The foundation of two distinct cell lineages within the mouse morula

The division of single cells, isolated from an 8-cell mouse embryo, to give $\text{2 ×}\text{1}\text{16}$ cells has been studied by sampling cells for analysis at defined stages during and after the division. Cells were analyzed for evidence of polarity in their surface organization as assessed by fluorescent ligand binding and distribution of microvilli. Individual $\text{1}\text{8}$ cells are polarized. At division, most (82%) divide such that both the pole of ligand binding and the pole of microvilli are distributed to only one of the two daughter cells. A couplet is thereby formed with a large polar cell and a small apolar cell. Some $\text{case1}\text{8}$ cells divide through the pole, generating a couplet of two polar cells, the poles being contiguous at the midbody. Elements of the surface polarity observed in the $\text{1}\text{8}$ cells can be found at all stages throughout division. Analysis of couplets of cells derived from newly formed 16-cell morulae also reveals that most consist of a polar:apolar pair and some consist of a polar:polar couplet in which the poles are contiguous at the midbody.The results indicate that two distinct cell populations are generated at division. These cells are known to occupy different positions within the morula, the polar cells being peripheral and the apolar cells being central. Since peripheral and central cells give rise to trophectoderm and inner cell mass in the blastocyst, we therefore suggest that the foundation of the trophectoderm and inner cell mass lineages may occur by a process of differential inheritance. This conclusion supports the recently proposed polarization hypothesis, which 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.     

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.     

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.     

Blastomeres of the mouse embryo lose totipotency after the fifth cleavage division: expression of Cdx2 and Oct4 and developmental potential of inner and outer blastomeres of 16- and 32-cell embryos

Sixteen inner or outer blastomeres from 16-cell embryos and 32 inner or outer blastomeres from 32-cell embryos (nascent blastocysts) were reaggregated and cultured in vitro. In 24 h old blastocysts developed from blastomeres derived from 16-cell embryos the expression of Cdx2 protein was upregulated in outer cells (new trophectoderm) of the inner cells-derived aggregates and downregulated in inner cells (new inner cell mass) of the external cells-derived aggregates. After transfer to pseudopregnant recipients blastocysts originating from both inner and outer blastomeres of 16-cell embryo developed into normal, fertile mice, but the implantation rate of embryos formed from inner cell aggregates was lower. The aggregates of external blastomeres derived from 32 cell embryo usually formed trophoblastic vesicles accompanied by vacuolated cells. In contrast, the aggregates of inner blastomeres quickly compacted but cavitation was delayed. Although in the latter embryos the Cdx2 protein appeared in the new trophectoderm within 24 h of in vitro culture, these embryos formed only very small outgrowths of Troma1-positive giant trophoblastic cells and none of these embryos was able to implant in recipient females. In separate experiment we have produced normal and fertile mice from 16- and 32-cell embryos that were first disaggregated, and then the sister outer and inner blastomeres were reaggregated at random. In blastocysts developed from aggregates, within 24 h of in vitro culture, the majority of inner and outer blastomeres located themselves in their original position (internally and externally), which implies that in these embryos development was regulated mainly by cell sorting.     

Reassortment of cells according to position in mouse morulae

Sixteen-cell mouse morulae were disaggregated and blastomeres originally occupying outer or inner positions were separated. Outer, inner, or unsorted populations of blastomeres were labeled with either trinitrobenzene sulphonic acid (TNP) or fluorescein isothiocyanate (FITC) and individual blastomeres aggregated to unlabelled partially decompact eight- to ten-cell morulae. After up to 6 h in culture, the positions of the labelled blastomeres within the aggregates were examined. The combined results demonstrated that between 86 and 92% of outer cells remained on the surface of the aggregate and flattened into extensive polygonal shapes, whereas 76-77% of the inner cells had become engulfed by the host morula cells and retained their initial spherical shape. Using unsorted cells, 33-37% were internalised, which is compatible with the most recent estimates of the presence of six to eight inner cells at the 16-cell stage. The possibility that differential adhesiveness of the outer and inner cells is involved in the allocation of cells to the trophectoderm and inner cell mass of the blastocyst is discussed.     

Par‐aPKC‐dependent and ‐independent mechanisms cooperatively control cell polarity,Hippo signaling,and cell positioning in 16‐cell stage mouse embryos

In preimplantation mouse embryos, the Hippo signaling pathway plays a central role in regulating the fates of the trophectoderm (TE) and the inner cell mass (ICM). In early blastocysts with more than 32 cells, the Par‐aPKC system controls polarization of the outer cells along the apicobasal axis, and cell polarity suppresses Hippo signaling. Inactivation of Hippo signaling promotes nuclear accumulation of a coactivator protein, Yap, leading to induction of TE‐specific genes. However, whether similar mechanisms operate at earlier stages is not known. Here, we show that slightly different mechanisms operate in 16‐cell stage embryos. Similar to 32‐cell stage embryos, disruption of the Par‐aPKC system activated Hippo signaling and suppressed nuclear Yap and Cdx2 expression in the outer cells. However, unlike 32‐cell stage embryos, 16‐cell stage embryos with a disrupted Par‐aPKC system maintained apical localization of phosphorylated Ezrin/Radixin/Moesin (p‐ERM), and the effects on Yap and Cdx2 were weak. Furthermore, normal 16‐cell stage embryos often contained apolar cells in the outer position. In these cells, the Hippo pathway was strongly activated and Yap was excluded from the nuclei, thus resembling inner cells. Dissociated blastomeres of 8‐cell stage embryos form polar–apolar couplets, which exhibit different levels of nuclear Yap, and the polar cell engulfed the apolar cell. These results suggest that cell polarization at the 16‐cell stage is regulated by both Par‐aPKC‐dependent and ‐independent mechanisms. Asymmetric cell division is involved in cell polarity control, and cell polarity regulates cell positioning and most likely controls Hippo signaling.     

Analysis of the fifth cell cycle of mouse development

The 5th cell cycle of mouse development was analyzed to determine the lengths of each cell cycle phase. The DNA content of Feulgen-stained blastomere nuclei was measured at various times throughout the cell cycle by microdensitometry. To achieve precise timing of the start of the 5th cell cycle, experiments utilized isolated 16-cell blastomeres and cell pairs obtained by in-vitro division of isolated 8-cell blastomeres. The following estimates were made for a mixed population of polar and apolar 16-cell blastomeres: G1, less than or equal to 2 h; S, 8-9 h; G2 + M, 2 h. No significant difference was found in the timing of DNA synthesis between polar and apolar cells or between cell pairs and whole embryos.     

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.     

Structure and regeneration of the eyes of strombid gastropods

Summary The tips of the eyestalks of three species of strombid gastropods were amputated and the structure of the fully developed eye investigated. The retina contains at least two types of cell: sensory cells bearing long tufts of microvilli with a central cytoplasmic core, and pigment cells with short microvilli.New eyes became visible at the tips of the eyestalk stump 5–16 days after amputation. When the regenerated eyes first appear, they consist of hollow balls of cells with a pigment lined cavity; two types of retinal cells are already distinguishable but their microvilli and cilia are small and sparse. The microvillous tufts and sensory cell contents develop quickly and about 14 days after their first appearance, the eye is a fully formed but miniature organ.     

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.     

Induction of polarized cell-cell association and retardation of growth by activation of the E-cadherin-catenin adhesion system in a dispersed carcinoma line

PC9 lung carcinoma cells cannot tightly associate with one another, and therefore grow singly, despite their expression of E-cadherin, because of their lack of alpha-catenin, a cadherin-associated protein. However, when the E-cadherin is activated by transfection with alpha-catenin cDNA, they form spherical aggregates, each consisting of an enclosed monolayer cell sheet. In the present work, we examined whether the alpha-catenin-transfected cell layers expressed epithelial phenotypes, by determining the distribution of various cell adhesion molecules on their surfaces, including E-cadherin, ZO-1, desmoplakin, integrins, and laminin. In untransfected PC9 cells, all these molecules were randomly distributed on their cell surface. In the transfected cells, however, each of them was redistributed into a characteristic polarized pattern without a change in the amount of expression. Electron microscopic study demonstrated that the alpha-catenin-transfected cell layers acquired apical-basal polarity typical of simple epithelia; they formed microvilli only on the outer surface of the aggregates, and a junctional complex composed of tight junction adherens junction, and desmosome arranged in this order. These results indicate that the activation of E-cadherin triggered the formation of the junctional complex and the polarized distribution of cell surface proteins and structures. We also found that, in untransfected PC9 cells, ZO-1 formed condensed clusters and colocalized with E-cadherin, but that other adhesion molecules rarely showed such colocalization with E-cadherin, suggesting that there is some specific interaction between ZO-1 and E- cadherin even in the absence of cell-cell contacts. In addition, we found that the activation of E-cadherin caused a retardation of PC9 cell growth. Thus, we concluded that the E-cadherin-catenin adhesion system is essential not only for structural organization of epithelial cells but also for the control of their growth.     

Comparison of the morphologies of a flotable and non-flotable strain of Saccharomyces cerevisiae

In previous paper, Saccharomyces cerevisiae LBG H620 and DAM 2155 were compared regarding their ability to float. LBG H620 did not float at all; cells' surface properties indicated that the yeast LBG H620 has a high surface hydrophilicity and a high electrokinetic potential; yeast DSM 2155 possesses high hydrophobicity and a low electrokinetic potential [Tybussek et al. (1994) J Appl Microbiol Biotechnol 41:13–22]. In the present paper, the morphologies of these two yeast strains are compared. Strain LBG H620 formed only single or dudding cells, strain DSM 2155 formed cell aggregates, their size depending on the cultivation condiotions: in the presence of adequate substrate concentration cell aggregates were formed, and during substrate limitation single cell dominated. During rerspiratory growth rather small spherical aggregates and during respiratory/fermentative growth long-strain aggregates were observed *** DIRECT SUPPORT *** AG903053 00004     

PC7 and the related proteases Furin and Pace4 regulate E-cadherin function during blastocyst formation

The first cell differentiation in mammalian embryos segregates polarized trophectoderm cells from an apolar inner cell mass (ICM). This lineage decision is specified in compacted morulae by cell polarization and adhesion acting on the Yes-associated protein in the Hippo signaling pathway, but the regulatory mechanisms are unclear. We show that morula compaction and ICM formation depend on PC7 and the related proprotein convertases (PCs) Furin and Pace4 and that these proteases jointly regulate cell–cell adhesion mediated by E-cadherin processing. We also mapped the spatiotemporal activity profiles of these proteases by live imaging of a transgenic reporter substrate in wild-type and PC mutant embryos. Differential inhibition by a common inhibitor revealed that all three PCs are active in inner and outer cells, but in partially nonoverlapping compartments. E-cadherin processing by multiple PCs emerges as a novel mechanism to modulate cell–cell adhesion and fate allocation.     

STUDIES ON THE HUMAN CORPUS LUTEUM : II. Observations on the Ultrastructure of Luteal Cells During Pregnancy

The ultrastructure of human corpora lutea obtained during the 6th, 10th, 16th, and 35th week of pregnancy is reported. Differences between the established luteal cell of pregnancy and the transitory luteal cell of the menstrual cycle are noted. In pregnancy the luteal cell is more compartmentalized into a peripheral mass of ER (endoplasmic reticulum) and a central area where mitochondria and Golgi complexes are concentrated. The latter area extends to a cell surface where microvilli face on a perivascular space. Long bundles of filaments are prominent within the luteal cell cytoplasm and, in contiguous cells, appear to arise from adjacent desmosomal regions. Bilateral subsurface cisternae of granular ER at lateral cell borders appear to be areas of specialized junctional surfaces. Certain luteal cells with irregular nuclear membranes are also characterized by vesicular aggregates enclosed within a single membrane. These aggregates are found within the peripheral nucleoplasm or the perinuclear cytoplasm. Their single limiting membrane often appears continuous with either the inner or outer leaflet of the nuclear membrane.     

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.     

Vergleichende Untersuchungen an Amoebozyten und Blasenzellen von Cepaea nemoralis L. (Gastropoda,Stylommatophora)

Summary The pecten oculi of the sparrow consists of capillaries, pigment cells and a superficial membrane. Because of the loose structure of the first two components broad intercellular spaces occur in the pecten. The capillary wall consists of endothelial cells and a perivascular membrane. The bodies of the endothelial cells are flattened, while the plasmalemma of both their surfaces (basal and luminal) is strongly folded and forms numerous microfolds with an average thickness of 700 Å. The height of the inner microfolds is 1.4–1.8 m, the outer microfolds measure 1.3–1.6 m. They lie densely packed side by side and are separated by recesses of the capillary lumen ca. 500 Å wide. Due to this the surface of the endothelial cell is increased by approximately 20-fold. The adjoining endothelial cells abut or overlap with margins, and are joined by the zonulae adherentes. Pigment cells form numerous processes and microvilli. Some rest on the capillary walls, while others penetrate the superficial membrane of the pecten or fill the intercellular spaces.     

Cytoskeletal organization affects cellular responses to cytochalasins: comparison of a normal line and its transformant

The relationships between cytoskeletal network organization and cellular response to cytochalasin D (CD) in a normal rat fibroblast cell line (Hmf-n) and its spontaneous transformant (tHmf-e), with markedly different cytoskeletal phenotypes, were compared (using immunofluorescence, electron microscopy, and DNAse I assay for actin content). Hmf-n have prominent, polar stress fiber (SF) arrays terminating in vinculin adhesion plaques whereas tHmf-e, which are apolar, epithelioid cells with dense plasma membrane-associated actin networks, lack SF and adhesion plaques. Hmf-n exposed to CD become markedly retracted and dendritic, SF-derived actin aggregates form large endoplasmic masses, and discrete tabular aggregates at the distal ends of retraction processes. Prolonged exposure leads to recession of process, cellular rounding, and development of large cystic vacuoles. tHmf-e cells exposed to similar doses of CD display a diagnostically different response; retraction is less drastic, cells retain broad processes containing scattered actin aggregates in discrete foci often associated with plasma membrane, large tabular aggregates are never found and processes persist throughout long exposure, vacuolation is uncommon. The CD-induced microfilamentous aggregates in Hmf-n are composed of short, kinky filament fragments forming a felt-like skein, often aggregates contain a more ordered array of roughly parallel fragments, while those of tHmf-e are very short, kinky, randomly orientated filaments imparting a distinctly granular nature to the mass. Total actin content and the amount of actin associated with detergent-resistant cytoskeletons increase following CD exposure in both cell types. Throughout exposure to CD, the actin-associated contractile proteins tropomyosin, myosin, and alpha-actinin co-localize within the actin aggregates in both cell types. Fodrin, the protein linking cortical actin to membrane, co-localizes with actin aggregates in tHmf-e cells and most, but not all, such aggregates in Hmf-n cells, consistent with their stress fiber derivation. Vinculin is lost from the tabular aggregates at the distal ends of retraction processes in Hmf-n cells concomitant with the fragmentation and contraction of SF. The aborized processes in both cells types contain strikingly similar axial cores of bundled vimentin filaments associated with passively compressed microtubules. The characteristic CD-induced distribution of actin filament aggregates and redistribution of vimentin in these cell types also occur when cells are allowed to respread from the rounded state in the presence of CD.     

Induction of cytoplasmic polarity in heterokaryons of mouse 4-cell-stage blastomeres fused with 8-cell- and 16-cell-stage blastomeres

Cell surface and cytoplasmic polarity is exhibited by the blastomeres of mouse preimplantation embryos following compaction at the 8-cell stage of cleavage. It has been hypothesized that cytoplasmic polarity is initiated by plasma membrane functions of polar blastomeres that are absent from apolar blastomeres. To test this hypothesis the plasma membranes of "test" polar and apolar 8-cell- and 16-cell-stage blastomeres were inserted into the plasma membrane of "carrier" 4-cell-stage blastomeres by polyethylene glycol-mediated fusion of carrier-test blastomere pairs. After a 4-hr culture period each heterokaryon was scored for the distribution of two marker organelles--lipid droplets and nuclei--with respect to their proximity to the plasma membrane insert from the test blastomere. Plasma membrane inserts from polar test blastomeres were identified by labeling their apical domains with fluorescently tagged (succinylated) concanavalin A. The incidence of polar heterokaryons (those exhibiting a discrete fluorescently labeled area of plasma membrane corresponding to the apical domain inherited from the test blastomere) was 55/85 (69%) and 48/79 (61%) for 8-cell-stage and 16-cell-stage test blastomeres, respectively. In all polar heterokaryons, both nuclei were subjacent to the fluorescent label (apical domain of a polar plasma membrane insert), while the majority of lipid droplets resided in the hemisphere opposite the fluorescent label. In all 61 apolar heterokaryons examined (those lacking a discrete fluorescently labeled plasma membrane area) both nuclei were centrally located and lipid droplets were randomly distributed. These observations are consistent with the hypothesis that cytoplasmic polarity can be initiated by properties that distinguish the plasma membranes of polar blastomeres from those of apolar blastomeres.