竹节参雌配子体发育的研究

本文报道了竹节参(Panax japonicus C.A.Mey)雌配子体(胚囊)的发育过程。竹节参大孢子母细胞减数分裂产生线形排列的大孢子四分体。胚囊发育属蓼型,由合点端大孢子发育而成。游离核胚囊时期,胚囊珠孔端的细胞器种类和数量都较胚囊合点端多;胚囊合点端相邻的珠被细胞中有含淀粉粒的小质体,与胚囊珠孔端相邻的退化中的非功能大孢子中则有含淀粉粒的大质体和大类脂体。成熟胚囊中,反足细胞较早退化;极核融合成次生核;卵细胞高度液泡化,细胞器数量较少;助细胞则有丰富的细胞器和发达的丝状器。PAS反应表明,受精前的成熟胚囊中积累淀粉粒。次生核受精后,很快分裂产生胚乳游离核,到几十至数百个核时形成胚乳细胞。卵细胞受精后则要经过较长的休眠期。     

CAPSELLA EMBRYOGENESIS: THE EGG,ZYGOTE, AND YOUNG EMBRYO

The ultrastructure and composition of the egg, zygote, and young embryo of Capsella bursa-pastoris were examined. The egg is a highly polarized cell; one-half to one-third of the micropylar end is filled with a large vacuole while the chalazal end contains the nucleus and much of the cytoplasm of the cell. The wall which surrounds the cell is incomplete at the chalazal end. Ribosomes fill the cytoplasm and show little or no aggregation into polysomes. The structure of the nucleolus suggests that ribosomes are not being produced. Following fertilization and the formation of the zygote, the cell decreases slightly in volume as the large central vacuole becomes smaller. The zygote soon increases in size as the small chalazal vacuoles present before fertilization begin to enlarge. The dictyosomes become active and a continuous wall forms around the zygote. Aggregation of the ribosomes begins and numerous polysomes are formed. Before division of the zygote all plasmodesmata between the zygote and the surrounding cells are lost. The first division of the zygote is unequal as a result of its marked polarity. A large basal cell and a small terminal cell are produced. The basal cell appears to contain more protein, RNA, carbohydrate, and cell organelles than the terminal cell. Ribosomal aggregation is even more pronounced at this stage. Starch accumulates in the plastids. Numerous plasmodesmata are present between the terminal and basal cells but there are no connections between the endosperm or other cells. The basal cell divides next to give rise to a three-celled linear embryo consisting of the basal cell, the suspensor cell, and the terminal cell. The terminal cell stains more intensely for protein and RNA as a result of increased numbers of ribosomes. Starch in all the cells is about equal and reaches a maximum in the embryo at this stage.     

Structure of Embryo Sac Before and After Fertilization and Distribution of Transfer Cells in Ovules of Green Gram

The structure of embryo sac before and after fertilization, embryo and endosperm development and transfer cell distribution in Phaseolus radiatus were investigated using light and transmission electron microscopy. The synergids with distinct filiform apparatus have a chalazal vacuole, numerous mitochondria and ribosomes. A cell wall exists only around the micropylar half of the synergids. The egg cell has a chalazally located nucleus, a large micropylar vacuole and several small vacuoles. Mitochondria and plasrids with starch grains are abundant. No cell wall is present at its chalazal end. There are no plasma membranes between the egg and central cell in several places. The zygote has a complete cell wall, abundant mitochondria and plastids containing starch grains. Both degenerated and persistent synergids migh.t serve as a nutrient supplement to proembryo. The wall ingrowths occur in the central cell, basal cell, inner integumentary cells, suspensor cells and endosperm cells. These transfer cells may contribute to embryo nutrition at different developmental stages of embryo.     

Cytological evidence of biparental inheritance of plastids and mitochondria inPelargonium

Summary Based on the organelle differences between egg and sperm cells inPelargonium hortorum, the zygote, proembryo, and endosperm were examined under the transmission electron microscope. Plastids and mitochondria in the egg cell are significantly different from those of the sperm cell. Egg plastids are starch-containing and less electron dense. They appear circular, elliptical irregular elongate in sections. Sperm cell plastids are relatively electrondense, mostly cup-shaped or dumbbell and devoid of starch granules. Mitochondria of the egg cell are giant and mostly cup-shaped while sperm mitochondria are smaller and usually circular in section. Double fertilization is completed by 24 h after pollination and the pollen tube can be seen in the degenerated synergid. In the zygote, plastids and mitochondria from male and female gametes can be distinguished by their characteristic differences. Moreover, paternal and maternal organelles appear to be distributed at random in the zygote. Aside from the pollen tube and its released starch granules, there is no enucleated cytoplasmic body in the degenerated synergid. Two days after pollination, the zygote undergoes one transverse division to form a 2-celled proembryo which consists of one larger vacuolated basal cell and one smaller densely cytoplasmic apical cell. Paternal and maternal organelles can be detected in both cells of the proembryo and also in the endosperm at this stage. From these results, it can be concluded that plastids and mitochondria from both male and female gametes have been transmitted into the apical cell of the proembryo and most probably to the following generation.Abbreviations TEM transmission electron microscope - DAPI 4,6-diamidino-2-phenylindole - RFLP restriction fragment length polymorphism     

The zygote and proembryo of alfalfa: quantitative,three-dimensional analysis and implications for biparental plastid inheritance

Summary Genetic studies have demonstrated biparental inheritance of plastids in alfalfa. The ratio of paternal to maternal plastids in the progeny varies according to the genotypes of the parents, which can be classified as strong or weak transmitters of plastids. Previous cytological investigations of generative cells and male gametes have provided no consistent explanation for plastid inheritance patterns among genotypes. However, plastids in the mature egg cells of a strong female genotype (6–4) were found to be more numerous and larger than in mature eggs of a weak female genotype (CUF-B), and the plastids in 6–4 eggs are positioned equally around the nucleus. In CUF-B, the majority of plastids are positioned below (toward the micropyle) the mid level of the nucleus, which is the future division plane of the zygote. Since only the apical portion of the zygote produces the embryo proper, plastids in the basal portion were predicted to become included in the suspensor cells and not be inherited. In the present study, we examined zygotes and a two-celled proembryo from a cross between CUF-B and a strong male genotype (301), a cross that results in over 90% of the progeny possessing paternal plastids only. Our results indicate that the distribution of plastids observed in the CUF-B egg cell is maintained through the first division of the zygote. Further, paternal plastids are similarly distributed; however, within the apical portion of the zygote and in the apical cell of the two-celled proembryo, the number of paternal plastids is typically much greater than the number of maternal plastids. These findings suggest that maternal and paternal plastid distribution within the zygote is a significant factor determining the inheritance of maternal and paternal plastids in alfalfa.     

Cytological Events during Zygote Formation of the Fern Ceratopteris thalictroides

The cytological events, including nuclear fusion, digestion of male organelles and rebuilding of the plasmalemma and cell wall, during zygote formation of the fern Ceratopteris thalictroides (L.) Brongn. are described based on the observations of transmission electron microscopy. When the spermatozoid enters the egg and contacts the cytoplasm, the male chromatin relaxes continually. The microtubular ribbon (MTr) is separated from the male nucleus and then an envelope reappears around the male nucleus. During nuclear fusion, the egg nucleus becomes highly irregular and extends some nuclear protrusions. It is proposed that the protrusions fuse with the male nucleus actively. After nuclear fusion the irregular zygotic nucleus contracts gradually. It becomes spherical before the zygote divides. The male chromatin is identifiable as fibrous structure in the zygotic nucleus in the beginning, but it gradually becomes diffused completely. The male organelles, including the MTr, multilayered structure, flagella and the male mitochondria are finally digested in the zygotic cytoplasm. Finally a new plasmalemma and cell wall are formed outside the protoplast. The organelles in the zygote are rearranged, which produces a horizontal polarity zygote. The zygote divides with an oblique-vertical cell plate facing the apical notch of the gametophyte.     

The Cytological Mechanism of Biparental Cytoplasmic Inheritance in Pelargonium hortorum -Ultrastructural and DNA Fluorescence Studies of Male and Female

Electron microscopic investigation has demonstrated that plastids and mitochondria are conserved in the generative cell, sperm cells and egg cell of Pelargonium hortorum Bailey. The plastids in the generative cell which contain starch for a short period, gradually changed to proplastids during the maturation of generative cell. The plastids in the sperm cells are large and numerous the characteristics of dense matrix and an abundant endomembrane systems. These plastids always appear ringlike in cross section. In the generative cell and sperms, the spherical or rod-shaped mitochondria are smaller than the.plastids and remain unchanged during the development process from generative cell to sperm cells. DNA filaments are visualized in the transparent central zone of the mitochondria. In the egg cell, plastids are more abundant than mitochondria. The structures of the plastids and mitochondria are obviously different from those in the sperm cell. Most of the plastids are irregularly rod-shaped and contain starch, the mitochondria are about 3 times larger than those in the sperm cells. Most of them are cup-shaped as proved by successive sections. DNA epifluorescence study demonstrated that DNA nucleoids are present in both plastids and mitochondria of the egg, generative cell and sperm cells. In the sperm cells, there is no ringlike DNA nucleoid as is existed in the egg cell. This study has defined the characteristics of the plastids and mitochondria in both male and female gemates of P. hortorurn. The results are essential contributions for further investigation of the biparental organelle transmission in the zygote and proembryo.     

The Ultrastructural Study on the Early Embryonic Development of Radish

The ultrastructure of the mature embryo sac, the early stages of the embryo and endosperm development of common radish, Raphanur sativus was examined. The embryo sac consists of 7 cells with antipodal ceils disappeared when it matures. The egg cell is highly polarized. The wall surrounded the chalazal end of the egg cell is incomplete, showing a discontinuous structure of an electron dense material deposited intermittently in the space between the two plasma membranes of the egg cell and central cell. The synergid has filiform apparatus, rich in organelles and well developed ER. The two polar nuclei of the central cell are located near the egg apparatus because of the big vacuole, and the finger-like protrutions from the cell wall, as that in synergid, are found. The first division of the zygote occurs 4–5 days after pollination and the development of the embryo follows the Onagrad type, and the structure of the embryo cell is quite simple for containing small quantity of ER, plastids and other organelles. The primary endosperm nucleus deviates 2 days earlier than zygote. The endosperm is of nuclear-endosperm containing chloroplasts, well developed ER, and plentiful of mitochondria and golgi bodies and the nodule-like aggregation in both. the chalazal and micropylar ends of the embryo sac during the early development appeared, and cell wall starting at the micropylar end by freely-growing forms about 16 days after pollination.     

Gamete fusion site on the egg cell and autonomous establishment of cell polarity in the zygote

Gamete fusion activates the egg in animals and plants, and the gamete fusion site on the zygote might provide a possible cue for zygotic development and/or embryonic patterning. In angiosperms, a zygote generally divides into a two-celled proembryo consisting of an apical and a basal cell with different cell fates. This is a putative step in the formation of the apical-basal axis of the proembryo. We observed the positional relationship between the gamete fusion site and the division plane formed by zygotic cleavage using an in vitro fertilization system with rice gametes. There was no relationship between the gamete fusion site and the division plane leading to the two-celled proembryo. Thus, the gamete fusion site on the rice zygote does not appear to function as a determinant for positioning the zygote division plane, and the zygote apparently possesses autonomous potential to establish cell polarity along the apical-basal axis for its first cleavage.Key words: asymmetric division, egg cell, fertilization, gamete fusion, rice, sperm cell, two-celled proembryo, zygote     

Western white pine (Pinus monticola Dougl.) reproduction: II. Fertilisation and cytoplasmic inheritance

Fertilisation and proembryo development are described from transmission electron micrographs emphasising the origin and fate of the maternal and paternal mitochondria and plastids. During central cell and egg development mitochondria migrate toward the nuclei, forming a perinuclear zone consisting predominantly of maternal mitochondria and polysomes. At the same time, maternal plastids transformed and at fertilisation are excluded from the neocytoplasm. The pollen tube releases two sperm nuclei into the egg with cytoplasm from the generative cell and the tube cell. The leading sperm nucleus fuses with the egg nucleus and a small number of paternal mitochondria and plastids are taken into the perinuclear zone. The second sperm nucleus degenerates. As the zygote nucleus undergoes mitosis followed by free nuclear division and nuclear migration to the chalazal end of the archegonium, maternal and paternal organelles intermingle within the neocytoplasm. The result is paternal inheritance of plastids and biparental, but predominantly maternal, inheritance of mitochondria. This pattern is consistent within the Pinaceae but differs from some other conifer families. Received: 9 December 1999 / Revision accepted: 30 April 2000     

The ultrastructure of zygotic embryo development in pearl millet (Pennisetum glaucum; Poaceae)

The ultrastructure, morphology, and histology of zygotic embryogenesis in pearl millet (Pennisetum glaucum) were examined using light and electron microscopic techniques. Embryogenesis was initially characterized by the presence of a vacuolated egg cell and zygote. The increased presence of Golgi bodies in the zygote suggested it was metabolically more active than the egg cell. The first zygotic division resulted in a densely cytoplasmic apical cell and a highly vacuolated basal cell. The club-shaped proembryo displayed a large amount of endoplasmic reticulum (ER) and ribosomes, very few lipids, and a continuous gradient of vacuoles from the highly vacuolated basal suspensor cells to the densely cytoplasmic apical cells. The embryo had well-defined parts by 8 days after pollination, including shoot and root meristems, coleoptile, scutellum, provascular system, and the first leaf primordium. Large increases in ER, lipids, starch, and vacuoles occurred in the scutellum during the maturation of the embryo, except in the provascular cells. Throughout zygotic embryogenesis, embryo cells were connected by plasmodesmata except where intercellular spaces occurred. Ultrastructural, morphological, and histological observations of zygotic embryogenesis in pearl millet are in agreement with previous reports for other grass species.     

Paternal cytoplasmic transmission in Chinese pine (Pinus tabulaeformis)

Summary. In this paper, the stages of normal sexual reproduction between pollen tube penetration of the archegonium and early embryo formation in Pinus tabulaeformis are described, emphasizing the transmission of parental cytoplasm, especially the DNA-containing organelles – plastids and mitochondria. The pollen tube growing in the nucellus contained an irregular tube nucleus followed by a pair of sperm cells. The tube cytoplasm contained abundant organelles, including starch-containing plastids and mitochondria. The two sperm cells differed in their volume of cytoplasm. The leading sperm, with more cytoplasm, contained abundant plastids and mitochondria, while the trailing one, with a thin layer of cytoplasm, had very few organelles. The mature egg cell contained a great number of mitochondria, whereas it lacked normal plastids. At fertilization, the pollen tube penetrated into the egg cell at the micropylar end and released all of its contents, including the two sperms. One of the sperm nuclei fused with the egg nucleus, whereas the other one was retained by the receptive vacuole. Very few plastids and mitochondria of male origin were observed around the fusing sperm and egg nuclei, while the retained sperm nucleus was surrounded by a large amount of male cytoplasm. The discharged tube cytoplasm occupied a large micropylar area in the egg cell. In the free nuclear proembryo, organelles of maternal and paternal origins intermingled in the neocytoplasm around the free nuclei. Most of the mitochondria had the same features as those of the egg cell, but some appeared to be from sperm cells and tube cytoplasm. Plastids were obviously of male origin, with an appearance similar to those of the sperm or tube cells. After cellularization of the proembryo, maternal mitochondria became more abundant than the paternal ones and the plastids enlarged and began to accumulate starch. The results reveal the cytological mechanism for paternal inheritance of plastids and biparental inheritance of mitochondria in Chinese pine. Correspondence and reprints: State Key Laboratory of Plant Physiology and Biochemistry, College of Biological Science, China Agricultural University, Beijing 100094, People’s Republic of China.     

THE ULTRASTRUCTURE AND HISTOCHEMISTRY OF THE SYNERGIDS OF COTTON

The composition and ultrastructure of the synergids of cotton were studied. The cells were found to be surrounded by a partial wall composed of cellulose, hemicellulose, and pectins. The structure of the wall was observed to consist of an unusual fibrillar arrangement. The filiform apparatus was demonstrated to be an extension of the wall at the micropylar end of the cell. Large amounts of ER surround the filiform apparatus. Also associated with the latter are large numbers of plastids and mitochondria. The nucleus is large and contains a single, large nucleolus and, frequently, 1 or more micronucleoli. The nuclear membrane contains membrane-bound vesicles but has few extensions into the cytoplasm. The ER is oriented parallel to the long axis of the cell and decreases in concentration from the micropylar to the chalazal end of the cell. Dictyosomes are common throughout the cell but are more numerous in the midportion where they are closely associated with the ER. The chalazal end of the cell is occupied by vacuoles rich in an inorganic compound which leaves a considerable residue of ash. Spherosome-like bodies are common throughout the cell. Both the plastids and mitochondria show evidence of division. Ribosomes are numerous and are both free and associated with the ER, nucleus, plastids, and mitochondria. The function of the synergids is proposed to be the absorption, storage, and transport of compounds from the nucellus. On the basis of this function, it is suggested that the synergids act by providing material to the egg and the developing embryo and endosperm and that they are involved in the growth of the pollen tube into the embryo sac.     

Tobacco zygotic embryogenesis in vitro: the original cell wall of the zygote is essential for maintenance of cell polarity, the apical-basal axis and typical suspensor formation

We have developed a reliable in vitro zygotic embryogenesis system in tobacco. A single zygote of a dicotyledonous plant was able to develop into a fertile plant via direct embryogenesis with the aid of a co-culture system in which fertilized ovules were employed as feeders. The results confirmed that a tobacco zygote could divide in vitro following the basic embryogenic pattern of the Solanad type. The zygote cell wall and directional expansion are two critical points in maintaining apical-basal polarity and determining the developmental fate of the zygote. Only those isolated zygotes with an almost intact original cell wall could continue limited directional expansion in vitro, and only these directionally expanded zygotes could divide into typical apical and basal cells and finally develop into a typical embryo with a suspensor. In contrast, isolated zygote protoplasts deprived of cell walls could enlarge but could not directionally elongate, as in vivo zygotes do before cell division, even when the cell wall was regenerated during in vitro culture. The zygote protoplasts could also undergo asymmetrical division to form one smaller and one larger daughter cell, which could develop into an embryonic callus or a globular embryo without a suspensor. Even cell walls that hung loosely around the protoplasts appeared to function, and were closely correlated with the orientation of the first zygotic division and the apical-basal axis, further indicating the essential role of the original zygotic cell wall in maintaining apical-basal polarity and cell-division orientation, as well as subsequent cell differentiation during early embryo development in vitro.     

Cytological Mechanism of Cytoplasmic Inheritance in Pinus tabulaeformis: II. Transmission of Male and Female Organelles During Fertilization and Proembryo Development

In an earlier report the ultrastructure and nucleoid organelles of male gamete in Pinus tabulaeformis Carr. have been described. Presently, the ultrastructure of the cytoplasm of the egg cell and pollen tube—immediately before fertilization and during cytoplasmic transmission of male gametophyte—has been described for the same species. The fate of parental plastids and mitochondria in the proembryo has also been followed. The mature egg cell contains a large amount of mitochondria, but seems to lack normal plastids. Most plastids have transformed into large inclusions. Apart from the large inclusions, there are abundant small inclusions and other organelles in the egg cell. During fertilization, pollen tube penetrates into the egg cell at the micropylar end and thereafter the contents are released. Plastid and mitochondrion of male origin are lacking near the fusing sperm-egg nuclei. The second sperm nucleus—not involved in karyogamy—remains at a site near the receptive vacuole. This nucleus is surrounded by large amount of male cytoplasm containing mixed organelles from the sperm cell, tube cell, and egg cell. At the free nuclear proembryo stage, organelles of male and female origin are visible in the perinucleus-cytoplasmic zone. Most of the mitochondria have the same morphological features as those in the egg cell. Some of the mitochondria appear to have originated from the sperm and tube cells. Plastids are most likely of male gametophyte origin because they have similar appearance as those of the sperm and tube cell. Large inclusions in the egg cell become vacuole-like. Paternal plastids have been incorporated into the neocytoplasm of the proembryo. In the cellular proembryo, maternal mitochondria are more abundant. Plastids resembling those of the sperm and tube cell are still present. These cytological results clearly show that in P. tabulaeformis , plastids are inherited paternally and mitochondria bipaternally. The cytological mechanism of plastid and mitochondrion inheritance in gymnosperm is discussed.     

Asymmetric cell division of rice zygotes located in embryo sac and produced by in vitro fertilization

In angiosperms, a zygote generally divides into an asymmetric two-celled embryo consisting of an apical and a basal cell. This unequal division of the zygote is a putative first step for formation of the apical–basal axis of plants and is a fundamental feature of early embryogenesis and morphogenesis in angiosperms. Because fertilization and subsequent embryogenesis occur in embryo sacs, which are deeply embedded in ovular tissue, in vitro fertilization of isolated gametes is a powerful system to dissect mechanisms of fertilization and post-fertilization events. Rice is an emerging molecular and experimental model plant, however, profile of the first zygotic division within embryo sac and thus origin of apical–basal embryo polarity has not been closely investigated. Therefore, in the present study, the division pattern of rice zygote in planta was first determined accurately by observations employing serial sections of the egg apparatus, zygotes and two-celled embryos in the embryo sac. The rice zygote divides asymmetrically into a two-celled embryo consisting of a statistically significantly smaller apical cell with dense cytoplasm and a larger vacuolated basal cell. Moreover, detailed observations of division profiles of zygotes prepared by in vitro fertilization indicate that the zygote also divides into an asymmetric two-celled embryo as in planta. Such observations suggest that in vitro-produced rice zygotes and two-celled embryos may be useful as experimental models for further investigations into the mechanism and control of asymmetric division of plant zygotes.     

天竺葵雌性生殖单位的超微结构

应用透射电镜研究了临近受精时天竺葵(Pelargonium hortorum Bailey)胚囊中的卵细胞、助细胞和中央细胞的结构。证明了卵细胞与助细胞以及助细胞与助细胞之间从合点端至珠孔端有很大的面积以质膜分界,仅珠孔端少部分以壁分隔。卵细胞与中央细胞之间同样缺乏细胞壁。在卵细胞的合点端,两质膜不同程度地分离形成宽窄相间的间隙。在间隙的絮状基质中存在小泡,这些小泡的产生似与卵和中央细胞中周质内质网的活动有关。推测小泡为多糖性质,可能为合子新壁的建造提供物质。卵细胞质中含巨大线粒体,质体和内质网也较丰富。基于超微结构的特征,可认为卵细胞具高度的生理合成活动的潜能。中央细胞极核位于珠孔端与卵器细胞毗邻,有利于在双受精作用中同时发生精细胞与卵细胞和精细胞与中央细胞核的融合。中央细胞的侧壁在珠孔端形成内突,具传递细胞的特点,表明这是雌配子体向孢子体摄取营养的重要部位。助细胞的细胞质含丰富的细胞器,这与多数植物中的相似,但具几个明显的特征,即核中存在微核仁,内质网形成圆球体或脂体,线粒体富集在丝状器的附近。传粉后花粉管进入胚囊之前,两个助细胞中一个退化。     

Early cytological events after induction of cell division in egg cells and zygote development following in vitro fertilization with angiosperm gametes

Early events, such as formation of the cell wall, first nuclear division and first unequal division of the zygote, were examined following in vitro fusion of single egg and sperm protoplasts of maize ( Zea mays L.). The time course of these events was determined. The formation of cell wall components was observed 30 sec following egg—sperm fusion and proceeded continuously thereafter. Within 15 h after fusion most of the organelles became more densely grouped around the nucleus of the zygote. In the in vitro produced zygote the location of the cell organelles and of the dividing nucleus showed polarity. Two nucleoli were first observed 18 h after gamete fusion. The zygotic nucleus remained undivided for about 40 h. The first cell division was observed 40–60 h, generally 42–46 h, after egg—sperm fusion. The non-fused egg cell could be triggered to sporophytic development in vitro by pulses of high amounts of 2,4-D. Without such a treatment, cultured egg cells of different maize lines did not divide. Although nuclear fusion seemed to occur, fusion products of two egg cells also did not divide. Cell wall formation was incomplete and non-uniform, showing a polarity of cultured egg cells and fusion products of two egg protoplasts. Cell division was also induced after fusion of maize egg with sperms of genetically remote species, such as Coix, Sorghum, Hordeum or Triticum . These gametic heterologous fusion products developed to microcalli. Moreover, cell division occurred in fusion products of an egg and a diploid somatic cell-suspension protoplast from maize.     

Changes of Plastids Mitochondria and Their DNA in the Egg Cell Before and After Fertilization in Pharbitis

The ultrastructure and cytoplasmic DNA in the egg cell and zygote of Pharbitis purpurea, (L.) Voyght and P. limbata Lindl. which were studied with electron microscopy and DNA epifiuorescence microscopy. The egg cell before fertilization was highly vacuolated with only a few cytoplasmic plastids and mitochondria. Plastids were spherical and/or rod- shaped containing 1 ～ 2 large starch grains. Most of the mitochondria were cup and/or circular. The cytoplasm in the zygote was much more abundant than that in the egg cell. The number of plastids and their electronic density were greatly increased, in most of which containing osmiophilic bodies. The mitochondria were rich and spherical-shaped in the zygote. Two types of cytoplasmic DNA nucleoids were detected in the egg cell, the more abundant one being big and circle-shaped and the other dot-shaped. Only dot-shaped nucleoids were present in the zygote. The content of nucleoids in the zygote was much less than that in the egg cell. Authors propose that some cytoplasmic DNA may degenerate after fertilization. The ultrastructural characteristics of the egg cell and the reduction of cytoplasmic DNA in the zygote may related to the mechanisms of plastid unipaternal inheritance in Pharbitis.