EMBRYO SAC LACKING ANTIPODAL CELLS IN ARABIDOPSIS THALIANA (BRASSICACEAE)

Ultrastructure of the embryo sac lacking antipodals in prefertilization stages in Arabidopsis thaliana has been examined 2 hr before and 5 hr after manual cross pollination. The cytoplasm of both synergids before fertilization is rich in ribosomes, mitochondria, and rough endoplasmic reticulum, and also contains several microbodies and spherosomes. The filiform apparatus includes electron-dense material and a fibrous part. Many cortical microtubules appear in the filiform apparatus area. One of the two synergids degenerates before fertilization. The synergids, the egg cell, and central cell have a rich cytoskeleton of microtubules; only the synergids appear to contain microfilaments. At the chalazal end, the antipodals are initially present but degenerate by the time of pollination in most embryo sacs in the starchless line studied. The embryo sac is completely surrounded by a wall containing an electron-dense layer, separating it from the nucellus, including the chalazal end. When the antipodals have degenerated, the electron-dense layer disappears at the chalazal end only, and the wall between the central cell and the nucellus is homogeneous. Between the central cell and nucellar cells no plasmodesmata are found. The membranes of both antipodal cells at the chalazal end of the embryo sac appear sinuous, like those of transfer cells. The central cell has plastids preferentially distributed around the nucleus, but the other organelles are randomly distributed. The central cell in the embryo sac and the adjacent chalazal nucellar cells show a transfer-cell function in the embryo sac after the antipodals degenerate.     

Iatercellular Migration of Protoplasm and Its Relation to the Development of Embryo Sac in Nucellus of Wheat

During the development of the ovule before pollination, deterioration of successive layers of nucellar tissue, beginning from the nnermost, constantly takes place and consistently forms a zone of disorganization surrounding the periphery of the enlarging embryo sac. Nucellar tissue deteriorates much more profusely near the antipodal end of the sac. "Nuclear extrusion" taken as an indication of intercellular movement of the protoplasm which has undergone partial disassembly, can be seen among the nucellar tissues and between the nucellus and the embryo sac. The intruding nuclear fragments, some of which assume the form of nucleolus, can be found in the antipodal cells. The results interpreted according to our previous hypothesis, are as follows. The nucellar cell by means of intercellular movement of its own protoplasm in the state of partial disassembly, furnishes the embryo sac with composite units of various polymers and organelles. Consequently, the antipodal cells proliferate and flourish The interrelationship between nucellus and embryo sac has been discussed from the viewpoint of supply and utilization of nourishment, which is necessary for the rapid development of the embryo sac.     

宁夏枸杞大孢子发生和雌配子体发育的细胞学研究

采用半薄切片技术和组织化学染色法对宁夏枸杞大孢子发生和雌配子体发育过程中的细胞结构变化及营养物质积累特征进行了观察。结果表明,(1)宁夏枸杞为中轴胎座,多室子房,倒生胚珠,单珠被,薄珠心类型。(2)位于珠心表皮下的孢原细胞可直接发育为大孢子母细胞,减数分裂后形成直线型大孢子四分体,合点端第一个大孢子发育为功能大孢子,胚囊发育类型为蓼型,具有珠被绒毡层。(3)初形成的胚囊外周组织中没有营养物质积累,成熟胚囊时期出现了大量的淀粉粒且呈珠孔端明显多于合点端的极性分布特征。(4)助细胞的珠孔端具有明显的丝状器结构,呈PAS正反应表现出多糖性质,成熟胚囊具有承珠盘结构。     

Optimization of conditions for in situ hybridization and determination of the relative number of ribosomes in the cells of the mature embryo sac of maize

Summary We have initiated experiments to understand the molecular regulation of embryo sac development in flowering plants by a study of ribosome synthesis and accumulation. Because of the very small size of the embryo sac and the large volume of ovule tissue it is embedded in, in situ hybridization with nucleic acid probes is presently the only practical method for such molecular measurements on individual cells of the embryo sac. Methods of tissue preparation, sectioning and screening of ovules for embryo sac containing sections, in situ hybridization using a ribosomal mRNA probe, and staining were optimized. Relative densities of silver grains for individual cells of the mature maize (W22) embryo sac were determined from in situ hybridizations. The silver grain counts are directly related to the numbers of ribosomes. Volumes of individual cells were determined by confocal microscope image analysis, and this permitted the calculation of the relative total numbers of ribosomes in individual cells of the embryo sac and nucellus. The central cell has a volume 260 times that of a nucellar cell at the micropylar end of the ovule, 15 times that of the egg cell, 30 times that of a synergid, and 130 times the volume of an antipodal cell. The mature maize embryo sac has 20 or more antipodal cells. The central cell has approximately 200 times the number of ribosomes as are present in a nucellar cell, about 7 times as many ribosomes as are in the egg cell, 14 times as many ribosomes as in each synergid, and about 80 times the ribosome content of individual antipodal cells. The data are discussed with respect to the utilization of the ribosomes following fertilization in the early embryo and endosperm.     

A CYTOCHEMICAL STUDY OF EMBRYO SAC DEVELOPMENT IN STELLARIA MEDIA

Megasporogenesis and embryo sac development in Stellaria media were investigated using cytochemical methods for the demonstration of nucleic acids, proteins, and polysaccharides. RNA concentrations were high in the archesporial cells, low in the megaspore mother cell, and increased again to high concentrations with the formation of the megaspore and 2-, 4-, and early 8-nucleate embryo sac. RNA levels were also high in the egg and primary endosperm nucleus but low in the synergid and antipodal cells. Nucleolar size and vacuolation were indicative of RNA synthetic activity. Protein concentrations were parallel in concentration and distribution to those observed for RNA. Polysaccharides were conspicuously absent from all stages except the synergids and nucellar cells. Feulgen-stained DNA was demonstrable in the antipodal cells, megaspore mother cell, and megaspore cell, but was not visible in the 2-, 4-, or early 8-nucleate embryo sac. Feulgen staining was also absent from the egg and primary endosperm nucleus but was visible in the synergids and antipodals. Histones were difficult to visualize anywhere except in the egg cytoplasm and the nuclei of the antipodals.     

ADVENTIVE EMBRYOGENESIS IN CITRUS AND ITS RELATION TO POLLINATION AND FERTILIZATION

Cytological and histological studies of seeds from three facultative apomictic Citrus cultivars show that adventive embryos develop, as a rule, from the first few cell layers of the nucellus adjacent to the embryo sac in the micropylar half and occasionally from the chalazal end. The adventive embryos initiated in nucellar tissue away from the embryo sac and most of those initiated from the chalazal end of the nucellus do not develop beyond the one-celled stage. When two or more embryos are developing in the same seed, the successful development of a given embryo depends on its location in relation to access to nutrients from the endosperm. The presence of a zygote and triploid endosperm in seeds with adventive embryos, the abortion of seed when endosperm degenerates, and the lack of seed set without pollination indicate that pollination and fertilization are essential for in vivo adventive embryogenesis.     

水蔗草兼性无融合生殖胚胎学研究

对水蔗草 (ApludamuticaL .)的生殖方式进行研究 ,结果表明水蔗草进行兼性无融合生殖。胚囊发育分为两种类型 ,即有性生殖的蓼型和无孢子生殖的大黍型。无融合生殖胚囊频率为 6 0 .74%。在大孢子母细胞发育至四分体后 ,珠孔端的 3个大孢子解体。合点端的大孢子未解体时 ,邻近大孢子的 1个珠心细胞开始特化 ,形成无融合生殖的原始细胞 ,由该原始细胞发育形成有 1个卵细胞、1个助细胞和 2个极核的四核胚囊。     

The Structural Changes During the Degeneration Process of Antipodal Complex and Its Function to Endosperm Formation in Wheat Caryopsis

During the early developmental stage of wheat caryopsis the antipodal complex (composed of 20 or more cells) located on the chalazal part of embryo sac gradually turns to degeneration and degradation from its outer part to the innermost, undergoing apparent structural changes of protoplasm. The senescent tissue (antipodals) exports its cell contents continually to support the proliferation and enlargement of the adjacent free-nuclear endosperm and accommodate the dual function of both material transport and nurture supply. The lacking of callose deposition on the boundary wails between antipodals and endosperm is much benefit to the solute transport, but not all cell contents in antipodals undergo thorough degradation until exporting, at least, part of the protoplasm only undergoes limited structural disintegration. The disassembled protoplasmic constituents actively migrate through symplast route in the form of macromolecule. This shows another mode of material transport in feeding endosperm. The occurrence of wide cytoplasmic channel in part of boundary wal ls berween antipodals and endosperm shows a special structural transformation of intercellular connection. Therefore, disassembled nuclear materials, cisternae of endoplasmic reticulum and plastids, mitochondria, etc. could migrate from antipodals into the developing endosperm. It is deduced that this mode of material transport may play an important role in supporting rapid proliferation and enlargement of free-nuclear endosperm in the developing caryopsis.     

Megasporogenesis, female gametophyte development and embryonic development of Ambrosia L. in China

The megasporogenesis, female gametophyte development and embryonic development of Ambrosia artemisiifolia L. and Ambrosia trifida L. of genus Ambrosia L. in China were studied using conventional paraffin section technology and optical microscopy. The results show that both A. artemisiifolia L. and A. trifida L. have a bilobed pistil stigma, two carpels, one chamber, basal placenta, unitegmic, tenuinucellate, anatropous ovule, and well-developed integumentary tapetum. Megaspore mother cells are directly developed from archesporial cells originated from the nucellar cells under the nucellar epidermis and further undergo meiosis to form linear tetrads. The megaspore at the chalazal end develops into a functional megaspore and the other three megaspores are degraded. The development of embryo sac is monosporic type. After three consecutive mitosis, mononucleate embryo sac becomes a mature embryo sac with two synergids and one egg cell at the micropylar end, a central cell at the center and three antipodal cells at the chalazal end. Most antipodal cells are mononucleate or binucleate, only few are trinucleate. The embryonic development process contains four stages: globular embryo, heart-stage embryo, torpedo-stage embryo and mature embryo. The development of endosperm is cellular type.     

水蔗草兼性无融合生殖胚胎学研究

对水蔗草(Apluda mutica L.)的生殖方式进行研究,结果表明水蔗草进行兼性无融合生殖.胚囊发育分为两种类型,即有性生殖的蓼型和无孢子生殖的大黍型.无融合生殖胚囊频率为60.74%.在大孢子母细胞发育至四分体后,珠孔端的3个大孢子解体.合点端的大孢子未解体时,邻近大孢子的1个珠心细胞开始特化,形成无融合生殖的原始细胞,由该原始细胞发育形成有1个卵细胞、1个助细胞和2个极核的四核胚囊.     

The Embryology of Nyssa sinensis Oliv. (Nyssaceae)

The flower develops in March and blossoms in early May in Nanjing. The cytokinesis of microsporocytes is simultaneous and most tetrads are tetrahedral. The tapetum is secretory and the nuclei become polyploid at last. The style is solid and most ovaries are unilocular, rarely bilocular. The ovule is pendulous, anatropous and unitegmic. The nucellus is pseudocrassinucellate. An obturator formed by transmitting tissue covers the micropyle. The raphe vascular strand extends into the integument when it reaches the chalaza and on a whole keeps a “U” shape. The endothelium cell is uninucleate. In most cases no nucellar cap is formed. No hypostase is found below the embryo sac. The archesporium is one-celled. The embryo sac development conforms to the Polygonum or Allium types. The degeneration of the megaspores in the linear tetrad usually occurs from the chalazal toward the micropylar end. Two synergids persist during fertilization. Three antipodal cells are uninucleate and ephemeral. Two polar nuclei fuse at the time of fertilization. The fertilization type accords with porogamy. The syngamy is premitotic. The development of endosperm is cellular. The initial four successive divisions of the primary endosperm cell are transverse-verticaltransverse-transverse subsequently, giving rise to sixteen cells of the early endosperm. The mature embryo is straight and nearly as long as the endospermous seed. The cotyledons are more or less cordate at base. The seedoat is thin and composed of 5-11 layers of compressed cells. Neither embryo nor endosperm contain the alkaloid camptothecine. The major similarities of Nyssa sinensis to the American nyssas in embryology, which may be a counted as the generic features, are the polyploid tapetum cells, the unitegmic ovule with U-shaped vascular strand, the direct enlargement of the archesporial cell to produce the megasporocyte, the pseudocrassinucellus, the usual absence of the nucellar cap, the Polygonum or Allium type of the embryo sac development, the first degeneration of the metachalazal megaspore, the ephemeral antipodal cells, a single nucleolus in the nucleus ofthe primary endosperm cell, the more or less cordate base of the cotyledons.     

Some aspects of organization and histochemistry of the embryo sac ofScilla sibirica sato

Summary The present investigation deals with some of the organizational and histochemical aspects of the embryo sac ofScilla sibirica. Both the synergids and egg cell are invested by PAS-positive complete walls. The filiform apparatus comprises an elaborate system of fibrillar projections, showing extensive ramifications. The micropylar region of the embryo sac wall from where the filiform apparatus originates is composed of three distinct layers. On a histochemical basis it may be surmised that, unlike the egg cell, the synergids are metabolically very active. Two kinds of wall ingrowths (i) massive and highly branched very much akin to the filiform apparatus, and (ii) small tuberculate wall projections, are unique to the antipodal cells of S.sibirica. Small tuberculate projections have also been observed along the wall of the central cell adjacent to the nutrient-rich nucellar cells. The antipodals and the central cell show the presence of starch grains and abundant total proteins. All the cell types in the embryo sac ofS. sibirica are structurally so organized as to meet the requirements of its nutrition during pre- and postfertilization development. The presence of abundant PAS-positive granular substance in the cells of nucellar epidermis probably establishes a gradient which assists in the pollen tube growth.     

水稻胚囊壁的形成与发育观察

通过透射电镜对水稻(Oryza sativa L.)功能大孢子形成开始至胚囊成熟期间胚囊壁的形成与发育进行观察,结果表明:水稻胚囊壁是在原有功能大孢子壁的基础上,通过与其周围退化珠心细胞留下的壁相叠合,使壁加厚。功能大孢子近合点端壁存在胞间连丝,其中个别胞间连丝可保留到八核胚囊。胚囊壁上内突最早于四核胚囊近珠孔端发生。八核胚囊形成后,内突的发育在胚囊不同的细胞中表现不同,其中以中央细胞最具特点,表现为先在中央细胞与珠心相接的近珠孔端和近合点端两个区域的胚囊壁上形成,以后近珠孔端胚囊壁上的内突大量增加,而近合点端的却增加不明显,中部胚囊壁上的内突出现的时间相对较晚。到胚囊成熟时,近珠孔端胚囊壁上内突的分布密度最大,中部次之,近合点端的最小,三个区域上内突的形态各异。反足细胞与珠心相接的胚囊壁上内突的形成时间较早,但以后的发育却相对缓慢,数量增加不明显。2个助细胞交界处胚囊壁上的丝状器在胚囊未明显膨大时已形成。卵细胞除在与助细胞交界处的壁外,其它部位不形成明显的内突结构。     

高山红景天胚胎学研究

高山红景天(Rhodiola sachalinensis A.Bor.)具8个雄蕊,每个雄蕊有4个花粉囊。小孢子母细胞减数分裂时,胞质分裂为同时型。形成的四分体为四面体形。花药壁由表皮、药室内壁、二层中层和绒毡层五层细胞组成,其发育方式为基本型。腺质型绒毡层,有些绒毡层细胞分裂形成不规则双层,少数细胞双核。二细胞型花粉。雌蕊由4心皮组成。边缘胎座,倒生胚珠,双珠被,厚珠心,胚珠发育中形成珠心喙。大孢子四分体线形或T -形,合点大孢子具功能。胚囊发育为蓼型。成熟胚囊中,卵细胞核、助细胞核均位于细胞的合点端,珠孔端具液泡;极核融合为次生核,并位于卵细胞合点端附近; 3个反足细胞退化。双受精属于有丝分裂前配子融合类型。胚的发育为石竹型;基细胞侵入珠孔端,形成囊状吸器。细胞型胚乳;初生胚乳核分裂形成两个细胞,其珠孔端的细胞发育成胚乳本体,合点端的细胞直接发育成具一单核的合点吸器。     

Ultrastructural characterization of apospory in Panicum maximum

The nucellar ultrastructure of apomictic Panicum maximum was analyzed during the meiocytic stage and during aposporous embryo sac formation. At pachytene the megameiocyte shows a random cell organelle distribution and sometimes only an incomplete micropylar callose wall. The chalazal nucellar cells are meristematic until the tetrad stage. They can turn into initial cells of aposporous embryo sacs. The aposporous initials can be recognized by their increased cell size, large nucleus, and the presence of many vesicles. The cell wall is thin with few plasmodesmata. If only a sexual embryo sac is formed, the nucellar cells retain their meristematic character. The aposporous initial cell is somewhat comparable to a vacuolated functional megaspore. It shows large vacuoles around the central nucleus and is surrounded by a thick cell wall without plasmodesmata. In the mature aposporous embryo sac the structure of the cells of the egg apparatus is similar to each other. In the chalazal part of the egg apparatus the cell walls are thin and do not hamper the transfer of sperm cells. Structural and functional aspects of nucellar cell differentiation and aposporous and sexual embryo sac development are discussed.     

Ultrastructure of endopolyploid antipodals inAconitum vulparia Rchb.

Summary The ultrastructure of antipodals ofAconitum vulparia Rchb. was studied at two stages of development: at the earlier stage the endosperm has several nuclei, at the later one the endosperm is multinucleate. Over the investigated period the antipodal size enlarges distinctly. The wall ingrowths increase in size and number. Finally, they occur throughout the antipodal walls except for a small area in the extreme chalazal part, sunk deep into the nucellar podium. There are no plasmodesmata in the antipodal cell walls. The cytoplasm is dense and rich in ribosomes; it shows weak vacuolation. The rough endoplasmic reticulum is well developed. At the later stage dilated cisternae of endoplasmic reticulum are formed. Mitochondria, plastids and active dictyosomes are abundant. At the later stage some giant mitochondria are present; their matrix contains a large clear area with fine fibrils and an aggregation of fibrillar material. At this stage of development plastids have two types of inclusions: electron-transparent vacuoles and aggregations of electron-dense granules. The giant endopolyploid nuclei are considerably larger than those at the mature embryo sac stage; they are lobed on all sides.During the studied periodA. vulparia antipodals seem to be at their most active state.     

粉叶小檗大孢子发生和雌配子体形成

采用石蜡切片方法对粉叶小檗（Berberis pruinosa Franch.)的大孢子发生和雌配子体形成过程进行了研究。主要结果如下：雌蕊1枚,子房单心皮,边缘胎座,2枚胚珠倒生,具双珠被,厚珠心,珠孔由内外两层珠被共同形成,呈“Z”字形;单孢原,位于珠心表皮下;直线形大孢子四分体,合点端的1个大孢子发育为功能大孢子,胚囊发育类型为蓼型;成熟胚囊中,2个极核在受精前融合为次生核;3个反足细胞不发达,较早退化;"品"字形卵器,其中助细胞发达且具丝状器。     

Embryology of barley. IV. Ultrastructure of the antipodal cells of Hordeum vulgare L. cv. Bomi before and after fertilization of the egg cell

The antipodal cells have been the stepchildren in most investigations of the female gametophyte. In Hordeum vulgare cv. Bomi, three antipodal cells are originally developed chalazally but because of differential growth of the embryo sac they soon become laterally situated and their number increases to 35–50 cells and the shape, size and structure of the cells change in the time before as well as after fertilization. The cells persist until about 60–70 h after pollination. At that time, the embryo consists of about 12–15 cells and a cellularization of the nuclear endosperm has started peripherally. The size of nuclei, and especially nucleoli, in the antipodal cells increases tremendously in the investigated period and the amounts of organelles also change. The walls of antipodals are diversified depending on which cells they are separating, and wall invaginations are developed especially between antipodal cells and surrounding nucellar cells in the placental region. The mitochondria appear in various shapes in section view, very often as cups or dumbbells with a rim in the ends containing cristae and a thin cristae-free base. These bases are sometimes stretched out as thin parts and at last a simple parting occurs. Binary fissions of the plastids happen especially in the hours before and just after egg fertilization. ER is extraordinarily well developed in the whole period of investigation and many ribosomes are attached to the membranes. Dictyosomes form numerous vesicles, especially in the antipodals near the nucellar cells in the placental region. These ultrastructural details support the opinion that antipodal cells may play an important role in the embryo sac and are able to be responsible for the supply of nutrition for the whole gametophyte and take part in the supply of nutrition during embryo formation.     

An anatomical study of ovary-to-cuke development in consistently low-producing trees of the ‘Fuerte’ avocado (Persea americana Mill.) with special reference to seed abortion

Summary Cukes develop from female-sterile, cryptically male flowers on consistently low-producing Fuerte trees. A hypostase that has, as yet, not been reported for the avocado, is present in the chalazal tissue of the mature ovule and aborting seed. This layer seems to play a role in the degeneration of the peripheral nucellar tissue and the non-development of the intercalary meristem of the pachychalaza. The ultimate cause of cuke formation, however, seemingly lies in the disturbance of the polarity of the primordial nucellar tissue. Additional megagametophytes and non-functional megaspores that develop in the nucellus effect the collapse of the chalazal region of the embryo sac. Degeneration of these gametophytes and megaspores causes the formation of nucellar cavities that isolate the embryo sac from the nutritive tissues and chalazal flow of nutrients. The micropylar region of the embryo sac contains a well-developed egg cell, synergids and central cell nucleus. An embryo and a limited amount of endosperm tissue are formed. Because the endosperm is starved of nutrients, the formation of this tissue is curtailed at an early stage, and embryo development ceases. A meristematic zone that initiates from the inner layers of the outer integument, directly opposite the place where the vascular supply to the chalaza terminates, causes abnormal growth in the outer integument. It is suggested that, due to the absence of meristematic activity in the chalazal region of the embryo sac and the non-developing pachychalaza, resources are redistributed towards the stronger sink, i.e. the outer integument. Consequently, this part of the seed coat proliferates, while the embryo sac and pachychalaza degenerate. In spite of the abortion of the seed, the pericarp of the cuke continues to develop, possibly because the pericarp of the avocado contains phytohormones.