甜菜无融合生殖单体附加系M14成熟胚囊的超微结构特征

以甜菜无融合生殖单体附加系M14（Betavulgaris,2n=18＋1）为实验材料,利用电子显微镜技术对成熟胚囊及其超微结构进行研究。结果表明：M14成熟胚囊包括1个卵细胞、2个退化的助细胞、1个具有次生核的中央细胞和3-6个反足细胞。其卵细胞具有3种不同的形态：（1）极性正常的卵细胞,细胞核位于合点端,细胞质含有大量核糖体、线粒体、内质网等细胞器;（2）细胞核位于细胞中央;（3）细胞核位于珠孔端,且后2种形态细胞器的种类与数量少。大多数胚囊中的2个助细胞在开花前已退化。中央细胞的次生核位于反足细胞附近;未经受精自发分裂前的卵细胞与中央细胞的细胞核大、核仁明显,细胞器的种类与数量多,呈现旺盛代谢活动特征,成为二倍体孢子无融合生殖过程中,卵细胞与次生核自发分裂的细胞学标志。     

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。     

甜菜无融合生殖单体附加系M14 成熟胚囊的超微结构特征

以甜菜无融合生殖单体附加系M14(Beta vulgaris, 2n=18+1)为实验材料, 利用电子显微镜技术对成熟胚囊及其超微结构进行研究。结果表明: M14成熟胚囊包括1个卵细胞、2个退化的助细胞、1个具有次生核的中央细胞和3-6个反足细胞。其卵细胞具有3种不同的形态: (1)极性正常的卵细胞, 细胞核位于合点端, 细胞质含有大量核糖体、线粒体、内质网等细胞器; (2)细胞核位于细胞中央; (3)细胞核位于珠孔端, 且后2种形态细胞器的种类与数量少。大多数胚囊中的2个助细胞在开花前已退化。中央细胞的次生核位于反足细胞附近; 未经受精自发分裂前的卵细胞与中央细胞的细胞核大、核仁明显, 细胞器的种类与数量多, 呈现旺盛代谢活动特征, 成为二倍体孢子无融合生殖过程中, 卵细胞与次生核自发分裂的细胞学标志。     

黑脊倒刺鲃卵子发生中生殖质的产生

采用光学和电子显微镜对黑脊倒刺的卵原细胞和各期卵母细胞中生殖质的形成过程进行观察。仅在卵原细胞和Ⅱ时相卵中观察到了生殖质的产生过程 ,在Ⅲ、Ⅳ时相卵中未观察到生殖质的产生过程。生殖质来源于核仁。它从细胞核中释放出来 ,进入细胞质。卵原细胞和卵母细胞产生生殖质的方式不同。在卵原细胞的生殖质形成过程中 ,生殖质的前体物质先移到核膜内侧 ,核膜解体 ,形成囊泡 ,随后 ,在生殖质前体物质所在处的内侧重新形成核膜 ,这样 ,细胞核表面就形成一个凹陷 ,生殖质前体物质位于核表面的凹陷之中 ,就这样被隔离于细胞核之外而进入细胞质中 ,成为生殖质。生殖质形成后 ,在细胞质中与线粒体相结合。生殖质的这种形成方式与精原细胞中拟染色体的形成方式相似。而在卵母细胞的生殖质形成过程中 ,生殖质的前体物质移到核膜内侧之后 ,核膜并无囊泡化 ,核孔明显 ,生殖质的前体物质通过核孔离开细胞核 ,位于细胞核表面 ,形成生殖质。生殖质产生之后也与线粒体结合。以后 ,生殖质连同线粒体离开细胞核。生殖质最终与线粒体分离 ,分散于细胞质中。在Ⅲ时相卵中 ,生殖质细小 ;在Ⅳ时相卵中 ,几乎见不到生殖质     

甘蓝型油菜珠孔与胚囊的超微结构研究

甘蓝型油菜的外珠孔基本上为开放结构,内珠孔为闭合结构。胚囊成熟时反足细胞已退化,仅由二个助细胞、一个卵细胞、与一个中央细胞组成。助细胞极性不明显,二个助细胞在花粉管到达前均显示同等退化迹象。卵细胞极性明显。中央细胞中含结构独特的质体。受精前,卵与中央细胞的质膜之间含有特殊的电子致密物质。     

水稻中央细胞发育期间超微结构变化的观察

本文通过透射电镜对水稻受精前胚囊中央细胞发育过程中超微结构的变化进行观察。结果表明,八核胚囊形成后很快就进行细胞化形成7个细胞,其中刚形成的中央细胞由1个大液泡、2个极核（珠孔端和合点端各1个）和一些含有丰富细胞器的胞质组成。中央细胞以后的发育主要是极核的发育和极核周围胞质的变化。极核发育经历以下过程：a．2个核都膨大呈“椭圆”形。核周围胞质呈不对称分布。b．2个核分别向胚囊中央移动并相互靠近。之后2个极核调整排列方式,由纵排（即与胚囊纵轴平行）变成横排。此时期有细胞质“桥”联结珠孔端卵器、2个极核和合点端反足细胞器。c．横排的极核移向卵器,并排列于卵细胞之上。此时胚囊未明显膨大,但极核相靠近的两边核膜有许多处已形成“融合桥”,核周围的胞质也起较大的变化,如质体内淀粉消失和光面内质网增加等。极核进一步发育直至胚囊成熟期间,极核排列方式及其周围胞质组成未观察到明显的变化,但胚囊体积明显增大。     

水稻PDER品系的特点和二倍体孢子生殖胚囊的形成和发育

对水稻（ＯｒｙｚａｓａｔｉｖａＬ．）早发生胚ＰＤＥＲ（ｐｒｅ－ｄｅｖｅｌｏｐｅｄｅｍｂｒｙｏｏｆｒｉｃｅ）品系的特点和细胞胚胎学研究表明,ＰＤＥＲ是二倍体植物２ｎ＝２４,约有５０％胚囊的卵细胞未经受精能自行发育形成胚,成熟种子的萌发和生长速度较常规正常水稻快。ＰＤＥＲ的大孢子母细胞经有丝分裂产生未减数的胚囊,即无融合生殖中的二倍体孢子生殖类型。在胚囊形成和发育过程中有如下几个特点：（１）孢原细胞至大孢子母细胞分裂前的过渡期持续时间较长,孢原细胞和大孢子母细胞的细胞质比周围的珠心细胞质稀淡。（２）大孢子母细胞经二次有丝分裂后形成直线排列的三个细胞（三分体）,珠孔端的两个解体,合点端的一个发育为功能细胞,有少数胚囊的三个细胞全部解体形成败育胚囊。（３）功能细胞经三次连续核分裂形成具八核七个细胞的成熟胚囊,它的结构与常规正常水稻基本相同,但助细胞呈长形而没有回抱着卵细胞。     

非洲狼尾草无融合生殖胚胎学研究

报道非洲狼尾草（ＰｅｎｎｉｓｅｔｕｍｓｑｕａｍｕｌａｔｕｍＦｒｅｓｅｎ）的胚囊形成、胚胎发生与发育过程。非洲狼尾草的孢原细胞直接发育成大孢子母细胞,并由它分裂产生三分体。从大孢子母细胞发育至三分体的不同阶段,均会出现败育。性细胞退化期间,其周围的珠心组织中,常出现一至多个体积较大的无孢子生殖原始细胞。通常只有靠近珠孔端的１个无孢子生殖原始细胞体积进一步增大,并出现大液泡,发育成无孢子生殖单核胚囊。随后,其核经连续两次有丝分裂,形成无孢子生殖四核胚囊,胚囊内的４个核常聚积在珠孔端,４个核进一步分化形成１个卵细胞、１个助细胞和具两个极核的中央细胞,没有反足细胞。胚囊发育属于大黍型。其它的无孢子生殖原始细胞能发育到单核或二核胚囊阶段,而后核解体导致胚囊败育。胚的发生有两种类型：（１）早发生胚。大多数胚囊在开花前一、二天,次生核未分裂,卵细胞不经受精,自发分裂形成胚。（２）迟发生胚。少数胚囊的卵细胞不经过受精,但需要在开花后三、四天次生核分裂为多个胚乳核时才开始分裂。无论是早发生胚或迟发生胚,卵细胞在分裂前具有极性,珠孔端有大液泡,细胞质稀薄,合点端细胞质较浓。胚的发育经历球形胚、梨形胚和胚分化阶段。     

刺五加开花后雌蕊的发育状态与受精作用

刺五加Eleutherococcus senticosus(Rupr． et Maxim．)Maxim．植株在开花后雌配子体的发育状态与 一般植物不同在于:雌配子体在开花当天均末成熟,在开花后经4-5天才发育成熟。开花第6天,雌株 和两性株的成熟胚囊百分率各为82．25％和67．25％,其余为未育、败育、退化或未成熟胚囊,未观察到 已受精的胚囊;而此时,雄株的雌配子体退化、花朵全部脱落。伴随着胚囊的分化,刺五加雌株和两性株 的花柱逐渐延长,蜜腺渐趋成熟。开花后4～6天,乳突细胞发育,柱头开始外翻;此后,蜜腺分泌花蜜, 柱头进入可授期。开花第7天,胚囊开始受精。开花后9～10天,雌株已受精的胚囊占胚囊总数的40～ 65％,两性株已受精的胚囊占胚囊总数的25～41％。刺五加花粉萌发至雌雄性核融合的间隔期约为2 ～3天。刺五加的双受精过程与一般被子植物基本相同。其受精作用属于有丝分裂前配子融合类型。 此外,还观察了成熟胚囊退化的类型,观察到多余花粉管进入胚囊以及两个精子与卵受精、两个精子与次生核融合的图象。     

赤苎无融合生殖细胞胚胎学研究

对赤苎(Boehmeria silvestrii (Pamp.)W.T.Wang)细胞胚胎学研究表明,其生殖模式属无融合生殖的二倍体孢子生殖(diplospory),但其未减数胚囊的发育途径不同于已报道的类型。大孢子母细胞的减数分裂I在到达终变期时停滞,染色体呈单价体状态并维持较长的时间。在尚未到达以核膜、核仁消失,纺锤体出现为特征的中期I前,大孢子母细胞由终变期直接“跳”入间期,从而始终保持了二倍体水平。减数分裂Ⅱ正常进行并产生二倍体二分孢子。珠孔端孢子退化,合点端孢子经3次分裂形成包括1个卵细胞、2个助细胞、2个极核和3个反足细胞的八核胚囊。胚和胚乳分别起源于卵和次生核未受精的自发分裂。胚乳属核型,其发育早于胚。     

Study on Degeneration of Unfertilized Aposporous Embryo Sac in Pennisetum squamulatium (Gramineae)

To understand the degeneration of unfertilized aposporous embryo sac in an aposporous species Pennisetum squamulatum, the central cell in the unfertilized embryo sac was characterized ultrastructurally . The most prominent sign of degeneration is that the central cell nucleus produced nuclear vacuoles . These nuclear vacuoles can be classified into singleanddouble- layered types . Single- layered nuclear vacuoles are found in the cytoplasm, while the double-layered are inside the nucleus . There are two ways to produce nuclear vacuoles . One is that the outer membrane of the nuclear envelope distends towards the cytoplasm to form nuclear vacuoles ; and the other is the double-layered nuclear envelope derives vacuoles by depressing inwards . Nuclear envelope types are in relation to the ways they are produced . All nuclear vacuoles absorb cytoplasm or nuclear matrix , and trap organelles such as mitochondria .     

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.     

Ultrastructural characterization of apospory in Panicum maximum

The nucellar ultrastructure of apomictic Panicum maximum was analyzed during the meiocytic stage and during aposporous embryo sac formation. At pachytene the megameiocyte shows a random cell organelle distribution and sometimes only an incomplete micropylar callose wall. The chalazal nucellar cells are meristematic until the tetrad stage. They can turn into initial cells of aposporous embryo sacs. The aposporous initials can be recognized by their increased cell size, large nucleus, and the presence of many vesicles. The cell wall is thin with few plasmodesmata. If only a sexual embryo sac is formed, the nucellar cells retain their meristematic character. The aposporous initial cell is somewhat comparable to a vacuolated functional megaspore. It shows large vacuoles around the central nucleus and is surrounded by a thick cell wall without plasmodesmata. In the mature aposporous embryo sac the structure of the cells of the egg apparatus is similar to each other. In the chalazal part of the egg apparatus the cell walls are thin and do not hamper the transfer of sperm cells. Structural and functional aspects of nucellar cell differentiation and aposporous and sexual embryo sac development are discussed.     

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.     

东北地区野豌豆属VICIAL．物种生物学研究Ⅷ．幼苗形体结构动态和种间界限

在野外居群调查的启示下,本文以组件观点对柳叶野豌豆复合种和歪头菜幼苗亚单位的时序变化与开花关系进行了分析。结果发现在柳叶野豌豆复合种栽培居群中存在打破物种间形体结构特征的个体,即在复叶由一对小叶组成的植株就已开花而进入生殖时期。另外,在歪头菜的野生居群中发现由三或四枚小叶组成复叶的个体,因此,我们推测这种形体结构的变化可能暗示着柳叶野豌豆复合种和歪头菜有着共同的祖先。     

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。     

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.