Quantitative and qualitative approach of glycan-glycan interactions in marine sponges.

Cell recognition and adhesion involving many kinds of cell surface molecules operate via homotypic and/or heterotypic protein-protein and protein-carbohydrate binding. Our investigations in marine sponges have provided direct evidence for a novel molecular mechanism of multivalent glycan-glycan binding related to cellular interactions. Biochemical characterization of purified proteoglycans revealed the presence of specific acidic glycans, different from classical glycosaminoglycans. Such acidic glycans of high molecular weight, containing fucose, glucuronic or galacturonic acids, and pyruvate and sulfate groups may represent a new class of primordial proteoglycans, named by us glyconectins. The thermodynamic and kinetic approaches of biological macromolecule interactions do not provide a direct measurement of the intermolecular binding forces that are fundamental for the function of the ligand-receptor association. Using the atomic force microscopy (AFM), we provided the first quantitative evaluation of the binding strength between cell adhesion proteoglycans. Measurement of binding forces intrinsic to cell adhesion glyconectin proteoglycans (AGPs) is necessary to assess their contribution to the maintenance of the anatomical integrity of multicellular organisms. (i) As a model, we selected the cell AGP isolated from the marine sponge Microciona prolifera; it mediates in vivo cell recognition and aggregation via homotypic, species-specific, multivalent, and calcium ion-dependent glycan-glycan interactions. (ii) Under physiological conditions, a large cohesive force theoretically able to hold the weight of approximately 1600 cells was measured. (iii) The C-2 autocomplementarity model for AGP-AGP interactions; and (iv) the requirement of the calcium ionic bridges suggest also that the self-recognition and multivalency of glycan-glycan interactions are essential for cell adhesion. (v) The evolution of glyconectin-like proteoglycan molecules may have been a fundamental prerequisite for the emergence of the first multicellular organisms. Glycan-glycan interactions may thus provide a new paradigm for molecular self-recognition.

Atomic force microscopy measurements. Measurements of binding strength between a single pair of molecules in physiological solutions.

Atomic force microscopy (AFM) measurements of intermolecular binding strength between a single pair of complementary cell adhesion molecules in physiological solutions provided the first quantitative evidence for their cohesive function. This novel AFM based nanobiotechnology opens a molecular mechanic approach for studying structure to function related properties of any type of individual biological macromolecules. The presented example of Porifera cell adhesion glyconectin proteoglycans showed that homotypic carbohydrate to carbohydrate interactions between two primordial proteoglycans can hold the weight of 1600 cells. Thus, glyconectin type carbohydrates, as the most peripheral cell surface molecules of sponges (today's simplest living Metazoa), are proposed to be the primary cell adhesive molecules essential for the evolution of the multicellularity.

Molecular self-recognition and adhesion via proteoglycan to proteoglycan interactions as a pathway to multicellularity: atomic force microscopy and color coded bead measurements in sponges.

During the emergence of multicellular organisms, molecular mechanisms evolved to allow maintenance of anatomical integrity and self-recognition. We propose that carbohydrates from proteoglycans, as the most peripheral cell surface, and matrix molecules might have provided these key adhesion and recognition functions. If so, the Porifera as the simplest metazoans alive today should retain, at least in part, proteoglycan adhesion and recognition mechanisms. Early work on cell adhesion of dissociated marine sponge cells provided important phenomenological evidence for cell sorting. Here is reviewed recent work on molecular mechanisms of cell recognition and adhesion mediated by cell surface proteoglycans purified from three marine sponge species, Microciona prolifera, Halichondria panicea, and Cliona celata. Biochemical characterization of isolated proteoglycans showed that each species expressed a unique type of primordial molecule named glyconectins. These proteoglycans displayed species-specific self-recognition and adhesion in color-coded bead, cell, and blotting assays. The specificity of homophilic proteoglycan to proteoglycan interactions in the Porifera approaches the binding selectivity of the evolutionarily advanced immunoglobulin superfamily system. Such xeno-selectivity may be a new paradigm for the molecular self-recognition, which was a fundamental requirement in the self/non-self discrimination during the emergence of multicellularity and further divergence of species. We have used atomic force microscopy (AFM) technology to directly measure intermolecular binding strength between individual pairs of ligand and receptor molecules in physiological solution. Homophilic glyconectin interactions were investigated by AFM after covalent attachment of the protein core to the sensor tip and to a flat surface, leaving the carbohydrates unmodified. AFM measurements of the binding strength between glyconectins indicated that one pair of molecules could theoretically hold the weight of 1,600 cells in physiological solution. These results provided the first essential and quantitative evidence that proteoglycan-proteoglycan binding can perform the adhesion function that we have assigned to it. Our investigations with purified proteoglycans from the marine sponge M. prolifera (glyconectin 1) using bead and cell adhesion assays have provided evidence that a new molecular mechanism of polyvalent and specific glycan-glycan binding between proteoglycans can mediate cell recognition and adhesion. Partial sequencing of the glycans has revealed two new cell adhesion carbohydrate structures: (3)GlcNAc(3OSO3)beta1-3Fuc and Pyr4,6Galbeta1-4GlcNAcbeta1-3Fuc.

Binding strength between cell adhesion proteoglycans measured by atomic force microscopy.

Measurement of binding forces intrinsic to adhesion molecules is necessary to assess their contribution to the maintenance of the anatomical integrity of multicellular organisms. Atomic force microscopy was used to measure the binding strength between cell adhesion proteoglycans from a marine sponge. Under physiological conditions, the adhesive force between two cell adhesion molecules was found to be up to 400 piconewtons. Thus a single pair of molecules could hold the weight of 1600 cells. High intermolecular binding forces are likely to form the basis for the integrity of the multicellular sponge organism.

A novel class of embryonic cell adhesion glycan epitopes is expressed in human colon carcinomas.

A new class of acidic glycans isolated from marine sponges and sea urchin embryos was shown to mediate cell adhesion via carbohydrate-carbohydrate interactions. Cell aggregation blocking monoclonal antibodies (Block 1 and Block 2 mAbs) directed against these polysaccharides localized functional epitopes in embryonic sea urchin gut. Immunofluorescence light microscopy of human colon carcinomas and healthy colon samples with Block 1 and Block 2 mAbs established that the carbohydrate structures similar to the invertebrate acidic glycan adhesion molecules are also expressed in humans. The Block 1 mAb labeled basal and apical lamina of tumor cells, whereas the Block 2 bound exclusively to the apical part of the epithelium. In normal tissue whole goblet cell membrane was stained with both antibodies indicating that transformation leads to spatial rearrangement of glycan antigens. Acidic glycans from human colon carcinomas and normal colon were isolated after delipidation, and complete pronase and DNase digestion, by gel filtration and adsorption to anion exchange membranes. Immunodot assay with Block 1 and Block 2 mAbs revealed that tumor cells have elevated expression of both carbohydrate structures. These results suggest that the acidic glycan adhesion molecules, originally found in sponges and sea urchin embryos, may represent a new class of carbohydrate carcino-embryonal antigens involved in cellular interactions associated with morphogenesis, metastasis and renewal of adult tissue.

A novel class of adhesion acidic glycans in sea urchin embryos. Isolation, characterization and immunological studies during early embryonal development.

Total glycans were isolated and purified from Lytechinus pictus embryos at early developmental stages by gel-filtration chromatography after pronase and DNase digestion, and alkali-borohydride treatment. Fractionation by Superose 6 and HPLC gel-filtration chromatography revealed three major glycan fractions of 580, 150 and 2 kDa consistently throughout development up to the stage of end gastrula. The 580-kDa and the 150-kDa glycan fractions isolated from fertilized eggs up to the stage of end gastrula are highly acidic, whereas the 2-kDa glycan fractions have no detectable uronic acid residues and charged groups. Chemical analysis of the glycan fractions showed that their content of neutral hexoses, uronic acid, GlcNAc, GalNAc and sulphate changes during development. The resistance of the 580-kDa and the 150-kDa glycan fractions to glycosaminoglycan-degrading enzymes indicates a structure which is different from the glycosaminoglycans. The incorporation of [3H]glucosamine into the 580-kDa, the 150-kDa and the 2-kDa glycan fractions showed that glycan synthesis increases in a linear fashion from the stage of early blastulation to end of gastrulation. Maximal incorporation of the radioligand occurs in the 2-kDa glycan fractions, with the highest rate observed between the stages of mesenchyme blastula and early gastrulation. Immunological studies, using a monoclonal antibody which inhibits cell aggregation, showed that the total glycans isolated from morula, early blastulation, early gastrulation and the end of gastrulation carry cell-adhesion epitopes. The number of these epitopes, as indicated by the intensity of the immunostaining, increases from morula formation to end-gastrulation stages and correlates with the increased rate of morphogenetic movements. These results suggest that controlled expression of the cell-adhesion glycan epitopes play an important role in sea urchin gastrulation.

Isolation and characterization of a new class of acidic glycans implicated in sea urchin embryonal cell adhesion.

Three major glycan fractions of 580 kDa (g580), 150 kDa (g150), and 2 kDa (g2) were isolated and purified from Lytechinus pictus sea urchin embryos at the mesenchyme blastula stage by gel filtration and high pressure liquid chromatography. Chemical analysis, by gas chromatography, revealed that g580 is highly sulfated and rich in N-acetylglucosamine, N-acetylgalactosamine, glucuronic acid, and fucose. The g150 fraction is less acidic than g580 and contains high amounts of amino sugars, xylose, and mannose. The g2 fraction is neutral, rich in N-acetylglucosamine, mannose, and galactose. The g580 and g150 fractions are resistant to glycosaminoglycan-degrading enzymes, indicating that they are distinct from the glycosaminoglycans. The g580 fraction resembles, with respect to chemical composition, a previously characterized 200 kDa sponge adhesion glycan (g200). The binding of the monoclonal antibody Block 2, which recognizes a repetitive epitope on g200, as well as of the anti-g580 polyclonal antibodies to both g580 and g200 indicated that these two glycans share similar antigenic determinants. The Fab fragments of the Block 2 antibody, which previously have been shown to inhibit cell adhesion in sponges, also blocked the reaggregation of dissociated sea urchin mesenchyme blastula cells. These results indicate that g580 carries a carbohydrate epitope, similar to the sponge adhesion epitope of g200, which is involved in sea urchin embryonal cell adhesion.

Expression of type IV collagen-degrading activity during early embryonal development in the sea urchin and the arresting effects of collagen synthesis inhibitors on embryogenesis.

Type IV collagen-degrading activity was expressed in homogenates of Lytechinus pictus embryos during embryogenesis. Activity was concentrated 1,600-fold by ammonium sulfate fractionation, ion exchange, and gel chromatography and could not be activated further upon trypsin or organomercurial treatment. This enzyme activity could also degrade gelatin but had no affinity for type I, III, and V collagens. Activity was inhibited by addition of excess type IV collagen or gelatin, but was unaffected by addition of excess amounts of non-collagenous proteins of the extracellular matrix. Chelators such as 1,10-phenanthroline or Na2EDTA reduced activity to control levels. Inhibitors of plasmin and of serine and thiol proteases were without effect. Type IV collagen-degrading activity first became apparent at the stage of early mesenchyme blastula. It then increased by a small increment and remained stable up to the stage of late mesenchyme blastula, coinciding with first detection of collagen synthesis and the appearance of the archenteron. Thereafter, a sharp increase in activity was observed, concurrently with remodelling of the archenteron. Maximum activity was attained at prism stage and was retained throughout to pluteus-larva stage. The specific inhibitors of collagen biosynthesis 8,9-dihydroxy-7-methyl-benzo[b]quinolizinium bromide and tricyclodecane-9-yl xanthate arrested sea urchin embryo development at early blastula, prevented the invagination of the archenteron, and reverted the expression of type IV collagen-degrading activity to non-detectable levels. Removal of the inhibitors allowed embryos to gastrulate and express type IV collagen-degrading activity.

Carbohydrate-carbohydrate interactions of a novel acidic glycan can mediate sponge cell adhesion.

Cell recognition and adhesion were first demonstrated in marine sponges. These phenomena were later shown in Microciona prolifera sponge to be mediated by a Ca(2+)-dependent self-association of adhesion proteoglycans (APs) attached in a species-specific manner to cell-surface receptors. Using the same experimental system we now provide three lines of evidence that highly polyvalent Ca(2+)-dependent carbohydrate-carbohydrate interactions of a novel AP glycan represent the basis of AP-AP self-binding and thus of cell adhesion. 1) A specific monoclonal antibody which blocks cell aggregation and AP bead adhesion identified a highly repetitive novel carbohydrate epitope (2500 sites) in an acidic glycan of M(r) = 200 x 10(3) (g200) from AP. 2) Reconstitution of the Ca(2+)-dependent self-interaction activity of AP was achieved by cross-linking the purified protein-free g200 glycan into polymers of similar valency as the native AP. 3) Beads coated with the protein-free g200 glycan showed a Ca(2+)-dependent aggregation equivalent to that of AP beads. Carbohydrate and amino acid analyses of the g200 glycan purified by gel electrophoresis, high performance liquid chromatography gel filtration, and ion exchange chromatography yielded six components in the following proportions; 68 fucose, 32 glucuronic acid, 2 mannose, 18 galactose, 19 N-acetylglucosamine, and 1 asparagine residue. These unique chemical features together with immunological and enzymological analyses suggest that the g200 glycan is a large highly fucosylated, acidic, N-linked polysaccharide with a novel structure distinct from that of other known glycosaminoglycans.

The species-specific cell-binding site of the aggregation factor from the sponge Microciona prolifera is a highly repetitive novel glycan containing glucuronic acid, fucose, and mannose.

Species-specific adhesion of dissociated cells from the marine sponge Microciona prolifera is mediated by a Mr = 2 x 10(7) proteoglycan-like aggregation factor (MAF) via two highly polyvalent functional domains, a cell-binding and a self-interaction domain. Glycopeptide N-glycosidase F release of a major glycan of Mr = 6.3 gamma 10(3) (G-6) from the MAF protein core resulted in the loss of cell binding activity, indicating a role of this polysaccharide molecule in MAF-cell association. The G-6 glycan was isolated and purified after complete Pronase digestion of MAF using gel electrophoresis, gel filtration, and ion exchange chromatography. Quantification of the amount of carbohydrate recovered in G-6 showed that one MAF molecule has about 950 repeats of this glycan. In its monomeric state G-6 did not display any measurable binding to cells (K alpha less than or equal to 10(3) M-1). Intermolecular cross-linking of the G-6 glycan with glutaraldehyde resulted, however, in the concomitant recovery of polyvalency (about 2200 repeats of G-6 per polymer of Mr greater than or equal to 1.5 x 10(7) and species-specific high cell binding affinity (K alpha = 1.6 x 10(9) M-1) but not of the MAF-MAF self-interaction activity. Thus, the G-6 glycan is the multiple low affinity cell-binding site involved in cell-cell recognition and adhesion of sponge cells. The G-6 glycan has 7 glucuronic acids, 3 fucoses, 2 mannoses, 5 galactoses, 14 N-acetylglucosamines, 2 sulfates, and 1 asparagine. Such a unique chemical composition indicates a new type of structure which includes features of glycosaminolycans and N-linked polysaccharides.

Involvement of a highly polyvalent glycan in the cell-binding of the aggregation factor from the marine sponge Microciona prolifera.

A proteoglycan-like aggregation factor from the marine sponge Microciona prolifera (MAF) mediates cell-cell recognition via a cell-binding and a self-association domain. After repetitive and prolonged treatment of MAF with glycopeptide-N-glycosidase (PNGase) the specific binding of MAF to homotypic cells was decreased by 72%. Polyacrylamide gel electrophoresis and gel filtration analysis of such PNGase digests showed that: 1) the enzyme released a single glycan type of Mr = 6 X 10(3) (G-6) from MAF, 2) 1 mole of MAF contains at least 830 moles of N-linked chains of G-6 glycan. The correlation between the loss of the binding activity of MAF and the extent of the release of the repetitive G-6 polysaccharide strongly suggests its involvement in MAF-cell association via highly polyvalent interactions.

Involvement of carbohydrates as multiple low affinity interaction sites in the self-association of the aggregation factor from the marine sponge Microciona prolifera.

Cell aggregation in the marine sponge Microciona prolifera is mediated by a multimillion molecular weight aggregation factor (MAF) and is based on two functional properties, a Ca2+-independent cell binding activity and a Ca2+-dependent factor-factor self-interaction. Monoclonal antibodies were prepared against purified MAF, and one clone was characterized which selectively inhibited the MAF-MAF association activity. Binding of the blocking antibody (Block 1) to MAF demonstrated that this epitope structure was present in 1100 copies per one MAF molecule of Mr = 2 X 10(7). Such blocking antibodies precipitated a small molecular weight protein-free glycan fraction prepared from MAF by Pronase digestion, thus indicating that the highly repetitive epitope is located in the carbohydrate portion of the molecule. Since the inhibitory activity of the Block 1 antibody could only be achieved when most of the sites were occupied by Fab fragments of this antibody, the self-association of MAF seemed to be based on the polyvalency of the carbohydrate determinants. The affinity of the protein-free glycans was very low as shown by the fact that they did not display any measurable self or MAT binding activity in their monomeric form. After cross-linking them with glutaraldehyde into polymers of the size of MAF, however, the self-interaction could be reconstituted. Thus, the MAF-MAF association activity, which is needed for cell aggregation in sponges, seems to be based on multiple low affinity carbohydrate-carbohydrate interactions, which is different from most interactions mediated by adhesion molecules characterized so far.

Reconstitution of high cell binding affinity of a marine sponge aggregation factor by cross-linking of small low affinity fragments into a large polyvalent polymer.

Species-specific reaggregation of cells from the marine sponge Microciona prolifera is mediated by a proteoglycan-like aggregation factor (MAF) of Mr = 2 X 10(7) which has two functional domains, a cell binding domain and an aggregation factor interaction domain. After extensive trypsin digestion, over 60% of the MAF mass was converted into a glycopeptide fragment of Mr = 10,000 (T-10) which is therefore a representative part of the major portion, but not of the entire MAF molecule. The T-10 fragment has a similar amino acid and carbohydrate composition as the intact MAF and displays species-specific binding. Although T-10 also inhibited MAF association with homotypic cells, its apparent affinity is 3 X 10(6) M-1, i.e. 13,000 times lower than that of native MAF. Reconstitution of binding affinity in the same order of magnitude as native MAF (Ka = 10(10) M-1) was obtained by cross-linking the glycopeptide fragment into polymers of the approximate size of MAF (Mr greater than 1.5 X 10(7) using diepoxybutane and glutaraldehyde, or periodate oxidation and glutaraldehyde. The apparent association constants of intermediate polymers with Mr = 1 X 10(5), 6 X 10(5), 9 X 10(5), 2 X 10(6) and above 1.5 X 10(7) increased proportionally to their size and were in line with association constants of MAF degradation fragments. Since the binding affinity of the T-10 glycopeptide fragment could be reconstituted by cross-linking, and since this fragment accounts for over 60% of MAF, we propose that the specificity and high affinity of the MAF-cell association is based on a highly polyvalent interaction of low affinity cell-binding sites. Such a polyvalency of the cell binding domain is advantageous for efficient cell-cell interactions and thus differs from most known interaction molecules and receptors characterized.

Cell binding fragments from a sponge proteoglycan-like aggregation factor.

The marine sponge Microciona prolifera aggregation factor (MAF) is a 2 X 10(7) dalton proteoglycan. MAF mediates species-specific cell-cell recognition through two functionally different sites: a Ca2+-independent species-specific cell binding site and a Ca2+-dependent MAF-MAF binding site. Dissociation procedures combined with protease treatment were used to produce cell-binding pieces from the large complex. The seven different sized fragments produced were all uronic acid-rich glycoproteins of the apparent molecular weights: 15 X 10(6), 2.5 X 10(5), 1.2 X 10(5), 7 X 10(4), 2.7 X 10(4), 5 X 10(3), and 3.6 X 10(3). Each of the fragments retained species-specific binding to Microciona cells and was also capable of inhibiting MAF-promoted cell aggregation. However, the fragments were unable to bind to MAF-conjugated agarose beads in the presence or absence of CA2+ ions. These three properties are those expected for the cell binding site of MAF. Since the binding affinity decreased linearly with decreasing molecular weight of the fragments, we believe that the cell binding sites in MAF may be highly polyvalent, although to fully support such a concept, a detailed chemical characterization of each of the fragments is needed. A high valency of cell binding sites would overcome a relatively low Ka for the single site and would thereby not only guarantee specificity but also explain the need for the large size of the proteoglycan complex found to mediate species-specific sponge aggregation.