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。     

植物的受精作用 第三讲 雄性配子与雌性配子融合的过程

当花粉管进入胚囊后,立即释放出其中的内容物,包括两个精子。接着发生雌雄配子的融合:一个精子与卵融合,形成合子,进一步发育成胚;另一个精子与中央细胞的极核(通常两个)融合,形成初生胚乳核,发育成为胚乳。受精作用发生的两种融合的现象,称为双受精。这是被子植物独具的特点。     

杂交石竹授粉受精及其胚胎发育过程的观察

以‘杂交石竹’为试验材料,利用荧光显微镜观察其授粉后花粉萌发、花粉管生长情况,采用石蜡切片法对其受精及胚胎发育过程进行观察研究。结果表明:(1)授粉后1h母本柱头上少量花粉开始萌发;授粉后4h大量花粉萌发,花粉管生长至柱头中部有胼胝质出现;授粉后6h花粉管生长至子房组织并有少量与胚珠结合;授粉后15h柱头中出现大量胼胝质,花粉管与胚珠结合数增多;授粉后24h胚珠周围出现多条花粉管,其中1条花粉管进入胚珠,部分进入胚囊的花粉管卷曲盘绕生长并产生胼胝质;精细胞与极核的融合主要发生在授粉后17~48h,与卵细胞融合主要于授粉后1~3d。(2)杂交石竹胚发育经过原胚、球形胚、棒状形胚、心形胚、鱼雷形胚和子叶形胚阶段。(3)杂交障碍表现为:只有游离的胚乳核而无胚发育的胚囊、合子未分裂、两极核未融合、球形胚败育。研究表明,杂交石竹存在受精前和受精后障碍,这是导致其结实率低的主要原因。     

被子植物助细胞中钙含量的变化

助细胞是被子植物受精过程中花粉管进入胚囊并释放精子及其内容物的场所,而助细胞中不同时期的钙含量与受精作用的顺利完成密切相关。在大多数植物中,助细胞是成熟胚囊中钙含量最高的细胞。传粉后在花粉管中所产生的信号诱导下,助细胞中钙含量还可能继续增加。花粉管进入退化助细胞后,在超高钙环境中破裂并释放精子,精子沿退化助细胞转移到受精靶区实现双受精。随后助细胞中的钙含量迅速降低。因此钙在吸引花粉管、雄配子释放甚至雄配子转移等过程中都发挥了重要作用。     

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。     

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。     

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。     

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。     

花粉管导向控制机制的研究取得重要进展

植物从水生向陆生进化过程中,精细胞丧失了运动能力,需要依靠花粉管把它递送到雌配子体--胚囊中与卵子融合,完成受精。花粉管导向是一个精确调控的雌-雄配子体细胞相互识别的过程。胚囊释放吸引信号,花粉管接收信号     

水稻双受精过程的细胞形态学及时间进程的观察

应用常规石蜡切片和荧光显微镜观察水稻（Oryza sativa）受精过程中雌雄性细胞融合时的形态特征及时间进程,确定合子期,为花粉管通道转基因技术的实施提供理论依据。结果表明：授粉后,花粉随即萌发,花粉管进入羽毛状柱头分支结构的细胞间隙,继续生长于花柱至子房顶部的引导组织的细胞间隙中,而后进入子房,在子房壁与外珠被之间的缝隙中向珠孔方向生长,花粉与花粉管均具有明显的绿色荧光。花粉管经珠孔及珠心表皮细胞间隙进入一个助细胞,释放精子。精子释放前,两极核移向卵细胞的合点端：两精子释放于卵细胞与中央细胞的间隙后,先后脱去细胞质,然后分别移向卵核和极核,移向卵核的精核快于移向极核的精核：精核与两极核在向反足细胞团方向移动的过程中完成雌雄核融合。大量图片显示了雌雄性核融合的详细过程以及多精受精现象。水稻受精过程经历的时间表如下：授粉后,花粉在柱头萌发：花粉萌发至花粉管进入珠孔大约需要0．5小时：授粉后0．54,时左右,花粉管进入一个助细胞,释放精子：授粉后0．5—2．5小时,精卵融合形成合子：授粉后约10．0小时,合子第1次分裂,合子期为授粉后2．5-10．04,时：授粉后1．0-3．04,时,精核与两极核融合：授粉后约5．0小时,初生胚乳核分裂。’     

异叶苦竹花粉管生长及双受精过程

以异叶苦竹为材料,采用扫描电镜、荧光显微镜技术及传统的石蜡制片技术,解剖观察其花粉管生长途径及双受精过程。结果表明:(1)授粉后,花粉在柱头上吸水膨胀,约30 min即可萌发。(2)授粉1～2 h后花粉管可达到花粉长度的5～10倍,花粉管在柱头分支中进一步伸长,并开始伸入花柱中生长。(3)授粉后5 h,大量花粉管沿引导组织进入花柱基部与子房顶部之间的子房壁,有少量花粉管在子房壁与外珠被之间的缝隙中生长。(4)授粉后8 h,少量花粉管到达珠孔端。(5)授粉后15～18 h,精核与极核融合,形成初生胚乳核;精、卵核融合,形成合子。(6)授粉后20～30 h,仍可在花柱中见到大量呈束状的花粉管。(7)授粉后48 h,子房内的大部分花粉管出现解体,大多数花粉死亡。研究认为,精细胞到达胚珠的时间为8 h。     

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。     

Studies on Fertilization in Glycine max

This work studies the whole process of fertilization in Glycine max. The results are summarized as follows: 1. The type of ripened pollen grain of soybean was two-cell type. The generative cell was divided mitotically into two spermatids within the pollen tube. 2. In the 6th hour after self-pollination, the pollen tube entered into the embryo sac and released two sperms. Before the fusion of the male and female nuclei, the cytoplasmic sheath of the spermatids falled off. The cytoplasm of the male gamete did not fuse with that of the egg cell. 3. In the 6th hour after self-pollination, one spermatid nucleus come in contact with the egg nucleus and the other with the secondary nucleus, The contact of the sperimatid nucleus with the egg nucleus was a little earlier than that with the secondary nucleus. 4. The spermatid nucleus entered into the egg nucleus; the chromatic granules of the spermatid despiralized. After the complete fusion of the spermatid nucleus with the egg nucleus, the egg nucleus was darkly stained and the chromonemata increased, afterward the male nucleus appeared. 5. In the 28th hour after self-pollination, the zygote begun the first mitotic division. It took about 20 hours to fuse the male and female gametes, and to form the zygote untile before first mitotic division. It means that the zygote dormancy stage of soybean was about twenty hours. 6. In the 7th hour after self-pollination, the spermatid nucleus fused with the secondary nucleus. The process was similar to that of the spermatid nucleus with the egg nucleus. The chromatic granules gradually despiralized within the secondary nucleus, and the male nucleoli appeared. The velocity of the fusion of the spermatid nucleus with the secondary nucleus was faster than that of the other spermatid nucleus with the egg nucleus. 7. In the 10th hour after self-pollination, the secondary nucleus begun the first mitotic division. 8. The fertilization of soybean was the premitotic type.     

On the Fertilization of Oryza sativa L. × Sorghum vulgare Pets.

1.The pollen germination of Sorghum vulgate appeared normal on the stigma of the Oryza sativa, but the pollen tubes grew slowly in the style. Some of the pollen tubes may become enlarged in their tips or sometimes bursting, while others have continued to grow and entered the embryo sacs. 2. The growth rate of the pollen tubes varied widely. A few pollen tubes were observed in the embryo sacs of the materials 2 hours after pollination, but most of them entered the embryo sacs much later. 3. The zygote associated with a paucity of endosperm nuclei was observed in the materials 1 day after pollination. The double fertilization and 8–12-celled proembryo associated with a number of the free nuclei of the endosperm appeared with a rather high frequency (10.3%) in the materials 3 days after pollination. Some of them are normal in appearance and others may show more or less abnormalities. 4. No division figure was found except in one single case in which mitoses have occurred in both the proembryo and the endosperm. It is most likely that in such case the proembryo and the endosperm if left intact might develop further. 5. A 80-celled embryo was the biggest one which appeared in the materials 5 days after pollination. In general, no cells were ever formed in the endosperm, except in one instance among the 7 days materials the endosperm became cellular in micropylar end. In all other cases the endosperm either ceased to develop early or disorganized. The disorganized endosperm materials are considered to be utilized by the embryo. 6. In certain instances the free nuclei of the endosperm were not distributed at random. They were not equal in size and might fuse into giant nuclelei. 7. The most striking feature is that in the embryo sacs, in which double fertilization or proembryo and endosperm have occurred, a dark stained pollen tube was commonly present. This fact leads us to the conviction that in general only if a healthy pollen tube entered the embryo sac, double fertilization can take place and further development can proceed. 8. In certain cases the protoplasm of the embryo cells appeared scanty. It is apparently that the normal metabolism of the embryo was disturbed owing to the lack of nutrient, and the death of the embryo ensued. 9. No differentiated embryo was observed and no mature seeds were produced. The materials fixed 12 days after pollination showed a variety of abnormalities and collapses. The authors believe that the failure of seed production of rice X kaoliang was primarily due to the fact that the pollen tubes in the style grew too slowly to reach the embryo sacs in time. The consequence is that the double fertilization took place only in a late stage while the male and female gametes may have already become unhealthy. In addition, in this late stage the stored starch in the maternal tissues having gradually disappeared, the nutrient supply to the embryo sac was therefore limited and the young embryo and endosperm were finally in starvation.     

Kinetics of double fertilization in Torenia fournieri based on direct observations of the naked embryo sac

Torenia fournieri Lind. has a naked embryo sac that protrudes from the micropyle. The precise time course of the entire process of double fertilization and the kinetics of fertilization events were determined in this species by the following methods: (i) without squashing, pollen tubes on the torn stylar canal were observed by fluorescence microscopy after staining with both 4′,6-diamidino-2-phenylindole (DAPI) and aniline blue; and (ii) large numbers of living embryo sacs were observed directly by differential interference microscopy before and after fertilization. The pollen began to germinate 5 min after pollination and extruded pollen tubes which elongated at a constant rate of 2.3 mm · h⁻¹. At 4.0 h after pollination, the mitotic index of the generative cell within the pollen tube reached 88% and the two sperm cells were formed. Pollen tubes began to arrive at ovules 8.9 h after pollination and directly entered one of two synergids in the naked embryo sac. The time required for transport of sperm cells in the degenerated synergid was estimated statistically to be 1.9 ± 1.8 min for transport of the first cell and 7.4 ± 1.6 min for the second. In the nucleus of the fertilized egg cell, the male nucleolus began to emerge 10 h after pollination and the female nucleolus often decreased in size. The two nucleoli fused together prior to elongation of the zygote, which began 28 h after pollination. In the central cell, the secondary nucleus migrated to a region adjacent to the egg apparatus after pollination but prior to the arrival of the pollen tube. The primary endosperm nucleus rapidly returned to the inner region after fertilization. Prior to embryogenesis, the first division of the primary endosperm began about 15 h after pollination, at a defined site, to form the chalazal haustorium. Received: 24 October 1996 / Accepted: 13 March 1997     

Observations on Fertilization in Sugar Beet

The whole process of double fertilization in sugar beet has been observed, the main results are as follows: About 2 hours after pollination, the pollen grains germinate, the sperms in the pollen tube are long-oval. 15 hours after pollination, the pollen tube destroys a synergid and releases two sperms on one side or at the chalazal end of the egg cell. The sperms are spherical each having a cytoplasmic sheath. 17 hours after pollination, one sperm enters the egg cell, and the sperm nucleus fuses with the egg nucleus rapidly. 21 hours after pollination, the zygote is formed. In the meantime, the primary endosperm nucleus has divided into two free endosperm nuclei. 25 hours after pollination, the zygote begins to divide, forming a two-celled proembryo. The dormancy stage of the zygote is about 4 hours. In the meantime the endosperm is at the stage of four free nuclei. 17 hours after pollination, the sperm nucleus comes into contact and fuses with the secondary nucleus. The sperm nucleus fuses with the secondary nucleus, faster than the sperm with the egg. he first division of the primary endosperm nucleus is earlier than that of the zygote, it takes place about 20 hours after pollination, the dormancy stage of the primary endosperm is about 2 hours. The endosperm is free nuclear. The fertilization of sugar beet belongs to premitotic type of syngamy. From the stage of zygote to the two-celled proembryo, it can be seen that addition- al sperms enter the embryo sac, but polyspermy has not been observed yet.     

Fertilization and Embryo Development of Populus lasiocarpa Oliv

The double fertilization and embryo development of P. lasiocarpa were studied using cytochemical method for DNA, RNA, polysaccharides and proteins. Stigmas were covered by secretion stained positively with PAS and mercuric bromphenol blue at receptive stage. The pollen grains germinated on the stigma in large quantities 6 hours after pollination. Fertilization started at the 6th days after pollination. The sperm nucleus fused with the secondary nucleus faster than the sperm nucleus with the egg nucleus. The syngamy belonged to peremitotic type. A great deal of starch grains in the embryo sac disappeared during fertilization. The endosperm was nuclear type and becomed a cel 31 days after pollination. The endosperm was characterized by a dense cytoplasm rich in protein. No discrete starch grains were observed in endosperm. Afterwards, the endosperm was consumed by the developing embryo, thus the mature seeds were non-endospermous. The zygote was dormant for 6–8 days. During the dormency, many striking changes took place, and then, the zygotes showed more pronounced polarity. These changes included the shinkage of the large vacuole, the reduced size, the reappearance of large vacuole, the enlarging of the size. The embryogenesis conformed to the Solanad type. The ovules matured into seeds successively 44 days after pollination. The mature embryo was straight. Two cotyledons folded each other.     

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。