Further Embryological Studies on the in Vitro Apogamy in Oryza saliva L.

In the cultured young ovaries of rice, the processes of megagametophyte develop- ment could be switched to the formation of various abnormally organized embryo sacs and then to the initiation of synergid apogamy. The main pathway leading to apogamy was found to go via a linearly oriented 4-nucleate embryo sac to the formation of a li- nearly oriented egg apparatus, from which it was usually the chalazal synergid giving rise to an apogamous proembryo, and the micropylar synergid degenerated. The proembryo thus produced was located at the base of a vacuolated egg cell (Plate Ⅰ, 1–7). The second pathway went through a nonlinearly oriented 4-nucleate embryo sac to the formation of an egg apparatus in which the two synergids were located at one side of the egg and oriented longitudinally. In this case it was often the chalazal synergid that could be triggered to apogamy, resulting in a hook-shaped proembryo embracing the egg cel1 from one side (Plate Ⅰ, 8–11). When ovaries with nearly matured embryo sac were cultured, in a few cases where apogamy was induced, the proembryos observed were all situated at one side of the egg and were hook-shaped (Plate Ⅰ, 12). All these pathways are summarized in a diagram (Fig. 23). Some interesting changes were observed in the synergid and the egg cell of the cultured ovaries by PAS reaction and mercuric bromphenol blue staining. The egg cells, in contrast to in vivo condition, often contained abundant starch grains,. The synergids and synergid proembryos were rich of cytoplasmic protein (Plate Ⅱ, 13, 14). We supposed that the egg may supply some nutrients as well as stimulants to the developing synergid in the course of apogamy. The distribution of starch and protein in apogamous embryoids during subsequent development was also described in this paper (Plate, 15–22).     

Micromanipulation of male and female gametes ofNicotiana tabacum: II. Preliminary attempts for in vitro fertilization and egg cell culture

This research is part of an attempt to establish an in vitro fertilization system in tobacco to aid in understanding mechanisms of fertilization. Fusions of isolated male and female gametes were induced in a polyethylene glycol solution. Fusion appears similar to that in maize. One nuclear division of both an unfertilized egg cell and a synergid was induced in KM8p medium with 1 mg/l 2,4-dichlorophenoxyacetic acid in a microchamber culture; one cellular division of the egg cell was also induced in the same medium in solid-drop culture. The osmolality of suspension culture feeder cells was critical for the development of these cells. These results indicate that in vitro fertilization is possible in tobacco, which would be the first such system in dicots.Abbreviations 2,4-D 2,4-Dichlorophenoxyacetic acid - PEG Polyethylene glycol     

小麦×大麦胚胎发育的研究——Ⅲ.小麦×大麦胎胚发育过程中淀粉的积累和动态

我们观察了小麦与大麦杂交胚胎发育过程中,雌蕊各个组成部分发生的淀粉积累和转移的动态。结果如下: 1.胚乳和杂种胚早期发育过程中,子房壁和胚囊中淀粉的积累和动态的趋势与其他学者所作小麦自交的情况基本相同。2.当胚乳细胞充满胚囊而胚没有分化时,子房壁中的淀粉已极少,当胚乳解体时,子房壁中淀粉已几乎消失。可见,子房壁中淀粉的迅速消失与胚乳的迅速败育是平行的。3.胚囊发育的停滞与败育跟子房壁组织中淀粉的积累及对胚囊营养的正常供应有密切关系。4.花柱、珠被、珠心组织及胚囊中的助细胞和反足细胞,在整个杂种胚和胚乳发育过程中,始终不存在淀粉粒。助细胞胚亦和助细胞一样,无淀粉粒的存在。     

被子植物受精机制的研究进展

被子植物的受精是一个复杂而精巧的过程。花粉管到达子房,通过退化助细胞进入胚囊,释放出两个精细胞。原来在花粉管中相互联结的两个精细胞在退化助细胞中分开,一个与卵细胞融合,另一个与中央细胞融合,完成双受精。目前对双受精过程中有关雌、雄配子识别的机制还知之甚少。本文介绍了目前被子植物精、卵细胞融合前后的细胞周期变化、退化助细胞的功能、精细胞在退化助细胞中迁移的研究动态、精细胞的倾向受精和卵细胞的激活等被子植物受精生物学领域中的一些新的研究成果和发展趋势。     

韭菜幼小子房培养时胚囊的发育和一些异常现象

对韭菜开花前1天左右的子房进行培养可获得大量的单倍体植株。观察表明单倍体植株起源于未受精的卵细胞和反足细胞。为了探索培养不同发育时期的子房对单倍体原胚发生频率的影响,我们又对大孢子母细胞时期的幼     

水稻雌蕊与胚囊中钙的超微细胞化学定位

用焦锑酸盐沉淀法对水稻（OryzasativaL．）授粉前后雌蕊和胚囊中的钙进行了超微细胞化学定位。结果表明,柱头乳突细胞表面和花柱薄壁细胞中均含钙沉淀;开花前1d,整个胚囊中含钙较少,两个助细胞中钙分布无差异;临近开花时,1个助细胞已退化,其钙含量明显增加;开花后6h,胚囊已受精,退化助细胞中钙含量进一步增加;受精前卵细胞中钙主要分布在液泡中,核和胞质中较少;受精后,其钙含量明显增加,主要分布于核中。重点讨论了钙与助细胞退化和卵细胞激活的关系。     

In Vitro Divisions of Unfertilized Central Cells and Other Embryo Sac Cells in Nicotiana tabacum var macrophylla

The embryo sacs and female cells could be isolated from the unfertilized ovules of Nicotiana tabacum L. var. macrophylla which were treated in a solution containing 1.5 % cellulase R- 1O, 1% macerozyme R-10, 10% mannitol, 10 mmol/L CaCI:, pH 5.8 for 3 h followed by given slight pressure with a micropipette. The central cells could be kept viable for 10 h and the egg cells for 3 h in 10% mannital. Sometimes, the in situ fusion products of egg cell and synergid protoplasts could be obtained and kept viable for at least 5 h. The high concentration (20 mg/L) of 2, 4-D was used in enzyme solution to induce the division of the unfertilized central cells and other megagametophytic cells in subsequent culture. Treatment of 2,4-D together with enzymatic maceration of ovules was proved to be better than its direct treatment of isolated embryo sac or its component cells. Isolated embryo sacs were cultured in microchambers (Millicell-CM PICM 012 50 MILLIPORE) feeded with divided mesophyll protoplasts of Nicotiana rustica L. The medium was KMSp medium supple- mented with 1% glucose, 0.1 mol/L mannitol, 0.1 mol/L sorbitol, 0.25 mol/L sucrose, 1 mg/L BA, 6% to 10% coconut water, and 0.15% low gelling agarose. Division of central cells, antipodal cells and the in situ fusion products of egg cell and synergid protoplasts were induced. The unfertilized central cell was for the first time to be induced in vitro to develop into small cell clusters.     

Synergid degeneration in Nicotiana: a quantitative,fluorochromatic and chlorotetracycline study

Summary Synergid degeneration was examined in the isolated embryo sac and egg apparatus of Nicotiana tabacum using quantitative cytology, fluorochromatic reaction (FCR) and chlorotetracycline (CTC). Most synergid degeneration occurs after pollen tubes (PT) arrive in the ovarian chamber between 42 and 48 h after pollination; synergid degeneration was precluded when PT were prevented from entering the ovary by stylar excision indicating that the signal that triggers synergid degeneration travels only relatively short distances in this plant. There was no evidence for any preferentiality between right or left synergids with regard to cell size or degeneration pattern. FCR staining confirms that synergid degeneration involves the loss of membrane integrity and is a reliable indicator of the onset of degeneration. CTC labeling of the degenerated synergid reveals that a concentrated reserve of membrane-bound calcium is present in the receptive synergid, possibly aiding in the attraction, arrest and discharge of the PT, releasing the sperms into the receptive ES.     

烟草未受精中央细胞及其它胚囊细胞的离体分裂

自70年代中期以来,未传粉子房和胚珠的离体培养已在多种植物中取得成功,得到的单倍体植株来源于胶囊中的卵细胞、助细胞以及反足细胞。而分离的未受精胚囊及其成员细胞的离体培养虽屡经尝试,迄今只有Kranz等诱导了玉米未受精卵细胞分裂形成小愈伤组织,至于中央细胞与其它雌配子体细胞则无离体分裂的报道。本文报道大叶烟草未受精中央细胞首次培养成细胞团及其它胚囊细胞启动离体分裂的实验结果。     

毒莠定作为外源激素促进水稻子房培养中胚状体的分化

用毒莠定(4-氨基-3,5,6-三氯-2-羧基吡啶)代替MCPA(2-甲基-4-氯苯氧乙酸)作为水稻未传粉子房培养中的外源激素,所诱导的助细胞无配子生殖胚状体分化率大幅度提高,愈伤组织化的倾向大为减弱,并观察到在诱导培养基上直接出苗的现象。用N_6基本培养基附加3%的蔗糖、2毫克/升的毒莠定与500毫克/升的水解乳蛋白可获得较佳的培养效果。组织学观察表明在毒莠定的作用下,原胚多数是沿着接近体内合子胚正常分化的途径形成具根、芽的两极结构,而和MCPA所诱导的原胚不分化与愈伤组织化有很大的差异。讨论了毒莠定作为外源激素在植物组织培养中应用的潜力。     

Influence of metabolic stress on the inheritance of cell determination in the moss, Pottia intermedia

Epigenetically-determined apogamy in aposporous regenerants of the moss Pottia intermedia persists during vegetative propagation, the capacity of apogamy being inherited by individual aposporous protonemal cells. To test Bauer-Lazarenko's proposal that stable apogamy in mosses may be due to some self-replicating cytoplasmic factor, the effects of different metabolic stress treatments on the expression of apogamy have been tested. Chronic metabolic stress caused by long-term growth of autotrophic aposporous protonema on mineral medium with 0.25% of casamino acids and on Murashiga-Skoog (MS) medium with sucrose and phytohormones, as well as by transitory action of high kinetin concentration, have a much stronger influence on the expression of apogamy, than short-term stress treatments with RNase and Pb(2+). Apogamy has been found to be lost stably, after prolonged growth on MS medium containing kinetin and ABA. The proposal that the capacity for apogamy is related to the release of aposporous protonemal cells from a putative factor for apogamy is discussed.     

An Electron Microscopic Study of Double Fertilization in Allohexaploid Wheat Triticum aestivum L.

Double fertilization has been examined by electron microscopyin allohexaploid wheat, Triticum aestivum L. cv. Mardler. Serialsections through fertilized ovules revealed that following dischargeof the pollen tube contents into the degenerate synergid thelatter extended to form a continuum between the egg and centralcells. The two naked sperm nuclei were seen at the far end ofthis extended synergid. These observations suggest that thedegenerate synergid may play a role in transporting the spermnuclei to the site where they can be accepted by the egg andcentral cell. In comparison with double fertilization in Plumbagozeylanica L., we also suggest that the degenerate synergid preventsmale cytoplasms from being transmitted to the egg and centralcell. The present study also confirms that in the fertilizedcentral cell the maternal and paternal genomes remain physicallyseparate at least until the first nuclear division of the coenocyticphase of endosperm development. Double fertilization, degenerate synergid, Triticum aestivum     

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(Oryz a 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0.5小时左右, 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2.5-10.0小时; 授粉后1.0-3.0小时, 精核与两极核融合; 授粉后约5.0小时, 初生胚乳核分裂。     

Light Microscope Study of Pollen Tube Growth, Fertilization and Early Embryo and Endosperm Development in the Avocado Varieties Fuerte and Hass

Pollen tube growth, fertilization and early embryo and endospermdevelopment were studied using light microscopy in the avocadovarieties Fuerte and Hass. The ovule was penetrated by a pollen tube by 24 h after pollination.On reaching the ovary, the pollen tube grew along the surfaceof the inner ovary wall. It then grew around the funicle, throughthe micropyle in the inner integument and between the papillatecells at the apex of the nucellus. It entered the embryo sacvia a synergid. Sperm nuclei were present in the embryo sacat 48 h after pollination and fusion of the polar and spermnuclei took place before fusion of the egg and sperm. The endospermnucleus was the first to divide and cell wall formation occurredfollowing division. The first division of the zygote occurredat 5 or 6 days after pollination. In the variety Fuerte less than 20 per cent of the 1- and 2-day-oldembryo sacs had been penetrated by a pollen tube although tubeswere often observed in the integument or nucellus. In the varietyHass over 60 per cent of the embryo sacs were penetrated. Inwas concluded that low yields of the variety Fuerte may be partlyattributable to the failure of the pollen tube to penetratethe embryo sac. Persea americana Mill, avocado, pollen tube, fertilization, embryo, endosperm     

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。’     

Fertilization in Arabidopsis thaliana wild type: developmental stages and time course

We describe some previously uncharacterised stages of fertilization in Arabidopsis thaliana and provide for the first time a precise time course of the fertilization process. We hand-pollinated wild type pistils with wild type pollen (Columbia ecotype), fixed them at various times after pollination, and analysed 600 embryo sacs using Confocal Laser Scanning Microscopy. Degeneration of one of the synergid cells starts at 5 Hours After Pollination (HAP). Polarity of the egg changes rapidly after this synergid degeneration. Karyogamy is then detected by the presence of two nucleoli of different diameters in both the egg and central cell nuclei, 7-8 HAP. Within the next hour, first nuclear division takes place in the fertilized central cell and two nucleoli can then be seen transiently in each nucleus produced. In a second set of experiments, we hand-pollinated wild type pistils with pollen from a transgenic promLAT52::EGFP line that expresses EGFP in its pollen vegetative cell. Release of the pollen tube contents into the synergid cell could be detected in living material. We show that the timing of synergid degeneration and pollen tube release correlate well, suggesting that either the synergid cell degenerates at the time of pollen tube discharge or very shortly before it. These observations and protocols constitute an important basis for the further phenotypic analysis of mutants affected in fertilization.     

The synergid cell: attractor and acceptor of the pollen tube for double fertilization

In flowering plants, the egg cell is generally accompanied by two symmetrical cells, called synergid cells. As early as the 1870s, synergid cells were distinguished from egg cells and cooperation between synergid and egg cells was proposed; the term "synergid" is derived from the Greek "synergos," which means "working together." The accumulation of morphological and genetic data, and, more recently, the in vitro physiological analysis of the fertilization system of Torenia fournieri, have revealed that synergid cells work together with egg and central cells to accomplish double fertilization. This cooperation is of crucial importance in the attraction and acceptance of the pollen tube. In this review article, I focus on the physiological function and behavior of the synergid cell during the fertilization process. Received: December 20, 2001 / Accepted: December 27, 2001     

Effects of High Temperature on the Cultures of Isolated Microspores in Brassica campestris ssp. pekinensis

The influence of high temperature (33℃) on embryogenesis in isolated microspore culture of Chinese cabbage (Brassica campestris spp. pekinensis ) was investigated by microscpopy of FDA and DAPI. The microspores cultured at constant temperature of 25 ℃ lost their viability quickly and only few viable microspores were found after 7 days of culture. The morphology of the cultured microspores became as turgescent as the "rugby" which was similar to the mature pollen of the Chinese cabbage. The first nuclear division of the microspores was asymmetric. The microspores lost their capacity of embryogenesis under such condition. In contrast, when the microspores were cultured at 33℃ for 24 h before they were transfered to the culture condition of 25 ℃, their developmental pattern was changed. Some of the microspores could remain viable even for 7 days in culture, they became rounded off. The symmetric nuclear division pattern was induced. The frequency of such division was about 40%. Of the several new cell division types observed, the symmetric type was more frequent (55%) than others. The microspores treated under 33℃ were able to form embryoids via embryogenesis. The critical period of high temperature treatment on microspore culture of Chinese cabbage was about the initial 12 h, if the cell division index of microspore was concerned, but the period was the initial 24 h if the frequency of embryogenesis was considered.     

Studies on nuclear degeneration during programmed cell death of synergid and antipodal cells in<Emphasis Type="Italic"> Triticum aestivum</Emphasis>

Morphological changes in the nuclear degeneration of the synergid (mainly the synergid that receives the pollen tube) and antipodal cells in Triticum aestivum were studied. Although located in the same embryo sac, and derived from the same megaspore, nuclear degeneration of the synergid and antipodal cells differs greatly. Nuclear degeneration in the synergid is characterized by pycnosis, i.e., total chromatin condensation, nuclear deformation and distinct shrinkage in volume, followed by the formation of an irregular and densely stained mass—the degenerated nucleus—while the nucleolus disappears prior to the degradation of chromatin. In contrast, in the nuclear degeneration of antipodal cells, chromatin is only partly condensed and the nuclear volume changes only slightly after the distinct chromatin condensation. Chromatolysis then occurs, i.e., stainable contents disappear while the nuclear envelope is retained. The nucleoli persist after the disappearance of the chromatin. The possible functions of nuclear degeneration of synergid and antipodal cells are discussed, especially with respect to the guidance of pollen tube growth and the proliferation of free-nuclear endosperm. The degeneration of synergids and antipodal cells in T. aestivum are distinct forms of programmed cell death, regarded as cytoplasmic cell death and nuclear degradation in advance of cell death, respectively.     

Ultracytochemical Localization of Calcium in Micropyle and Embryo Sac of Brassica napus Before and After Pollination

Potassiam antimonate was used to localize Ca2+ in the micropyle and embryo sac of Brassica napus L. before and after pollination. To identify the nature of the pyroantimonate deposits, energy-dispersive X-ray microanalysis (EDXA) was employed and the deposits were proved to contain calcium pyroantimonate. Image processing system was employed to measure the volume density and the diameter of the deposits. Before and after pollination, calcium was more abundant in the exostome and endostome as compared with the other regions of the integuments, and was concentrated at the apoplast system, i.e. the intercellular matrix of the micropyle canal and the cell wall. Before pollination, each of the two sister synergids accumulated more calcium than the other embryo sac cells. Although the mean diameter of the deposits in the synergid was only two-thirds as that in the egg cell and central cell, the volume density of the deposits in the synergid was about 2.5 times and 1.9 times as that in the egg cell and the central cell respectively. The filiform apparatus and the nucleus had the most abundant calcium within a synergid. After pollination both sister synergids degenerated conspicuously and were characterized by much more deposited calcium (about 2.4 times more than before); and the diameter of the deposits decreased dramatically, which was less than one-third as before. The relationship between calcium distribution and synergid degeneration as well as its functions was discussed.