Change in the Activity of Na1, K+-ATPase in Embryos of the Sea Urchin, Hemicentrotus pulcherrimus, during Early Development

The activity of ouabain-sensitive Na⁺, K⁺-ATPase in sea urchin embryos at the morula and the swimming blastula stage was practically the same to that in unfertilized eggs. The activity increased during the period between the mesenchyme blastula and the late gastrula stages. In embryo-wall cell fraction, which contained presumptive ectodermal cells as well as those of other cell lineages at the pre-gastrula stage and ectodermal cells at the late gastrula stage, the Na⁺, K⁺-ATPase activity increased in this developmental period more largely than in another cell fraction, containing mesenchyme cells and archenteron cells. Cycloheximide did not only block the activity increase in this period but also caused evident decrease in the activity in embryos at all examined stages. The activity increase in this period was strongly blocked by the treatment with actinomycin D, starting before the mesenchyme blastula stage, and was not seriously inhibited by the treatment starting at the mesenchyme blastula stage. The treatment starting at the initiation of gastrulation only slightly blocked further increase in the activity. Probably, an accumulation of mRNA encoding Na⁺, K⁺-ATPase occurs mainly in ectodermal cells and is completed up to the early gastrula stage.     

Effect of α,α'-dipyridyl on Exogut Formation in Vegetalized Embryos of the Sea Urchin

In presumptive vegetalized embryos, obtained by 3-hr treatment with chloramphenicol at the 16–32 cell stage, the rates of [¹⁴C]proline incorporation into the collagen fraction and production of the [¹⁴C]hydroxyproline residues increased during development between 16 hr (equivalent to mesenchyme blastula stage) and 40 hr (the early pluteus stage) after fertilization at 20°C. In presumptive vegetalized embryos, the radioactivity of [¹⁴C]hydroxyproline residues was higher at the mesenchyme blastula stage (16 hr after fertilization), but lower at the post-gastrula stage than in normal embryos. In normal embryos at the post-gastrula stage, [¹⁴C]hydroxyproline residues were mainly found in isolated spicules, and the amounts of [¹⁴C]hydroxyproline residues in other parts were much lower than in vegetalized embryos, which had few, if any, spicules. α, α'-Dipyridyl, an inhibitor of prolyl hydroxylase, inhibited the hydroxylation of [¹⁴C]proline residues in presumptive vegetalized and normal embryos, and blocked the formation of the archenteron and exogut.     

Ontogeny and regulation of matrix metalloproteinase activity in the zebrafish embryo by in vitro and in vivo zymography

Remodeling of the extracellular matrix (ECM) during development, angiogenesis, wound healing, tumor metastasis, and other morphogenetic processes depends on the exquisitely regulated activities of matrix metalloproteinases (MMPs). Yet very little is known about the activity patterns of these proteases in vivo. We have employed fluorescent MMP-substrates, both in vitro and in vivo, to characterize patterns of MMP activity in the zebrafish embryo. Qualitatively similar patterns of degradation are detected using native Type I or Type IV collagen substrates, suggesting that multiple MMPs are being regulated concomitantly. MMP activity is observed primarily in ECM-rich structures predicted to be undergoing active remodeling, such as the perichordal sheath and somite boundaries. Patterns of Type I and Type IV collagen hydrolysis are similar, but not identical in embryos of any given stage. Conventional gelatin zymography shows MMPs present in embryos as early as 3-somites (11 h) and our in vivo assays detect Type IV collagen degradation at somite boundaries as early as 4-somites (11.5 h). However, we are unable to detect significant in vitro activity using homogenates made from embryos prior to Prim-16 (31 h). Mixed lysate assays demonstrate that this is the result of endogenous inhibitors present in early embryos, suggesting a model of matrix remodeling regulated by spatially heterogeneous MMP inhibition.     

Angiogenesis is associated with collagenous protein synthesis and degradation in the chick chorioallantoic membrane.

Extracts of the chick embryo chorioallantoic membrane (CAM) obtained from 7-20 day old embryos, contained enzyme activity that could degrade type IV collagen. Peak enzyme activity was observed on days 8-10 of embryogenesis, which coincides with the stage of maximum angiogenesis. This activity decreased to lowest values at days 13-15 and increased thereafter up to day 20. Maximum rate of collagen biosynthesis in CAM was observed between days 7 and 10, with a drastic decrease at day 12, when vascular density has reached a plateau. The type IV collagen-degrading activity of CAM was of the metalloprotease type, since it was inhibited by 1,10-phenanthroline and EDTA but was also partially inhibited by serine and thiol protease inhibitors.     

Modulation of murine hemopoiesis in vivo by a synthetic hemoregulatory pentapeptide (HP 5b)

Abstract. Degeneration of the archenteron in middle gastrulae occurred in the presence of α,α'-dipyridyl or Zn²⁺, inhibitors of prolyl hydroxylase. In the presence of these substances the archenteron degenerated and was eventually destroyed. Adding Fe²⁺ to the embryo culture containing α,α'-dipyridyl protected the archenteron from further degeneration, but the collapsed archenteron was not restored to the upright position. At the late gastrula stage, α,α'-dipyridyl did not cause the degeneration of the archenteron. Treatment of the embryos by α,α'-dipyridyl, starting at the swimming blastula stage, resulted in the production of many mesenchyme-like cells but archenteron was not produced in the embryos. Addition of Fe²⁺ to α,α'-dipyridyl culture, just before the beginning of gastrulation of normal embryos, resulted in the formation of normal archenteron. α,α'-Dipyridyl inhibited hydroxylation of proline residues of collagen in sea urchin embryos and Fe²⁺ prevented the inhibition by α,α'-dipyridyl. Respiration was not inhibited by α,α'-dipyridyl.     

Acid mucopolysaccharide metabolism, the cell surface, and primary mesenchyme cell activity in the sea urchin embryo

The relationship between ³⁵SO₄ incorporation into acid mucopolysaccharides and the appearance and activity of the primary mesenchyme cells has been studied in the sea urchin, Lytechinus pictus. The ratio of the uptake of ³⁵SO₄ to its incorporation into cetylpyridinium chloride precipitable material varies over a wide range during early development, with the smallest ratio, therefore the greatest sulfation activity, being found at the early mesenchyme blastula stage. The types of mucopolysaccharides produced have not been identified, but are heterogeneous. At the mesenchyme blastula stage nearly 90% of the polysaccharides produced become sulfated. When embryos develop in sulfate-free sea water to the mesenchyme blastula stage there is a 70% decrease in the incorporation of ³H-acetate into polysaccharides and a 13-fold decrease in the ratio of sulfated to nonsulfated polysaccharides produced. Embryos raised in sulfate-free sea water develop normally to the mesenchyme blastula stage at which time there is an accumulation in the blastocoel of primary mesenchyme cells that do not migrate. The surface of the primary mesenchyme cells of sulfate-deficient embryos has a smooth appearance in the scanning electron microscope, while the surface of these cells in control embryos is rough, possibly reflecting the presence of an extracellular coat. It is suggested that there is a correlation between sulfated polysaccharide synthesis, cell surface morphology and cell movement.     

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     

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.     

Micromere descendants at the blastula stage are involved in normal archenteron formation in sea urchin embryos

Several lines of evidence suggest that micromere signaling plays a key role in endo-mesoderm differentiation along the animal-vegetal (A-V) axis in sea urchin embryos. A recent study has suggested that the activity of micromeres of inducing endoderm differentiation of mesomere descendants is, unexpectedly, maximal at the hatching blastula stage in the echinoids Scaphechinus mirabiris and Hemicentrotus pulcherrimus. In the present study, to confirm the inductive capacity of the micromere descendants in normal development, the timing of initiation of gastrulation and the elongation rate of the archenteron were examined in both micromereless embryos and in micromereless embryos cultured until the hatching blastula stage and then recombined with micromere descendants of the same age. The micromereless embryos consistently exhibited a delay in the initiation of gastrulation and a decrease in elongation rate of the archenteron, as compared with those in controls. In contrast, when the micromereless embryos cultured until the hatching blastula stage were recombined with micromere descendants of the same age, the recombinant embryos exhibited rescue of both the delay in initiation of gastrulation and a decrease in elongation rate of the archenteron. The delayed expression of alkaline phosphatase activity, an endoderm-specific marker, in the micromereless embryos was also rescued in the recombinant embryos. The recombined micromere descendants formed the larval spicules in the same schedule as that observed in the controls. These results indicate that at the hatching blastula stage, micromere descendants emanate a signal(s) required for normal gastrulation of the presumptive endo-mesodermal region.     

Identification and characterization of bone morphogenetic protein 2/4 gene from the starfish Archaster typicus

A bone morphogenetic protein 2/4 (BMP2/4) gene has been cloned from the starfish, Archaster typicus, for the purpose of investigating the expression pattern of the BMP4 gene in echinoderm embryos which do not produce micromeres. The isolated gene (named AtBMP2/4) contained two exons that encoded the entire coding region. The deduced AtBMP2/4 protein sequence contained 509 amino acids. Sequence comparison showed that it shared high amino acid similarity with sea urchin BMP2/4 and Xenopus BMP2 and BMP4. Northern blot analyses indicated that AtBMP2/4 mRNA initially appears at the blastula stage and has a maximal expression level at the gastrula stage. Whole-mount in situ hybridization revealed that AtBMP2/4 mRNA is expressed in the archenteron, coelomic vesicles, and ectodermal cells of gastrula stage embryos. The observed spatial distribution pattern vastly differs from that of sea urchin SpBMP2/4, which is expressed mainly in the oral ectoderm region of the mesenchyme blastula and early gastrula embryos.     

The role of lysyl oxidase and collagen crosslinking during sea urchin development

Lysyl oxidase, the only enzyme involved in collagen crosslinking, is shown to be present in embryos of the sea urchin Strongylocentrotus purpuratus. The enzyme specific activity increases over six-fold during development, showing the greatest rise during gastrulation and prism larva formation. The enzyme is inhibited by the specific inhibitor, beta-aminoproprionitrile (BAPN). Continuous BAPN treatment of S. purpuratus and Lytechinus pictus embryos from late cleavage stages onward increases the amount of noncrosslinked collagen present in prism larvae. When BAPN is added at the 128- or 256-cell stage it causes developmental arrest at the mesenchyme blastula stage. Embryos can be maintained in the arrested state for at least 96 h and will resume normal development and morphogenesis following BAPN removal. If BAPN is added after the mesenchyme blastula stage, it has little adverse effect on development; consequently nonspecific toxic effects of the drug are unlikely. The results suggest that lysyl oxidase and collagen crosslinking play a vital role in primary mesenchyme migration, gastrulation, and morphogenesis during sea urchin development and indicate that BAPN may be very useful in studying the extracellular matrix-cell interactions at the cellular and molecular level.     

Stimulation of Protein Synthesis in the Mitochondria of Sea Urchin Embryos before Gastrulation

A transient increase in protein synthesis was observed in mitochondria at the mesenchyme blastula stage of sea urchin ( Hemicentrotus pulcherrimus ) embryos. This stimulated activity was inhibited by chloramphenicol but not by cycloheximide. Reconstituting experiments in which poly U-dependent protein synthesis was carried out showed the mitochondrial peptide elongation factor to be essential for increasing the protein synthetic activity in mesenchyme blastula, but aminoacyl tRNA synthetase and ribosome fraction containing initiation factor not to be involved in this increase. These findings are discussed in relation to the differentiation of embryos at the gastrulation stage.     

Gastrulation in the sea urchin embryo requires the deposition of crosslinked collagen within the extracellular matrix

This study demonstrates that a collagenous extracellular matrix (ECM) is necessary for gastrulation in the sea urchin embryo. The approach taken was to disrupt collagen processing with two types of agents (a lathyritic agent, beta-aminopropionitrile (BAPN), and three types of proline analogs: dehydroproline, cis-OH-proline, and azetidine carboxylic acid) and to assess the effect on embryogenesis by morphological, immunological, and biochemical criteria. Embryos chronically exposed to either of the agents following fertilization displayed no detectable developmental abnormalities before the mesenchyme blastula stage. These embryos, however, did not gastrulate nor differentiate any further and remained at the mesenchyme blastula stage for at least 36 hr. Upon removal of the agents, the embryos resumed a normal developmental schedule and formed pluteus larvae that were indistinguishable from control embryos. By immunofluorescence studies with monospecific antibodies to type I and type IV collagens it is seen that the lathyritic agent BAPN reduces the accumulation of collagens within the ECM. This effect is confirmed and quantitated by use of an ELISA and by a biochemical determination of OH-proline. When the agents are removed from the inhibited embryos, collagen deposition returns to normal, coincident with gastrulation. Western-blot analysis, using monospecific antibodies to collagen, demonstrates that the effect of the lathyritic agent is to reduce the stability of the extracellular collagen by inhibiting the intra- and intermolecular crosslinking of collagen molecules. BAPN exhibits a dose-dependent effect on morphogenesis, but has no effect on respiration nor on protein synthesis of the embryos throughout development. Although the lathyritic agent affects collagen deposition, it is shown to not affect the expression of other molecules of the ECM, nor that of several cell surface molecules. However, a cell surface molecule that is expressed specifically in the endoderm, termed Endo 1, is not expressed in the inhibited embryos. Endo 1 is expressed after removal of the lathyritic agent and its appearance is coincident with gastrulation in the recovered embryos. These results suggest that a collagenous ECM is important for gastrulation and subsequent differentiation in the sea urchin, but not for earlier developmental processes. In addition, the dependence of Endo 1 expression on the collagenous ECM raises the possibility that this cell surface molecule is in some way regulated by interactions of the presumptive endodermal cells with the ECM.     

Gastrulation in the Sea Urchin,Strongylocentrotus purpuratus,Is Disrupted by the Small Laminin Peptides YIGSR and IKVAV

Laminin is present on the apical and basolateral sides of epithelial cells of very early sea urchin blastulae. We investigated whether small laminin-peptides, known to have cell binding activities, alter the development of sea urchin embryos. The peptide YIGSR-NH₂ (850 μM) and the peptide PA22-2 (5 μM), which contains the peptide sequence IKVAV (Tashiro et al., J. Biol. Chem. 264, 16174, 1989), typically blocked archenteron formation when added to the sea water soon after fertilization. At lower doses, the YIGSR peptide allowed invagination of the archenteron but blocked archenteron extension and differentiation and evagination of the feeding arms. The effect of YIGSR and PA22-2 peptides declined when added to progressively older stages until no effect was seen when added at the mesenchyme blastula stage (24 hours after fertilization). Control peptides GRGDS, YIGSE, and SHA22, a dodeca-peptide with a scrambled IKVAV sequence, had no effect on development. The YIGSK peptide containing a conserved amino acid modification had only a small effect on gastrulation. The results suggest that YIGSR and IKVAV peptides specifically disrupt cell/extracellular matrix interactions required for normal development of the archenteron and feeding arms. Our recent finding that YTGIR is at the cell binding site of the B1 chain of S. purpuratus laminin supports this conclusion. Evidently, laminin or other laminin-like molecules are among the many extracellular matrix components needed for the invagination and extension of the archenteron during the gastrulation movements of these embryos.     

Stage Specific Effects on Sea Urchin Embryogenesis of Zn2+, Li+, several Inhibitors of cAMP-Phosphodiesterase and Inhibitors of Protein Synthesis

Treatment of sea urchin embryos for 3 hr starting at the 16-64 cell stage with Li⁺ or 3-isobutyl-1-methylxanthine as well as with other inhibitors of cAMP-phosphodiesterase (PDE) and several inhibitors of protein synthesis, resulted in production of vegetalized embryos with a large exogut. However, the same treatment starting at other stages produced hardly any vegetalized embryos. The specific stage for these substances to cause vegetalization is probably the 16-64 cell stage. Treatment with Zn²⁺ between the times of fertilization and hatching, followed by culture in normal sea water produced animalized embryos with little if any archenteron, but the same treatment followed by culture with ethylenediamine-N, N'-diacetic acid (EDDA), a chelator of Zn²⁺, produced quasi-normal plutei. This chelator did not counteract the animalizing effect of Zn²⁺ when culture with EDDA was started at the post-gastrula stage. Treatment of embryos for a long period (1-3 days) starting at the blastula stage with Li⁺ and the inhibitors of PDE and protein synthesis, as well as with Zn²⁺, produced spherical embryos with little or no archenteron. The stages at which these substances produced abnormal embryos with a poor archenteron are post-hatching stages.     

Essential role of growth factor receptor-mediated signal transduction through the mitogen-activated protein kinase pathway in early embryogenesis of the echinoderm

In this study it was shown that growth factor receptors (GFR) play a crucial role in early embryogenesis of the echinoderms Hemicentrotus pulcherrimus and Clypeaster japonicus by transmitting signals to the mitogen-activated protein kinase (MAPK) pathway. The phosphorylation ratio of extracellular signal-regulated kinase 1 (ERK1) changed dynamically during early embryogenesis and showed a peak at the swimming blastula (sBl) stage. Suramin, an inhibitor of GFR, when applied during the sBl stage perturbed morphogenesis, including primary mesenchyme cell (PMC) migration, cell proliferation, archenteron elongation, spiculogenesis, pigment cell differentiation and phosphorylation of myosin light chains (MLC). Genistein, a receptor-type protein tyrosine kinase inhibitor, severely inhibited PMC migration, gastrulation and the phosphorylation of MLC. Manumycin A, a Ras inhibitor, inhibited spiculogenesis and invagination. PD98059, a MAPK/ERK kinase inhibitor, perturbed early PMC migration and pigment cell differentiation, but not spiculogenesis and gastrulation (although these two events were significantly delayed). PMC ingression was not perturbed by genistein, suramin, manumycin A or PD98059. All of the inhibitors perturbed the phosphorylation of ERK1, which was completely restored by exogenous platelet-derived growth factor (PDGF)-AB. PDGF-AB also partially restored elongation of the archenteron by restoring cell proliferation that had been perturbed by suramin.     

Inhibition of mitogen activated protein kinase signaling affects gastrulation and spiculogenesis in the sea urchin embryo

The mitogen activated protein (MAP) kinase signaling cascade has been implicated in a wide variety of events during early embryonic development. We investigated the profile of MAP kinase activity during early development in the sea urchin, Strongylocentrotus purpuratus, and tested if disruption of the MAP kinase signaling cascade has any effect on developmental events. MAP kinase undergoes a rapid, transient activation at the early blastula stage. After returning to basal levels, the activity again peaks at early gastrula stage and remains high through the pluteus stage. Immunostaining of early blastula stage embryos using antibodies revealed that a small subset of cells forming a ring at the vegetal plate exhibited active MAP kinase. In gastrula stage embryos, no specific subset of cells expressed enhanced levels of active enzyme. If the signaling cascade was inhibited at any time between the one cell and early blastula stage, gastrulation was delayed, and a significant percentage of embryos underwent exogastrulation. In embryos treated with MAP kinase signaling inhibitors after the blastula stage, gastrulation was normal but spiculogenesis was affected. The data suggest that MAP kinase signaling plays a role in gastrulation and spiculogenesis in sea urchin embryos.     

Mitochondrial profile densities and areas in different developmental stages of the sea urchin Sphaerechinus granularis

Mitochondrial profile densities in electronmicrographs were counted in the swimming blastula, mesenchyme blastula, gastrula and prism stages of the sea urchin embryos Sphaerechinus granularis. No numerical changes were statistically apparent. When profile areas were investigated, the mean values of the swimming blastula, the gastrula and the prism stage showed no statistical differences. However, increased areas were measured in the mesenchyme blastula stage. This increase might be related to an increase of the embryonic volumina in the mesenchyme blastula stage. In contrast to earlier reported data, the results indicate that the mitochondrial density in S. granularis embryos does not alter during development in these stages.     

A protein of the basal lamina of the sea urchin embryo

The purification, biochemical characterization and functional features of a novel extracellular matrix protein are described. This protein is a component of the basal lamina found in embryos from the sea urchin species Paracentrotus lividus and Hemicentrotus pulcherrimus . The protein has been named PI-200 K or Hp-200 K, respectively, because of the species from which it was isolated and its apparent molecular weight in SDS-PAGE under reducing conditions. It has been purified from unfertilized eggs where it is found packed within cytoplasmic granules, and has different binding affinities to type I collagen and heparin, as assessed by affinity chromatography columns. By indirect immunofluorescence experiments it was shown that, upon fertilization, the protein becomes extracellular, polarized at the basal surface of ectoderm cells, and on the surface of primary mesenchyme cells at the blastula and gastrula stages. The protein serves as an adhesive substrate, as shown by an in vitro binding assay where cells dissociated from blastula embryos were settled on 200K protein-coated substrates. To examine the involvement of the protein in morphogenesis of sea urchin embryo, early blastula embryos were microinjected with anti-200K Fab fragments and further development was followed. When control embryos reached the pluteus stage, microinjected embryos showed severe abnormalities in arms and skeleton elongation and patterning. On the basis of current results, it was proposed that 200K protein is involved in the regulation of sea urchin embryo skeletogenesis.