银杏雌性生殖器官发育过程的显微观察

对银杏(Ginkgo biloba)雌性生殖器官的发育过程进行了连续显微观察.结果表明:功能大孢子经过大约1个月的分裂形成约5000个游离核后开始细胞化.授粉后约45天近珠孔端两侧各产生1个颈卵器母细胞.授粉后约50天.颈卵器母细胞平周分裂形成初生颈细胞和中央细胞.授粉后约55天,初生颈细胞垂周分裂形成2个扁平状次生颈细胞,之后次生颈细胞体积逐渐增大并突入颈卵器腔.授粉后约130天,2个次生颈细胞斜向分裂形成4个颈细胞,中央细胞不均等分裂形成腹沟细胞和卵细胞.套细胞起源于颈卵器母细胞的周围细胞,授粉后70天至受精作用发生前,套细胞内不断积累营养物质,且套细胞与中央细胞间的细胞壁以及套细胞之间角隅处的细胞壁均出现明显增厚现象.在受精及胚胎早期发育过程中,套细胞内营养物质逐渐消失,细胞逐渐解体.授粉后55天,2个颈卵器之间的一些细胞向上突起形成帐篷柱,之后帐篷柱体积逐渐增加,并突入颈卵器腔.自授粉后120天至受精前帐篷柱细胞内开始积累大量营养物质,随后这些营养物质在受精过程中被逐渐消耗.到了原胚游离核后期,帐篷柱的顶端细胞发生变形并解体.     

银杏套细胞发育的解剖学研究

银杏套细胞起源于近雄配子体表达的颈卵器母细胞周围细胞,中央细胞形成时,套细胞呈明显的一层,围绕颈卵器紧密排列,随着颈卵器的发育,套细胞体积逐渐地大,细胞质变浓厚,细胞质中脂滴增多,套细胞和中央细胞的接触壁开始出现局部加厚,在颈卵器发育的泡沫化阶段,套细胞和中央细胞的接触壁不均匀加厚较为显著,在较薄的区域可见胞间连丝,受精前,套细胞中液泡增多,脂滴迅速减少,造淀粉体增大,套细胞与卵细胞的接触壁的不均匀加厚非常明显,精核进入颈卵器以后,卵细胞与套细胞的接触壁和卵细胞的质膜之间形成一个薄厚不均的间隔层,受精卵分裂时,受精卵细胞与套细胞接触壁的凹陷处可见许多小泡和内质网,游离核期时,套细胞内出现大量小液泡,细胞内含物迅速消失,套细胞外形变长,胚胎长出颈卵器后,套细胞逐渐解体消失。     

樟子松大孢子的发生和雌配子体的形成过程

樟子松大孢子母细胞经一系列变化,发育成雌配子体。在哈尔滨地区樟子松大孢子母细胞于每年6月8～14日形成,接着进行减数分裂,于6月16～20日形成大孢子。随着大孢子核的分裂,进入游离核时期,并于次年5月28日～6月4日形成细胞壁,幼雌配子体中出现颈卵器原始细胞,它分裂一次形成颈细胞和中央细胞。6月7～9日中央细胞分裂成卵细胞和腹沟细胞,6月13～15日颈卵器发育成熟。成熟的颈卵器含有颈细胞、腹沟细胞和卵细胞,但颈细胞和腹沟细胞已经退化。     

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。     

地钱颈卵器发育和卵发生的显微观察及细胞化学研究

对地钱（Marchantia polymorpha）颈卵器发育和卵发生过程进行了显微观察和细胞化学的研究,颈卵器起始于原始细胞,该细胞呈乳突状,经横分裂产生基细胞和顶细胞,顶细胞经3次纵斜向分裂和1次横分裂产生初生细胞,初生细胞是颈卵器内的第一个细胞,经横分裂产生中央细胞和颈沟母细胞,前者产生1个腹沟细胞和1个卵细胞,后者最终产生4个颈沟细胞。颈卵器的成熟表现为颈部显著伸长和腹部膨大,卵细胞成熟时具有不规则的核,细胞质内含有丰富的囊泡和颗粒物,卵细胞周围充满粘性物质,细胞化学研究表明,该粘性物质为多糖,卵细胞质中深染色的颗粒可能为脂类物质,腹沟细胞自产生后就逐渐退化,颈沟细胞的退化迟于腹沟细胞,其数量通常为4个,偶尔可见5个颈沟细胞或具有双核的现象。     

蓝猪耳受精过程中中央细胞和初生胚乳细胞中微丝骨架的组装和细胞核的迁移

通过对蓝猪耳(Torenia fournieri)活体胚囊的研究,发现中央细胞和初生胚乳细胞中的微丝骨架在细胞核迁移时发生了显著的变化.授粉前,微丝在中央细胞的周质位置呈现短束状随机分布.开花两天后,它们组装成截然不同的微丝网络,在这个阶段,次生核位于中央细胞中央位置并与短束状的微丝列阵相联系.在授粉发生后不久,分布在珠孔端的微丝发生片断化,此时次生核与卵器相邻.受精后,初生胚乳细胞核从卵细胞处移开, 在初生胚乳细胞中微丝又重组形成清晰的网络结构.用latrunculin A (LAT-A)和细胞松弛素B(cytochalasin B,CB)破坏微丝骨架,得到的试验结果说明,微丝参与了中央细胞中的细胞核迁移运动.数据也表明,在受精过程中,微丝骨架的动力学特性在中央细胞和初生胚乳细胞的胞质重组中起重要作用.     

福建柏受精作用的研究

福建柏精原细胞分裂后,产生两个形态和大小都相同的雄配子——精子;精子形成时,犹如两个相连的半球体,各具细胞壁。中央细胞分裂产生腹沟核和卵核,腹沟核形成后逐渐退化;卵核却迅速增大。6月下旬,精核在颈卵器中部或中上部与卵核相遇,进行受精作用。在精卵融合过程中,进入卵细胞的雄细胞质,逐渐包围受精卵,并与部分卵细胞质结合形成新细胞质。受精后,在新细胞质中,又呈现大量淀粉粒。当受精卵移到颈卵器底部时,合子开始进行第一次有丝分裂。在原胚和幼胚发育阶段,多余精核还可进入卵细胞,并进行有丝分裂,以致形成7—8个游离核。     

黑节草双受精过程及胚胎发育的研究

黑节草从传粉到受精约需１３０ｄ,精子在花粉管中形成,胚囊发育属蓼型胚囊,因反足细胞较早退化,故受精前胚囊多只由卵器和中央细胞组成。精卵核融合时,精核染色质进入卵核后凝集成颗粒状,并在原位与卵核的染色质融合,雌、雄性核仁一直维持至合子的第一次分裂期前。双受精作用正常,属于有丝分裂前配子融合类型,初生胚乳核发生２－３次分裂后逐渐退化消失,胚的发育局限于球形胚阶段。     

阔鳞瘤蕨颈卵器形成与卵发生的初步研究

运用光学显微镜与透射电镜对阔鳞瘤蕨（Phymatosorus hainanensis(Noot.) S.G.Lu）颈卵器形成和卵发生进行了研究。阔鳞瘤蕨颈卵器产生于雌配子体生长点下方分枝毛状体内侧。切片观察表明颈卵器起源于配子体表面的原始细胞,该细胞经两次不等分裂形成3个细胞,上下两个细胞分别发育为颈卵器的颈部与底部壁细胞,中间的细胞为初生细胞,含有较丰富的细胞器。初生细胞进行两次不等分裂产生颈沟细胞、腹沟细胞与卵细胞。成熟颈卵器内颈沟细胞和腹沟细胞退化,卵细胞上表面产生受精孔。本研究阐述了阔鳞瘤蕨颈卵器形成和卵发生的细胞学过程,对阐明蕨类植物雌性生殖器官的发育特征有一定的科学意义。     

The Gametophytes and Fertilization in Pseudotaxus

The development of the gametophytes and fertilization of Pseudotaxus chienii Cheng has been investigated. Pollination first occurred on April 17 (1964). The pollen grains shed at the uninucleate stage and germination on the nucellus is almost immediate. The pollen tubes approached the freenucleate female gametophyte about May 5. The spermatogenous cell is continuously enlarging with the growth of the pollen tube and two unequal sperms are formed after its division. Occasionally the small sperm may divide further into two smaller ones. During pollination the megaspore mother cell is in meiosis and 3 or 4 megaspores are formed. Generally 2 or 3 megaspores at the micropylar end are going to degenerate while the chalaza] megaspore is rapidly enlarging. After 8 successive simultaneous divisions of the functional megaspore 256 free nuclei are resulted and they are evenly distributed at the bulge of the famale gametophyte. Then the wall formation follows. Sometimes there are more than two, even as many as 5–6 gametophytes developed within a single ovule. The archegonial initials become differentiated at the apical end of the female gametophyte. They are usually single and apical, rarely lateral in position. The number of the archegonia vary from 3 to 7, usually 4–6. There are 2–8 neck cells in each archegonium which is surrounded by a layer of jacket cells. The central cell divided about May 20–26 (1964) and the division of the central cell gives rise to the egg and the ventral canal nucleus, the latter being degenerated soon. There are many proteid vacuoles near the nucleus of the matured egg. The fertilization took place about May 23–26 (1964). At first, the pollen tube discharges its contents into the egg, then the larger sperm fuses with the egg nucleus in the middle part of the archegonium. At the same time the male cytoplasm also fuses with the female cytoplasm and a layer of densely-staining neocytoplasm is formed around the fused nucleus. The smaller sperm, tube nucleus and sterile cell usually remain in the cytoplasm above the egg nucleus for some time. Based upon the observations of the development of the gametophytes and fertilization the authors conclude that Pseudotaxus is more close related to Taxus than any other member of Taxaceae.     

Development of Embryo and Fruit in Ipomoea batatas Lam

This paper deals with the development of the embryo and the formation of the fruit for lpomoea batatas Lam. based on the observation of its flower bud differentiation, megasporogenesis and the development of the female gametophyte, microsporogenesis and the development of the male gametophyte. The pollen grain germinated on the stigma about 10–30 min. after pollination. The pollen tube penetrated the transmitting tissue in the middle of the style between 30–60 min. after pollination. After 2 hours the tip of the pollen tube reached the micropyle. Double fertilization completed after 5 or 12 hours then the zygote and the endosperm nucleus formed. The first mitotic division of the endosperm nucleus takes place about 12 hours after pollination, earlier about 3 hours than the first division of the zygote, the latter gives rise to a terminal cell and a basal cell by a transverse division. The second division is transverse in the terminal cell, forming two cells. The basal cell divides longitudinally into two adjoining cells. The terminal cell becomes the proembryo with four cells, and at the same time, the basal cell becomes the suspensor with four cells after 41–52 hours. The proembryo gradually becomes globular, cordate and torpedo-shaped, respectively about 96–120, 144–156, 168-192 hours after pollination. The cotyledons of the embryo gradually prolongate 10 days after pollination. The embryo almost completes its development within 21–30 days after pollination. he fruit is a capsule. The ovary gradually swells 3–4 days after pollination, then forms fruit, which ripens about 21–30 days after pollination, 2R.=4–8 mm. A fruit contains 1–4 seeds. 7,000 fruits were analysed in 1983, the results are as follows: 64.6% of then with only one seed in a capsule, 31.8% two seeds, 5.48% three seeds and 0.1% four seeds. The seeds are small, 2R. from 3.84 mm to 2.84 mm. The shape and the weight of the seeds are different from each other because of difference in number of seeds within a capsule.     

银杏雌雄配子体发育及胚胎形成的研究进展

银杏(Ginkgo biloba)是现存最古老的裸子植物之一, 其生殖过程表现出许多原始特征和独特性状, 长期以来备受国内外专家的关注。经过近100年的研究取得了显著成果: (1) 银杏雄配子体发育周期长, 经历了从平周分裂到斜背式分裂,并最终垂周分裂形成带有鞭毛的游动精子; (2) 银杏雌配子体发育经历较长的游离核期和细胞化期, 分化形成颈卵器母细胞并经平周分裂、垂周分裂和斜向分裂形成成熟的颈卵器(包括有4个颈细胞和1个卵细胞); (3) 推测其精细胞中的液泡状结构为受精过程中的遗传物质载体; (4) 原胚的形成经历了游离核期和细胞化期。该文针对国内外最新银杏生殖生物学方面的研究进展, 对银杏雌雄配子体发育、受精过程以及胚胎形成等方面进行较为系统全面的分析和总结, 为进一步的银杏生殖生物学研究提供有价值的参考资料。     

侧金盏花双受精进程研究

应用荧光显微镜和常规石蜡切片观察侧金盏花(Adonis amurensis)花粉管生长和受精作用的全过程。结果表明,侧金盏花为湿型柱头,授粉后1–2小时,花粉粒与柱头识别;授粉后2–4小时,花粉粒萌发;授粉后4–6小时,花粉管进入柱头。侧金盏花的受精模式为珠孔受精,授粉后10小时,精子被释放;授粉后30小时,精核与卵核融合;授粉后7天合子形成;授粉后15天合子进入分裂期,合子休眠期为8天。2个极核在受精前不融合,授粉后14–16小时,精核与1个极核融合;授粉后20–22小时,受精极核与另1个极核融合形成初生胚乳核。双受精作用属于有丝分裂前配子融合型。通过实验确定了侧金盏花受精过程的雌雄性细胞融合形态变化与相应经历的时间及其合子休眠期。研究结果丰富了侧金盏花胚胎学资料,对其今后的育种及转基因研究具有重要意义。     

腊梅的受精作用及胚胎发生

腊梅(Chimonanthus praecox)花两性,离心皮雌蕊着生在杯状花托上,柱头线形,干性。花粉经昆虫传播,落在柱头上1 d后萌发,第8d从珠孔进入,第14d左右完成双受精,为珠孔受精。胚乳为核型胚乳;初生胚乳核经短暂休眠进行核分裂,位于合点端的游离核首先形成细胞,并从合点向珠孔端细胞化,第37d胚乳充满整个囊腔。合子经过近2周的休眠后开始分裂,随着胚的发育,大部分胚乳降解,为胚的发育提供营养。合点端的胚乳细胞则侵入合点珠心组织,为胚进一步发育提供营养。其胚胎发生为柳叶菜型。     

腊梅的受精作用及胚胎发生

腊梅 (Chimonanthuspraecox)花两性 ,离心皮雌蕊着生在杯状花托上 ,柱头线形 ,干性。花粉经昆虫传播 ,落在柱头上 1d后萌发 ,第 8d从珠孔进入 ,第 1 4d左右完成双受精 ,为珠孔受精。胚乳为核型胚乳 ;初生胚乳核经短暂休眠进行核分裂 ,位于合点端的游离核首先形成细胞 ,并从合点向珠孔端细胞化 ,第 37d胚乳充满整个囊腔。合子经过近 2周的休眠后开始分裂 ,随着胚的发育 ,大部分胚乳降解 ,为胚的发育提供营养。合点端的胚乳细胞则侵入合点珠心组织 ,为胚进一步发育提供营养。其胚胎发生为柳叶菜型。     

Cytological study of pollen tube growth and early seed development inPetunia inflata

Pollen tube growth from the stigma into the ovule, and the early fruit and seed development following fertilization were examined using fluorescence microscopy, scanning electron microscopy and light microscopy inPetunia inflata. After growing intercellularly in the transmitting tract for 24–36 hr, the pollen tubes emerged into the top part of the ovary cavity and grew along the surface of the septum to reach the ovule. It grew around the furnicle and penetrated the micropyle to enter the embryo sac for fertilization. After fertilization, the endosperm nucleus divided first before the embryo, and the cell wall formation occurred following the division, exhibiting the pattern of cellular type of endosperm development. The first division of the zygote did not occur until 3 days after pollination. At 6 days after pollination, the seeds grew considerably and the endosperm has gone through multiple rounds of cell division. High starch formation in the integument, especially around the embryo sac, was also observed.     

Invvestigations on Early Embryogenesis of Actinidia chinensis Planch var. chinensis

This paper deals with early embryogenesis of Actinidia chinensis var. chinensis. 1. Ovary superior consists of 34—45 carpels. Each carpel contains 11–45 ovules. The ovule is uni-integument and tenuinucellar. The ovule is anatropous. The archesporium is formed by a single cell, and directly develops into megaspore mother cell. Sometimes the archesporium consists of 2–3 cells, but only one of them develops into megaspore mother cell and the others are degenerated. 2. The mature pollen grain is two-celled and the embryo sac belongs to olygonum type. In most embryo sacs two polar nuclei are fused before fertilization. One of the synergids was destroyed as the pollen tube penetrated into embryo sac the other one disappeared after fertilization. In most cases the antipodal cells became degenerated in fertilization process, only some remained until the first division of primary endosperm nucleus. 3. In Beijing area the double fertilization of Actinidia chinensis occurred 30–72 hours after pollination. In the fertilization one sperm fused with egg nucleus and the other sperm fused with the secondary nucleus as usual. The fusion of the secondary nucleus with sperm was in advance of the fusion of the egg nudeus. 4. The endosperm is cellular type.