Deviation of the blastocyst axis from the first cleavage plane does not affect the quality of mouse postimplantation development

Several researchers have suggested recently that the embryonic-abembryonic (Em-Ab) axis of the mouse blastocyst is orthogonal to the first cleavage plane of the two-cell embryo. To determine the universality of this relationship, we used embryos of two different genotypes, F1 (C57BL/6 x DBA/2) and CD-1. The position of the first cleavage plane in the early blastocyst was determined by labeling a blastomere with the fluorescent lineage tracer DiI (1,1'-dioctadecyl-3,3,3',3'-tetramethylindocarbocyanine perchlorate) at the two-cell stage. Approximately one quarter of the blastocysts from both genotypes possessed an Em-Ab axis that respected the orthogonal relationship with the first cleavage plane. However, the remainder of the blastocysts deviated from the orthogonal relationship. This result indicates that the orthogonal orientation of the Em-Ab axis to the first cleavage plane is not a universal phenomenon. We also tested whether the angular relationship between the Em-Ab axis and first cleavage plane influences postimplantation embryo development. We sorted the blastocysts that had the Em-Ab axis orthogonal to the first cleavage plane from the ones that did not. These two types of blastocysts were transferred separately into surrogates, and fetal development was examined in late gestation. The results revealed that both types of blastocysts produced normal fetuses at a similar frequency. Thus, the relationship of the blastocyst axis to the first cleavage plane does not significantly influence later development.     

Unbiased contribution of the first two blastomeres to mouse blastocyst development

Several recent studies have proposed a model that the organization of the mouse blastocyst is determined by the pattern of early cleavages: the plane of first cleavage divides the two-cell embryo into embryonic (Em) and abembryonic (Ab) halves, while the timing of the second cleavages specifies which blastomere becomes the Em half. This model is still controversial because of conflicting observations in various studies. Here, we investigated the possibility that the difference between mouse strains contributed to the discrepancy of the findings of different experiments regarding the relationship between the first two cleavages and the blastocyst axial pattern. First, we showed by using a lipophilic, fluorescent tracer that the plane of the first cleavage bears no consistent spatial relationship to the Em-Ab axis of the blastocyst regardless of the genotypic background. Secondly, the order of the second cleavage does not correlate with the Em-Ab polarity of the blastocyst. This was demonstrated by tracing the lineage of the early- and later-dividing two-cell stage blastomeres in the whole embryo as well as by comparing the developmental potential of isolated early- and later-dividing blastomeres and chimeras made entirely of early- or later-dividing blastomeres. These results suggest that contrary to recent studies, the differences between the early- and later-dividing blastomeres of the two-cell embryo are not functionally evident and do not define the Em-Ab polarity of the blastocyst. The significance of these findings is discussed in relation to human assisted reproduction and preimplantation genetic diagnosis.     

Analysis of cell lineage in two- and four-cell mouse embryos

Compared with other animals, the embryos of mammals are considered to have a highly regulative mode of development. However, recent studies have provided a strong correlation between the first cleavage plane and the future axis of the blastocyst, but it is still unclear how the early axes of the preimplantation embryo reflect the future body axes that emerge after implantation. We have carried out lineage tracing during mouse embryogenesis using the Cre-loxP system, which allowed us to analyze cell fates over a long period of development. We used a transgenic mouse strain, CAG-CAT-Z as a reporter line. The descendants of the manipulated blastomere heritably express beta-galactosidase. We examined the distribution of descendants of a single blastomere in the 8.5-day embryo after labeling at the two-cell and four-cell stages. The derivatives of one blastomere in the two-cell embryo randomly mix with cells originating from the second blastomere in all cell layers examined. Thus we find cells from different blastomeres intermingled and localized randomly along the body axis. The results of labeling experiments performed in the four-cell stage embryo fall into three categories. In the first, the labeled cells were intermingled with non-labeled cells in a manner similar to that seen after labeling at the two-cell stage. In the second, labeled cells were distributed only in the extra-embryonic ectoderm layers. Finally in the third category, labeled cells were seen only in the embryo proper and the extra-embryonic mesoderm. Manipulated embryos analyzed at the blastocyst stage showed localized distribution of the descendants of a single blastomere. These results suggest that incoherent clonal growth and drastic cell mixing occurs in the early mouse embryo after the blastocyst stage. The first cell specification event, i.e., partitioning cell fate between the inner cell mass and trophectoderm, can occur between the two-cell and four-cell stage, yet the cell fate is not determined.     

Spatial alignment of the mouse blastocyst axis across the first cleavage plane is caused by mechanical constraint rather than developmental bias among blastomeres

The embryonic-abembryonic (Em-Ab) axis of the mouse blastocyst has been found in several studies to align orthogonal to the first cleavage plane, raising the possibility that a developmental prepattern already exists at the two-cell stage. However, it is also possible that such alignment is not due to any developmental disparity between the two-cell stage blastomeres, but rather is caused by an extrinsic mechanical constraint that is conferred by an irregular shape of the zona pellucida (ZP). Here, we conducted a series of experiments to distinguish between these possibilities. We showed that the shape of the ZP at the two-cell stage varied among embryos, ranging from near spherical to ellipsoidal, and that the ZP shape did not change until the blastocyst stage. In those embryos with an ellipsoidal ZP, the Em-Ab axis tended to lie orthogonal to the first cleavage plane, while in those embryos with a near spherical ZP, there was no such relationship. The clonal boundary between the descendants of the two-cell stage blastomeres tended to lie orthogonal to the Em-Ab axis when the rotation of the embryo within the ZP was experimentally prevented, while the control embryos did not exhibit such tendency. These results support the possibility that an apparent correlation between the first cleavage plane and the blastocyst axis can be generated by the mechanical constraint from the ZP but not by a developmental prepattern. Moreover, recent reports indicate that the vegetal blastomere of the four-cell stage embryo that had undergone a specific type of second cleavages is destined to contribute to the abembryonic side of the blastocyst. However, our present study shows that in spite of such specific second cleavages, the vegetal blastomere did not preferentially give rise to the abembryonic side. This result implicates that the lineage of the four-cell stage blastomere is not restricted even when embryos undergo a specific type of second cleavages.     

Morphogenetic tissue movement and the establishment of body plan during development from blastocyst to gastrula in the mouse

In many animal species, the early development of the embryo follows a stereotypic pattern of cell cleavage, lineage allocation and generation of tissue asymmetry leading to delineation of the body plan with three primary embryonic axes. The mammalian embryo has been regarded as an exception and primary body axes of the mouse embryo were thought to develop after implantation. However, recent findings have challenged this view. Asymmetry in the fertilised oocyte, as defined by the position of the second polar body and the sperm entry point, can be correlated with the orientation of the animal-vegetal and the embryonic-abembryonic axes in the preimplantation blastocyst. Studies of the pattern of morphogenetic movement of cells and genetic activity in the peri-implantation embryo suggest that the animal-vegetal axis of the blastocyst might presage the orientation of the anterior-posterior axis of the gastrula. This suggests that the asymmetry of the zygote that is established at fertilisation and early cleavage has a lasting impact on the delineation of body axes during embryogenesis.     

Blastomeres arising from the first cleavage division have distinguishable fates in normal mouse development

Two independent studies have recently suggested similar models in which the embryonic and abembryonic parts of the mouse blastocyst become separated already by the first cleavage division. However, no lineage tracing studies carried out so far on early embryos provide the support for such a hypothesis. Thus, to re-examine the fate of blastomeres of the two-cell mouse embryo, we have undertaken lineage tracing studies using a non-perturbing method. We show that two-cell stage blastomeres have a strong tendency to develop into cells that comprise either the embryonic or the abembryonic parts of the blastocyst. Moreover, the two-cell stage blastomere that is first to divide will preferentially contribute its progeny to the embryonic part. Nevertheless, we find that the blastocyst embryonic-abembryonic axis is not perfectly orthogonal to the first cleavage plane, but often shows some angular displacement from it. Consequently, there is a boundary zone adjacent to the interior margin of the blastocoel that is populated by cells derived from both earlier and later dividing blastomeres. The majority of cells that inhabit this boundary region are, however, derived from the later dividing two-cell stage blastomere that contributes predominantly to the abembryonic part of the blastocyst. Thus, at the two-cell stage it is already possible to predict which cell will contribute a greater proportion of its progeny to the abembryonic part of the blastocyst (region including the blastocyst cavity) and which to the embryonic part (region containing the inner cell mass) that will give rise to the embryo proper.     

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     

Radiosensitivity variation during the cell cycle in pronuclear mouse embryos in vitro

Abstract. The radiosensitivity of pronuclear mouse (B6D2 F1 x ICR) embryos has been measured in vitro as a function of time during the cell cycle. This was done by measuring the dose of X-rays (LD50) required to prevent development of 50% of the pronuclear embryos to the blastocyst stage in 5 days of culture. The LD50 was found to vary from 1 to 2 Gy during the period from G1 to the first cleavage. The cell cycle in the pronuclear embryo was analysed by [³H]thymidine autoradiography. Compared with earlier studies on two-cell mouse embryo radiosensitivity, the pronuclear embryos appear to be more sensitive to radiation than the two-cell embryos. If, however, one considers the radiation sensitivity on a blastomere basis, the pronuclear embryos are not different in their radiation sensitivity from the two-cell embryos. Thus, during the early cleavage stages of mice, radiosensitivity is mainly governed by the content of cells of various cell cycle ages in the embryo.     

The basis and significance of pre-patterning in mammals

The second polar body (Pb) provides an enduring marker of the animal pole of the zygote, thereby revealing that the axis of bilateral symmetry of the early blastocyst is aligned with the zygote's animal-vegetal axis. That this relationship is biologically significant appeared likely when subsequent studies showed that the equator of the blastocyst tended to correspond with the plane of first cleavage. However, this cleavage plane varies both with respect to the position of the second Pb and to the distribution of components of the fertilizing sperm that continue to mark the point where it entered the egg. It also maps too variably on the blastocyst to play a causal role in early patterning. The zygote has been found transiently to exhibit bilateral symmetry before regaining an essentially spherical shape prior to first cleavage. Marking experiments indicate that the plane of bilateral symmetry of the blastocyst is aligned with, and the plane of first cleavage is typically orthogonal to, the zygote's bilateral plane. The bilateral symmetry of the zygote bears no consistent relationship either to the point of sperm entry or to the distribution of the pronuclei, and may therefore be a manifestation of intrinsic organization of the egg. Finally, the two-cell blastomere inheriting the sperm entry point has not been found to differ consistently in fate from the one that does not.     

Mitotic spindles and cleavage planes are oriented randomly in the two-cell mouse embryo

Most experimental embryological studies performed on the early mouse embryo have led to the conclusion that there are no mosaically distributed developmental determinants in the zygote and early embryo (for example see [1-6]). It has been suggested recently that "the cleavage pattern of the early mouse embryo is not random and that the three-dimensional body plan is pre-patterned in the egg" (in [7] for review see [8-10]). Two major spatial cues influencing the pattern of cleavage divisions have been proposed: the site of the second meiotic division [11, 12] and the sperm entry point [13-14], although the latter is controversial [15-17]. An implication of this hypothesis is that the orientations of the first few cleavage divisions are stereotyped. Such a define cleavage pattern, leading to the segregation of developmental determinants, is observed in many species [18]. Recently, it was shown that the first cleavage plane is not predetermined but defined by the topology of the two apposing pronuclei [19]. Because the position of the female pronucleus is dependent upon the site of polar body extrusion and the position of the male pronuclei is dependent upon the sperm entry point [19-20], this observation leaves open the possibility that the sperm may provide some kind of directionality [7]. But, even if asymmetries were set up only after fertilization, a stereotyped cleavage pattern should take place during the following cleavage divisions. Thus, we studied the cleavage pattern of two-cell embryos by videomicroscopy to distinguish between the two hypotheses. After the mitotic spindle formed, its orientation did not change until cleavage. During late metaphase and anaphase, the spindle poles appear to be anchored to the cortex through astral microtubules and PARD6a. Only at the time of cleavage, during late anaphase, do the forming daughter cells change their relative positions. These studies show that cleavage planes are oriented randomly in two-cell embryos. This argues against a prepatterning of the mouse embryo before compaction.     

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.     

Early patterning of cloned mouse embryos contributes to post-implantation development

Several research groups have suggested that the embryonic-abembryonic (Em-Ab) axis in the mouse can be predicted by the first cleavage plane of the early embryo. Currently, it is not known whether this early patterning occurs in cloned embryos produced by nuclear transfer and whether it affects development to term. In this work, the relationship between the first cleavage plane and the Em-Ab axis was determined by the labeling of one blastomere in cloned mouse embryos at the 2-cell stage, followed by ex-vivo tracking until the blastocyst stage. The results demonstrate that approximately half of the cloned blastocysts had an Em-Ab axis perpendicular to the initial cleavage plane of the 2-cell stage. These embryos were classified as "orthogonal" and the remainder as "deviant". Additionally, we report here that cloned embryos were significantly more often orthogonal than their naturally fertilized counterparts and overexpressed Sox2. Orthogonal cloned embryos demonstrated a higher rate of post-implantation embryonic development than deviant embryos, but cloned pups did not all survive. These results reveal that the angular relationship between the Em-Ab axis and the first cleavage plane can influence later development and they support the hypothesis that proper early patterning of mammalian embryos is required after nuclear transfer.     

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.     

Preimplantation mouse embryos synthesize membrane sterols

The total cholesterol content of preimplantation mouse embryos increases approximately threefold (to 1 pmole) during the development of a blastocyst from a fertilized egg. From the two-cell stage onwards embryos are capable of converting [³H]mevalonate into the membrane sterols lanosterol and cholesterol. However, activity of the ratelimiting enzyme in sterol synthesis, hydroxymethylglutaryl coenzyme A reductase, was only measurable in late expanded blastocysts. These estimates of cholesterol content and the amounts of ³H-sterol formed suggest that the preimplantation mouse embryo can synthesize membrane sterols from early cleavage stages onwards. Late compaction and early fluid accumulation (approx. 84 hr post-hCG) are associated with a transition from lanosterol to cholesterol synthesis. The possible relationship between this transition and changes in the properties of embryo membranes which occur at this time is discussed. The results, taken together with previous evidence for phospholipid synthesis in early embryos, demonstrate that the preimplantation mouse embryo is capable of synthesizing major membrane lipids and hence has the potential for assembling cell membranes and modulating their lipid-mediated properties.     

Quantitative changes in cytoskeletal beta- and gamma-actin mRNAs and apparent absence of sarcomeric actin gene transcripts in early mouse embryos

Actin is known to be synthesized both during oogenesis and in cleavage-stage embryos in mice. Cytoskeletal beta-actin appears to be the major component, followed by gamma-actin, but the synthesis of alpha-actin has also been inferred from protein electrophoretic patterns. We have studied the expression of cytoskeletal (beta- and gamma-) and sarcomeric (alpha-cardiac and alpha-skeletal) actin genes at the level of the individual mRNAs in blot hybridization experiments using isoform-specific RNA probes. The results show that there are about 2 x 10(4) beta-actin mRNA molecules in the fully grown oocyte; this number drops to about one-half in the egg and less than one-tenth in the late two-cell embryo but increases rapidly during cleavage to about 3 x 10(5) molecules in the late blastocyst. The amount of gamma-actin mRNA is similar to that of beta-actin in oocytes and eggs but only about 40% as much in late blastocysts, indicating a differential accumulation of these mRNAs during cleavage. The developmental pattern of beta- and gamma-actin mRNA provides a striking example of the transition from maternal to embryonic control that occurs at the two-cell stage and involves the elimination of most or all of the maternal actin mRNA. There was no detectable alpha-cardiac or alpha-skeletal mRNA (i.e., less than 1,000 molecules per embryo) at any stage from oocyte to late blastocyst, suggesting that the sarcomeric actin genes are silent during preimplantation development.     

Comparison of conditioned medium and direct co-culture of human granulosa cells on mouse embryo development

Although numerous investigations have demonstrated the beneficial effects of co-culture system of different somatic cells on in vitro development of embryos, the effects of conditioned-media of co-culture cells have not been well documented. The objective of this study was to compare the effects of human granulosa cells co-culture system and its conditioned medium on the developmental rate of mouse embryos in vitro. Two sets of experiments were undertaken: in the first one 317 mouse one-cell embryos were cultured in human granulosa cell co-culture system (GC). Ham's F10 medium conditioned with granulosa cells (CM) and non-conditioned Ham's F10 for 120 h. In the second experiment. 391 late two-cell embryos were cultured in the 3 fore-mentioned culture treatments for 72 h. Embryos were obtained from NMRI mice. Granulosa cells were collected from patients undergoing an IVF program during oocyte pickup. In the first set of experiments, 23.6, 14.5 and 11.1% of one-cell embryos passed two-cell block and continued growing to 4-cell in GC, CM and HF, respectively. This index in GC was significantly different from two other treatments. Also significantly more embryos reached blastocyst stage in GC compared with two other treatments. The blastocyst rate was not significantly different between CM and HF. In the second set of experiments the proportion of blastocyst stage was significantly higher in CM than that in HF and lower than that in GC. In conclusion, although human granulosa cell-conditioned medium has beneficial effects on mouse embryo development, it was not as effective as co-culture of these cells.     

Stage-specific changes in protein phosphorylation during preimplantation development in the mouse

To gain insight into the role of protein phosphorylation during early mammalian development, seven mouse preimplantation stages were metabolically labeled with radioactive orthophosphate and the radiolabeled proteins identified using gel electrophoresis and autoradiography. The results obtained indicate that there are marked differences in protein phosphorylation patterns between the zygote and two-cell stage and between the morula and blastocyst stage. In addition, there is a compaction-specific change in the phosphorylation profile of three components of Mr 37,000. This compaction-specific change takes place during compaction in the eight-cell embryo; thus, it is the first biochemical change specifically correlated to this important event of early development.