扁豆成熟胚囊的超微结构

本文对扁豆（Dolichos lablab)成熟胚囊的超微结构进行了研究,在成熟胚囊中,卵细胞和助细胞仅在珠孔端1／3有细胞壁,靠近合点端,卵细胞一助细胞,卵细胞－中央细胞,助细胞－中央细胞之间没有细胞壁存在,相邻细胞的质膜靠在一起,在卵细胞和中央细胞的质膜间,有些地方存在中等电子密度的物质,卵细胞的细胞质中含有很多的线粒体和质体,内质网和高尔基体较少,助细胞的珠孔端有一复杂的丝状器,靠近珠孔端的细胞质中有很多管状的内质网,表明助细胞可能具有分泌功能,在助细胞的合点端,含有丰富的粗糙内质网,助细胞和卵细胞的质膜之间有很多囊泡状的结构,中央细胞内含有丰富的线粒体,高尔基体和内质网,中央细胞的壁向内形成突起,在周缘细胞质中含有丰富的脂滴。     

扁豆成熟胚囊的超微结构

本文对扁豆（Dolichos lablab)成熟胚囊的超微结构进行了研究,在成熟胚囊中,卵细胞和助细胞仅在珠孔端1／3有细胞壁,靠近合点端,卵细胞一助细胞,卵细胞－中央细胞,助细胞－中央细胞之间没有细胞壁存在,相邻细胞的质膜靠在一起,在卵细胞和中央细胞的质膜间,有些地方存在中等电子密度的物质,卵细胞的细胞质中含有很多的线粒体和质体,内质网和高尔基体较少,助细胞的珠孔端有一复杂的丝状器,靠近珠孔端的细胞质中有很多管状的内质网,表明助细胞可能具有分泌功能,在助细胞的合点端,含有丰富的粗糙内质网,助细胞和卵细胞的质膜之间有很多囊泡状的结构,中央细胞内含有丰富的线粒体,高尔基体和内质网,中央细胞的壁向内形成突起,在周缘细胞质中含有丰富的脂滴。     

天竺葵雌性生殖单位的超微结构

应用透射电镜研究了临近受精时天竺葵(Pelargonium hortorum Bailey)胚囊中的卵细胞、助细胞和中央细胞的结构。证明了卵细胞与助细胞以及助细胞与助细胞之间从合点端至珠孔端有很大的面积以质膜分界,仅珠孔端少部分以壁分隔。卵细胞与中央细胞之间同样缺乏细胞壁。在卵细胞的合点端,两质膜不同程度地分离形成宽窄相间的间隙。在间隙的絮状基质中存在小泡,这些小泡的产生似与卵和中央细胞中周质内质网的活动有关。推测小泡为多糖性质,可能为合子新壁的建造提供物质。卵细胞质中含巨大线粒体,质体和内质网也较丰富。基于超微结构的特征,可认为卵细胞具高度的生理合成活动的潜能。中央细胞极核位于珠孔端与卵器细胞毗邻,有利于在双受精作用中同时发生精细胞与卵细胞和精细胞与中央细胞核的融合。中央细胞的侧壁在珠孔端形成内突,具传递细胞的特点,表明这是雌配子体向孢子体摄取营养的重要部位。助细胞的细胞质含丰富的细胞器,这与多数植物中的相似,但具几个明显的特征,即核中存在微核仁,内质网形成圆球体或脂体,线粒体富集在丝状器的附近。传粉后花粉管进入胚囊之前,两个助细胞中一个退化。     

花生胚乳细胞化的超微结构观察

花生（ＡｒａｃｈｉｓｈｙｐｏｇｅａｅＬ．）心形胚期的胚乳游离核多瓣裂,或具长尾状结构。胚乳细胞质内有大量线粒体、质体、高尔基体、小泡及少量内质网。中央细胞壁有壁内突。球胚及心形胚期常见胚乳瘤。心形胚晚期,胚乳开始细胞化,胚乳细胞壁形成有３种方式,分别存在于不同的胚珠中：（１）从胚囊壁产生自由生长壁形成初始垂周壁,具有明显的电子密度深的中层,其生长主要靠末端的高尔基体小泡及内质网囊泡的融合。两相邻的自由生长壁末端或其分枝末端相连形成胚乳细胞。（２）核有丝分裂后产生细胞板,细胞板向外扩展并可分枝。间期的非姊妹核间也观察到形成了细胞板。小泡与微管参与细胞板的扩展,高尔基体和内质网是小泡的主要来源。细胞板的扩展末端相互连接,形成胚乳细胞的前身。小泡继续加入细胞板的组成,以后形成胚乳细胞壁。（３）胚乳细胞质中,出现一些比较大的不规则形的片段性泡状结构,它们可能来源于高尔基体小泡,这些片段性泡状结构随机相连形成细胞壁,未见微管参与。胚乳细胞外切向壁及经向壁上有壁内突。     

小麦受精过程中酸性磷酸酶的超微细胞化学定位

小麦（Ｔｒｉｔｉｃｕｍ ａｅｓｔｉｖｕｍ ）受精前成熟胚囊,除胚囊中央细胞的合点端细胞质中有酸性磷酸酶外,其余部位均未发现酸性磷酸酶。受精时期,以下部位存在酸性磷酸酶活性：卵细胞的细胞核内一部分染色质和细胞质中大部分线粒体;精、卵核融合时两核的核周腔内;退化助细胞合点端细胞质和一些液泡内;进入雌性细胞中的两个精核;胚囊各成员细胞的细胞壁及胚囊周围珠心细胞的细胞壁。二细胞原胚中未见有酸性磷酸酶。早期胚乳游离核染色质上有酸性磷酸酶。小麦受精过程酸性磷酸酶的分布特点可能与卵细胞生理状态的变化和细胞质中线粒体的改组、助细胞的退化、精核的生理状态以及精核与卵核的核膜融合等有关。     

水稻胚囊超微结构的研究

水稻(Oryza sativa L.)胚囊成熟时,卵细胞的合点端无细胞壁,核居细胞中部,细胞器集中在核周围,液泡分散于细胞周边区域。助细胞珠孔端有丝状器,合点端无壁,核位于细胞中部贴壁处,细胞器主要分布在珠孔端,液泡主要分布在合点端。开花前不久,一个助细胞退化。中央细胞为大液泡所占,两个极核靠近卵器而部分融合,细胞器集中在极核周围和靠近卵器处,与珠心相接的胚囊壁上有发达的内突。反足细胞多个形成群体,其增殖主要依靠无丝分裂与壁的自由生长,反足细胞含丰富活跃的细胞器,与珠心相接的壁上有发达的内突。开花后6小时双受精已完成,合子和两个助细胞合点端均形成完整壁。合子中开始形成多聚核糖体、液泡减小。退化助细胞含花粉管释放的物质,其合点端迴抱合子。极核已分裂成数个胚乳游离核,中央细胞中细胞器呈活化状态。反足细胞仍在继续增殖。讨论了卵细胞的极性、助细胞的退化、卵器与中央细胞间界壁的变化、反足细胞的分裂特点等问题。     

萝卜胚胎早期发育的亚显微结构研究

本研究对萝卜（Raphanus sativus L.)的成熟胚囊,胚和胚乳的早期发育过程作了亚显微结构观察：（1）萝卜胚囊由7个细胞组成,成熟时反足细胞消失;（2）卵细胞表现明显的极性,其合点端不具完整的细胞壁,它是电子致密物质在卵细胞和中央细胞两者质膜之间沉积所形成的一种非连续结构。（3）助细胞的明显特点是具丝状器,细胞器丰富,内质网发达,（4）中央细胞具大液泡,它的两个极核位于靠近卵器的一侧,细胞壁也有类似助细胞丝状器的结构。（5）授粉后4－5天,萝卜合子开始第一次分裂,胚胎发育遵循柳叶菜型模式。（6）萝卜初生胚乳核比合子早约2天分裂,属核型胚乳,在胚囊的合点端和珠孔端,曾出现胚乳的结节状聚集,授粉后第16天左右,从珠孔区胚乳开始了细胞壁自由生长和形成胚乳细胞的过程。     

萝卜胚胎早期发育的亚显微结构研究

本研究对萝卜（Raphanus sativus L.)的成熟胚囊,胚和胚乳的早期发育过程作了亚显微结构观察：（1）萝卜胚囊由7个细胞组成,成熟时反足细胞消失;（2）卵细胞表现明显的极性,其合点端不具完整的细胞壁,它是电子致密物质在卵细胞和中央细胞两者质膜之间沉积所形成的一种非连续结构。（3）助细胞的明显特点是具丝状器,细胞器丰富,内质网发达,（4）中央细胞具大液泡,它的两个极核位于靠近卵器的一侧,细胞壁也有类似助细胞丝状器的结构。（5）授粉后4－5天,萝卜合子开始第一次分裂,胚胎发育遵循柳叶菜型模式。（6）萝卜初生胚乳核比合子早约2天分裂,属核型胚乳,在胚囊的合点端和珠孔端,曾出现胚乳的结节状聚集,授粉后第16天左右,从珠孔区胚乳开始了细胞壁自由生长和形成胚乳细胞的过程。     

水稻胚囊卵器细胞发育期间超微结构变化的观察

通过透射电镜对水稻（ＯｒｙｚａｓａｔｉｖａＬ．）胚囊卵器发育过程中超微结构的变化进行观察,结果表明：卵器刚形成时,３个细胞均有完整的细胞壁,壁上分布着许多胞间连丝,不久各细胞合点极壁出现突起解体。随着卵器细胞进一步发育,合点极壁不断解体。到胚囊成熟时,卵细胞的合点极壁消失,仅留下一层质膜;助细胞由于出现退化,侧边近合点端壁出现断裂破碎解体。此时,３个细胞只在弯钩壁上观察到胞间连丝。卵器细胞不同发育阶段各种细胞器的变化很明显,其中最为明显的是质体和液泡。卵细胞在整个发育过程中大部分的质体都含有淀粉粒,而助细胞的质体在２个极核移向卵器上方时,质体内淀粉粒已消失,直至胚囊成熟也未重新出现;卵细胞液泡的出现时间、大小和位置与助细胞的有所不同,卵细胞液泡出现较迟,但到发育后期,液泡体积却明显比助细胞的大,液泡除了主要位于合点极外,珠孔极也有些液泡,而助细胞的则主要位于合点极。助细胞中脂滴的出现存在一个高峰期,即发生在胚囊近成熟时。助细胞核在发育早期呈椭圆形,位于近中部偏珠孔端,在发育中后期呈不规则形,位于近珠孔端壁旁边。水稻卵器发育过程中各细胞的超微结构变化充分反映其代谢规律。     

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。     

西瓜不同发育时期的助细胞超微结构的变化

被子植物胚囊的“雌性生殖单位”,已在多种植物上进行了超微结构的观察,但大多都以卵细胞受精前后的结构变化为主要研究内容。对于“雌性生殖单位”中的另一重要成员——助细胞,在不同发育状态下其结构变化的详细资料不多,尤其是助细胞退化后的物质去向,少见报道。本研究主要观察了西瓜不同发育时期(受精前后)、不同发育状态(柱头授粉和未授粉)的助细胞超微结构,以期为研究助细胞在双受精中所起作用提供新的资     

西瓜不同发育时期的助细胞超微结构的变化（简报）

The ultrastructure of synergids of watermelon (Citrullus Lanatus L.) was investigated using transmission electron microscopy at following stages of embryo sacs: 1. Unpollination, on the first flowering day. 2. Unpollination, on 2nd day after anthesis (DAA). 3. Fertilization, on DAA 2. The synergids with distinct filiform apparatus at the micropylar end have abundant organelle, such as mitochondria, endoplasmic reticulum, and plastids in cytoplasm, which indicate that they are active on the first flowering day. No wall is present at the chalazal part of synergid, and there are some flocculent materials and vesicles in the spaces of cytoplasma membranes among synergid, egg cell and central cell in embryo sacs at the first and the second stages. On DAA 2, in unpollinated embryo sacs, the central large vacuole of synergid is divided into several smaller ones and the starch grains decrease in cytoplasm. There is no newly synthesized wall at the chalazal end of persistent synergid in fertilized embryo sacs. The contents of degenerated synergid, in the form of electron dense granules, are located in the wide space among central cell, zygote and persistent synergid, and some of them migrate into central cell through cytoplasma membrane. Therefore, it is deduced that the contents of synergid might serve as a nutrient supplement to the development of endosperm, but not embryo.     

Structure of Embryo Sac Before and After Fertilization and Distribution of Transfer Cells in Ovules of Green Gram

The structure of embryo sac before and after fertilization, embryo and endosperm development and transfer cell distribution in Phaseolus radiatus were investigated using light and transmission electron microscopy. The synergids with distinct filiform apparatus have a chalazal vacuole, numerous mitochondria and ribosomes. A cell wall exists only around the micropylar half of the synergids. The egg cell has a chalazally located nucleus, a large micropylar vacuole and several small vacuoles. Mitochondria and plasrids with starch grains are abundant. No cell wall is present at its chalazal end. There are no plasma membranes between the egg and central cell in several places. The zygote has a complete cell wall, abundant mitochondria and plastids containing starch grains. Both degenerated and persistent synergids migh.t serve as a nutrient supplement to proembryo. The wall ingrowths occur in the central cell, basal cell, inner integumentary cells, suspensor cells and endosperm cells. These transfer cells may contribute to embryo nutrition at different developmental stages of embryo.     

The Ultracytochemical Localzation of Acid Phosphatase Activity in Wheat During Fertilization

No acid phosphatase activity was observed in the mature embryo sac of wheat (Triticum aestivum) except the chalazal cytoplasm Of the central cell before fertilization. During fertilization, acid phosphataseactivity was observed in the following loci: part of chromatin of the egg nucleus and most of the mitochondria in the egg cytoplasm; the perinuclear spaces of the egg and sperm nuclei at the fusion of the egg and sperm nuclei; the chalazal cytoplasm and some vacuoles of the degenerated synergid; two sperm nuclei within the cytoplasm of female cells; the cell wall of each cell of the embryo sac and that of the nucellar cells surrounding the embryo sac. No acid phosphatase was observed in the two-celled proembryo. Dense enzyme reaction product was localized in the chromatin of the free nuclei at early stage of the endosperm. The characteristic of acid phosphatase distribution during fertilization may be associated with the physiological change of the egg Cell, the reorganization of mitochondria in the egg cell cytoplasm, the degeneration of one of the two synergids, the physiological state of the sperm nuclei and the nuclear membrane fusion of the egg and sperm nuclei.     

The Ultrastructural Study on the Early Embryonic Development of Radish

The ultrastructure of the mature embryo sac, the early stages of the embryo and endosperm development of common radish, Raphanur sativus was examined. The embryo sac consists of 7 cells with antipodal ceils disappeared when it matures. The egg cell is highly polarized. The wall surrounded the chalazal end of the egg cell is incomplete, showing a discontinuous structure of an electron dense material deposited intermittently in the space between the two plasma membranes of the egg cell and central cell. The synergid has filiform apparatus, rich in organelles and well developed ER. The two polar nuclei of the central cell are located near the egg apparatus because of the big vacuole, and the finger-like protrutions from the cell wall, as that in synergid, are found. The first division of the zygote occurs 4–5 days after pollination and the development of the embryo follows the Onagrad type, and the structure of the embryo cell is quite simple for containing small quantity of ER, plastids and other organelles. The primary endosperm nucleus deviates 2 days earlier than zygote. The endosperm is of nuclear-endosperm containing chloroplasts, well developed ER, and plentiful of mitochondria and golgi bodies and the nodule-like aggregation in both. the chalazal and micropylar ends of the embryo sac during the early development appeared, and cell wall starting at the micropylar end by freely-growing forms about 16 days after pollination.     

Studies of Ultrastructure and ATPase Localization of Mature Embryo Sac in Vicia faba L.

Studies of ultrastructure and ATPase localization of the mature embryo sac in Vicia faba L. show that the egg cell has no cell wall at thechalazal end, it has a chalazally located nucleus and a large micropylar vacuole. There are many nuclear pores in the nuclear membrane. The cytoplasm is restricted around the nucleus. Dictyosome and mitochondria are few. There are some starch grains and lipid grains in the egg cytoplasm. There are no obvious differences between two synergids. No cell wall is seen at the chalazal end either, but there are some vesicles which project to vacuole of the central cell and fuse with its vacuolar membrane. Plasmodesmata connections occur within the synergid wall where it is adjacent to the central cell. The synergid has a micropylarly located nucleus and a chalazal vacuole, the nucleus is irregularly shaped. The synergid cytoplasm is rich in organelles. The filiform aparatus is of relatively heterogeneous structure. The central cell is occupied by a large vacuole and its cytoplasm is confined to a thin layer along the empryo sac wall, but is rich in various organelles, starch grains and lipid bodies. Nucleolar vacuoles are often present two polar nuclei. The nuclear membranes of two polar nuclei have partly fused. ATPase reactive product was located obviously at the endoplasmic reticulum in cytoplasm of the egg cell and central cell. The embryo sac wall consists of different density of osmiophilic layer. There are some wall ingrowths in chalazal region of the embryo sac. The long-shaped and cuneate cells of chalazal region are peculiar. Special tracks of ATPase reactive products are visible at their intercellular space which may be related to transportation of nutrients.     

An electron microscopic study of the mature megagametophyte in Zea mays

With light microscopy maize megagametophytes stained with Alcian blue-periodic acid-Schiff (AB-PAS) reveal acid or neutral polysaccharides in various cell walls. Comparative fine structural studies were made of permanganate- or OsO₄-fixed material. Organelle distribution is random in the vacuolate and multinucleate antipodal cells; organelles are abundant; starch is scarce. Antipodal cell walls have large openings forming several syncytia. Some walls are papillate. In the central cell (primary endosperm cell) a thin peripheral layer of cytoplasm surrounds the large vacuole; organelle number is moderate; starch is abundant. The central cell wall is also papillate adjacent to the antipodals and around the egg apparatus. In the synergids organelle distribution is non-random; nuclei and numerous organelles occupy the micropylar cytoplasm of each synergid; vacuoles dominate the chalazal cytoplasm of these cells. The filiform apparatus stains with AB-PAS and is composed of both lightly and darkly stained amorphous material. In the egg, organelle distribution is perinuclear with vacuoles proximal to the micropyle; mitochondria are large, abundant and polymorphic; starch is abundant. Nucleolar diameter is five times greater in the central cell and egg than in the antipodal cells and ten times greater than in the synergids. Plasmodesmata occur in all cell walls within the gametophyte, but none appear in the gametophyte wall itself. It is suggested that the antipodals and synergids might be secretory, the latter probably being involved in pollen tube attraction, and that stored metabolites in the central cell and egg cytoplasm support rapid increase in metabolism following fertilization.