Development of cytoskeletal connections between cells of preimplantation mouse embryos

Summary Observations by scanning electron microscopy of mouse cleaving embryos reveal the presence of long microvilli around cell contact regions that often bridge the gap between blastomeres. These microvilli correspond, in detergent-extracted morulae, to strings connecting the cortical cytoskeletons of adjoining cells. They appear about 4 h after compaction in synchronized cultures. Transmission electron microscopy, heavy meromyosin decoration and DNase I digestion show that cytoskeletal connections contain bundles of actin microfilaments. The establishment of cytoskeletal connections does not require immediate protein synthesis, as shown by incubation with cycloheximide. Diverse treatments that interfere with compaction were tested for the development of cytoskeletal connections: culture media with low Ca²⁺ and/or Mg²⁺, or EGTA, or -lactalbumin, do not prevent the establishment of connections, while colchicine delays their appearance and cytochalasin D suppresses it. The relation between cytoskeletal connections, compaction and blastulation is discussed.     

Cell subpopulations in the late morula and early blastocyst of the mouse

Late morulae and early blastocysts consist of two main cell subpopulations which occupy different positions within the embryos. The cells of the outer layer have a polar surface phenotype. The outward-facing surface of this cell type has a discrete dense pole of short microvilli, whilst the inward-facing surface has a relatively sparse distribution of longer, thick microvilli. The inner cells lack short, dense microvilli but exhibit thick microvilli of variable density. After short-term isolation in medium low in Ca²⁺, the individual polar and apolar cells remain distinguishable. The expanded blastocyst also has two major cell subpopulations, but within each of these, heterogeneity is observed. The mural trophectodermal cells have a larger, more regular outward-facing area of sparse, short microvilli than do polar trophectodermal cells. The ICM consists of some cells that show extensive blebbing in medium low in Ca²⁺ and others that do not.     

The polarized distribution of an apical cell surface glycoprotein is maintained by interactions with the cytoskeleton of Madin-Darby canine kidney cells

A monoclonal antibody made against a 135-kD glycoprotein (gp135) on the plasma membrane of Madin-Darby canine kidney (MDCK) cells was used to study the development and maintenance of epithelial cell surface polarity. Immunofluorescence microscopy and immunogold electron microscopy of confluent monolayers demonstrated that gp135 had a polarized cell surface distribution and was only localized on the apical surface. The role of membrane contacts in establishing gp135 polarity was determined by plating cells in low Ca++-medium to prevent the formation of intercellular junctions. Quantitative immunogold electron microscopy demonstrated that gp135 had a polarized distribution on cells lacking membrane contacts and was observed on the apical surface at a density 24 times that of the basal membrane contacting the substratum. The possibility that gp135 was associated with components of the apical cytoskeleton was investigated using cytoskeleton-disrupting drugs. Incubation in cytochalasin D produced a clustering of both actin and gp135, and double-label fluorescence microscopy demonstrated that these proteins were colocalized. Experiments using nocodazole had no effect, suggesting that gp135 could be interacting with actin microfilaments, but not microtubules. Treatment with Triton X-100 extracted approximately 50% of the gp135 and immunofluorescence microscopy indicated that the gp135 which remained associated with the detergent-insoluble cytoskeleton had a distribution identical to that of control cells. Experiments demonstrating that gp23, a nonpolarized glycoprotein, was preferentially extracted from the apical membrane suggested that the improperly sorted apical gp23 did not interact with the cytoskeleton. These results provided evidence that the polarized cell surface distribution of gp135 was maintained through its interaction with actin in the apical cytoskeleton.     

Cytoskeletal control of the apical surface transformation of rat uterine epithelium

Summary— During early pregnancy, in the lead up to blastocyst implantation, the apical cell surface of luminal epithelial cells of the rat uterus undergo a dramatic shape transformation. This study aims to investigate the role of the cytoskeleton in this apical transformation by considering the effects of the drugs cytochalasin D and colchicine on the uterine luminal cell surface. The results are determined using transmission and scanning electron microscopy. In vivo exposure to cytochalasin D during oestrus, as well as on day 1 of pregnancy, did not affect the long, regular surface microvilli. This drug, however, did disrupt the terminal web within the apical cytoplasm of these cells. Disruption of microfilament (MF) polymerization by cytochalasin D on day 4 of pregnancy induced a cell surface transformation, resulting in the appearance of numerous irregular projections normally present during blastocyst implantation on day 6 of pregnancy. Colchicine did not alter the uterine microvilli of oestrus or day 1 pregnant tissue. Unlike the effect of cytochalasin D, colchicine-induced microtubule (MT) disruption on day 4 of pregnancy did not increase irregular projections and hence this treatment did not result in the cell surface appearance associated with blastocyst implantation. These results indicate that the disruption of MF, rather than MT, contributes to the transformation of the uterine luminal cell surface during the lead up to blastocyst attachment.     

Phosphorylation of ezrin on threonine T567 plays a crucial role during compaction in the mouse early embryo

The preimplantation development of the mouse embryo leads to the divergence of the first two cell lineages, the inner cell mass and the trophectoderm. The formation of a microvillus pole during compaction at the eight-cell stage and its asymmetric inheritance during mitosis are key events in the emergence of these two cell populations. Ezrin, a member of the ERM protein family, seems to be involved in the formation and stabilization of this apical microvillus pole. To further characterize its function in early development, we mutated the key residue T567, which was reported to be essential for regulation of ezrin function through phosphorylation. Here, we show that expression of ezrin mutants in which the COOH-terminal threonine T567 was replaced by an aspartate (to mimic a phosphorylated residue; T567D) or by an alanine (to avoid phosphorylation; T567A) interferes with E-cadherin function and disrupts the first morphogenetic events of development: compaction and cavitation. The active mutant ezrin-T567D induces the formation of numerous and abnormally long microvilli at the surface of blastomeres. Moreover, it localizes all around the cell cortex and inhibits cell-cell adhesion and cell polarization at the eight-cell stage. During the following stages, only half of the embryos are able to compact and finally to cavitate. In those embryos, the amount of ezrin-T567D decreases in the basolateral areas, while the proportion of adherens junctions increases. The reverse inactive mutant ezrin-T567A is mainly cytoplasmic and does not perturb compaction at the eight-cell stage. However, at the 16-cell stage, it relocalizes at the basolateral cortex, leading to a strong decrease in the surface of adherens junctions, and finally, embryos abort development. Our results show that ezrin is directly involved in the formation of microvilli in the early mouse embryo. Moreover, they indicate that maintenance of ezrin in basolateral areas prevents microvilli breakdown and inhibits the formation of normal cell-cell contacts mediated by E-cadherin, thereby impairing blastomeres polarization and morphogenesis of the blastocyst.     

Changes in cell surface and cortical cytoplasmic organization during early embryogenesis in the preimplantation mouse embryo

Membrane topography and organization of cortical cytoskeletal elements and organelles during early embryogenesis of the mouse have been studied by transmission and scanning electron microscopy with improved cellular preservation. At the four- and early eight-cell stages, blastomeres are round, and scanning electron microscopy shows a uniform distribution of microvilli over the cell surface. At the onset of morphogenesis, a reorganization of the blastomere surface is observed in which microvilli becomes restricted to an apical region and the basal zone of intercellular contact. As the blastomeres spread on each other during compaction, many microvilli remain in the basal region of imminent cell-cell contacts, but few are present where the cells have completed spreading on each other. Microvilli on the surface of these embryos contain linear arrays of microfilaments with lateral cross bridges. Microtubules and mitochondria become localized beneath the apposed cell membranes during compaction. Arrays of cortical microtubules are aligned parallel to regions of apposed membranes. During cytokinesis, microtubules become redistributed in the region of the mitotic spindle, and fewer microvilli are present on most of the cell surface. The cell surface and cortical changes initiated during compaction are the first manifestations of cell polarity in embryogenesis. These and previous findings are interpreted as evidence that cell surface changes associated with trophoblast development appear as early as the eight-cell stage. Our observations suggest that morphogenesis involves the activation of a developmental program which coordinately controls cortical cytoplasmic and cell surface organization.     

Development of cellular polarity of hamster embryos during compaction.

Development of cellular polarity is an important event during early mammalian embryo development and differentiation. Blastomeres of hamster embryos at various stages were examined by scanning electron microscopy (SEM) and immunocytochemical staining. SEM observations revealed that 1- to 7-cell-stage embryos showed a uniform distribution of microvilli throughout the cell surface. Microvillous polarization was initially noted in the blastomeres (10-35%) of 8-cell-stage embryos. The polarized microvilli were observed mostly in the basal region of cell-cell contact and occasionally at the apical, outward-facing surface of the blastomere. Fluorescein-isothiocyanate-conjugated concanavalin A failed to reveal any polarity in the blastomeres regardless of the stages of the embryos. Actin staining showed that microfilaments were present beneath the cell surface, and in addition, areas of cell contact were more heavily stained, indicating a thick microfilament domain. Microtubules were located throughout the cytoplasm and were heavily concentrated near the nucleus during interphase, although they became redistributed in the region of the mitotic spindle during karyokinesis. The position of nucleus changed from the cell center to the apical, outward-facing surface of the cell, and it distanced itself from the basal microvillous pole. It is suggested that the changes in the cell surface and nuclear position are the first manifestations of cell polarity in peri-compacted hamster embryos, which appear as early as the 8-cell stage; furthermore, the outward migration of the nuclei may parallel the redistribution of microtubules in the cytoplasm.     

A scanning electron microscope study of the extraembryonic endoderm of the 8th-day mouse embryo

Abstract. Late primitive streak embryos were dissected to reveal the junction between the visceral (VE) and parietal (PE) extraembryonic endoderm. Scanning electron microscopy showed that the two cell types differ markedly in their surface morphology and intercellular organization: the VE cells have numerous apical microvilli and form part of a continuous epithelial layer, while the smoother PE cells are scattered individually over the surface of Reichert's membrane. One interpretation of the morphology of the junction between the two tissues is that visceral endoderm cells in this region are detaching from the epithelial layer, migrating on to Reichert's membrane and differentiating into parietal endoderm. Preparatory to this, the visceral endoderm cells in the junctional zone may undergo extensive reorganization of their surface membranes.     

Actin microfilaments play a critical role in endocytosis at the apical but not the basolateral surface of polarized epithelial cells

Treatment with cytochalasin D, a drug that acts by inducing the depolymerization of the actin cytoskeleton, selectively blocked endocytosis of membrane bound and fluid phase markers from the apical surface of polarized MDCK cells without affecting the uptake from the basolateral surface. Thus, in MDCK cell transformants that express the VSV G protein, cytochalasin blocked the internalization of an anti-G mAb bound to apical G molecules, but did not reduce the uptake of antibody bound to the basolateral surface. The selective effect of cytochalasin D on apical endocytosis was also demonstrated by the failure of the drug to reduce the uptake of 125I-labeled transferrin, which occurs by receptor-mediated endocytosis, via clathrin-coated pits, almost exclusively from the basolateral surface. The actin cytoskeleton appears to play a critical role in adsorptive as well as fluid phase apical endocytic events, since treatment with cytochalasin D prevented the apical uptake of cationized ferritin, that occurs after the marker binds to the cell surface, as well as uptake of Lucifer yellow, a fluorescent soluble dye. Moreover, the drug efficiently blocked infection of the cells with influenza virus, when the viral inoculum was applied to the apical surface. On the other hand, it did not inhibit the basolateral uptake of Lucifer yellow, nor did it prevent infection with VSV from the basolateral surface, or with influenza when this virus was applied to monolayers in which the formation of tight junctions had been prevented by depletion of calcium ions. EM demonstrated that cytochalasin D leads to an increase in the number of coated pits in the apical surface where it suppresses the pinching off of coated vesicles. In addition, in drug-treated cells cationized ferritin molecules that were bound to microvilli were not cleared from the microvillar surface, as is observed in untreated cells. These findings indicate that there is a fundamental difference in the process by which endocytic vesicles are formed at the two surfaces of polarized epithelial cells and that the integrity and/or the polymerization of actin filaments are required at the apical surface. Actin filaments in microvilli may be part of a mechanochemical motor that moves membrane components along the microvillar surface towards intermicrovillar spaces, or provides the force required for converting a membrane invagination or pit into an endocytic vesicle within the cytoplasm.     

Surface defects in ventricular cells of brains of mouse embryos homozygous for the Loop-tail gene: scanning electron microscopic study.

Luminal surfaces in the mesencephalon and rhombencephalon in normal mouse embryos and those homozygous for Lopp-tail were studied by means of scanning electron microscopy. Ventricular cells in the ventrolateral regions of normal day-10 and -11 brains showed single apical cilia and microvilli, whereas those in ventromedial regions showed a dense network of microvilli and bulbous projections which tended to obscure the apical cilia and cellular outlines. Similar regional differences occurred in the Loop-tail brains, although there was a marked decrease in the number and density of microvilli and bulbous projections. At days 12-14 of gestation the latter brains also showed a flattening of cell surfaces, shallow depressions, and craterlike ruptures in the plasma membranes.     

Ultrastructural characteristics of fresh and frozen-thawed ovine embryos using two cryoprotectants

Cryopreservation of sheep embryos with ethylene glycol as a protectant appears to be more effective than glycerol, particularly at the morula stage, as has been demonstrated on the basis of in vitro and in vivo development rates after thawing. In this study we compare the ultrastructure of fresh morulae, thawed morulae, and blastocysts cryopreserved with either ethylene glycol or glycerol at the electron microscopic level, to look for cellular damage that could be responsible for proven differences in embryo survival after transfer. Embryos cryopreserved with glycerol showed unequal degrees of conservation even among blastomeres within a single embryo. In morulae, inner blastomeres were completely damaged, whereas external ones appeared to be intact. Both morulae and blastocysts cryopreserved with ethylene glycol showed a higher uniformity in blastomere conservation than embryos with glycerol. The most remarkable features in this experimental group were the presence of desmosomes following tight junctions between blastomeres and the presence of many microvilli on the outer surface of external blastomeres. These characteristics are similar in fresh embryos of the control group. Our results show that ethylene glycol protects membrane and cytoplasmic structures of embryonic cells from cryoinjury much better than glycerol. In vivo survival of embryos confirmed the ultrastructural observations. A limited permeability of glycerol would explain the observed ultrastructural differences in blastomere integrity, which depends on blastomere location and the differences between morulae and blastocysts. We conclude that the low reproductive yield after cryopreservation using glycerol can be attributed to the lack of protection of inner cells.     

Effect of cytochalasins on the surface topography of neoplastic cells in suspension

The effect of cytochalasins B or D on the surface topography of mouse neoplastic fibroblasts of L line (detached from glass by trypsin-EDTA solution) or of its LS subline (adapted to the growth in suspension in vitro), as well as on that of Ehrlich's ascites tumor cells was investigated by screening electron microscopy. Incubation of suspended cells with cytochalasin B (2 micrograms/ml) or cytochalasin D (0.2 microgram/ml) for 30-180 min led to the following changes: (I) progressive decrease of the proportion of the cells with a microvillous surface relief and simultaneous increase in the percentage of the cells with a blebbed microrelief; (2) shortening of the microvilli and decrease of their density on the cell surface; (3) appearance of surface areas with a rough folded relief; (4) formation of very large blebs on the LS or L cell surfaces; (5) unusual "polar" distribution of blebs on Ehrlich's tumor and L cells: the blebs were concentrated in one locus on the cell surface. The data show that normal organization of the actin microfilament system in the cell cortex is necessary for formation of the microvilli but not for the blebs.     

EphA4 activity causes cell shape change and a loss of cell polarity in Xenopus laevis embryos.

The Eph family of receptor tyrosine kinases and their ephrin ligands are believed to limit cell-cell interactions during embryonic development via a repulsive mechanism. Little is known, however, about the intracellular effects of Eph signaling that lead to cellular repulsion. We have used scanning and transmission electron microscopy to examine the effects of EphA4 catalytic activity on cells in early embryos of Xenopus laevis. We show that ectopic EphA4 catalytic activity in superficial blastula cells leads to a more rounded cellular morphology, a loss of apical microvilli, and a loss of the apical/basolateral boundary, in addition to the previously reported loss of cell adhesion. These effects indicate that these epithelial cells have lost their apical/basolateral polarity. We also show that EphA4 catalytic activity causes a preferential loss of adherens junctions, compared to tight junctions. Furthermore, EphA4 catalytic activity was found to result in a change in filamentous actin levels in blastomeres. These results taken together suggest that the actin cytoskeleton might be a target of EphA4 signaling.     

Cell junctions in early embryos of squid (Loligo pealei)

Summary Squid embryos examined by freeze-fracture and thin-section electron microscopy exhibit identifiable gap junctions during mid-cleavage stages (stages 7–8), and junctional complexes composed of adherent appositions, elaborate septate junctions and gap junctions at slightly later stages (stages 12–13). During germinal layer establishment (stages 12–13) cytoplasmic bridges frequently link the embryonic cells. The presence of gap junctions in cleavagestage embryos provides the morphological substrate for a demonstrated pathway of direct cell-cell communication that is modifiable by experimental treatments and may be physiologically regulatable. The existence of septate junctions and adherent contacts at later stages suggests that some functional specialization, perhaps the establishment of a strongly joined framework of cells at the surface of the embryo, accompanies the formation of germinal layers.     

Establishment and maintenance of a regionalized glycoprotein distribution during early mouse development

The regionalization of the cell membranes of the mouse embryo into apical and basolateral zones has been studied using antibodies to a pair of glycoproteins expressed during the two-cell to early blastocyst stage. These antigens are found on the outer, free surface and in the underlying cortical cytoplasm, but are not detectable at areas of cell contact. In the early blastocyst stage, antigen also appears at the free surfaces of cells bordering the blastocoel. Antigen regionalization is also reestablished after experimental manipulation and appears to be a direct consequence of cell contact. Thus, blastomeres examined 4 hr after dissociation from four- and eight-cell stage embryos express antigen in cortical areas underlying newly exposed surfaces and new sites of contact between embryos in multiple-embryo aggregates lose detectable antigen within 2 to 4 hr of the formation of the contacts. Microfilaments are involved in controlling the regional expression of these glycoproteins. Incubation of embryos from the two-cell stage in medium containing cytochalasin B interferes with antigen targeting, resulting in abnormal expression of the antigens both on the surface and in the cytoplasm of the embryos. Cytochalasin B treatment of later stage embryos results in an uneven distribution of the antigen in cortical cytoplasm and prevents the complete removal of antigen from new sites of cell contact in multiple-embryo aggregates. The presence of nocodozole, which inhibits the polymerization of microtubules, had no detectable effect on the expression of the antigens. Interference with the glycosylation of these proteins, by incubation of embryos in the presence of tunicamycin, did not alter the regionalized pattern of expression.     

Apically administered cytochalasin B and D decreases sensitivity of electroreceptor organs in the North-American catfish,Ictalurus nebulosus

The receptor cells of the ampullary electroreceptor organs of Ictalurus nebulosus bear microvilli on the apical membrane. Whereas microvilli in mechanoreceptive hair cells and in chemoreceptor cells have a transduction function, the function of these membrane specializations in electroreceptor cells is not fully understood. To study the role of the microvilli of the electroreceptor cells, the ampullary electroreceptor organs were apically exposed to the microfilament-disrupting agents cytochalasin B and D. Electrophysiological measurements showed that cytochalasin caused a high decrease in sensitivity and a slight decrease in spontaneous activity. Exposure to cytochalasin B resulted in a striking disorganization of the microvilli on the apical membrane of the electroreceptor cells. The most plausible explanation for the results is that treatment with cytochalasin mainly affects the actin filaments of the microvilli causing an increase of the resistance of the apical membrane. A high apical resistance results in a decrease of the voltage over the basal membrane, which in turn reduces the sensitivity. The conclusion is that intact apical microvilli are necessary for proper functioning of ampullary electroreceptor organs. Alterations in microvillar properties, like surface area and ion channel conductancy might play a considerable role in the regulation of the sensitivity.     

Intercellular connectivity in the eight-cell Xenopus embryomcorrelation of electrical and morphological investigations.

The distribution of individual intercellular electrical junctions has been examined in eight-cell Xenopus embryos using linear systems analysis. Morphological evidence for corresponding intercellular contacts has been sought by light microscopy and scanning electron microscopy. The electrical investigation indicated that each cell is directly coupled to each of the other seven cells by identical resistive junctions. Scanning electron microscopy of the cell surfaces of cleaved embryos revealed protrusions from the surfaces of the cells which could mediate such intercellular connections. Light microscopy of serial sections through the embryos also showed fine processes of the cell surfaces which come into contact with several other cells. The complete intercellular connectivity suggested by these results appears to be an extension of similarly close connectivity in the two- and four-cell embryos. The possible significance of this high connectivity to morphogenesis is discussed.     

Effects of cytochalasin B on the fine structure of organized endodermal cells of the early chick embryo

Fresh pullet eggs (White Leghorn) were incubated for 36 to 48 hours. The blastoderms were exposed to cytochalasin B (CB), 10 or 40 microgram/ml, for 2, 5, and 15 minutes prior to fixation by immersion in buffered chick Ringers solution containing CB, previously dissolved in dimethysulfoxide (DMSO), or by sub-blastodermic injection. Controls fixed in ovo possess relatively flat surfaces with bulges due to uptake of yolk. Numerous microappendages (blebs, microvilli and ruffles) are present, especially at cell margins. DMSO-controls present a similar cell surface except that small blebs are more prominent. The plasmalemmas of CB-treated endodermal cells possess numerous large blebs (2-10 micron in diameter), smaller blebs (0.2 micron) and microvilli. Cell dissociation occurs in selected areas resulting in rounded cells, devoid of microappendages, with peripheral processes. Transmission electron microscopic preparations of tissues similar to those used for scanning electron microscopy reveal that large blebs are filled with membranous material. Microfilaments are present but lack their normal subplasmalemmal arrangement. Microtubules and other cell organelles are apparently unaffected by CB. Evidence in this study supports the concept that cytochalasin B exerts its influence through alteration of the plasmalemma.     

Expression and distribution of cell adhesion molecule uvomorulin in mouse preimplantation embryos

We have examined the synthesis and distribution of the cell adhesion molecule uvomorulin in mouse preimplantation embryos. Uvomorulin can already be detected on the cell surface of unfertilized and fertilized eggs but is not synthesized in these cells. Uvomorulin synthesis starts in late two-cell embryos and seems not to be correlated with the onset of compaction. The first signs of compaction are accompanied by a redistribution of uvomorulin on the surface of blastomeres. During compaction uvomorulin is progressively removed from the apical membrane domains of peripheral blastomeres. In compact morulae uvomorulin is no longer present on the outer surface of the embryo but is localized predominantly in membrane domains involved in cell-cell contacts of adjacent outer blastomeres. On inner blastomeres of compact morulae uvomorulin remains evenly distributed. This uvomorulin distribution once established during compaction is maintained and also found in the blastocyst: on trophectodermal cells uvomorulin localization is very similar to that in adult intestinal epithelial cells while uvomorulin remains evenly distributed on the surface of inner cell mass cells. The possible role of the redistribution of uvomorulin for the generation of trophectoderm and inner cell mass in early mouse embryos is discussed.