Expression of two mRNAs encoding EGF-related proteins identifies subregions of sea urchin embryonic ectoderm

Mechanisms of the epithelial-to-mesenchymal transition in sea urchin embryos

Sea urchin mesenchyme is composed of the large micromere-derived spiculogenetic primary mesenchyme cells (PMC), veg2-tier macromere-derived non-spiculogenetic mesenchyme cells, the small micromere-derived germ cells, and the macro- and mesomere-derived neuronal mesenchyme cells. They are formed through the epithelial-to-mesenchymal transition (EMT) and possess multipotency, except PMCs that solely differentiate larval spicules. The process of EMT is associated with modification of epithelial cell surface property that includes loss of affinity to the apical and basal extracellular matrices, inter-epithelial cell adherens junctions and epithelial cell surface-specific proteins. These cell surface structures and molecules are endocytosed during EMT and utilized as initiators of cytoplasmic signaling pathways that often initiate protein phosphorylation to activate the gene regulatory networks. Acquisition of cell motility after EMT in these mesenchyme cells is associated with the expression of proteins such as Lefty, Snail and Seawi. Structural simplicity and genomic database of this model will further promote detailed EMT research.

Gene expression patterns in a novel animal appendage: the sea urchin pluteus arm

The larval arms of echinoid plutei are used for locomotion and feeding. They are composed of internal calcite skeletal rods covered by an ectoderm layer bearing a ciliary band. Skeletogenesis includes an autonomous molecular differentiation program in primary mesenchyme cells (PMCs), initiated when PMCs leave the vegetal plate for the blastocoel, and a patterning of the differentiated skeletal units that requires molecular cues from the overlaying ectoderm. The arms represent a larval feature that arose in the echinoid lineage during the Paleozoic and offers a subject for the study of gene co-option in the evolution of novel larval features. We isolated new molecular markers in two closely related but differently developing species, Heliocidaris tuberculata and Heliocidaris erythrogramma. We report the expression of a larval arm-associated ectoderm gene tetraspanin, as well as two new PMC markers, advillin and carbonic anhydrase. Tetraspanin localizes to the animal half of blastula stage H. tuberculata and then undergoes a restriction into the putative oral ectoderm and future location of the postoral arms, where it continues to be expressed at the leading edge of both the postoral and anterolateral arms. In H. erythrogramma, its expression initiates in the animal half of blastulae and expands over the entire ectoderm from gastrulation onward. Advillin and carbonic anhydrase are upregulated in the PMCs postgastrulation and localized to the leading edge of the growing larval arms of H. tuberculata but do not exhibit coordinated expression in H. erythrogramma larvae. The tight spatiotemporal regulation of these genes in H. tuberculata along with other ontogenetic and phylogenetic evidence suggest that pluteus arms are novel larval organs, distinguishable from the processes of skeletogenesis per se. The dissociation of expression control in H. erythrogramma suggest that coordinate gene expression in H. tuberculata evolved as part of the evolution of pluteus arms, and is not required for larval or adult development.

Cell adhesion and communication: a lesson from echinoderm embryos for the exploitation of new therapeutic tools

In this chapter, we summarise fundamental findings concerning echinoderms as well as research interests on this phylum for biomedical and evolutionary studies. We discuss how current knowledge of echinoderm biology, in particular of the sea urchin system, can shed light on the understanding of important biological phenomena and in dissecting them at the molecular level. The general principles of sea urchin embryo development are summarised, mainly focusing on cell communication and interactions, with particular attention to the cell-extracellular matrix and cell-cell adhesion molecules and related proteins. Our purpose is not to review all the work done over the years in the field of cellular interaction in echinoderms. On the contrary, we will rather focus on a few arguments in an effort to re-examine some ideas and concepts, with the aim of promoting discussion in this rapidly growing field and opening new routes for research on innovative therapeutic tools.

Patterning the sea urchin embryo: gene regulatory networks, signaling pathways, and cellular interactions

We discuss steps in the specification of major tissue territories of the sea urchin embryo that occur between fertilization and hatching blastula stage and the cellular interactions required to coordinate morphogenetic processes that begin after hatching. We review evidence that has led to new ideas about how this embryo is initially patterned: (1) Specification of most of the tissue territories is not direct, but proceeds gradually by progressive subdivision of broad, maternally specified domains that depend on opposing gradients in the ratios of animalizing transcription factors (ATFs) and vegetalizing (beta-catenin) transcription factors; (2) the range of maternal nuclear beta-catenin extends further than previously proposed, that is, into the animal hemisphere, where it programs many cells to adopt early aboral ectoderm characteristics; (3) cells at the extreme animal pole constitute a unique ectoderm region, lacking nuclear beta-catenin; (4) the pluripotential mesendoderm is created by the combined outputs of ATFs and nuclear beta-catenin, which initially overlap in the macromeres, and by an undefined early micromere signal; (5) later micromere signals, which activate Notch and Wnt pathways, subdivide mesendoderm into secondary mesenchyme and endoderm; and (6) oral ectoderm specification requires reprogramming early aboral ectoderm at about the hatching blastula stage. Morphogenetic processes that follow initial fate specification depend critically on continued interactions among cells in different territories. As illustrations, we discuss the regulation of (1) the ectoderm/endoderm boundary, (2) mesenchyme positioning and skeletal growth, (3) ciliated band formation, and (4) several suppressive interactions operating late in embryogenesis to limit the fates of multipotent cells.

SpKrl: a direct target of beta-catenin regulation required for endoderm differentiation in sea urchin embryos

Localization of nuclear beta-catenin initiates specification of vegetal fates in sea urchin embryos. We have identified SpKrl, a gene that is activated upon nuclear entry of beta-catenin. SpKrl is upregulated when nuclear beta-catenin activity is increased with LiCl and downregulated in embryos injected with molecules that inhibit beta-catenin nuclear function. LiCl-mediated SpKrl activation is independent of protein synthesis, indicating that SpKrl is a direct target of beat-catenin and TCF. Embryos in which SpKrl translation is inhibited with morpholino antisense oligonucleotides lack endoderm. Conversely, SpKrl mRNA injection rescues some vegetal structures in beta-catenin-deficient embryos. SpKrl negatively regulates expression of the animalizing transcription factor, SpSoxB1. We propose that SpKrl functions in patterning the vegetal domain by suppressing animal regulatory activities.

The effect of epidermal growth factor on the fetal rabbit mandibular condyle and isolated condylar fibroblasts

The load-bearing surface of the mandibular condyle presents a unique arrangement of tissues consisting of an avascular layer composed largely of collagen bundles. Fibroblasts are interspersed amongst these bundles and are generally agreed to produce the collagen. The mechanisms controlling development of these tissues have not been determined. This study was conducted to explore the role of epidermal growth factor (EGF), which appears to be important in the development of many oral tissue types as well as in the growth and differentiation of the mandibular condyle. Superficial cells of the fibrous zone of the condyle were isolated from fetal rabbit condyles and [(3)H]thymidine incorporation into DNA measured. The application of EGF produced a significant increase in radiolabel incorporation after 2 days compared to 4 days in the controls, suggesting that EGF induced cells to enter S-phase more rapidly. Fetal condyles were also cultured on gelfoam surgical sponges for up to 21 days. Autoradiography of cultured condyles showed that cells of all three zones may potentially replicate, as indicated by incorporation of [(3)H]thymidine. All three regions displayed greater increases in cell numbers in samples exposed to EGF than in control samples. The measurement of zone thickness in condyles cultured on gelfoam sponges with or without EGF showed that this peptide was able to re-establish thickness, bringing it in line with the relation observed when the condyles were isolated initially, particularly of the intermediate zone over a period of 21 days. As very little autoradiographic labelling occurred at this time-point in any of the zones, the increase in thickness must primarily be due to matrix production. It is concluded that EGF is one factor potentially regulating both replication and differentiation in mandibular condyle and its associated cells.

SpSoxB1, a maternally encoded transcription factor asymmetrically distributed among early sea urchin blastomeres

We have identified a Sox family transcription factor, SpSoxB1, that is asymmetrically distributed among blastomeres of the sea urchin embryo during cleavage, beginning at 4th cleavage. SpSoxB1 interacts with a cis element that is essential for transcription of SpAN, a gene that is activated cell autonomously and expressed asymmetrically along the animal-vegetal axis. In vitro translated SpSoxB1 forms a specific complex with this cis element whose mobility is identical to that formed by a protein in nuclear extracts. An anti-SpSoxB1 rabbit polyclonal antiserum specifically supershifts this DNA-protein complex and recognizes a single protein on immunoblots of nuclear proteins that comigrates with in vitro translated SpSoxB1. Developmental immunoblots of total proteins at selected early developmental stages, as well as EMSA of egg and 16-cell stage proteins, show that SpSoxB1 is present at low levels in unfertilized eggs and progressively accumulates during cleavage. SpSoxB1 maternal transcripts are uniformly distributed in the unfertilized egg and the protein accumulates to similar, high concentrations in all nuclei of 4- and 8-cell embryos. However, at fourth cleavage, the micromeres, which are partitioned by asymmetric division of the vegetal 4 blastomeres, have reduced nuclear levels of the protein, while high levels persist in their sister macromeres and in the mesomeres. During cleavage, the uniform maternal SpSoxB1 transcript distribution is replaced by a zygotic nonvegetal pattern that reinforces the asymmetric SpSoxB1 protein distribution and reflects the corresponding domain of SpAN mRNA accumulation at early blastula stage (approximately 150 cells). The vegetal region lacking nuclear SpSoxB1 gradually expands so that, after blastula stage, only cells in differentiating ectoderm accumulate this protein in their nuclei. The results reported here support a model in which SpSoxB1 is a major regulator of the initial phase of asymmetric transcription of SpAN in the nonvegetal domain by virtue of its distribution at 4th cleavage and is subsequently an important spatial determinant of expression in the early blastula. This factor is the earliest known spatially restricted regulator of transcription along the animal-vegetal axis of the sea urchin embryo.

Specification of cell fate in the sea urchin embryo: summary and some proposed mechanisms

An early set of blastomere specifications occurs during cleavage in the sea urchin embryo, the result of both conditional and autonomous processes, as proposed in the model for this embryo set forth in 1989. Recent experimental results have greatly illuminated the mechanisms of specification in some early embryonic territories, though others remain obscure. We review the progressive process of specification within given lineage elements, and with reference to the early axial organization of the embryo. Evidence for the conditional specification of the veg2 lineage subelement of the endoderm and other potential interblastomere signaling interactions in the cleavage-stage embryo are summarized. Definitive boundaries between mesoderm and endoderm territories of the vegetal plate, and between endoderm and overlying ectoderm, are not established until later in development. These processes have been clarified by numerous observations on spatial expression of various genes, and by elegant lineage labeling studies. The early specification events depend on regional mobilization of maternal regulatory factors resulting at once in the zygotic expression of genes encoding transcription factors, as well as downstream genes encoding proteins characteristic of the cell types that will much later arise from the progeny of the specified blastomeres. This embryo displays a maximal form of indirect development. The gene regulatory network underlying the embryonic development reflects the relative simplicity of the completed larva and of the processes required for its formation. The requirements for postembryonic adult body plan formation in the larval rudiment include engagement of a new level of genetic regulatory apparatus, exemplified by the Hox gene complex.

Expression of S9 and actin CyIIa mRNAs reveals dorso-ventral polarity and mesodermal sublineages in the vegetal plate of the sea urchin embryo

We have used whole amount in situ hybridization to analyze the patterns of expression of two genes, S9 and actin CyIIa, during the development of the sea urchin, Strongylocentrotus purpuratus. We demonstrate that at the late blastula stage, these two mRNAs are expressed specifically by cells of the vegetal plate. Their domains of expression, however, are different. S9 mRNA is broadly distributed within most of the vegetal plate except for the central region, while CyIIa expression is restricted to a population of 10-15 cells in the ventral region of the plate. S9-expressing secondary mesenchyme cells (SMCs) migrate from the vegetal plate into the blastocoel early in gastrulation and later populate the dorsal ectoderm. The numbers, morphology, and migratory behavior of these cells strongly suggest that they are pigment cells. Throughout gastrulation, CyIIa mRNA is expressed by a population of presumptive SMCs at the ventral aspect of the archenteron tip. The pattern of expression of this mRNA is dynamic, however, and by the early pluteus stage, CyIIa mRNA accumulates in primary mesenchyme cells (PMCs), SMCs, and endodermal cells of the gut. When embryos are treated with NiCl2, a compound that has been shown to ventralize other embryonic tissues, CyIIa mRNA is expressed by an increased number of cells in the vegetal plate in a radially symmetrical pattern. The spatial pattern of CyIIa expression provides the first direct molecular evidence that the vegetal plate is polarized along the dorso-ventral (D-V) axis of the embryo. This gene product should be a valuable marker in future studies of D-V axis specification, as it can be detected at earlier developmental stages than existing molecular markers of this axis. Our observations show that the vegetal plate consists of subterritories of gene expression, and provide further support for the view that diversification of the presumptive, non-skeletogenic mesoderm begins prior to the onset of invagination.

SpFGFR, a new member of the fibroblast growth factor receptor family, is developmentally regulated during early sea urchin development

We describe the cloning of a new fibroblast growth factor receptor, SpFGFR1, that is differentially regulated at the level of transcript abundance during sea urchin embryogenesis. Sequence representing the conserved tyrosine kinase domain was obtained by reverse transcription-polymerase chain reaction using degenerate primers, and the entire open reading frame was obtained by standard cDNA library screening methods. SpFGFR contains a series of domains characteristic of FGFRs: three immunoglobulin-like motifs, an acid box, a transmembrane domain, a relatively long juxtamembrane sequence, a split tyrosine kinase domain, and two conserved intracellular tyrosine residues. Alternative splicing of SpFGFR generates two variants (Ig3L and Ig3S), which differ by insertion in the center of the Ig3 domain of 34 extra amino acids, encoded by an additional exon. Transcripts encoding both variants accumulate when morphogenesis begins with mesenchyme cell ingression and gastrulation. SpFGFR transcripts accumulate in all cell types of the embryo, although in situ hybridization shows that they are somewhat enriched in cells of oral ectoderm and endoderm. Transcripts encoding the Ig3S variant, whose structure resembles more closely that of vertebrate receptors, are enriched in endomesoderm, suggesting that the SpFGFR variants could play distinct roles in the sea urchin embryo.

Promoter analysis meets pattern formation: transcriptional regulatory genes in sea urchin embryogenesis

Analyses of spatial and temporal gene control mechanisms in the sea urchin embryo have identified several important trans-regulatory factors, including some that are related to known developmental control genes of the fly and mouse. Recent advances in gene perturbation technologies, including the use of antisense oligonucleotides to target mRNAs in early-stage embryos, as well as the injection of mRNAs into zygotes to express genes ectopically, have made it possible to test the functions of such factors directly.

A POU gene required for early cleavage and protein accumulation in the sea urchin embryo

SpOct is a POU gene expressed during oogenesis and early embryogenesis of the sea urchin, Strongylocentrotus purpuratus. In the first use of antisense technology in the sea urchin embryo, we report that disruption of SpOct gene function in 1-cell zygotes by the injection of antisense oligodeoxynucleotides arrests development prior to the first cell division. We show that single-stranded antisense oligodeoxynucleotides specifically block cleavage, and that injection of SpOct mRNA overcomes this block. The accumulation of [35S]methionine into zygotically synthesized protein is significantly reduced in antisense-injected embryos. DNA synthesis is also reduced by the antisense regimen as expected from the antisense inhibition of protein accumulation. That protein accumulation prior to the first cleavage is retarded by antisense targeting of a transcription factor is very surprising in light of classical work showing that the activation of protein synthesis does not require zygotic transcription. We conclude that either some new transcription is obligate for the accumulation of new protein, or that the SpOct gene plays a novel, non-transcriptional role in this process.

Size regulation and morphogenesis: a cellular analysis of skeletogenesis in the sea urchin embryo

The formation of the skeleton is a central event in sea urchin morphogenesis. The skeleton serves as a framework for the larval body and is the primary determinant of its shape. Previous studies have shown that the size of the skeleton is invariant despite wide experimentally induced variations in the number of skeleton-forming primary mesenchyme cells (PMCs). In the present study, we have used PMC transplantation, fluorescent cell markers and confocal laser scanning microscopy to analyze cellular aspects of skeletal patterning. Labeling of embryos with 5-bromodeoxyuridine demonstrates that the entire embryonic phase of skeletal morphogenesis occurs in the absence of PMC division. During embryogenesis, skeletal rods elongate by one of two mechanisms; either preceded by a cluster (plug) of PMCs or by extending along an existing PMC filopodial cable. Elongation of skeletal rods occurs exclusively by the addition of new material at the rod tips, although radial growth (increase in rod thickness) occurs along the length of the rods. Photoablation of a distinctive region of ectoderm cells at the arm tip results in an inhibition of skeletal rod elongation, indicating that a local ectoderm-PMC interaction is required for skeletal growth. The regulation of skeletal patterning was also examined in embryos that had been microinjected with additional PMCs and in half-sized larvae derived from blastomeres isolated at the 2-cell stage. Microinjection of 50–100 PMCs into the blastocoel at the mesenchyme blastula stage leads to an increase in the numbers of PMCs along all skeletal rods and a two-fold increase in the number of cells in the plugs, yet no increase in the length of the skeletal rods. The length of the anal rods can, however, be increased by microinjecting developmentally ‘young’ PMCs into the arm tips of late stage embryos. We find that the rate of skeletal rod elongation is independent of both the mode of rod growth (chain or plug) and the number of PMCs in the plug at the growing rod tip. Instead, the rate of elongation appears to be strictly regulated by the quantity of ectodermal tissue present in the embryo. These studies provide new information concerning normal mechanisms of skeletal growth and patterning and lead us to propose a model for the regulation of skeleton size based upon an intrinsic PMC ‘clock’ and an ectoderm-derived signal that regulates the rate of skeletal rod elongation.

Sea urchin maternal mRNA classes with distinct development regulation

Previous studies of newly synthesized proteins during early development in sea urchins have revealed several different patterns of synthesis that can be used to predict the existence of mRNA classes with distinct regulatory controls. We have identified clones for abundant maternal mRNAs that are actively translated during early development by screening a cDNA library prepared from polysomal poly(A)+RNA isolated from 2-cell stage (2-hour) Strongylocentrotus purpuratus embryos. Probes prepared from these cDNA clones and several previously characterized maternal mRNA cDNAs were used to compare relative levels of individual mRNAs in eggs and embryos and their translational status at various developmental stages. These abundant mRNAs can be classified into two major groups which we have termed cleavage stage-specific (CSS) and post cleavage stage (PCS) mRNAs. The relative levels of the CSS mRNAs are highest during the rapid cleavage stage and decrease dramatically at the blastula stage (12-hours). In contrast, PCS mRNAs are present at relatively low levels during the rapid cleavage stage and then increase at the blastula stage. Polysome partition profiles reveal that CSS mRNAs are translated more efficiently than PCS mRNAs in the unfertilized egg, at fertilization, and during the cleavage stages. Following the blastula stage, some CSS transcripts move out of polysomes and accumulate as untranslated RNAs, while newly transcribed PCS mRNAs are recruited into polysomes. These data suggest that the rapid cell cycles following fertilization require high levels of specific cleavage stage proteins, and the synthesis of these proteins occurs preferentially over PCS mRNAs.

Differential expression of the msp130 gene among skeletal lineage cells in the sea urchin embryo: a three dimensional in situ hybridization analysis

In order to examine the ontogeny of tissue-specific expression of the msp130 gene during early embryogenesis of the sea urchin, we have developed a whole-mount, non-radioactive in situ hybridization protocol suitable for these embryos. This protocol is adapted from the existing technology of immunohistochemical localization of digoxygenin-labelled hybridization probes in tissue sections. Transcript distribution patterns in the whole embryo are seen in three dimensions, and at much higher resolution and sensitivity than can be achieved using radioactive probes and sectioned material. We have traced the ontogeny of expression of the skeleton-specific gene, msp130, during the development of Strongylocentrotus purpuratus. Transcripts are first detected at the blastula stage, in micromere-lineage cells just prior to ingression. Appearance of msp130 transcripts remains strictly limited to this lineage through the pluteus stage. Estimated from the relative intensity of staining of the PMCs of an embryo, the relative abundance of msp130 transcripts is uniform among the 32 cells of this lineage in secondary mesenchyme blastulae and in gastrulae, indicating that expression is homogeneous among these cells up to the early prism stage. However, the relative intensity of stain, and therefore abundance of transcripts, changes dramatically and in a consistent pattern among the PMCs of an embryo during prism and pluteus stages, suggesting that these cells switch from an autonomous mode of regulation of the msp130 gene, to an inductive mode. In the pluteus larva, the highest levels of expression occur in those cells associated with the rapidly growing tips of the spicular skeleton.

Expression of spatially regulated genes in the sea urchin embryo

Spatially controlled genes expressed in the early sea urchin embryo have been characterized, and the patterns of expression in terms of the mechanisms by which this embryo accomplishes its initial set of founder cell specifications are the subject of current discussion. Sea urchin transcription factors that have been cloned are classified with respect to their target sites and the genes they regulate. Among the best known of the sea urchin cis-regulatory systems is that controlling expression of the Cyllla gene, which encodes an aboral ectoderm-specific cytoskeletal actin. The Cyllla regulatory domain includes approximately 20 sites of DNA-protein interaction, serviced by about ten different factors. Certain of these factors are known to negatively control spatial expression, while others positively regulate temporal activation and the level of Cyllla gene expression. Differential, lineage-specific gene expression is instituted in the sea urchin embryo by mid-late cleavage, prior to any cell migration or overt differentiation, and shortly following lineage segregation.

Spatial expression of the hatching enzyme gene in the sea urchin embryo

The sea urchin embryo at the blastula stage hatches from its protective fertilization envelope which is degraded by a secreted protease, the hatching enzyme. We have previously purified the hatching enzyme from Paracentrotus lividus (Lepage and Gache (1989). J. Biol. Chem. 264, 4787-4793), cloned its cDNA, and analyzed the temporal expression of its gene (Lepage and Gache (1990). EMBO J. 9, 3003-3012). We study here the temporal and spatial expression of the hatching enzyme gene in whole embryos by immunolabeling with an affinity-purified polyclonal antibody and by in situ hybridization using nonradioactive RNA probes. The timing of expression is consistent with our data on the activation of the gene, the mRNA accumulation in the blastula, and the role of the enzyme. Immunolabeling was observed only in blastula stage embryos; neither before the 128-cell stage nor after hatching. The distribution of the enzyme varies with time from a diffuse labeling around the nucleus to a punctate localization between the nucleus and the apical face of the blastomeres, and finally at the time of hatching, to a submembranous apical location. Not all the cells of an embryo are labeled. The presence of the hatching enzyme is restricted to a sharply delimited continuous territory spanning about two-thirds of the blastula. The orientation of this territory has been determined with respect to the animal-vegetal axis of the embryo using as a landmark the subequatorial pigmented band of the P. lividus species. The synthesis of the hatching enzyme only takes place in the animal-most two-thirds of the blastula. By in situ hybridization, the mRNA coding for the hatching enzyme is only detected in early blastulas, in a limited area having the same size and shape as the territory in which the protein is found. Thus the hatching enzyme gene is likely to be spatially controlled at the transcriptional level: its expression is restricted to a region of the blastula that corresponds roughly to the presumptive ectoderm territory. To date, the hatching enzyme gene products constitute the earliest molecular markers of the sea urchin embryo spatial organization along the primordial egg axis.

Tissue-restricted accumulation of a ribosomal protein mRNA is not coordinated with rRNA transcription and precedes growth of the sea urchin pluteus larva

We have identified an mRNA that encodes a protein, SpS24, of the small ribosomal subunit in the sea urchin, Strongylocentrotus purpuratus. RNA blot and in situ hybridization analyses show that the SpS24 gene is active during early oogenesis, downregulated in the mature egg and during cleavage, and reactivated in the early blastula. The mRNA then increases in abundance at least 100-fold. Later in development, expression of SpS24 mRNA becomes restricted primarily to cells in the oral ectoderm and endoderm of the pluteus larva, and the message is undetectable in aboral ectoderm cells and most mesenchyme cells. To determine whether transcription of the ribosomal RNA genes occurs at a higher rate in oral ectoderm and endoderm tissues, a probe for the transcribed spacer was used in RNase protection and in situ hybridization assays. High concentrations of rRNA-processing intermediates were observed in unfertilized eggs and shown to reside primarily, if not exclusively, in the cytoplasm. The spatial and temporal distributions of these sequences strongly suggest that they are associated with heavy bodies. New embryonic rRNA transcripts are first detectable at the very early blastula stage. In later embryos, the content of this transcribed spacer sequence is similar in all but a few cells, which implies that they synthesize rRNA at a similar low rate. Comparison of available estimates of rRNA transcription rate with the potential rate of SpS24 protein synthesis, calculated from SpS24 mRNA prevalence, shows that oral ectoderm and endoderm cells have the capacity to synthesize 15- to 30-fold more SpS24 protein than is required to keep pace with rRNA synthesis in these cells. Because the sea urchin embryo develops from an egg to a pluteus larva in the absence of growth, this stockpiling of SpS24 mRNA anticipates rather than accompanies the onset of growth, which does not begin until after feeding. Upregulation of this gene is therefore part of the developmental program, rather than a physiological response to nutrient availability.

Fibropellins, products of an EGF repeat-containing gene, form a unique extracellular matrix structure that surrounds the sea urchin embryo

The sea urchin SpEGF 1 gene belongs to a growing family of developmentally important genes which encode proteins that contain repeated epidermal growth factor-like motifs. To characterize the embryonic expression of the protein products of this gene from Strongylocentrotus purpuratus, we generated polyclonal antisera from SpEGF I fusion proteins. These antibodies recognize two glycoproteins of 145 and 185 kDa, which we have named fibropellins. These proteins are present in unfertilized oocytes and throughout early development. The fibropellins are stored in cytoplasmic vesicles in the oocyte and are released soon after fertilization in a distinct secretory event following the exocytosis of cortical granule contents. Following secretion the proteins are localized in the basal surface of the hyaline layer. At the blastula stage the fibropellins become organized into distinct fibers which form a mesh-like network over the surface of the embryo. During subsequent development to the pluteus larva stage this network increases in overall morphological complexity and becomes regionally distinct. The molecular weights of the fibropellins and their pattern of embryonic localization indicate that these proteins form a component of the hyaline layer previously described as the apical lamina.