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。     

白刺胚乳早期发育的超微结构研究

白刺(Nitraria sibirica)胚乳发育经历游离核阶段、细胞化阶段和被吸收解体阶段。游离核胚乳沿胚囊壁均匀排列为一层,胞质浓厚,其中有丰富的质体、线粒体、高尔基体、内质网和各种小泡等细胞器。珠孔区域的胚囊壁具发达的分枝状壁内突,而周缘区域的胚囊壁具间隔的钉状内突,内突周围的细胞质中具多数线粒体和小泡。胚乳细胞化时,初始垂周壁源于核有丝分裂产生的细胞板。在细胞板两端开始壁的游离生长,一端与胚囊壁相连接,另一端向心自由延伸。壁的游离生长依赖于小泡的融合。早期胚乳细胞具大液泡,具核或无核,细胞质中有大量的线粒体,质体缺乏,其壁仍由多层膜结构组成。     

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。     

荞麦糊粉层和子叶中贮藏蛋白质积累过程的超微结构

应用透射电镜技术对荞麦（Fagopyrum esculentum)子叶和糊粉层细胞中贮藏蛋白质的积累过程进行了研究。荞麦开花后15天,胚乳最外细胞的液泡中开始积累蛋白质。开花后25天,最外层胚乳细胞中积累较多的糊粉粒（直径1－2μm)形成糊粉层。开花后20天,子叶细胞中蛋白质开始在液泡和细胞质中积累,同时液泡通过膜的向内生长和缢裂两种方式形成体积较小的液泡。开花后25天,成熟的子叶细胞中含有丰富的蛋白质,贮藏蛋白质主要积累在液泡中形成体积较大的蛋白质贮藏液泡（PSVs,protein storage vacuoles,直径1－3μm）。在荞麦子叶积累蛋白质的各个阶段,细胞质中都有一些来源于高尔基体,含蛋白质的电子不透明小泡（直径0.1-0.7μm)存在,观察到有些小泡正进入液泡,推断这种来自高尔基体膜囊的小泡不仅将蛋白质运输到液泡形成PSVs的作用,也可能是荞麦成熟子叶积累贮藏蛋白质的一种结构。     

矮生菜豆胚乳细胞形成时的超微结构研究

应用透射电镜对矮生菜豆的游离核胚乳、胚乳细胞及珠被绒毡层的超微结构进行了观察,揭示了胚乳细胞化过程中自由生长壁的形成方式。实验表明,在游离核胚乳中存在大量有被小泡,胚乳游离核的外层核膜发生明显外突并以出芽的方式产生有被小泡。初始胚乳细胞壁为自由生长壁,大量有被小泡融合于自由生长壁末端使之不断延伸并产生分枝。与珠被绒毡层相邻的胚乳细胞产生发达的壁内突,具有传递细胞特征;在这些细胞中出现大量的核糖体及粗糙内质网,表现现高度的合成活性。     

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。     

花生胚乳细胞化过程的超微结构研究

花生胚乳细胞化过程的超微结构研究邢树平,席湘媛（山东农业大学植物学教研室,秦安２１１０１８）研究材料为海花一号。利用透射电镜观察了花生胚乳细胞化过程,结果如下：（－）游离核胚乳：心形胚期,胚乳游离核多沿胚囊壁分布,珠孔端和合点端较多,游离核的形状常不...     

降香黄檀次生韧皮部薄壁组织细胞液泡蛋白质的形成和积累的超微结构研究

热带豆科树木降香黄檀（Ｄａｌｂｅｒｇｉａｏｄｏｒｉｆｅｒａ）落叶时期末端小枝次生韧皮部薄壁组织细胞的中央液泡中有大量的贮藏蛋白质。用透射电镜技术研究了这些蛋白质的形成和积累。在这些细胞的周缘细胞质中有丰富的游离核糖体和许多粗糙内质网（ＲＥＲ）。在这些核糖体之间,总是分散着纤维状物质,有时还出现一些类似液泡蛋白质的结构。常常看到与ＲＥＲ相连的含有稀疏纤维状物质的小泡,以及含有类似液泡蛋白质的形状不规则的小泡和含有更多类似液泡蛋白质的光滑小泡。从连接ＲＥＲ的小泡到形状不规则小泡,再到光滑小泡,可能存在个体发生的连续性。通过内吞作用细胞质中的纤维状物质和核糖体以及其它结构被并入上述３种小泡。光滑小泡通常与中央液泡的膜融合而释放其内含物到液泡中。     

大葱卵器及受精后助细胞的超微结构

章丘大葱（Ａllium fistulosum L.cv.Zhangqiu)的卵器由１个卵细胞及２个助细胞组成,观察到不少卵器没有卵细胞,只有２个助细胞。卵细胞的核及大部分细胞质位于细胞的合点端,１个大液泡占据了细胞其他部位。卵细胞含有很多的核糖体及多聚核糖体、嵴明显的线粒体、粗面内质网、高尔基体具小泡,卵细胞似是一个活跃的细胞。细胞外被细胞壁,其合点端及侧方与助细胞共同壁不连续,助细胞有一较大的核,位于细胞膨大的部位,众多的小液泡遍布细胞中。核糖体及聚合核糖体、线粒体,粗面内质网及风心圆环状粗面内质丰富,高尔基体及小泡常见,反映了其活跃的代谢作用。助细胞合点端及侧方与卵细胞、中央细胞的共同壁不连续,与卵细胞共同壁含胞间连丝,壁不连续处,有不状多层膜结构伸入卵细胞质,显示助细胞可能对卵细胞提供营养,伟粉后,一个助细胞退化,宿存助细胞至随胚胚期尚存在,它经历了一个缓慢的退化过程,出现质壁分离,细胞质变稀,液泡扩大,细胞器逐渐减少,在椭形胚期,宿存助细胞核内的染色质及核仁消失,有细胞质侵入核内,因宿存助细胞壁变厚,细胞质出现现脂滴,宿存助细胞可能仍有合成功能,宿存助细胞壁出现若干无壁部位,细胞内的营养物质可能通过无壁部位向胚乳转运,供游离核胚乳及胚乳细胞化初期的发育。     

荞麦糊粉层和子叶中贮藏蛋白质积累过程的超微结构

应用透射电镜技术对荞麦(Fagopyrum esculentum)子叶和糊粉层细胞中贮藏蛋白质的积累过程进行了研究.荞麦开花后15天,胚乳最外层细胞的液泡中开始积累蛋白质.开花后25天,最外层胚乳细胞中积累较多的糊粉粒(直径1-2μm)形成糊粉层.开花后20天,子叶细胞中蛋白质开始在液泡和细胞质中积累,同时液泡通过膜的向内生长和缢裂两种方式形成体积较小的液泡.开花后25天,成熟的子叶细胞中含有丰富的蛋白质,贮藏蛋白质主要积累在液泡中形成体积较大的蛋白质贮藏液泡(PSVs,protein storage vacuoles,直径1-3μm).在荞麦子叶积累蛋白质的各个阶段,细胞质中都有一些来源于高尔基体、含蛋白质的电子不透明小泡(直径0.1-0 7μm)存在,观察到有些小泡正进入液泡,推断这种来自于高尔基体膜囊的小泡不仅有将蛋白质运输到液泡形成PSVs的作用,也可能是荞麦成熟子叶积累贮藏蛋白质的一种结构.     

Studies on the Development of the Embryo and Endosperm of Nitraria sibirica Pall

The pollen tube enters the embryo sac through the crassinucellus at the micropylar end, and brings about the porogamy. The embryogeny corresponds to the Solanad type. The defference of the suspensor structure is notable by comparing it with the other genera of Zygophyllaceae that have been studied. The endosperm is of the Nuclear type. Mitosis is the main form of the free endosperm nuclei proliferation. No cell plates develop in the early free nuclear division, however, they appear in late development, without developing into the cell wall and disappear ultimately. At the late globular embryo stage, cell formation in endosperm starts first from the micropylar end. The first anticlinal walls develop from the cell plate that is initiated from tile phragmoplast as a result of normal cytokinesis. Follwing this a wall begins to grow from the base of the cell plates, the outer growing margin soon fuses with the wall of the central cell, and the inner growing margin continues to grow towards the central vacuole. The growing walls branch and eventually fuse on the side nearest the central vacuole. Thus, the first periclinal walls are initiated, and a complete endosperm cell is formed. Along with the development of embryo, cell is gradually formed in the endosperm from the micropylar end towards the chalazal end, but the chalazal endosperm is still coenocytic until the endosperm disintegrate completely. The mature seed has no endosperm.     

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.     

Structure and function of the microtubular cytoskeleton during endosperm development in wheat: an immunofluorescence study

Summary The three-dimensional structure of the microtubular cytoskeleton of developing wheat endosperm was investigated immunocytochemically. Semi-thin sections were prepared from polyethylene glycol embedded ovaries. At the free-nuclear stage the endosperm cytoplasm with regularly distributed nuclei surrounded a large central vacuole and exhibited an extensive network of fluorescent labelled microtubular assemblies radiating from each nucleus. As was found in other coenocytes, this particular and nuclear-dependent cytoskeletal configuration functions in the arrangement of nuclei and in the stabilization of the nuclear positions. At the beginning of cellularization of the endosperm the formation of vacuoles altered the radiating networks. It is likely that the radiating microtubular arrays function in the formation of phragmoplasts, independent of nuclear divisions. The formation of anticlinal cell walls, giving rise to openended cell cylinders, coincides with the occurrence of phragmoplast microtubular arrays which were demonstrated during the period of cell wall elongation. The microtubular system radiating from the nuclei in these cell cylinders anchored the nuclei in stage- and locus-specific positions. During the development of aleurone and inner endosperm cells, cell morphogenesis was related to earlier demonstrated types of microtubular configurations in the cortical cytoplasm. This suggests that a general mechanism is involved.Abbreviations A alveolus - AL aleurone layer - CE central endosperm - CV central vacuole - DAP days after pollination - END endosperm - FITC fluorescein isothiocyanate - GAR-FITC goat anti-rabbit antibodies conjugated with FITC - I integument - IE PC inner epidermis pericarp - II inner integument - N nucleus - NC nucellus cells - NE nucellar epidermis - NUC nucellus - OI outer integument - PBS phosphate buffered saline - PC pericarp - PEG polyethylene glycol - V vacuole     

Polarization predicts the pattern of cellularization in cereal endosperm

Summary The endosperm of cereal grains develops as a multinucleate mass of wall-less cytoplasm (syncytium) that lines the periphery of the central cell before becoming cellular. The pattern of initial wall formation is precisely oriented and is followed by a round of precisely oriented formative cell division that gives rise to initials for the two tissues of endosperm. The initial anticlinal walls form at boundaries of nuclear-cytoplasmic domains (NCDs) defined by radial microtubules emanating from nuclei in the syncytium. Polarized growth of the NCDs in axes perpendicular to the embryo sac wall and centripetal elongation of the anticlinal walls results in a single layer of open ended alveoli overtopped by the remaining syncytial cytoplasm. This arboreal stage, so named because the elongate nucleate columns of cytoplasm resemble an orchard of trees, predicts the division polarity of the imminent formative division. Mitosis occurs as a wave which, like polarization, moves in both directions from ventral to dorsal. Spindles are oriented parallel to the long axis of the alveoli and cell plates give rise to periclinal walls. The outer daughter nuclei (aleurone initials) are thus completely enclosed by walls and the inner nuclei (starchy endosperm initials) are in alveoli adjacent to the central vacuole.     

Development of the endosperm in rice (Oryza sativa L.): Cellularization

The syncytial endosperm of rice undergoes cellularization according to a regular morphogenetic plan. At 3 days after pollination (dap) mitosis in the peripheral synctium ceases. Radial systems of microtubules emanating from interphase nuclei define nuclear-cytoplasmic domains (NCDs) which develop axes perpendicular, to the embryo sac wall. Free-growing anticlinal walls between adjacent NCDs compart-mentalize the cytoplasm into open-ended alveoli which are overtopped by syncytial cytoplasm adjacent to the central vacuole. At 4 dap, mitosis resumes as a wave originating adjacent to the vascular bundle. The spindles are oriented parallel to the alveolar walls and cell plates formed in association with interzonal phragmoplasts result in periclinal walls that cut off a peripheral layer of cells and an inner layer of alveoli displaced toward the center. Polarized growth of the newly formed alveoli and elongation of the anticlinal walls occurs during interphase. The next wave of cell division in the alveoli proceeds as the first and a second cylinder of cells is cut off inside the peripheral layer. The periods of polarized growth/anticlinal wall elongation alternating with periclinal cell division are repeated 3–4 times until the grain is filled by 5 dap.     

The Development of Green Onion (Allium Fistulosum L. )Embryo and Endosperm

Embryo development of Zhangqiu green onion conforms to the Asterad type and goes through the following stages: proembryo, globular, ellipsoidal, laterally concave, stick-shaped, and curved and mature. The persistent synergid is present until the late globular stage of embryogenesis. Endosperm development of Zhangqiu green onion follows the nuclear pattern. Endosperm cell formation begins at both the micropylar end and the chalazai end of the embryo sac when the embryo is in the late globular stage. Due to the anticlinal wall formation, a layer of free nuclei becomes a layer of “open cells” which lack the inner periclinat wall. The open cells undergo cell division periclinally, and a layer of complete cells is cut off outside and a new layer of open cells inside. The subsequent cell divisions give rise to the endosperm cells centripetally until those from the opposite of the embryo sac meet. The first anticlinal walls arise from the cell plates without phragmoplasts between the free nuclei in interphase. The first periclinal walls are formed by normal cytokinesis. When a few layers of endosperm cells are formed at the micropylar end and the chalazal end of the embryo sac, free cells are present in the central vacuole.     

Cytokinesis in the developing wheat grain; Division with and without a phragmoplast

Summary Cell wall formation during the transition from free-nuclear to cellular endosperm of wheat (Triticum aestivum L. cv. Heron) was investigated using correlated light and electron microscopy. Partitioning of the multinucleate syncytium that lines the inner periphery of the embryo sac is initiated 1–2 days after anthesis. Wall ingrowths, at first recognizable in sections as minute wall pegs, furrow inward from the edge of the embryo sac through the vacuolate cytoplasm which, to the inside, is clearly delimited by the central vacuole. Growth of the walls at this stage is independent of a phragmoplast and in this respect is reminiscent of the cleavage processes of lower plant cells. Intense fluorescence of the walls after staining with aniline blue suggests that callose may be a principal component. The growing walls branch and eventually meet on the side nearest the central vacuole. Cellularization of the peripheral layer of endosperm cytoplasm is thus complete about 2 days after anthesis. Between 2 and 3 days after anthesis, the peripheral layer of cells commences to divide both radially and tangentially and by 4 days the entire embryo sac is cellular. Cytokinesis during this phase entails the formation of a cell plate between sister nuclei. At the periphery of a forming cell plate, vesicles appear scattered amongst an array of phragmoplast microtubules. This mechanism of wall growth differs markedly from the initial infurrowing of the first-formed walls. The overall timing and the manner of cell wall deposition vary in a number of important respects from the model recently proposed by Mares et al. whose work was based largely on light microscopy (D.J. Mares; K. Norstog; A.B. Stone: Aust. J. Bot. 23, 311–326, 1975).Abbreviations CV central vacuole - D dictyosome - En endosperm - ER endoplasmic reticulum - II inner integument - m mitochondrion - MTs microtubules - N nucellus - NE nucellar epidermis - Nu nucleus - S starch - V vacuole - W embryo sac wall This work was supported by grants from the Australian Research Grants Committee and the Reserve Bank of Australia (to T.P. O'B.) while one of us (I.N.M.) received financial assistance from the Australian Government through the Commonwealth Scholarship and Fellowship Plan.     

Microtubular configurations during the cellularization of coenocytic endosperm in Ranunculus sceleratus L.

Summary Endosperm cellularization in Ranunculus sceleratus was studied in terms of the initiation of cell-wall formation in the coenocytic endosperm. The first endosperm cell walls were in an anticlinal position relative to the cell wall of the embryo sac and originated from the cell plates and not from wall ingrowths from the embryo-sac wall itself. Alveolar endosperm was formed 3 days after pollination. Microtubules were associated with the freely growing wall ends of the anticlinal walls and were observed in various orientations that generally ranged from angles of 45 ° to 90 ° to the plane of the wall. They were absent in the regions where vesicles had already fused. These microtubules may function in maintaining the growth and the direction of growth of the anticlinal wall until cellularization is completed. At the site where three neighbouring alveoli share their freely growing wall ends, remarkable configurations of microtubules were observed: in each alveolus, microtubules ran predominantly parallel to the bisector of the angle formed by the common walls. These microtubules may form a physically stable framework and maintain the direction of growth of the wall edges. It is concluded that the growing edge of the anticlinal endosperm wall and its associated microtubules are a special continuum of the original phragmoplast that gave rise to the anticlinal wall.