被子植物受精作用的分子和细胞生物学机制

被子植物双受精包括精-卵、精子-中央细胞两个融合过程。由于双受精深藏于母体组织中进行, 长期以来一直是植物有性生殖研究中的难点。近年来, 随着各种植物配子体cDNA文库的构建, 各种离体研究系统的建立和突变体分析的兴起, 极大地推动了被子植物受精作用研究的快速发展, 增进了人们对被子植物受精过程的分子和细胞生物学机制的深入了解。本文着重讨论受精作用的若干重要发育事件, 包括受精前卵器细胞对花粉管向胚珠定向生长的近距离引导信号, 精子的靶向运动,精、卵细胞相互作用和配子融合后卵细胞的激活与中央细胞发育的启动等。     

被子植物受精作用的分子和细胞生物学机制

被子植物双受精包括精-卵、精子-中央细胞两个融合过程。由于双受精深藏于母体组织中进行,长期以来一直是植物有性生殖研究中的难点。近年来,随着各种植物配子体cDNA文库的构建,各种离体研究系统的建立和突变体分析的兴起,极大地推动了被子植物受精作用研究的快速发展,增进了人们对被子植物受精过程的分子和细胞生物学机制的深入了解。本文着重讨论受精作用的若干重要发育事件,包括受精前卵器细胞对花粉管向胚珠定向生长的近距离引导信号,精子的靶向运动,精、卵细胞相互作用和配子融合后卵细胞的激活与中央细胞发育的启动等。     

植物胚乳发育的表观遗传学调控

被子植物的种子发育从双受精开始, 产生二倍体的胚和三倍体的胚乳。在种子发育和萌发过程中, 胚乳向胚组织提供营养物质, 因此胚乳对胚和种子的正常生长发育至关重要。开花植物发生基因组印迹的主要器官是胚乳。印迹基因的表达受表观遗传学机制的调控, 包括DNA甲基化和组蛋白H3K27甲基化修饰以及依赖于PolIV的siRNAs (p4-siRNAs)调控。基因组印迹的表观遗传学调控对胚乳的正常发育和种子育性具有不可或缺的重要作用。最新研究显示, 胚乳的整个基因组DNA甲基化水平降低, 而且去甲基化作用可能源于雌配子体的中央细胞。该文综述了种子发育的表观遗传学调控机制, 包括基因组印迹机制以及胚乳基因组DNA甲基化变化研究的最新进展。     

有花植物的有性生殖

花是有花植物（被子植物）的有性生殖器官。在雄蕊的花药中产生雄配子体,通常称花粉;在雌蕊子房内的胚珠中发育雌配子体,通常称胚囊。在花粉或花粉管中形成的一对精细胞分别与胚囊中的卵和中央细胞受精,由此产生胚和胚乳。随着胚和胚乳的发育,整个胚珠发育为种子。这是被子植物有性生殖的一般过程。     

有花植物的有性生殖

花是有花植物（被子植物）的有性生殖器官。在雄蕊的花药中产生雄配子体,通常称花粉;在雌蕊子房内的胚珠中发育雌配子体,通常称胚囊。在花粉或花粉管中形成的一对精细胞分别与胚囊中的卵和中央细胞受精,由此产生胚和胚乳。随着胚和胚乳的发育,整个胚珠发育为种子。这是被子植物有性生殖的一般过程。     

丫蕊花的双受精及胚和胚乳发育的初步观察

丫蕊花（Ypsilandra thibetica Franch.)为珠孔受精,进入胚囊的两个精子分别与卵细胞和中央细胞进行正常的双受精,其受精作用属有丝分裂前型,受精后的初生胚乳核立即分裂,其发育方式为沼生目型,到发育后期,由游离状态的胚乳核形成胚乳细胞时,珠孔室和合点室都形成胚乳细胞,合子的休眠期很长,而且胚的发育过程较为缓慢,种子成熟时胚尚无器盲的分化,本文还观察了以上发育过程中淀粉粒,蛋白质的动态。     

大葱胚和胚乳的发育

观察了“章丘大葱”胚珠、胚囊的结构,胚及胚乳的发育。胚发育属紫菀型,经历球胚前的原胚、球胚、椭形胚、凹形胚、长棒形胚及弯形成熟胚等各期。宿存助细胞生存到球形胚期。胚乳发育属核型。球胚晚期,在胚褒珠孔端及合点端,胚乳开始细胞化。由于游离核之间出现了垂周壁,由一层胚乳游离核形成了一层无内切向壁的“开放细胞”。“开放细胞”行平周分裂而形成两层细胞,外层为完整细胞,内层为新的“开放细胞”。如此多次分裂,向心增生胚乳细胞,最后将中央细胞填满。初始的垂周壁来自于间期游离核之间的细胞板,非“自由生长壁”但又未见明显的成膜体。初始的平周壁是正常有丝分裂的胞质分裂的结果,与成膜体,细胞板有关。在球胚晚期,胚乳细胞化后,在中央液泡内观察到游离细胞。     

丫蕊花的双受精及胚和胚乳发育的初步观察

丫蕊花（Ypsilandra thibetica Franch.)为珠孔受精,进入胚囊的两个精子分别与卵细胞和中央细胞进行正常的双受精,其受精作用属有丝分裂前型,受精后的初生胚乳核立即分裂,其发育方式为沼生目型,到发育后期,由游离状态的胚乳核形成胚乳细胞时,珠孔室和合点室都形成胚乳细胞,合子的休眠期很长,而且胚的发育过程较为缓慢,种子成熟时胚尚无器盲的分化,本文还观察了以上发育过程中淀粉粒,蛋白质的动态。     

黄花油点草胚胎发育研究

利用石蜡切片技术对百合科植物黄花油点草[Tricyrtis maculata(D.Don)Machride]双受精、胚及胚乳发育进行了研究,以明确其胚胎发育的特征,为百合科植物的系统研究提供生殖生物学资料。结果表明:(1)黄花油点草为珠孔受精;进入胚囊的2枚精子分别与卵细胞和中央细胞进行正常的双受精,其受精作用属有丝分裂前型。(2)受精后的初生胚乳核立即分裂,其发育方式为核型胚乳;早期的游离胚乳核沿胚囊的边缘分布,胚囊中央部位主要为胚乳细胞质,随着游离胚乳核数量的增加,胚乳核慢慢充满整个胚囊;当发育至球形胚早期阶段,在各胚乳核周围产生胚乳细胞壁,形成完整的胚乳细胞。(3)合子有较长的休眠时间,胚的发育方式为茄型;合子第一次有丝分裂为横裂,分裂后形成基细胞和顶细胞;基细胞经过3次横裂,形成一列胚柄细胞;顶细胞经过分裂形成胚体,依次形成球形胚、棒状胚和盾形胚。(4)种子成熟时胚无器官分化;成熟种子由种皮、胚和胚乳三部分组成。     

刺梨胚及胚乳的发育

本研究对单瓣刺梨胚及胚乳的发育过程进行了观察,获得如下主要结果:1.刺梨胚的发育属于紫菀型的一种变异类型。原胚发育早期,在胚体顶端具有明显的胚芽原细胞。成熟胚为典型的双子叶植物胚的形态,在子叶中贮藏大量的蛋白质粒。2.刺梨的胚乳属核型。经游离核时期以后形成胚乳细胞。紧邻胚囊周界壁的表层胚乳细胞可以进行平周分裂,产生层叠状的胚乳周缘层。此种后形成的胚乳,我们称之为次生胚乳。当次生胚乳形成时,其余的胚乳细胞逐渐解体,最后几乎完全消失。次生胚乳只在合点处解体,其余保留至种子成熟。3.发现了开花后一些胚珠中无胚或胚和胚乳在发育早期退化的现象,可认为是刺梨种子不育的一个重要原因。     

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。     

莴苣助细胞发育过程中钙的分布研究

用焦锑酸盐沉淀法对莴苣助细胞中的钙分布进行了观察。结果表明,开花前3天刚形成的助细胞中的钙颗粒很少:开花前2天助细胞壁中的钙颗粒增加;开花前1天助细胞珠孔端细胞壁加厚,其中积累了许多钙颗粒:开花当天助细胞珠孔端的丝状器中聚集了大量的钙颗粒。授粉后1h时两个助细胞的结构和钙分布发生差异,一个呈退化状,其中的钙颗粒明显增多,另一宿存助细胞中的钙分布与授粉前相似。去雄不授粉1天后两个助细胞均保持完好,且两助细胞中的钙分布没有明显差异,表明由花粉管引起一个助细胞中钙含量增加进而导致了助细胞退化。退化助细胞在卵细胞与中央细胞之间形成一薄层。助细胞退化后不同部位的钙颗粒呈现出与受精作用密切有关的变化:授粉后1h时,钙主要聚集在近合点端部位;授粉后2.5h卵细胞即将受精,这时许多细小的钙颗粒主要聚集在卵细胞与中央细胞之间的薄层中;授粉后4h精、卵细胞已融合,这时退化助细胞合点端的钙颗粒明显减少,而在其珠孔端又聚集了较多的钙。上述助细胞中的钙含量变化与吸引花粉管进入胚囊和促使精卵细胞融合密切有关。     

Fertilization in Torenia fournieri: Actin organization and nuclear behavior in the central cell and primary endosperm

Studies of the living embryo sacs of Torenia fournieri reveal that the actin cytoskeleton undergoes dramatic changes that correlate with nuclear migration within the central cell and the primary endosperm. Before pollination, actin filaments appear as short bundles randomly distributed in the cortex of the central cell. Two days after anthesis, they become organized into a distinct actin network. At this stage the secondary nucleus, which is located in the central region of the central cell, possesses an associated array of short actin filaments. Soon after pollination, the actin filaments become fragmented in the micropylar end and the secondary nucleus is located next to the egg apparatus. After fertilization, the primary endosperm nucleus moves away from the egg cell and actin filaments reorganize into a prominent network in the cytoplasm of the primary endosperm. Disruption of the actin cytoskeleton with latrunculin A and cytochalasin B indicates that actin is involved in the migration of the nucleus     

Calcium changes in ovules and embryo sacs of Plumbago zeylanica L.

Calcium was localized in ovules of Plumbago zeylanica from 1 day before anthesis to 3 days after anthesis using potassium antimonate and transmission electron microscopy in pollinated and emasculated flowers. At 1 day before anthesis, embryo sacs (containing an egg cell, a central cell and zero to three accessory cells) appear mature and contain abundant calcium precipitates (ppts), in contrast to nucellar cells. At anthesis, the vacuoles of nucellar cells have enlarged, and micropylar cells, in particular, are heavily labeled with calcium ppts. As pollen tubes elongate through ovular tissues, ppts diminish in ovular cells and become concentrated in the pollen tube cell wall. After fertilization, the calcium ppts sharply diminish in fertilized ovules; in unfertilized ovules, calcium ppts remain abundant up to 3 days after anthesis (when unfertilized ovules are shed). The distribution of calcium in the ovule changes in apparent response to fertilization, suggesting that calcium content may be related to the attraction and receipt of the pollen tube. In contrast with conventionally-organized embryo sacs with synergids, Plumbago accumulates calcium in the egg cell. Received: 30 December 1999 / Revision accepted: 24 March 2000     

Fertilization in Torenia fournieri: Actin organization and nuclear behavior in the central cell and primary endosperm

Studies of the living embryo sacs of Torenia fournieri reveal that the actin cytoskeleton undergoes dramatic changes that correlate with nuclear migration within the central cell and the primary endosperm. Before pollination, actin filaments appear as short bundles randomly distributed in the cortex of the central cell. Two days after anthesis, they become organized into a distinct actin network. At this stage the secondary nucleus, which is located in the central region of the central cell, possesses an associated array of short actin filaments. Soon after pollination, the actin filaments become fragmented in the micropylar end and the secondary nucleus is located next to the egg apparatus. After fertilization, the primary endosperm nucleus moves away from the egg cell and actin filaments reorganize into a prominent network in the cytoplasm of the primary endosperm. Disruption of the actin cytoskeleton with latrunculin A and cytochalasin B indicates that actin is involved in the migration of the nucleus in the central cell. Our data also suggest that the dynamics of actin cytoskeleton may be responsible for the reorganization of the central cell and primary endosperm cytoplasm during fertilization.     

Subcellular localization of calcium during Alpinia mutica Roxb. (Zingiberaceae) style movement

The subcellular localization of calcium in Alpinia mutica Roxb. during style movement was studied in two morphs. In the styles, Ca-antimonate precipitates (ppts) were principally located in apoplasts, with some minimal accumulation in the nucleus. At different movement, stages of movement, the ppts in the abaxial and adaxial sides changed, and no lateral gradient of ppts in the apoplast was established. The increase or decrease of ppts in the apoplast was not accompanied with equivalent changes in the cytoplasm. These results indicate that calcium could not affect the curvature by inhibiting cell elongation but may play a role in style movement by acting as a secondary messenger. EGTA-treatment affected style movement, providing further evidence supporting a role for calcium as a secondary messenger     

Changes of calcium distribution in egg cells,zygotes and two-celled proembryos of rice (<Emphasis Type="Italic">Oryza sativa </Emphasis>L.)

Changes in loosely bound calcium of rice egg cells (pre- and post-pollination) and two-celled proembryos were localized using potassium pyroantimonate precipitation. Egg cells and zygotes (6 h after pollination) have few calcium precipitates (ppts); however within 3 h, (9 -12 h after pollination), ppts become locally abundant in all regions. Statistical analysis indicates that ppts in cytoplasm and nucleoplasm increase by 4.4 and 10.5-fold in zygotes at 9 h and 12 h after pollination, respectively. The ppts labeling the nucleolus 9 h after pollination show a 52-fold increase. In two-celled proembryos, ppts declined to a level similar to that of zygotes 6 h after pollination, except in the nucleolus and cell wall. Following pollination, abundant calcium was detected in the apoplast of the embryo sac.     

Cytological Studies of the Double Fertilization in Rice

Detailed studies on the process of double fertilization in rice were conducted in the present work. The results are summarized as follows: 1. In the embryosac 30 minutes after anthesis, the pollen tube has already reached the micropyle in every specimen. In some cases, it has even entered further into the embryosac and discharged its contents, including the two male gametes. 2. 1½ hours after anthesis, the male gamete enters into the egg cell. As soon as it comes in contact with the egg nucleus, it increases in size. 2 hours after anthesis, the male nucleus is found inside the female one. A male nucleolus is now clearly discernible. 3. The male nucleolus is gradually growing until it reaches the size of the female one, and then the fusion of the two takes place. The fusion is generally completed and the zygote is formed 7 hours after anthesis. 4. The first mitotic division of the zygote occurs 9 hours after anthesis. 5. The fusion of the male gamete and the polar nucleus proceeds in a similar way as that of the male and female gametes, but it takes a much shorter time usually being completed within 3 hours after anthesis. 6. The male gamete enters into one of the polar nuclei and reveals its nucleolus which increases rapidly in size and then unites with that of the polar nucleus. As soon as the union is completed, the nuclear membrane between the closely contacted parts of the two polar nuclei disappears and the primary endosperm nucleus is formed. 7. The first mitotic division of the primary endosperm nucleus begins right after its formation. 8. With the fusion of the male and female gametes and the development of the zygote, the mitochondria in the cytoplasm surrounding the nucleus increase in size and number. However, in the central cytoplasm about the polar nuclei they show no notice- able change during the fertilization process. 9. Based on the facts that in the embryosac a secondary pollen tube is often seen in every stage of the fertilization process and that additional nucleoli are also observed sometimes in the egg nucleus, the authors believe that polyspermy most probably exists in rice plants, and that this may be one of the causes of polyploid plants often found in rice field as reported by several authors.     

Embryological Studies on Apomixis in Pennisetum squamulatum

Studies on the formation and development of the embryo sac of the apomictic material of Pennisetum squamulatum Fresen indicated that normal archesporial cell did form with consequent development of a megaspore mother cell and later meiotic division to give rise to a triad. But invariably the megaspore mother cell and the triad underwent degeneration after formation. During the period of formation or degeneration of the megaspore or the triad a number of nucellar cells around the degenerated sexual cell became much enlarged. Frequently, one of the enlarging nucellar cells near the micropylar end became vacuolated and then developed into an aposporous uninucleate embryo sac, which underwent two further mitotic divisions to form an aposporous four-nucleate embryo sac, where the four nuclei remained in the micropylar end. Thus in the mature aposporous embryo sac there were one egg cell, one synergid and one central cell (containing two polar nuclei). Antipodal cells were completely lacking. The pattern of development of the aposporous embryo sac resembles the panicum type. There were two types of embryo formed during apomictic development namely ( 1 ) The pre-genesis embryo--embryo formed without fertilization, 1 to 2 days before anthesis, and (2) The late-genesis embryo--derived from the unfertilized egg cells, 3 to 4 days after anthesis. In the late-genesis embryo type, the egg cell divided after the secondary nucleus has undergone division to form the endosperm nuclei. All egg cells developed vacuoles before they differentiated into embryos. The development of the aposporous embryo followed the sequence of the formation of globular, pearshaped embryo and full stages of differentiation. The unfertilized secondary nucleus divides to form free endosperm nuclei after being stimulated by pollination. The development of the endosperm belongs to the nuclear-type.     

水稻双受精过程的细胞形态学及时间进程的观察

应用常规石蜡切片和荧光显微镜观察水稻(Oryz a sativa)受精过程中雌雄性细胞融合时的形态特征及时间进程, 确定合子期, 为花粉管通道转基因技术的实施提供理论依据。结果表明: 授粉后, 花粉随即萌发, 花粉管进入羽毛状柱头分支结构的细胞间隙, 继续生长于花柱至子房顶部的引导组织的细胞间隙中, 而后进入子房, 在子房壁与外珠被之间的缝隙中向珠孔方向生长, 花粉与花粉管均具有明显的绿色荧光。花粉管经珠孔及珠心表皮细胞间隙进入一个助细胞, 释放精子。精子释放前, 两极核移向卵细胞的合点端; 两精子释放于卵细胞与中央细胞的间隙后, 先后脱去细胞质, 然后分别移向卵核和极核, 移向卵核的精核快于移向极核的精核; 精核与两极核在向反足细胞团方向移动的过程中完成雌雄核融合。大量图片显示了雌雄性核融合的详细过程以及多精受精现象。水稻受精过程经历的时间表如下: 授粉后, 花粉在柱头萌发; 花粉萌发至花粉管进入珠孔大约需要0.5小时; 授粉后0.5小时左右, 花粉管进入一个助细胞, 释放精子; 授粉后0.5-2.5小时, 精卵融合形成合子; 授粉后约10.0小时, 合子第1次分裂, 合子期为授粉后2.5-10.0小时; 授粉后1.0-3.0小时, 精核与两极核融合; 授粉后约5.0小时, 初生胚乳核分裂。