Determinative development in the polyclad turbellarian,Hoploplana inquilina

Summary

Blastomere deletion experiments at the two- and four-cell stages were carried out on the embryo of the polyclad turbellarian Hoploplana inquilina to further examine the relationship between spiral cleavage and early embryonic determination in primitive spiralians. Deletion of one cell at the two-cell stage resulted in “half” larvae that were abnormal in body shape, lobe development, and behavior. Deletion of one cell at the four-cell stage produced less abnormal “three-quarter” larvae which were still underdeveloped in one of the quadrants. A 3:1 ratio of one-eyed to two-eyed larvae implies that deletion of any one of three blastomeres results in loss of an eye, with two constituting the eye lineage and the third controlling the development of two eyes. The results demonstrate that the polyclad embryo is determined early in development, though significant cell interactions occur during cleavage, and suggest that determinative development and quartet spiral cleavage are always associated and probably represent a primitive, strongly conserved evolutionary condition.     

Four-cell stage mouse blastomeres have different developmental properties

Blastomeres of the early mouse embryo are thought to be equivalent in their developmental properties at least until the eight-cell stage. However, the experiments that have led to this conclusion could not have taken into account either the spatial origin of individual blastomeres or the spatial allocation and fate of their progeny. We have therefore readdressed this issue having defined cell lineages in mouse embryos undergoing different patterns of cleavage in their second division cycle. This has enabled us to identify a major group of embryos in which we can predict not only the spatial origin of each given four-cell blastomeres, but also which region of the blastocyst is most likely to be occupied by its progeny. We show that a pattern of second cleavage divisions in which a meridional division is followed by one that is equatorial or oblique allows us to identify blastomeres that differ in their fate and in their developmental properties both from each other and from their cousins. We find that one of these four-cell stage blastomeres that inherits some vegetal membrane marked in the previous cleavage cycle tends to contribute to mural trophectoderm. The progeny of its sister tend to donate cells to part of the ICM lining the blastocyst cavity and its associated trophectoderm. Chimaeras made entirely of these equatorially or obliquely derived blastomeres show developmental abnormalities in both late preimplantation and early postimplantation development. By contrast, chimaeras made from four-cell stage blastomeres from early meridional divisions develop normally. The developmental defects of chimaeras made from the most vegetal blastomeres that result from later second cleavages are the most severe and following transplantation into foster mothers they fail to develop to term. However, when such individual four-cell blastomeres are surrounded by blastomeres from random positions, they are able to contribute to all embryonic lineages. In conclusion, this study shows that while all four-cell blastomeres can have full developmental potential, they differ in their individual developmental properties according to their origin in the embryo from as early as the four-cell stage.     

Influence of early fate decisions at the two-cell stage on the derivation of mouse embryonic stem cell lines

The first event of differentiation in mammalian embryogenesis is the segregation of the inner cell mass and trophectoderm lineages in the blastocyst. Cellular and molecular events related to this process are still a controversial issue. During the years it was thought that first allocation of blastomeres before the blastocyst stage was done in the late eight-cell stage with the formation of inner and outer cells. Lately, many studies have pointed out that individual blastomeres at the four-cell stage differ in their developmental properties according to their position within the embryo. In this report, we wanted to elucidate whether these early decisions influence the production of mouse embryonic stem cell lines, so that a selective isolation of blastomeres at the four-cell stage to derive the lines could improve the efficiency of the derivation process. Results from blastomere tracking experiments support the idea of a different developmental potential of blastomeres within the four-cell stage embryo. However, we also show a high plasticity in the developmental pattern of blastomeres once isolated from the embryo, thus making all four-cell stage blastomeres equally competent to derive ESC lines.     

Regulation and the modification of axial properties in partial embryos of the nemertean, Cerebratulus lacteus

 Embryos acquire axial properties (e.g., the animal-vegetal, dorsoventral and bilateral axes) at various times over the course of their normal developmental programs. In the spiral-cleaving nemertean, Cerebratulus lacteus, lineage tracing studies have shown that the dorsoventral axis is set up prior to the first cleavage division; however, blastomeres isolated at the two-cell stage will regulate to form apparently perfect, miniature pilidium larvae. We have examined the nature of axial specification in this organism by determining whether partial embryos retain the original embryonic/larval axial properties of the intact embryo, or whether new axial relationships are generated as a consequence of the regulatory process. Single blastomeres in two-cell stage embryos were injected with lineage tracer, and were then bisected along the second cleavage plane at the four-cell stage. Thus, the relationship between the plane of the first cleavage division and various developmental axes could be followed throughout development in the ”half-embryos”. While some embryo fragments appear to retain their original animal-vegetal and dorsoventral axes, many fragments generate novel axial properties. These results indicate that axial properties set up and used during normal development in C. lacteus can be completely reorganized during the course of regulation. While certain embryonic axes, such as the animal-vegetal and dorsoventral axes, appear to be set up prior to first cleavage, these axes and associated cell fates are not irreversibly fixed until later stages of development in normal intact embryos. In C. lacteus, the process whereby these properties are ultimately determined is apparently controlled by complex sets of cell-cell interactions. Received: 11 October 1996 / Accepted: 21 February 1997     

Laser Fusion of Mouse Embryonic Cells and Intra-Embryonic Fusion of Blastomeres without Affecting the Embryo Integrity

Manipulation with early mammalian embryos is the one of the most important approach to study preimplantation development. Artificial cell fusion is a research tool for various biotechnological experiments. However, the existing methods have various disadvantages, first of them impossibility to fuse selected cells within multicellular structures like mammalian preimplantation embryos. In our experiments we have successfully used high repetition rate picosecond near infrared laser beam for fusion of pairs of oocytes and oocytes with blastomeres. Fused cells looked morphologically normal and keep their ability for further divisions in vitro. We also fused two or three blastomeres inside four-cell mouse embryos. The presence of one, two or three nuclei in different blastomeres of the same early preimplantation mouse embryo was confirmed under UV-light after staining of DNA with the vital dye Hoechst-33342. The most of established embryos demonstrated high viability and developed in vitro to the blastocyst stage. We demonstrated for the first time the use of laser beam for the fusion of various embryonic cells of different size and of two or three blastomeres inside of four-cell mouse embryos without affecting the embryo’s integrity and viability. These embryos with blastomeres of various ploidy maybe unique model for numerous purposes. Thus, we propose laser optical manipulation as a new tool for investigation of fundamental mechanisms of mammalian development.     

Prospective fate of early blastomeres in Hydractinia echinata (Cnidaria,Hydrozoa)

Summary Blastomeres of two-cell, four-cell, and eight-cell embryos of Hydractinia echinata were injected with horseradish-peroxidase (HRP) or fluorescein isothiocyanate (FITC)-dextran. The fate of the descendants of the injected blastomeres was followed until the planula larva had developed. The results obtained after HRP or FITC-dextran injection were essentially the same. Blastomeres are equivalent up to the four-cell stage, i.e. half-blastomeres produce half of the ectoderm of the planula larva and quarter-blastomeres give rise to one quarter of the larval ectoderm. During normal embryogenesis, the larval anterior-posterior axis corresponds to the animal-vegetal axis of the zygote. Thus, the labelled areas of larvae consisting of the progeny of injected half or quarter blastomeres normally stretch along the larval anterior-posterior axis. Normally, material giving rise to anterior or posterior larval parts, respectively, is separated at the third cleavage. Irrespective of the type of experiment, the progeny of injected blastomeres always contributed to endoderm formation, i.e. in larvae resulting from injected embryos the endoderm was more or less uniformly labelled. Application of vital stains locally to the exterior of zygotes and following these markers through first and second cleavage, produced evidence that in the vast majority of cases, the second cleavage is meridional. Offprint requests to: A. Schlawny     

Significance of the polar lobe for the determination of dorsoventral polarity in Dentalium vulgare (da Costa)

The development of dorsoventral polarity in Dentalium dentale has been analyzed after inhibiting first polar lobe formation with cytochalasin B and bisecting the egg into two equal parts at an early trefoil stage. Cleavage pattern and morphogenesis have been studied in both in vivo and permanent cytological preparations. After bisecting the egg, each blastomere may fuse with its adhering polar lobe half and subsequently behave as a CD blastomere. The polar lobe substance may induce both halves to develop an apical tuft and probably also a posttrochal region. Cytochalasin B embryos which pass through an equal first cleavage form a four-cell stage in which the two D blastomeres are situated opposite or adjacent to each other (CDCD or CCDD embryos, respectively). During further development the larvae show a duplication of lobe-dependent structures. It is concluded that dorsoventral polarity originates epigenetically by fusion of the polar lobe with one of the first two blastomeres and is not preformed in the uncleaved egg.     

MEX-3 interacting proteins link cell polarity to asymmetric gene expression in Caenorhabditis elegans

The KH domain protein MEX-3 is central to the temporal and spatial control of PAL-1 expression in the C. elegans early embryo. PAL-1 is a Caudal-like homeodomain protein that is required to specify the fate of posterior blastomeres. While pal-1 mRNA is present throughout the oocyte and early embryo, PAL-1 protein is expressed only in posterior blastomeres, starting at the four-cell stage. To better understand how PAL-1 expression is regulated temporally and spatially, we have identified MEX-3 interacting proteins (MIPs) and characterized in detail two that are required for the patterning of PAL-1 expression. RNA interference of MEX-6, a CCCH zinc-finger protein, or SPN-4, an RNA recognition motif protein, causes PAL-1 to be expressed in all four blastomeres starting at the four-cell stage. Genetic analysis of the interactions between these mip genes and the par genes, which provide polarity information in the early embryo, defines convergent genetic pathways that regulate MEX-3 stability and activity to control the spatial pattern of PAL-1 expression. These experiments suggest that par-1 and par-4 affect distinct processes. par-1 is required for many aspects of embryonic polarity, including the restriction of MEX-3 and MEX-6 activity to the anterior blastomeres. We find that PAL-1 is not expressed in par-1 mutants, because MEX-3 and MEX-6 remain active in the posterior blastomeres. The role of par-4 is less well understood. Our analysis suggests that par-4 is required to inactivate MEX-3 at the four-cell stage. Thus, PAL-1 is not expressed in par-4 mutants because MEX-3 remains active in all blastomeres. We propose that MEX-6 and SPN-4 act with MEX-3 to translate the temporal and spatial information provided by the early acting par genes into the asymmetric expression of the cell fate determinant PAL-1.     

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.     

Morphogenetic consequences of partial removal of blastomere cytoplasm during early embryonic development of the loach, Misgurnus fossilis L

The development of loach embryos is successfully regulated (normalized) after partial removal of the cytoplasm from one blastomere at the two- or four-cell stage or complete removal of one or two blastomeres at the stage of 8-16 cells. Using time-lapse video imaging and morphometric analysis, it has been shown that this regulation is a two-stage process. At the first stage, the ratio between the volumes of the blastodisk and yolk sac is rapidly (within one or two cell cycles) restored almost to the initial level; at the second stage, morphogenesis of the embryo is modified according to its new structural features acquired after the operation. After several rounds of cytokinesis, the cytoplasm remaining in the operated blastomere fuses with the marginal yolk syncytium (periblast),which at the blastula stage forms a distinct extension at the operation site. This extension marks the site of embryonic shield formation. The results of morphometric analysis show that restoration of the initial blastoderm volume in operated embryos leads to a reduction of active tension at the blastoderm--yolk boundary and an increase in the ratio of blastoderm surface to its volume at the moment of epiboly initiation. As a result, the convergence of blastoderm cells to the operation site and the embryonic shield formation begin at a lesser degree of epiboly, compared to the control.     

Participation of the paternal genome is not required before the eight-cell stage for full-term development of mouse embryos

Differential expression of the paternal and maternal genomes during mouse embryonic development is considered a reason for both genomes being required for development to term. Extending previous studies performed on two-cell embryos, we show here that diploid embryos reconstituted at the four-cell stage from uniparental haploid blastomeres can produce living offspring. This result shows that for normal development to occur, a paternal genome does not need to be associated with a maternal genome within the same nucleus before the eight-cell stage.     

Morphogenetic consequences of partial removal of blastomere cytoplasm during early embryonic development of the loach, Misgurnus fossilis L.

The development of loach embryos is successfully regulated (normalized) after partial removal of the cytoplasm from one blastomere at the two- or four-cell stage or complete removal of one or two blastomeres at the stage of 8?C16 cells. Using time-lapse video imaging and morphometric analysis, it has been shown that this regulation is a two-stage process. At the first stage, the ratio between the volumes of the blastodisk and yolk sac is rapidly (within one or two cell cycles) restored almost to the initial level; at the second stage, morphogenesis of the embryo is modified according to its new structural features acquired after the operation. After several rounds of cytokinesis, the cytoplasm remaining in the operated blastomere fuses with the marginal yolk syncytium (periblast), which at the blastula stage forms a distinct extension at the operation site. This extension marks the site of embryonic shield formation. The results of morphometric analysis show that restoration of the initial blastoderm volume in operated embryos leads to a reduction of active tension at the blastoderm-yolk boundary and an increase in the ratio of blastoderm surface to its volume at the moment of epiboly initiation. As a result, the convergence of blastoderm cells to the operation site and the embryonic shield formation begin at a lesser degree of epiboly, compared to the control.     

Origin of body axes in the mouse embryo

How and at what stage of development are the axes of the body determined? The left-right axis of the mouse embryo is generated de novo at embryonic day (E) 8.0 in a manner dependent on pre-existing positional cues. The anterior-posterior (A-P) axis becomes apparent earlier when distally located visceral endoderm migrates toward the future anterior side at E5.5. The direction of this migration is predetermined by asymmetric expression of Lefty1 and Cerl1(Cerberus-like 1). Asymmetric expression of Lefty1 takes place even earlier, in the primitive endoderm of the implanting blastocyst, pushing back the origin of the A-P axis to the peri-implantation stage. Although its functional significance remains to be seen, studies on how this molecular asymmetry emerges may provide insight into the origin of A-P polarity. The first cell fate decision occurs by the morula stage. Although blastomeres at the two-cell or four-cell stage may have biased fates, it is currently unknown whether this bias has any causal relation to later fate.     

Experimental evidence for the origins of determinative development in the polyclad turbellarians

Cell-deletion experiments were carried out on the embryo of the polyclad turbellarian Hoploplana inquilina to examine further the nature of development in primitive spiralians. The polyclads are of particular interest because they provide a link between the regulative development of acoels and the determinative development of annelids and molluscs. Single blastomeres were deleted at the two- and four-cell stages by puncture through the eggshell membrane with tungsten needles. All deletions resulted in abnormal larvae with consistent characteristics representing half or three-quarter Müller's larvae. The number of larval eyes was a particularly useful character in revealing mosaicism. This study establishes the polyclad embryo as determinative, but with important cell interactions also occurring during early development, and provides evidence that mosaicism became associated with spiral cleavage in the quartet form during the evolution of the Turbellaria.     

Developmental potential of isolated blastomeres from early murine embryos

Experiments were designed to evaluate the effect of blastomere separation on blastocoele formation and development of viable fetuses. Two-cell and four-cell murine embryos were dissociated into individual blastomeres and cultured to the blastocyst stage. For embryos of both stages, zona removal and blastomere separation reduced (P<0.05) the number of viable embryos at the onset of culture and reduced (P<0.01) the frequency of continuation of development of blastomeres to the blastocyst stage. Attempts to repeatedly split two-cell stage embryos decreased in vitro development to blastocysts. The number of cells in two-cell embryos that were cultured to blastocyst was not different for control (64.8 +/- 11.5) or for two-cell embryos cultured without the zona pellucida (60.9 +/- 10.1) but was reduced (P<0.01) for one-half embryos that were cultured to blastocysts (35.6 +/- 10.6). The cell number of blastocysts obtained from dissociated four-cell (1/4) embryos (17.4 +/- 1.4) was similarly reduced (P<0.01). In vivo development was assessed after cultured embryos were transferred to the uteri of day 3 pseudopregnant females. Zona free intact embryos (2/36, 6%) and zona free half embryos (7/36; 19%) developed less frequently (P<0.05) than intact controls (45/100). Noncultured morula briefly exposed to pronase to thin the zona had similar impaired development. Embryos with thinned zona or no zona developed less frequently (21/82, 2/72 respectively, P<0.05) than nonpronase-treated controls (50/83).     

Deuterostome evolution: early development in the enteropneust hemichordate, Ptychodera flava

SUMMARY Molecular and morphological comparisons indicate that the Echinodermata and Hemichordata represent closely related sister‐phyla within the Deuterostomia. Much less is known about the development of the hemichordates compared to other deuterostomes. For the first time, cell lineage analyses have been carried out for an indirect‐developing representative of the enteropneust hemichordates, Pty‐ chodera flava. Single blastomeres were iontophoretically labeled with DiI at the 2‐ through 16‐cell stages, and their fates followed through development to the tornaria larval stage. The early cleavage pattern of P. flava is similar to that of the direct‐developing hemichordate, Saccoglossus kowalevskii, as well as that displayed by indirect‐developing echinoids. The 16‐celled embryo contains eight animal “mesomeres,” four slightly larger “macromeres,” and four somewhat smaller vegetal “micromeres.” The first cleavage plane was not found to bear one specific relationship relative to the larval dorsoventral axis. Although individual blastomeres generate discrete clones of cells, the appearance and exact locations of these clones are variable with respect to the embryonic dorsoventral and bilateral axes. The eight animal mesomeres generate anterior (animal) ectoderm of the larva, which includes the apical organ; however, contributions to the apical organ were found to be variable as only a subset of the animal blastomeres end up contributing to its formation and this varies from embryo to embryo. The macromeres generate posterior larval ectoderm, and the vegetal micromeres form all the internal, endomesodermal tissues. These blastomere contributions are similar to those found during development of the only other hemichordate studied, the direct‐developing enteropneust, S. kowalevskii. Finally, isolated blastomeres prepared at either the two‐ or the four‐cell stage are capable of forming normal‐appearing, miniature tornaria larvae. These findings indicate that the fates of these cells and embryonic dorsoventral axial properties are not committed at these early stages of development. Comparisons with the developmental programs of other deuterostome phyla allow one to speculate on the conservation of some key developmental events/mechanisms and propose basal character states shared by the ancestor of echinoderms and hemichordates.     

Determination of dorso-ventral axis in early embryos of the sea urchin, Hemicentrotus pulcherrimus

To elucidate a relationship between early cleavage planes and dorso-ventral (DV)-axis of sea urchin embryos, a fluorescent dye, Lucifer Yellow CH, was iontophoretically introduced into one blastomere at the 2-cell stage, and the location of the progeny cells was determined in the half-labeled prism larvae by examining the embryos from the animal pole. The boundary plane which divides the embryonic tissue into the labeled and nonlabeled parts was (1) coincident with, (2) perpendicular to, or (3) obliquely crossing the larval plane of bilateral symmetry. The oblique boundaries took only two angles mutually symmetrical with regard to the DV-axis of embryos. Combining these labeling patterns, the tissue of prism larvae could be divided into 8 sectors around the animal-vegetal axis. When the 2-cell stage embryos with different diameters of sister blastomeres were labeled with the dye, one end of the boundary plane was again found at one of the 8 boundary points noticed in equally cleaved embryos, while the other was observed to fall in the middle of a sector. These results indicate that the DV-axis of the embryo is established according to the spatial arrangement of blastomeres during the 5-6th cleavage stages when blastomeres align in 8 rows in meridional direction. It was also suggested that intercellular communication takes part in the determination of the fate of individual founder blastomeres during the two subsequent cleavages, i.e., 7-8th cleavage stages.     

Establishment of the dorsoventral axis in nemertean embryos: Evolutionary considerations of spiralian development

The Nemertea represent one of a number of invertebrate phyla that display a highly conserved pattern of cell division known as spiral cleavage. The fates of the early blastomeres are known for representatives of some spiralian phyla (i.e., molluscs and annelids) and in these species there appears to be a high degree of conservation in the ultimate fates of particular embryonic cells. The first two cleavage planes bear an invariant relationship to the symmetry properties of the future larval and adult body plan. To investigate whether these properties of spiralian embryo-genesis are shared (conserved) amongst members of other spiralian phyla, individual blastomeres in two- and four-cell embryos of the nemertean, Nemertopsis bivittata, were microinjected with bi-otinylated dextran lineage tracers. N. bivittata is a direct-developing hoplonemertean that forms a nonfeeding larva. When individual blastomeres are injected at the two-cell stage, two sets of complementary labeling patterns (a total of four different patterns) were observed in the ectoderm of the larvae. When cells were injected at the four-cell stage, four different patterns were observed that represented subsets of the four patterns observed in the previous experiment. Unlike the case in the annelids and molluscs, in which the first cleavage plane bears a strict 45° angular relationship to the future dorsoventral axis, the first cleavage plane in N. bivittata can bear one of two different relationships relative to the larval/adult dorsoventral axis. In half the cases examined, the first cleavage plane corresponded roughly to the plane of bilateral symmetry, and in the rest, it lay along a frontal plane. A similar result was observed for the embryos of the indirect-developing heteronemertean, Cerebratutus lacteus. These results indicate that the fates of the four cell quadrants in nemerteans are not directly homologous to those in other spira-lians, such as the annelids and molluscs. For instance, no single cell quadrant appears to contribute a greater share to the formation of ectoderm, as is the case in the formation of the post-trochal region by the D-cell quadrant in annelids and mol-luscs. Rather, two adjacent cell quadrants contribute nearly equally to the formation of dorsal or ventral ectoderm in the larvae. Possible explanations for the determination of dorsoventrality in nemerte-ans, as well as implications of these findings regarding the evolution of spiralian development, are discussed. © 1994 Wiley-Liss, Inc.     

Spatial arrangement of individual 4-cell stage blastomeres and the order in which they are generated correlate with blastocyst pattern in the mouse embryo

In the unperturbed development of the mouse embryo one of the 2-cell blastomeres tends to contribute its progeny predominantly to the embryonic and the other to the abembryonic part of the blastocyst. However, a significant minority of embryos (20-30%) do not show this correlation. In this study, we have used non-invasive lineage tracing to determine whether development of blastocyst pattern shows any correlation with the orientation and order of the second cleavage divisions that result in specific positioning of blastomeres at the 4-cell stage. Although the orientation and order of the second cleavages are not predetermined, in the great majority (80%) of embryos the spatial arrangement of 4-cell blastomeres is consistent with one of the second cleavages occurring meridionally and the other equatorially or obliquely with respect to the polar body. In such cleaving embryos, one of the 2-cell stage blastomeres tends to contribute to embryonic while the other contributes predominantly to abembryonic part of the blastocyst. Thus, in these embryos the outcome of the first cleavage tends to correlate with the orientation of the blastocyst embryonic-abembryonic axis. However, the order of blastomere divisions predicts a specific polarity for this axis only when the earlier 2-cell blastomere to divide does so meridionally. In contrast to the above two groups, in those embryos in which both second cleavage divisions occur in a similar orientation, either meridionally or equatorially, we do not observe any tendency for the 2-cell blastomeres to contribute to specific blastocyst parts. We find that all these groups of embryos develop to term with similar success, with the exception of those in which both second cleavage divisions occur equatorially whose development can be compromised. We conclude that the orientations and order of the second cleavages are not predetermined; they correlate with the development of blastocyst patterning; and that the majority, but not all, of these cleavage patterns allow equally successful development.     

Cleavage in vivo and in culture in the Dasyurid marsupial Antechinus stuartii (macleay)

Cleavage in the brown marsupial mouse, Antechinus stuartii, from the zygote to the unilaminar blastocyst, was observed in vivo and in culture and in sections of embryos. The first three divisions were meridional and passed from the yolk pole to the opposite pole. Deutoplasmolysis, resulting in a distinct yolk mass, occurred during the first two divisions. Prior to the third and fourth divisions, the blastomeres elongated and flattened against the zona pellucida. The fourth division was latitudinal and resulted in two histologically distinct rings of eight blastomeres which were at first rounded and then became flattened against the zona. Further divisions and flattening of the blastomeres resulted in a complete unilaminar blastocyst by the time the blastocyst numbered 22 to 30 cells. Some expansion, causing compression of the zona and mucoid layers, occurred before completion of the blastocyst, but most expansion occurred once the blastocyst was complete. No histological differences could be detected between the blastomeres at this stage. Embryos were successfully cultured from the zygote to the rounded four-cell stage and from the flattened four-cell stage to the completed unilaminar blastocyst of around 32 cells. Total estimated cleavage times were slower in culture than in vivo, but the relative lengths of time for each division were approximately the same.