Centrifugal elutriation of large fragile cells: isolation of RNA from fixed embryonic blastomeres.

In order to analyze the RNA populations present in different cells of very early embryos, we have developed a protocol to purify these large blastomeres using counterflow centrifugal elutriation (CCE). This procedure employs ethanol fixation to stabilize the cells against shear forces encountered during CCE. Using this method, we fractionated the three different blastomere types of the 16-cell sea urchin embryo, the micromeres, mesomeres, and macromeres, achieving 96, 94, and 96% mean purities, respectively. We show here that intact RNA is recovered with equal efficiency from each blastomere preparation. Using this method, we have identified several RNAs that are distributed non-uniformly among these cells.     

Histone modifications accompanying the onset of developmental commitment

In the sea urchin, Strongylocentrotus purpuratus, three cell types comprise the 16-cell stage embryo: micromeres, macromeres, and mesomeres. We have analyzed these three cell types for nuclear proteins that were synthesized during the earliest stages of embryonic development. The most striking differences in composition of newly synthesized proteins were found between the micromeres, which are the most committed cell type, and the macromeres and mesomeres. First, the micromeres lacked triply modified forms of histone H3; the levels of doubly modified forms of H3 were also greatly reduced. In contrast, micromeres were enriched in a band which migrated at the position of unmodified, unacetylated, histone H3 protein. Second, the overall distribution of H2A histone variants differed among the three cell types. Compared with macromeres and mesomeres, micromeres had a higher ratio of alpha-stage to cleavage-stage (CS) histone H2A; the micromere nuclei were depleted by 50 and 35%, respectively, in embryonically synthesized histone CS-H2A. Third, micromeres displayed different profiles of H1 histones. (a) They contained a cleavage-stage H1 histone which migrated faster than that of macromeres and mesomeres. This protein displays the electrophoretic behavior expected for a protein with reduced levels of posttranslational covalent modification. (b) Micromeres also had reduced levels of an H1 histone (designated H1 alpha a) band found in the alpha-H1 region of macromeres and mesomeres. These changes in chromatin modification correlate with the degree of commitment of cells in the developing embryo; they may reflect differing activities of the chromatin modifying enzymes in the various cell types at the 16-cell stage. Thus, the newly synthesized chromatin proteins of the individual blastomere types already differ in the developing sea urchin by the 16-cell stage. We suggest that variations in histone subtypes and in the levels of activity of chromatin modifying enzymes, e.g., acetylases and phosphorylases, could be involved in commitment and differentiation of different cell types.     

Cleavage and differentiation in the sea urchin embryo transplantation studies of micromeres

Summary Micromeres isolated from the 16-cell stage were implanted on mesomeres or macromeres from the same larva. The process of coalescence and the cleavage pattern of the transplanted micromeres were studied by means of light and electron microscopy.The transplanted micromere shows the same cleavage pattern as the micromerein situ. A close contact is established between the micromere and the host cell and cytoplasmic bridges are found between the cells.The micromere is dependent on its adjoining blastomere(s) and the rate of cleavage is slowed down when the micromere is isolated. Macromeres and mesomeres are not subjected to a similar change in rate of cleavage when isolated from the rest of the embryo.The ratio mitochondria/yolk in micromeres is different from that observed in macro- or mesomeres and the possible consequences of this fact are discussed.     

Synthesis of RNA by dissociated cells of the sea urchin embryo

The incorporation of radioactive uridine into RNA by micromeres, mesomeres and macromeres of sea urchin embryos was studied, employing methods for separating the cell types in pure suspension. At the 16-cell stage, the 3-cell types, on a per genome basis, synthesized RNA at approximately the same rate although on a per mg protein basis the micromere-RNA synthetic rate was considerably higher than either mesomeres or macromeres. At the 32-cell stage, incorporation of radioactive uridine by micromeres decreased relative to mesomeres and macromeres. It was demonstrated that radioactive uridine could not be effectively washed or diluted out of the cells of 16-cell stage embryos. Experiments on reaggregating cells did not detect any transfer or transport of radioactivity from micromeres to the other cells. Possible explanations for these findings versus the disparate results of previous investigators were presented.     

Range and stability of cell fate determination in isolated sea urchin blastomeres

We have examined the developmental potential of blastomeres isolated from either the animal (mesomeres) or vegetal (macromeres-micromeres) half of 16-cell embryos of the sea urchin Lytechinus pictus. We have also examined the effects of two known vegetalizing agents on the development of isolated mesomeres; LiCl treatment and combination with micromeres, the small blastomeres found at the vegetal pole of the 16-cell embryo. The markers for differentiation used were both morphological (invaginations, spicules and pigment cells) and molecular (gut-specific alkaline phosphatase activity, and monoclonal antibodies against antigens specific for gut and oral ectoderm). Embryoids derived from isolated mesomeres expressed markers characteristic of vegetal differentiation only at very low levels. They did express an antigen characteristic of animal development, the oral ectoderm antigen, but with an altered pattern. Isolated macromere-micromere pairs expressed all markers characteristic of vegetal development, but did not express the marker characteristic of animal development. Increasing concentrations of LiCl caused isolated mesomeres to give rise to embryoids with an increasing tendency to express vegetal markers of differentiation, and it was found that expression of different vegetal markers begin to appear at different concentrations of LiCl. LiCl also caused the marker for oral ectoderm to be expressed in a more normal pattern. Combining micromeres with mesomeres also induced mesomere derivatives to differentiate in a vegetal manner. Micromeres were not completely effective in inducing a more normal pattern of expression of the marker for oral ectoderm. The treatment of isolated mesomeres with both LiCl and micromeres produces a synergistic effect resulting in embryoids expressing markers not induced by either treatment alone.     

A Stereometric Analysis of Karyokinesis, Cytokinesis and Cell Arrangements during and following Fourth Cleavage Period in the Sea Urchin, Lytechinus variegatus

Fourth cleavage of the sea urchin embryo produces 16 blastomeres that are the starting point for analyses of cell lineages and bilateral symmetry. We used optical sectioning, scanning electron microscopy and analytical 3-D reconstructions to obtain stereo images of patterns of karyokinesis and cell arrangements between 4th and 6th cleavage. At 4th cleavage, 8 mesomeres result from a variant, oblique cleavage of the animal quartet with the mesomeres arranged in a staggered, offset pattern and not a planar ring. This oblique, non-radial cleavage pattern and polygonal packing of cells persists in the animal hemisphere throughout the cleavage period. Contrarily, at 4th cleavage, the 4 vegetal quartet nuclei migrate toward the vegetal pole during interphase; mitosis and cytokinesis are latitudinal and subequatorial. The 4 macromeres and 4 micromeres form before the animal quartet divides to produce a 12-cell stage. Subsequently, macromeres and their derivatives divide synchronously and radially through 8th cleavage according to the Sachs-Hertwig rule. At 5th cleavage, mesomeres and macromeres divide first; then the micromeres divide latitudinally and unequally to form the small and large micromeres. This temporal sequence produces 28-and 32-cell stages. At 6th cleavage, macromere and mesomere descendants divide synchronously before the 4 large micromeres divide parasynchronously to produce 56- and 60-cell stages.     

SPECIES SPECIFIC PATTERN OF CILIOGENESIS IN DEVELOPING SEA URCHIN EMBRYOS

The events of cell division and ciliogenesis in individual blastomeres of developing embryos of the sea urchins Temnopleurus toreumaticus and Hemicentrotus pulcherrimus were followed with a Nomarski differential interference microscope. The number of cell divisions before initiation of ciliogenesis was determined with respect to species. In T. toreumaticus , ciliogenesis began about 4 hr after fertilization at 25°C. The sequence of ciliogenesis was as follows: cilia appeared first on smaller micromeres, followed in order by blastomeres derived from larger micromeres, those from mesomeres and finally those derived from macromeres. Blastomeres originating from mesomeres, macromeres, larger micromeres and smaller micromeres had completed the 8th, 9th, 7th and 5th divisions respectively, before they generated cilia.
In H. pulcherrimus , embryos started to form cilia about 9 hr after fertilization at 18°C. Cilia appeared first on blastomeres of mesomere origin and, then on those of macromere origin. Before initiation of ciliogenesis, descendants of mesomeres and macromeres completed 9 and 10 rounds of cell division. Descendants of larger micromeres and the majority of cells derived from smaller micromeres did not acquired cilia even when the embryo began to rotate within the fertilization membrane. At this stage, the former had completed the 6th division and the latter the 8th division. Cell counts of blastomeres per embryo at the blastula stage also supported this observation.     

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.     

Change in the adhesive properties of blastomeres during early cleavage stages in sea urchin embryo

Blastomeres of sea urchin embryo change their shape from spherical to columnar during the early cleavage stage. It is suspected that this cell shape change might be caused by the increase in the adhesiveness between blastomeres. By cell electrophoresis, it was found that the amount of negative cell surface charges decreased during the early cleavage stages, especially from the 32-cell stage. It was also found that blastomeres formed lobopodium-like protrusions if the embryos were dissociated in the presence of Ca2+. Interestingly, a decrease in negative cell surface charges and pseudopodia formation first occurred in the descendants of micromeres and then in mesomeres, and last in macromeres. By examining the morphology of cell aggregates derived from the isolated blastomeres of the 8-cell stage embryo, it was found that blastomeres derived from the animal hemisphere (mesomere lineage) increased their adhesiveness one cell cycle earlier than those of the vegetal hemisphere (macromere lineage). The timing of the initiation of close cell contact in the descendants of micro-, meso- and macromeres was estimated to be 16-, 32- and 60-cell stage, respectively. Conversely, the nucleus-to-cell-volume ratios, which are calculated from the diameters of the nucleus and cell, were about 0.1 when blastomeres became adhesive, irrespective of the lineage.     

Interactions of different vegetal cells with mesomeres during early stages of sea urchin development

It has been known from results obtained in the classical experiments on sea urchin embryos that cell isolation and transplantation showed extensive interactions between the early blastomeres and/or their descendants. In the experiments reported here a systematic reexamination of recombination of mesomeres and their progeny (which come from the animal hemisphere) with various vegetal cells derived from blastomeres of the 32- and 64-cell stage was carried out. Cells were marked with lineage tracers to follow which cell gave rise to what structures, and newly available molecular markers have been used to analyze different structures characteristic of regional differentiation. Large micromeres form spicules and induce gut and pigment cells in mesomeres, conforming to previous results. Small micromeres, a cell type not heretofore examined, gave rise to no recognizable structure and had very limited ability to evoke poorly differentiated gut tissue in mesomeres. Macromeres and their descendants, Veg 1 and Veg 2, form primarily what their normal fate dictated, though both did have some capacity to form spicules, presumably by formation from secondary mesenchyme. Macromeres and their descendants were not potent inducers of vegetal structures in animal cells, but they suppress the latent ability of mesomeres to form vegetal structures. The results lead us to propose that the significant interactions during normal development may be principally suppressive effects of mesomeres on one another and of adjacent vegetal cells on mesomeres.     

Transient appearance of Strongylocentrotus purpuratus Otx in micromere nuclei: Cytoplasmic retention of SpOtx possibly mediated through an α-actinin interaction

At the 16-cell stage, the sea urchin embryo is partitioned along the animal-vegetal axis into eight mesomeres, four macromeres, and four micromeres. The micromeres, unlike the other blastomeres, are autonomously specified to produce skeletogenic mesenchymal cells and are also required to induce the vegetal-plate territory. A long-held belief is that micromeres inherit localized maternal determinants that endow them with their cell autonomous behavior and inducing capabilities. Here, we present evidence that an orthodenticle-related protein, SpOtx appears transiently in nuclei of micromeres but not in nuclei of mesomeres and macromeres. At later stages of development, SpOtx was translocated into nuclei of all cells. To address the possibility that SpOtx was retained In the cytoplasm at early developmental stages we searched for cytoplasmic proteins that interact with SpOtx. A proline-rich region of SpOtx resembling an SH3-binding domain was used to screen an embryo cDNA expression library, and a cDNA clone was isolated and shown to be α-actinin. A yeast two-hybrid analysis showed a specific interaction between the proline-rich region of SpOtx and a putative SH3 domain of the sea urchin α-actinin. Because micromeres lack an actin-based cytoskeleton, the results suggested that, at the vegetal pole of the 16-cell stage embryo, SpOtx was translocated into micromere nuclei, whereas in other blastomeres SpOtx was actively retained in the cytoplasm by binding to α-actinin. The transient appearance of SpOtx in micromere nuclei may be associated with the specification of micromere cell fate. © 1996 Wiley-Liss, Inc.     

The influence of cell interactions and tissue mass on differentiation of sea urchin mesomeres

The developmental potential of different blastomeres of the sea urchin embryo was re-examined. We have employed a new method to isolate substantial numbers of different kinds of blastomeres from 16-cell-stage embryos, and we have used newly available molecular markers to analyze possible vegetal differentiation. We have found that, while isolated mesomere pairs behave according to the classical expectations and develop into ectodermal vesicles, there is a clear effect of reaggregating two or more mesomere pairs. They survive better in long-term culture and, after prolonged periods, they display an astonishing ability to express vegetal differentiation. We also combined mesomeres with stained micromeres or macromeres from the vegetal hemisphere. Although induction of guts and spicules was observed, there was little if any effect of varying the ratio of different blastomeres on the kinds of differentiation obtained.     

Intracellular fate mapping in a basal metazoan, the ctenophore Mnemiopsis leidyi, reveals the origins of mesoderm and the existence of indeterminate cell lineages.

Ctenophores are marine invertebrates that develop rapidly and directly into juvenile adults. They are likely to be the simplest metazoans possessing definitive muscle cells and are possibly the sister group to the Bilateria. All ctenophore embryos display a highly stereotyped, phylum-specific pattern of development in which every cell can be identified by its lineage history. We generated a cell lineage fate map for Mnemiopsis leidyi by injecting fluorescent lineage tracers into individual blastomeres up through the 60-cell stage. The adult ctenophore body plan is composed of four nearly identical quadrants organized along the oral-aboral axis. Each of the four quadrants is derived largely from one cell of the four-cell-stage embryo. At the eight-cell stage each quadrant contains a single E ("end") and M ("middle") blastomere. Subsequently, micromeres are formed first at the aboral pole and later at the oral pole. The ctene rows, apical organ, and tentacle apparatus are complex structures that are generated by both E and M blastomere lineages from all four quadrants. All muscle cells are derived from micromeres born at the oral pole of endomesodermal precursors (2M and 3E macromeres). While the development of the four quadrants is similar, diagonally opposed quadrants share more similarities than adjacent quadrants. Adult ctenophores possess two diagonally opposed endodermal anal canals that open at the base of the apical organ. These two structures are derived from the two diagonally opposed 2M/ macromeres. The two opposing 2M/ macromeres generated a unique set of circumpharyngeal muscle cells, but do not contribute to the anal canals. No other lineages displayed such diagonal asymmetries. Clones from each blastomere yielded regular, but not completely invariant patterns of descendents. Ectodermal descendents normally, but not always, remained within their corresponding quadrants. On the other hand, endodermal and mesodermal progeny dispersed throughout the body. The variability in the exact complements of adult structures, along with previously published cell deletion experiments, demonstrates that cell interactions are required for normal cell fate determination. Ctenophore embryos, like those of many bilaterian phyla (e.g., spiralians, nematodes, and echinoids), display a highly stereotyped cleavage program in which some, but not all, blastomeres are determined at the time of their birth. The results suggest that mesodermal tissues originally evolved from endoderm tissue.     

Time-lapse and electron microscopic studies of sea urchin micromeres

Summary The cleavage pattern of the young sea urchin embryo was studied by means of light and electron microscopy.The micromeres, which are known to have a strong organizing effect on the embryo, were found to form a syncytium with their neighbouring micromeres and with the macromeres. The cell walls between these cells were observed to be incomplete while there were interphase nuclei with intact nuclear membranes in the micro- and the macromeres. Similar phenomena with a break down of the cell membranes were not observed between macro- and mesomeres while there were intact interphase nuclei in these cells. Micromeres implanted on macromeres or mesomeres were found to coalesce with these latter cells in the course of a few minutes. During interphase, when the nuclei of both micro- and mesomere (macromere) had intact nuclear membranes, there also was a break down of the cell walls and a syncytium was formed by the host cell and the implanted micromere (see Fig. 6).The primary mesenchyme cells, which are regarded as the descendants of the micromeres, were also studied and were likewise found to form true syncytia.The importance to embryogenesis of this unique formation of syncytia is discussed.     

Studies on Unequal Cleavage in Sea Urchins II. Surface Differentiation and the Direction of Nuclear Migration

Cortical features of the meso- and macromeres differ from those of the micromeres in sea urchins. At the end of the 8-cell stage, the four animal cells have a continuous row of vesicles lining the free surface of the cell by transmission electron microscopy (TEM) and the nuclei and the resulting mitotic apparatuses (MA) remain at the cell centers and eventually divide equally into eight mesomeres. In the four vegetal cells, narrow gaps can be seen in the vesicular rows near the vegetal pole. The resting nuclei migrate to these gaps and on forming the spindles, they point directly to the gaps. The result is formation of vesicle-free micromeres and vesicle-covered macromeres by unequal divisions.     

Differentiation of Sea Urchin Micromeres: Correlation between Specific Protein Synthesis and Spicule Formation

Sea urchin micromeres were isolated from the 16-cell stage embryos and cultured until they differentiated into spicule-forming cells. Electrophoretic analysis of proteins labeled with [³⁵S]-methionine showed that the differentiation accompanied the synthesis of five cell-specific proteins. These proteins appeared prior to spicule formation and were synthesized continuously or maintained stably while the cultured micromeres formed spicules. In contrast, these proteins were hardly detectable during development of the meso- and macromeres. Correlation between synthesis of the specific proteins and spicule formation was further examined in culture conditions which inhibit spicule formation. In Zn²⁺ -containing or serum-free medium, the micromere descendants failed to form spicules and exhibited markedly reduced synthesis of one of the specific proteins (32 K daltons). After removal of Zn²⁺, or addition of serum, however, spicules were formed with delay but concomitantly with an increase in the synthesis of this protein. This clear correlation suggests the participation of the 32 K protein in the process of spicule formation.     

Complete regulation of development throughout metamorphosis of sea urchin embryos devoid of macromeres

The developmental potential of the animal cap (consisting of eight mesomeres) recombined with micromeres or of micromere progeny was examined in sea urchin embryos. The embryos derived from the animal cap recombined with a quartet of micromeres or their descendants developed into four-armed plutei. After feeding, the larvae developed into eight-armed plutei. The left-right polarity of the larvae, recognized by the location of the echinus rudiment, was essentially normal, regardless of the orientation of animal-vegetal polarity in micromeres combining with the animal cap. The larvae had sufficient potential to metamorphose into complete juvenile sea urchins with five-fold radial symmetry. Cell lineage tracing experiments showed that: (i) macromere progeny were not required for formation of the typical pattern of primary mesenchyme cells derived exclusively from large micromeres; (ii) the progeny of large micromeres did not contribute to cells in the endodermal gut with three compartments of normal function; (iii) the presumptive ectoderm had the potential to differentiate into endodermal gut and mesodermal secondary mesenchyme cells, from which pigment cells likely differentiated; and (iv) behavior of the progeny of small micromeres was the same as that in normal embryos through the gastrula stage. These results indicate that the mesomeres respecify their fate under the inductive influence of micromeres so perfectly that complete juvenile sea urchins are produced.