Electron and immunofluorescence microscopy on the fertilization ofFucus distichus (Fucales,Phaeophyceae)

Summary Processes of fertilization and zygote development inFucus distichus were studied by indirect immunofluorescence microscopy using anti- tubulin antibody and electron microscopy. Just after plasmogamy, sperm aster formation occurs during migration of a sperm nucleus toward an egg nucleus at the center of cytoplasm. Only sparse microtubules (MTs) exist around the egg nucleus. The sperm aster can be observed till karyogamy, but afterwards vanishes. Accompanying sperm aster formation, cortical MTs which are reticulately arranged develop further in the zygotes. In 4 h-old zygotes, characteristic structures which are composed of fine granular masses and consist of intermixed dense and lighter staining areas appear around the nucleus. These structures cannot be detected with anti- tubulin immunofluorescence microscopy. The two centrioles derived from the sperm separate and migrate to both poles. In 4 h-and 8 h-old zygotes, there are no defined MT foci around the zygote nucleus and MTs radiate from the circumference of it. In 12 h-old zygotes, each centriole has migrated to the poles and derivative centrioles are generated. The fine granular masses also migrate to both poles and finally disappear accompanying the appearance of numerous MTs radiating from the poles. Therefore, two distinct MT foci appear from 12 h onwards. Progressive stages of nuclear division were also examined with electron and immunofluorescence microscopy in 16 h-old zygotes. The sperm chloroplast with an eyespot and the sperm mitochondria with an intercristal tubular structure, which are distinctive from those of egg, can be detected after plasmogamy and karyogamy. The sperm chloroplast is still present in 16 h-old zygotes.     

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.     

The spatial distribution of maternal mRNA is determined by a cortical cytoskeletal domain in Chaetopterus eggs

Messenger RNA molecules are localized in the cortical region of eggs and unevenly segregated to the embryonic cells during early development of the annelid Chaetopterus. The egg cortex is enriched in two organelles, ectoplasmic spherules and associated structures, which are similar in appearance to nuage. The physical basis of cortical mRNA localization was examined in stratified eggs and in eggs extracted with the nonionic detergent Nonidet P-40 (NP-40). The cortical organelles were displaced to the most centrifugal zone of stratified eggs. In situ hybridization with poly(U) or cloned DNA probes showed that a large proportion of the poly(A)+RNA, histone mRNA, and actin mRNA molecules was also displaced to the centrifugal zone. Extraction with NP-40 revealed a detergent-insoluble cytoskeletal domain (CD) in the egg cortex which contained the remnants of ectoplasmic spherules and nuage embedded in a fibrous network. Although most of the total protein and RNA was extracted by NP-40, a large proportion of the poly(A)+RNA, histone mRNA, and actin mRNA molecules was retained in the CD. In situ hybridization of stratified eggs extracted with NP-40 indicated that the CD, with its associated organelles and mRNA molecules, is displaced to the centrifugal zone as a unit. The results suggest that the tenacious association of mRNA molecules with the cortical CD may be responsible for maternal mRNA localization during early development.     

Derivation of the membrane comprising the male pronuclear envelope in inseminated sea urchin eggs

Investigations were conducted in an effort to determine the origin of the membrane comprising the male pronuclear envelope of inseminated sea urchin eggs. The events of fertilization in zygotes treated with 200 μg/ml of puromycin are not impaired even though incorporation of [³H]leucine is inhibited up to 80% when compared to control specimens. Developing male pronuclei in zygotes treated with puromycin form nuclear envelopes structurally similar to and within the same period as controls. In puromycin-treated and untreated zygotes morphologically recognizable portions of the sperm nuclear envelope are incorporated into the structure of the male pronuclear envelope. Pronuclear development was also examined in inseminated ova where most of the endoplasmic reticulum (ER) was confined to a specific area of the zygote. Eggs were centrifuged in order to stratify their organelles into specific layers (stratified eggs); with further centrifugation stratified eggs are bisected to form nucleate (rich in ER) and nonnucleate halves (containing little ER). Observations of inseminated stratified eggs and nucleate and nonnucleate halves demonstrate an inverse relation between the amount of ER present in the vicinity of a reorganizing sperm nucleus and the time it takes to form the male pronuclear envelope. Computation of the maximum quantity of membrane in the male pronucleus that may be derived from the sperm nuclear envelope is approximately 15%. These investigations suggest that a major portion of the male pronuclear envelope is derived from endoplasmic reticulum within the egg and only a small portion (up to 15%) originates from the sperm nuclear envelope.     

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.     

Localization of arabinogalactan proteins in egg cells, zygotes, and two-celled proembryos and effects of beta-D-glucosyl Yariv reagent on egg cell fertilization and zygote division in Nicotiana tabacum L

Arabinogalactan proteins (AGPs) have been implicated in a variety of plant development processes including sexual plant reproduction. As a crucial developmental event, plant sexual reproduction generally occurs inside an ovule embedded in an ovary. The inaccessibility of the egg cells, zygotes, and embryos has hindered our understanding of the importance of AGPs in the early events involving fertilization, zygotic division, and early embryogenesis. In this study, the well-established in vitro zygote and ovary culture systems, together with immunofluorescence and immunogold labelling techniques, were employed to investigate the role of AGPs in the early events of sexual reproduction in Nicotiana tabacum. Dramatic changes in AGP content during ovule development were evidenced by western blotting. Subcellular localization revealed that AGPs are localized in the plasma membrane, cell wall, and cytoplasm of pre- and post-fertilized egg cells, and cytoplasm and vacuoles of two-celled proembryos. Abundant AGPs were detected in unfertilized egg cells; however, the level of AGPs substantially decreased in fertilized egg cells. Polar distribution of AGPs in elongated zygotes was observed. The early two-celled proembryos just from zygote division displayed accumulation of AGPs at a low level, while in the elongated two-celled proembryos at the late stage, the AGP content clearly increased. Provision of betaGlcY, a synthetic phenylglycoside that specifically binds AGPs, to the in vitro cultures of isolated zygote and fertilized ovaries increased abnormal symmetrical division of zygotes. In the culture of pollinated but unfertilized ovaries, addition of betaGlcY resulted in arrest of fertilization of the egg cells, but had no effect on fertilization of the central cells. The possible roles of AGPs in fertilization, zygotic division, and proembryo development are discussed.     

Differences in the macromolecular composition of the zona pellucida isolated from pig oocytes, eggs, and zygotes

The macromolecular differences in the zona pellucida (ZP) isolated from pig oocytes, eggs, and zygotes were investigated using two-dimensional polyacrylamide gel electrophoresis. The ZP was isolated from individual cells or zygotes using micropipettes, radiolabeled with 125I and analyzed using disulfide bond reducing and nonreducing conditions. The reduced ZP isolated from oocytes was composed of four glycoprotein components. The gel pattern of the ZP isolated from a single oocyte was indistinguishable from that isolated en masse. The ovulated egg ZP contained the four oocyte components plus three additional macromolecules. Relative to the egg ZP, the zygote ZP lacked one component but had three additional smaller macromolecules. We concluded that: the macromolecular differences between the oocyte and egg ZPs are caused by the addition of macromolecules to the ZP as the egg transits the oviduct, the macromolecular differences between the egg and the zygote ZPs reflect hydrolytic processing of ZP glycoproteins probably by enzymes derived from the egg cortical granules, and the microheterogeneity of the pig ZP glycoproteins is due to posttranslational modification and is not due to population genetic variation.     

Morphology and fertilizability of zona-free hamster eggs separated into halves and quarters by centrifugation

When mature hamster eggs were freed from their zonae pellucidae and centrifuged in a Percoll gradient, each egg was separated into a light half and a heavy half. Chromosomes remained in their original position during centrifugation, resulting in the production of light and heavy halves with and without chromosomes. When the eggs were treated with cytochalasin D (CD) and then centrifuged, the chromosomes moved to the centripetal pole and were extruded rapidly before each egg separated into halves or fragments. In the eggs without CD treatment, the density of cortical granules was reduced in the centripetal region of the egg. In those treated with CD, the density of the granules was reduced in both centripetal and centrifugal regions of the egg. Both light and heavy halves were fertilizable. There was, however, a notable difference between light and heavy halves. Most of the heavy halves supported development of sperm nuclei into pronuclei, whereas only few of light halves could do so, suggesting that most of light halves were lacking or deficient in materials necessary for the development of a sperm (male) pronucleus. When the light and heavy halves were centrifuged further, each separated into two quarters. The lightest quarter, which was almost totally devoid of organelles, was buoyant and very fragile. Spermatozoa could fuse with it, but the incidence of the fusion was low. In this quarter, the sperm nucleus could decondense, but could not develop into a pronucleus. This was in marked contrast with other three quarters in which sperm nuclei could develop into well-formed pronuclei.     

Dislocation of gold particles in the cytoplasm of mouse zygotes during cleavage

Summary Gold particles were introduced into mouse zygotes before the first cleavage. At cleavage, dislocation of particles within the cytoplasm was monitored. Cytoplasmic movement occurs in the central region of dividing zygotes as judged from the centripetal dislocation of particles there. Cytoplasm in polar regions appears less mobile. No particle crosses a vertical axis of the zygote during cytokinesis, which suggests that the cytoplasm of the arising blastomeres is not mixed. Our general conclusion is that the cytoplasmic territories of the mouse egg appear to be passively segregated between two blastomeres.     

Fertilization-induced changes in the microtubular architecture of the maize egg cell and zygote—an immunocytochemical approach adapted to single cells

By using single cell micromanipulation techniques, we developed an immunocytochemical procedure to examine subcellular protein localization in isolated and cultured cells. Localization of microtubules was examined in isolated single egg cells and developing zygotes of maize with anti--tubulin antibodies. In egg cells, a few cortical microtubules were detected but well organized microtubules were rarely observed. In contrast, distinct cortical microtubules and strands of cytoplasmic microtubules radiating from the nucleus to the cell periphery were observed in developing zygotes. Solely cortical microtubules were observed in zygotes up to 7 h after in vitro fertilization. After this time, radiating microtubules additionally appeared, and persisted during zygote development. These results indicate early and pronounced fertilization-induced changes in microtubular organization in the fertilized egg cell of maize.     

Relationship between ectopic germinal vesicle breakdown in Xenopus oocytes and dorsal development of the embryo

The early development of several species involves the segregation of cytoplasmic components into different regions of the egg. In Xenopus zygotes, a 30° rotation displaces the central animal cytoplasm to the future dorsal side of the embryo. To elucidate the role of the central animal cytoplasm in dorsal determination, we induced germinal vesicle breakdown (GVBD) closer to the equator by cold/centrifugation treatment of oocytes. Centrifugation moved the germinal vesicle to the centripetal side; eggs with such displaced GVBD fertilized and began to develop normally. Dorsal embryonic structures tended to develop on the GVBD side of the egg, but displacement of the GVBD was insufficient to rescue dorsal structures in axis-deficient embryos. The labeling of yolk platelets of oocytes with Trypan Blue revealed similar cytoplasmic patterns in control and treated eggs. Furthermore, 67% of treated eggs had Danilchik's swirl, indicative of the dorsal side, on the GVBD side. In conclusion, both the swirl and dorsal development tend to occur on the GVBD side of cold/centrifuged eggs; however, displaced GVBD cannot by itself determine dorsality.     

An electron microscope study on in vitro parthenogenesis in sunflower

Summary Electron microscope studies have been conducted on the parthenogenesis induced by in vitro culture of unfertilized ovules of sunflower (Helianthus annuus). In comparison with the state of the egg prior to inoculation, some eggs 5 days after culture show striking ultrastructural changes, which include, among others, nuclear migration, an increase in the number and activity of the organelles, a loss of polarity and wall formation at the chalazal end of the cell. Most of these changes are similar to those that occur normally in the zygote, indicating that parthenogenic development has been triggered in these eggs. Such eggs have been termed activated and are presumed to be capable of undergoing parthenogenesis. The parthenogenic proembryos which result share some features in common with zygotic proembryos. In addition, some parthenogenic proembryos exhibit unique properties not found in zygotic proembryos. These include embryos that consist of two parts differing markedly in density, an inversion of polarity, the frequent occurrence of autophagic vacuoles, the thickening of cell walls, a centripetal growth mode of wall formation, the appearance of an incomplete cell wall, free nuclear division, amitosis and degeneration. We believe that these ultrastructural peculiarities are the effects of in vitro culture.     

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.     

Distribution of ion channels in ascidian eggs and zygotes

Ascidian eggs and zygotes were whole-cell voltage-clamped and inward membrane currents, generated by stepping the membrane potential, studied from fertilization up to cytokinesis. Currents, induced by changing the voltage in steps from -80 to -30 mV, or to 0 mV, had maximum amplitudes which ranged from 400 to 1200 pA in the unfertilized egg and 100 to 1300 pA in the zygote. At 5 to 10 min after fertilization it was not possible to generate inward currents owing to the activity of nonspecific fertilization channels. Preceding cytokinesis, we observed a reduction in amplitude of the inward currents. By cutting eggs and zygotes into fragments, we have shown that the ion channels generating these inward currents are symmetrically distributed over the egg plasma membrane, but regionalized in the zygote with a maximum density at the animal pole.     

Pelargonium embryogenesis: cytological investigations of organelles in early embryogenesis from the egg to the two-celled embryo

. Changes in the distribution of organelles and organelle-DNA in Pelargonium zonale from the mature egg cell stage to the first zygotic division during the early stages of embryogenesis were investigated using electron microscopy and fluorescence microscopy. The mature egg is a large, polarized bulbous-shaped cell, tapering toward its micropylar end. The wide chalazal region has a large nucleus that is surrounded by cytoplasm containing many giant mitochondria and large amyloplasts. The mitochondria contain a large amount of mitochondrial DNA and appear as long stretched rods or complex rings, sometimes consisting of several concentric or half-concentric circles in sections. The time from pollination to cell fusion is approximately 6-9 h and it is 20-24 h until the first zygotic division. The changes in the zygote and its organelles preparatory to division occur in 3 stages. At stage 1 (6-9 h after pollination), cell fusion occurs and the zygote begins to elongate. Many vacuoles of varying size appear surrounding the nucleus. At stage 2 (9-15 h), the zygote nucleus migrates to a central position in the cell and the mitochondria form a single ring that becomes either irregularly crushed or appears as long thin strings. Amyloplasts exhibit a gradual decrease in the number of starch grains. At stage 3 (15-20 h), the vacuoles disappear, except for a few that remain in the micropylar region, and cell size decreases. Mitochondria become short, fine strings or small rings. Amyloplasts with starch grains are no longer observed, but are transformed into large proplastids. Following the first division of the zygote, approximately equal-sized apical and basal cells are formed. Short rod-shaped or small ring-shaped mitochondria are randomly distributed near the nucleus of the apical cell, whereas mitochondria in the basal cell are long and rod-shaped. In the electron microscope, two types of plastids can be distinguished: dark oval plastids originating from the sperm cell, which are observed in both the apical and basal cell, and others with a less dense, amorphous matrix, believed to originate from egg amyloplasts, which are unevenly distributed in the micropylar region of the basal cell. Fluorometry using a video-intensified microscope photon counting system reveals that, correlated with changes in mitochondrial morphology, DNA amount within the mitochondrion decreases linearly during these stages.     

Fluorescence visualization of the distribution of microfilaments in gonads and early embryos of the nematode Caenorhabditis elegans

Several intracellular motility events in the Caenorhabditis elegans zygote (pseudocleavage, the asymmetric meeting of the pronuclei, the segregation of germ line-specific granules, and the generation of an asymmetric spindle) appear to depend on microfilaments (MFs). To investigate how MFs participate in these manifestations of zygotic asymmetry, the distribution of MFs in oocytes and early embryos was examined, using both antibodies to actin and the F-actin-specific probe rhodamine-phalloidin. In early-stage zygotes, MFs are found in a uniform cortical meshwork of fine fibers and dots or foci. In later zygotes, concomitant with the intracellular movements that are thought to be MF mediated, MFs also become asymmetrically rearranged; as the zygote undergoes pseudocleavage and as the germ line granules become localized in the posterior half of the cell, the foci of actin become progressively more concentrated in the anterior hemisphere. The foci remain anterior as the spindle becomes asymmetric and the zygote undergoes its first mitosis, at which time fibers align circumferentially around the zygote where the cleavage furrow will form. A model for how the anterior foci of actin may participate in zygotic motility events is discussed. Phalloidin and anti-actin antibodies have also been used to visualize MFs in the somatic tissues of the adult gonad. The myoepithelial cells that surround maturing oocytes are visibly contractile and contain an unusual array of MF bundles; the MFs run roughly longitudinally from the loop of the gonad to the spermatheca. Myosin thick filaments are distributed along the MFs in a periodic manner suggestive of a sarcomere-like configuration. It is proposed that these actin and myosin filaments interact to cause sheath cell contraction and the movement of oocytes through the gonad.     

Dynamics of Nuclear DNA Quantities during Zygote Development in Barley

Quantities of DNA were estimated in the nuclei of mechanically isolated egg and zygote protoplasts in two cultivars of barley using 4[prime],6-diamidino-2-phenylindole staining and microfluorometry. Unlike many previous studies on DNA amounts within the sex cells of flowering plants, we obtained consistent and unambiguous results indicating that the egg and sperm nuclei are at the 1C DNA level (basic haploid amount) at the time of karyogamy. Karyogamy was initiated within 60 min postpollination, and the male chromatin became completely integrated into the egg nucleus within 6 to 7 hr postpollination (hpp). Zygotic nuclear DNA levels began to increase at ~9 to 12 hpp in cultivar Alexis and at 12 to 15 hpp in cultivar Igri. The 4C DNA complement was reached in most zygotes by 22 to 26 hpp in cultivar Alexis and by 23 to 29 hpp in cultivar Igri. These data are fundamental to a better understanding of fertilization and zygote maturation in flowering plants. They are also relevant to studies in which the timing of zygotic DNA replication is of interest, such as ongoing investigations on genetic transformations in barley using the microinjection technique.