水稻胚与胚乳分化发育中的内源多胺

稻胚发育过程中,其内源多胺以腐胺、亚精胺为主。在幼胚分化期,腐胺和亚精胺的含量很高;幼胚分化完成时,其含量急剧下降;直至分化后期才趋稳定。在胚及胚乳发育时期,还出现一种未知多胺X_(22),其含量除在胚分化完成时较少外,在胚发育的其他各期中,含量则一直很高。DNA和蛋白质含量的变化,从分化期开始递增直至物质积累成熟期,其趋势均相同。多胺可能参与胚与胚乳中核酸和蛋白质合成的调节。     

高等植物胚胎的发育生物学研究——Ⅵ.粳稻胚分化发育期间一些大分子物质的动态

鉴测了粳稻胚的发育进程及不同分化发育时期中DNA、RNA、蛋白质、淀粉含量和鲜重、干重、细胞数的变化。 开花后6～13天(胚分化第一到第四叶原基期间)胚细胞数增加时,DNA、RNA含量迅速上升。此后细胞数和DNA、RNA含量都趋于稳定,但RNA在18～25天再次增长。每胚蛋白质和干重基本上随RNA含量相应地变化。 每毫克胚于重的核酸和蛋白质含量在13天出现明显的转折。平均每细胞的DNA含量在整个发育期保持稳定,RNA第一阶段的增长只持续到分化完成的前夕,而蛋白质在25天以前一直增加。 胚内淀粉的累积在整个胚形成期呈现三段斜率不同的直线。以单位干重表示时则在8天左右和21天出现两个高峰,先于RNA和蛋白质两次积累的高峰。 在大分子物质的变化与胚胎发育进程相互关系并与籼稻比较的基础上,将稻胚发育划分为原胚期、分化期、成熟期和休止期。     

玉米花粉胚状体发育过程中DNA,RNA蛋白质含量及合成动态变化

继代培养的玉米花粉胚状体的发育过程可划分为6个时期:胚性细胞团时期、球形胚时期、心形胚时期、梨形胚时期、子叶形胚时期以及分化期。我们应用微量生化分析技术以及放射性同位素液体闪烁计数技术研究了玉米花粉胚状体发育过程的DNA、RNA、蛋白质含量及合成动态,发现DNA、RNA和蛋白质含量在胚性细胞团期较高,然后下降,但到了分化期时又有所升高。DNA合成速度在胚性细胞团时期较高,在以后的各时期降低并保持平稳。RNA和蛋白质的合成动态呈相似的变化规律。这个结果说明DNA、RNA和蛋白质在胚状体发育早期的活跃代谢,可能与胚性细胞的快速分裂以及胚性结构的形成有关,而后期的活跃代谢可能与胚状体的分化有关。     

高等植物胚胎的发育生物学研究——Ⅴ.水稻种胚发育过程中胚和胚乳内几种碳水化合物含量及淀粉酶活力的动态 高锦华;唐锡华

在开花后6～15天稻胚分化过程中,胚内淀粉、总糖和非还原糖含量逐渐地增加,但在胚器官原基分化完成后淀粉含量明显下降。胚分化期淀粉酶活力增加显著,尤其是β-淀粉酶活力较高,变化幅度大;胚器官原基分化完成后酶活性亦下降。以单位胚干重或每胚细胞计算的结果基本上亦表现了相似的趋势。稻胚分化发育过程中淀粉是处于不断被贮存同时不断被利用的状态,它积极参与了胚胎发育的代谢过程。至于β-淀粉酶可能在降解淀粉、提供能源,为合成蛋白质及纤维素等物质提供碳架方面起着重要作用。当胚分化完成后胚乳中淀粉含量仍有少量增加。在胚乳中α-淀粉酶活力低,变化幅度小,而β-淀粉酶活力在发育初期很高,以后下降,但活力仍比α-淀粉酶高,可能它在发育前期亦有类似在胚内的作用。     

水稻种子发育过程中Poly(A)RNA和蛋白质水平的变化

我们用[~3H]—Poly(U)饱和杂交的方法分析了水稻种子发育过程中Poly(A)含量和Poly(A)RNA水平的变化。胚乳发育过程中,Poly(A)含量和Poly(A)RNA水平均于开花后11天达到高峰,比蛋白质高峰出现时间约早10天。随着胚乳的成熟,蛋白质水平在开花后6～21天持续增长。但 Poly(A)含量和Poly(A)RNA水平却急剧下降。因此,在胚乳发育早期合成的Poly(A)RNA中,可能有部分不是直接用于蛋白质的合成。在胚的发育过程中,Poly(A)含量和Poly(A)RNA水平分别出现三次高峰。开花后30天,每胚含有5.94ng Poly(A)RNA,约占胚总RNA的0.097％,为稻胚中贮存的mRNA存在提供了一个直接的证据。     

水稻胚胎形成期间蛋白质和RNA合成活力的变化

用~3H-亮氨酸和~3H-尿苷标记不同发育时期的稻胚,发现蛋白质合成活力呈四阶段变化;各种RNA的合成与胚胎各发育阶段密切有关。α-鹅膏蕈碱(1.0μg/ml)对稻胚RNA合成的抑制作用在开花后7、15和18天较强,13天时很弱。在水稻胚胎形成期间,胚细胞蛋白质合成活力高峰先后出现于胚分化后期(开花后11天)和成熟中期(18天);mRNA的合成在分化初期(7天)和成熟中期(15～18天)较强;而rRNA和/或tRNA的合成高峰则出现在胚胎器官原基分化已经完成时(13天)。     

高等植物胚胎的发育生物学研究——Ⅸ.稻胚发育过程中呼吸强度及细胞色素氧化酶活力的变化

前文已报道稻胚在分化发育过程中细胞分裂增殖迅速,生物大分子物质的含量亦相应增长(唐锡华等1980;朱治平等1980;覃章铮和唐锡华1982),而且淀粉在胚乳及胚中积累时还可能通过β淀粉酶而降解被发育中的胚所利用(高锦华和唐锡华1982)。为了研究这个过程中的生理变化,本文作者结合稻胚分化器官原基及积累贮藏物质各发育期的进展,研究了胚的呼吸强度与细胞色素氧化酶活力的变化规律;因为呼吸强度标志着胚体总的生理活性变化,而细胞色素氧化酶是呼吸链中末端氧化的一个重要酶,它直接关系到高能键ATP的形成。过去已有作者(1960;夏叔芳等1966)证明;水稻幼苗或籽粒中有末端氧化酶系统存在;而且较幼嫩籽粒中糖的末端氧化主要是通过金属末端氧化酶类,乳熟后磷酸戊糖支路(HMP)及非金属氧化酶类逐渐加强。夏叔芳(1964)还指出水稻种子成熟时,稻胚的呼吸强度并不下降。因此有必要在了解稻胚分化发育过程中胚呼吸作用的变化的同时,研究稻胚中金属末端氧化酶中的细胞色素氧化酶活力变化规律,以便了解稻胚分化发育过程中胚细胞分化发育与物质代谢的能量来源。     

胡萝卜体细胞胚胎发生中的细胞组织化学和蛋白质组成变化

研究胡萝卜体细胞胚不同发育阶段的细胞组织化学和蛋白质组成变化的结果表明:胚性愈伤组织主要源自维管束周围的细胞.球胚形成前期,淀粉粒和糊粉粒极性分布已很明显.子叶胚期,芽开始分化,有大量糊粉粒累积.在体细胞胚发育过程中,淀粉粒在胚性愈伤组织形成初期和球胚后期、糊粉粒在胚性愈伤组织形成后期和球胚期各有两次累积高峰.     

党参的体细胞胚发生及不同发育阶段几种同工酶的分析

以党参为材料,在附加0.1 mg·L-1 2,4-D、0.3 mg·L-1 6-BA和3%蔗糖的MS培养基上获得大量发育良好的体细胞胚. 附加6-BA可以使胚性愈伤组织进行芽的分化,而添加0.1%活性炭后仅有根的分化.利用梯度凝胶电泳进行同工酶的研究表明在胚性愈伤组织和体细胞胚之间,酶谱差异比较大;而在不同发育时期的体细胞胚之间,差异较小.并讨论了同工酶酶谱和酶活性变化与体细胞胚发生、发育的关系.     

无核荔枝胚胎发育时期蛋白质图谱分析

通过二维聚丙烯酰胺凝胶电泳(2DE)以及计算机辅助的图像分析技术,对荔枝开花后20d的正常与败育胚蛋白质图谱进行了初步分析。结果表明,正常胚总蛋白质斑点数为129,败育胚总蛋白质斑点数为130,其中24个蛋白质点在两种胚中的表达丰度没有明显变化,35个蛋白质点在表达丰度上有明显差异,55%的蛋白则发生了蛋白质缺失、增加以及位置改变等变化。这两种蛋白质组的表达差异说明了胚内蛋白质成分在其败育过程中发生了变化,这些蛋白可能参与了胚败育的调节和控制。     

家蚕催青前期胚胎蛋白质双向电泳图谱分析

为了探讨家蚕Bombyx mori胚胎蛋白质整体变化,以多化性品种P50为材料,采用蛋白质双向电泳技术及图像分析技术分析了催青前期胚胎（戊₃以前）各个时期蛋白质图谱及其变化情况。研究发现:从临界Ⅱ期（丙_２）胚胎到缩短期(戊₂)胚胎蛋白质双向电泳图谱基本稳定,存在于临界Ⅱ期胚胎的蛋白斑点在催青前期的4个胚胎中消失的个数较少,仅占22.80％,而在催青的最后2个胚胎中消失的蛋白质斑点却占48.18％;在神经沟出现（丁₁）、腹肢突起（丁₂）、上唇突起（戊₁）和缩短期（戊₂）胚胎的双向电泳图谱中能够检测到100个特异蛋白质斑点,这些特异蛋白质斑点大多在随后邻近的胚胎发育中消失,暗示了这些特异蛋白可能与相应胚胎的形体特征发育有关。     

家蚕催青后期胚胎蛋白质双向电泳图谱分析

采用蛋白质双向电泳技术分析了家蚕Bombyx mori催青后期胚胎蛋白质图谱的变化。研究发现: 在头胸分化期（戊₃）、反转期（己₁）、毛瘤发生期（己₂）、点青期（己₃）、转青期（己₄）和孵化期（己₅）胚胎蛋白质的双向电泳图谱中共检测到209个特异蛋白斑点,其中己₃和己₄两个胚胎出现的特异蛋白斑点数在整个催青期胚胎中为最多,分别达55和77个。与催青前期胚胎出现的特异蛋白斑点变化规律相似,这些特异蛋白斑点大多也是在随后邻近的胚胎发育中消失。推测这些特异蛋白可能与相应胚胎的形体特征发育有关。     

Changes in the protein spectrum of the chick embryo mesonephros and metanephros in the course of development

The protein spectra of two fractions (the soluble and the membrane fraction) of chick embryo kidney homogenates were isolated by electrophoresis on polyacrylamide gels with the aim of detecting the kidney differentiation process at the molecular level and, at the same time, of evaluating similarities in the construction of the mesonephros and metanephros at this level. Corresponding stages of the above two types of kidney were chosen for studying changes in protein structure during differentiation--i.e. the outset of differentiation (the 6-day mesonephros, the 11-day metanephros) and the stage of full maturity (the 14-day mesonephros, the 20-day metanephros). A total of 36 proteins was distinguished. The analysis of the protein spectra showed that the number of proteins changes but slightly during differentiation; the protein composition of the two types of kidney during differentiation altered by 20-35% of the total number of proteins; the similarity of the protein composition of the corresponding stages of mesonephros and metanephros, expressed as the proportion of the number of identical proteins, was greater than the mutual similarity of different developmental stages of the same type of kidney. The percentage of different proteins at corresponding stages of the kidneys varied from 5% to 23% of the total number of proteins detected.     

乌龙岭’龙眼胚胎发育时期特异性蛋白质的变化

应用IEF-SDS-PAGE技术分析龙眼胚胎分化发育过程中蛋白质组分的变化。结果表明,在各发育阶段大多数蛋白质组分的电泳图谱基本一致,但也有变化。其中花后38d存在TE1(27．1kD、p,7．3),TE2(17．5kD、pI8．2)2个特异蛋白,45d存在TE3(11．4kD、pI7．6),TE4(13．2kD、pI9．9)2个特异蛋白,52d存在TE5(22．6kD、pI7．2),TE6(18．6kD、pI8．3),TE,(23．5kD、pI3．6)3个特异蛋白。31d胚胎电泳图谱中的蛋白质点数相对较多,表明此时蛋白质旺盛合成与积累,这与蛋白含量的变化基本一致。龙眼胚胎发育过程中特异蛋白的出现或消失．对胚胎的分化发育具有重要作用。     

Changes in plasma membrane protein composition during early development of the frog Rana ridibunda.

Plasma membranes of fully-grown oocytes and early developmental stage embryos of Rana ridibunda were isolated by differential and density gradient centrifugation; they were purified 18-fold as indicated by 5'-nucleotidase. The plasma membrane protein pattern of five different developmental stages was studied by two-dimensional polyacrylamide gel electrophoresis. More than 60 protein species could be detected by silver staining. Most of them are largely conserved during development. The rest either show precise stage specificity or exhibit stronger staining intensity at particular stages. The number of proteins specific for each stage is small, neurula being exempted. The changes observed in the plasma membrane profile during development are mostly prominent in a group of proteins with similar molecular weights (40-45 kDa) but with different pI values. The differences observed in the plasma membrane patterns are discussed in relation to the significance of each stage during development.     

水稻叶绿体蛋白质在生长发育过程中的表达研究

在植物中,叶绿体是负责光合作用的细胞器,对叶绿体内的各种生物过程人们已经积累了很多知识,但对叶绿体蛋白质的表达还所知甚少．为了解水稻叶绿体蛋白质在正常生长发育过程中的表达情况,尝试基于抗体的水稻蛋白质组学策略．选取了10个水稻叶绿体基因,利用表达的蛋白质或合成的抗原决定簇片段制备了抗体,用Western blotting检测了相应蛋白质在5个发育时期的根、茎、叶及穗组织中的表达．发现10个蛋白质均在叶片中表达,在根中不表达．与原初反应相关的叶绿素A/B结合蛋白1和2(CAB1和CAB2)、与电子传递相关的放氧增强蛋白1(OEE1)及与活性氧清除相关的过氧还蛋白过氧化物酶(2-CysP)和硫氧还蛋白(Trx)在茎中表达．而在卡尔文循环中发挥作用的Rubisco活化酶(RCA)、甘油醛-3-磷酸脱氢酶(GAPDH)、果糖二磷酸醛缩酶(FBPA)和景天庚酮糖-1, 7-二磷酸酶(SBPase)蛋白质在茎中不表达．在穗中,这些蛋白质的表达时序不同,CAB2和2-CysP在穗发育的全程表达,CAB1和OEE1在中后期表达,而卡尔文循环中的蛋白质只在中期表达．有意思的是,卡尔文循环中的蛋白质表达模式相似,这一结果从蛋白质表达水平支持它们之间的相互衔接关系．此外,实验还揭示了可能的蛋白质修饰、二聚体及不同的转录本现象．将目标基因的表达谱与转录谱进行比较,发现二者间有一定的平行性,但也有明显的区别．以水稻叶绿体蛋白质为对象,直观并相对定量地揭示了它们的表达模式,为阐释其功能提供了信息,也为基于抗体的水稻蛋白质组学策略提供了一个初步数据．     

Protein databases for compacted eight-cell and blastocyst-stage mouse embryos

High-resolution two-dimensional sodium dodecyl sulfate-polyacrylamide (2D-SDS) gel electrophoresis combined with computerized analysis of gel images was used to construct and analyze protein databases for two stages of preimplantation mouse embryogenesis, the compacted eight-cell stage and the fully expanded blastocyst stage. These stages were chosen for their ease in identification of multiple synchronous embryos. Synchronous cohorts of 30–50 embryos were labelled with L-[³⁵S]methionine for 2 hr. The embryos were then lysed in 30 μl hot SDS sample buffer, and the lysates were stored at ?80°C until the gels were run. Five replicates were run for eight-cell embryos, and four for blastocyst-stage embryos. The samples were processed for 2D gel electrophoresis and fluorography; multiple exposures were made. Gel images were analyzed using the PDQUEST system, and databases were constructed. Analysis of the databases for both developmental stages showed high reproducibility of protein spots in multiple gel images. Of 1,674 total spots in eight-cell embryo standards, >79% of spots had a percentage error (S.E.M./average) <50%, and >45% had a percentage error <30%. Similarly, of 1,653 total spots in blastocyst-stage embryo standards, 74% of spots had a percentage error <50%, and approximately 47% of spots had a percentage error <30%. Forty-three spots (approximately 3% of the total spots) were found to be detected only in the eight-cell stage, while 75 spots were detected solely in the blastocyst stage. Sixty-nine proteins showed a greater than threefold increase in isotope incorporation from the eight-cell to the blastocyst stage, with a percentage error <50% in both the eight-cell and the blastocyst stages. In contrast, 41 of the proteins showed a decrease during this period. Analysis of the protein databases described in this study has allowed us to document the overall quantitative changes in proteins from the compacted eight-cell stage to the blastocyst stage of mouse preimplantation development. These databases provide a valuable tool for further detailed quantitative analysis of specific proteins associated with developmental events. In addition they will permit analysis of the effects of environmental factors, such as growth factors, on early embryo development. © 1994 Wiley-Liss, Inc.     

Evaluation of 2-DE protein patterns from pre- and postnatal stages of the mouse brain

Brains of the mouse from three developmental stages, embryo day 16 (Ed16), postnatal stage one week (1W) and eight weeks (8W), were distributed to different laboratories for a collaborative proteome analysis (The Human Brain Proteome Project). As one of the laboratories involved in this project, we separated total protein extracts of the brains by large gel 2-DE. From the 2-DE protein patterns a section was evaluated for each of the three stages according to resolution, reproducibility and quantitative changes using an image analysis software. The evaluated pattern section was selected to allow comparisons of 2-DE patterns between different laboratories on the basis of optimum separation. Changes in protein expression were analysed within two phases of development: Stage Ed16 versus stage 1W and stage 1W versus stage 8W. Out of the 200 protein spots evaluated 5-6% showed quantitative changes in the range of > or = 30% between two stages. The relationship in the frequency of up- and down-regulated protein spots differed between the two investigated phases. Most of the protein spots which showed altered expression between two stages were identified by MS. High quality in protein separation and evaluation is demonstrated.