Blastomeres show differential fate changes in 8-cell Xenopus laevis embryos that are rotated 90° before first cleavage

To study the mechanisms of dorsal axis specification, the alteration in dorsal cell fate of cleavage stage blastomeres in axis-respecified Xenopus laevis embryos was investigated. Fertilized eggs were rotated 90° with the sperm entry point up or down with respect to the gravitational field. At the 8-cell stage, blastomeres were injected with the lineage tracers, Texas Red- or FITC-Dextran Amines. The distribution of the labeled progeny was mapped at the tail-bud stages (stages 35–38) and compared with the fate map of an 8-cell embryo raised in a normal orientation. As in the normal embryos, each blastomere in the rotated embryos has a characteristic and predictable cell fate. After 90° rotation the blastomeres in the 8-cell stage embryo roughly switched their position by 90°, but the fate of the blastomeres did not simply show a 90° switch appropriate for their new location. Four types of fate change were observed: (i) the normal fate of the blastomere is conserved with little change; (ii) the normal fate is completely changed and a new fate is adopted according to the blastomere's new position; (iii) the normal fate is completely changed, but the new fate is not appropriate for its new position; and (4) the blastomere partially changed its fate and the new fate is a combination of its original fate and a fate appropriate to its new location. According to the changed fates, the blastomeres that adopt dorsal fates were identified in rotated embryos. This identification of dorsal blastomeres provides basic important information for further study of dorsal signaling in Xenopus embryos.     

Fate map for the 32-cell stage of Xenopus laevis

A complete fate map has been produced for the 32-cell stage of Xenopus laevis. Embryos with a regular cleavage pattern were selected and individual blastomeres were injected with the lineage label fluorescein-dextran-amine (FDA). The spatial location of the clones was deduced from three-dimensional (3D) reconstructions of later stages and the volume of each tissue colonized by labelled cells in each tissue was measured. The results from 107 cases were pooled to give a fate map which shows the fate of each blastomere in terms of tissue types, the composition of each tissue by blastomere, the location of each prospective region on the embryo and the fate of each blastomere in terms of spatial localization. Morphogenetic movements up to stage 10 (early gastrula) were assessed by carrying out a number of orthotopic grafts at blastula and gastrula stages using donor embryos uniformly labelled with FDA. Although there is a regular topographic projection from the 32-cell stage this varies a little between individuals because of variability of positions of cleavage planes and because of short-range cell mixing during gastrulation. The cell mixing means that the topographic projection fails for anteroposterior segments of the dorsal axial structures and it is not possible to include short segments of notochord or neural tube or individual somites on the pregastrulation fate map.     

Evolutionary modification of cell lineage in the direct-developing sea urchin Heliocidaris erythrogramma

The sea urchin Heliocidaris erythrogramma undergoes direct development, bypassing the usual echinoid pluteus larva. We present an analysis of cell lineage in H. erythrogramma as part of a definition of the mechanistic basis for this evolutionary change in developmental mode. Microinjection of fluoresceinated tracer dye and surface marking with vital dye are used to follow larval fates of 2-cell, 8-cell, and 16-cell blastomeres, and to examine axial specification. The animal-vegetal axis and adult dorsoventral axis are basically unmodified in H. erythrogramma. Animal cell fates are very similar to those of typically developing species; however, vegetal cell fates in H. erythrogramma are substantially altered. Radial differences exist among vegetal blastomere fates in the 8-cell embryo: dorsal vegetal blastomeres contribute proportionately more descendants to ectodermal and fewer to mesodermal fates, while ventral vegetal blastomeres have a complementary bias in fates. In addition, vegetal cell fates are more variable than in typical developers. There are no cells in H. erythrogramma with fates comparable to those of the micromeres and macromeres of typically developing echinoids. Instead, all vegetal cells in the 16-cell embryo can contribute progeny to ectoderm and gut. Alterations have thus arisen in cleavage patterns and timing of cell lineage partitioning during the evolution of direct development in H. erythrogramma.     

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.     

Ectopic expression of a homeobox gene changes cell fate in Xenopus embryos in a position-specific manner.

We have injected XIHbox 6 mRNA together with the lineage tracer colloidal gold into individual dorso-anterior blastomeres of the 32-cell stage Xenopus embryo and analyzed their cell fate during embryogenesis. While the developing tadpoles appeared entirely normal, the fate of the progeny of the injected blastomere was altered. In the brain injected cells failed to differentiate terminally, as indicated by a loss of labeled cranial nerves. Differentiation of spinal nerves remained unaffected. Fate change in the CNS occurred at about the time of normal XIHbox 6 protein expression. In addition, progeny of injected blastomeres gained head epidermal fate and lost anterior notochord fate as a result of altered cell migrations during gastrulation. The results show that a homeodomain protein is capable of altering cell fate in a position-specific and cell-autonomous manner in Xenopus embryos. The experimental approach used here should be applicable to other molecules specifying cell fate.     

Cell lineage analysis in ascidian embryos by intracellular injection of a tracer enzyme. III. Up to the tissue restricted stage

Cell lineages during embryogenesis of the ascidian Halocynthia roretzi were analyzed up until the stage where each blastomere was fated to be only a single tissue type (i.e., the tissue restricted stage) by intracellular injection of horseradish peroxidase using the iontophoretic injection method. Initially, the developmental fates of all blastomeres of the 64-cell stage embryo were examined, and thereafter, only the fates of daughter blastomeres of those blastomeres that were not tissue restricted at the 64-cell stage were traced. The developmental fates of blastomeres were highly invariant except for two candidates for "equivalence groups" (J. Kimble, J. Sulston, and J. White (1979). In "Cell Lineage, Stem Cells and Cell Determination," pp. 59-68. Elsevier, Amsterdam/New York), in which cellular interaction is suggested to be involved in the specification of the fates. The right and left a8.25 cells gave rise to the otolith and ocellus, and the right and left b8.17 cells gave rise to the spinal cord and endodermal strand in a complementary manner. No fixed relationship existed between the position of the blastomere and its derivative. Most restrictions of cell fates occurred early in cleavage. The numbers of blastomeres which generated a single type of tissue were 44 at the 64-cell stage and 94 at the 110-cell stage. Eight pairs of blastomeres had not yet become tissue restricted by the 110-cell stage. Almost complete lineages of epidermis, nervous system, muscle, mesenchyme, notochord, and endodermal tissues were described, and a fate map was constructed for the blastula. For certain tissues, the primordial cells occupied two different regions. Supplementary investigations of the lineage of muscle cells were also performed on embryos of another species, Ciona intestinalis.     

Origin and organization of the zebrafish fate map

We have analyzed lineages of cells labeled by intracellular injection of tracer dye during early zebrafish development to learn when cells become allocated to particular fates during development, and how the fate map is organized. The earliest lineage restriction was described previously, and segregates the yolk cell from the blastoderm in the midblastula. After one or two more cell divisions, the lineages of epithelial enveloping layer (EVL) cells become restricted to generate exclusively periderm. Following an additional division in the late blastula, deep layer (DEL) cells generate clones that are restricted to single deep embryonic tissues. The appearance of both the EVL and DEL restrictions could be causally linked to blastoderm morphogenesis during epiboly. A fate map emerges as the DEL cell lineages become restricted in the late blastula. It is similar in organization to that of an amphibian embryo. DEL cells located near the animal pole of the early gastrula give rise to ectodermal fates (including the definitive epidermis). Cells located near the blastoderm margin give rise to mesodermal and endodermal fates. Dorsal cells in the gastrula form dorsal and anterior structures in the embryo, and ventral cells in the gastrula form dorsal, ventral and posterior structures. The exact locations of progenitors of single cell types and of local regions of the embryo cannot be mapped at the stages we examined, because of variable cell rearrangements during gastrulation.     

Investigations into the degree of cell mixing that occurs between the 8-cell stage and the blastocyst stage of mouse development.

This study was designed to assess the degree of cell mixing that occurs during the early development of the mouse embryo, and thus provide information which is important in relation to the current theories of differentiation. Previous studies of this nature have involved either chimeric composites, or have only followed a very limited number of cells in the embryo. Here the products of one of the 4-cell stage blastomeres have been labeled with tritiated thymidine, at a level which allows their descendants to be identified three or four cell divisions later, and recombined with the remaining blastomeres of the same embryo. After fixing and sectioning of the embryos at the blastocyst stage the locations of the labelled cells have been analyzed to assess the degree of clumping that they display. A significant tendency for the products of this one 4-cell stage blastomere to be confined to a single area in the blastocyst is demonstrated. This indicates that there is little marked cell movement during the observation period. The relevance of these results to current knowledge of blastocyst development is discussed.     

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.     

Cell interactions involved in development of the bilaterally symmetrical intestinal valve cells during embryogenesis in Caenorhabditis elegans.

We describe two different cell interactions that appear to be required for the proper development of a pair of bilaterally symmetrical cells in Caenorhabditis elegans called the intestinal valve cells. Previous experiments have shown that at the beginning of the 4-cell stage of embryogenesis, two sister blastomeres called ABa and ABp are equivalent in development potential. We show that cell interactions between ABp and a neighboring 4-cell-stage blastomere called P2 distinguish the fates of ABa and ABp by inducing descendants of ABp to produce the intestinal valve cells, a cell type not made by ABa. A second cell interaction appears to occur later in embryogenesis when two bilaterally symmetrical descendants of ABp, which both have the potential to produce valve cells, contact each other; production of the valve cells subsequently becomes limited to only one of the two descendants. This second interaction does not occur properly if the two symmetrical descendants of ABp are prevented from contacting each other. Thus the development of the intestinal valve cells appears to require both an early cell interaction that establishes a bilaterally symmetrical pattern of cell fate and a later interaction that breaks the symmetrical cell fate pattern by restricting to only one of two cells the ability to produce a pair of valve cells.     

The competence of Xenopus blastomeres to produce neural and retinal progeny is repressed by two endo-mesoderm promoting pathways

Only a subset of cleavage stage blastomeres in the Xenopus embryo is competent to contribute cells to the retina; ventral vegetal blastomeres do not form retina even when provided with neuralizing factors or transplanted to the most retinogenic position of the embryo. These results suggest that endogenous maternal factors in the vegetal region repress the ability of blastomeres to form retina. Herein we provide three lines of evidence that two vegetal-enriched maternal factors (VegT, Vg1), which are known to promote endo-mesodermal fates, negatively regulate which cells are competent to express anterior neural and retinal fates. First, both molecules can repress the ability of dorsal-animal retinogenic blastomeres to form retina, converting the lineage from neural/retinal to non-neural ectodermal and endo-mesodermal fates. Second, reducing the endogenous levels of either factor in dorsal-animal retinogenic blastomeres expands expression of neural/retinal genes and enlarges the retina. The dorsal-animal repression of neural/retinal fates by VegT and Vg1 is likely mediated by Sox17alpha and Derriere but not by XNr1. VegT and Vg1 likely exert their effects on neural/retinal fates through at least partially independent pathways because Notch1 can reverse the effects of VegT and Derriere but not those of Vg1 or XNr1. Third, reduction of endogenous VegT and/or Vg1 in ventral vegetal blastomeres can induce a neural fate, but only allows expression of a retinal fate when both BMP and Wnt signaling pathways are concomitantly repressed.     

Regulation of primary spinal neuron lineages after deletion of a major progenitor

Vertebrate embryos are able to reconstitute the body plan when early blastomeres are deleted, but it is not known whether this is accomplished by cells local to the lesion or by a readjustment of the entire pattern of the embryo. We distinguished between these two possibilities by studying which embryonic cells change primary spinal neuronal fates after deletion of a major spinal cord progenitor. After ablation of the V1.2 blastomere of the 16-cell Xenopus embryo, the spinal cord contained normal numbers of Rohon-Beard neurons and primary motoneurons, indicating that the remaining blastomeres numerically reconstituted these populations. Using lineage-tracing techniques we revealed a global response: 10 out of the 15 remaining blastomeres significantly changed the number of one or both neuronal types they produced. This widespread response indicates that position in the early embryo plays an important role in regulating the production of primary spinal neurons. However, not all cells are influenced solely by position; a vegetal cell transplanted into the position of the deleted V1.2 did not take on the neuronal fate of its new position. Thus, restitution of pattern relies on a combination of positional cues and intrinsic fate restrictions.     

Cellular interactions in early C. elegans embryos

In normal development both the anterior and posterior blastomeres in a 2-cell C. elegans embryo produce some descendants that become muscles. We show that cellular interactions appear to be necessary in order for the anterior blastomere to produce these muscles. The anterior blastomere does not produce any muscle descendants after either the posterior blastomere or one of the daughters of the posterior blastomere is removed from the egg. Moreover, we demonstrate that a daughter of the anterior blastomere that normally does not produce muscles appears capable of generating muscles when interchanged with its sister, a cell that normally does produce muscles. Embryos develop normally after these blastomeres are interchanged, suggesting that cellular interactions play a major role in determining the fates of some cells in early embryogenesis.     

Cell lineage and determination of cell fate in ascidian embryos

A detailed cell lineage of ascidian embryos has been available since the turn of the century. This cell lineage was deduced from the segregation of pigmented egg cytoplasmic regions into particular blastomeres during embryogenesis. The invariant nature of the cell lineage, the segregation of specific egg cytoplasmic regions into particular blastomeres, and the autonomous development of most embryonic cells suggests that cell fate is determined primarily by cytoplasmic determinants. Modern studies have provided strong evidence for the existence of cytoplasmic determinants, especially in the primary muscle cells, yet the molecular identity, localization, and mode of action of these factors are still a mystery. Recent revisions of the classic cell lineage and demonstrations of the lack of developmental autonomy in certain embryonic cells suggest that induction may also be an important mechanism for the determination of cell fate in ascidians. There is strong evidence for the induction of neural tissue and indirect evidence for inductive interactions in the development of the secondary muscle cells. In contrast to the long-accepted dogma, specification of cell fate in ascidians appears to be established by a combination of cytoplasmic determinants and inductive cell interactions.     

Blastomere Explants to Test for Cell Fate Commitment During Embryonic Development

Fate maps, constructed from lineage tracing all of the cells of an embryo, reveal which tissues descend from each cell of the embryo. Although fate maps are very useful for identifying the precursors of an organ and for elucidating the developmental path by which the descendant cells populate that organ in the normal embryo, they do not illustrate the full developmental potential of a precursor cell or identify the mechanisms by which its fate is determined. To test for cell fate commitment, one compares a cell''s normal repertoire of descendants in the intact embryo (the fate map) with those expressed after an experimental manipulation. Is the cell''s fate fixed (committed) regardless of the surrounding cellular environment, or is it influenced by external factors provided by its neighbors? Using the comprehensive fate maps of the Xenopus embryo, we describe how to identify, isolate and culture single cleavage stage precursors, called blastomeres. This approach allows one to assess whether these early cells are committed to the fate they acquire in their normal environment in the intact embryo, require interactions with their neighboring cells, or can be influenced to express alternate fates if exposed to other types of signals.     

Gastrulation in the nematode Caenorhabditis elegans

Gastrulation in Caenorhabditis elegans has been described by following the movements of individual nuclei in living embryos by Nomarski microscopy. Gastrulation starts in the 26-cell stage when the two gut precursors, Ea and Ep, move into the blastocoele. The migration of Ea and Ep does not depend on interactions with specific neighboring cells and appears to rely on the earlier fate specification of the E lineage. In particular, the long cell cycle length of Ea and Ep appears important for gastrulation. Later in embryogenesis, the precursors to the germline, muscle and pharynx join the E descendants in the interior. As in other organisms, the movement of gastrulation permit novel cell contacts that are important for the specification of certain cell fates.     

Is a mosaic embryo also a mosaic of communication compartments?

We have studied the pathways of cell communication in embryos of the mollusc Lymnaea stagnalis in which the developmental fate of a cell or a group of cells is known from cell lineage studies. We iontophoretically injected Lucifer Yellow CH and followed the spread of fluorescence between cells interconnected via gap junctions. In early stages all blastomeres appear to be dye-coupled, but later on communication is restricted within compartments. The pattern of cell communication corresponds with the development of compartments with specific cell fates. Dye-spread is limited by communication boundaries which completely or mostly prevent the passage of dye to adjacent compartments with different developmental fates. These boundaries appear progressively during development. Our results suggest that, during the development of Lymnaea, the progressive changes in the pattern of dye spread correspond with the progressive restrictions of the developmental fates of individual cells or groups of cells. We conclude that changes in the pattern of cell communication and in the appearance of communication compartments are not exclusive features of regulative embryos.