Changes in cell surface charges during differentiation of isolated micromeres and mesomeres from sea urchin embryos

Changes in the negative surface charge were observed by cell electrophoresis during the differentiation of micromeres and mesomeres isolated from 16-cell-stage sea urchin embryos. Micromeres and mesomeres were separated by a sucrose density gradient column and were cultured in normal seawater. An isolated micromere developed to a cell aggregate, and, at the mesenchyme-blastula stage of control, the aggregate began to scatter into single cells. These processes are quite similar to those of the primary mesenchyme cells in situ. An isolated mesomere, on the other hand, developed into an ectodermal vesicle. At desired stages of development, the cell aggregates which derived from single blastomeres were dissociated into single cells, and their electrophoretic mobilities were measured. It was found that the electrophoretic mobility of the micromere- and mesomere-derived cells concomitantly increased from the early blastula stage up to the early mesenchyme stage. In contrast with the mesomere-derived cells, however, the micromere-derived cells showed another increase in electrophoretic mobility when the cells began to migrate as primary mesenchyme cells. These results show that a correlation exists between the increase in cell surface negative charge and the migration of the primary mesenchyme cells.     

Patterns of junctional communication during development of the early amphibian embryo

Cell-cell communication through gap junctions was examined in Xenopus laevis embryos between the 16-cell and early blastula stages using Lucifer Yellow, Fluorescein, lead EDTA and dicyanoargentate as probes of junctional permeability. Injections were made into cells whose position was identified with respect to the primary cleavage axis and the grey crescent. FITC dextrans revealed cytoplasmic bridges between the injected cell and its sister only. In the animal pole at the 16-cell stage at the future dorsal side of the embryo, Lucifer Yellow was frequently and extensively transferred between cells through gap junctions. At the future ventral side gap junctional transfer of Lucifer Yellow was significantly less frequent and less extensive. The asymmetry of transfer between future dorsal and ventral sides of the animal pole was more marked at the 32-cell stage. In the vegetal pole also at the 32-cell stage, a dorsoventral difference in junctional permeability to Lucifer Yellow was observed. At the 64-cell stage the transfer of Lucifer Yellow was relatively frequent between cells lying in the same radial segment in the animal pole; transfer into cells outside each segment was infrequent, except at the grey crescent. At the 128-cell stage, Lucifer transfer between future dorsal or future ventral cells in the equatorial region was infrequent. A high incidence of transfer was restored at the future dorsal side at the 256-cell stage. At the 32-cell stage, fluorescein was infrequently transferred between animal pole cells although lead EDTA moved from cell to cell with high, comparable frequency in future dorsal and ventral regions. Dicyanoargentate always transferred extensively, both at the 32- and 64-cell stages. Treatment of embryos with methylamine raised intracellular pH by 0.15 units, increased the electrical conductance of the gap junction and produced a 10-fold increase in the frequency of Lucifer Yellow transfer through gap junctions in future ventral regions of the animal pole at the 32-cell stage.     

Developmental time,cell lineage,and environment regulate the newly synthesized proteins in sea urchin embryos

Strongylocentrotus purpuratus embryos were fractionated into two cell populations of defined lineages at times corresponding to two critical developmental events: determination (16-cell stage) and early differentiation (mesenchyme blastula). The 16-cell stage blastomeres, labeled with [³⁵S]methionine, exhibited identical protein synthesis patterns by fluorography, and this pattern was not significantly altered by cell separation. In comparing the proteins of the mesenchyme blastula to the 16-cell stage, differences (increases and decreases) were seen by fluorography of newly synthesized proteins. The synthesis of 2.9% of the mesenchyme blastula proteins is specific to or enriched in primary mesenchyme cells and 8.2% is specific to or enriched in endoderm/ectoderm cells. Additionally, in contrast to the earlier stage, the pattern of protein synthesis in the mesenchyme blastula embryos is substantially altered by cell separation. The ability to alter protein synthesis in response to environmental factors may be a further demonstration of the differentiation of these cells.     

Elongated Microvilli on Vegetal Pole Cells in Sea Urchin Embryos

The ultrastructure of cells in the vegetal pole region of sea urchin embryos during early development to the mesenchyme blastula stage was examined by scanning electron microscopy. Vegetal pole cells in the ectoderm with longer microvilli than those of neighboring cells were first detectable at the early blastula stage just before hatching. These cells with elongated microvilli remained in the central region of the vegetal plate when most vegetal plate cells ingressed into the blastocoel to form primary mesenchyme. When first detectable in the sea urchin, Anthocidaris crassispina , four vegetal pole cells had elongated microvilli, but at the time of primary mesenchyme cell ingression, the number of cells with elongated microvilli had increased to eight, apparently by cell division. These vegetal pole cells were wedge-shaped with a broad surface adhering to the hyaline layer at the time of primary mesenchyme cell ingression. SEM observation of the outer surface of embryos showed that the microvilli extended into the hyaline layer. The reinforced attachment of vegetal pole cells to the hyaline layer through their elongated microvilli may explain why these cells could remain at the vegetal pole when the surrounding cells ingressed into the blastocoel as primary mesenchyme cells.     

Studies on the mechanism of blastula formation in starfish embryos denuded of fertilization membrane

A starfish egg, denuded of the fertilization membrane and placed on a glass surface, becomes a cell monolayer after several cleavages. This sheet of cells folds and forms a hollow sphere resembling a normal blastula at the 2(9)-2(10)-cell stage ('closing movement'). A marked morphological change was observed in each cell, preceding the closing movement. The surface of each blastomere differentiated into two parts: one was smooth, whereas the other was rough with microvilli. The smooth surface was more adhesive and flexible than the rough surface, suggesting that the closing movement may be driven by a local increase in cell adhesiveness.     

Ultrastructural Study of Changes in Cell Morphology and Extracellular Matrix in Prospective Endodermal Cells of Newt Embryos (Cynops pyrrhogaster) before and during Gastrulation

The cell morphology, cell-to-cell contact behavior and extracellular matrix (ECM) of inner cells (prospective endodermal cells) of newt ( Cynops pyrrhogaster ) embryos were examined from the morula to gastrula stage by light and electron microscopy. The inner cells showed increased cell-to-cell contact from the early blastula to early gastrula stage. The cells formed blebs (5–15 μm in diameter) during the blastula stage, and started to form filopodia and lamellipodia before gastrulation. Alcian blue and lanthanum nitrate treatment revealed ECM components on the cell surface in the early blastula stage and these components increased in amount from the late blastula to early gastrula stage. It is suggested that the increase in ECM components on the cell surface may have some relation with changes in cell-to-cell contact and formation of processes on the cell surface. Besides the cell surface ECM components, glycogen-like granules were observed in intercellular spaces. From the distribution of granules in gastrulae, it is suggested that these may be important in maintaining intercellular spaces for migration of invaginating cells.     

A scanning electron microscope study of early sea urchin reaggregation

Sea urchin embryos were observed with SEM during the first 2 h of reaggregation, following dissociation of the 16-cell stage. A dense meshwork, composed of elongated microvilli embedded in the hyaline layer, surrounds the egg during early development. The dissociation procedure strips off some of the meshwork layer leaving fewer and smaller microvilli on the cell surface. Shortly after reaggregation has begun, several types of cell extensions are formed, including filopodia, which anchor the cells to the substrate, and ruffles and pseudopods, which enable the cells to move. Possible factors involved in the behavior of dissociated cells are discussed with regard to (1) the source of additional membrane in the formation of new cell extensions; (2) the ability of the cells to move.     

Cytokeratin filament assembly in the preimplantation mouse embryo

The timing, spatial distribution and control of cytokeratin assembly during mouse early development has been studied using a monoclonal antibody, TROMA-1, which recognizes a 55,000 Mr trophectodermal cytokeratin (ENDO A). This protein was first detected in immunoblots at the 4-cell stage, and became more abundant at the 16-cell stage and later. Immunofluorescence analysis revealed assembled cytokeratin filaments in some 8-cell blastomeres, but not at earlier stages. At the 16-cell stage, filaments were found in both polarized (presumptive trophectoderm; TE) and apolar (presumptive inner cell mass; ICM) cells in similar proportions, although polarized cells possessed more filaments than apolar cells. By the late 32-cell, early blastocyst, stage, all polarized (TE) cells contained extensive filament networks whereas cells positioned inside the embryo tended to have lost their filaments. The presence of filaments in inside cells at the 16-cell stage and in ICM cells was confirmed by immunoelectron microscopy. Lineage tracing techniques demonstrated that those cells in the ICM of early blastocysts which did possess filaments were almost exclusively the progeny of polar 16-cell blastomeres, suggesting that these filaments were directly inherited from outside cells at the 16- to 32-cell transition. Inhibitor studies revealed that proximate protein synthesis but not mRNA synthesis is required for filament assembly at the 8-cell stage. These results demonstrate that there are quantitative rather than qualitative differences in the expression of cytokeratin filaments in the inner cell mass and trophectoderm cells of the mouse embryo.     

Change in the activity of Cl-,HCO3(-)-ATPase in microsome fraction during early development of the sea urchin, Hemicentrotus pulcherrimus

In sea urchin embryos, primary mesenchyme cells, descendants from micromeres produced at the 16-cell stage, form spicules or CaCO3 deposits in their skeletal vacuoles, at the post-gastrula stage. Micromeres isolated at the 16-cell stage also differentiate into spicule-forming cells during their culture at the same time schedule as in the embryos. The present study was planned to observe change in the activity of Cl-,HCO3(-)-ATPase, which was expected to contribute to the carbonate supply for CaCO3 deposition, during development. ATP-hydrolysis in the microsome fraction, obtained from embryos of the sea urchin, Hemicentrotus pulcherrimus, and from micromere-derived cells in culture was stimulated by Cl- and HCO3- in the presence of ouabain and EGTA. The ATP-hydrolysis was inhibited by ethacrynic acid, an inhibitor of Cl-,HCO3(-)-ATPase. The activity of Cl-,HCO3(-)-ATPase in embryos and in micromere-derived cells increased during development, keeping pace with the rate of calcium deposition in spicules. Formation of calcified spicules in the cultured micromere-derived cells was inhibited by ethacrynic acid. These results indicate that Cl-,HCO3(-)-ATPase plays an important role in the mechanism of CaCO3 deposition in the primary mesenchyme cells.     

The effects of phorbol ester on mouse blastomeres: a role for protein kinase C in compaction?

The effects of phorbol myristate acetate (PMA) and other activators of protein kinase C on the cytoskeletal organization of mouse oocytes and early embryos have been examined. The effects observed depended on the developmental stage on exposure to PMA. PMA had little effect on the cytoskeletal or microvillous organization of unfertilized oocytes. Interphase cells from embryos prior to compaction showed limited disruption and loss of microvilli when exposed to PMA and foci of polymerized actin remained visible in the cytocortex of embryos up to the early 8-cell stage. When compacted late 8-cell embryos were exposed to PMA, most microvilli were lost and little polymerized actin remained in the cytocortex. PMA also caused loss of microtubules from compact 8-cell embryos under some experimental conditions. Intercellular flattening was both prevented and reversed. The relevance of these observations to the rearrangement of cell-cell contacts and cytoskeletal organization seen during compaction at the 8-cell stage is discussed and a possible role for protein kinase C in the generation of cell polarity proposed.     

Changes in the synthesis and intracellular localization of nuclear proteins during embryogenesis in the sea urchin Strongylocentrotus purpuratus

A rapid, gentle technique is described for the isolation of nuclei from sea urchin embryos. Using this technique, we have analyzed the synthesis and accumulation of nonhistone nuclear proteins during sea urchin development by two-dimensional gel electrophoresis. Most nuclear proteins fall into one of three patterns of synthesis, which are distinguished by maximal rates of accumulation at early (prior to hatching blastula), middle (hatching blastula/gastrula), or late (prism/pluteus) stages of development. Over 60% of observed nuclear proteins undergo apparent qualitative changes in synthesis and accumulation between the 64-cell and pluteus stages. Most of these changes represent appearances of new proteins. A large number of qualitative changes occur very early in development; the period of greatest change is between the 64-cell and 200-cell stages. Over half of the proteins which first appear in the nucleus subsequent to the 64-cell stage are synthesized at stages prior to the time of their initial appearance in nuclei, but are excluded from nuclei for some time.     

Changes in Insulin-Binding Capacity of the Plasma Membrane Fraction during Culture in vitro of Cells Derived from Micromeres of 16-Cell-Stage Sea Urchin Embryos

In cultured cells derived from isolated micromeres of 16-cell stage sea urchin embryos, which undergo insulin-induced pseudopodial cable growth, specific and reversible insulin binding by a 52-kDa protein, probably an insulin receptor in the plasma membrane, is augmented during 5 h of culture without any change in the dissociation constant (Kuno et al : 1994). The increase in insulin-binding capacity in micromere-derived cells was only minimally blocked by actinomycin D and cycloheximide, which inhibited [U-³H]uridine incorporation into RNA and [³⁵S]methionine incorporation into protein, respectively. Insulin binding capacity was found in the plasma membrane fraction and the microsome fraction of isolated micromeres. The capacity in the plasma membrane fraction increased, accompanied by its decrease in the microsome fraction, during 5 h of culture of micromere-derived cells. The insulin receptor is probably accumulated in microsomes of presumptive micromeres prior to the 16-cell stage and transferred to the plasma membrane, resulting in an increase in the insulin binding capacity of micromere-derived cells during 5 h of culture.     

Unequal distribution of otx1 mRnas among cleavage stage blastomeres in the teleost,Leucopsarion petersii (shiro-uo)

The otx genes belong to the orthodenticle gene family and play important roles in anterior brain development in vertebrates. We isolated two cDNA sequences, one homologous to human and zebrafish otxl and another homologous to zebrafish otx3, from the teleost Leucopsarion petersii (shiro-uo), which belongs to the family of gobies in the Perciformes. During embryogenesis of shiro-uo, otx1 and otx3 were expressed in the fore- and mid-brain throughout development in a manner similar to that observed in other vertebrates so far studied. However, otx-1 mRNA was also present at earlier stages and we obtained unique results using in situ hybridization and RT-PCR analysis demonstrating that otx-1 signals showed a distinct increase in the upper blastomeres, but not in the lower blastomeres, at the 8-cell stage. These stronger signals were maintained in the animal pole blastomeres during the 16-cell to 64-cell stages, followed by a gradual decrease during blastula stages. Such unexpected unequal distribution of otx1 mRNA revealed that blastomeres at early cleavage stages already showed non-equivalence in the embryogenesis of shiro-uo.     

MOTILITY AND LOCOMOTION OF EMBRYONIC CELLS OF THE MEDAKA, ORYZIAS LATIPES, DURING EARLY DEVELOPMENT

The motility and locomotion of embryonic cells of the medaka, Oryzias latipes , were studied in situ with time-lapse cinematography.
In the early morula (128-cell stage), the surface of the blastomeres begins to undulate gently. By the early blastula stage, these undulations increase gradually in amplitude, and blebs appear. These blebs protrude and retract rapidly. In the mid-blastula stage they are found in most of the blastomeres. Some are found adhering to the surfaces of other cells. Blebs often expand into elongate lobopodia. Cell locomotion is first evident in the mid-blastula stage and continues throughout gastrulation and afterward. The cells move in the direction of the protrusion. In the late blastula a number of blastomeres locomote in random directions. In the thickening stage, when blastoderm epiboly begins, the cells with lamellipodia or elongate filopodia increase gradually in number, and in the early gastrula most cells change into this form. The motility, rate of movement, and mode of locomotion of embryonic cells during early development are described in detail.     

Cytocortical organization during natural and prolonged mitosis of mouse 8-cell blastomeres

Late 8-cell blastomeres were harvested within the first 45 min after entering mitosis. Some mitotic cells were analysed within the ensuing 2 h for the organization of their surface in relation to their progress through mitosis. Whereas in most late interphase cells microvilli were restricted to a discrete polar region, in mitotic cells at all stages from early metaphase to immediately postcytokinesis microvilli were found to be present over more of the cell surface. Other mitotic cells were placed in nocodazole to arrest them in M-phase for up to 10 h. They were found to show an even more extensive distribution of microvilli over the whole surface, the longer periods of incubation yielding more extended coverage such that many cells no longer appeared to have any residual surface polarity. Removal from nocodazole at all time points from 1 to 10 h resulted in most cells completing mitosis to yield pairs of cells which, in most cases, resembled pairs derived from nonarrested blastomeres and in which a defined polar area of microvilli was restored. However, the percentage of differentiative divisions decreased after 6 h arrest. If, instead of removing cells from nocodazole, they were placed in both nocodazole and cytochalasin D (CCD) for periods of up to 3 h, most microvilli retracted to reveal a tight polar zone of CCD-resistant microvilli. This result suggests that a heterogeneity of cytocortical organization may still exist within the arrested mitotic cell. We propose a model to explain the origin of this heterogeneity of organization and its relationship to the generation of cell diversity.     

Properties of polar and apolar cells from the 16-cell mouse morula

Summary The surface properties of newly formed, isolated 1/16 mouse blastomeres have been analyzed over the 10–12 h period prior to their division to 2/32 cells. Two populations of cells are formed at the 8- to 16-cell transition and their surface phenotypes vary with their relative position within the morula. Outer cells are polar, relatively non-adhesive and relatively large; inner cells are apolar, adhesive and smaller. The surface phenotypes of both inner and outer 1/16 cells are stable during culture for 11 h in isolation. However, the surface phenotypes can be induced to change by culture in combination with a second 1/16 cell, in a manner that is dependent upon the identity of the second cell. Two aggregated polar cells never flatten completely against each other, and both cells retain a clearly defined polar phenotype for 11–12 h. In aggregates of two apolar cells, cell outlines are lost as a result of intercellular flattening and microvilli are displaced away from areas of cell contact. However, if the two apolar cells are subsequently separated an even distribution of microvilli is restored. In most aggregates of an apolar and a polar cell, the polar cell envelops the apolar cell completely. These results are discussed in the context of the normal fate and potential of each cell type within the morula.     

Atypical protein kinase C controls sea urchin ciliogenesis

The atypical protein kinase C (aPKC) is part of the conserved aPKC/PAR6/PAR3 protein complex, which regulates many cell polarity events, including the formation of a primary cilium at the apical surface of epithelial cells. Cilia are highly organized, conserved, microtubule-based structures involved in motility, sensory processes, signaling, and cell polarity. We examined the distribution and function of aPKC in the sea urchin embryo, which forms a swimming blastula covered with motile cilia. We found that in the early embryo aPKC is uniformly cortical and becomes excluded from the vegetal pole during unequal cleavages at the 8- to 64-cell stages. During the blastula and gastrula stages the kinase localizes at the base of cilia, forming a ring at the transition zone between the basal body and the elongating axoneme. A dose-dependent and reversible inhibition of aPKC results in mislocalization of the kinase, defective ciliogenesis, and lack of swimming. Thus, as in the primary cilium of differentiated mammalian cells, aPKC controls the growth of motile cilia in invertebrate embryos. We suggest that aPKC might function to phosphorylate kinesin and so activate the transport of intraflagellar vesicles.     

Changes in the nature of the cell adhesions of the sea urchin embryo

Reaggregation of cells from 16-cell, 100-cell, 200-cell, hatched-blastula, and gastrula stage sea urchin embryos is essentially equivalent in the absence of experimental treatments. Gentle shearing of the forming aggregates revealed that the stability of the adhesions to shearing gradually increases as the embryos develop from the 100-cell to the hatched-blastula stage. During the same developmental period, the cell adhesions become progressively more sensitive to a mixed exoglycosidase, but their sensitivity to Pronase remains constant. Both changes we detected occur at the time other investigators have observed cell junctions appearing and cellular apposition increasing. All of these changes temporally correlate with the transition from loosely associated cleavage blastomeres into the organized epithelium of the hatched blastula.