Inhibition of cell migration in sea urchin embryos by beta-D-xyloside

RNA-Seq identifies SPGs as a ventral skeletal patterning cue in sea urchins

The sea urchin larval skeleton offers a simple model for formation of developmental patterns. The calcium carbonate skeleton is secreted by primary mesenchyme cells (PMCs) in response to largely unknown patterning cues expressed by the ectoderm. To discover novel ectodermal cues, we performed an unbiased RNA-Seq-based screen and functionally tested candidates; we thereby identified several novel skeletal patterning cues. Among these, we show that SLC26a2/7 is a ventrally expressed sulfate transporter that promotes a ventral accumulation of sulfated proteoglycans, which is required for ventral PMC positioning and skeletal patterning. We show that the effects of SLC perturbation are mimicked by manipulation of either external sulfate levels or proteoglycan sulfation. These results identify novel skeletal patterning genes and demonstrate that ventral proteoglycan sulfation serves as a positional cue for sea urchin skeletal patterning.

Glycobiology of reproductive processes in marine animals: the state of the art

Glycobiology is the study of complex carbohydrates in biological systems and represents a developing field of science that has made huge advances in the last half century. In fact, it combines all branches of biomedical research, revealing the vast and diverse forms of carbohydrate structures that exist in nature. Advances in structure determination have enabled scientists to study the function of complex carbohydrates in more depth and to determine the role that they play in a wide range of biological processes. Glycobiology research in marine systems has primarily focused on reproduction, in particular for what concern the chemical communication between the gametes. The current status of marine glycobiology is primarily descriptive, devoted to characterizing marine glycoconjugates with potential biomedical and biotechnological applications. In this review, we describe the current status of the glycobiology in the reproductive processes from gametogenesis to fertilization and embryo development of marine animals.

Oral-aboral patterning and gastrulation of sea urchin embryos depend on sulfated glycosaminoglycans

Glycosaminoglycans (GAGs) are a heavily sulfated component of the extracellular matrix (ECM) implicated in a variety of cell signaling events involved in patterning of embryos. Embryos of the sea urchin Strongylocentrotus purpuratus were exposed to several inhibitors that disrupt GAG function during development. Treatment with chlorate, a general inhibitor of sulfation that leads to undersulfated GAGs, reduced sulfation of the urchin blastocoelar ECM. It also prevented correct specification of the oral-aboral axis and mouth formation, resulting in a radialized phenotype characterized by the lack of an oral field, incomplete gastrulation and formation of multiple skeletal spicule rudiments. Oral markers were initially expressed in most of the prospective ectoderm of chlorate-treated early blastulae, but then declined as aboral markers became expressed throughout most of the ectoderm. Nodal expression in the presumptive oral field is necessary and sufficient to specify the oral-aboral axis in urchins. Several lines of evidence suggest a deregulation of Nodal signaling is involved in the radialization caused by chlorate: (1) Radial embryos resemble those in which Nodal expression was knocked down. (2) Chlorate disrupted localized nodal expression in oral ectoderm, even when applied after the oral-aboral axis is specified and expression of other oral markers is resistant to treatment. (3) Inhibition with SB-431542 of ALK-4/5/7 receptors that mediate Nodal signaling causes defects in ectodermal patterning similar to those caused by chlorate. (4) Intriguingly, treatment of embryos with a sub-threshold dose of SB-431542 rescued the radialization caused by low concentrations of chlorate. Our results indicate important roles for sulfated GAGs in Nodal signaling and oral-aboral axial patterning, and in the cellular processes necessary for archenteron extension and mouth formation during gastrulation. We propose that interaction of the Nodal ligand with sulfated GAGs limits its diffusion, and is required to specify an oral field in the urchin embryo and organize the oral-aboral axis.

A novel approach to study adhesion mechanisms by isolation of the interacting system

For decades most investigations into mechanisms of adhesive interactions have examined whole organisms or single cells. Results using whole organisms are often unclear because it may not be known if a probe used in an experiment is directly affecting the cellular interaction under study or if it is an indirect effect resulting from action on some other structure or pathway. Here we develop a novel approach to isolate the structural components of a cellular interaction by dissecting them out of the organism to study them in a pristine environment away from all confounding factors. We used the adhesion between the archenteron and blastocoel roof of the sea urchin gastrula stage embryo as a model that can be replicated in many other developmental and pathological systems. The isolated components of the cellular interaction and those in the whole organism possessed identical cell surface receptors and adhesive affinities.

Embryos of the sea urchin Strongylocentrotus purpuratus synthesize a dermatan sulfate enriched in 4-O- and 6-O-disulfated galactosamine units

Unfertilized eggs of the sea urchin Strongylocentrotus purpuratus are surrounded by a gelatinous layer rich in sulfated fucan. Shortly after fertilization this polysaccharide disappears, but 24 h later the embryos synthesize high amounts of dermatan sulfate concomitantly with the mesenchyme blastula-early gastrula stage when the larval gut is forming. This glycosaminoglycan has the same backbone structure [4-alpha-L-IdoA-1-->3-beta-D-GalNAc-1](n) as the mammalian counterpart but possesses a different sulfation pattern. It has a high content of 4-O- and 6-O-disulfated galactosamine units. In addition, chains of this dermatan sulfate are considerable longer than those of vertebrate tissues. Adult sea urchin tissues contain high concentrations of sulfated polysaccharides, but dermatan sulfate is restricted to the adult body wall where it accounts for approximately 20% of the total sulfated polysaccharides. In addition, sulfation at the 4-O-position decreases markedly in the dermatan sulfate from adult sea urchin when compared with the glycan from larvae. Overall, these results demonstrate the occurrence of dermatan sulfates with unique sulfation patterns in this marine invertebrate. The physiological implication of these oversulfated dermatan sulfates is unclear. One hypothesis is that interactions between components of the extracellular matrix in marine invertebrates occur at higher salt concentrations than in vertebrates and therefore require glycosaminoglycans with increased charge density.

Cloning and characterization of cDNA for syndecan core protein in sea urchin embryos

The cDNA for the core protein of the heparan sulfate proteoglycan, syndecan, of embryos of the sea urchin Anthocidaris crassispina was cloned and characterized. Reverse transcription-polymerase chain reaction (RT-PCR) was used with total ribonucleic acid (RNA) from late gastrula stage embryos and degenerate primers for conserved regions of the core protein, to obtain a 0.1 kb PCR product. A late gastrula stage cDNA library was then screened using the PCR product as a probe. The clones obtained contained an open reading frame of 219 amino acid residues. The predicted product was 41.6% identical to mouse syndecan-1 in the region spanning the cytoplasmic and transmembrane domains. Northern analysis showed that the transcripts were present in unfertilized eggs and maximum expression was detected at the early gastrula stage. Syndecan mRNA was localized around the nuclei at the early cleavage stage, but was then found in the ectodermal cells of the gastrula embryos. Western blotting analysis using the antibody against the recombinant syndecan showed that the proteoglycan was present at a constant level from the unfertilized egg stage through to the pluteus larval stage. Immunostaining revealed that the protein was expressed on apical and basal surfaces of the epithelial wall in blastulae and gastrulae.

Pamlin-induced tyrosine phosphorylation of SUp62 protein in primary mesenchyme cells during early embryogenesis in the sea urchin, Hemicentrotus pulcherrimus

Ingression of primary mesenchyme cells (PMC) is associated with the encounter of basal lamina including pamlin. It was found that sea urchin embryos have a protein that binds antihuman focal adhesion kinase (FAK) antibodies, yet it has a 62 kDa homo-dimeric structure. Thus, this protein was distinctive from known FAK, and was named SUp62. In mesenchyme blastulae, one of the subunits increased its apparent molecular mass slightly but distinctively, then restored the original molecular mass in early gastrulae. This temporal and stage-specific shifting of the molecular mass was associated with the occurrence of tyrosine phosphorylation of a subunit that did not increase the apparent molecular mass. Herbimycin A induced the hyperphosphorylation of tyrosine residues of SUp62, and inhibited the occurrence of molecular mass shifting. Immunohistochemistry showed a strong positive signal of SUp62 and phosphotyrosine in PMC. Herbimycin A also severely but reversibly inhibited PMC dissociation, migration and gastrulation. Tyrosine phosphorylation of SUp62 was induced when PMC were incubated with pamlin in vitro, and it was initiated within 10 min after onset of the incubation. It reached its peak in 1 h, and declined gradually in the next 1 h, indicating that pamlin-induced tyrosine phosphorylation of SUp62 occurs closely associated with acquiring PMC migration activity.

Regulative specification of ectoderm in skeleton disrupted sea urchin embryos treated with monoclonal antibody to Pl-nectin

Pl-nectin is a glycoprotein first discovered in the extracellular matrix (ECM) of Paracentrotus lividus sea urchin embryo, apically located on ectoderm and endoderm cells. The molecule has been described as functioning as an adhesive substrate for embryonic cells and its contact to ectoderm cells is essential for correct skeletogenesis. The present study was undertaken to elucidate the biochemical characteristics of Pl-nectin and to extend knowledge on its in vivo biological function. Here it is shown that the binding of mesenchyme blastula cells to Pl-nectin-coated substrates was calcium dependent, and reached its optimum at 10 mM Ca2+. Perturbation studies using monoclonal antibody (McAb) to Pl-nectin, which prevent ectoderm cell-Pl-nectin contact, show that dorsoventral axis formation and ectoderm differentiation were retarded. At later stages, embryos recovered and, even if growth and patterning of the skeleton was greatly affected, the establishment of dorsoventral asymmetry was reached. Similarly, the expression of specific ectoderm and endoderm territorial markers was achieved, although occurring with some delay. Endoderm differentiation and patterning was not obviously affected. These results suggest that both endoderm and ectoderm cells have regulative capacities and differentiation of territories is restored after a lag period. On the contrary, failure of inductive differentiation of the skeleton cannot be rescued, even though the ectoderm has recovered.

Cell-substrate interactions during sea urchin gastrulation: migrating primary mesenchyme cells interact with and align extracellular matrix fibers that contain ECM3, a molecule with NG2-like and multiple calcium-binding domains

The migratory primary mesenchyme cells (PMCs) of the sea urchin embryo are a model experimental system for the analysis of cell-extracellular matrix (ECM) interactions. Although the behavior of PMCs during gastrulation has been analyzed in considerable detail, it has proven difficult to identify specific substrate molecules with which these cells interact. Here, using a new monoclonal antibody (2.5C4) generated by an in vitro immunization procedure, we show that migrating PMCs interact with a distinct class of ECM fiber. The 2.5C4-positive fibers are distributed in a vegetal (high) to animal (low) gradient on the basal surface of the ectoderm. Three observations indicate that PMC filopodia interact directly with the fibers: (1) During gastrulation, 2.5C4-positive fibers gradually become oriented in a prominent circumferential belt that corresponds precisely to the position of the subequatorial PMC ring. (2) This fiber pattern is blocked by microsurgical removal of PMCs but is restored if PMCs are reintroduced into the embryo. (3) Examination of immunostained embryo whole mounts by confocal microscopy reveals a striking association between PMC filopodial roots and foci of fiber bundling. Double-immunostaining experiments using 2.5C4 and antibodies against previously identified matrix constituents show that the protein ECM3 is a component of the fibers. We have determined the complete amino acid sequence of ECM3 and find that this large protein (3103 amino acids) consists of an N-terminal domain similar to the mammalian chondroitin sulfate proteoglycan core protein NG2, a central region composed of five tandem repeats of a domain contained within the regulatory Ca2+-binding loop of Na+-Ca2+ exchange proteins, and a C-terminal region with no homology to known proteins. The general structure of ECM3 is similar in several respects to that of a sponge protein, MAFp4. MAFp4 is a major component of aggregation factor, an ECM complex that mediates the calcium-dependent, species-specific sorting of sponge cells. These studies establish ECM3 as a strong candidate for a PMC substrate molecule and point to several possible mechanisms by which interactions between PMC filopodia and ECM3-containing fibers could provide guidance information to migrating PMCs.

Cell movements in the sea urchin embryo

Recent studies show that gastrulation in the sea urchin embryo involves movement of cells over the blastopore lip (involution). Some cells in the vegetal plate of the late blastula become bottle-shaped but they play a limited role in gastrulation. The functions of specific integrins, regulators of cell-cell adhesion, and extracellular matrix components in gastrulation are currently being analyzed. In addition, light-microscopic studies continue to provide a unique picture of dynamic cell behavior in vivo.

Protein tyrosine kinase activity following fertilization is required to complete gastrulation, but not for initial differentiation of endoderm and mesoderm in the sea urchin embryo

The egg activation process functions to implement developmental programs that act much later in embryogenesis. One example of this is the fact that application of protein tyrosine kinase inhibitors to the fertilized sea urchin egg for a 15-min period results in a defect in the gastrulation process occurring over 24 h later (Kinsey, W. H., Dev. Biol. 172, 704-707, 1995). In the present study, we show that the window of sensitivity is not due to differential uptake of inhibitor, and establish that the inhibitor inhibits tyrosine kinase activity at the time of application. We also demonstrate that inhibition of protein tyrosine kinase activity in the zygote causes a specific defect in the morphogenetic movements associated with gastrulation without interfering with the initial specification and differentiation of endoderm and mesoderm. Differentiation events occurring concurrent with or subsequent to gastrulation were also suppressed in embryos derived from treated zygotes. These findings indicate that fertilization initiates a signaling cascade involving protein tyrosine kinase activity that is required specifically for events at gastrulation. This signaling event is required to complete the developmental program of both endoderm and mesoderm, but is different from those events necessary for initial specification of endodermal and mesodermal cell fate.

Isolation and characterization of an endodermally derived, proteoglycan-like extracellular matrix molecule that may be involved in larval starfish digestive tract morphogenesis

A monoclonal antibody, anti-Pisaster matrix-1 (anti-PM1) has been developed against an extracellular matrix antigen, Pisaster matrix-1 (PM1) found in embryos and larvae of the starfish Pisaster ochraceus. Pisaster matrix-1 was first observed in endodermal cells of the early gastrula, and shortly thereafter it was secreted into the blastocoel where it accumulated steadily during gastrulation. During the late gastrula stage it also appeared in the extracellular matrix (ECM) of the gut lumen. Immunogold electron microscopy with anti-PM1 revealed that PM1 was found in condensations of ECM associated with blastocoel matrix fibers, in the trans Golgi network, in Golgi-associated vesicles in endoderm and mesenchyme cells and throughout the ECM lining the digestive tract of late gastrula and bipinnaria larvae. When blastula or early gastrula stage embryos were grown in the presence of the PM1 antibody, archenteron elongation, bending and mouth formation failed to occur. Pisaster matrix-1 stained with alcian blue and its assembly could be disrupted with the common inhibitor of O-linked glycosaminoglycan assembly, beta-xyloside but not by tunicamycin. It was not sensitive to enzymes that degrade vertebrate proteoglycans. Pisaster matrix-1 is a large (600 kDa) proteoglycan-like glycosaminoglycan, secreted exclusively by endodermal and/or endodermally derived cells that may be necessary for morphogenesis of the mouth and digestive tract of Pisaster ochraceus embryos/larvae.

Regulated exocytosis and sequential construction of the extracellular matrix surrounding the sea urchin zygote

After fertilization most eggs become surrounded by a complex extracellular matrix. This study examines those matrix assembly processes that are triggered by fertilization of the sea urchin egg. The study uses antibodies that identify five different storage compartments in the egg. These compartments release their protein contents in a highly regulated fashion to assemble and modify the extraembryonic layers. The exocytosis sequence begins with a fertilization wave that progresses from the site of sperm entry and elevates the fertilization envelope above a water-filled perivitelline space. The immediate surface of the zygote then becomes covered by a newly secreted hyaline layer. Prior to fertilization some of the antigens are localized to cortical granules. Others are found in "basal laminar vesicles" that are released in a wave beginning at about 30 sec, or roughly at the same time as cortical granule exocytosis. The remaining antigens are exocytosed with a rather precise timing, but with a delay of several to tens of minutes relative to the first wave of exocytosis. "Apical vesicles," so named because antigens from this class are preferentially exocytosed toward the apical cell surface of polarized cells, include antigens that are exocytosed beginning at about 5 min postfertilization. The fourth compartment, named "echinonectin vesicles" release echinonectin, a protein that is deposited to the inner side of the hyaline layer. Surface staining of echinonectin is first detected about 10-15 min following sperm contact. Finally, maternal cadherin, which is stored in yet a fifth distinct compartment, is not detected on the surface until at least 30 min following fertilization. The data are also consistent with the notion that the tightly regulated timing of exocytosis contributes to the ordered assembly of the hyaline layer and elevation of the fertilization envelope. Finally, two of the vesicle classes continue to exocytose after the cells become polarized. In polarized cells apical and basal laminar antigens are trafficked toward opposite sides of the same cell after passing through the same trans-Golgi network-like compartment.

PG-M/versican-like proteoglycans are components of large disulfide-stabilized complexes in the axolotl embryo

Large disulfide-stabilized proteoglycan complexes were previously shown to be synthesized by the epidermis of axolotl embryos during stages crucial to subepidermal migration of neural crest cells. We now show that the complexes contain PG-M/versican-like monomers in addition to some other component with low buoyant density. Metabolically 35S-labeled proteoglycans were extracted from epidermal explants and separated by size exclusion chromatography and density equilibrium gradient centrifugation. The complexes, which elute in the void volume on Sepharose CL-2B, were recovered at buoyant density 1.42 g/ml in CsCl gradients, whereas the monomer proteoglycans, which could only be liberated from the complexes by reduction, had a higher buoyant density (1.48 g/ml). The native complexes did not aggregate with hyaluronan. The purified complexes reacted with antibodies against a portion of a cloned PG-M/versican-like axolotl proteoglycan. These antibodies were found to stain the subepidermal matrix of axolotl embryos, suggesting that the proteoglycan complexes are encountered by neural crest cells during subepidermal migration. From Western blot analysis, the core protein of the PG-M/versican-like monomers was found to be of similar size ( approximately 500 kDa) as those of PG-M/versican variants of other species. Another chondroitin sulfate proteoglycan that was present in small amounts in the epidermal extracts was found to be distinctly different from the similarly sized PG-M/versican-like monomers.

Localization and characterization of blastocoelic extracellular matrix antigens in early sea urchin embryos and evidence for their proteolytic modification during gastrulation

Previously, results were presented showing a spatiotemporal expression of matrix metalloproteases consistent with a role in remodeling the blastocoelic extracellular matrix (bECM) of the gastrulating sea urchin embryo [35]. In the present work, we provide evidence suggesting that the bECM is in fact the substrate for developmentally regulated proteolysis. Monoclonal antibody (mAb) LG11C7 was generated against testicular tissue of the sea urchin, Strongylocentrotus purpuratus, and recognizes extracellular matrix antigens overlying the perivisceral epithelium. Indirect immunofluorescence microscopy shows that mAb LG11C7 cross-reacts with components of the basal lamina lining the blastocoeles of early embryos and Western immunoblots of detergent extracts indicate that it recognizes gastrula-stage antigens with M(r)s of 158, 68, and 37 kDa. Glycosidase treatments reveal that the embryonal antigens contain multiple N-linked oligosaccharides. Developmental studies employing immunoprecipitations and Western blot analyses of staged embryonal detergent extracts show that the 68-kDa antigen appears between 18 and 24 h after fertilization and is accompanied by a substantial increase in the 37-kDa antigen. Thus, the appearances of the 68- and 37-kDa antigens occur during the blastula-gastrula transition, and their spatiotemporal expression is similar to that of the matrix metalloproteases reported previously. The appearance of the 68-kDa antigen and the increase in the 37-kDa antigen may be blocked by exposing the embryos to the metalloprotease inhibitor 1,10-phenanthroline, which also blocks gastrulation reversibly. These results suggest (1) that the 68- and 37-kDa antigens are products of developmentally regulated proteolysis of a basal laminar glycoprotein, and (2) that this proteolysis is required for the cell-cell/cell-matrix interactions and morphogenetic movements associated with normal gastrulation in the sea urchin embryo.

Developmentally regulated protease expression during sea urchin embryogenesis

A temporal study of protease expression employing the technique of SDS-PAGE gelatin substrate zymography revealed a definitive appearance of proteases during early development in the sea urchins, Lytechinus pictus and Strongylocentrotus purpuratus. The levels of these proteases increase substantially during gastrulation in each species. The two major proteases with relative molecular masses of 57 and 50 kDa were found to be inhibited by the zinc chelator, 1,10-phenanthroline, the more nonspecific metal chelator, EDTA, and the reducing agent, dithiothreitol. The serine protease inhibitor, benzamidine, exerted no effects on the activities of these proteases, and both enzymes exhibited activity in the neutral to slightly basic pH range. Treatment of embryos with actinomycin D, an inhibitor of transcription, beginning up to 9 hr after fertilization, inhibited the subsequent appearances of the two proteases 48 hr after fertilization, as well as any morphological changes associated with gastrulation. Treatments beginning 15 and 21 hr after fertilization resulted in increased levels of proteases that correlate with arrests at successively more advanced stages of gastrulation. SDS-PAGE zymographic analyses of five different embryo fractions indicated that the 57- and 50-kDa proteases are localized in the blastocoel, and blastocoelic protease activity was further confirmed microscopically by in situ zymography. Hence, the 57- and 50-kDa proteases are characterized as metalloproteases. Their expression is dependent on transcription of the embryonic genome, and their spatiotemporal appearance suggests an involvement in blastocoelic matrix remodeling during gastrulation.

Heparan sulfate proteoglycans are required for mesoderm formation in Xenopus embryos

Mesoderm forms in the vertebrate embryo as a result of inductive interactions involving secreted growth factors and cell surface molecules. Proteoglycans have recently been implicated in the control of cell adhesion, migration and growth factor responsiveness. We have found that removal of glycosaminoglycan chains of proteoglycans from Xenopus ectodermal explants by heparinase, but not by chondroitinase, results in inhibition of elongation and mesodermal differentiation in response to signaling factors: activin, FGF and Wnt. Heparinase treatment differentially affected expression of early general and region-specific mesodermal markers, suggesting that mesodermal cell fates become specified in the early embryo via at least two signaling pathways which differ in their requirements for heparan sulfate proteoglycans. Addition of soluble heparan sulfate restored activin-mediated induction of muscle-specific actin gene in heparinase-treated explants. Finally, heparinase inhibited autonomous morphogenetic movements and mesodermal, but not neural, differentiation in dorsal marginal zone explants, which normally give rise to mesoderm in the embryo. These results directly demonstrate that heparan sulfate proteoglycans participate in gastrulation and mesoderm formation in the early embryo.

A high molecular weight proteoglycan is differentially expressed during development of the mollusc Concholepas concholepas (Mollusca; Gastropoda; Muricidae)

Incorporation of radioactive sulfate to hatched veliger larvae of the gastropod muricid Concholepas concholepas indicated that over 87% of the sulfated macromolecules were found in the detergent insoluble fraction, rich in extracellular matrix (ECM) components. The sulfated material was solubilized with guanidine salt followed by urea dialysis and fractionated by DEAE-Sephacel chromatography. Three sulfated compounds eluting at 0.7, 1.1, and 3.0 M NaCl, called peaks I, II, and III, respectively, were obtained. The sulfated compound present in peak I was degraded by pronase or sodium alkaline treatment to a small sulfated resistant material, suggesting the presence of a proteoglycan (PG). Filtration analysis on Sephacryl S-500 and SDS-PAGE of the intact PG indicates that it has a high molecular weight (360,000 to over 1 x 10(6)). Monoclonal antibodies (mAb) against this PG were produced. The specificity of one mAb, the 6H2, was demonstrated by size chromatography and ELISA analysis. The epitope recognized by this mAb seems to be present in the core protein of the PG. Both the extent of sulfation and the presence of different sulfated species of PGs were evaluated during the development of this mollusc. A twelvefold increase in the incorporation of sulfate to PGs per milligram of protein was found in veliger larvae compared to blastula-glastula stages. This change correlated well with the differential expression of the sulfated PG present in peak I. Biochemical and immunological analysis indicate that high levels of this PG are found in veliger and trocophore larvae in comparison with blastula-gastrula and early juveniles.(ABSTRACT TRUNCATED AT 250 WORDS)

Microfilaments, cell shape changes, and the formation of primary mesenchyme in sea urchin embryos

Primary mesenchyme formation in sea urchin embryos occurs when a subset of epithelial cells of the blastula move from the epithelial layer into the blastocoel. The role of microfilaments in producing the cell shape changes that characterize this process, referred to as ingression, was investigated in this study. f-Actin was localized by confocal microscopy using labeled phalloidin. The distribution of f-actin was observed before, during, and after ingression and was correlated with cellular movements. Prior to the onset of ingression, staining became intense in the apical region of putative primary mesenchyme and disappeared following the completion of mesenchyme formation. The apical end of these cells constricted coincidentally with the appearance of the intensified staining, indicating that f-actin may be involved in this constriction. In addition, papaverine, a smooth muscle cell relaxant that interferes with microfilament-based contraction, and that was shown in this study to inhibit cytokinesis, diminished apical constriction and delayed ingression. Despite this interference with apical constriction, the basal surface of ingressing cells protruded into the blastocoel. It is suggested that apical constriction, while not necessary for ingression, does contribute to the efficient production of mesenchyme and that protrusion of the basal surface results from changes that occur independent of apical constriction.

Altered proteoglycan synthesis via the false acceptor pathway can be dissociated from beta-D-xyloside inhibition of proliferation

beta-D-Xylosides have been used to perturb proteoglycan (PG) synthesis to elucidate the function of PGs in a number of cellular processes, including proliferation, migration, and differentiation. This study was designed to examine whether specific xylosides affect the proliferation of several different cell types and, if so, whether this effect is dependent on altered PG synthesis via the false acceptor pathway. Both methylumbelliferyl beta-D-xylopyranoside and p-nitrophenyl beta-D-xylopyranoside (PNP beta-xyloside) inhibit cell proliferation and modulate PG synthesis; however, the alpha form of PNP xyloside which does not perturb PG synthesis inhibits the proliferation of cultured cells on a molar basis equally as well as the beta form. Conversely, beta-methyl xylopyranoside stimulates the synthesis of free glycosaminoglycan chains equally as well as PNP beta-xyloside and yet has no measurable effect on cell proliferation at comparable doses, indicating that cells can grow normally while experiencing disruption of their proteoglycan metabolism. At doses ranging from 0.5 to 5 mM, PNP beta-xyloside arrests cells in the G1 phase of the cell cycle at the same time point as serum starvation. It also delays the exist of cycling cells from the S phase. This treatment is not cytotoxic and is rapidly reversed by the replacement of PNP beta-xyloside containing medium with control medium. Dimethyl sulfoxide, the most commonly used solvent for beta-xyloside in proteoglycan studies, potentiates the inhibitory effect of PNP beta-xyloside on cell proliferation. These results indicate that the perturbation of PG synthesis via the false acceptor pathway can be uncoupled from control of cell proliferation.

Large disulfide-stabilized proteoglycan complexes are synthesized by the epidermis of axolotl embryos

Proteoglycans (PGs) synthesized by the epidermis during stages crucial to the subepidermal migration of neural crest cells in the trunk of the axolotl (Ambystoma mexicanum, Urodela, Amphibia) embryo were studied. The glycosaminoglycan chains were biosynthetically labeled with [35S]sulfate in vitro during a period corresponding to the onset of migration. After extraction with guanidine HCl, the radiolabeled PGs were separated according to size by molecular-sieve chromatography on Sepharose CL-2B under dissociative conditions. This resulted in the separation of high-molecular-weight PGs, which eluted in the void volume, and low-molecular-weight PGs, eluting in a broad peak with a mean Kav of 0.7. The large PGs were also found to elute in the void volume when chromatographed on a Sephacryl S-1000 column. The low-molecular-weight PGs contained heparan sulfate and chondroitin sulfate (CS) and were not further characterized. The glycosaminoglycan component of the high-molecular-weight PG was completely degraded by chondroitinase ABC, while a large portion was resistant to chondroitinase AC, indicating the presence of dermatan sulfate (DS). These CS/DS chains were of unusually large size (Mr approximately 150,000) as estimated by chromatography on Sepharose CL-4B, relating the elution position to hyaluronan standards. Moreover, the chains were found to have a lower surface charge density than standard CS, and may therefore be undersulfated. After reduction and alkylation the high-molecular-weight PGs were included on both Sepharose CL-2B and Sephacryl S-1000 columns, eluting at Kav 0.2 and 0.4, respectively. Hence, the high-molecular-weight material appears to consist of large PG complexes, stabilized by intermolecular disulfide bonds. A CS/DSPG of similar size as the reduced monomeric form of the high-molecular-weight PG was found in small amounts in the total extract of 35S-labeled material.

Role of the extracellular matrix in tissue-specific gene expression in the sea urchin embryo

The role of extracellular matrix (ECM) in the differentiation of tissue types was examined in embryos of Strongylocentrotus purpuratus. We have examined the expression of various tissue-specific molecular markers after disrupting the ECM by culturing embryos in the presence of beta-aminoproprionitrile fumarate (BAPN), which disrupts collagen deposition, and beta-D-xyloside, which disrupts proteoglycan metabolism. The markers examined included accumulation of primary mesenchyme-specific mRNA (SM 50); an aboral ectoderm-specific mRNA (Spec 1); and a gut-specific enzyme, alkaline phosphatase. Treatment with BAPN or beta-D-xyloside results in developmental arrest at the mesenchyme blastula stage. Although spicule formation is inhibited, the accumulation of SM 50 transcripts and the synthesis of most of the prominent spicule matrix proteins is similar to that of control embryos. Spec 1 mRNA, in contrast, while accumulating to a significant extent when collagen and proteoglycan metabolism is disrupted, does accumulate to a level somewhat lower than that seen in control embryos. Additionally, the postgastrula rise in gut-specific alkaline phosphatase is reversibly inhibited by BAPN and xyloside treatment. These results demonstrate a differential effect of the ECM on expression of tissue-specific molecular markers.

The synthesis and secretion of collagen by cultured sea urchin micromeres

Circumstantial evidence in several previous studies has suggested that sea urchin embryo micromeres, the source of primary mesenchyme cells which produce the embryonic skeleton, contribute to the extracellular matrix of the embryo by synthesizing collagen. A direct test of this possibility was carried out by culturing isolated micromeres of the sea urchin Stronglyocentrotus purpuratus in artificial sea water containing 4% (v/v) horse serum. Under these conditions the micromeres divide and differentiate to produce spicules with the same timing as intact embryos. Collagen synthesis was determined by labeling cultures with [3H]proline or [35S]methionine and the medium and cell layer were assayed for collagen. The results indicate that by the second day in culture micromeres synthesize and secrete a collagenase-sensitive protein doublet with a molecular weight of about 210 kDa. Densitometry indicates a 2:1 ratio of the respective bands in the doublet which is characteristic of Type I collagen. The doublet is insensitive to digestion with pepsin. This differential sensitivity is characteristic of collagen. Over 90% of the collagen synthesized by micromeres is soluble in the seawater culture medium. On days 2-4 in culture, collagen accounts for 5% of the total protein synthesized and secreted. Additional collagenase-sensitive bands are noted at 145 and 51 kDa. The relationship of the described collagen metabolism to previously characterized collagen gene expression in sea urchin embryos is discussed.

Proteoglycan production in Drosophila egg development: effect of beta-D-xyloside on proteoglycan synthesis and larvae motility

1. Proteoglycans (PGs) of the extracellular matrix (ECM) play an important role in several morphogenetic and differentiation events that occur during embryonic development. 2. The purpose of this work was to characterize the ECM PGs present during development of Drosophila melanogaster, in an attempt to elucidate their functional relevance. 3. The major 35SO4 incorporation into PGs occurred during the first instar larvae. Sulfated PGs (90%) from both first and second instar larvae were degraded by HNO2 treatment. 4. This result indicated that heparan sulfate proteoglycans (HSPG) are present in Drosophila ECM throughout early development. 5. Charge fractionation of PGs on DEAE-Sephacel columns indicated that most of them eluted at 0.45 M NaCl and were sensitive to HNO2. 6. The administration of beta-D-xyloside, a drug that competes with core proteins for the glycosaminoglycan synthetic apparatus, generated biochemical modifications in the ECM PGs together with alterations in larval locomotor behavior.

Extracellular matrix synthesis is required for the movement of sclerotome and neural crest cells on collagen

During early embryogenesis cells of several different populations disperse by active cell movement from one location to another. Preexisting extracellular materials are major determinants of these dispersal patterns, but the cells are also able to modify their substrata by synthesizing and secreting extracellular matrix molecules as they move. In order to determine the contribution made by these deposited materials, several tissues from the early chick embryo have been cultured in the presence of inhibitors of extracellular matrix synthesis and secretion. The tissues examined were sclerotome cells from differentiated somites and neural crest cells. For comparison, undifferentiated somites were also cultured. The movement of these cells was compared in type I collagen gel culture and in conventional culture on artificial substrata. Inhibitors of collagen synthesis were used (cis-hydroxy proline and L-azetidine-2-carboxylic acid) in addition to a proteoglycan inhibitor (p-nitrophenyl-xylopyranoside) and a secretion inhibitor (monensin). Results indicate that sclerotome cells require collagen synthesis for movement in a collagen matrix. Reversal of the effects of collagen inhibitors, by proline and type II collagen, suggest that sclerotome cells normally condition the type I matrix in order to move in it. Inhibition of proteoglycan synthesis produced the greatest effect on the movement of neural crest cells regardless of the substratum, confirming an important role for these molecules in the crest migratory routes. The attachment of all cells to collagen was highly sensitive to the presence of monensin, which is known to reduce the deposition of glycosaminoglycans and fibronectin. These results suggest that conditioning of the extracellular matrix by newly synthesized material is required for cell attachment and movement during early development.

Dependence of sea urchin primary mesenchyme cell migration on xyloside- and sulfate-sensitive cell surface-associated components

The migration of sea urchin primary mesenchyme cells (PMC) is inhibited in embryos cultured in sulfate-free seawater and in seawater containing exogenous xylosides. In the present study, primary mesenchyme cells and extra-cellular matrix have been isolated from normal and treated Lytechinus pictus and Strongylocentrotus purpuratus embryos and recombined in an in vitro migration assay to determine whether the cells or the matrix are migration defective. Normal cells were found to migrate on either normal or treated matrix, whereas sulfate-deprived and xyloside-treated PMC failed to migrate in vitro on normal and treated substrata. Migratory ability can be restored to defective cells by returning the PMC to normal seawater, or by exposing the defective cells to materials removed from the surface of normal cells with 1 M urea. The similarity of the results obtained with sulfate-deprived and xyloside-treated PMC suggested that a common molecule may be affected by the two treatments. As a first test of this possibility, xyloside-treated S. purpuratus PMC were given the urea extract prepared from sulfate-deprived S. purpuratus PMC, and this extract did not restore migratory ability. These findings indicate that PMC normally synthesize a surface-associated molecule that is involved in cell migration, and the sensitivity to exogenous xylosides and sulfate deprivation suggests that a sulfated proteoglycan may be involved in primary mesenchyme cell migration.

Migratory and invasive behavior of pigment cells in normal and animalized sea urchin embryos

Pigment cell precursors in the vegetal plate of late mesenchyme blastulae of the sea urchin Strongylocentrotus purpuratus begin to express a cell surface epitope recognized by the monoclonal antibody SP-1/20.3.1. When one-quarter gastrulae are dissociated into ectodermal and mesenchymal fractions, most SP-1/20.3.1 immunoreactive cells separate into the mesenchymal fraction, whereas at the full gastrula and all later stages almost all epitope-bearing cells are in the ectodermal fraction. Exposure of embryos to sulfate-free seawater p-nitrophenyl beta-D-xyloside, and tunicamycin, all of which prevent primary mesenchyme migration, does not inhibit SP-1/20.3.1 immunoreactive cells from distributing similarly to those in controls, although pigment synthesis is completely inhibited in sulfate-free conditions. Time-lapse video sequences reveal that pigment cells, and a small set of rapidly migrating, SP-1/20.3.1 immunoreactive amoeboid cells that appear in the pluteus, remain closely associated with the ectodermal epithelium during most of larval development. Transmission electron microscopy observations of plutei show pigment cells tightly apposed to the ectodermal epithelium at discontinuities in the basal lamina and sandwiched between the basal lamina and the epithelial cells. It is concluded that SP-1/20.3.1 immunoreactive mesenchymal cells invade the ectodermal epithelium and may use migratory substrates other than those used by primary mesenchymal cells.