Interactions between mucopolysaccharides and cationic polypeptides in aqueous solution: hyaluronic acid, heparitin sulfate, and keratan sulfate

Circular dichroism spectroscopy has been used to study the interactions of hyaluronic acid, heparitin sulfate, and keratan sulfate with cationic polypeptides. The results indicate that the presence of these mucopolysaccharides has an effect in the conformation of poly(L -lysine) and poly(L -arginine), such that the former adopts the “random” form and the latter takes up the α-helical conformation, rather than the “charged coil” form expected at neutral pH. The relative strengths of the interactions can be judged from the melting temperatures above which they are disrupted. Both the stoichiometry and the strength of the interactions depend on the position, number, and type of anionic groups attached to the polysaccharide backbone. Such considerations place the six common mucopolysaccharides in order of increasing strength of interaction: hyaluronic acid < chondroitin 4-sulfate < heparitin sulfate < chondroitin 6-sulfate < keratan sulfate ? dermatan sulfate. These differences should be paralleled by differences in the interaction of the mucopolysaccharides with collagen and fibrous proteins.     

The effect of changes in salt concentration and pH on the interaction between glycosaminoglycans and cationic polypeptides.

Circular dichroism (CD) spectroscopy has been used to investigate the effects of changes in salt concentration and pH on the interactions between basic polypeptides and connective tissue glycosaminoglycans in dilute aqueous solution. The polypeptides undergo conformation-directing interactions in the presence of glycosaminoglycans, which are subject to transitions as the ionic strength and pH are varied. For poly(L -lysine), the conformational change due to interaction breaks down as the ionic strength (monovalent ions) is increased. Based on the ionic strength at which disruption occurs, the glycosaminoglycans can be placed in order of increasing strength of interaction: chondroitin 6-sulfate, hyaluronic acid, chondroitin 4-sulfate, heparin, and dermatan sulfate. Prior to the conformational transition, scattering effects are observed, indicating the development of larger aggregates. Each glycosaminoglycan induces α-helicity for poly(L -arginine), which does not break down as the ionic strength is increased, indicating a stronger interaction for this polypeptide. The pH-induced transitions are in the pH range 2.5–3.8 and are probably related to deionization of carboxyl groups. For poly(L -lysine) the conformational effect is disrupted at low pH. For poly(L -arginine), the transitions are not complete, but appear to correspond to an increase in scattering.     

Mucopolysaccharide-polypeptide interactions: Effect of the position of the sulfate group

The differences in the interaction in solution of poly(l-lysine) with chondroitin 6-sulfate (chondroitin sulfate C) and with chondroitin 4-sulfate (chondroitin sulfate A) have been studied by circular dichroism spectroscopy. Both mucopolysaccharides force the poly(l-lysine) to adopt the α-helix in solution rather than the charged coil form expected at neutral pH. The observed spectra indicates that the polypeptide is at least 80% helical when the 6-sulfate form is present, but only about 20% α-helical in the presence of chondroitin 4-sulfate. Thus chondroitin66-sulfate has a stronger conformation directing effect on poly(l-lysine) than does the 4-sulfate, which is probably due to the different positions of the sulfate group on the polysaccharide c chain.     

Interactions between chondroitin-6-sulfate and poly-L-lysine in aqueous solution: Circular dichroism studies

The interactions between chondroitin-6-sulfate (chondroitin sulfate C) and poly-L -lysine have been studied as models for investigation of possible complex formation between fibrous proteins and mucopolysaccharides. Results obtained using circular dichroism spectroscopy show that poly-L -lysine adopts the α-helical conformation in dilute aqueous salt solution at pH 7 when mixed with chondroitin-6-sulfate, rather than the “charged-coil” observed in the absence of this mucopolysaccharide. This conformation-directing interaction is at a maximum when the ratio of lysine to disaccharide residues is 1 : 1. Changes in the CD spectrum of a 1 : 1 mixture following increase in the salt concentration, or addition of non-polar solvents, indicate that the interaction is ionic in nature. No such effects are observed for non-sulfated mucopolysaccharides mixed with poly-L -lysine, suggesting that, for chondroitin-6-sulfate, it is the sulfate groups rather than the carboxyls which interact with the amine groups of the polypeptide. Elevation of the temperature leads to disruption of the interactions between the polypeptide and polysaccharide species. A sharp melting transition occurs at 47.0 ± 1.0°C, when the poly-L -lysine reverts to the “charged-coil” conformation. The sharp transition suggests that regular ionic bonds are formed between the polypeptide and polysaccharide. These results suggest that a conformation-directing interaction may occur between sulfated mucopolysaccharides and the polar regions of collagen and other fibrous proteins.     

Interaction between chondroitin-6-sulfate and poly-L-arginine in aqueous solution

The interactions between chondroitin-6-sulfate and poly-L -arginine in aqueous salt solution have been investigated by circular dichroism techniques. In the presence of chondroitin-6-sulfate, at neutral pH, poly-L -arginine adopts the α-helical conformation rather than “charged coil” form observed in the absence of mucopolysaccharide. This interaction is at a maximum when the ratio of arginine to disaccharide residues is 2:1. Elevation of the temperature leads to a sharp melting transition at 76.0 ± 1.0°C. This behavior is in marked contrast to that for poly-L -lysine-chondroitin-6-sulfate interactions, which are at a maximum at a 1:1 residue ratio and have a melting transition at 47.0 ± 1.0°C. These results indicate a stronger interaction for poly-L -arginine than for poly-L -lysine. The positive arginine side chains appear to interact with both the negative sulfate and carboxyl residues, while those of the lysines are involved only with the sulfates. Poly-L -ornithine at neutral pH shows no conformation directing interaction with chondroitin-6-sulfate, although a small proportion of α-helix is formed on dilution of the mixture with methanol. The extent of the interaction of cationic polypeptides with chondroitin-6-sulfate increases in the order poly-L -ornithine, poly-L -lysine, poly-L -arginine, i.e., in the order of increasing side-chain length.     

Selective exposure of mucopolysaccharides is involved in macrophage physiology.

Surface and intracellular mucopolysaccharides of guinea-pig peritoneal macrophages maintained in suspension and monolayer culture were studied. At least five classes of compound (hyaluronic acid, heparan sulfate, dermatan sulfate, chondroitin 4-sulfate and chondroitin 6-sulfate) were resolved and characterized by electrophoresis and enzymatic degradation. The results reported here suggest that modulation of mucopolysaccharide exposure is involved in macrophage physiology. The possible biological role of surface mucopolysaccharides in macrophage activity is discussed.     

Chromatography of glycosaminoglycans on hydrophobic gel. Correlation between chromatographic behavior of glycosaminoglycans on phenyl-sepharose CL-4B and their solubility in the presence of high concentrations of ammonium sulfate

The effect of bound sulfate groups and uronic acid residues of glycosaminoglycans on their behavior in chromatography on hydrophobic gel was examined by the use of several pairs of depolymerized chondroitin, chondroitin 4- or 6-sulfate, and dermatan sulfate having comparable degree of polymerization. Chromatography on Phenyl-Sepharose CL-4B in 4.0-2.0 ammonium sulfate containing 10m hydrochloric acid showed that: (a) The retention of depolymerized chondroitin 4- or 6-sulfate on the gel varies with the temperature, whereas the depolymerized samples of chondroitin and dermatan sulfate does not show a temperature dependence (this is not the case for hyaluronic acid or dextrans). (b) Among depolymerized samples of chondroitin and chondroitin 4- and 6-sulfate that have a similar degree of polymerization, chondroitin 4- and 6-sulfate showed the highest retention. (c) The retention on the gel of chondroitin 6-sulfate, chondroitin 4-sulfate, and dermatan sulfate decreased in this order. The solubility in ammonium sulfate solution of the polysaccharides agreed well with the chromatographic behavior, suggesting that the fractionation by the hydrophobic gel largely depends on the ability to precipitate on the gel rather than on the hydrophobic interaction between gel and polysaccharide.     

Modulation of cAMP-dependent protein kinase by derivatives of chondroitin sulfate

Here, we report investigations about the direct effect of glycosaminoglycans, such as dermatan sulfate, chondroitin 4- and 6-sulfate upon cAMP-dependent protein kinase activity. The results indicate that glycosaminoglycans strongly influence the phosphorylation activity of this enzyme against histone type IIa and [Val⁶,Ala⁷]-kemptide. While chondroitin 4-sulfate and dermatan sulfate exhibit inhibitory effects, chondroitin 6-sulfate shows a stimulating effect. In addition, the chondroitin 6-sulfate is also able to reduce the chondroitin 4-sulfate and dermatan sulfate specific inhibition.     

Effects of sulfate deprivation on the production of chondroitin/dermatan sulfate by cultures of skin fibroblasts from normal and diabetic individuals

Human skin fibroblast monolayer cultures from two normal men, three Type I diabetic men, and one Type I diabetic woman were incubated with [3H]glucosamine in the presence of diminished concentrations of sulfate. Although total synthesis of [3H]chondroitin/dermatan glycosaminoglycans varied somewhat between cell lines, glycosaminoglycan production was not affected within any line when sulfate levels were decreased from 0.3 mM to 0.06 mM to 0.01 mM to 0 added sulfate. Lowering of sulfate concentrations resulted in diminished sulfation of chondroitin/dermatan in a progressive manner, so that overall sulfation dropped to as low as 19% for one of the lines. Sulfation of chondroitin to form chondroitin 4-sulfate and chondroitin 6-sulfate was progressively and equally affected by decreasing the sulfate concentration in the culture medium. However, sulfation to form dermatan sulfate was preserved to a greater degree, so that the relative proportion of dermatan sulfate to chondroitin sulfate increased. Essentially all the nonsulfated residues were susceptible to chondroitin AC lyase, indicating that little epimerization of glucuronic acid residues to iduronic acid had occurred in the absence of sulfation. These results confirm the previously described dependency of glucuronic/iduronic epimerization on sulfation, and indicate that sulfation of the iduronic acid-containing disaccharide residues of dermatan can take place with sulfate concentrations lower than those needed for 6-sulfation and 4-sulfation of the glucuronic acid-containing disaccharide residues of chondroitin. There were considerable differences among the six fibroblast lines in susceptibility to low sulfate medium and in the proportion of chondroitin 6-sulfate, chondroitin 4-sulfate, and dermatan sulfate. However, there was no pattern of differences between normals and diabetics.     

Purification and characterization of N-acetylgalactosamine 4-sulfate 6-O-sulfotransferase from the squid cartilage

N-Acetylgalactosamine 4-sulfate 6-O-sulfotransferase (GalNAc4S-6ST), which transfers sulfate from 3'-phosphoadenosine 5'-phosphosulfate (PAPS) to position 6 of N-acetylgalactosamine 4-sulfate in chondroitin sulfate and dermatan sulfate, was purified 19,600-fold to apparent homogeneity from the squid cartilage. SDS-polyacrylamide gel electrophoresis of the purified enzyme showed a broad protein band with a molecular mass of 63 kDa. The protein band coeluted with GalNAc4S-6ST activity from Toyopearl HW-55 around the position of 66 kDa, indicating that the active form of GalNAc4S-6ST may be a monomer. The purified enzyme transferred sulfate from PAPS to chondroitin sulfate A, chondroitin sulfate C, and dermatan sulfate. The transfer of sulfate to chondroitin sulfate A and dermatan sulfate occurred mainly at position 6 of the internal N-acetylgalactosamine 4-sulfate residues. Chondroitin sulfate E, keratan sulfate, heparan sulfate, and completely desulfated N-resulfated heparin were not efficient acceptors of the sulfotransferase. When a trisaccharide or a pentasaccharide having sulfate groups at position 4 of N-acetylgalactosamine was used as acceptor, efficient sulfation of position 6 at the nonreducing terminal N-acetylgalactosamine 4-sulfate residue was observed.     

Epitope-specific changes in chondroitin sulfate/dermatan sulfate proteoglycans as markers in the lymphopoietic and granulopoietic compartments of developing bursae of Fabricius

The types and distributions of chondroitin sulfate proteoglycans within developing chick bursae of Fabricius were determined by indirect immunocytochemical analyses using mAb specific for chondroitin/dermatan sulfate epitopes. Analyses obtained from the use of well characterized mAb known to specifically identify chondroitin 4- and dermatan sulfates (antibody 2B6) and chondroitin 6-sulfate (antibody 3B3) were compared with those obtained from two additional mAb raised against chick chondroitin sulfates proteoglycans derived from hemopoietic tissue. The results indicate that chondroitin sulfate compositions of the adjacent lymphopoietic and granulopoietic compartments differ. Chondroitin 6-sulfate, notably absent from lymphopoietic regions, is a major chondroitin sulfate species in granulopoietic regions of day 13 bursae. Moreover, chondroitin 6-sulfate disappears from the granulopoietic compartment in a time course that corresponds to the decline in granulopoietic activity. Simultaneously, there is an apparent increase in chondroitin sulfates associated with developing medullary regions of lymphoid follicles. The content of chondroitin 4-/dermatan sulfates and, most significantly, of chondroitin/dermatan sulfates identified by antibodies raised against chick proteoglycans, increases within developing follicles. As a consequence, by day 18 of incubation, immunostained follicles become clearly demarcated from the connective tissue of the tunica propria. This study provides evidence that chondroitin sulfates are constituents of both lymphopoietic and granulopoietic microenvironments and that subtle changes occur within these proteoglycan structures during bursal development. These developmental changes in chondroitin sulfate compositions are consistent with these molecules playing a functional role in hemopoiesis.     

Turnover, change of composition with rate of cell growth and effect of phenylxyloside on synthesis and structure of cell surface sulfated glycosaminoglycans of normal and transformed cells

The synthesis of sulfated glycosaminoglycans was analysed in mouse fibroblasts during the transition from exponential growth to quiescent monolayers. 'Normal' Swiss 3T3 fibroblasts were compared with SV40 transformed 3T3, C6, ST1 and HeLa cells. p-Nitrophenyl-beta-D-xyloside, an artificial acceptor for glycosaminoglycans synthesis, was used as a probe. Exponentially growing 'normal' 3T3 cells synthesized both dermatan sulfate and chondroitin 4-sulfate, retaining the latter and releasing the former to the medium. Upon reaching quiescence these cells switched to retention of dermatan sulfate and release of chondroitin 4-sulfate. SV3T3 cells synthesized several fold less sulfated glycosaminoglycans than 'normal' 3T3. Even though SV3T3 cells are able to synthesize dermatan sulfate, they only retained chondroitin 4-sulfate, never switching to retention of dermatan sulfate. These results indicated that the transition from rapidly proliferating to resting G0 state in normal cells is accompanied by a switch from chondroitin-sulfate rich to dermatan-sulfate-rich cells. This switching was not observed with transformed cells, which are unable to enter the G0 state. Phenylxyloside caused a several fold increase in glycosaminoglycans released to the medium in both cell types, but it did not interfere with either growth rate or cell morphology. Particularly the phenylxyloside treatment led to an increase of more than 10-fold in production of dermatan and chondroitin sulfate by SV3T3, C6, ST1 and HeLa cells. This demonstrated that transformed cells have a high capacity for glycosaminoglycan synthesis. Analysis of enzymatic degradation products of glycosaminoglycans, synthesized in the presence of phenylxyloside, by normal and transformed cells, led to the finding of 4- and 6-sulfated iduronic and glucuronic acid-containing disaccharides. This result indicated that the xyloside causes the synthesis of a peculiar chondroitin sulfate/dermatan sulfate, in both normal and transformed cells.     

A fingerprinting method for chondroitin/dermatan sulfate and hyaluronan oligosaccharides

A previously published method for the analysis of glycosaminoglycan disaccharides by high pH anion exchange chromatography (Midura,R.J., Salustri,A., Calabro,A., Yanagishita,M. and Hascall,V.C. (1994), Glycobiology,4, 333-342) has been modified and calibrated for chondroitin and dermatan sulfate oligosaccharides up to hexasaccharide in size and hyaluronan oligosaccharides up to hexadecasaccharide. For hyaluronan oligosaccharides chain length controls elution position; however, for chondroitin and dermatan sulfate oligosaccharides elution times primarily depend upon the level of sulfation, although chain length and hence charge density plays a role. The sulfation position of GalNAc residues within an oligosaccharide is also important in determining its elution position. Compared to 4-sulfation a reducing terminal 6-sulfate retards elution; however, when present on an internal GalNAc residue it is the 4-sulfate containing oligosaccharide which elutes later. These effects allow discrimination between oligosaccharides differing only in the position of GalNAc sulfation. Using this simple methodology, a Dionex CarboPac PA-1 column with NaOH/NaCl eluents and detection by absorbance at 232 nm, a quantitative analytical fingerprint of a chondroitin/dermatan sulfate chain may be obtained, allowing a determination of the abundance of chondroitin sulfate, dermatan sulfate, and hyaluronan along with an analysis of structural features with a linear response to approximately 0.1 nmol. The method may readily be calibrated using either commercial disaccharides or the di- and tetrasaccharide products of a limit digest of commercial chondroitin sulfate by chondroitin ABC endolyase. Commercially available and freshly prepared shark, whale, bovine, and human cartilage chondroitin sulfates have been examined by this methodology and we have confirmed that freshly isolated shark cartilage CS contains significant amounts of the biologically important GlcA2Sbeta(1-3)GalNAc6S structure.     

Fractionation and isolation of heparan sulfates using poly-L-lysine-Sepharose

A simple procedure for the isolation of heparan sulfates from pig lung using a poly-L-lysine-Sepharose column is described. Glycosaminoglycans are absorbed on poly-L-lysine-Sepharose at pH 7.5 and eluted with an NaCl linear gradient in the following order: hyaluronic acid (0.32 M NaCl), chondroitin (0.36 M NaCl), keratan sulfate (0.80 M NaCl), chondroitin 4-sulfate (0.86 M NaCl), chondroitin 6-sulfate (0.95 M NaCl), dermatan sulfate (0.91 M NaCl), heparan sulfate (1.2 M NaCl), and heparin (1.35 M NaCl). Based on these observations, isolation of heparan sulfate from pig lung crude heparan sulfate fractions which contain chondroitin sulfates and dermatan sulfate was attempted, using this chromatographic technique.     

Human venous and arterial glycosaminoglycans have similar affinity for plasma low-density lipoproteins

We compared the glycosaminoglycan content of human venous and arterial walls. The most abundant glycosaminoglycan in human veins is dermatan sulfate whereas chondroitin 4/6-sulfate is preponderant in arteries. The concentrations of chondroitin 4/6-sulfate and heparan sulfate are approximately 4.8- and approximately 2.5-fold higher in arteries than in veins whereas dermatan sulfate contents are similar in the two types of blood vessels. Normal and varicose saphenous veins do not differ in their glycosaminoglycan contents. It is known that certain glycosaminoglycan species from the arterial wall, mainly high-molecular-weight fractions of dermatan sulfate+chondroitin 4/6-sulfate have greater affinity for plasma LDL. These types of glycosaminoglycans can be identified on a LDL-affinity column. We now demonstrated that a similar population of glycosaminoglycan also occurs in veins, although with a lower concentration than in the arteries due to less chondroitin 4/6-sulfate with affinity for LDL. The concentrations of dermatan sulfate species, which interact with LDL, are similar in arteries and veins. The presence of these glycosaminoglycans with affinity to plasma LDL in veins raises interesting questions concerning the role of these molecules in the pathogenesis of atherosclerosis. Possibly, the presence of these glycosaminoglycans in the vessel wall are not sufficient to cause retention of LDL and consequently endothelial dysfunction, but may require additional intrinsic factors and/or the hydrodynamic of the blood under the arterial pressure.     

Sulfated mucopolysaccharides of midgestation embryonic and extraembryonic tissues of the mouse

Incorporation of [³⁵S]sulfate into sulfated mucopolysaccharides has been characterized in midgestation mouse embryo, yolk sac, trophoblast, and decidua. Enzymatic analysis indicated that chondroitin sulfates contained approximately half of the label in embryo, trophoblast, and decidua, but less than 20% in yolk sac. While the labeled chondroitin sulfate fraction of trophoblast and decidua was mainly chondroitin-4-sulfate, only embryo contained a significant proportion of labeled chondroitin-6-sulfate. The relative incorporation into embryo chondroitin-6-sulfate was also substantially higher than that observed in four adult soft tissues. Labeled dermatan sulfate was absent from the embryo and yolk sac, but small amounts might have been synthesized by the placenta. Nitrous acid degradation studies revealed that essentially all the chondroitinase resistant MPS was N-sulfated, i.e., heparan sulfate and/or heparin. Electrophoretic profiles indicate that the bulk of the N-sulfated material resembles heparan sulfate rather than heparin. Electrophoretic heterogeneity and slow migration rates relative to standard markers suggest that the majority of labeled chondroitin sulfates may be undersulfated. The different mucopolysaccharide patterns in the various tissues may reflect their specialized properties and functions.     

Separation and properties of five glycosaminoglycan sulfatases from rat skin.

Chondroitin sulfates, dermatan sulfate, heparan sulfate, heparin, keratan sulfate, and oligosaccharides derived from these sulfated glycosaminoglycans have been used for the measurement of sulfatase activity of rat skin extracts. Chromatographic fractionation of the extracts followed by specificity studies demonstrated the existence of five different sulfatases, specific for 1) the nonreducing N-acetylglucosamine 6-sulfate end groups of heparin sulfate and keratan sulfate, 2) the nonreducing N-acetylgalactosamine (or galactose) 6-sulfate end groups of chondroitin sulfate (or keratan sulfate), 3) the nonreducing N-acetylgalactosamine 4-sulfate end groups of chondroitin sulfate and dermatan sulfate, 4) certain suitably located glucosamine N-sulfate groups of heparin and heparan sulfate, or 5) certain suitably located iduronate sulfate groups of heparan sulfate and dermatan sulfate. Two arylsulfatases, one of which was identical in its chromatographic behaviors with the third enzyme described above, were also demonstrated in the extracts. These results taken together with those previously obtained from studies on human fibroblast cultures suggest that normal skin fibroblasts contain at least five specific sulfatases and diminished activity of any one may result in a specific storage disease.     

Dermatan sulfate and chondroitin 6-sulfate conformations

X-ray diffraction patterns show that dermatan sulfate in oriented, crystalline films occurs as two or three or eight-fold helices. The two-fold helix has a greater axial rise per disaccharide residue $\text{[}\text{h}\text{= 9.6}\text{A}\text{?}\text{]}$ than the corresponding chondroitin 6-sulfate helix $\text{[}\text{h}\text{= 9.3}\text{A}\text{?}\text{]}$. Three-fold dermatan sulfate and chondroitin 6-sulfate helices both have $\text{h}\text{= 9.5}\text{A}\text{?}$. Consequently the α-L-iduronate residues in dermatan sulfate helices have the C1 chair conformation like β-D-glucuronate in chondroitin 6-sulfate. Since the eight-fold dermatan sulfate helix has $\text{h}\text{= 9.3}\text{A}\text{?}$ rather less than the eight-fold chondroitin 6-sulfate helix $\text{[}\text{h}\text{= 9.8}\text{A}\text{?}\text{]}$ the possibility of α-L-iduronate 1C chairs cannot be ruled out for it. Computer methods have been used to produce molecular models. In these the polysaccharide chains are almost linear. Each backbone conformation can accommodate a variety of arrangements of charged side groups.     

Characterization of a chondroitin 4-sulfate proteoglycan carrier for heparin neutralizing activity (platelet factor 4) released from human blood platelets

Platelet heparin neutralizing activity (platelet factor 4) is released from human blood platelets by thrombin in the form of a high molecular weight proteoglycan-platelet factor 4 complex. This complex was partially purified by isoelectric precipitation and gel filtration. At high ionic strength (I = 0.75) the complex dissociates into the active component (mol. wt 29000) and the proteoglycan carrier. The components were separated by gel filtration and the proteoglycan further purified by Na₂SO₄ treatment. The molecular weight of the purified carrier was 59000. The carbohydrate moieties of the proteoglycan isolated after papain digestion and ion-echange chromatography were shown to consist of chondroitin 4-sulfate by chemical, physical and electrophoretic analysis. The multichain proteoglycan consists of four chondroitin 4-sulfate chains (mol. wt 12000) in covalent linkage to a single polypeptide. The molecular weight (350000) of the fully saturated proteoglycan carrier suggests that 4 moles of platelet factor 4 are bound per mole of proteoglycan and that the carrier occurs in the form of a dimer consisting of 8 moles of platelet factor 4 and 2 moles of proteoglycan. The isolated chondroitin 4-sulfate moieties combine with platelet factor 4 at a binding ratio of one mole of platelet factor 4 per carbohydrate chain. Heparin completely displaces platelet factor 4 from both the saturated proteoglycan and chondroitin 4-sulfate complexes. Heparitin sulfate, dermatan sulfate and chondroitin 6-sulfate also combine stoichiometrically with platelet factor 4 and are displaced by equimolar amounts of heparin. Hyaluronic acid did not combine with platelet factor 4. The relative binding capacities of glycosaminoglycans for platelet factor 4 were shown to be: heparin (100), heparitin sulfate (75), chondroitin 4-sulfate (50), dermatan sulfate (50), chondroitin 6-sulfate (50), and hyaluronic acid (o). Chondroitin 4-sulfate was identified as the major glycosaminoglycan in all platelet subcellular fractions; in addition, the soluble fraction contains a minor amount of hyaluronic acid. Subcellular distribution studies revealed that 55% of both the proteoglycan carrier and platelet factor 4 activity were localized in the “granule rich” fraction. This data together with the low recovery of both these components in the membrane fraction, suggest that they occur together as a complex within specific granules and are released in this form under physiologic conditions.     

Change of glycosaminoglycan in pus of patients with purulent pleurisy

The glycosaminoglycan content in pus from patients with purulent pleurisy was studied. The uronic acid content rose in the first 4 hospital days, continued at a high level during hospital days 5-8, and then fell to a low level after 9 hospital days. Four glycosaminoglycans were isolated from the preparation; they were identified as hyaluronic acid, chondroitin 4-sulfate, chondroitin 6-sulfate, and dermatan sulfate. Hyaluronic acid was the main component and its relative proportion increased with increasing hospital days. The relative proportions of chondroitin 4-sulfate and chondroitin 6-sulfate were low during the first 4 day and during Days 10-21, whereas they were high during Days 5-9. The proportion of dermatan sulfate was high during the early hospital days, and thereafter decreased with increasing hospital days.