction in Echiuroid Eggs

The calcium antagonists diltiazem and verapamil at 100 μM caused considerable inhibition of the glycolysis system in recently fertilized eggs of the echiuroid, Urechis unicinctus . The levels of glycolytic intermediates in eggs were found to be higher 5 min after insemination than before fertilization while the levels of adenine nucleotides and inorganic phosphate were almost the same before and after fertilization. Addition of diltiazem or verapamil 30 sec after insemination did not inhibit fertilization, but resulted in maintenance of as low levels of glycolytic intermediates as in unfertilized eggs. The apparent mass action ratio in the phosphorylase step, calculated from the levles of glucose-1-phosphate and inorganic phosphate was normally higher in fertilized eggs than in unfertilized eggs, but was maintained at as low a level as in unfertilized eggs by adding these compounds 30 sec after insemination. Phosphorylase a activity also normally increased after insemination, but was maintained at a low level in fertilized eggs by adding these compounds. These compounds also inhibited the increased ⁴⁵Ca²⁺ uptake normally observed after fertilization. These results suggest that after fertilization, the Ca²⁺ level increases associated with fertilization-induced Ca²⁺ influx and that this stimulates Ca²⁺ dependent protein kinase to phosphorylate phosphorylase b , resulting in an increased rate of the phosphorylase reaction.     

A second L-type isozyme of potato glucan phosphorylase: cloning,antisense inhibition and expression analysis

In potato tubers two starch phosphorylase isozymes, types L and H, have been described and are believed to be responsible for the complete starch breakdown in this tissue. Type L has been localized in amyloplasts, whereas type H is located within the cytosol. In order to investigate whether the same isozymes are also present in potato leaf tissue a cDNA expression library from potato leaves was screened using a monoclonal antibody recognizing both isozyme forms. Besides the already described tuber L-type isozyme a cDNA clone encoding a second L-type isozyme was isolated. The 3171 nucleotide long cDNA clone contains an uninterrupted open reading frame of 2922 nucleotides which encodes a polypeptide of 974 amino acids. Sequence comparison between both L-type isozymes on the amino acid level showed that the polypeptides are highly homologous to each other, reaching 81–84% identity over most parts of the polypeptide. However the regions containing the transit peptide (amino acids 1–81) and the insertion sequence (amino acids 463–570) are highly diverse, reaching identities of only 22.0% and 29.0% respectively.Northern analysis revealed that both forms are differentially expressed. The steady-state mRNA levels of the tuber L-type isozyme accumulates strongly in potato tubers and only weakly in leaf tissues, whereas the mRNA of the leaf L-type isozyme accumulates in both tissues to the same extent. Constitutive expression of an antisense RNA specific for the leaf L-type gene resulted in a strong reduction of starch phosphorylase L-type activity in leaf tissue, but had only sparse effects in potato tuber tissues. Determination of the leaf starch content revealed that antisense repression of the starch phosphorylase activity has no significant influence on starch accumulation in leaves of transgenic potato plants. This result indicated that different L-type genes are responsible for the starch phosphorylase activity in different tissues, but the function of the different enzymes remains unclear.     

Glycosis in the eggs of the echiuroid, Urechis unicinctus and the oyster, Crassostrea gigas. Rate-limiting steps and activation at fertilization.

The content of glycolytic intermediates and of adenine nucleotides was measured in eggs of the echiuroid, Urechis unicinctus and the oyster, Crassostrea gigas, before and after fertilization. On the whole, the profile of the change in each glycolytic intermediate in Urechis eggs upon fertilization was found to be essentially similar to that in oyster eggs. Calculation of the mass action ratio for each glycolytic step from the amounts of glycolytic intermediates determined suggests that there are at least three limiting enzymes in the glycolysis system in unfertilized and fertilized eggs of each species examined. Phosphorylase (EC 2.4.1.1), phosphofructokinase (EC 2.7.1.11), and pyruvate kinase (EC 2.7.1.40) may be rate-limiting enzymes for the glycolysis system in Urechis eggs as well as in oyster eggs. These enzymes are thought to be activated upon fertilization, though even the reactions of the enzymes in fertilized eggs do not reach a state of equilibrium. In eggs of Urechis and oyster, phosphorylase is the first enzyme to be activated following fertilization. In Urechis eggs, pyruvate kinase is activated after the instant increase in the phosphorylase activity upon fertilization, followed by phosphofructokinase activation. In oyster eggs, however, pyruvate kinase and phosphofructokinase seem to be stimulated simultaneously, subsequent to phosphorylase activation upon fertilization. The mechanism controlling phosphorylase and pyruvate kinase activity is unknown, but the phosphofructokinase activity in both species may be regulated by the intracellular concentration of adenine nucleotides, since the enzyme activity is enhanced along with a decline in the phosphate potential in the eggs of both Urechis and of oyster.     

Phosphorylases I and II of Maize Endosperm

Two phosphorylases have been found in the endosperm of Zea mays. Phosphorylase I is found through all stages of endosperm development and seed germination investigated. The other enzyme, phosphorylase II appears only at the stage of rapid starch biosynthesis and is not found during germination. At 22 days after pollination, the activity of phosphorylase II is 10 times that of phosphorylase I. These 2 phosphorylases are separable by column chromatography and behave differently in several respects.     

Some properties of starch phosphorylase from cotyledons of germinating seeds of Voandzeia subterranea.

Two isoenzymes (Forms I and II) of starch phosphorylase (1,4-alpha-D-glucan: orthophosphate alpha-glucosyltransferase, EC 2.4.1.1) were found in cotyledons of germinating seeds of Voandzeia subterranea L. Thouars. Phosphorylase I, which was the major component, had a pH optimum of 5.5--5.6, whereas phosphorylase II had a pH optimum of 6.1--6.3. Phosphorylase I had a molecular weight of 204 000 +/- 4000 and a subunit molecular weight of about 95 000. Phosphorylase I was stimulated by Mg2+, Mn2+, AMP, cyclic AMP, pyruvate and EDTA, but inhibited by Fe2+, Cu2+, Zn2+ and ATP. Stimulation of phosphorulase I by AMP was accompanied by changes in the affinity of the enzyme for glucose-1-phosphate in the presence of increasing AMP concentrations, and of AMP in the presence of increasing glucose-1-phosphate concentrations. Double-reciprocal plots of initial velocity data were non-linear (convex up) at low glucose-1-phosphate concentrations but became linear in the presence of AMP or ATP. Double-reciprocal plots were linear at high glucose-1-phosphate concentrations in the absence or presence of modifiers.     

Kinetic properties of two starch phosphorylases from pea seeds

Both of the starch phosphorylase fractions from Victory Freezer pea seeds, that can be separated by DEAE—cellulose chromatography and purified by Sepharose 4B-starch affinity chromatography, contain pyridoxal 5′-phosphate. The addition of further quantities of pyridoxal 5′-phosphate causes inactivation. Both enzymes showed similar bi-substrate kinetics with d-Glc-1-P and varying amounts of amylopectin and also with P_i and varying amounts of amylopectin. In the direction of glucan sythesis the K_m for amylopectin with phosphorylase II was much higher than with phosphorylase I. However, the two enzymes differed in their behaviour on glucan degradation at varying concentrations of P_i. With phosphorylase II the K_m for amylopectin was dependent on the concentration of P_i but that for phosphorylase I was constant. Phosphorylase II was strongly inhibited by ADPG in the direction of glucan degradation but only slightly in the direction of glucan synthesis by both ADPG and UDPG. Phosphorylase I was only slightly inhibited by ADPG in both directions and by UDPG in synthesis. UDPG inhibited both enzymes moderately in glucan degradation,     

Expression of a cDNA for the catalytic subunit of skeletal-muscle phosphorylase kinase in transfected 3T3 cells.

Phosphorylase kinase is a multimeric enzyme of composition (alpha, beta, gamma, delta)4 whose catalytic activity resides in the gamma-subunit. As an approach to understand further its regulation, a cDNA for the gamma-subunit of phosphorylase kinase (gamma PhK) has been cloned into a mammalian expression vector behind the mouse metallothionein-1 promoter. NIH 3T3 cells were co-transfected with this construct (pEV gamma PhK) and pSV2neo, G418-resistant clones were selected, and several were found to have stably incorporated the gamma-subunit cDNA into their genomic DNA. Phosphorylase kinase activity was clearly present in extracts from cultures of pEV gamma PhK-transformed cells and increased several-fold after 24 h of incubation with Zn2+, whereas it was undetectable in the parent 3T3 cells. A significant, but variable, proportion (15-70%) of the activity was Ca2+-dependent. We conclude that the phosphorylase kinase activity expressed by the cells transformed with pEV gamma PhK is due to free gamma-subunit and gamma-subunit associated with cellular calmodulin, which replaces the delta-subunit normally associated with the gamma-subunit in the holoenzyme.     

Phosphorylase activity in relation to starch synthesis in developing Hordeum distichum grain

Activity, control and primer requirements of starch phosphorylase in developing barley endosperm were investigated. Phosphorylase was detected in endosperm extracts from 3 days after anthesis. Unprimed activity was predominant between 2 and 10 days after anthesis, when it constituted 70–80% of total activity, but this proportion declined rapidly as the grain developed. The existence of at least 2 isoenzymes was indicated by studies of pH dependence and phosphate inhibition, and was further supported by acrylamide gel electrophoresis and column chromatography using DEAE-cellulose. The two isoenzymes which ere possibly both glyco proteins, appear in barley endosperm soon after anthesis. One appears capable of unprimed activity, and may be associated with the initiation of a-1,2 glucans, which then serve as primers for starch synthetase. This disappears by 13–15 days after anthesis. The other isoenzyme is capable of some unprimed activity but undergoes modification between 15 and 20 days after anthesis, resulting in the loss of unprimed activity. The relevance of the results to initiation of starch synthesis and to starch synthetase in amyloplasts is discussed.     

Two Additional Phosphorylases in Developing Maize Seeds

Two additional phosphorylases (III and IV) have been detected in developing seeds of maize. Phosphorylase IV is found only in the embryo (with scutellum). It is also present in the embryo of the germinating seed where its activity is 90-fold greater than the activity in the developing embryo 22 days after pollination. Phosphorylase IV is eluted from a DEAE-cellulose column in the same fraction as phosphorylase I of the endosperm, and the 2 enzymes are similar in many respects. Phosphorylase IV is distinguished from phosphorylase I by electrophoretic mobility, by pH optimum, and because its properties are not affected by the shrunken-4 mutation.Phosphorylase III is found both in the endosperms and embryos of developing seeds. Activity for this enzyme is not detected in crude homogenates nor eluates from a DEAE-cellulose column apparently because it complexes with a non-dialyzable, heat-labile inhibitor. High activity is found after protamine sulfate fractionation. Phosphorylase III is bound to protamine sulfate and is then removed by washing with 0.3 m phosphate buffer. Phosphorylase III activity in the endosperm is not detectable 8 days after pollination but is present 12 days after pollination. Phosphorylase III differs from phosphorylases I, II, and IV in several respects-pH optimum, pH-independent ATP inhibition, time of appearance in the endosperm, and because purine and pyrimidine nucleotides are equally inhibitory. In common with phosphorylase II, phosphorylase III apparently does not require a primer to initiate the synthesis of an amylose-like polymer.