Monensin interferes with the determination of the mesodermal cell line in embryos of Patella vulgata

Summary In embryos of the equally cleaving marine gastropod Patella vulgata, the mesodermal stem cell is determined during the interval between the fifth and sixth cleavage by means of cellular interactions between one of the four vegetally located macromeres with the overlying animal micromeres. Shortly before and during this interaction phase an extracellular matrix (ECM) is present between the interacting cells. In this study the glycosylation-perturbing ionophore monensin was used to investigate the possible morphogenetic significance of the ECM. Incubation of 32-cell-stage Patella embryos in 10^–6 M monensin results in radialized embryos in which none of the four macromeres interacts with the overlying animal micromeres. None of the macromeres is determined, therefore, to form mesoderm in such embryos. Trochophore larvae reared from these embryos retain their radial symmetry, as is indicated by the presence of four shell glands and four blastopore- or stomodeum-like invaginations in these larvae. The monensin-treated embryos probably secrete abnormal ECM that does not provide the proper conditions for the blastomeres to stretch and interact with the micromeres. Changes in intracellular ionic concentrations may also be involved.     

Mesodermal cell differentiation in echinoid embryos derived from the animal cap recombined with a quartet of micromeres

Mesodermal cell differentiation in echinoid embryos derived from the animal cap recombined with micromeres was examined. An animal cap consisting of mesomere-descendants was isolated from a 32-cell stage embryo, and recombined with a quartet of micromeres isolated from a 16-cell stage embryo. The recombined embryos were completely depleted of the progenitors of an archenteron, pigment cells, blastocoelar cells and muscle cells. Secondary mesenchyme-like cells (induced SMC) were released from the archenteron derived from the animal cap cells in the recombined embryos. Some induced SMC differentiated into pigment cells, confirming previous data for another echinoid species. Moreover, three different kinds of mesodermal cells-blastocoelar, muscle and coelomic pouch cells-were formed in the recombined larvae. Experiments using a fluorescent probe confirmed that the pigment, blastocoelar, muscle cells and cells in part of the coelomic pouches in the recombined larvae were derived from the animal cap mesomeres. These results indicated that the animal cap mesomere had the potential to differentiate through cell fate regulation into four mesodermal cell types-pigment, blastocoelar, muscle and coelomic pouch cells-.     

Microinjection of lectins, hyaluronidase, and hyaluronate fragments interferes with cleavage delay and mesoderm induction in embryos of Patella vulgata

In embryos of Patella vulgata at the 32-cell stage, one of the four vegetally located macromeres makes contacts with overlying animal micromeres. As a result, this macromere (designated 3D) divides significantly later than the other macromeres and forms the mesodermal stem cell 4d. Shortly before and during this interaction two types of extracellular matrix are present: a basal lamina-like layer on the tips of the micromeres and a loose fibrillar meshwork in the blastocoel. In this paper we examine the role of the matrix in cleavage delay and mesoderm determination. The microinjection of extracellular matrix-binding lectins, or of hyaluronidase, or of decasaccharide fragments of hyaluronate into the blastocoel results in embryos in which either no or two macromeres are delayed in cleavage and are presumably determined as mesodermal stem cells. We suggest that the fibrillar meshwork is needed for macromere elongation toward the micromeres and that the basal lamina-like layer is involved in the determination process itself.     

Development of dorsoventral polarity and mesentoblast determination in Patella vulgata

In Patella vulgata the 32-cell stage represents a pause in the mitotic activity prior to the differentiation of the mesentoblast mother cell 3D. At the onset of this stage, the embryo is radially symmetrical. Nevertheless, the plane of bilateral symmetry is indicated as it passes through the macromeres forming the vegetal cross-furrow. From the early beginning of the 32-cell stage, all four macromeres intrude far into the interior and touch the centrally radiating cells of the first quartet of micromeres. The two cross-furrow forming macromeres (3B and 3D) intrude the farthest and come into contact with the greatest number of micromeres. Finally, the contacts are extended significantly and maintained with only one of these macromeres. From that moment, this cell can be called the macromere 3D and the dorsoventral axis is determined. The evolution of the internal cell contacts between the micromeres of the first quartet and the macromeres indicates an essential role of the former in the determination of one of the latter as the mesentoblast mother cell, and thus in the determination of dorsoventral polarity.     

Localized activity of Ca2+-stimulated ATPase and transcellular ionic currents during mesoderm induction in embryos ofLymnaea stagnalis (Mollusca)

Summary InLymnaea stagnalis, mesoderm induction occurs at the 24-cell stage, when the apical tip of the macromere 3D establishes a close contact with a number of micromeres. Via its tip, the macromere 3D is supposed to receive an inductive signal from the micromeres, resulting in the determination of the mesodermal stem cell 4d at the next division. In view of the possibility that transcellular ionic currents might somehow be involved, either in the processes that bring about this particular configuration of blastomeres or in the induction process itself, we mapped the electric field around the embryo during the 24-cell stage, using a vibrating probe. We detected a reversal of the current direction as compared to the uncleaved egg, whilst the polarity of the field along the animal-vegetal axis was maintained. We also mapped the localization of Ca²⁺-stimulated AT-Pase, an enzyme that drives the Ca²⁺-efflux from the cell. We found that this enzyme is localized exclusively along the cytoplasmic face of the apical plasma membrane of macromere 3D, and that its presence is restricted to the period from 110 to 135 min after the fifth cleavage, when there is close contact between macormere 3D and the micromeres. Since the localization of the Ca²⁺-stimulated ATPase coincides both in time and space with the induction of the mesoderm-mother cell, we suggest that localized calcium fluxes may play a role in this induction process.     

Timing of the potential of micromere-descendants in echinoid embryos to induce endoderm differentiation of mesomere-descendants

It has been reported that the micromeres of echinoid embryos have the potential to induce an archenteron in animal cap mesomeres recombined at the 16- or 32-cell stage. In the present study, experiments were performed to determine the exact period when the micromeres transmit their inductive signal to respecify the cell fate of mesomeres as endo-mesoderm. An animal cap was recombined with a quartet of micromeres, or micromere-descendants cultured in isolation, to form a recombinant embryo. The micromere-descendants were completely removed at various developmental stages, resulting in an embryo composed only of mesomere-descendants that had been under the inductive influence of micromeres for a limited period. The resulting embryos were cultured and examined for their potential to differentiate endoderm. The results indicated that the signal effective for inducing an archenteron in mesomere-descendants emanated from the micromere-descendants at the early blastula stage around hatching onward. Before this stage, the micromeres and micromere-descendants showed this potential slightly or not at all. The inductive signal emanated from the micromere-descendants almost on time even when the cells were cultured in isolation. The micromere-descendants completed transmission of the signal for inducing the archenteron in the animal cap within 2 h of recombination. The animal cap at between the 28-cell stage and 2 h after the 32-cell stage could react with the inductive signal from the micromere-descendants. Embryos composed of only animal cap mesomeres that had received the inductive signal from micromere-descendants for a limited period had the potential to develop into 8-armed plutei. Each pluteus formed an adult rudiment essentially on the left side of the larval body, and metamorphosed into a juvenile with pentaradiate symmetry.     

Evolutionary modification of specification for the endomesoderm in the direct developing echinoid <Emphasis Type="Italic">Peronella japonica</Emphasis>: loss of the endomesoderm-inducing signal originating from micromeres

We investigated the inductive signals originating from the vegetal blastomeres of embryos of the sand dollar Peronella japonica, which is the only direct developing echinoid species that forms micromeres. To investigate the inductive signals, three different kinds of experimental embryos were produced: micromere-less embryos, in which all micromeres were removed at the 16-cell stage; chimeric embryos produced by an animal cap (eight mesomeres) recombined with a micromere quartet isolated from a 16-cell stage embryo; and chimeric embryos produced by an animal cap recombined with a macromere-derived layer, the veg1 or veg2 layer, isolated from a 64-cell stage embryo. Novel findings obtained from this study of the development of these embryos are as follows. Micromeres lack signals for endomesoderm specification, but are the origin of a signal establishing the oral–aboral (O–Ab) axis. Some non-micromere blastomeres, as well as micromeres, have the potential to form larval skeletons. Macromere descendants have endomesoderm-inducing potential. Based on these results, we propose the following scenario for the first step in the evolution of direct development in echinoids: micromeres lost the ability to send a signal endomesoderm induction so that the archenteron was formed autonomously by macromere descendants. The micromeres retained the ability to form larval spicules and to establish the O–Ab axis.     

SPICULE FORMATION IN VITRO BY THE DESCENDANTS OF PRECOCIOUS MICROMERE FORMED AT THE 8-CELL STAGE OF SEA URCHIN EMBRYO*

The micromeres at the 16-cell stage of sea urchin embryo have already been endowed with a faculty to self-differentiate into spicule-forming cells (11). The present experiment was designed to test whether the factor(s) necessary for such self-differentiation had already been localized at the 8-cell stage in an area corresponding to the presumptive micromere region in Hemicentrotus pulcherrimus. Since the blastomeres at the 8-cell stage are all equal in size in normal embryo, unequal 3rd cleavage, by which small blastomeres are pinched off toward the vegetal pole (precocious micromeres), was experimentally induced either by treatment with 4NQO (4-nitroquinoline-1-oxide) at the 2-cell stage or by continuous culture in Ca-free sea water. The precocious micromeres were cultured in vitro in natural sea water containing horse serum. Descendants of the precocious micromeres formed spicules. In comparison their spicule formation with that by the descendants of the micromere of normal embryo, no differences were found regarding 1) time of initiation of spicule formation, 2) rate of growth of spicule, 3) size and shape of resultant spicule and 4) percentage of clones which formed spicule. The fact indicates that factor(s) indispensable for self-differentiation into spicule-forming cells have already been localized near the vegetal pole as early as the 8-cell stage.     

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.     

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.     

A quantitative analysis of cell allocation to trophectoderm and inner cell mass in the mouse blastocyst

The allocation of cells to the trophectoderm and inner cell mass (ICM) in the mouse blastocyst has been examined by labelling early morulae (16-cell stage) with the short-term cell lineage marker yellow-green fluorescent latex (FL) microparticles. FL is endocytosed exclusively into the outside polar cell population and remains autonomous to the progeny of these blastomeres. Rhodamine-concanavalin A was used as a contemporary marker for outside cells in FL-labelled control (16-cell stage) and cultured (approximately 32- to 64-cell stage) embryos, immediately prior to the disaggregation and analysis of cell labelling patterns. By this technique, the ratio of outside to inside cell numbers in 16-cell embryos was shown to vary considerably between embryos (mean 10.8:5.2; range 9:7 to 14:2). In cultured embryos, the trophectoderm was derived almost exclusively (over 99% cells) from outside polar 16-cell blastomeres. The origin of the ICM varied between embryos; on average, most cells (75%) were descended from inside nonpolar blastomeres with the remainder derived from the outside polar lineage, presumably by differentiative cleavage. In blastocysts examined by serial sectioning, polar-derived ICM cells were localised mainly in association with trophectoderm and were absent from the ICM core. In nascent blastocysts with exactly 32 cells an inverse relationship was found between the proportion of the ICM descended from the polar lineage and the deduced size of the inside 16-cell population. From these results, it is concluded that interembryonic variation in the outside to inside cell number ratio in 16-cell morulae is compensated by the extent of polar 16-cell allocation to the ICM at the next division, thereby regulating the trophectoderm to ICM cell number ratio in early blastocysts.     

Studies on Unequal Cleavage in Sea Urchins III. Micromere Formation under Compression

When sea urchin embryos at 2-cell stage are flattered between agar plates, the direction of cleavage is rotated by 90° in each division in reference to the preceding cleavage and no micromere is formed. But under this condition, micromeres are formed in 2 cases; 1) When the egg axis is parallel to the plane of flattening, 2 micromeres are formed on one side of a square 16-cell stage. 2) when the egg axis is perpendicular to the plane, 4 micromeres are formed at the center of the square.
When put into a groove, a string of 4 cells is formed showing that the spindle direction is further deflected by the groove. In the following 16-cell stage in the groove, which consists of 2 layers of 8 cells, cases with 2 micromeres on one side and 4 micromeres at the center are still found. If the 2-cell stage is introduced into a groove after the formation of mitotic apparatus, the spindle direction can no longer be changed and the 4-cell stage becomes like 4 pancakes stuck in 2 layers, indicating that 2 asters are holding the ends of a spindle in fixed positions.     

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.     

Mass isolation and culture of sea urchin micromeres

Summary A procedure is described for large-scale isolation of micromeres from 16-cell stage sea urchin embryos. One to two grams of >99% pure, viable micromeres (2.3 to 4.6 × 10⁸ cells) are routinely isolated in a single preparation. In culture, these cells uniformly proceed through their normal development, in synchrony with micromeres in whole embryos, ultimately differentiating typical larval skeletal structures. The attributes of this procedure are: (a) the very early time of isolation of the cells, directly after the division that establishes the cell line; (b) the large yield of cells; (c) the purity of the preparation of cell; and (d) their synchronous development in culture through skeletogenesis. The procedure greatly aids in making sea urchin micromeres a favorable material for molecular analysis of development. This work was supported in part by the following grants from the National Institutes of Health: Grant HL-10312 to A.H.W., Grant GM-20784 to Helen R. Whiteley, Grant ES-02190 to N. Karle Mottet, M.D., and Training Grants ES-07032 and HD-00266.     

Conserved mechanism of dorsoventral axis determination in equal-cleaving spiralians

Many members of the spiralian phyla (i.e., annelids, echiurans, vestimentiferans, molluscs, sipunculids, nemerteans, polyclad turbellarians, gnathostomulids, mesozoans) exhibit early, equal cleavage divisions. In the case of the equal-cleaving molluscs, animal-vegetal inductive interactions between the derivatives of the first quartet micromeres and the vegetal macromeres specify which macromere becomes the 3D cell during the interval between fifth and sixth cleavage. The 3D macromere serves as a dorsal organizer and gives rise to the 4d mesentoblast. Even though it has been argued that this situation represents the ancestral condition among the Spiralia, these inductive events have only been documented in equal-cleaving molluscs. Embryos of the nemertean Cerebratulus lacteus also undergo equal, spiral cleavage, and the fate map of these embryos is similar to that of other spiralians. The role of animal first quartet micromeres in the establishment of the dorsal (D) cell quadrant was examined in C. lacteus by removing specific combinations of micromeres at the eight-cell stage. To follow the development of various cell quadrants, one quadrant was labeled with DiI at the four-cell stage, and specific first quartet micromeres were removed from discrete positions relative to the location of the labeled quadrant. The results indicate that the first quartet is required for normal development, as removal of all four micromeres prevented dorsoventral axis formation. In most cases, when either one or two adjacent first quartet micromeres were removed from one side of the embryo, the cell quadrant on the opposite side, with its macromere centered under the greatest number of the remaining animal micromeres, ultimately became the D quadrant. Twins containing duplicated dorsoventral axes were generated by removal of two opposing first quartet micromeres. Thus, any cell quadrant can become the D quadrant, and the dorsoventral axis is established after the eight-cell stage. While it is not yet clear exactly when key inductive interactions take place that establish the D quadrant in C. lacteus, contacts between the progeny of animal micromeres and vegetal macromeres are established during the interval between the fifth and sixth round of cleavage divisions (i.e., 32- to 64-cell stages). These findings argue that this mechanism of cell and axis determination has been conserved among equal-cleaving spiralians.     

Micromere Differentiation in the Sea Urchin Embryo: Two-Dimensional Gel Electrophoretic Analysis of Newly Synthesized Proteins

A method for large-scale culture of isolated blastomeres of sea urchin embryos in spinner flasks was developed. Micromeres and meso-, macromeres isolated from sea urchin embryos at the 16-cell stage were cultured by this method and the patterns of protein synthesis by their descendants were examined by two-dimensional gel electrophoresis of [³⁵S] methionine-labeled proteins. Six distinct proteins with molecular weights of 140–kDa, 105–kDa, 43–kDa, 32–kDa, and 28–kDa (two components) were specifically synthesized by differentiating micromeres. Quantitative analysis of the two-dimensional gel patterns demonstrated that all these proteins, except the 32–kDa protein, appeared at the time of ingression of primary mesenchyme cells (PMC's) in vivo , several hours earlier than the onset of spicule formation. The synthesis of 32–kDa protein was paralleled to active spicule formation and the uptake of Ca²⁺. Cell-free translation products directed by poly (A)⁺ RNAs isolated from descendant cells of micromeres and meso-, macromeres were compared by two-dimensional gel electrophoresis. Several spots specific to the micromere lineage were detected. However, none of them comigrated with the proteins synthesized specifically by the cultured micromeres. The results suggest that the expression of these proteins specific to differentiating micromeres may involve post-translational modification.     

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.     

Vasa protein expression is restricted to the small micromeres of the sea urchin, but is inducible in other lineages early in development

Vasa is a DEAD-box RNA helicase that functions in translational regulation of specific mRNAs. In many animals it is essential for germ line development and may have a more general stem cell role. Here we identify vasa in two sea urchin species and analyze the regulation of its expression. We find that vasa protein accumulates in only a subset of cells containing vasa mRNA. In contrast to vasa mRNA, which is present uniformly throughout all cells of the early embryo, vasa protein accumulates selectively in the 16-cell stage micromeres, and then is restricted to the small micromeres through gastrulation to larval development. Manipulating early embryonic fate specification by blastomere separations, exposure to lithium, and dominant-negative cadherin each suggest that, although vasa protein accumulation in the small micromeres is fixed, accumulation in other cells of the embryo is inducible. Indeed, we find that embryos in which micromeres are removed respond by significant up-regulation of vasa protein translation, followed by spatial restriction of the protein late in gastrulation. Overall, these results support the contention that sea urchins do not have obligate primordial germ cells determined in early development, that vasa may function in an early stem cell population of the embryo, and that vasa expression in this embryo is restricted early by translational regulation to the small micromere lineage.     

Cellular distribution of RNA populations in 16-cell stage embryos of the sand dollar, Dendraster excentricus

RNA was extracted from pure preparations of micromeres and meso-plus macromeres isolated from 16-cell stage embryos of Dendraster excentricus. Molecular hybridization-competition experiments disclosed that the binding of 16-cell stage labeled RNA to denatured sperm DNA was competed equally well by micromere RNA, meso-plus macromere RNA, total 16-cell RNA and unfertilized egg RNA, indicating the egg-type populations were distributed almost equally in the different blastomeres. In contrast, experiments with ³H-RNA extracted from micromeres obtained from pulse-labeled 16-cell stage embryos showed qualitative differences when unfertilized egg RNA and total 16-cell stage RNA were used as competitors. Such differences in RNA populations could not be detected in ³H-RNA isolated from the meso-plus macromere fraction.     

Structural differences in the chromatin from compartmentalized cells of the sea urchin embryo: differential nuclease accessibility of micromere chromatin.

The chromatin structure of three cell types isolated from the 16-cell stage sea urchin embryo has been probed with micrococcal nuclease. In micromeres, the four small cells at the vegetal pole, the chromatin is found to be considerably more resistant to degradation by micrococcal nuclease than chromatin in the larger mesomere and macromere cells which undergo more cellular divisions and are committed to different developmental fates. The micromeres show an order of magnitude decrease in the initial digestion rate and a limit digest value which is one third that of the larger blastomeres; both observations are suggestive of the formation of a more condensed chromatin structure during the process of commitment, or as the rate of cell division decreases. The decreased sensitivity to nuclease for micromeres is similar to results reported for sperm and larval stages of development.