Influence of the timing of blastomere isolation after the removal of nocodazole in bovine nuclear transfer

This study was conducted to investigate the influence of the timing of blastomere isolation after the removal of nocodazole on the subsequent division of blastomeres and developmental ability of reconstituted bovine embryos. The division rate of isolated blastomeres was examined at 3, 5 and 24 h of culture after nocodazole removal. Furthermore, isolated blastomeres and those of whole embryos were used as donors in nuclear transfer to determine the development of reconstituted embryos. The division rate of isolated blastomeres at 3 h was significantly lower than the presumptive division rate of blastomeres from whole embryos (P<0.05). When these blastomeres were used as donor nuclei, the dividing blastomeres yielded a significantly higher development rate than blastomeres from whole embryos (P<0.05). These results confirm that the timing of blastomere isolation influences the subsequent division of blastomeres and the developmental ability of the reconstituted embryos.     

Modification of cell division by phorbol ester in preimplantation mouse embryos

2-cell mouse embryos were treated in vitro with a 2 h pulse of phorbol myristate acetate (PMA) at 32nd, 38th and 50th h after hCG, then chased in culture for up to 46 h. Embryos were fixed at various time intervals of chasing, then stained and inspected. Some embryos were carefully inspected with a video recording system, every 1.44s and the cell divisions (cytokinesis) as well as formation of large, single blastomeres, each from two smaller ones, were recorded. PMA pulse let to the suppression of cell divisions. The rate of the suppression was time dependent: with a delay of 0-1, 12 and 18 h between the PMA pulse and time of scheduled cell division about 99, 87 and 44% of 2-cell embryos remained at this stage of development, for at least 10 h, respectively, and 90, 58 and 12% of their blastomeres revealed binuclearity. Since we found that PMA-mediated formation of binuclearity was not the effect of cell fusions, it was assumed that the inhibition of cytokinesis preceded by karyokinesis was responsible for binuclearity. PMA effect on cell divisions was reversible. PMA-treated embryos revealed formation of large, single blastomeres, each from two smaller ones. If cell division appeared after PMA pulse, in about 52% of 3- to 6-cell embryos, the large blastomere formation was recorded in the course of the subsequent 38 h. Large blastomere formation was concluded to be the result of either cell fusion or reversion of incompleted cytokinesis brought about by PMA.     

Dyssymmetrical cytotomy and orientation of the spindles in early isolated blastomeres of gastropod molluscs]

While removing the vitelline membrane mechanically or by trypsinization, one or two blastomeres were isolated from two-, four- and eight-celled embryos Lymnaea stagnalis, Physa fontinalis and Ph. acuta. If a pair of blastomeres was isolated prior to the formation of the III and IV cleavage spindles, it became similar to a two-cell embryo; the spindles oriented in parallel to each other and the contact zone of blastomeres preserving the previous localization of the nuclei and the subsequent division was equal. If a pair of blastomeres was isolated in metaphase, the localization of spindles did not change and the relative size of sister blastomeres after the subsequent division resembled the normal size (in particular, the III division was unequal). In the course of division of isolated single blastomeres, as well as pairs of blastomeres with parallel spindles, mutual turns of sister cells along the plane of new furrow, always dexiotropic in Lymnaea and laetropic in Physa, were observed in all cycles. The ability of dissymmetrical invariant turns during cytotomy, shown earlier when studying the whole embryos, is, thus, inherent to each blastomere irrespective of the neighbour ones but is supressed during the normal development after the III division mechanically due to the dense cellular packing projected by the orientation of spindles.     

Periodic appearance and disappearance of microvilli associated with cleavage cycles in the egg of the ascidian, Halocynthia roretzi

The surface of eggs of the ascidian Halocynthia roretzi, observed with SEM, is essentially smooth until immediately before cell division when numerous microvilli appear and remain during cytokinesis. As the dividing blastomeres become closely adherent, however, the microvilli disappear and the eggs recover their smooth surface. This periodic appearance-disappearance of microvilli is repeated at each cleavage cycle up to at least the 32-cell stage. During blastomere adhesion, microvilli that have appeared near the plane of the first cleavage or of the bilateral symmetry seem to fuse together across the plane to form a zipper-like complex of cytoplasmic processes, which might be responsible for attachment of the two halves of these bilaterally symmetrical embryos via the blastomeres bordering the plane of symmetry.     

Allocation of cells in mouse blastocyst is not determined by the order of cleavage of the first two blastomeres

The second cleavage of the mouse embryo is asynchronous. Some recent investigators have proposed that the sequence of division of blastomeres in two-cell embryos may predict the ultimate location of the descendants of these blastomeres within the blastocyst. To verify this model, we tracked the cells derived from two-cell stage blastomeres using tetramethylrhodamine-conjugated dextran as a lineage tracer. In the first variant of the experiment, we labeled one of two blastomeres in two-cell embryos and subsequently recorded which blastomere cleaved first. In the second variant of the experiment, fluorescent dextran was injected at the three-cell stage into the blastomere that had not yet cleaved. Subsequently, the fate of the progeny of labeled and unlabeled blastomeres was followed up to the blastocyst stage. Our results suggest that allocation of cells into the embryonic and abembryonic parts of the blastocyst is not determined by the order of cleavage of the first two blastomeres.     

Asymmetrical rotations of blastomeres in early cleavage of gastropoda

Summary The movements of blastomere surfaces marked with carbon particles during cytokinesis of the Ist–IVth cleavage divisions in the eggs of the gastropodsLymnaea stagnalis, L. palustris, Physa acuta and Ph. fontinalis have been studied by time-lapse cinematographic methods. The vitelline membrane was removed with trypsin. At 2- and 4-cell stages shifts of nuclei have also been studied.Symmetrical as well as asymmetrical surface movements (in respect to the furrow plane) have been revealed. Symmetrical surface movements at the beginning of cytokinesis consist mainly in contraction of the furrow zone and in expansion of the more peripheral regions; between these there is a stationary zone. After the end of cytokinesis the furrow region expands.Considerableasymmetrical surface movements have also been observed in all four divisions. From anaphase until the end of cytokinesis each of the two sister blastomeres rotates with respect to the other in such a way, that if viewed along the spindle axis, the blastomere nearest to the observer rotates dexiotropically in a dextral species and laeotropically in a sinistral species (primary rotations). After the completion of cytokinesis the blastomeres may rotate in a reverse direction. The latter rotations are less pronounced in the IInd and IIIrd divisions and most pronounced in the IVth division. Blastomeres with the vitelline membrane intact retain a slight capacity for primary rotations. In normal conditions nuclei of the first two blastomeres shift mainly laeotropically in dextral species, but dexiotropically in sinistral species, being carried along by the reverse surface rotations.The invariable primary asymmetrical rotations of blastomeres seem to be the basis of enantiomorphism in molluscan cleavage. They are assumed to be determined by an asymmetrical structure of the contractile ring carrying out the cytokinesis.     

Intravital selection of early mouse embryos by sex and karyotypic characteristics

The possibility of live karyotyping by a single blastomere isolated at the 2-, 4-, and 8-cell stage has been investigated. It is expedient to use to this end a single blastomere isolated from a 4-cell embryo. Three rest blastomeres formed normal morulae or blastocysts upon cultivation during 44 or 68 hrs. When the isolated blastomeres were cultivated for 14-16 hrs in a medium 0.5 micrograms/ml colcemide, 97% of blastomeres were at the metaphase stage and 72% of chromosome plates were suitable for karyotyping. The prospects of the method proposed in experimental embryology and for selection of the early embryos of farm animals by sex are discussed.     

Effect of Initiation Time of Hydrostatic Pressure Shock on Chromosome Set Doubling of Tetraploidization in Turbot <Emphasis Type="Italic">Scophthalmus maximus</Emphasis>

The objective of the study was to clarify the effects of initiation time on chromosome set doubling induced by hydrostatic pressure shock through nuclear phase fluorescent microscopy in turbot Scophthalmus maximus. The ratio of developmentally delayed embryo and chromosome counting was used to assess induction efficiency. For the embryos subjected to a pressure of 67.5 MPa for 6 min at prometaphase (A group), chromosomes recovered to the pre-treatment condition after 11-min recovering. The first nuclear division and cytokinesis proceeded normally. During the second cell cycle, chromosomes did not enter into metaphase after prometaphase, but spread around for about 13 min, then assembled together and formed a large nucleus without anaphase separation; the second nuclear division and cytokinesis was inhibited. The ratio of developmentally delayed embryo showed that the second mitosis of 78% A group embryo was inhibited. The result of chromosome counting showed that the tetraploidization rate of A group was 72%. For the embryos subjected to a pressure of 67.5 MPa for 6 min at anaphase (B group), chromosomes recovered to the pre-treatment condition after about 31-min recovering. Afterwards, one telophase nucleus formed without anaphase separation; the first nuclear division was inhibited. The time of the first cleavage furrow occurrence of B group embryos delayed 27 min compared with that of A group embryos. With the first cytokinesis proceeding normally, 81.3% B group embryos were at two-cell stage around the middle of the second cell cycle after treatment. Those embryos were one of the two blastomeres containing DNA and the other without DNA. The first nuclear division of those embryos was inhibited. During the third cell cycle after treatment, 65.2% of those abovementioned embryos were at four-cell stage, cytokinesis occurred in both blastomeres, and nuclear division only occurred in the blastomere containing DNA. Of those abovementioned embryos, 14.0% were at three-cell stage and cytokinesis only occurred in the blastomere containing DNA. The result of chromosome counting showed that the tetraploidization rate of B group was only 7%. To summarize what had been mentioned above, mechanisms on chromosome set doubling of tetraploid induction would be different with different initiation time of hydrostatic pressure treatment. Chromosome set doubling was mainly due to inhibition of the second mitosis when hydrostatic pressure treatment was performed at prometaphase. Otherwise, chromosome set doubling was mainly due to inhibition of the first nuclear division when hydrostatic pressure treatment was performed at anaphase. Induction efficiency of tetraploidization resulted from inhibition of the second cleavage was higher than which resulted from inhibition of the first nuclear division. This study was the first to reveal biological mechanisms on the two viewpoints of chromosome set doubling through effect of initiation time of hydrostatic pressure treatment on chromosome set doubling in tetraploid induction.     

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.     

Binary specification of nerve cord and notochord cell fates in ascidian embryos

In the ascidian embryo, the nerve cord and notochord of the tail of tadpole larvae originate from the precursor blastomeres for both tissues in the 32-cell-stage embryo. Each fate is separated into two daughter blastomeres at the next cleavage. We have examined mechanisms that are responsible for nerve cord and notochord specification through experiments involving blastomere isolation, cell dissociation, and treatment with basic fibroblast growth factor (bFGF) and inhibitors for the mitogen-activated protein kinase (MAPK) cascade. It has been shown that inductive cell interaction at the 32-cell stage is required for notochord formation. Our results show that the nerve cord fate is determined autonomously without any cell interaction. Presumptive notochord blastomeres also assume a nerve cord fate when they are isolated before induction is completed. By contrast, not only presumptive notochord blastomeres but also presumptive nerve cord blastomeres forsake their default nerve cord fate and choose the notochord fate when they are treated with bFGF. When the FGF-Ras-MAPK signaling cascade is inhibited, both blastomeres choose the default nerve cord pathway, supporting the results of blastomere isolation. Thus, binary choice of alternative fates and asymmetric division are involved in this nerve cord/notochord fate determination system, mediated by FGF signaling.     

Properties of smaller and larger cells from the 16-cell mouse embryo: increase in cell adhesiveness in the smaller cells cultured up to late 16-cell stage

Blastomeres isolated from 16-cell mouse embryos consist of larger cells and smaller cells. In the intact embryo, the larger cells tend to differentiate to the trophectoderm, while the smaller cells give rise to the inner cell mass. The mode of phenotypic alteration of isolated blastomeres from early 16-cell embryos was examined by culturing them as single cells in vitro. The smaller blastomeres showed an increased tendency to be engulfed, as revealed by aggregation experiments during a 15 h culture period just prior to division into the 32-cell stage, while the larger cells remained showing high engulfing activity during this period. The present result demonstrates that the smaller blastomere continues to adopt a selected differentiation program for a certain period, even after its environment is changed.     

Contact-independent polarization of the cell surface and cortex of free sea urchin blastomeres

In a normal, intact sea urchin embryo blastomeres are structurally polarized so that all microvilli and cortical "pigment granules" are situated at the apical surfaces facing the hyaline layer and are absent from basolateral surfaces facing adjacent blastomeres and the internal embryonic cavity. To test the roles of intercellular contacts and the hyaline layer in the process of establishing this blastomere polarity, these two factors were experimentally eliminated; sea urchin eggs of four species were denuded of the nascent hyaline layer soon after fertilization and then cultured in calcium-free artificial seawater to prevent subsequent intercellular adhesion and contact. Such free blastomeres divided normally and still developed polarized distributions of microvilli and pigment granules resembling those of the corresponding blastomeres in intact embryos. These results indicate that the process of polarization is intrinsic to individual blastomeres (self-polarization) and that neither intercellular contacts nor adhesion of microvilli to the hyaline layer is necessary. The precise temporal and spatial coincidence of the patterns of polarization and the division cycles further suggests that a mechanistic link is maintained among cell division, blastomere polarization, and probably also a heritable component of the animal-vegetal axis.     

Mesendoderm cells induce oriented cell division and invagination in the marine shrimp Sicyonia ingentis

The mesendoderm (ME) cells are the two most vegetal blastomeres in the early developing embryo of the marine shrimp Sicyonia ingentis. These two cells enter mitotic arrest for three cycles after the 5th cell cycle (32-cell stage) and ingress into the blastocoel at the 6th cycle (62-cell stage). Circumjacent to the ingressing ME cells are nine presumptive naupliar mesoderm (PNM) cells that exhibit a predictable pattern of spindle orientation into the blastopore, followed by invagination. We examined the role of ME cells and PNM cells in gastrulation using blastomere recombinations and confocal microscopy. Removal of ME progenitors prevented gastrulation. Removal of any other blastomeres, including PNM progenitors, did not interfere with normal invagination. Altered spindle orientations occurred in blastomeres that had direct contact with one of the ME cells; one spindle pole localized to the cytoplasmic region closest to ME cell contact. In recombined embryos, this resulted in an extension of the region of ME-embryo contact. Our results show that ME cells direct the spindle orientations of their adjacent cells and are consistent with a mechanism of oriented cell division being a responsible force for archenteron elongation.     

Fates of the blastomeres of the 16-cell stage Xenopus embryo

The fate of each of the blastomeres in the 16-cell stage Xenopus embryo which had been carefully selected for stereotypic cleavages was determined by intracellularly marking a single blastomere with horseradish peroxidase and identifying the labeled progeny in the tailbud embryo by histochemistry. Each blastomere populated all three primary germ layers. The progeny of each blastomere were distributed characteristically both in phenotype and in location. For example, most organs were populated by the descendants of particular sets of blastomeres. Furthermore, within an organ the progeny of a single blastomere were restricted to defined spatial addresses. This study describes the fates of identified 16-cell stage blastomeres and demonstrates that they are distinct and predictable if embryos are preselected for stereotypic cleavages.     

The effects of altering the position of cleavage planes on the process of localization of developmental potential in ctenophores.

During the transition from the four- to the eight-cell stage in ctenophore embryos, each blastomere produces one daughter cell with the potential to form comb plate cilia and one daughter cell that does not have this potential. If the second cleavage in a two-cell embryo is blocked, at the next cleavage these embryos frequently form four blastomeres which have the configuration of the blastomeres in a normal eight-cell embryo. At this division there is also a segregation of comb plate-forming potential. By compressing a two-cell embryo in a plane perpendicular to the first plane of cleavage it is possible to produce a four-cell blastomere configuration that is identical to that produced following the inhibition of the second cleavage. However, under these circumstances the segregation of comb plate potential does not occur. These results suggest that the appropriate plane of cleavage must take place for a given cleavage cycle, in order for localizations of developmental potential to be properly positioned within blastomeres.     

Muscle lineage cytoplasm can change the developmental expression in epidermal lineage cells of ascidian embryos

Cytoplasm from muscle lineage blastomeres of an ascidian embryo can cause cells of a nonmuscle lineage to produce larval tail muscle acetylcholinesterase. Muscle cytoplasm was partitioned microsurgically into epidermal lineage blastomeres at the eight-cell stage. Posterior half-embryos (the two B3 cells) of Ascidia nigra were obtained first by separating the anterior and posterior blastomere pairs at the four-cell stage. At third cleavage, the two B3 cells divide into an ectodermal cell pair that gives rise solely to epidermal tissues, and a mesodermal-endodermal blastomere pair from which the tail muscle cells are derived. When the ectodermal and mesendodermal blastomere pairs were isolated from one another by microsurgery and reared as partial embryos, only cells originating from the mesendodermal blastomeres produced a histochemical acetylcholinesterase reaction. Immediately after cleavage of the isolated B3 cells into ectodermal and mesendodermal cell pairs, the cleavage furrows could be made to disappear by pressing firmly on the mesendodermal cells with a microneedle. Repeated up and down pressure with the microneedle at a new position across the mesendodermal cells caused furrows to reestablish in the new position, thereby incorporating mesodermal cytoplasm and increasing the size of the ectodermal cells. The cytoplasmically altered ectodermal blastomere pairs, which became detached from the mesendodermal cells by this microsurgical procedure, continued to divide and were reared to “larval” stages. One-third of these epidermal partial larvae produced patches of cells containing acetylcholinesterase. These results lend further support to the theory that choice of particular differentiation pathways (embryonic determination) in ascidian embryos is mediated by segregation of specific egg cytoplasmic determinants.     

Reconstruction of enucleated mouse germinal vesicle oocytes with blastomere nuclei

We have investigated the possibility that mitotic nuclei originating from preimplantation stage embryos and placed in the oocyte cytoplasm can undergo remodelling that allows them to undergo meiosis in the mouse. To address this question, we have used enucleated germinal vesicle (GV) ooplasts as recipients and blastomeres from the 2-, 4- or 8-cell stage as nuclear donors. We employed two methods to obtain ooplasts from GV oocytes: cutting and enucleation. Although efficiency of the reconstruction process was higher after enucleation than after cutting (90% and 70% respectively), the developmental potential of the oocytes was independent of how they had been produced. Nuclei from the 2-, 4-, or 8-cell stage embryos supported maturation in about 35%, 55% and 60% of cases, respectively. The time between nuclear envelope breakdown and the first meiotic division was shortened by up to 5 h in reconstructed oocytes, a period equivalent to the mitotic division of control blastomeres. About one-third of oocytes reconstituted with blastomere nuclei divided symmetrically instead of extruding a polar body; however, in the majority of them metaphase plates were found, suggesting that reconstructed oocytes (cybrids) underwent a meiotic rather than mitotic division. The highest percentage of asymmetric divisions accompanied by metaphase plates was found in cybrids with 8-cell-stage blastomere nuclei, suggesting that the nuclei from this stage appear to conform best to the cytoplasmic environment of GV ooplasts. Our results indicate that the oocyte cytoplasm is capable of remodelling blastomere nuclei, allowing them to follow the path of the meiotic cell cycle.     

Fates of the blastomeres of the 32-cell-stage Xenopus embryo

A detailed fate map of all of the progeny derived from each of the blastomeres of the 32-cell-stage South African clawed frog embryo (Xenopus laevis), which were selected for stereotypic cleavages, is presented. Individual blastomeres were injected with horseradish peroxidase and all of their descendants in the late tailbud embryo (stages 32 to 34) were identified after histochemical processing of serial tissue sections and whole-mount preparations. The progeny of each blastomere were distributed characteristically, both in phenotype and location. Most organs were populated largely by the descendants of particular sets of blastomeres, the progeny of each often being restricted to defined spatial addresses. Thus, the descendants of any one blastomere were distinct and predictable when embryos were preselected for stereotypic cleavages. However, variations among embryos were common and the frequencies with which one may expect organs to contain progeny from any particular blastomere are reported. The differences in the fates of the 16-cell-stage blastomeres and their 32-cell-stage daughter blastomeres are outlined and can be grouped into three general categories. The two daughter cells may give rise to equal numbers of cells in a particular organ, one daughter cell may give rise to many more of the cells in an organ derived from the mother blastomere, or one daughter cell may give rise to all of the progeny in an organ derived from the mother blastomere. Thus, cell fates are segregated during cleavage stages in both symmetric and asymmetric manners, and the lineages exhibit a diversification mode (G. S. Stent, 1985, Philos. Trans R. Soc. London Ser. B 312, 3-19) of cell division.     

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.