Skeletogenic potential of induced secondary mesenchyme cells derived from the presumptive ectoderm in echinoid embryos

 During the normal development of echinoids, an animal cap consisting of 8 mesomeres in a 16-cell stage embryo differentiates exclusively into ectoderm. Micromeres in an embryo at the same stage differentiate into primary mesenchyme cells (PMC) and coelomic pouch constituents. An animal cap and a quartet of micromeres were isolated from a 16-cell stage embryo and recombined to make a chimeric embryo devoid of presumptive endoderm and secondary mesenchyme cells (SMC). The PMC in the chimeric embryo were completely removed at the mesenchyme blastula stage. The PMC-depleted chimeric embryos formed an archenteron derived from the mesomeres. Some secondary mesenchyme-like cells (induced SMC) were released from the archenteron tip. A considerable fraction of the induced SMC formed the typical mesenchyme pattern after migrating into the vegetal region, synthesized skeletogenic mesenchyme cell-surface protein (msp130) and produced the larval skeleton. These findings indicate that induced SMC derived from the presumptive ectoderm have the same nature as natural SMC in both the timing of their release and their skeletogenic potential expressed in the absence of PMC. Received: 14 November 1996 / Accepted: 30 December 1996     

CHANGES IN CELL SURFACE MORPHOLOGY DURING DIFFERENTIATION OF MICROMERE- AND MESOMERE-DERIVED CELLS OF THE SEA URCHIN EMBRYO

Micromeres and mesomeres isolated from 16-cell embryos of the sea urchin, Strongylocentrotus intermedius , were cultured in vitro , and changes in the cells surface architecture during the differentiation of the micromere- and mesomere-derived cells were observed using scanning electron microscopy. Two types of the distribution of the surface microvilli were observed in both blastomere-derived cell masses. One type showed a uniform distribution of the microvilli and the other type showed an uneven one. Though many microvilli were observed in most of both mesomere and micromere-derived cells at the 64-cell stage and the early blastula stage (16 hr after the 16-cell stage at 6°C) respectively, the microvilli decreased in number at the later stages in both blastomere-derived cell masses as compared with the 64-cell stage and the early blastula stage respectively. Rapid disappearance of the surface microvilli was observed in the micromere-derived cells in contrast with the mesomere-derived cells which still had many microvilli even at the midmesenchyme stage.     

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.     

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.     

The program of protein synthesis during the development of the micromere-primary mesenchyme cell line in the sea urchin embryo

Changes in the pattern of protein synthesis were analyzed during the in vitro development of the micromere-primary mesenchyme cell line of the sea urchin embryo. Micromeres were isolated and cultured from 16-cell stage embryos, and primary mesenchyme cells were isolated and cultured from early gastrulae. Both cell isolates developed normally in culture with about the same timing as their in situ counterparts in control embryos. Newly synthesized proteins were labeled with [³H]valine at several stages of development and were analyzed by two-dimensional polyacrylamide gel electrophoresis and fluorgraphy. The electrophoretic pattern of labeled proteins changed dramatically during development. More than half of the analyzed proteins underwent qualitative or quantitative changes in their relative rates of valine incorporation and these changes were highly specific to this cell line. Almost all of the changes were initiated prior to gastrulation and many prior to hatching. The highest frequency of changes in the micromere pattern of protein synthesis occurred between hatching and the start of gastrulation. This peak of activity coincided with the normal time of ingression of the primary mesenchyme and preceded the differentiation of spicules by more than 30 hr. Most of the observed changes were characterized as either decreases in the synthesis of proteins that showed maximum incorporation at the 16-cell stage or increases in the synthesis of proteins that showed maxima in the fully differentiated cells. Very few proteins exhibited transient synthetic maxima at intermediate stages. Thus, the program of protein synthesis associated with the development of micromeres consists largely of a switch in emphasis from early to late proteins, with the primary time of switching being between hatching and the onset of gastrulation.     

The factors that promote the development of symmetry properties in aggregates from dissociated echinoid embryos

Summary Embryos of Hemicentrotus pulcherrimus at the 16 cell, 400 cell or mesenchyme blastula stage of development were dissociated into single cells. The cells were reaggregated, and the development of individual aggregates was monitored. Only aggregates from 16 cell embryos developed into pluteus-like larvae with radial or bilateral symmetry. When embryos at these three developmental stages were incompletely dissociated so that there were mixtures of single cells and groups of undissociated cells, the percentage of aggregates from 16 cell embryos that developed in a pluteus-like manner was greater than in aggregates from completely dissociated 16 cell embryos. Also a small percentage of aggregates from 400 cell embryos now developed into pluteus-like larvae. In both of these experiments small aggregates tend to develop in a more normal manner than larger aggregates.In order to test the role of undissociated cells in promoting pluteus-like development in aggregates from incompletely dissociated blastula stage embryos, pieces of intact animal, lateral, or vegetal blastula wall were grafted to aggregates formed from completely dissociated embryos. While each kind of graft improved the ability of the aggregate to develop in a pluteus-like manner, grafts of vegetal blastula wall were most effective. In an aggregate, a graft differentiates according to its presumptive fate and influences the cells of the aggregate to differentiate in an appropriate manner. The ability of the graft to influence the development of the other cells in the aggregate depends on the developmental stage of the cells that make up the aggregate and the size of the aggregate.     

Electrophoretic mobility of mouse cells and homologous isolated nuclei

The electrophoretic mobilities of Ehrlich ascites, sarcoma 37 ascites, mouse liver cells and their isolated nuclei were measured under similar environmental conditions. No differences in mobility were detected between cells and homologous nuclei from the same cell population and it was concluded that their surface charge densities were probably the same. The effect of neuraminidase on Ehrlich ascites and liver cells and nuclei was also determined; neuraminidase reduced the mobility of Ehrlich ascites cell nuclei as well as cells. The reduction in mobility of cells and nuclei prepared by a sucrose method was the same; however, the reduction in mobility of citric acid prepared nuclei was less than that of citric acid treated cells. The reduction in mobility of both liver cells and nuclei was small or insignificant. It is suggested that although cells and nuclei have similar electrophoretic mobilities, possibly different groups contribute to their surface charge.     

Changes in the cell surface of human diploid fibroblasts during cellular aging.

The electrophoretic mobility of 13 human diploid cell strains, TIG-1, TIG-2, TIG-3, TIG-7, WI-38, IMR-90, MRC-5, MRC-9, TIG-1H, TIG-1L, TIG-2M, TIG-2B, and TIG-3S, which were established from different tissues of human embryos, was studied at different passages. The net negative surface charge of the cells was characteristic for each cell strain and decreased significantly during the in vitro aging of the cells. The decrease in the net negative charge of the cells correlated well with the decrease in cell density throughout the life span of the cells. A strict linear correlation between the electrophoretic mobility and the number of cells harvested at each passage was obtained for all the human diploid cell strains. Moreover, almost the same linear regression coefficient of the cells was obtained among these cell strains. Therefore, the net negative surface charge of human diploid cell strains could serve as a cell surface marker for in vitro cellular aging.     

Trypanosoma cruzi: surface charge and freeze-fracture of amastigotes

Amastigotes of Trypanosoma cruzi, within vertebrate cells or isolated from the supernatant of vertebrate cell cultures (L-A9 fibroblast or J774G8 macrophage-like cell lines), possess glycoproteins or glycolipids on the cell surface according to the periodic acid-thiosemicarbazide-silver proteinate technique used in association with electron microscopy. The cell surface of isolated amastigotes is negatively charged, as evaluated by the binding of cationic particles (colloidal iron hydroxyde at pH 1.8 and cationized ferritin at pH 7.2) as well as by direct measurement of cellular electrophoretic mobility. Amastigotes (Y strain) isolated from the spleen of infected mice and amastigotes (Y and CL strains) from the supernatant of cell cultures previously infected with T. cruzi have the same mean electrophoretic mobility (-0.85 micron sec-1 V-1 cm). It is intermediate between the epimastigote and the trypomastigote forms (determined previously). Sialic acid is the important component responsible for the negative surface charge, as determined by the use of neuraminidase. Thus, it is possible to use the mean electrophoretic mobility as an indicator for identifying amastigotes of T. cruzi.     

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-.     

A cell surface alteration in mouse L cells induced by interferon

Mouse L cells grown in suspension culture when treated with L cell interferon have a greater electrophoretic mobility toward the anode than control cells. This change in electrophoretic mobility depends on the concentration of interferon in the medium and the duration of interferon interaction with the cells. It is concluded that the interferon-treated cells have a greater net negative charge on the cell surface than control cells and it is suggested that the cell surface is altered because of the interaction with interferon.     

Developmental time,cell lineage,and environment regulate the newly synthesized proteins in sea urchin embryos

Strongylocentrotus purpuratus embryos were fractionated into two cell populations of defined lineages at times corresponding to two critical developmental events: determination (16-cell stage) and early differentiation (mesenchyme blastula). The 16-cell stage blastomeres, labeled with [³⁵S]methionine, exhibited identical protein synthesis patterns by fluorography, and this pattern was not significantly altered by cell separation. In comparing the proteins of the mesenchyme blastula to the 16-cell stage, differences (increases and decreases) were seen by fluorography of newly synthesized proteins. The synthesis of 2.9% of the mesenchyme blastula proteins is specific to or enriched in primary mesenchyme cells and 8.2% is specific to or enriched in endoderm/ectoderm cells. Additionally, in contrast to the earlier stage, the pattern of protein synthesis in the mesenchyme blastula embryos is substantially altered by cell separation. The ability to alter protein synthesis in response to environmental factors may be a further demonstration of the differentiation of these cells.     

Early inductive interactions are involved in restricting cell fates of mesomeres in sea urchin embryos

Isolated intact caps of animal blastomeres, obtained from either 8- or 16-cell embryos, differentiate as swollen ectodermal vesicles. These findings agree with earlier studies demonstrating that mesomeres contribute only to larval ectoderm during normal development. In contrast, we find that pairs of mesomeres isolated from 16-cell embryos can differentiate endodermal and mesenchymal cells in a substantial number of cases (23%). Thus, mesomeres have a greater developmental potential than is realized during normal development. Further results support hypotheses that graded distributions of morphogenetic determinants exist within these embryos, since the extent of differentiation of isolated mesomeres is related to the relative position of the third cleavage plane along the animal-vegetal axis. When the third cleavage plane is subequatorial and the resulting animal blastomeres inherit a fraction of the vegetal hemisphere, more cases (39%) differentiate endodermal and mesenchymal cell types. A significant number of mesomere pairs (9-14%), however, can still differentiate endodermal and mesenchymal cells when the mesomeres are formed within the animal hemisphere. Thus, putative vegetal morphogenetic determinants may extend into the animal hemisphere in some cases. Further results indicate a temporal restriction in the developmental potential of mesomeres or mesomere progenitor cells since their differentiative capability is greater if they are isolated earlier during development. Aggregates of isolated mesomere pairs also display a decreased developmental potential when compared to isolated mesomere pairs. These results suggest that associations with adjacent cells (vegetal cells as well as adjacent mesomeres) restrict the development of mesomeres between third and sixth cleavages.     

Isolation of two populations of sperm cells and microelectrophoresis of pairs of sperm cells from pollen tubes of tobacco (Nicotiana tabacum)

Prior research has indicated that the two sperm cells of Nicotiana tabacum are dimorphic, suggesting that they may participate in preferential fertilization during in vivo fusion with the egg and central cells. To probe the mechanism of potential preferential fertilization in this plant, it will be necessary to use modern sensitive molecular techniques. For this purpose, two individual populations of two sperm cells, constituting the Svn (associated with the vegetative nucleus) and Sua (unassociated with the vegetative nucleus), were isolated in the thousands from tobacco pollen tubes with a micromanipulator as a preliminary step toward research on gametic recognition using molecular techniques. Microelectrophoresis of paired sperm cells from a single pollen tube was conducted at different developmental stages. Sperm cells isolated from 1-, 2-, 3- and 4-cm stylar lengths migrated to the negative pole, with the Sua displaying significantly greater electrophoretic mobility than the Svn, reflecting a more positively charged cell surface on the Sua. The sperm cells isolated from 1-cm style are very sensitive to electron potential in an electrophoretic field, presumably reflecting that they are still in a young state. Differences in cell surface charge between the Sua and Svn may be related with cell fate during fertilization. Supported by National Natural Science Foundation of CHINA (30170060)     

Formation of chondrous and osseous tissues in micromass cultures of rat frontonasal and mandibular ectomesenchyme

Rat frontonasal and mandibular mesenchyme was isolated from day-12 1/2 (stage-22) rat embryos and cultured at high density for up to 12 days. The stage chosen was based on the observation that mandibular mesenchyme at this stage became independent of its epithelium with respect to the production of both cartilage and bone. Frontonasal cultures developed aggregates of anastomosing columns of cells within 2 days. These grew as the cells enlarged, laying down an Alcian-blue-positive matrix by day 3 of culture. Significant mineral was detected by von Kossa staining by day 5 at which time the aggregates covered a large portion of the culture, eventually covering the entire micromass by day 10-12. Mandibular cultures developed centrally located nodular aggregates by 3 days of culture. These nodules increased in number, spreading outwards as the cells enlarged, laying down an Alcian-blue-positive matrix by day 4 and mineral by days 6-7. At this time the nodules began to elongate and coalesce, but never covered the entire culture over the 12-day period. Antibody staining revealed that in both cultures the cells were initially positive for type I collagen. Subsequently, the aggregates began expressing type II collagen, followed by type X, which coincided with the onset of mineralization. At this time some cells were negative for these cartilage markers, but positive for osteoblast markers, bone sialoprotein II, osteocalcin and type I collagen. In addition osteonectin and alkaline phosphatase were demonstrable in all of the aggregate cells late in the culture period. This provided clear evidence that chondroblast and osteoblast differentiation was proceeding within these cultures. The culture of rat facial mesenchyme should prove very useful, not only for the analysis of bone and cartilage induction and lineage relationships, but also in furthering our knowledge of craniofacial differentiation, growth and pattern formation by extending our analysis to a mammalian system.     

TOTAL CELL NUMBER AND NUMBER OF THE PRIMARY MESENCHYME CELLS IN WHOLE, 1/2 AND 1/4 LARVAE OF CLYPEASTER JAPONICUS*

Total cell number and number of the primary mesenchyme cells of 1/2 and 1/4 larvae were counted at several developmental stages after hatching in comparison with those of a whole larva, using Clypeaster japonicus as material. To obtain partial larvae, blastomeres were isolated at the 2- or 4-cell stage in Ca-free sea water and cultured in natural sea water at around 23°C. Isolated blastomeres cleaved as in situ, namely, as a part of an embryo. Although each partial embryo tended to spread into a plate, it acquired spherical shape prior to hatching of control whole embryo and developed normally in terms of both developmental rate and morphogenesis. Total cell number of a whole larva was about 620 just after hatching and increased almost linearly until i t reached 1850 at the pluteus stage. A half and quarter larvae contained roughly 1/2 and 1/4, respectively, of the number of cells of whole larva through all stages counted. Numbers of the primary mesenchyme cells in the partial larvae, however, tended to be slightly larger than a half or a fourth of that in whole larva. In whole larva, 35, 50, 56 and 58 was counted at the mesenchyme blastula, early gastrula, late gastrula and pluteus stage, respectively.     

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.     

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.