Allocation of cells to inner cell mass and trophectoderm lineages in preimplantation mouse embryos

Inner cell mass (ICM) and trophectoderm cell lineages in preimplantation mouse embryos were studied by means of iontophoretic injection of horseradish peroxidase (HRP) as a marker. HRP was injected into single blastomeres at the 2- and 8-cell stages and into single outer blastomeres at the 16-cell and late morula (about 22- to 32-cell) stages. After injection, embryos were either examined immediately for localization of HRP (controls) or they were allowed to develop until the blastocyst stage (1 to 3.5 days of culture) and examined for the distribution of labeled cells. In control embryos, HRP was confined to one or two outer blastomeres. In embryos allowed to develop into blastocysts, HRP-labeled progeny were distributed into patches of cells, showing that there is limited intermingling of cells during preimplantation development. A substantial fraction of injected blastomeres contributed descendants to both ICM and trophectoderm (95, 58, 44, and 35% for injected 2-cell, 8-cell, 16-cell, and late morula stages, respectively). Although more than half of the outer cells injected at 16-cell and late morula stages contributed descendants only to trophectoderm (53 and 63%, respectively), some outer cells contributed also to the ICM lineage even at the late morula stage. Although the mechanism for allocation of outer cells to the inner cell lineage is unknown, our observation of adjacent labeled mural trophectoderm and presumptive endoderm cells implicated polarized cell division. This observation also suggests that mural trophectoderm and presumptive endoderm are derived from common immediate progenitors. These cells appear to separate into inner and outer layers during the fifth cleavage division. Our results demonstrate the usefulness of HRP as a cell lineage marker in mouse embryos and show that the allocation of cells to ICM or trophectoderm begins after the 2-cell stage and continues into late cleavage.     

ELECTRICAL COUPLING BETWEEN EMBRYONIC CELLS BY WAY OF EXTRACELLULAR SPACE AND SPECIALIZED JUNCTIONS

The meroblastic egg of the teleost, Fundulus heteroclitus, was studied electrophysiologically from cleavage to mid-gastrula stages. The yolk is an intracellular inclusion surrounded by a membrane of high resistivity (50 kΩcm²). This membrane generates a cytoplasm-negative resting potential in later stages. Cells of all stages studied are coupled electrically. In gastrulae, coupling is both by way of specialized junctions between cells and by way of intra-embryonic extracellular space, the segmentation cavity. The latter mode is present because the segmentation cavity is sealed off from the exterior by a high resistance barrier, and the outer membrane of surface cells is of high resistance (50–100 kΩcm²) compared to the inner membrane. It can be inferred that clefts between surface cells are occluded by circumferential junctions. Isolated cells from late cleavage stages develop coupling in vitro, confirming the existence of coupling by way of intercellular junctions. Both modes of coupling could mediate communication between cells that is important in embryonic development.     

Expression of syndecan, a putative low affinity fibroblast growth factor receptor, in the early mouse embryo.

Syndecan is an integral membrane proteoglycan that binds cells to several interstitial extracellular matrix components and binds to basic fibroblast-growth factor (bFGF) thus promoting bFGF association with its high-affinity receptor. We find that syndecan expression undergoes striking spatial and temporal changes during the period from the early cleavage through the late gastrula stages in the mouse embryo. Syndecan is detected initially at the 4-cell stage. Between the 4-cell and late morula stages, syndecan is present intracellularly and on the external surfaces of the blastomeres but is absent from regions of cell-cell contact. At the blastocyst stage, syndecan is first detected at cell-cell boundaries throughout the embryo and then, at the time of endoderm segregation, becomes restricted to the first site of matrix accumulation within the embryo, the interface between the primitive ectoderm and primitive endoderm. During gastrulation, syndecan is distributed uniformly on the basolateral cell surfaces of the embryonic ectoderm and definitive embryonic endoderm, but is expressed with an anteroposterior asymmetry on the surface of embryonic mesoderm cells, suggesting that it contributes to the process of mesoderm specification. In the extraembryonic region, syndecan is not detectable on most cells of the central core of the ectoplacental cone, but is strongly expressed by cells undergoing trophoblast giant cell differentiation and remains prominent on differentiated giant cells, suggesting a role in placental development. Immunoprecipitation studies indicate that the size of the syndecan core protein, although larger than that found in adult tissues (75 versus 69 x 10(3) Mr), does not change during peri-implantation development. The size distribution of the intact proteoglycan does change, however, indicating developmental alterations in its glycosaminoglycan composition. These results indicate potential roles for syndecan in epithelial organization of the embryonic ectoderm, in differential axial patterning of the embryonic mesoderm and in trophoblast giant cell function.     

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.     

小鼠胚胎致密化起始的调控机制

植入前小鼠胚胎的发育事件包括第一次卵裂、胚胎基因组激活、桑椹胚致密、囊胚形成。小鼠受精卵胚胎的致密化发生在8-细胞阶段晚期, 致密过程中, 胚胎卵裂球本身以及卵裂球之间发生了一系列的变化。这些变化包括卵裂球微绒毛以及胞质成分的极性化分布, 卵裂球之间形成特殊的胞间连接。致密化是哺乳动物胚胎发育过程中的第一个细胞分化事件, 即导致了内细胞团以及滋养外胚层的产生。植入后, 内细胞团将发育成为胚体, 滋养外胚层将发育成为胎盘等胚外组织。细胞粘附分子E-cadherin介导的胞间粘附起始了致密化。卵裂球发生粘附所需的组分在致密前已经存在, 但是直至8-细胞阶段晚期连接复合体才表现出明显的粘附活性。敲除E-cadherin基因, 发现母源性的E-cadherin足以介导致密。E-cadherin介导的胞间粘附是细胞粘附的第一步。文章综述了E-cadherin介导胞间粘附的具体过程以及蛋白激酶C(Protein kinase C, PKC)调控该过程的相关 机制。     

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.     

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.     

Shifts in ATP synthesis during preimplantation stages of mouse embryos.

The actual and potential activities of the cyochrome system were studied in cleavage-stage mouse embroys. Activities were determined by assaying embroys for total ATP and the rates of [32-P]ATP synthesis both before and after their incubation in medium supplemented either with an energy coupling site inhibitor (antimycin, amytal or cyanide) or with the FADH-linked substrate, succinate. The data indicate that there are three major shifts in the mode of ATP production during preimplantation stages: the first, between the two-cell and late four-cell stages; the second, between the eight-celland late morula stages; and the third, between the late morula and late blastocyst stages. These data are discussed in relation to studies on the energy metabolism of cleavage and blastocyst stage mouse embryos.     

EP-cadherin in muscles and epithelia of Xenopus laevis embryos.

EP-cadherin is a novel Xenopus Ca+2-dependent adhesion molecule, which shares comparable homology with mouse E- and P-cadherins (Ginsberg, De Simone and Geiger; 1991, Development 111, 315-325). We report here the patterns of expression of this molecule in Xenopus laevis embryos at different developmental stages ranging from cleavage to postmetamorphic. EP-cadherin is already expressed in the oocyte and egg and can then be detected in close association with the membrane of all blastomeres up to late blastula stages. Starting at late gastrula stages, the level of EP-cadherin expression increases sharply in non-neural ectodermal cells, in the somites and in the notochord; it persists in endodermal cells and decreases rapidly in all migratory cells. During neurulation the level of EP-cadherin expression declines gradually in the nervous system and is undetectable here throughout later development except in the optic nerve and in the neural part of the olfactory organ. This pattern continues during later development so that in the tailbud stage and up to metamorphosis the most prominent staining is detected in the epidermis and skeletal muscle. After metamorphosis, the molecule gradually disappears from the muscle tissue and the major site of expression remains the skin. EP-cadherin is invariably present in close association with the cell membrane. In the muscle it is associated with the sarcolemma at regions of myoblast-myoblast or myotube-myotube contact. In epidermal cells, EP-cadherin is usually coexpressed with E-cadherin. Yet, while E-cadherin staining is always restricted to the basolateral aspects of the cells, EP-cadherin is often distributed throughout the plasmalemma including the apical surface.     

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.     

Surface activity and locomotion of Fundulus deep cells during blastula and gastrula stages

The surface activity and locomotion of deep cells of the Fundulus blastoderm were studied in vivo with time-lapse cinemicrography. During late cleavage, the surfaces of the blastomeres begin to undulate gently. By early blastula, these undulations increase gradually in amplitude and hemispherical surface protrusions called blebs appear. These blebs form and retract rapidly, and at mid blastula some may be seen adhering to the surfaces of other cells. At the same time, they often expand into elongate lobopodia. Cell locomotion is first evident in mid blastula and continues throughout gastrulation. During locomotion, the leading edge of a deep cell behaves in various ways. When blebs and lobopodia adhere to a substratum (other deep cells, the undersurface of the enveloping layer, or the periblast) and retract, the cell may move in the direction of the shortening cell process. Alternatively, blebs and lobopodia may adhere, but not shorten. Locomotion is accomplished rather by protoplasmic flow into the protrusion. Blebs and lobopodia also may flatten and spread on the substratum as lamellipodia. Variations in the contact and locomotory behavior of deep cells and in the rate of their movement during blastula and gastrula stages are described in detail.     

Holoblastic early cleavage of Tetrodontophora bielanensis (Collembola) eggs, with special reference to its irregularity.

The fertilized eggs of Tetrodontophora bielanensis start to cleave 6 to 8 days after oviposition and initially only karyokineses occur. The cytokinesis begins after two karyokineses, when four nuclei are observed in the ooplasm. Two cleavage furrows, perpendicular to each other, appear simultaneously at the egg poles where polar bodies are located and gradually the furrows encompass the whole egg diameter. The furrow formation is initiated by the bundle of microfilaments that contract and pull superficial fragments of the oolemma into the yolk and subsequently new membranes, separating the daughter cells, start to form. However, they do not grow towards the egg centre but bifurcate, leaving the central part of the ooplasm outside of the newly formed blastomeres. Starting from the fourth or fifth cleavage division, the bifurcations permanently occur and multiple cleavage furrows are formed on the embryo surface. Moreover, fragments of the ooplasm, enclosed within the cell membrane but devoid of cell nucleus are observed. During further development such cell fragments become reincorporated into the embryo. This mode of cleavage leads eventually to the formation of cellular blastoderm on the embryo surface. The results presented in the paper suggest that the control of cleavage in T. bielanensis acts not at the level of cytoplasmic determinants but rather at the level of positional information of blastomeres.     

Polarization of the Surface Membrane and Cortical Layer of Sea Urchin Blastomeres, and its Inhibition by Cytochalasin B

Sea-urchin blastomeres have two domains of the plasma membrane which can be distinguished immunocytochemically. An egg-surface antibody (anti-ES), which binds to the membrane of the entire surface region of eggs before cleavage, binds to the membrane of the outer surface region of blastomeres after cleavage, but not to that of the cleavage furrow region or interblastomeric surface region.
The anti-ES binding sites on the egg membrane were chased after cleavage by labeling the egg plasma membrane with FITC conjugated monovalent anti-ES (FITC-Fab anti-ES) before the first cleavage, and then allowing the eggs to cleave. The surface fluorescence increased in intensity in the cleavage furrow region with progress of furrowing, but after completion of the furrowing, the fluorescence became uniform and finally decreased in the interblastomeric surface region.
The distributions of pigment granules and NBD-phallacidin stainable microfilaments in the cortex after completion of furrowing were polarized in the same way as the anti-ES binding area. As cytochalasin B completely inhibited the polarization in both the surface and cortical layer but colchicine did not, polarization of the anti-ES binding area was concluded to be due to the post-cleavage polarized distribution of submembranous microfilaments in the cortical layer.     

Radioautographic and cytofluorimetric analysis of DNA synthesis during the pre-implantation period of rat and mouse embryonic development]

The patterns of DNA synthesis and kinetics of cell population in the rat and mouse embryos were studied by means of 3H-thymidine autoradiography and cytofluorimetry. The rat and mouse embryos during the period of cleavage consist of a heterogenous population of blastomeres. At all the stages under study, all phases of the cell cycle occur in the blastomeres: G1, S, G2 and mitosis. The embryonic cells were distributed into groups containing 2c, 3c, 4c and more DNA. The ratio of cell number in these groups differed in the mouse and rat embryos. The mouse embryos are characterized by the appearance of a considerable amount of polyploid cells in S phase at the morula stage. The stage and species specific quantitative and qualitative patterns were established for DNA synthesis and kinetics of the cell population of blastomeres.     

Changes in the distribution of a spectrin-like protein during development of the preimplantation mouse embryo

The mouse blastocyst expresses a 240,000-mol-wt polypeptide that cross-reacts with antibody to avian erythrocyte alpha-spectrin. Immunofluorescence localization showed striking changes in the distribution of the putative embryonic spectrin during preimplantation and early postimplantation development. There was no detectable spectrin in either the unfertilized or fertilized egg. The first positive reaction was observed in the early 2-cell stage when a bright band of fluorescence delimited the region of cell-cell contact. The blastomeres subsequently developed continuous cortical layers of spectrin and this distribution was maintained throughout the cleavage stages. A significant reduction in fluorescence intensity occurred before implantation in the apical region of the mural trophoblast and the trophoblast outgrowths developed linear arrays of spectrin spots that were oriented in the direction of spreading. In contrast to the alterations that take place in the periphery of the embryo, spectrin was consistently present in the cortical cytoplasm underlying regions of contact between the blastomeres and between cells of the inner cell mass. The results suggest a possible role for spectrin in cell-cell interactions during early development.     

An electron microscopic study of the development of amphioxus,Branchiostoma belcheri tsingtauense: Cleavage

Development of the Asian amphioxus, Branchiostoma belcheri tsingtauense, was investigated by scanning and transmission electron microscopy (SEM and TEM) from the fertilized egg through the blastula stage. The fertilized egg is spherical (mean diameter 115 μm after SEM preparation) and is covered with microvilli. Throughout cleavage, the second polar body remains attached to the animal pole. The cleavage type in this species is essentially radial, as revealed by SEM observations. At the third cleavage or 8-cell stage, and at later stages, a size difference between blastomeres in the animal and the vegetal halves is clearly discernible, but less marked than that reported for the European amphioxus, B. lanceolatum. During the period spanning the third to the fifth cleavage (8–32-cell) stages, blastomeres are arranged in tiers along the animal-vegetal axis. After the sixth cleavage, or 64-cell stage, the tiered arrangement of the blastomeres is no longer seen. At the 4-cell stage, the blastocoel or cleavage cavity is seen as an intercellular space, opening to the outside. The blastocoel remains open at the animal and the vegetal poles in later stages. Throughout early development, the cytoplasm of the blastomeres includes yolk granules, mitochondria, Golgi complexes, and rough and smooth endoplasmic reticulum. Chromatin in the interphase nucleus is not clearly demonstrated, and chromosomes in the mitotic phase are also extremely difficult to detect. As yet, regional differences have not been found in distribution and organization of cytoplasmic components with respect to prospective ectodermal, mesodermal, and endodermal areas in the fertilized egg and later cleaved embryos, although there are possibly fewer yolk granules in the region of the animal pole than in the vegetal polar zone.     

CLEAVAGE FURROW FORMATION IN A TELOLECITHAL EGG (LOLIGO PEALII) : I. Filaments in Early Furrow Formation

Formation of the first cleavage furrow in the telolecithal egg of Loligo was studied with the electron microscope. Before the actual furrow forms, a dense filamentous band develops below the plasma membrane from membrane-bounded dense bodies which appear to be Golgi-derived. The egg surface is thrown into a number of longitudinal folds which parallel the furrow and eventually become incorporated into it. These longitudinal folds contain a network of tubules and vesicles. Frequently, multivesiculate bodies are associated with the furrow and possibly give rise to the network of tubules and vesicles. Apparently part of the membrane between the two new blastomeres is derived from the surface of the longitudinal folds. The theory of furrow formation by contraction is discussed in light of the filamentous band.     

Unequal cleavage in the early Tubifex embryo

Unequal cleavage that produces two blastomeres of different size is a cleavage pattern that many animals in a variety of phyla, particularly in Spiralia, adopt during early development. This cleavage pattern is apparently instrumental for asymmetric segregation of developmental potential, but it is also indispensable for normal embryogenesis in many animals. Mechanically, unequal cleavage is achieved by either simple unequal cytokinesis or by forming a polar lobe at the egg's vegetal pole. In the present paper, the mechanisms for unequal cytokinesis involved in the first three cleavages in the oligochaete annelid Tubifex are reviewed. The three unequal cleavages are all brought about by an asymmetrically organized mitotic apparatus (MA). The MA of the first cleavage is monastral in that an aster is present at one pole of a bipolar spindle but not at the other. This monastral form, which arises as a result of the involvement of a single centrosome in the MA assembly, is both necessary and sufficient for unequal first cleavage. The egg cortex during the first mitosis is devoid of the ability to remodel spindle poles. In contrast to the non-cortical mechanisms for the first cleavage, asymmetry in the MA organization at the second and third cleavages depends solely on specialized properties of the cell cortex, to which one spindle pole is physically connected. A cortical attachment site for the second cleavage spindle is generated de novo at the cleavage membrane resulting from the first cleavage; it is an actin-based, cell contact-dependent structure. The cortical microtubule attachment site for the third cleavage, which functions independently of contact with other cells, is not generated at the cleavage membrane resulting from the second cleavage, but is located at the animal pole; it may originate from the second polar body formation and become functional at the 4-cell stage.