Signal-dependent regulation of the sea urchin skeletogenic gene regulatory network

The endoskeleton of the sea urchin embryo is produced by primary mesenchyme cells (PMCs). Maternal inputs activate a complex gene regulatory network (GRN) in the PMC lineage in a cell-autonomous fashion during early development, initially creating a uniform population of prospective skeleton-forming cells. Previous studies showed that at post-blastula stages of development, several effector genes in the network exhibit non-uniform patterns of expression, suggesting that their regulation becomes subject to local, extrinsic cues. Other studies have identified the VEGF and MAPK pathways as regulators of PMC migration, gene expression, and biomineralization. In this study, we used whole mount in situ hybridization (WMISH) to examine the spatial expression patterns of 39 PMC-specific/enriched mRNAs in Strongylocentrotus purpuratus embryos at the late gastrula, early prism and pluteus stages. We found that all 39 mRNAs (including several regulatory genes) showed non-uniform patterns of expression within the PMC syncytium, revealing a global shift in the regulation of the skeletogenic GRN from a cell-autonomous to a signal-dependent mode. In general, localized regions of elevated gene expression corresponded to sites of rapid biomineral deposition. We used a VEGFR inhibitor (axitinib) and a MEK inhibitor (U0126) to show that VEGF signaling and the MAPK pathway are essential for maintaining high levels of gene expression in PMCs at the tips of rods that extend from the ventral region of the embryo. These inhibitors affected gene expression in the PMCs in similar ways, suggesting that VEGF acts via the MAPK pathway. In contrast, axitinib and U0126 did not affect the localized expression of genes in PMCs at the tips of the body rods, which form on the dorsal side of the embryo. Our results therefore indicate that multiple signaling pathways regulate the skeletogenic GRN during late stages of embryogenesis-VEGF/MAPK signaling on the ventral side and a separate, unidentified pathway on the dorsal side. These two signaling pathways appear to be activated sequentially (ventral followed by dorsal) and many effector genes are subject to regulation by both pathways.     

3H]serotonin binding to blastula, gastrula, prism, and pluteus sea urchin embryo cells

1. The presence of serotonin binding sites in blastula, gastrula, prism, and pluteus embryos of the sea urchin, Arbacia punctulata, was investigated by the binding of radiolabelled serotonin to dissociated embryo cells. 2. [3H]serotonin binding sites were identified in prism, early pluteus, and advanced pluteus larvae, but not in blastula or gastrula embryos. 3. The ontogeny of [3H]serotonin binding activity closely parallels that of serotonin content as previously reported in Paracentrotus lividus embryos (Toneby, 1977a). 4. Results of this study support a regulatory role of serotonin in developmental processes in postgastrula sea urchin embryos.     

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.     

Skeletogenesis by transfated secondary mesenchyme cells is dependent on extracellular matrix-ectoderm interactions in Paracentrotus lividus sea urchin embryos

In the sea urchin embryo, primary mesenchyme cells (PMCs) are committed early in development to direct skeletogenesis, provided that a permissive signal is conveyed from adjacent ectoderm cells. We showed that inhibition of extracellular matrix (ECM)-ectoderm cells interaction, by monoclonal antibodies (mAb) to Pl-nectin, causes an impairment of skeletogenesis and reduced expression of Pl-SM30, a spicule-specific matrix protein. When PMCs are experimentally removed, some secondary mesenchyme cells (SMCs) switch to skeletogenic fate. Here, for the first time we studied SMC transfating in PMC-less embryos of Paracentrotus lividus. We observed the appearance of skeletogenic cells within 10 h of PMCs removal, as shown by binding of wheat germ agglutinin (WGA) to cell surface molecules unique to PMCs. Interestingly, the number of WGA-positive cells, expressing also msp130, another PMC-specific marker, doubled with respect to that of PMCs present in normal embryos, though the number of SM30-expressing cells remained constant. In addition, we investigated the ability of SMCs to direct skeletogenesis in embryos exposed to mAbs to Pl-nectin after removal of PMCs. We found that, although phenotypic SMC transfating occurred, spicule development, as well as Pl-SM30-expression was strongly inhibited. These results demonstrate that ectoderm inductive signals are necessary for transfated SMCs to express genes needed for skeletogenesis.     

Modularity and dissociation in the evolution of gene expression territories in development

SUMMARY Modularity is a salient feature of development and crucial to its evolution. This paper extends modularity to include the concept of gene expression territory, as established for sea urchin embryos. Territories provide a mechanism for partitioning of the cells of a rapidly developing embryo into functional units of a feeding larva. Territories exhibit the characteristics of modules. The paper asks if the embryo and the nonfeeding larva of the direct-developing sea urchin Heliocidaris erythrogramma are organized into gene expression territories, and if its territories correspond to the canonical territories of the pluteus. An analysis of cell lineage and gene expression data for H. erythrogramma shows that skeletogenic cell, coelomic, and vegetal plate gene expression territories are conserved, although they arise from cell lineages distinct from those of the pluteus, and the overall morphology of the larva differs from that of a pluteus. The ectoderm, as in indirect developers, is divided into territories. However, the oral ectodermal territory characteristic of the pluteus is absent in H. erythrogramma. Oral ectoderm is restored in hybrids of H. erythrogramma eggs fertilized by Heliocidaris tuberculata sperm. This indicates that embryonic modules evolve by changes in expression of dominant regulatory genes within territories and that entire modules can be eliminated in evolution of embryos.     

Identification and developmental expression of new biomineralization proteins in the sea urchin Strongylocentrotus purpuratus

The endoskeleton of the sea urchin larva is a network of calcareous rods secreted by primary mesenchyme cells (PMCs). In this study, we identified seven new biomineralization-related proteins through an analysis of a large database of gene products expressed by PMCs. The proteins include three new spicule matrix proteins (SpSM29, SpSM32, and SpC-lectin), two proteins related to the PMC-specific cell surface glycoprotein MSP130 (MSP130-related-1 and -2), and two novel proteins (SpP16 and SpP19). The genes encoding these proteins are expressed specifically by cells of the large micromere-PMC lineage and are activated zygotically beginning at the blastula stage, prior to PMC ingression. Several of the mRNAs show regulated patterns of expression within the PMC syncytium that correlate with the pattern of skeletal rod growth. This work identifies new proteins that may regulate the process of biomineralization in this tractable model system.     

Novel origins of lineage founder cells in the direct-developing sea urchin Heliocidaris erythrogramma

The lineage and fate of each blastomere in the 32-cell embryo of the direct-developing sea urchin Heliocidaris erythrogramma have been traced by microinjection of tetramethylrhodamine-dextran. The results reveal substantive evolutionary modifications of the ancestral cell lineage pattern of indirect sea urchin development. Significant among these modifications are changes in the time and order of cell lineage segregation: vegetal ectodermal founder cells consistently arise earlier than during indirect development, while internal founder cells generally segregate later and in a different sequence. Modifications have also arisen in proportions of the embryo fated to become various cell types and larval structures. Ectodermal fates, particularly vestibular ectoderm, comprise a greater proportion of the total cellular volume in H. erythrogramma. Among internal cell types, coelom consumes more and endoderm less of the remaining cellular volume than during indirect sea urchin development. Evolutionary modifications are also apparent in the positional origin of larval cell types and structures in H. erythrogramma. These include an apparent tilt in the axis of prospective cell fate relative to the animal-vegetal axis as defined by cleavage planes. Together these evolutionary changes in the cell lineage of H. erythrogramma produce an accelerated loss of dorsoventral symmetry in cell fate relative to indirect development. The extent and diversity of rearrangements in its cell lineage indicate that the non-feeding larva of H. erythrogramma is a highly modified, novel form rather than a degenerate pluteus larva. These same modifications underscore the evolutionarily flexible relationship between cell lineage, gene expression, and larval morphology in sea urchin development.     

Cloning,expression, and localization of a new member of a Paracentrotus lividus cell surface multigene family

We have isolated and characterized a cDNA clone corresponding to a new member of bep (butanol, extracted, proteins) Paracentrotus lividus multigene family coding for cell surface proteins. The cDNA, called bep3, encodes a 370 amino acid protein and shares the same structural organization in the coding region with other members of the same gene family already characterized. Expression of this clone studied by Northern blot and by whole mount hybridization shows that the bep3 messenger is transcribed during oogenesis and utilized till the gastrula stage, whereas at the prism stage, unlike other members of the same gene family, new synthesis of messenger occurs. By whole mount hybridization spatial distribution of bep3 messenger in egg and embryos is established. This messenger appears located in the animal half of the unfertilized egg and moves to the cortical zone after fertilization; it is not present in the structures derived by the vegetal part of the embryo, such as the micromeres of the 16-cell stage, the primary mesenchyme cells of the blastula, and the primary intestine of the gastrula. At the prism stage instead, hybridization of bep3 messenger is restricted to the part of the embryo that will give origin to the oral region as successively confirmed by hybridization at the pluteus stage. The result of whole mount hybridization was confirmed by Northern blot hybridization of separated meso-macromere and micromere RNAs. A Southern blot experiment demonstrates that bep3 is codified by a single copy gene. Conservation of the bep multigene family in several Mediterranean and Japanese sea urchin species has also been analyzed. © 1996 Wiley-Liss, Inc.