玉米双受精过程的细胞学观察

1.玉米双受精属于有丝分裂前配子融合的类型。2.授粉后21至24小时,大部分雌、雄性核发生融合。雌、雄性核融合时,雄性核仁的出现存在两种情况,其一是精核染色质逐渐分散的同时出现雄性核仁,其二是精核染色质逐渐分散后,约经2至4小时才出现雄性核仁。3.合子内的雌、雄性核仁若发生融合,一般在合子分裂前进行。合子以一个大核仁的形式进入分裂期;雌、雄性核仁不融合的合子同样可以进入分裂期。授粉后30至33小时,合子进行第一次分裂。合子静止期大约为9小时左右。4.初生胚乳核内的雌、雄性核仁不发生融合。授粉后24至26小时,初生胚乳核进行第一次分裂。初生胚乳核的静止期为2—4小时。5.人工授粉条件下,玉米果穗受精过程的进行有一定的顺序;即自果穗上部逐渐向下部完成受精作用。     

大豆受精作用的研究

本文观察了受精作用的全过程。自花授粉约6小时后,花粉管进入胚囊,释放精于;8—12小时后,大部分雌雄性核发生融合;约10小时后,胚乳初生核进行第一次有丝分裂;28小时后,合子进行第一次有丝分裂,30—32小时合子分裂的频率最高;雌雄性配子融合形成合子至合子第一次有丝分裂需要20小时左右,即自花授粉9—30小时左右为大豆的合子休眠期。     

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。     

星星草受精作用及其胚与胚乳早期发育的观察

利用常规石蜡切片法对星星草[Puccinellia tenuiflora(Griseb．)Scribn．et Merr．]受精过程及胚与胚乳的早期发育进行了观察,主要结论如下：(1)开花后2h,花粉管破坏1个助细胞,释放2个精子,精子呈逗点状。(2)开花后2～3h,2个精子分别移向卵细胞与极核。(3)开花后3～5h,精核分别贴附于卵细胞与极核的核膜上。(4)开花后5～10h,精核与卵核融合,雄性核仁出现,合子形成。(5)开花后5～6h,精核与极核融合,并出现雄性核仁,形成初生胚乳核,精核与极核的融合比与卵核融合要快。(6)开花后20h左右,合子分裂。(7)开花后8h,初生胚乳核。     

羊草受精作用及其胚与胚乳早期发育的观察

利用常规石蜡制片方法研究了羊草受精过程及胚与胚乳的早期发育,其主要结果为：(1)授粉后1h,花粉管破坏1助细胞,释放2精子。精子为眼眉状,难以区分其细胞质鞘;(2)授粉后1～2h,2个精子分别移向卵细胞与极核;(3)授粉后2～3h,精核分别贴附于卵细胞与极核核膜上;(4)授粉后3～10h,精核与卵核融合,并出现雄性核仁,形成合子;(5)授粉后3～4h,精核与极核融合,并出现雄性核仁,形成初生胚乳核,精核与极核的融合比与卵核融合快;(6)传粉后20h,合子分裂,合子的休眠期为10h左右;(7)传粉4h,初生胚乳核分裂,初生胚乳核没有休眠期;(8)羊草双受精作用属于有丝分裂前配子融合类型;(9)胚胎发育属于紫菀型,胚乳发育属于核型胚乳。     

濒危植物——长喙毛茛泽泻的受精作用及胚和胚乳的发育

长喙毛茛泽泻Ranalisma rostratum Stapf的配子融合开始较早,但精核与极核融合速度较快。精核与珠孔极核融合后即移向胚囊合点端与另一极核再融合形成初生胚乳核。初生胚乳核第一次分裂后形成两个细胞,以后珠孔端胚乳细胞再进行游离核分裂,胚乳发育属于沼生目型。开花后两天,合子分裂,八分体呈4层,每层呈两个细胞方式排列胚胎发生属于石竹型。     

番茄受精作用及其间隔期的研究

利用常规石蜡切片法研究了番茄受精作用的全过程,具体研究结果为:(1)授粉后2 h,花粉粒在柱头上萌发;约2~4 h,花粉管长入柱头,且末端膨大;约8 h后,生殖细胞进入分裂期;并于约两小时后,分裂为两个精细胞。(2)约14 h,花粉管进入子房腔;约18~24 h,花粉管进入胚囊,破坏一个助细胞,并在其珠孔端释放两个精子;随后被释放的精子移到卵细胞与次生核附近。(3)授粉后约30 h精核进入卵细胞;约34 h,精核与卵核融合,并在卵核内出现分散的雄性染色质,进而出现雄性核仁;44~50 h,雌、雄性核仁融合,形成合子;合子的休眠期为10 h左右。60 h之后,合子分裂形成二细胞原胚。(4)约26 h,另一个精子的精核与次生核核膜相贴伏,随后与之融合;约30~34 h,次生核内出现分散的雄性染色质,随之出现雄性核仁;约38~42 h,雌、雄性核仁融合,形成初生胚乳核。约44 h后,初生胚乳核进行有丝分裂,形成两个胚乳细胞。番茄胚乳发育属于细胞型。初生胚乳核无休眠期。(5)精子与次生核的融合比与卵核的融合快。(6)番茄的受精作用属于有丝分裂前配子融合类型。     

西番莲双受精过程的细胞学观察

利用石蜡制片,观察了西番莲双受精的全过程,其主要结果如下：人工授粉后6．5小时,大量花粉管进入子房腔,并沿子房内壁生长,进行珠孔受精;7—7．5小时,花粉管由珠孔进入胚囊,破坏一个助细胞,释放出二个精子;7．5—9小时,大多数胚珠雌、雄性核发生融合。其受精作用属于有丝分裂前型的配子融合类型;精子与卵细胞、精子与极核融合几乎同时发生。两极核于受精后融合;合子与初生胚乳核无休眠期,受精后立即进行有丝分裂。     

被子植物合子的一些休眠表现

受精的卵细胞称为合子。胚的发育是从合子开始的。合子形成以后,通常要经过一个或长或短的“休眠”期才进行分裂,因此胚的开始发育一般较胚乳晚。合子“休眠”期的长短因植物种类不同而异,一般在数小时至几天不等,例如橡胶草传粉后大约4小时初生胚乳核分裂,5小时后合子跟着分裂;水稻在传粉后3小时初生胚乳核分裂,6小时后合子分裂;棉花传粉后24小时才可看到初生胚乳核分裂,而合子分裂要迟至传粉后的第3天。竟有少数植物合子“休眠”期很长,据记载秋水仙在秋季受精后,不久就有多数的胚核形成,而合子在整个冬季的4-5个月期间停留在休眠状态。合子的“休眠”期间发生许多显著的变化:①在电子显微镜下观察到有的植物如荠菜,卵     

Fuerte和Hass品种油梨的花粉管生长、受精与早期胚和胚乳发育的光学显微镜研究

用光学显微镜对Fuerte和Hass品种油梨的花粉管生长、受精与早期胚和胚乳发育进行了研究。授粉后24小时,花粉管穿入胚珠。当花粉管到达子房时,花粉管贴着子房内壁表面生长,然后沿着珠柄,穿过内珠被形成的珠孔,在珠心顶端的乳突细胞之间生长。它经过一个助细胞进入胚囊。授粉后48小时在胚囊中可见到精核,精核与极核融合后,精卵才融合。胚乳核先分裂,接着细胞壁形成。授粉后5—6天,合子第一次分裂。Fuerte品种授粉后1—2天的胚珠中,虽然在珠被或珠心处经常看到花粉管,但是只有不到20%的胚囊有花粉管进入。在Hass品种中,有60%的胚囊有花粉管穿入。可以认定,Fuerte品种之所以低产可能与花粉管很少进入胚囊有一定的关系。     

短柄五加开花后雌蕊的发育状态与受精作用的研究

短柄五加（ＥｌｅｕｔｈｅｒｏｃｏｃｕｓｂｒａｃｈｙｐｕｓＨａｒｍｓ．）开花当天,花药散粉,而雌配子体需经４～５ｄ才发育成熟。证实短柄五加为雄蕊先熟植物。开花第５天,成熟胚囊的比率为５７６９％,其余为退化和不育胚囊。开花第６天,胚囊开始受精。开花第１０天,受精胚囊占胚囊总数的５３５７％。柱头的可授期自开花后第４～５天开始,自花粉萌发至雌雄性核融合大约有２～３ｄ的间隔期。短柄五加受精过程与一般被子植物相同,其受精作用属于有丝分裂前配子融合类型。观察并统计了合子中雌性核仁的数目、存在状态,指出短柄五加合子中从雄性核仁出现到与雌雄性核仁融合为一个大核仁需经历３ｄ左右;如果以胚乳游离核数目为对照,大部分合子中雌雄性核仁的融合发生在３２～１２８个胚乳游离核时期。大多数合子是以雌雄性核仁融合为一个大核仁后进入合子分裂期;少数合子的雌雄性核仁不经融合也进入合子分裂期。观察到多精入胚囊、多精入卵以及成熟胚囊退化的现象。讨论了被子植物受精过程中有关受精终结的标志等问题。     

The Development of Gynoecium After Anthesis and Fertilization in Eleutherococcus brachypus (Araliaceae)

Eleutherococcus brachypus Harms. is a protandrous plant because the female gametophyte delays its maturation until the fifth day after anthesis and pollen shelling. On the fifth day after anthesis, about 57.69% of the embryo sacs matured and the rest degenerated or failed to develop. Fertilization began in the embryo sac on the fifth day. On the tenth day fertilization took place in 53.37 % of the total of embryo sacs. The stigma became receptible after 3 to 4 days of anthesis. It took 2 to 3 days from the germination of pollen grains on stigma to the fusion of male and female nuclei. The process of fertilization in E. brachypus is not different from most other angiosperms. It belonged to the type of premitotic syngamy. The observations and statistical analysis were made on the number feature of male and female nucleoli in the zygote. The result indicated that it took three days or so from the appearance of male nucleolus in the zygote to its fusion with the female nucleotus. Refering to the number of free nuclei of the endosperm, the fusion of male and female nucleoli in most of the zygotes occurred in the stage of 32 to 128 nuclei of the endosperm. Most zygotes con-tained a big nucleolus resulting from the fusion of male and female nucleolus and proceeding to mitosis. A few without fusion could also proceed to the mitotic stage. Features of multiple sperms entering the embryo sac or entering the egg cell and the degeneration of mature embryo sacs were observed as well. The sign of the termination of fertilization in angiosperms was discussed.     

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.     

Cytologic Observations on the Double Fertilization in Maize

1.The double fertilization is the type of the premitotic syngamy. 2. In 21 to 24 hours after pollination, most of the female nuclei fuse with the male nuclei. When the female nucleus fuses with the male nucleus, there are two situations in the appearance of the male nucleolus: one is that while the chromatin of the sperm nucleus relaxes gradually, a male nucleolus appears; the other is that after the chromatin of the sperm nucleus relaxes gradually, the male nucleus just appears in about 2 to 4 hours. 3. Generally, the fusion of the female nucleolus with the male nucleolus takes place before the division of the nygote. The nygote enters the stage of division when it has a jarge nucieojus; the zygote, in which the female nucleoius does not fuse with the male nucleolus, also can enter the stage of division. In 30 to 33 hours after pollination, the first division of the zygote occurs. The resting period of the zygote is about 9 hours 4. In the primary endosperm nucleus, the female nucleolus does not fuse with the male nucleolus. 24 to 26 hours after pollination, the primary endosperm nucleus begins the first division. The resting period of the primary endosperm nucleus is 2 to 4 hours. 5. Under the condition of artificial pollination, the fertilization of the fruit ears of maize proceeds sequencely, i.e. from the upper of the fruit ears to the lower the fertilization is fulfilled gradually.     

The kinetics of cytological events during double fertilization in Zea mays L.

By using a clearing method, the process of double fertilization in Zea mays L. (line A 188) was analysed and the precise sequence of events was determined. The period from pollen tube arrival to gamete fusion was relatively short, possibly less than 1 h. The karyogamy was of premitotic type, and the time from the contact of male and female nuclei to the fusion of male and female nucleoli was about 5 h in the egg cell and 3 h in the central cell. In the central cell, the sperm nucleus fused with either one of the polar nuclei or the secondary nucleus, the latter being observed for the first time in maize. The zygote was in the resting period for 13–16 h before division commenced, changing the cell polarity during karyogamy and the resting period. The primary endosperm nucleus divided immediately after karyogamy was completed in the central cell. The embryo sacs with two-celled proembryos contained four to eight endosperm nuclei. The timetable of fertilization events could be a standard for further studies on in vitro fertilization at the cytological and molecular levels.     

Studies on Fertilization and Embryogenesis of Red Vinespinach (Basella rubra L.)

This paper presents detailed report on the process of fertilization and the develop- ment of embryo and endosperm of Basella rubra L. The results obtained are summarized as follows: About 4–6 hours after anthesis a great deal pollen grains germinated on the stig- ma; 6–11 hours, the pollen tube passed through the style; 11–16 hours, the pollen tube reached the ovary cavity. About 16–18 hours, one sperm nucleus entered into the egg and the other one entered into the secondary nucleus. In most cases, after 16–24 hours the double fertilization had completed. After 2–8 days, two-celled proembryo was first shown. Finally, the proembryo gave rise to multicellular globular embryo proper. The development of the embryo of Basella rubra L. conforms to the Asterad type. Whether the Asterad type had a high frequency needs further to be studied. Although the fertilization of the sperm nucleus with the secondary nucleus began later, the fusion of two sexual nuclei and the development of the endosperm proceeded often quickly. After 20 hours, the free nuclei period began, and after 2–4 days the free nuclei of endosperm were rapidly formed. The endosperm of Basella rubra L. is a nuclear type. And at the time When the seed had ripened the endosperm tissues were all absorbed by the developing embryo. The author observed that there are different distributions of the vegetative nucleus and two sperms in the pollen tube, and that two sperms entered a egg or secondary nucleus. The changes of the starch accumulated and distributed et al. in the floral organs are also studied and discussed.     

苦瓜胚胎学研究

以石蜡制片法对苦瓜(Momordi cacharantia L.)进行了胚胎学研究。小孢子母细胞减数分裂时,胞质分裂为同时型,形成四面体型四分体和左右对称型四分体。成熟花粉为二细胞型。子房三室,双珠被,厚珠心,倒生胚珠。大孢子四分体为线形,合点端功能大孢子发育成为蓼型胚囊。中央细胞细胞质中有大量贮藏物质存在。极核在受精时融合。双受精过程属有丝分裂前配子融合类型。3个反足细胞随受精过程进行而退化。胚胎发生为柳叶菜型。核型胚乳,合点端具胚乳吸器。     

The temporal course of fertilization and localization of starch in the barley pistil

The time course of fertilization in barley is described and the observations compared with those of older authors. The triple fusion is terminated in spite of its late onset always before syngamy. Whereas the time period reported for the so-called preparatory phase of fertilization and for the division of the primary endospernal nucleus is similarly reported by many authors, there are difference of as much as 8 hours in various report on the beginning of the division of the zygote (beginning of the prophase 13–21 hours after fertilization). In the present material, the zygote began to divide latest. The transient reserve substance representing an energy store for fertilization in barley was found to be starch. Barley belongs to the species in whcih starch is formed in the pollen grain and the pollen tube itself. When the content of the pollen tube is released, part of it arrives in the embryo sac. A mature embryo sac contains many starch grains near the nucleus of the oosphere and the polar nuclei. Gradual hydrolysis of this starch is related to the more rapid triple fusion and the slower syngamy.