Cell specific loss of polarity-inducing ability by later stage mouse preimplantation embryos

The individual blastomeres of the preimplantation mouse embryo become polarized during the 8-cell stage. Microvilli become restricted to the free surface of the embryo and this region of the membrane shows increased labeling with FITC-Con A and trinitrobenzenesulfonate (TNBS). Previous studies have shown that this polarity develops in response to asymmetric cell-cell contact with stage specific induction competent blastomeres. In the present study, the ability of later stage embryos to induce 8-cell polarization has been investigated. Newly-formed, nonpolar 8-cell stage blastomeres (1/8 cells) were isolated, then aggregated with morulae, inner cell clusters (from morulae), blastocysts, or inner cell masses (ICM) and cultured for 8 hr. Aggregates were then assayed for polarity. The results show a hierarchy of inducing ability, with the ICM and IC cluster possessing greater activity than the morula and polar trophectoderm of the early blastocyst, while the mural trophectoderm shows very little inducing activity. Furthermore, the inducing ability of the polar trophectoderm decreases with complete expansion and hatching of the blastocyst. These results indicate that the ability to induce 8-cell blastomere polarization is retained by the embryo beyond the 8-cell stage and that this ability is lost with further differentiation.     

Inner cell allocation in the mouse morula: the role of oriented division during fourth cleavage

Two populations of blastomeres become positionally distinct during fourth cleavage in the mouse embryo; the inner cells become enclosed within the embryo and the outer cells form the enclosing layer. The segregation of these two cell populations is important for later development, because it represents the initial step in the divergence of placental and fetal lineages. The mechanism by which the inner cells become allocated has been thought to involve the oriented division of polarized 8-cell blastomeres, but this has never been examined in the intact embryo. By using the technique of time-lapse cinemicrography, we have been able for the first time to directly examine the division planes of 8-cell blastomeres during fourth cleavage, and find that there are three, rather than two, major division plane orientations; anticlinal (perpendicular to the outer surface of the blastomere), periclinal (parallel to the outer surface of the blastomere), and oblique (at an angle between the other two). The observed frequencies of each type of division plane orientation provide evidence that the inner cells of the morula must derive from oriented division of 8-cell blastomeres, in accordance with the polarization hypothesis. Analysis of fourth cleavage division plane orientation with respect to either lineage or division order reveals that it is not associated with lineage from either the 2- or the 4-cell stage, but has a slight statistical association with fourth cleavage division order. The lack of association between division plane orientation and lineage supports the prediction that packing patterns and intercellular interactions within the 8-cell embryo during compaction play a role in determining fourth cleavage division plane orientation and thus, the positional fate of the daughter 16-cell blastomeres.     

Polarization of blastomeres in the cleaving rabbit embryo

Cellular polarization is believed to be a crucial event in the differentiative divergence of the two cell lineages leading to the blastocyst in rodent embryos. This study was undertaken to determine if rabbit embryos exhibited cellular polarization prior to blastocyst formation and to define the embryonic stage at which polarization was first apparent. Polarity was assayed by observation of the pattern of binding of FITC-Con A to dissociated blastomeres from three stages of rabbit embryos. Scanning electron microscopy on the dissociated cells confirmed the fluorescence results. Fifty-one percent of blastomeres in 38- to 66-cell rabbit embryos exhibited an intense pole of FITC-Con A binding and a single pole of microvilli. Only 2% of blastomeres at the 17- to 34-cell stage were similarly polarized and none were polarized at the 8- to 16-cell stage. In addition, during attempts to remove the mucin coat and zona pellucida from the rabbit embryos prior to their dissociation, it was found that the protease sensitivity of these coats also changed at the 38- to 66-cell stage. Prior to this time, although the mucin coat disappeared after 30 min in 0.5% pronase, the zona required approximately 1.5-2.5 hr in pronase for even partial removal. At the 38- to 66-cell stage, pronase dissolved the mucin coat within 10 min and the zona pellucida within 20 min. The zona was resistant to 0.1% proteinase K at all stages examined.     

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.     

Archenteron-Forming Capacity in Blastomeres Isolated from Eight-Cell Stage Embryos of the Starfish, Asterina pectinifera

Starfish blastomeres are reported to be totipotent up to the 8-cell stage. We reinvestigated the development of blastomeres of 8-cell stage embryos with a regular cubic shape consisting of two tiers of 4 blastomeres. On dissociation of the embryo by disrupting the fertilization membrane at the 8-cell stage, each of the 4 blastomeres of the vegetal hemisphere gave rise to an embryo that gastrulated, whereas blastomeres from the animal hemisphere did not. By injection of a cell lineage tracer into blastomeres of 8-cell stage embryos, we found that only those of the vegetal hemisphere formed cells constituting the archenteron. Next, we compressed 4-cell stage embryos along the animal-vegetal axis so that all the blastomeres in the 8-cell stage were in a single layer. When these 8 blastomeres were then dissociated, an average of 7 of them developed into gastrulae. By cell lineage analysis, all the blastomeres in single-layered embryos at the 8-cell stage were shown to have the capacity to form cells constituting an archenteron. Taken together, these findings indicate that the fate to form the archenteron is specified by a cytoplasmic factor(s) localized at the vegetal hemisphere, and that isolated blastomeres that have inherited this factor develop into gastrulae.     

Reproductive cell specification during Volvox obversus development

Asexual spheroids of the genus Volvox contain only two cell types: flagellated somatic cells and immotile asexual reproductive cells known as gonidia. During each round of embryogenesis in Volvox obversus, eight large gonidial precursors are produced at the anterior extremity of the embryo. These cells arise as a consequence of polarized, asymmetric divisions of the anteriormost blastomeres at the fourth through nine cleavage cycles, while all other blastomeres cleave symmetrically to yield somatic cell precursors. Blastomeres isolated from embryos at any point between the 2-cell and the 32-cell stage cleaved in the normal pattern and produced the same complement and spatial distribution of cell types as they would have in an intact embryo. This result indicates that intrinsic features control the cleavage patterns and developmental potentials of blastomeres, and rules out any significant role for cell-cell interactions in gonidial specification. When substantial quantities of anterolateral cytoplasm were deleted from uncleaved gonidia or 4-cell stage blastomeres, the cell fragments frequently regulated and embryos were produced with the expected number of asymmetrically cleaving cells and gonidial precursors at their anterior ends. However, when anterior cytoplasm was deleted from 8-cell stage blastomeres, the depleted cells frequently failed to cleave asymmetrically and produced no gonidial precursors. Furthermore, when compression was used to reorient cleavage planes at the fourth division cycle, so that anterior cytoplasm was transmitted to more than the normal number of cells, those cells receiving a significant amount of such cytoplasm cleaved asymmetrically to produce supernumerary gonidial precursors. Together, these last two experiments indicate that blastomeres in the V. obversus embryo acquire (at least by the end of the third cleavage cycle) a polarized organization in which anterior cytoplasm plays a causal role in the process of reproductive-cell specification.     

Scanning microscopy of disaggregated and aggregated preimplantation mouse embryos

Summary Blastomeres isolated from 8-and 16-cell embryos (that is 1/8 and 1/16) show a smooth surface at their point of contact with other blastomeres and a microvillous free surface. Microvilli reappear completely on the smooth surface of 52% of 1/8 embryos and partially on 88% of 1/16 embryos if cultured in vitro for 6 h. When 2-to 8-cell embryos are aggregated to 8-cell embryos and forced apart after 1–3 h, the contact surface of the 8-cell embryos has become smooth. Fixed 8-cell embryos are also able to induce complete disappearance of microvilli on the contact surface of a living 8-cell embryo. Embryos having more than 8 cells do not induce complete disappearance of microvilli on the contact surface of 8-cell embryos. Aggregates of late morulae do not show complete disappearance of microvilli at their contact surfaces but rather a loosening of their peripheral blastomeres.Our results show that isolated 1/8 and 1/16 embryos tend to recover from regionalization, that the process of aggregation of embryos having 8 cells or less is similar to compaction and that embryos having more than 8 cells seem to aggregate by cell sorting. The processes of compaction, adhesion and reassortment are briefly discussed. We submit that blastomere regionalization, which depends on cell to cell contact, may be the spatial basis of embryonic regulation and of the inside-outside normal differentiation of early mouse embryos.     

Induction of murine 8-cell blastomere polarity by F9 embryonal carcinoma cells

The individual blastomeres of the preimplantation mouse embryo become polarized during the 8-cell stage of development. This polarity forms as a result of a specific cell-cell interaction that has been termed induction. The ability of embryonal carcinoma (EC) cells to induce 8-cell blastomere polarization has been investigated by aggregating nonpolar 8-cell blastomeres with various types of EC cells. F9, a nullipotent stem cell, induced polarization of a nonpolar 8-cell companion in 80% of the aggregates. Stimulation of differentiation of F9 cells with retinoic acid (RA), with or without dibutyryl cAMP, caused a reduction in the polarity-inducing ability of these cells. Other EC cells, PSA-1, NULLI-SCC1, 3TDM, C3HNE, and P10, all displayed less polarity-inducing activity than F9. In addition, it was observed that when any of these cell types assumed a more differentiated phenotype, either spontaneously or in response to specific stimuli, they displayed a decrease in their ability to induce 8-cell polarization. As a control, the inducing ability of cells from normal mouse tissues was examined. It was found that neither STO mouse fibroblasts nor primary cultures of mouse lymphocytes were able to induce significant polarization of 8-cell stage blastomeres. These data support the hypothesis that while undifferentiated stem cell populations retain the ability to induce 8-cell blastomere polarization, it is apparently lost upon cellular differentiation.     

The cytoskeleton, endocytosis and cell polarity in the mouse preimplantation embryo

The process of cell polarization in mouse 8-cell embryos includes the formation of a polar cluster of cytoplasmic endocytotic organelles (endosomes) subjacent to an apical surface pole of microvilli. A similar polar morphology, supplemented by basally localized secondary lysosomes, is evident following division to the 16-cell stage in outside blastomeres, precursors of the trophectodermal lineage. The roles of microfilaments and microtubules in generating and stabilizing endocytotic and surface features of polarity (visualized by horseradish peroxidase incubation and indirect immunofluorescence labeling, respectively) have been evaluated by exposure of 8- and 16-cell embryos and 8-cell couplets to drugs (cytochalasin D, colcemid, nocodazole) that disrupt the cytoskeleton. The generation of endocytotic polarity is dependent upon intact microtubules and microfilaments, but the newly established endocytotic pole in blastomeres from compacted 8-cell embryos appears to be stabilized exclusively by microtubules. Polarized endocytotic organelles at the 16-cell stage are more resistant to drug treatment than at the 8-cell stage (probably due to microfilament interactions) indicating a maturation phase in the polar cell lineage. Microtubules are also responsible for the orientation of endocytotic clusters along the cell's axis of polarity. In contrast, the generation and stability of polarity at the cell surface appears relatively independent of cytoskeletal integrity. The results are discussed in relation to the mechanisms that may control the development and stabilization of polarization during cleavage.     

Cell interactions influence the fate of mouse blastomeres undergoing the transition from the 16- to the 32-cell stage

Newly formed polar and apolar 1/16 blastomeres were isolated and cultured singly, or in various combinations, through division to form 32-cell blastomeres. The morphology of the resulting cell cluster appeared to depend upon the nature and composition of the cell combination used. In most polar + apolar couplets, the polar cell enveloped the apolar cell, and following division, a 4/32 cluster was thereby generated containing two trophectoderm-like external cells derived from the polar cell and two ICM-like internal cells derived from the apolar cells. A polar cell cultured in isolation divided to give either two trophectoderm-like external cells or a trophectoderm-like cell and an ICM-like cell. Two polar cells cultured together generated clusters in which the ratio of trophectoderm-like:ICM-like cells was 4:0 or 3:1. Most apolar cells cultured together in couplets polarized, and generated 4/32 clusters containing either purely trophectoderm-like or a mixture of trophectoderm- and ICM-like cells. The results are consistent with the notion that continuing interactions between polar and apolar cells are necessary to maintain their respective fates as trophectoderm and ICM, and that in the absence of these interactions polar cells can generate ICM cells by a differentiative division and apolar cells can generate trophectoderm cells by polarizing in response to asymmetric cell contacts.     

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.     

When and how does cell division order influence cell allocation to the inner cell mass of the mouse blastocyst?

Aggregate 8-cell embryos were constructed from four 2/8 pairs of blastomeres, one of which was marked with a short-term cell lineage marker and was also either 4 h older (derived from an early-dividing 4-cell) or 4 h younger (derived from a late-dividing 4-cell) than the other three pairs. The aggregate embryos were cultured to the 16-cell stage, at which time a second marker was used to label the outside cell population. The embryos were then disaggregated and each cell was examined to determine its labelling pattern. From this analysis, we calculated the relative contributions to the inside cell population of the 16-cell embryo of older and younger cells. Older cells were found to contribute preferentially. However, if the construction of the aggregate 8-cell embryo was delayed until each of the contributing 2/8 cell pairs had undergone intercellular flattening and then had been exposed to medium low in calcium to reverse this flattening immediately prior to aggregation, the advantage possessed by the older cells was lost. These results support the suggestion that older cells derived from early-dividing 4-cell blastomeres contribute preferentially to the inner cell mass as a result of being early-flattening cells.     

Change in the adhesive properties of blastomeres during early cleavage stages in sea urchin embryo

Blastomeres of sea urchin embryo change their shape from spherical to columnar during the early cleavage stage. It is suspected that this cell shape change might be caused by the increase in the adhesiveness between blastomeres. By cell electrophoresis, it was found that the amount of negative cell surface charges decreased during the early cleavage stages, especially from the 32-cell stage. It was also found that blastomeres formed lobopodium-like protrusions if the embryos were dissociated in the presence of Ca2+. Interestingly, a decrease in negative cell surface charges and pseudopodia formation first occurred in the descendants of micromeres and then in mesomeres, and last in macromeres. By examining the morphology of cell aggregates derived from the isolated blastomeres of the 8-cell stage embryo, it was found that blastomeres derived from the animal hemisphere (mesomere lineage) increased their adhesiveness one cell cycle earlier than those of the vegetal hemisphere (macromere lineage). The timing of the initiation of close cell contact in the descendants of micro-, meso- and macromeres was estimated to be 16-, 32- and 60-cell stage, respectively. Conversely, the nucleus-to-cell-volume ratios, which are calculated from the diameters of the nucleus and cell, were about 0.1 when blastomeres became adhesive, irrespective of the lineage.     

Delay of polarization event increases the number of Cdx2-positive blastomeres in mouse embryo

During preimplantation mouse embryo development expression of Cdx2 is induced in outer cells, which are the trophectoderm (TE) precursors. The mechanism of Cdx2 upregulation in these cells remains unclear. However, it has been suggested that the cell position and polarization may play a crucial role in this process. In order to elucidate the role of these two parameters in the formation of TE we analyzed the expression pattern of Cdx2 in the embryos in which either the position of cells and the time of polarization or only the position of cells was experimentally disrupted. Such embryos developed from the blastomeres that were isolated from 8-cell embryos either before or after the compaction, i.e. before or after the cell polarization took place. We found that in the embryos developed from polar blastomeres originated from the 8-cell compacted embryo, the experimentally imposed outer position was not sufficient to induce the Cdx2 in these blastomeres which in the intact embryo would form the inner cells. However, when the polarization at the 8-cell stage was disrupted, the embryos developed from such an unpolarized blastomeres showed the increased number of cells expressing Cdx2. We found that in such experimentally obtained embryos the polarization was delayed until the 16-cell stage. These results suggest that the main factor responsible for upregulation of Cdx2 expression in outer blastomeres, i.e. TE precursors, is their polarity.     

The influence of cell contact on the division of mouse 8-cell blastomeres

The pattern of division of polarized 8-cell blastomeres with respect to the axis of cell polarity has been compared (i) for cells dividing alone with cells dividing in pairs, and (ii) for early and late dividing cells within a pair. Cell interactions do not seem to influence significantly the overall pattern of division within the population. The only significant difference found was that the second dividing cell in a pair tended to divide in the same way as its earlier dividing companion slightly more frequently than expected. These results suggest that cell interactions immediately prior to and during division do not influence strongly the orientation and position of the division plane. In contrast, interactions between the cells within an intact early 8-cell embryo, which is subsequently disaggregated to singletons or pairs, do influence the type of progeny generated at division to the 16-cell stage, and seem to do so via an effect on the size of the microvillous region generated at the cell apex.     

Distribution of RNA binding protein MOEP19 in the oocyte cortex and early embryo indicates pre-patterning related to blastomere polarity and trophectoderm specification

We report the cloning and characterization of MOEP19, a novel 19 kDa RNA binding protein that marks a defined cortical cytoplasmic domain in oocytes and provides evidence of mammalian oocyte polarity and a form of pre-patterning that persists in zygotes and early embryos through the morula stage. MOEP19 contains a eukaryotic type KH-domain, typical of the KH-domain type I superfamily of RNA binding proteins, and both recombinant and native MOEP19 bind polynucleotides. By immunofluorescence, MOEP19 protein was first detected in primary follicles throughout the ooplasm. As oocytes expanded in size during oogenesis, MOEP19 increased in concentration. MOEP19 localized in the ovulated egg and early zygote as a symmetrical spherical cortical domain underlying the oolemma, deep to the zone of cortical granules. MOEP19 remained restricted to a cortical cytoplasmic crescent in blastomeres of 2-, 4- and 8-cell embryos. The MOEP19 domain was absent in regions underlying cell contacts. In morulae, the MOEP19 domain was found at the apex of outer, polarized blastomeres but was undetectable in blastomeres of the inner cell mass. In early blastocysts, MOEP19 localized in both mural and polar trophectoderm and a subset of embryos showed inner cell mass localization. MOEP19 concentration dramatically declined in late blastocysts. When blastomeres of 4- to 8-cell stages were dissociated, the polarized MOEP19 domain assumed a symmetrically spherical localization, while overnight culture of dissociated blastomeres resulted in formation of re-aggregated embryos in which polarity of the MOEP19 domain was re-established at the blastomere apices. MOEP19 showed no evidence of translation in ovulated eggs, indicating that MOEP19 is a maternal effect gene. The persistence during early development of the MOEP19 cortical oocyte domain as a cortical crescent in blastomers suggests an intrinsic pre-patterning in the egg that is related to the apical-basolateral polarity of the embryo. Although the RNAs bound to MOEP19 are presently unknown, we predict that the MOEP19 domain directs RNAs essential for normal embryonic development to specific locations in the oocyte and early embryo.     

Formation of the embryonic-abembryonic axis of the mouse blastocyst: relationships between orientation of early cleavage divisions and pattern of symmetric/asymmetric divisions

Setting aside pluripotent cells that give rise to the future body is a central cell fate decision in mammalian development. It requires that some blastomeres divide asymmetrically to direct cells to the inside of the embryo. Despite its importance, it is unknown whether the decision to divide symmetrically versus asymmetrically shows any spatial or temporal pattern, whether it is lineage-dependent or occurs at random, or whether it influences the orientation of the embryonic-abembryonic axis. To address these questions, we developed time-lapse microscopy to enable a complete 3D analysis of the origins, fates and divisions of all cells from the 2- to 32-cell blastocyst stage. This showed how in the majority of embryos, individual blastomeres give rise to distinct blastocyst regions. Tracking the division orientation of all cells revealed a spatial and temporal relationship between symmetric and asymmetric divisions and how this contributes to the generation of inside and outside cells and thus embryo patterning. We found that the blastocyst cavity, defining the abembryonic pole, forms where symmetric divisions predominate. Tracking cell ancestry indicated that the pattern of symmetric/asymmetric divisions of a blastomere can be influenced by its origin in relation to the animal-vegetal axis of the zygote. Thus, it appears that the orientation of the embryonic-abembryonic axis is anticipated by earlier cell division patterns. Together, our results suggest that two steps influence the allocation of cells to the blastocyst. The first step, involving orientation of 2- to 4-cell divisions along the animal-vegetal axis, can affect the second step, the establishment of inside and outside cell populations by asymmetric 8- to 32-cell divisions.     

Evolutionary modification of cell lineage in the direct-developing sea urchin Heliocidaris erythrogramma

The sea urchin Heliocidaris erythrogramma undergoes direct development, bypassing the usual echinoid pluteus larva. We present an analysis of cell lineage in H. erythrogramma as part of a definition of the mechanistic basis for this evolutionary change in developmental mode. Microinjection of fluoresceinated tracer dye and surface marking with vital dye are used to follow larval fates of 2-cell, 8-cell, and 16-cell blastomeres, and to examine axial specification. The animal-vegetal axis and adult dorsoventral axis are basically unmodified in H. erythrogramma. Animal cell fates are very similar to those of typically developing species; however, vegetal cell fates in H. erythrogramma are substantially altered. Radial differences exist among vegetal blastomere fates in the 8-cell embryo: dorsal vegetal blastomeres contribute proportionately more descendants to ectodermal and fewer to mesodermal fates, while ventral vegetal blastomeres have a complementary bias in fates. In addition, vegetal cell fates are more variable than in typical developers. There are no cells in H. erythrogramma with fates comparable to those of the micromeres and macromeres of typically developing echinoids. Instead, all vegetal cells in the 16-cell embryo can contribute progeny to ectoderm and gut. Alterations have thus arisen in cleavage patterns and timing of cell lineage partitioning during the evolution of direct development in H. erythrogramma.     

An electron-microscopic study of syncytium formation during early embryonic development of the freshwater planarian Bdellocephala brunnea

To substantiate the assumption that the egg cell and blastomeres in planarian embryos influence surrounding yolk cells to form a syncytium, embryos at 1- to 8-cell stages were examined by electron microscopy. Within special areas of the endoplasmic reticulum both in the egg cell and in the blastomeres, a large number of vacuoles of various sizes formed and then disappeared at least four times over the period from egg-laying through the 8-cell stage as if their contents were being secreted. These activities diminished markedly at the 8-cell stage. Yolk cells surrounding the egg cell and blastomeres were aggregated in close contact with one another in a small clump shortly after egg-laying, and then, late in the 4-cell stage, became fused, forming a syncytium. The correlation between release of vacuoles by the egg cell and blastomeres and the formation of a syncytium by the yolk cells indicate that the cell fusion could be induced by a factor contained in the vacuoles.     

Alternative routes for the establishment of surface polarity during compaction of the mouse embryo

During the process of compaction, mouse 8-cell blastomeres flatten upon each other and polarize along an axis perpendicular to cell contacts. If the process of flattening is prevented, polarization can still occur, but does so in a lower proportion of cells than for control populations, and without the normal contact-directed orientation. We compared contact-directed and noncontact-directed processes to see if they involve common mechanisms. In nonflattened cells, surface polarization was favored in cells with nuclei located close to the cell surface, and the positions of surface poles and of nuclei tended to coincide. We present evidence that microtubules are involved in the development of microvillous poles associated with nuclei. In contrast it is known that polarization of microvilli occurs in the absence of microtubules if blastomeres are allowed to flatten. We conclude that surface polarization of mouse blastomeres can be accomplished by at least two alternative routes. One requires flattening but is independent of microtubules, and another can occur without flattening but involves a microtubule-mediated interaction between the nucleus and the cell cortex. It seems that both these pathways operate in the undisturbed embryo.