Sakaru Suzuki

Cytodifferentiation and proteoglycan biosynthesis

The connective and skeletal tissues are concerned chiefly with the formation and maintenance of bodily structure. In addition to a wealth of collagen or other fibrous constituents, these tissues contain in their intercellular matrix a specific group of polysaccharideprotein compounds (proteoglycans**), in which the polysaccharide moiety (mucopolysaccharides) is composed of characteristic disaccharide units. A large body of evidence has now accumulated on the chemical characterization and structural configuration of the intercellular constituents. Certain aspects of the formation and deformation of the intercellular matrix and the role of cells in these processes have been studied also in some detail. Furthermore, a number of recent studies have called attention to the action of extracellular macromotecules on cells in a manner resulting in profound alteration of cell metabolism, growth, and various other properties. Our interest in the chemistry and metabolism of proteoglycans is an outgrowth of a curiosity about the mechanism of cytodifferentiation of cartilage cells

Appearance of distinct types of proteoglycan in a well-defined temporal and spatial pattern during early cartilage formation in the chick limb

Our recent studies have shown that chick embryo epiphyseal cartilage synthesizes three distinct species of proteoglycan (PG-H, PG-Lb, and PG-Lt) which are analogous in having glycosaminoglycan side chains of the chondroitin (dermatan) sulfate type but different from one another in regard to the structure of core protein. In the present report, the expression of PG-H and PG-Lb has been studied in developing chick hind limbs (stages 19-33), using antibodies specific for these substances in indirect immunofluorescence. At the onset of cartilage morphogenesis (stage 24), PG-H became recognizable in the cartilage primordia, whereas a parallel section stained for PG-Lb showed no reaction. The first evidence of PG-Lb appearance was seen in a stage 28 cartilage (e.g., tibia) in which the cells in the middiaphysis became elongated in a direction perpendicular to the long axis of the cartilage. The PG-Lb fluorescence was confined to the zone of these flattened, disc-like cells, whereas the fluorescence for PG-H was uniformly distributed throughout the cartilage. With further development of cartilage (stage 29 approximately), the zone of flattened cells spread proximally and distally, and simultaneously large hypertrophied cells appeared at the diaphyseal region. During these zonal changes of cell morphology, the PG-Lb fluorescence remained restricted to the zone of flattened cells. Parallel sections stained for PG-H, in contrast, showed an evenly distributed pattern of the PG-H fluorescence throughout the cartilage. The results indicate that the appearance of PG-Lb is closely associated with the zonal changes of cell shape and orientation along the proximal-distal axis of the developing limb cartilage, and further suggest that the flattened chondrocytes in this particular zone have undergone additional changes in gene expression to form an extracellular matrix of still another chemical property.

Selective removal of heparan sulfate chains from proteoheparan sulfate with a commercial preparation of heparitinase

Procedures employing the commercial preparation of heparitinase were developed for isolating a protein-enriched core molecule from proteoheparan sulfate by selective removal of the heparan sulfate chains. Treatment of proteoheparan sulfate with the enzyme preparation caused seriously extensive degradation owing to the presence of proteolytic activity in the enzyme preparation. This effect could be avoided by using a series of protease inhibitors which prevented proteolytic degradation with less significant effect on the heparitinase activity. Application of the procedures to a purified preparation from the Engelbreth-Holm-Swarm tumor yielded a single protein-enriched core fraction with a molecular weight of approximately 450,000, as ascertained by sodium dodceyl sulfate-gel electrophoresis.

The occurrence of low buoyant density proteoglycans in embryonic chick cartilage

Abstract Two proteoglycan fractions, PCS-H and PCS-L, have previously been isolated from 4 M guanidine HCl extract of embryonic chick cartilages. This communication reports further studies with PCS-L indicating that this fraction contains several different forms, of which one differs from hitherto known cartilage proteoglycans in 1) markedly lower buoyant density, 2) susceptibility to reduction with 2-mercaptoethanol, 3) aggregate-forming ability in 4 M guanidine HCl, and 4) presence of dermatan sulfate-chondroitin sulfate copolymer chains. Also isolated from the PCS-L fraction is a keratan sulfate-rich proteoglycan which represents the smallest molecular size species in cartilage proteoglycan populations.

Synthesis of a fluorogenic mucopolysaccharide by chondrocytes in cell culture with 4-methylumbelliferyl β-d-xyloside

Culture of chondrocytes in the presence of 4-methylumbelliferyl beta-D-xyloside resulted in a synthesis of protein-free, fluorogenic chondroitin sulfate which was heterogeneous on DEAE-cellulose chromatography. Degradation of the major chromatographic fraction with chondroitinase-ABC yielded, in addition to a large quantity of delta4-glucuronic acid-containing disaccharides, two fluorogenic oligosaccharides of different size. Quantitative analysis showed that delta4-glucuronic acid, galactose, xylose, and 4-methylumbelliferone were present in the small oligosaccharide fragment in a molar ratio of 1:2:1:1. Since these analytical data are analogous to those reported for glycopeptides derivedfrom proteochondroitin sulfates, it may be suggested that 4-methyl-umbelliferyl beta-D-xyloside replaces the need for xylosyl protein core in the normal synthesis of proteochondroitin sulfate with a resultant production of the unusual polysaccharide bearing the added xyloside at the reducing end.

Morphological and biochemical differentiation of limb bud cells cultured in chemically defined medium.

Abstract When chick limb buds were isolated from stage 22–23 embryos and cultured in chemically defined medium “BGJb,” the explants grew and, after about 9 days, showed good chondrogenesis of recognizable cartilage segments. Cartilage-type proteoglycan (termed PCS-H) was not synthesized during early days of culture, but by Day 9, it became a major proteoglycan constituent of the tissue. Freshly dissociated limb bud cells, when plated as monodispersed cultures at a density of 7 × 10 6 cells/ml of BGJb, did not undergo chondrogenic differentiation and, instead, assumed the appearance of unhealthy or degenerated cells. During 9 days of culture, even though proteoglycans were synthesized, they were nevertheless of much smaller molecular size than PCS-H. When limb bud cells were cultured as a pellet containing 7 × 10 6 cells in 1 ml of BGJb, a more tightly packed aggregate of about 2 × 10 6 cells appeared in an inner region of the pullet during the first 24 hr of culture, and by Day 12 the aggregate had differentiated into a cartilage nodule surrounded by a thin layer of what appear to be ectodermal cells. As the conversion of aggregate into cartilage nodule progressed, newly formed proteoglycans gradually became more like cartilage-type proteoglycans, and by Day 12 they had many chemical and physical characteristics similar to those of the proteoglycans isolated from fully differentiated cartilages. The results indicate that the initial association of limb bud cells is an important factor for the chondrogenesis in BGJb and further suggest that the tight binding of the cell surfaces to one another may directly or indirectly stimulate the mechanism of synthesis of cartilage-type proteoglycans.

Nascent mucopolysaccharides attached to the Golgi membrane of chrondrocytes

Abstract As observed radioautographically in the cartilage of embryonic chick, radio-sulfate was concentrated only in the Golgi apparatus within 10 min of its addition. The labeled material was obtained by cell fractionation as it exists in a bound form on the Golgi membrane. Comparison of this material to protein-polysaccharide isolated from the extracellular matrix supported the concept that biosynthesis of some chondroitin sulfate chain takes place prior to its conversion to the mature form, protein-polysaccharide.

Enzymatic dephosphorylation of dolichyl pyrophosphate — The bacitracinsensitive, rate-limiting step for dolichyl mannosyl phosphate synthesis in rat liver microsomes

Abstract The incorporation of [14C]mannose from GDP-[14C]mannose into dolichyl mannosyl phosphate in rat liver microsomes showed a biphasic time-course; an initial rapid incorporation of mannose which ceased within 2 min and a much slower incorporation which continued for 30 min. In the presence of 0.18 mM (250 μg/ml) bacitracin, the rapid incorporation proceeded normally whereas the slow incorporation was inhibited by about 70%. Upon addition of dolichyl pyrophosphate, the microsomes catalyzed the dephosphorylation of the added compound which was also inhibited by bacitracin. The results, coupled with several other observations, suggest that the rapid reaction represents the transfer of mannose to endogenous dolichyl phosphate whereas the bacitracin-sensitive, slow reaction represents a more complex process in which the enzymatic dephosphorylation of dolichyl pyrophosphate is involved as a rate-limiting step.

Isolation of a large glycopeptide from cartilage procollagen by collagenase digestion and evidence indicating the presence of glucose, galactose and mannose in the peptide

Abstract Digestion of cartilage procollagen, pro-α1(II), with bacterial collagenase followed by fractionation of Sephadex G-150 yielded a large glycopeptide (molecular weight 13,200) which could not be demonstrated in a similarly prepared digest of α1(II) chain. Isotopic studies suggested that this glycopeptide contained, in addition to glucose and galactose, mannose, a sugar that is not found in the authentic α-chain of cartilage. The results imply that in pro-α1(II) there is a glycopeptide region differing from the α1(II) chain in amino acid composition and also in the type of carbohydrates attached.

N-acetylgalactosamine 4,6-bissulfate in rat urine I. Isolation, identification and chemical synthesis

By starting with 4 1 of rat urine, it was possible to obtain a sulfate ester of hexosamine in crystalline form. A series of identification procedures including chemical analyses, enzymatic digestion, proton magnetic resonance spectroscopy and infrared spectroscopy showed that this substance is 2-acetamido-2-deoxy-D-galactose 4,6-bissulfate. The trivial name for this compound is N-acetylgalactosamine 4,6-bissulfate; Quantitation by isotopic techniques indicated the urine possessed an average concentration of 8 muM N-acetylgalactosamine 4,6-bissulfate. Further extension of these studies necessitated the chemical synthesis of N-acetylgalactosamine 4,6-bissulfate and related compounds to be used for references or as biological substrates. Direct sulfation of N-acetylgalactosamine was attempted first, and strong preference for attack on the primary hydroxyl group (position 6) was found for chlorosulfonic acid. Thus, the reaction with 2.2 molar equivalents of the sulfating agent gave N-acetylgalactosamine 6-sulfate and its derivatives bearing a second sulfate at either position 1 (minor) or position 3 (major). The lack of sulfation at position 4 could be attributed to steric effects of the sulfate group preferentially attached to position 6. Another experiment in which UDP-N-acetylgalactosamine 4-sulfate was used in place of the free sugar led to the formation of a bissulfated sugar-nucleotide which, on subsequent hydrolysis with mild acid, afforded N-acetylgalactosamine 4,6-bissulfate, the same compound as that obtained from rat urine.