The role of proteoglycan in the development of sea urchins. I. Abnormal development of sea urchin embryos caused by the disturbance of proteoglycan synthesis

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.

Cyclodextrin, a probe for studying adhesive interactions

In this short communication, we introduce alpha-cyclodextrin as a new probe to study mechanisms of adhesive interactions. We show that this cyclic polysaccharide, that consisting of six glucosyl residues linked by alpha-1,4 bonds, was the only sugar of 22 tested that dramatically blocked a specific cellular interaction in the sea urchin embryo (p<0.001 compared with non-sugar controls). A total of 150-400 embryos were sampled for each concentration of each sugar tested. Mechanisms of cellular interactions have been studied for almost a century and they still remain poorly understood. Cyclodextrin is an exciting new tool that can be utilized for investigating these mechanisms.

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.

Carbohydrate involvement in cellular interactions in sea urchin gastrulation

The sea urchin embryo is a model for studying cellular interactions that occur in higher organisms because of its availability, transparency, and accessibility to molecular probes. In previous studies, we found that the mannose/glucose-binding lectin Lens culinaris agglutinin entered living sea urchin embryos, bound to specific cell types and caused exogastrulation, when the developing gut (archenteron) falls out of the embryo proper. We have proposed that the lectin bound to sugar-containing ligands, thus preventing attachment of the archenteron to the blastocoel roof, resulting in exogastrulation. Here, we have continued our study of cellular interactions in this model using Lytechinus pictus sea urchin embryos, and have found that inhibitors of glycoprotein/proteoglycan synthesis, tunicamycin and sodium selenate, and the specific glycosidases, beta-amylase, alpha-glucosidase, and alpha-mannosidase, all inhibit archenteron organization, elongation, and attachment to the blastocoel roof in viable swimming embryos. We also show that single cells obtained by disaggregation of 32-h-old sea urchin embryos bind to L. culinaris agglutinin- and concanavalin A-derivatized beads; the binding is blocked by alpha-methyl mannose, but not l-fucose. These cells also bind to beads derivatized with mannan. These results provide evidence for a role of carbohydrate-containing molecules in cellular interactions in sea urchin gastrulation. In a second set of experiments, we found that the supernatant obtained by disaggregation of 24-32-h-old L. pictus embryos in calcium- and magnesium-free sea water contains molecules that cause exogastrulation, archenteron disorganization, inhibition of archenteron elongation and inhibition of archenteron attachment to the blastocoel roof in viable swimming embryos. We propose that the supernatant contains ligands and/or receptors that mediate archenteron development and attachment to the blastocoel roof and are released when embryos are disaggregated into single cells. These studies may lead to a better understanding of the molecular basis of mechanisms that control cellular interactions during development.

Sulfatases: Structure, Mechanism, Biological Activity, Inhibition, and Synthetic Utility

Sulfatases, which cleave sulfate esters in biological systems, play a key role in regulating the sulfation states that determine the function of many physiological molecules. Sulfatase substrates range from small cytosolic steroids, such as estrogen sulfate, to complex cell-surface carbohydrates, such as the glycosaminoglycans. The transformation of these molecules has been linked with important cellular functions, including hormone regulation, cellular degradation, and modulation of signaling pathways. Sulfatases have also been implicated in the onset of various pathophysiological conditions, including hormone-dependent cancers, lysosomal storage disorders, developmental abnormalities, and bacterial pathogenesis. These findings have increased interest in sulfatases and in targeting them for therapeutic endeavors. Although numerous sulfatases have been identified, the wide scope of their biological activity is only beginning to emerge. Herein, accounts of the diversity and growing biological relevance of sulfatases are provided along with an overview of the current understanding of sulfatase structure, mechanism, and inhibition.

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.

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.

Disruption of proteoglycans in neural tube fluid by beta-D-xyloside alters brain enlargement in chick embryos

Following neurulation, the anterior end of the neural tube undergoes a dramatic increase in size due mainly to the enlarging of the brain cavity. This cavity is filled with so-called neural tube fluid (NTF), whose positive pressure has been shown to play a key role in brain morphogenesis. This fluid contains a water-soluble matrix, rich in chondroitin sulfate (CS), which has been proposed as an osmotic regulator of NTF pressure genesis. The purpose of the present study is to observe the influence of CS on NTF osmolality and its relation to NTF hydrostatic pressure and brain expansion. NTF was obtained by means of microaspiration from the mesencephalic cavity of chick embryos. The osmolality of NTF between H.H. stages 20 and 29 was measured on the basis of its cryoscopic point. CS synthesis was disrupted by using beta-D-xyloside and the induced variations in brain volume were measured by means of morphometry. We also measured the variations in NTF osmolality, hydrostatic pressure, and the concentration of CS and sodium induced by means of beta-D-xyloside. Our data reveal that, at the earliest stages of development analyzed, variations in NTF osmolality show a characteristic pattern that coincides with the developmental changes in the previously described fluid pressure. Chick embryos treated with beta-D-xyloside, a chemical that disrupts CS synthesis, displayed a notable increase in brain volume but no other apparent developmental alterations. Morphometric analysis revealed that this increase was due to hyperenlargement of the brain cavity. Beta-D-xyloside brings about specific changes in the biochemical composition of NTF, which entails a large increase in CS concentration, mainly in the form of free chains, and in that of sodium. As a result, the fluid's osmolality and brain intraluminal pressure increased, which could account for the increase in size of the brain anlage. These data support the hypothesis that the intraluminal pressure involved in embryonic brain enlargement is directly dependent on NTF osmolality, and that the concentrations of CS and its associated microions could play a key role in the regulation of this process.

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.

The effects of beta-D-xyloside on the synthesis of proteoglycans by skeletal muscle: lack of effect on decorin and differential polymerization of core protein-bound and xyloside-linked chondroitin sulfate

Developing skeletal muscle cells, as both myoblasts and myotubules, synthesize a distinctive large chondroitin sulfate proteoglycan. To probe the role of this proteoglycan in myogenesis, chick embryonic muscle cells in culture were treated with beta-D-xyloside, a compound which interferes with proteoglycan synthesis by acting as an artificial acceptor for glycosaminoglycan synthesis and thereby competing with the proteoglycan core protein. Analysis of the proteoglycans indicates that with increasing concentrations of beta-D-xyloside, synthesis of the chondroitin sulfate proteoglycan is inhibited, with concomitant massive synthesis of xyloside-linked chondroitin sulfate glycosaminoglycans. Xyloside does not appear to inhibit glycosaminoglycan attachment onto the small heparan sulfate and dermatan sulfate proteoglycans which are synthesized in the muscle cultures, even though, because of the mechanism of action of beta-xyloside, these proteoglycans should be affected. At submaximal concentrations of beta-xyloside, there is synthesis of both large chondroitin sulfate proteoglycans and xyloside-linked chondroitin sulfate. The xyloside-linked chondroitin sulfate chains have the same sulfation pattern as the core protein-bound skeletal muscle chondroitin sulfate (90% 6-sulfated isomer), but are much smaller (24,000 vs. 65,000 in molecular weight). The discrepancy in size but identify of sulfation indicates that, although sulfation takes place normally on either the core protein or the xyloside acceptor, termination of glycosylation occurs earlier for xyloside-initiated chondroitin sulfate. In spite of these dramatic effects on chondroitin sulfate proteoglycan synthesis, beta-xyloside elicits no observable effects on in vitro myogenesis. This suggests that the function served by the large chondroitin sulfate proteoglycan is not required in the more simplified environment of the muscle cultures.

A role for regulated secretion of apical extracellular matrix during epithelial invagination in the sea urchin

Epithelial invagination, a basic morphogenetic process reiterated throughout embryonic development, generates tubular structures such as the neural tube, or pit-like structures such as the optic cup. The ‘purse-string’ hypothesis, which proposes that circumferential bands of actin microfilaments at the apical end of epithelial cells constrict to yield a curved epithelial sheet, has been widely invoked to explain invaginations during embryogenesis. We have reevaluated this hypothesis in two species of sea urchin by examining both natural invagination of the vegetal plate at the beginning of gastrulation and invagination induced precociously by Ca2+ ionophore. Neither type of invagination is prevented by cytochalasin D. In one species, treatment with A23187 three hours before the initiation of invagination resulted in the deposition of apical extracellular matrix at the vegetal plate, rather than invagination. This apical matrix contains chondroitin sulfate, as does the lumen of the archenteron in normal gastrulae. When the expansion of this secreted matrix was resisted by an agarose gel, the vegetal plate buckled inward, creating an archenteron that appeared 3–4 hours prematurely. Pretreatment with monensin, which blocks secretion, inhibits both Ca2+ ionophore-stimulated folding and natural invagination, demonstrating that secretion is probably required for this morphogenetic event. These results indicate that alternatives to the purse-string hypothesis must be considered, and that the directed deposition of extracellular matrix may be a key Ca(2+)-regulated event in some embryonic invaginations. A bending bilayer model for matrix-driven epithelial invagination is proposed in which the deposition of hygroscopic material into a complex, stratified extra-cellular matrix results in the folding of an epithelial sheet in a manner analagous to thermal bending in a bimetallic strip.

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)

Questioning the reliability of p-nitrophenyl-beta-D-xyloside as probe to study the metabolic effects of abrogated proteoglycan synthesis in cultured cells

p-Nitrophenyl-beta-D-xylopyranoside (PNP-Xyl) and similar aglycone derivatives of xylosides are proposed selective inhibitors of proteoglycan synthesis which are used frequently to analyse the metabolic and cellular effects of abrogated proteoglycan formation and, hence, tentatively, the functions of these complex molecules. Using rat liver fat storing cell (FSC) cultures as a model, the possibility was tested that p-nitrophenol (PNP), which might be generated by the enzymatic hydrolysis of PNP-Xyl, could mediate some of those effects ascribed previously to PNP-Xyl induced inhibition of proteoglycan synthesis. PNP-Xyl and PNP inhibited dose-dependently the proliferation of FSC reaching 50% inhibition at about 1.9 and 0.6 mM, respectively. The inhibition of proliferation was not accompanied by signs of toxic cell damage and was fully reversible after withdrawal of the drugs. After an initial 4-fold stimulation of the formation of [35S]sulfate-labeled medium glycosaminoglycans (GAG) by PNP-Xyl at 0.1 mM, higher concentrations of this compound (about 0.5 mM) but also PNP decreased progressively the synthesis of sulfated medium GAG. A proliferation inhibiting concentration of PNP (0.75 mM) induced disorganization and reduced the expression of desmin- and smooth muscle iso-alpha-actin containing cytoskeletal filaments. These effects were similar to related effects reported previously for PNP-Xyl. Incubation of FSC with 5 mM PNP-Xyl resulted in a time-dependent increase of PNP in medium and cells; intracellular concentrations of PNP were reached sufficient to inhibit the mitotic activity of FSC. In lysates of FSC 0.65 nmol PNP/hr/micrograms DNA or 1 x 10(5) cells were generated from PNP-Xyl (5 mM) added as substrate. Exemplified with PNP-Xyl-treated FSC cultures, the results suggest for other cell and organ systems also that PNP, which is enzymatically cleaved from PNP-Xyl, might mediate at least some of the major effects attributed previously to the inhibition of proteoglycan synthesis. The aglycone may interfere with the effects of PNP-Xyl on proteoglycan metabolism and, therefore, could complicate in an unpredictable manner the interpretation of metabolic inhibitory studies using these compounds.

Cell movements during the initial phase of gastrulation in the sea urchin embryo

The morphogenetic processes responsible for the initial phase of gastrulation in sea urchin embryos are not known. Here we report observations of the size and position of clones of cells derived from horseradish peroxidase (HRP)-injected mesomeres and macromeres. The displacement of these clones during the initial phase of gastrulation suggests that involution is a mechanism involved in primary invagination. Experiments with embryos marked with vital dyes indicate that movements occur only during a brief phase coincident with the invagination of the vegetal plate. Counts of cells derived from HRP-injected mesomeres and macromeres suggest it unlikely that localized growth in the vegetal plate is involved in gastrulation. An analysis of changes in cell shape during the initial phase of gastrulation indicates that there is a stage-dependent shift from cells being columnar to having their apices skewed toward the vegetal plate and an increase in the proportion of cells having basal processes during gastrulation. When embryos are grown in the presence of monoclonal antibodies to the apical lamina or monovalent fragments of these antibodies, the initial phase of gastrulation is delayed and they form partial exogastrulae. Analysis of embryos marked with HRP indicate that the antibody treatments interfere with the cellular movements observed in untreated embryos. We conclude that directed movements of cells within the blastoderm, probably employing tractoring on components of the hyaline layer, cause the buckling of the vegetal plate and displacement of presumptive endoderm cells seen during the initial phase of gastrulation.

Xyloside effects on in vitro hematopoiesis: functional and biochemical studies

Xyloside supplementation of long-term bone marrow cultures (LTBMCs) has been reported to result in greatly enhanced proliferation of hematopoietic stem cells. This was presumed to be the result of xyloside-mediated perturbation of proteoglycan synthesis by marrow-derived stromal cells. To investigate this phenomenon, we first studied the effects of xyloside supplementation on proteoglycan synthesis by D2XRadII bone marrow stromal cells, which support hematopoietic stem cell proliferation in vitro. D2XRadII cells were precursor labelled with 35S-sulfate, and proteoglycans separated by ion exchange chromatography, isopyknic CsCl gradient centrifugation, and gel filtration HPLC. Xyloside-supplemented cultures showed an approximately fourfold increase in total 35S incorporation, mainly as free chondroitin-dermatan sulfate (CS/DS) glycosaminoglycan chains in the culture media. Both xyloside supplemented and nonsupplemented cultures synthesized DS1, DS2, and DS3 CS/DS proteoglycans as previously described. In contrast to previous reports, xyloside was found to inhibit hematopoietic cell growth in LTBMC. Inhibitory effects were observed both in cocultures of IL-3-dependent hematopoietic cell lines with supportive stromal cell lines and in primary murine LTBMCs. Xyloside was found to have a marked inhibitory effect on the growth of murine hematopoietic stem cells and IL-3-dependent hematopoietic cell lines in clonal assay systems and in suspension cultures. In contrast, dialyzed concentrated conditioned media from LTBMCs had no such inhibitory effects. These findings suggest that xyloside-mediated inhibition of hematopoietic cell growth in LTBMC resulted from a direct effect of xyloside on proteoglycan synthesis by hematopoietic cells.

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.

Cell surface, heparin-like molecules are required for binding of basic fibroblast growth factor to its high affinity receptor

The role of low affinity, heparin-like binding sites for basic fibroblast growth factor (bFGF) was investigated in CHO cells mutant in their metabolism of glycosaminoglycans. Heparan sulfate-deficient mutants transfected to express a cloned mouse FGF receptor cDNA are not able to bind bFGF. It is demonstrated that free heparin and heparan sulfate can reconstitute a low affinity receptor that is, in turn, required for the high affinity binding of bFGF. These studies suggest that the low affinity receptor is an accessory molecule required for binding of bFGF to the high affinity site. Such an obligatory interaction of low and high affinity FGF receptors suggests a physiological role for heparin-like, low affinity receptors and constitutes a novel mechanism for the regulation of growth factor-receptor interactions.

The effect of beta-D-xylosides on the proliferation and proteoglycan biosynthesis of monoblastic U-937 cells

The monoblastic cell line U-937 was cultured in the presence of C-ethyl beta-D-xyloside (E-xyl), hexyl beta-D-thioxyloside (HX-xyl), p-nitrophenyl beta-D-xyloside, phenyl beta-D-xyloside or phenyl alpha-D-xyloside. All of the beta-D-xylosides inhibited proliferation, but HX-xyl was by far the most efficient, and had a maximum effect at 1 mM concentration. The inhibitory effect of HX-xyl could be reversed; after washing, the HX-xyl-treated cells proliferated with a pattern similar to that of control cells. For more detailed analysis of the effects of beta-D-xylosides on cell proliferation and chondroitin sulphate (CS)/chondroitin sulphate proteoglycan (CSPG) structure, a comparison between the effects of E-xyl and HX-xyl was made. Treating the cells with 1 mM-HX-xyl resulted in a large increase in CS synthesis, whereas 1 mM-E-xyl had only minor effects on the rate of PG/glycosaminoglycan synthesis. Sepharose CL-6B gel chromatography of medium and cell fractions from 35S-labelled cells revealed that HX-xyl treatment resulted in the expression of only free CS chains, whereas E-xyl exposure leads to the synthesis of both large and small CSPGs, as well as some free CS chains. The expression of elevated levels of free CS chains was clearly correlated to the inhibition of proliferation. The proliferation of U-937-4, a clone of U-937 synthesizing ten times more CSPG/CS than the parent line, was equally inhibited by HX-xyl treatment. With this clone, however, there was no stimulation of CS synthesis after xyloside exposure, indicating that the elevated level of CS evident after xyloside treatment of the parent cell line is not causing the inhibition of proliferation. Furthermore, the biosynthesis of hyaluronate was shown not to be implicated in the xyloside-induced decrease in proliferation. The inhibition of proliferation observed in the presence of 1 mM-HX-xyl did not lead to differentiation of the cells into macrophage-like cells, as is observed when the cells are cultured in the presence of phorbol esters, agents also known to inhibit proliferation of U-937 cells.

Ontogeny and characterization of mesenchyme antigens of the sea urchin embryo

A monoclonal antibody, Sp12, binds to cortical granules, the hyaline layer, and skeletogenic, chromogenic, and blastocoelar mesenchyme of sea urchin eggs and embryos. Adult urchins also express Sp12 antigens in the dermal layer of the test and spines. Antigen is expressed on the surface of primary mesenchyme cells after they have entered the blastocoel, and by two secondary mesenchyme derivatives--the blastocoelar cells after they have been released from the tip of the archenteron, and the pigment cells in prism stage embryos. Immunogold localizations show antigen on the surfaces of mesenchyme, within membrane bounded vesicles, and associated with the Golgi apparatus. Western blots of antigens immunoprecipitated from seven developmental stages reveal twelve antigens ranging in Mr from 35 k to 240 k. Most of these antigens appear, disappear or change Mr over the first five days of development. Characterizations of this complex array of antigens show that the epitope recognized by Sp12 is eliminated by proteolytic enzymes and endoglycosidase F, while immunoreactivity is only reduced by periodate oxidation. As well, calcium magnesium free seawater extracts a subset of antigens different from that retained by crude membrane preparations. It is proposed that the mesenchyme of sea urchin embryos produces a family of developmentally regulated cell surface and extracellular matrix glycoproteins which all exhibit a carbohydrate epitope recognized by Sp12.

Structure and tissue-specific developmental expression of a sea urchin arylsulfatase gene

Arylsulfatases are a group of enzymes that remove sulfate moieties from a diverse set of substrates including glycoproteins, steroids, and cerebrosides. We have isolated recombinant cDNA clones corresponding to an arylsulfatase (SpARS) message that encodes an abundant protein of pluteus larvae of the sea urchin Strongylocentrotus purpuratus. Although vertebrate arylsulfatases have broad tissue distributions, in situ hybridization with a probe for SpARS shows that the sea urchin message accumulates in the embryo only in the single cell type of aboral ectoderm and its precursors. The message is first detectable by RNase protection assays around hatching blastula stage and accumulates through pluteus larva stage. The open reading frame of cDNA clones is 1701 nt long and encodes a deduced protein with a predicted molecular mass of 61 kDa. Analysis of corresponding genomic DNA clones reveals that the pre-mRNA contains six exons. Consistent with the fact that arylsulfatase enzyme activity is extracellular, this polypeptide has a hydrophobic leader sequence and three potential glycosylation sites. Furthermore, hybridization in situ shows that in blastulae arylsulfatase message is preferentially concentrated around nuclei at the basal sides of cells. The S. purpuratus sequence is very similar to that recently reported for the same enzyme from Hemicentrotus pulcherrimus and 30% of the amino acid residues are also identical to those of both human arylsulfatase C (steroid sulfatase) and arylsulfatase A. Sequence relationships among these four mRNAs suggest that, assuming equal rates of evolution, the duplication separating the human genes occurred at about the time of separation of the echinoderm and vertebrate lineages.

Extracellular matrix of sea urchin and other marine invertebrate embryos

The extracellular matrix surrounding the sea urchin embryo (outer ECM) contains fibers and granules of various sizes which are organized in recognizable patterns as shown by ultrastructural studies, particularly stereoimaging techniques. The use of the ruthenium red method for retaining and staining the ECM, with modifications of the Luft (Anatomical Record 171:347-368, 1971) method for invertebrate embryos, allows for the clarification of certain structures, particularly fiber compaction in the interzonal region, and microvillus-associated bodies. The inner ECM in the sea urchin embryo includes the basal lamina and blastocoel matrix. Stereoimages show that the fibers which are loosely distributed in the blastocoel matrix become compacted around the periphery of the blastocoel to form the basal lamina. The ruthenium red method was also used on a number of marine invertebrate embryos and larvae, representing different phyla, to facilitate comparisons between their surface coats. The similarities observed in the specimens shown suggest that ECMs are widely found on marine invertebrate eggs, embryos, and larvae, and that they resemble vertebrate ECMs and may, therefore, have similar functions.

Specific binding of lectins with the nucleus of the sea urchin embryo and changes in the lectin affinity of the embryonic chromatin during the course of development

(1) Embryonic cells of sea urchins were made permeable by treating them with glycerol solution for the purpose of allowing penetration of macromolecules into the cell. With the use of such permeabilized cells, several kinds of fluorescent dye-labeled lectins were introduced into the cell, and it was found that some lectins showed notable affinity with the nucleus as compared with cytoplasmic structures. (2) Isolated chromatin was incubated with several kinds of fluorescent dye-labeled lectins in vitro, and the amount of lectins bound with the chromatin was measured by fluorometry. By means of this method, the lectin-binding capacity of chromatin was estimated and compared at various stages of development. It was found that lectins could be classified into three groups according to the mode of binding with the chromatin: (a) Extent of binding increased notably at the gastrula stage (Con A and RCA-120); (b) extent of binding showed a temporary decrease at the gastrula stage (TTA); and (c) very low level of binding was maintained throughout all stages, and no particular change was observed at any stage of development (WGA, SBA, and UEA-I). (3) These facts seem to suggest that lectin-binding components are contained in sea urchin chromatin, and that drastic changes occur in these components of chromatin at the stage of gastrulation. It was proposed that the lectin-binding components such as proteoglycans and glycoproteins may play regulatory roles in embryonic chromatin at early stages of development.

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.

A relationship between the inhibition of heparan sulfate and chondroitin sulfate synthesis and the inhibition of molting by selenate in the hemipteran Rhodnius prolixus

The insect Rhodnius prolixus synthesizes heparan sulfate and chondroitin sulfate after a blood meal containing [35S]-inorganic sulfate. A 40 to 80% inhibition of heparan sulfate synthesis was obtained when the meal was supplemented with 10(-5) and 10(-4) M sodium selenate respectively. Likewise an inhibition of the molting in the order of 30 to 60% was observed when the insects were fed with blood containing 10(-5) and 10(-4) M selenate respectively. The insects after a subsequent meal without selenate molted normally. Except for the inhibition of the ecdysis no gross physiological or morphological changes could be observed in the insects. Based on these and other findings the possible role of sulfated glycosaminoglycans in the control of cell growth is discussed.

Heparin sequences in the heparan sulfate chains of an endothelial cell proteoglycan

The structure of the glycosaminoglycan chain of a heparan sulfate proteoglycan isolated from the conditioned medium of an endothelial cell line has been analyzed by using various degradative enzymes (heparitinase I, heparitinase II, heparinase, glycuronidase, sulfatases) from Flavobacterium heparinum. This proteoglycan inhibits the thromboplastin-activated pathway of coagulation; as a consequence, the catalytic conversion of prothrombin to thrombin is arrested. Heparitinase I (EC 4.2.2.8), an enzyme with specificity restricted to the heparan sulfate portion of the polysaccharide, releases fragments with the electrophoretic mobility and the structure of heparin. Conversely, an assessment of the size and distribution of the heparan sulfate regions has been provided by the use of heparinase (EC 4.2.2.7), which, by degrading the heparin sections of the chain, releases two segments that exhibit the structure of heparan sulfate. One of these segments is attached to the protein core. On the basis of these findings, the heparan sulfate chain can be defined as a copolymer containing heparin regions in its structure. The combined use of these enzymes has made it possible to establish the disaccharide sequence of parts of the glycosaminoglycan moiety of this proteoglycan.

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

This investigation examines the effect of exogenous xylosides on primary mesenchyme cell behavior in Strongylocentrotus purpuratus embryos. In confirmation of studies in some other species the addition of 2 mM p-nitrophenyl-beta-D-xylopyranoside blocks the migration but not the initial ingression of primary mesenchyme cells. The blastocoel matrix of treated embryos appears deficient in a 15- to 30-nm-diameter granular component that is observed extensively on the basal lamina and on filopodia of migrating primary mesenchyme cells in untreated embryos. Other blastocoel components appear unaffected by ultrastructural criteria. The incorporation of 35SO4(2-) per embryo into ethanol precipitates of isolated blastocoel matrices was reduced significantly after xyloside treatment but the distribution of 35SO4(2-) after polyacrylamide gel electrophoresis or the glycosaminoglycan composition was unaffected. Chromatography on Sepharose CL-2B demonstrates a reduction in size of sulfated components of the blastocoel. While over 60% of the 35S-labeled material from the blastocoel of normal mesenchyme blastulae is voided from a Sepharose CL-2B column run in a dissociative solvent, only 10% from xyloside treated embryos is voided. Instead, there is a large included peak with Kav of 0.33. This material is acid soluble but cetylpyridinium chloride precipitable. It apparently consists largely of free glycosaminoglycan chains. Based on analysis of chondroitinase ABC digestion products this material consists of 41% chondroitin-6-sulfate and 58% dermatan sulfate. These results are consistent with a role in cell migration for intact chondroitin sulfate/dermatan sulfate proteoglycans in the sea urchin blastocoel matrix.

Phenotypic switching to long cilia effected by various proteases: results with Dendraster excentricus and Stronglyocentrotus purpuratus blastulae

Incubation in trypsin effects a phenotypic switch from short to long cilia (greater than 30 micron) in hatched blastulae of the sea urchin, Arbacia punctulata. To determine how trypsin causes such a switch we tested whether the phenomenon was unique to the species, Arbacia, and to the protease, trypsin. With two other echinoderm species, the sand dollar, Dendraster excentricus, and the sea urchin, Strongylocentrotus purpuratus, trypsin incubation increased the percentage of long cilia. During incubation of D. excentricus in trypsin, the percentage of long cilia increased progressively from the normal 10% long cilia of the apical tuft to 45-50% long cilia covering 1/2-3/4 of the embryo. With S. purpuratus blastulae, however, the percentage of long cilia was lower (32-40%) and the results were more variable. Of the additional proteases tested with D. excentricus, elastase was more effective than trypsin in terms of the percentage of long cilia (58%), the mean length, and the broad distribution of lengths formed. Thermolysin was about as effective as trypsin but chymotrypsin was much less so. Thus, increases in ciliary length were not unique to a particular echinoderm species or to incubation in trypsin. The magnitude of the change in length distribution, however, was species- and enzyme-dependent. An extracellular or membrane component with differential susceptibility to various proteases may, therefore, be involved in altering ciliary length.

Effect of benzyl beta-D-xyloside on the biosynthesis of chondroitin sulphate proteoglycan in cultured human monocytes

Monocytes isolated from human blood differentiate into macrophage-like cells when maintained in vitro for 3-5 days on plastic or glass culture dishes. In the process the cells display characteristic morphological changes, and in addition, a transition in glycosaminoglycan biosynthesis, from the production of chondroitin 4-sulphate to the formation of a polysaccharide containing 20% 4,6-disulphated disaccharide units [Kolset, Kjellén, Seljelid & Lindahl (1983) Biochem. J. 210, 661-667]. Cells were incubated with inorganic [35S]sulphate on day 1 or day 6 in culture, in the presence or absence of benzyl beta-D-xyloside, and labelled polysaccharide was isolated from the culture medium. In the presence of xyloside, the secretion of proteoglycans (90% galactosaminoglycan) was inhibited in a dose-dependent fashion and replaced by release of single polysaccharide chains, the size of which decreased with increasing dose of xyloside. The single polysaccharide chains produced on day 6 in the presence of 0.5 mM-xyloside showed the same proportion of disulphated disaccharide units as did the corresponding control material. Day-1 polysaccharide contained negligible amounts of this component, irrespective of the presence or absence of xyloside. It is concluded that the regulatory mechanism that induces 'oversulphation' during the differentiation process operates independently of any association between the polysaccharide chains and the core protein. Moreover, cells maintained in the presence of 0.5 mM-xyloside throughout a 6-day culture period showed the same morphological change, indicative of differentiation into macrophage-like cells, as did untreated control cells. The xyloside did not significantly affect the cytotoxicity of the monocytes, or of the differentiated macrophage-like cells, toward tumour cells.

Sulphation and the vegetative growth of Dictyostelium discoideum

The utilization of [35S]sulphate by bacterially grown amoebae of Dictyostelium discoideum strain NP73 was examined in this study. During vegetative growth the sulphation of at least ten macromolecules was observed. These macromolecules had molecular masses less than 66 kDa and isoelectric points below 5. Simple tests indicated that the sulphate linkage was periodate-sensitive but not acid-labile which implied that carbohydrate moieties, rather than tyrosine residues, were sulphated. Pulse-chase experiments indicated that the sulphated macromolecules were extremely stable during vegetative growth, but that secretion occurred on starvation, resulting in the loss of the sulphated macromolecules to the extracellular medium. Incorporation of [35S]sulphate into these macromolecules by amoebae declined rapidly within 2 h of starvation on membrane filters. In contrast, incorporation by amoebae starving in suspension culture continued for 6-8 h. Similar patterns of [35S]sulphate incorporation were observed for two other strains of D. discoideum (strains AX2 and NC4) and for Polysphondylium violaceum. Since in a previous study it was shown that the sulphation inhibitor, sodium selenate, arrests the growth of D. discoideum [Davis, S.J. & Wheldrake, J.F. (1985) FEMS Micro Lett. 30, 353-358], it is suggested that the sulphation of these macromolecules is necessary for the vegetative growth of D. discoideum.

Modification of lymphocyte migration by sulfated polysaccharides

The role of sulfated polysaccharides in lymphocyte migration has been analyzed in vivo using lymphocytes labeled with an intracellular DNA-binding fluorochrome Hoechst 33342. The influence of a panel of sulfated polysaccharides on entry (by injecting the sulfated polysaccharide prior to the labeled cells) and displacement from lymphoid organs (by injecting the sulfated polysaccharide after the labeled cells have localized) indicated that different sulfated polysaccharides have selective effects on entry and displacement, and furthermore positioning of subpopulations within organs. Additional experiments suggested that receptors for sulfated polysaccharides on high endothelial venules may interact with complementary structures on lymphocytes. The data supporting this conclusion were: (a) the normal localization behavior of lymphocytes preincubated with sulfated polysaccharides; (b) an inverse relationship between the expression of lymphocyte surface receptors for sulfated polysaccharides and the ability of the lymphocytes to enter lymphoid organs and (c) the selective binding of sulfated polysaccharide-coupled fluoresceinated beads to high endothelial venules. In this case only the beads coupled with the sulfated polysaccharides that inhibited entry bound to the high endothelial venules. These findings are discussed in terms of a fundamental cellular recognition system utilizing sulfated polysaccharides.

Glycosaminoglycan metabolism of HL-60 cells during differentiation induction by tetradecanoylphorbol-13-acetate

Many biochemical responses to phorbol ester differentiation inducers have been reported, including alterations in synthesis of specific gene products such as glycoproteins. Stage-specific glycosaminoglycan changes have previously been associated with the differentiation process, including a dramatic reduction in cellular chondroitin 4-sulfate during human myeloid leukemia cell maturation induced by 12-O-tetradecanoylphorbol-13-acetate (TPA). We have demonstrated that treatment of HL-60 human promyelocytic leukemia cells with 4-methyl-umbelliferyl-beta-D-xyloside increases precursor incorporation into glycosaminoglycans linked to beta-D-xyloside, rather than core protein, eliminating the need for core protein and xylosyltransferase. Therefore, these beta-D-xyloside-treated cells were used to study the decreased glycosaminoglycan production during TPA-induced HL-60 differentiation. Exposure of these pretreated HL-60 cells to TPA, which induces macrophage-like maturation, resulted in a 70% reduction of incorporation of [35S]sulfate into cell-associated glycosaminoglycans. Thus, even in HL-60 cells in which glycosaminoglycan production is maximally stimulated by beta-D-xyloside, TPA is a strong inhibitor of free glycosaminoglycan chain production, and this biochemical effect is associated with other features of leukocyte maturation.

Polysaccharides sulfated at the time of gastrulation in embryos of the sea urchin Clypeaster japonicus

Based on the fact that the development of sea urchin embryos is arrested at the blastula stage in sulfate-free sea water (SFSW), we attempted in the present study to elucidate the nature of sulfated polysaccharides (PSs) which appear at the time of gastrulation in embryos of the sea urchin Clypeaster japonicus. Electrophoretic analysis of PSs prepared from embryos at different developmental stages revealed that three kinds of PSs (3A, 3B, 3C) appear de novo at the gastrula stage, and that these PSs are not found in embryos at the hatching blastula stage, nor are they found in permanent blastula reared in SFSW. These, three PSs were mostly of extracellular matrix origin. Among them, 3C was identified as dermatan sulfate on the basis of its electrophoretic mobility and sensitivity to enzymatic digestion. 3A and 3B remained to be identified. Further, a plausible precursor of 3C, which was sulfated under normal conditions, was detected as 6D in the embryos reared in SFSW. Autoradiographic analysis using [35S]sulfate revealed that these three PSs, accounted for more than 90% of [35S]sulfate incorporated into the acid PS fraction during gastrulation.

Inaccessibility of certain Ricinus lectin binding sites due to the increase in hyaluronic acid during chick embryo development

Chick embryo fibroblasts constitute a useful model for investigating cell surface differentiation using Ricinus lectin as a marker. Fibroblasts from 8-day chick embryos had two classes of Ricinus lectin binding sites, whereas those from 16-day embryos displayed only one class. Hyaluronidase treatment of fibroblasts from 8-day embryos had no effect on their capacity to bind Ricinus lectin; however after this treatment, 16-day cells resembled 8-day cells since the former also exhibited two classes of lectin-binding sites. Treatment with hyaluronidase released 2-5 times more hyaluronic acid from the older cells than from the younger cells. The same hyaluronidase treatment did not change the number of 8-day cells detached by trypsin from the substrate, but increased the number of detached 16-day cells. These observations suggest (i) that the greater adhesiveness to the substrate of the 16-day cells might be due to the presence on the cell surface of a larger amount of glycosaminoglycans at 16 days than at 8 days, and (ii) that the increased accumulation of hyaluronic acid on the cell surface might be involved in an alteration in the cell membrane during differentiation.

Serum effects on the in vitro differentiation of sea urchin micromeres

When micromeres isolated from the 16-cell stage of Strongylocentrotus purpuratus are cultured in sea water containing 3.5% horse serum, they produce spicules at approximately the same time as in normal development. The serum requirement of the micromeres has been investigated by adding serum at varying intervals after isolation or by pulsing the cells with serum at specific times during their in vitro development. The optimum time of serum addition for spicule formation is 36 h after fertilization (AF). Further delay in the addition of serum results in a reduction in the number of spicules formed in culture and a delay in the time at which they appear. A 1-h pulse of serum at 36 h AF is sufficient to initiate a response in some of the micromere aggregates. A 12-h pulse at 36 h AF produces the maximum number of spicules per culture. The critical period for serum addition, 36-48 h AF, corresponds to the time in the normal embryo at which the syncytial primary mesenchyme ring is formed. Electron micrographs of cultured cells demonstrate that micromeres cultured without serum until 48 h AF fail to form pseudopodial extensions and remain as rosette-like clusters of cells. If serum is present, extensive pseudopodial networks form which resemble the primary ring syncytium. These results suggest that serum acts to stimulate fused pseudopodial networks in cultures of micromeres and that the resulting syncytium is necessary for spicule formation.

Differences in the distribution of O-sulphate groups of cell-surface and secreted heparan sulphate produced by human neuroblastoma cells in culture

Confluent cultures of a human neuroblastoma cell line (CHP100) were incubated for 48 h with D-[1-3H]glucosamine and sodium [35S]sulphate. Radioactive glycosaminoglycans were analysed in the growth medium, rapid trypsin digest of the cell monolayer and a 1% (w/v) Triton/0.5 M NaOH extract of the final cell pellet. Sulphated glycosaminoglycans co-chromatographed when eluted by NaCl gradient from DEAE-cellulose. The medium contained mainly chondroitin sulphates, whereas the cell surface was enriched in heparan sulphate. Heparan sulphate was isolated as chondroitinase ABC-resistant material and treated with nitrous acid. Analysis of the scission products on Bio-Gel P-10 yielded fragments varying in size from single disaccharides to glycans consisting of nine disaccharide units. Cell-surface and medium heparan sulphate had respectively 52% and 54% N-sulphated glucosamine residues distributed in similar patterns along the polymer chain. The N:O-sulphate ratio of neuroblastoma heparan sulphate was 1.1:1. Analysis by high-voltage electrophoresis of di- and tetrasaccharide products produced by nitrous acid treatment showed that the distribution of 'O'-sulphate groups differed strikingly between heparan sulphates from the medium and cell-surface compartments. A di-O-sulphated tetrasaccharide was identified in both heparan sulphate species. The absence of detectable amounts of 35[S]sulphate associated with fragments larger than tetrasaccharide supports the close topographical association of N-sulphate and O-sulphate groups.

Sulfated glycan present in the EDTA extract of Hemicentrotus embryos (mid-gastrula)

Light microscopical observations of the Alcian blue-stained gastrulae of Hemicentrotus pulcherrimus together with the scanning electron microscopical observations of the embryos revealed the presence of highly acidic glycans in the invaginating archenteron (inside surface), the surrounding of secondary mesenchyme cells (pseudopodial protrusions and filamentous structures) and the hyaline layer. In the embryos grown in sulfate-free sea water and thus with arrested gastrulation it was found that the dye stainability in the above regions was markedly reduced. The glycosaminoglycan fraction prepared from the whole embryos (mid-gastrulae) was found to contain various kinds of acidic glycans as analysed by chromatography on DEAE-cellulose. Among these glycan components, the "F" component was mainly recovered in the EDTA extract of the embryos, and was shown to be specifically deleted in the embryos grown in sulfate-free sea water, suggesting that the "F" component may be related to the Alcian blue-stainable material in Hemicentrotus embryos. The component "F" was found to consist of sulfated fucan and acid mucopolysaccharide (unidentified) chains, which are probably linked to a common peptide core, forming macromolecules with larger than 10(6) molecular weights.