Enzymic pathways of hyaluronan catabolism

The enzymic degradation of hyaluronan in mammalian tissues takes place in two phases, encompassing breakdown of the polysaccharide to its monosaccharide constituents and subsequent utilization of the monosaccharide products. Degradation to the monosaccharide components is effected by the concerted action of three enzymes, hyaluronidase, beta-D-glucuronidase and beta-N-acetyl-D-hexosaminidase. The relative contributions of hyaluronidase and the two exoglycosidases to the physiological catabolism of hyaluronan are not yet known but consideration of the kinetic properties of the three enzymes clearly indicates that hyaluronidase is best suited for the initial attack on the polysaccharide, inasmuch as its Km for hyaluronan is 1000- to 10,000-fold lower than that estimated for beta-D-glucuronidase. Recent investigations in the authors' laboratories have been focused on the catabolism of hyaluronan and other complex carbohydrates in liver, since the sinusoidal endothelial cells in this organ are the main sites for degradation of circulating hyaluronan. Assay of ten lysosomal hydrolases in isolated rat liver cells showed considerably higher activities in Kupffer cells and endothelial cells than in hepatocytes for nine of the enzymes, including beta-D-glucuronidase and beta-N-acetyl-D-hexosaminidase. The activity of N-acetylglucosamine-6-phosphate deacetylase, a key enzyme in the metabolism of the N-acetylglucosamine released by the lysosomal degradation of hyaluronan and other complex carbohydrates, has also been determined. High deacetylase activities were observed in both Kupffer cells and endothelial cells but, surprisingly, virtually no activity was detected in hepatocytes. This finding implies that N-acetylglucosamine cannot be degraded in hepatocytes and must be largely reutilized in the synthesis of new macromolecules. Further studies of the enzymes involved in hyaluronan degradation and N-acetylglucosamine utilization in the liver are under way.

Dermatan is a better substrate for 4-O-sulfation than chondroitin: implications in the generation of 4-O-sulfated, L-iduronate-rich galactosaminoglycans

The biosynthesis of dermatan sulfate is a complex process that involves, inter alia, formation of L-iduronic acid residues by C5-epimerization of D-glucuronic acid residues already incorporated into the growing polymer. It has been shown previously that this reaction is promoted by the presence of the sulfate donor 3'-phosphoadenosine-5'-phosphosulfate. In the present investigation, the role of sulfation in the biosynthesis of L-iduronic acid-rich galactosaminoglycans was examined more closely by a study of the substrate specificities and kinetic properties of the sulfotransferases involved in dermatan sulfate biosynthesis. Comparison of the acceptor reactivities of oligosaccharides from chondroitin and dermatan, in an in vitro system containing microsomes from cultured human skin fibroblasts and 3'-phosphoadenosine-5'-phosphosulfate, showed that Km values for the dermatan fragments were substantially lower than those for their chondroitin counterparts. Calculation of Vmax values likewise showed that dermatan was the better substrate. Whereas dermatan incorporated [35S]sulfate exclusively at the C4 position of N-acetylgalactosamine residues, approximately equal amounts of radioactivity were found at the C4 and C6 positions in the labelled chondroitin. Under standard assay conditions, the 4-O-sulfation of dermatan proceeded about six times faster than the 4-O-sulfation of chondroitin. On the basis of these results, we propose that L-iduronic acids, formed in the course of the biosynthesis of dermatan sulfates, enhance sulfation of their adjacent N-acetylgalactosamine residues, and will thereby be locked in the L-ido configuration.

Biosynthesis of heparin/heparan sulfate: kinetic studies of the glucuronyl C5-epimerase with N-sulfated derivatives of the Escherichia coli K5 capsular polysaccharide as substrates

The D-glucuronyl C5-epimerase involved in the biosynthesis of heparin and heparan sulfate was investigated with focus on its substrate specificity, its kinetic properties, and a comparison of epimerase preparations from the Furth mastocytoma and bovine liver, which synthesize heparin and heparan sulfate, respectively. New substrates for the epimerase were prepared from the capsular polysaccharide of Escherichia coli K5, which had been labeled at C5 of its D-glucuronic and N-acetyl-D-glucosamine moieties by growing the bacteria in the presence of D-[5-(3)H]glucose. Following complete or partial ( approximately 50%) N-deacetylation of the polysaccharide by hydrazinolysis, the free amino groups were sulfated by treatment with trimethylamine.SO(3)complex, which yielded products that were recognized as substrates by the epimerase and released tritium from C5 of the D-glucuronyl residues upon incubation with the enzyme. Comparison of the kinetic properties of the two substrates showed that the fully N-sulfated derivative was the best substrate in terms of its K(m)value, which was significantly lower than that of its partially N-acetylated counterpart. The V(max)values for the E.coli polysaccharide derivatives were essentially the same but were both lower than that of the O-desulfated [(3)H]heparin used in our previous studies. Surprisingly, the apparent K(m)values for all three substrates increased with increasing enzyme concentration. The reason for this phenomenon is not entirely clear at present. Partially purified C5-epimerase preparations from the Furth mastocytoma and bovine liver, respectively, behaved similarly in terms of their reactivity towards the various substrates, but the variation in apparent K(m)values with enzyme concentration precluded a detailed comparison of their kinetic properties.

Analysis of the Morgan-Elson chromogens by high-performance liquid chromatography

The Morgan-Elson method for quantitative N-acetylhexosamine analysis is a two-step procedure comprising alkali treatment of the sugar and subsequent condensation of the resulting chromogens with p-dimethylaminobenzaldehyde (Ehrlich's reagent) to yield a colored product. In the present investigation, the products formed in the first step of the procedure were analyzed by high-performance liquid chromatography (HPLC) on a reversed-phase (C18) column, which was eluted with a water-methanol gradient; the absorbance of the effluent was monitored at 229 nm. The profile generated from alkali-treated N-acetylglucosamine exhibited two major peaks, in a ratio of approximately 2.5:1, which accounted for 94% of the total peak area. A third peak, accounting for 3% of the peak area, was eluted in an intermediate position, and several smaller peaks were also observed. The three predominant components, isolated by preparative HPLC, all gave a purple color on addition of Ehrlich's reagent, indicating that they were Morgan-Elson chromogens. The HPLC profile of alkali-treated N-acetylmannosamine was identical to that of the products generated from N-actylglucosamine, as was expected because of the elimination of the asymmetry at C-2 during formation of the chromogens. N-Acetylgalactosamine yielded two major peaks, which were eluted in the same positions as the two major products formed from N-acetylglucosamine, but the intermediate peak seen in the N-acetylglucosamine pattern was absent. The HPLC procedure allowed detection of as little as approximately 25 ng of N-acetylglucosamine and may therefore be of value as an alternative to the complete Morgan-Elson procedure when only small amounts of sample are available for quantitative analysis.

Alkylglycosides as artificial primers for glycogen biosynthesis

Glycogenin is a 37 kDa self-glycosylating protein which has been demonstrated to be the initiating enzyme and primer for glycogen biosynthesis in liver, skeletal muscle and other tissues. We have recently shown that glycogenin will use alkylglucosides and alkylmaltosides as artificial acceptors in glycosyl transfer from UDP-glucose and UDP-xylose in vitro and have suggested that such substrates might be used to promote the synthesis of glycogen in vitro and in vivo. We now report that alkylglycosides can also serve as acceptors for transfer of glucose by glycogen synthase, yielding alkylmaltooligosaccharide products which may potentially be elongated to glycogen. alpha-Glucosides were better substrates than the corresponding beta-glucosides, and alkylmaltosides were preferred over alkylglucosides. The hydrophobicity of the substrates markedly affected their acceptor activity, less hydrophobic substrates being more active. This is in contrast to the behavior of glycogenin, which acted preferentially upon the more hydrophobic substrates tested. Aromatic glycosides were also substrates for glycogen synthase, e.g., naphthyl-alpha-D- and beta-D-glucoside. The substrates were active in vitro both with partially purified rabbit muscle glycogen synthase and in incubations with crude muscle and liver homogenates from rat. In vivo experiments with mice further proved that intraperitoneal administration of alkylglucosides and alkylmaltosides increased the uptake of 14C-glucose in liver. The elevated uptake was due to an increase in both hydrophobic products, isolated by adsorption to Sep-Pak C18 columns, and more hydrophilic material that co-fractionated with glycogen upon treatment of the tissue with alkali and precipitation with ethanol. These results demonstrate the ability of alkylglycosides to serve as artificial primers for glycogen biosynthesis in vivo.

N-acetylglucosamine kinase and N-acetylglucosamine 6-phosphate deacetylase in normal human erythrocytes and Plasmodium falciparum

The major pathways of glucose metabolism in the malaria parasite, Plasmodium falciparum, have now been elucidated, and the structures and properties of parasite-specific enzymes are presently being investigated. Little is known, however, about the enzymes catalysing monosaccharide interconversions in the parasite. In the present investigation we have examined the pathway of N-acetylglucosamine catabolism which, in higher organisms, involves the following reaction sequence: N-acetylglucosamine -->N-acetylglucosamine 6-phosphate-->glucosamine 6-phosphate-->fructose 6-phosphate. Assay of the specific kinase (E.C. 2.7.1.59) catalysing the phosphorylation of the sugar showed that the enzyme is present in Plasmodium extracts as well as in normal human erythrocytes; specific activities of 7.2 and 5.3 nmol/h/mg protein were measured for the parasite and erythrocyte extracts, respectively, N-Acetylglucosamine 6-phosphate deacetylase (E.C. 3.5.1.25), catalysing the second reaction, was also detected in both normal and Plasmodium-infected erythrocytes. At 75% parasitaemia, the deacetylase activity was close to 3 times higher than that of normal control cells. The erythrocyte deacetylase was purified approximately 16,000-fold by chromatography on DE52 cellulose, chromatofocusing, and size exclusion chromatography. Attempts to purify the parasite enzyme by the same procedures were unsuccessful due to loss of activity. A partially purified erythrocyte deacetylase preparation (eluted from DE52 cellulose) had a pH optimum of 7.5, a pI of 6.0, as indicated by chromatofocusing, and a K(m) of 29 microM. In conjunction with previous investigations, the present study indicated that all three enzymes required for N-acetylglucosamine utilization are present in Plasmodium parasites as well as in normal erythrocytes.

Glucosamine 6-phosphate deaminase in Plasmodium falciparum

The pathways of glucose utilization for energy production in the malaria parasite, Plasmodium falciparum, have been studied extensively. Little is known, however, about the reactions by which glucose is converted into complex carbohydrates in the parasite, and knowledge of the catabolism of these substances is likewise scanty. The present investigation was undertaken to determine whether the parasites possess a key enzyme of glucosamine catabolism, i.e. glucosamine 6-phosphate deaminase (EC 5.3.1.40), which catalyses the conversion of the sugar phosphate to fructose 6-phosphate and ammonia. Lysates of Plasmodium-infected erythrocytes had substantially higher deaminase activity than control samples from normal erythrocytes, and an even higher specific activity was observed in extracts of isolated parasites, amounting to 20-40 times that of uninfected cells. Anion exchange chromatography indicated that the parasite deaminase eluted in a retarded position when compared to the elution profile of the erythrocyte enzyme. The charge difference suggested by these findings was established more directly by chromatofocusing, which indicated pI values of 6.85 and 8.55 for the parasite and erythrocyte deaminases, respectively. Other differences were also observed, notably a greater thermolability on the part of the parasite enzyme. These results indicated that the parasites synthesize a specific deaminase that is distinct from the normal erythrocyte enzyme. Studies on synchronized parasite cultures further indicated that the parasite deaminase is developmentally regulated, because a dramatic increase in activity levels occurred during the later stages of parasite development.

Glucosamine 6-phosphate deaminase in normal human erythrocytes

In the course of an investigation of hexosamine catabolism in the human malaria parasite, Plasmodium falciparum, it became apparent that a basic understanding of the relevant enzymatic reactions in the host erythrocyte is lacking. To acquire the necessary basic knowledge, we have determined the activities of several enzymes involved in hexosamine metabolism in normal human red blood cells. In the present communication we report the results of studies of glucosamine 6-phosphate deaminase (GlcN6-P) using a newly developed sensitive radiometric assay. The mean specific activity in extracts of fresh erythrocytes assayed within 4h of collection was 14.7 nmol/h/mg protein, whereas preparations from older erythrocytes that had been stored at 4 degrees C for up to 4 weeks had a mean specific activity of 6.2 nmol/h/mg. Characterization of the deaminase by chromatofocusing gave a pI of 8.55. The enzyme was optimally active at pH 9.0 and had a Km of 41 microM. The metal chelators EDTA and EGTA were non-inhibitory; however, inhibition was observed in the presence of metal ions, especially Cu2+, Ni2+ and Zn2+. In addition, the deaminase was also inhibited by several sugar phosphates including the reaction product, fructose 6-phosphate.

Inhibition of glycogenin-catalyzed glucosyl and xylosyl transfer by cytidine 5'-diphosphate and related compounds

The self-glucosylation of beef kidney glycogenin was inhibited by the following pyrimidine nucleotides and nucleotide sugars, listed in order of decreasing effectiveness: CDP-glucose, CDP, UDP-xylose, UDP-N-acetylglucosamine, UDP-galactose, UDP, CTP, CDP-choline, UDP-glucuronic acid, beta-S-UDP-glucose, and CMP. In contrast, the purine nucleotide sugars, ADP-glucose and GDP-glucose, were essentially ineffective, as was the pyrimidine nucleoside, cytidine. UDP-Xylose may be utilized by glycogenin as an alternative sugar donor instead of UDP-glucose (Rodén, L., Ananth, S., Campbell, P., Manzella, S., and Meezan, E. (1994) J. Biol. Chem. 269, 11509-11513) and therefore presumably inhibited the glucosyl transfer reaction by being a competitive substrate. Like glucosyl transfer, xylosyl incorporation into glycogenin was also inhibited effectively by CDP. On the other hand, UDP-xylose:proteoglycan core protein xylosyltransferase (EC 2.4.2.26) was not affected by CDP, nor was it inhibited by UDP-glucose. Addition of CDP or UDP-glucose to reaction mixtures containing both enzymes therefore made it possible to assay xylosyltransferase EC 2.4.2.26 reliably without the extensive product characterization that is otherwise necessary. The CDP effect on glycogenin further allowed the development of an improved procedure for the purification of this enzyme, in which specific elution of an affinity matrix (UDP-glucuronic acid-agarose) was carried out with CDP as the eluant.

Tritium labelling of amino sugars at C-2 by alkaline epimerization in tritiated water

N-Acetyl-D-[2-3H]glucosamine was synthesized from N-acetyl-D-mannosamine by alkaline 2-epimerization in pyridine containing 3H2O and nickelous acetate. The reaction involves reversible formation of an enol intermediate and therefore also resulted in incorporation of tritium into N-acetylmannosamine. After completed reaction, the two N-acetylhexosamines were separated from other radioactive products and Morgan-Elson chromogens by chromatography on a column of Sephadex G-10, which was eluted with 10% ethanol, and were then separated from each other by chromatography on Sephadex G-15 in 0.27 M sodium borate (pH 7.8). The location of the incorporated tritium was established by treatment of the N-acetylhexosamines with borate under the conditions of the Morgan-Elson reaction, which converts the sugars to Kuhn's chromogen I with concomitant loss of the C-2 hydrogen. As expected, this treatment resulted in the formation of 3H2O, indicating that the tritium was located at C-2. [2-3H]Glucosamine was prepared by acid hydrolysis of the labelled N-acetylglucosamine and was converted to [2-3H]glucosamine 6-phosphate by incubation with hexokinase and ATP. The sugar phosphate was used as a substrate for glucosamine 6-phosphate deaminase (isomerase, EC 5.3.1.10) in a simple 3H2O release assay.

Dodecyl-beta-D-maltoside as a substrate for glucosyl and xylosyl transfer by glycogenin

Glycogenin is the core protein of glycogen proteoglycan and is, at the same time, a self-glucosylating enzyme which catalyses early glucosyl transfer steps in the biosynthesis of glycogen. In the course of this process, glycogenin is glucosylated progressively until an oligosaccharide containing 8-11 glucose residues has been formed. Although glycogenin, under physiological conditions, is both enzyme and acceptor in the glucosyl transfer reactions, it is also capable of utilizing p-nitrophenyl-linked malto-oligosaccharides as exogenous acceptors. In view of the potential usefulness of exogenous acceptors in the study of the mechanism of the glycogenin reaction, we have expanded the search for such compounds and report here that several alkyl glucosides and alkyl maltosides may serve as acceptors in glucosyl transfer by beef kidney glycogenin. Dodecyl-beta-D-maltoside (Km approximately 100 microM) was the most effective acceptor among the compounds tested and yielded 30 times as much product as p-nitrophenyl-alpha-maltoside. Substantial product formation was also observed with tetradecyl-beta-D-maltoside and octyl-beta-D-maltoside (39 and 22%, respectively, of the value measured for dodecyl-beta-D-maltoside). It was further demonstrated that dodecyl-beta-D-maltoside served as an acceptor in the transfer of xylose from UDP-xylose, indicating that the exogenous substrate behaved similarly to glycogenin itself in this regard. Dodecyl-beta-D-maltoside has already proven useful in the development of a simple glycogenin assay, and it is further suggested that this and related compounds may be active in vivo and in cell culture as artificial initiators of glycogen synthesis.

Biosynthesis of heparin/heparan sulfate. Purification of the D-glucuronyl C-5 epimerase from bovine liver

The D-glucuronyl C-5 epimerase involved in the biosynthesis of heparin/heparan sulfate was purified from the high speed supernatant fraction of a homogenate of bovine liver by chromatography on immobilized O-desulfated heparin, red Sepharose, phenyl Sepharose, and concanavalin A-Sepharose. After close to 1 million-fold purification, in 10-15% yield, the product gave a single band on SDS-polyacrylamide gel electrophoresis with silver staining and had a mobility corresponding to an M(r) of approximately 52,000. Since the epimerase assay used in the course of purification was based on release of tritium, as [3H]H2O, from a [5-3H]uronyl-labeled substrate, it was important to establish that the purified enzyme did indeed catalyze the actual conversion of D-glucuronyl to L-iduronyl residues. Upon incubation of the purified enzyme with 3H-labeled heparosan N-sulfate, prepared by metabolic labeling (with D-[1-3H]glucose) of a capsular polysaccharide from Escherichia coli K5 and subsequent chemical partial N-deacetylation and N-sulfation, approximately 30% of the D-glucuronyl residues located between two N-sulfated glucosamine units were converted to L-iduronyl units.

Xylosyl transfer to an endogenous renal acceptor. Purification of the transferase and the acceptor and their identification as glycogenin

A xylosyltransferase in rat kidney, tentatively identified as glycogenin (Meezan, E., Ananth, S., Manzella, S., Campbell, P., Siegal, S., Pillion, D. J., and Rodén, L. (1994) J. Biol. Chem. 269, 11503-11508), was purified by a procedure in which affinity chromatography on UDP-glucuronic acid-agarose was a particularly useful step. The purified material was nearly homogeneous, as shown by SDS-polyacrylamide gel electrophoresis and silver staining, and had an electrophoretic mobility corresponding to a M(r) of 32,000. The purified enzyme possessed both glucosyl- and xylosyltransferase activity, and incubation with UDP-[3H]xylose or UDP-[3H]glucose yielded a single macromolecular product, which had the same electrophoretic mobility as the major silver-stained component. These results indicate that the kidney transferase was indeed glycogenin and that it was functionally analogous to the larger glycogenin species previously isolated from rabbit muscle. Further examination of the properties of the rat kidney enzyme showed, i.a., that it was inhibited strongly by cytidine 5'-diphosphate. This effect was used to advantage in an alternative purification procedure, which was applied to beef kidney and involved adsorption of the enzyme to UDP-glucuronic acid-agarose and subsequent elution with cytidine 5'-diphosphate. In contrast to glycogenin, glycogen synthase did not catalyze transfer from UDP-xylose, and it is suggested that the incorporation of xylose into glycogen observed by other investigators was due to glycogenin-catalyzed xylosyl transfer and subsequent chain elongation by glycogen synthase.

Xylosyl transfer to an endogenous renal acceptor. Characteristics of the reaction and properties of the product

In the course of a study of UDP-xylose:proteoglycan core protein xylosyltransferase (EC 2.4.2.26), another xylosyltransferase was discovered in the soluble fraction of a rat kidney homogenate. The latter enzyme catalyzed [3H]xylosyl transfer from UDP-[3H]xylose to an endogenous acceptor and yielded a product in which the xylose was bound by an alkali-stable linkage. It was therefore concluded that the acceptor was not the core protein of one of the proteoglycans containing a xylose-->serine linkage, since this linkage is cleaved by alkali. The [3H]xylose-labeled product emerged with the void volume when chromatographed on Sephadex G-50, it was precipitated by trichloroacetic acid, and it had a mobility on sodium dodecyl sulfate-polyacrylamide gel electrophoresis corresponding to a molecular mass of about 32,000 Da. Digestion with trypsin or alpha-amylase degraded the labeled product to small fragments, as determined by gel chromatography, suggesting that it was a glycoprotein related to glycogen. A product of similar characteristics was formed when UDP-[3H]glucose was substituted for UDP-[3H]xylose as the glycosyl donor, and the two nucleotide sugars were mutually competitive in the respective transfer reactions, indicating that they were substrates for the same enzyme. On the basis of these findings, it was tentatively concluded that the xylosyltransferase and its acceptor were the renal form of glycogenin.

A biphasic radiometric assay of glycogenin using the hydrophobic acceptor n-dodecyl-beta-D-maltoside

Glycogenin is a self-glycosylating protein that catalyzes early glucosyl transfer steps in the biosynthesis of glycogen. In currently used assays of glycogenin activity, the enzyme is incubated with radioactive UDP-glucose, and the labeled reaction product is then isolated by precipitation with trichloroacetic acid. A new assay is reported here which is based on the observation that glycogenin is not only self-glycosylating but may also use exogenous alkyl maltosides as substrates. After incubation of the enzyme with n-dodecyl-beta-D-maltoside and UDP-[3H]glucose, the radioactivity in the resultant n-dodecyl-beta-D-[3H]maltotrioside is determined by any one of the following three procedures, which all rely on the hydrophobic properties conferred on the reaction product by the alkyl aglycone: (i) adsorption of the product to a Sep-Pak C18 cartridge and elution with 70% ethanol; (ii) biphasic liquid scintillation counting in ScintiLene/25% isoamyl alcohol, without isolation of the product, and (iii) precipitation with trichloroacetic acid in the presence of carrier protein. The Sep-Pak C18 procedure has the advantage that it allows essentially quantitative isolation of the reaction product, while, under the conditions chosen, only about 50% of the product is precipitated by trichloroacetic acid. For most applications, however, biphasic liquid scintillation counting is the method of choice, since close to 90% of the labeled product is extracted into the organic phase and can be counted directly without interference from the labeled nucleotide sugar which remains in the aqueous phase.(ABSTRACT TRUNCATED AT 250 WORDS)

Separation of sugars by ion-exclusion chromatography on a cation-exchange resin

A method for the separation of N-acetylmannosamine and N-acetylglucosamine is described, which consists of chromatography of the two sugars on a column (30 x 1 cm) of the cation-exchange resin, Dowex 50W-X2, in borate buffer at pH 7.8. N-Acetylmannosamine is eluted near the void volume, while N-acetylglucosamine emerges in a more retarded position. It is postulated that the separation occurs as a result of the combined effects of ion exclusion and gel permeation. Thus, in borate solution, N-acetylmannosamine presumably exists largely as a negatively charged complex and is therefore excluded from the sulfonated polystyrene matrix, while N-acetylglucosamine occurs mainly as the free sugar in the equilibrium mixture and, being a neutral compound, has free access to the porous resin. The proposed mechanism for the separation was supported by the finding that glucose and glucose 6-phosphate could also be separated on a column of the same resin, with water as the eluent.

Separation of N-acetylglucosamine and N-acetylmannosamine by chromatography on Sephadex in borate buffer

Several procedures have been used previously for the separation of N-acetylglucosamine and N-acetylmannosamine, which are based on the difference in strength of the borate complexes of the two N-acetylhexosamines and include paper chromatography on borate-treated paper, paper electrophoresis in borate buffer, and anion-exchange chromatography of the borate complexes. In the present study, we have observed that the two sugars, despite their identical size in noncomplexed form, may also be separated by gel chromatography in borate buffer. Nearly complete resolution was obtained by chromatography on a column (1.5 x 117 cm) of Sephadex G-15, which was eluted at room temperature with 0.27 M sodium borate, pH 7.8 (prepared from H3BO3 by addition of NaOH), at a flow rate of 10 ml/h. This procedure complements existing methods for the separation of N-acetylmannosamine and N-acetylglucosamine and has the advantage that it can be carried out on a relatively large preparative scale.

Glucuronosyl transfer to galactose residues in the biosynthesis of HNK-1 antigens and xylose-containing glycosaminoglycans: one or two transferases?

An early step in the assembly of the xylose----serine-linked proteoglycans is the transfer of glucuronic acid to the C-3 position of a galactose residue in the carbohydrate-protein linkage region. Since a similar reaction occurs in the biosynthesis of NHK-1 antigens, the question arose whether these processes are catalyzed by the same enzyme. In the present study, the proteoglycan-related glucuronosyltransferase activity in embryonic chick brain was found to be firmly membrane-associated, while the majority of the activity towards N-acetyllactosamine - a model substrate for HNK-1 antigen biosynthesis - was readily solubilized. No activity towards N-acetyllactosamine was found in embryonic chick cartilage, which is a rich source of the proteoglycan-related enzyme. Together with the results of mixed substrate experiments, these findings strongly indicate the existence of two separate glucuronosyltransferases catalyzing transfer to galactose residues.

Biosynthesis of heparin. Enzymatic sulfation of pentasaccharides

Heparin-derived pentasaccharides with the general structures GlcN-GlcA/IdoA-GlcN-GlcA/IdoA-GlcN (where GlcA represents D-glucuronic acid and IdoA represents L-iduronic acid) and GlcNSO3-GlcA/IdoA-GlcNSO3-GlcA/IdoA- GlcNSO3 (where -NSO3 represents an N-sulfate group) were tested as exogenous sulfate acceptors in incubations with adenosine 3'-phosphate 5'-[35S]phosphosulfate and microsomal enzymes from a heparin-producing mouse mastocytoma. No transfer occurred to the N-unsubstituted pentasaccharide containing only L-iduronic acid, but the other three isomers incorporated various amounts of 35S, which was totally present in N-sulfate groups. After complete chemical N-sulfation, all four pentasaccharides served as acceptors in O-sulfotransferase reactions and incorporated from 20 to greater than 200 times as much radioactivity as did the nonsulfated parent compounds. The C-6 position of the internal glucosamine unit was labeled preferentially, irrespective of the structures of the adjacent hexuronic acid units. Significant 2-O-35S-sulfation of IdoA units occurred in both -IdoA-Glc-NSO3-GlcA- and -GlcA-GlcNSO3-IdoA- sequences, whereas no significant sulfation of GlcA residues was detected. The pentasaccharide GlcNSO3-GlcA-Glc-NSO3-GlcA-GlcNSO3 thus can be used as a selective substrate in assays for glucosaminyl-6-O-sulfotransferase activity. The antithrombin-binding region, essential for the blood anticoagulant activity of heparin, has been identified as a pentasaccharide sequence with the predominant structure GlcNR(6-OSO3)-GlcA-GlcNSO3(3,6-di-OSO3)-++ +IdoA(2-OSO3)-GlcNSO3(6-OSO3) (where R represents either a sulfate or an acetyl group and -OSO3 represents an O-sulfate/ester sulfate group, with locations of O-sulfate groups indicated in parentheses) (Lindahl U., Thunberg, L., Bäckström, G., Riesenfeld, J., Nordling, K., and Björk, I. (1984) J. Biol. Chem. 259, 12368-12376). The products of [35S]sulfate transfer to the pentasaccharide GlcNSO3-GlcA-GlcNSO3-IdoA-GlcNSO3 contained molecules with high affinity for antithrombin, corresponding to 0.3-0.5% of the total label. Structural analysis suggested the occurrence of O-[35S]sulfate groups at both C-6 of the nonreducing terminal glucosamine unit and C-3 of the internal glucosamine unit. No products with high affinity for antithrombin were formed from the pentasaccharides that had a different monosaccharide sequence than the binding region; and moreover, these oligosaccharides appeared unable to incorporate glucosaminyl 3-O-sulfate groups. These findings point to the importance of the uronic acid sequence in the generation of the antithrombin-binding region of heparin.

Nuclear magnetic resonance and molecular modeling studies on O-beta-D-galactopyranosyl-(1----4)-O-beta-D-xylopyranosyl-(1----0)-L-se rine, a carbohydrate-protein linkage region fragment from connective tissue proteoglycans

The solution conformation of O-beta-D-galactopyranosyl-(1----4)-O-beta-D-xylopyranosyl-(1----0)-L-ser ine (GXS), a carbohydrate-protein linkage region fragment from connective tissue proteoglycans, was investigated by two-dimensional NMR spectroscopy and molecular modeling calculations. Specifically, the 1H and 13C resonances were assigned by 2D-COSY and by 1H-13C heteronuclear correlation spectroscopy methods. 2D-NOESY was used to generate distance constraints between the galactose and xylose and between the xylose and serine residues. The 1H vicinal coupling constants for the sugars and the serine were also determined. A general molecular modeling methodology suitable for complex carbohydrates was developed. This methodology employed molecular dynamics and energy minimization procedures together with the application of inter-residue spatial constraints across the linkages derived from 2D-NOESY. The first step in this methodology is the generation of a wide variety of starting conformations that span the (phi, psi) space for each linkage. In the present study, nine such conformations were constructed for each linkage using the torsion angles phi and psi corresponding to the gauche+, gauche-, and trans configurations across each of the two bonds constituting the linkage. These conformations were subjected to a combined molecular dynamics/energy minimization refinement using the NOESY derived constraints as pseudoenergy functions. Families of conformations for the whole molecule were then constructed from the structures derived for each linkage. Characterization of GXS using this methodology identified a single family of conformations that are consistent with the solution phase NMR data on this molecule.

Quantitative analysis of N-sulfated, N-acetylated, and unsubstituted glucosamine amino groups in heparin and related polysaccharides

A colorimetric procedure for quantitative determination of free and substituted glucosamine amino groups in heparin and related polysaccharides has been developed. The total content of hexosamine amino groups is determined by a modification of the method of Tsuji et al. (1969, Chem. Pharm. Bull. 17, 1505-1510); this method involves acid hydrolysis under conditions effecting complete removal of N-acetyl and N-sulfate groups, deaminative cleavage with nitrous acid, and colorimetric analysis of the resultant anhydromannose residues by reaction with 3-methyl-2-benzothiazolinone hydrazone (MBTH). N-sulfated glucosamine residues are cleaved selectively by treatment with nitrous acid at pH approximately 1.5 (J. E. Shively, and H.E. Conrad, 1976, Biochemistry 15, 3932-3942) and quantitated by the MBTH reaction. Under carefully controlled conditions, deamination at pH approximately 1.5 is highly specific for N-sulfated glucosamine residues, but an excess of reagent causes some cleavage of residues with unsubstituted amino groups as well. Deaminative cleavage at pH approximately 4.5 results in preferential degradation of unsubstituted glucosamine residues, but some cleavage (5-8%) of N-sulfated residues also occurs. However, analysis of the content of N-sulfated residues by the specific pH 1.5 procedure allows appropriate corrections to be made. From the value for total hexosamine content and the sum of N-sulfated and unsubstituted residues, the content of N-acetylated residues is calculated by difference. The modified deamination procedures, in combination with product analysis by the MBTH reaction, have been applied to several problems commonly encountered in the analysis and characterization of heparin.

A genetic defect in the biosynthesis of dermatan sulfate proteoglycan: galactosyltransferase I deficiency in fibroblasts from a patient with a progeroid syndrome

A small proteoglycan that contains only a single dermatan sulfate chain is the main proteoglycan synthesized by skin fibroblasts. Fibroblasts from a patient with progeroidal appearance and symptoms of the Ehlers-Danlos syndrome have a reduced ability of converting the core protein of this proteoglycan into a mature glycosaminoglycan chain-bearing species. This abnormality is the consequence of a deficiency in galactosyltransferase I (xylosylprotein 4-beta-galactosyltransferase; EC 2.4.1.133), which catalyzes the second glycosyl transfer reaction in the assembly of the dermatan sulfate chain. The glycosaminoglycan-free core protein secreted by the patient's fibroblasts bears an unsubstituted xylose residue. The mutant enzyme is abnormally thermolabile. Preincubation of fibroblasts at 41 degrees C leads to a further reduction in the production of mature proteoglycan and affects the capacity for glycosaminoglycan synthesis on p-nitrophenyl beta-D-xyloside more strongly in the mutant than in control cells.

N-acetylglucosamine-6-phosphate deacetylase in hepatocytes, Kupffer cells and sinusoidal endothelial cells from rat liver

The activity of N-acetylglucosamine-6-phosphate deacetylase, a key enzyme in the pathway of N-acetylglucosamine catabolism, was measured in hepatocytes, Kupffer cells and sinusoidal endothelial cells from rat liver and cultured human skin fibroblasts. Kupffer cells and endothelial cells had similar high levels of deacetylase activity that were more than twice the level observed in fibroblasts. In contrast, hepatocytes had extremely low activity (several hundredfold less than Kupffer cells and endothelial cells). A major implication of deacetylase deficiency in hepatocytes is that N-acetylglucosamine generated as a result of the catabolism of complex carbohydrates in these cells cannot enter glycolysis and must be largely reused for the synthesis of plasma glycoproteins and other N-acetylglucosamine-containing macromolecules.

Synthesis of proteoglycans in rat mucosal keratinocytes

The synthesis of hyaluronic acid and proteoglycans by rat mucosal keratinocytes of an established cell line (CCL-10) has been investigated. Proliferating cultures at or near confluency were grown in the presence of [35S] sulfate or D-[1-3H] glucosamine for 24 h, and the glycosaminoglycan composition of cells and medium was determined. Characterization of the 35S-labelled glycosaminoglycans showed that heparan sulfate was the major component (approximately 90%) and that small amounts (approximately 10%) of galactosaminoglycans had also been synthesized. Analysis of cultures labelled with D-[1-3H] glucosamine demonstrated that hyaluronic acid was also present, most prominently in the medium where approximately one third of the radioactivity in the glycosaminoglycan pool was found in the hyaluronic acid fraction. [35S]-labelled proteoglycans extracted from the cell layer in the presence of protease inhibitors showed substantial heterogeneity upon chromatography on Sepharose CL-6B. In contrast, the proteoglycans in the medium gave a major peak which was eluted at a Kav of 0.28. Gel chromatography of the glycosaminoglycan chains in the latter, isolated after proteolytic digestion, indicated a molecular weight of 17,000.

Identification of oversulphated galactosaminoglycans in intestinal-mucosal mast cells of rats infected with the nematode worm Nippostrongylus brasiliensis

The oversulphated galactosaminoglycans synthesized by rat mucosal mast cells were isolated from the small intestine of animals infected with the nematode Nippostrongylus brasiliensis, which causes proliferation of these cells. The 35S-labelled polysaccharides were degraded by digestion with chondroitinase ABC, and the structures of the disaccharide products were determined by cleavage with mercuric acetate followed by electrophoretic characterization of the resultant sulphated monosaccharides. It was concluded that about half of the disulphated disaccharide units in the polysaccharide consisted of chondroitin sulphate E-type structures [GlcA-GalNAc(4,6-di-OSO3)], in which both sulphate groups were located on the N-acetylgalactosamine unit. The remainder consisted of isomeric structures with one sulphate group on the N-acetylgalactosamine residue and one on the hexuronic acid unit and presumably represented the dermatan sulphate-type sequence [IdoA(2-OSO3)-GalNAc(4-OSO3)].

Assay and properties of N-acetylglucosamine-6-phosphate deacetylase from rat liver

A single-vial assay has been developed for N-acetylglucosamine-6-phosphate deacetylase, in which [3H]acetate released from 3H-acetyl-labeled substrate is measured in a biphasic liquid scintillation counting system after acidification of the reaction mixture. The deacetylase was partially purified from rat liver, and some of its properties were determined. Chromatography on a calibrated Sepharose CL-6B column indicated a molecular weight of 345,000. The Km for the substrate at pH 8.0 was 0.3 mM. Glucosamine 6-phosphate and glucose 6-phosphate inhibited the enzyme, whereas N-acetylgalactosamine, N-acetylglucosamine, N-acetylglucosamine 1-phosphate, and glucosamine 1-phosphate were without effect. The effects of several divalent cations were also examined. Under the conditions tested, Ca2+, Mg2+, and Ba2+ had essentially no effect, whereas Mn2+, Ni2+, and Cu2+ were inhibitory and Co2+ stimulated activity at low concentrations but inhibited above 5 mM. An increase in the ionic strength of the reaction mixture to 0.3 M decreased the activity by 40%.

Inhibition of chondroitin and heparan sulfate biosynthesis in Chinese hamster ovary cell mutants defective in galactosyltransferase I

We have isolated five Chinese hamster ovary cell mutants defective in galactosyltransferase I (UDP-D-galactose:xylose beta-1,4-D-galactosyltransferase) and studied the effect of p-nitrophenyl-beta-D-xyloside supplementation on glycosaminoglycan biosynthesis in the mutant cells. Assays of galactosyltransferase I showed that the mutants contained less than 2% of the enzyme activity present in wild-type cells, and enzyme activity was additive in mixtures of mutant and wild-type cell extracts, suggesting that the mutations most likely defined the structural gene encoding the enzyme. Cell hybridization studies showed that the mutations in all five strains were recessive and that the mutants belonged to the same complementation group. The mutants contained wild-type levels of xylosyltransferase (UDP-D-xylose:core protein (serine) beta-D-xylosyltransferase), lactose synthase (UDP-D-galactose:N-acetyl-glucosaminide beta-1,4-D-galactosyltransferase), and lactosylceramide synthase (UDP-D-galactose:glucosylceramide beta-1,4-D-galactosyltransferase). Their sensitivity to lectin-mediated cytotoxicity was virtually identical to that of the wild-type, indicating that there were no gross alterations in glycoprotein or glycolipid compositions. Anion-exchange high performance liquid chromatography of 35S-glycosaminoglycans from one of the galactosyltransferase I-deficient mutants showed a dramatic reduction in both heparan sulfate and chondroitin sulfate, demonstrating that galactosyltransferase I is responsible for the formation of both glycosaminoglycans in intact cells. Surprisingly, the addition of 1 mM-p-nitrophenyl-beta-D-xyloside, a substrate for galactosyltransferase I, restored glycosaminoglycan synthesis in mutant cells. This finding suggested that another galactosyltransferase, possibly lactose synthase, can transfer galactose to xylose in intact cells.

Reaction of unsaturated uronic acid residues with mercuric salts. Cleavage of the hyaluronic acid disaccharide 2-acetamido-2-deoxy-3-O-(beta-D-gluco-4-enepyranosyluronic acid)-D-glucose

Degradation of connective-tissue polysaccharides with bacterial or fungal eliminases and subsequent characterization of the reaction products are now part of standard methodology for the analysis of these compounds. However, the scope of preparative and analytical work based on the use of eliminases has been limited by the lack of procedures for specific removal of the unsaturated uronic acid residues generated in the eliminase reactions. In the present investigation, we have shown that these residues are cleaved by mercuric salts under mild conditions that are not likely to affect other structures in an oligo- or poly-saccharide molecule. Thus the disaccharide generated from hyaluronic acid by digestion with chondroitinase AC or ABC was cleaved into a keto acid and free N-acetylglucosamine within 10 min at room temperature upon exposure to 14 mM-mercuric acetate at pH 5. The reaction of the disaccharide with mercuric salts was used for ready determination of the distribution of radioactivity between the glucuronic acid and N-acetylglucosamine moieties in radioactive hyaluronic acid that had been synthesized by IMR-90 fibroblasts from 3H-labelled monosaccharides. When the precursor was [3H]galactose, over 95% of the incorporated radioactivity was found in the glucuronic acid moiety. In contrast, cells grown in the presence of [3H]glucosamine synthesized a polysaccharide in which almost all of the label was located in the N-acetylglucosamine units. It is apparent from these experiments that the reaction of unsaturated uronic acid residues with mercuric salts provides a new tool with potential for many applications in the study of the structure and metabolism of connective-tissue polysaccharides.

Proteoglycans and hypertension: III: Aorta proteoglycans in Dahl salt-sensitive hypertensive rats

The vascular proteoglycans probably have an important influence on the biomechanical properties of blood vessels and, therefore, may play a role in the development or maintenance of hypertension. In the aorta of the spontaneously hypertensive rat, the authors previously observed an increased content of chondroitin sulfate, an increased incorporation of [35S]sulfate into proteoglycans, and qualitative alterations in the [35S]polysaccharides compared to the normotensive Wistar Kyoto rat. To determine if these differences were related to hypertension or to strain variations, normotensive and hypertensive Dahl S rats were studied. There was a significant elevation (70%) in the aorta content of chondroitin sulfate, whereas the dermatan sulfate and hyaluronic acid contents were similar in the two groups. The in vitro incorporation of [35S]sulfate was increased 2.6-fold in the hypertensive animals. No differences between the two groups were observed with respect to the gel chromatographic profiles of the [35S]proteoglycans or the charge density of the [35S]glycosaminoglycans, as assessed by ion exchange chromatography. It was concluded that the increase in chondroitin sulfate and [35S]sulfate incorporation into proteoglycans occurred as a result of hypertension, regardless of genetic factors.

Proteoglycans and hypertension. II. [35S]sulfate incorporation into aorta proteoglycans of spontaneously hypertensive rats

Spontaneously hypertensive (SH) rats are known to have an increased content of chondroitin sulfate (CS) proteoglycans (PG) in the aorta as compared to normotensive Wistar Kyoto (WKY) rats. In the present study we have compared WKY and SH rat aortas with respect to [35S]sulfate incorporation in vivo and in vitro. The specific activity (cpm/mg aorta) of the total glycosaminoglycan (GAG) pool from SH rat aorta, measured 48 h after intraperitoneal injection of [35S]sulfate, was twice as high as that of WKY aorta GAG. After in vitro incubation of aortas for 4 or 6 h, the specific activity (cpm/mg aorta) of glycosaminoglycans from SH rat was 2.4- to 7.1-fold higher than in controls. Labeled PG were extracted with 4 M guanidine from aortas which had been incubated with [35S]sulfate, and chromatography of the extract on Sepharose CL-6B yielded two incompletely resolved peaks, one emerging with the void volume (peak I) and one in a more retarded position (peak II). Peak I (WKY) contained nearly equal amounts of CS and HS (53 and 46%, respectively) and a small amount of DS (8%). Peak II (WKY) (Kav, 0.34) was divided into two fractions; the fraction of larger molecular weight (II A) contained 43% CS, 35% DS, and 20% HS, whereas the smaller fraction (II B) contained 40% CS, 51% DS, and 5% HS. In each corresponding pool from SH rat aorta, a similar proportion of HS was found, but the DS content was approximately half, and the CS content was correspondingly greater. The estimated molecular weights of the CS/DS chains in peaks I, II A, and II B from WKY aorta were 34,600, 18,800, and 11,600 daltons, respectively, whereas the corresponding values for the SH rat aorta pools were 32,300, 24,700, and 17,000 daltons, respectively. The proportions of 4- and 6-sulfated galactosamine residues as well as the degree of sulfation of the CS/DS PG were similar in the two strains. The HS-PG was larger in the WKY rat aorta and was made up of larger HS chains (Mr 26,600 vs. 16,100); however, the degree of sulfation was apparently similar in the two strains. These results suggest that the rates of PG synthesis and/or degradation and the PG structure are altered in the SH rat aorta.

Proteoglycans and hypertension. I. A biochemical and ultrastructural study of aorta glycosaminoglycans in spontaneously hypertensive rats

The extracellular matrix of blood vessel walls contains elastin, collagen, and proteoglycans, all of which can affect vascular resistance and, hence, blood pressure by virtue of their biomechanical properties. In the present study, we have begun to explore the possibility that proteoglycans may play a role in the pathophysiology of hypertension by analyzing, qualitatively and quantitatively, the polysaccharide components of proteoglycans from aorta of two normotensive rat strains, Wistar Kyoto (WKY) and Wistar rats, and from spontaneously hypertensive (SH) rats of the Okamoto strain. The total concentration of aorta glycosaminoglycans in the SH rat was 33% higher than in the WKY rat, due to a 164% increase in chondroitin 4- and 6-sulfate. The content of dermatan sulfate (DS), hyaluronic acid (HA), and heparan sulfate (HS) was similar in the two strains. The 4-wk-old SH rat also had an increase in chondroitin sulfate (CS) compared to the 4-wk-old WKY rat, without any change in DS, HA, or HS. The Wistar rat had approximately the same concentration of CS und DS in the aorta as the WKY rat, but HS und HA were reduced by 62 and 37%, respectively. The galactosaminoglycans (CS and DS) were heterogeneous on cellulose acetate electrophoresis and exhibited a different pattern for each of the three strains. Undersulfated CS accounted for 15% of the total CS in WKY aorta but was present in only trace amounts in the SH aorta; 2% of the CS from the Wistar aorta was undersulfated. In all three strains, DS was exclusively 4-sulfated, and the CS contained approximately equal amounts of 4- and 6-sulfated galactosamine residues. Ultrastructural studies demonstrated that the HS was localized in the subendothelial matrix and the pericellular region surrounding the medial smooth muscle cells. CS and DS were primarily associated with collagen in the media. In the SH rat aorta the subendothelial matrix was thicker, and there was a relative increase in the CS/DS in the smooth muscle cell pericellular matrix. We suggest that, if similar alterations in CS proteoglycans are present in the resistance vessels, these changes may contribute to the increased peripheral vascular resistance in the hypertensive animal.

Oligosaccharide substrates for heparin sulfamidase

The Sanfilippo A syndrome is characterized by a deficiency in heparin sulfamidase, which removes the N-sulfate groups of heparan sulfate and heparin in the course of normal catabolism of these polysaccharides. [N-35S]Heparin is the most commonly used substrate for the assay of sulfamidase activity but has certain disadvantages which have prompted us to search for alternative substrates. We report here on the use of heparin oligosaccharides for this purpose. The trisaccharide, GlcN-IdoUA-GlcN, and the pentasaccharide, GlcN-GlcUA-GlcN-GlcUA-GlcN, were N-sulfated with [35S]sulfur trioxide-trimethylamine complex; the tetrasaccharide, GlcN-UA-GlcN-UA, and the pentasaccharide, GlcN-IdoUA-GlcN-IdoUA-GlcN, were labeled by reduction with sodium borotritide followed by chemical N-sulfation. When incubated with sonicates of cultured skin fibroblasts from normal individuals, all four oligosaccharides were found to serve as substrates for heparin sulfamidase. Fibroblast sonicates from patients with the Sanfilippo A syndrome had little or no activity toward these substrates. Optimal activity of the enzyme was at pH 4.4-4.5. Comparison of the kinetic parameters showed that heparin had a lower Km than the oligosaccharides, whereas the Vmax values of the latter were higher than for heparin.

Ultrastructural and biochemical characterization of glycosaminoglycans in HNK-1-positive large granular lymphocytes

Natural killer (NK) cells are large granular lymphocytes (LGLs) that contain distinct lysosomal granules. The present study was undertaken to determine if these lysosomes contain glycosaminoglycans (GAGs) similar to those previously described in myeloid cells. Mononuclear cells from human blood were stained with HNK-1 fluoresceinated monoclonal antibody, and the NK cell population reactive with this antibody were isolated with a fluorescence-activated cell sorter (FACS). Specific staining of sulfated macromolecules with the cationic reagent, high iron diamine, was observed in the lysosomal granules of 90% of the HNK-1 positive cells. Staining in the same location was also observed in the unsorted LGLs, presumed to be NK cells, and intense staining of the cell surface was also a prominent feature of these cells. Surface staining was not evident in the majority of the FACS-separated NK cells. Digestion with chondroitinase ABC or treatment with nitrous acid reduced the staining in both locations; after sequential treatment with both chondroitinase and nitrous acid, little or no staining was seen. The presence of chondroitin sulfate (and/or dermatan sulfate) and heparan sulfate was also shown by the finding that incubation of the isolated NK cells with 35S-sulfate yielded cell-associated radiolabeled macromolecules with the characteristics of these two groups of GAGs. Of the labeled GAG pool, 60% was degraded by chondroitinase and 40% was susceptible to nitrous acid treatment. LGLs of a patient with Chediak-Higashi syndrome was also stained, and intracellular sulfate staining was clearly localized to the enlarged granules, supporting the conclusion that the lysosomes are the major site of intracellular accumulation of GAGs in normal NK cells.

Mechanisms of chain initiation in the biosynthesis of connective tissue polysaccharides

Carbohydrate-protein linkages of three types are found in the connective tissue proteoglycans; these linkages involve the following monosaccharide-amino acid pairs: xylose-serine; N-acetylglucosamine-asparagine; and N-acetylgalactosamine-threonine (or serine). The biosynthesis of carbohydrate groups containing linkages of the latter two types presumably occurs by the same pathways that have been well established for many glycoproteins, but details of these processes as they pertain to proteoglycans are not yet known. Initiation of polysaccharide chains linked by the xylose-serine linkage takes place by direct transfer of xylose from UDP-xylose to the hydroxyl groups of specific serine residues in the core proteins of the respective proteoglycans, and the xylosyltransferase catalyzing these reactions has been detected in the rough endoplasmic reticulum of embryonic chick chondrocytes. Although the completed or nascent core proteins are the natural substrates for xylose transfer in the intracellular assembly of proteoglycans, a survey of potential exogenous substrates has shown that small peptides containing alternating serine and glycine residues may also serve as acceptors in this reaction. Nevertheless, larger substrates are preferred, such as chondroitin sulfate proteoglycan, which has been deglycosylated by Smith degradation or HF treatment, or silk fibroin, which contains Ser-Gly pairs. In contrast to the sulfated polysaccharides, which are synthesized by carbohydrate transfer to protein in the endoplasmic reticulum and the Golgi apparatus, hyaluronic acid is formed in the plasma membrane by a different mechanism. The reaction by which chains are initiated is not yet known, but recent work by Prehm suggests that this process occurs either by transfer of the glucuronosyl component of UDP-glucuronic acid to UDP-N-acetylglucosamine or by the converse reaction, i.e., transfer of the N-acetylglucosaminyl unit of UDP-N-acetylglucosamine to UDP-glucuronic acid.

Degradation of chondroitin 4-sulphate by tri-fluoroacetolysis: isolation of oligosaccharides from the carbohydrate-protein linkage region

Oligosaccharides from the linkage-region tetrasaccharide, beta-D-GlcpA-(1----3)-beta-D-Galp-(1----3)-beta-D-Galp-(1----4)-D- Xylp, of chondroitin 4-sulphate were isolated after trifluoroacetolysis. The oligosaccharides were purified by ion-exchange chromatography and paper chromatography and subjected to sugar and methylation analysis and g.l.c.-m.s. The recovery of linkage-region oligosaccharides was approximately 45% after trifluoroacetolysis, calculated according to the D-xylose present in the chondroitin 4-sulphate preparation. The following structures were identified: beta-D-Galp-(1----4)-D-Xylp, beta-D-Galp-(1----3)-D-Galp, beta-D-Galp-(1----3)-beta-D-Galp-(1----4)-D-Xylp, beta-D-GlcpA-(1----3)-beta-D-Galp-(1----3)-beta-D-Galp-(1----4)-D- Xylp.

Silk--a new substrate for UDP-d-xylose:proteoglycan core protein beta-D-xylosyltransferase

The formation of most connective tissue polysaccharides is initiated by transfer of D-xylose from UDP-D-xylose to specific serine residues in the core proteins of the putative proteoglycans. The substrate specificity of the xylosyltransferase catalyzing this reaction has not yet been examined in detail, but it appears that a -Ser-Gly- pair is an essential part of the substrate structure. Since the preparation of the known acceptors (e.g., Smith-degraded or HF-treated cartilage proteoglycan) involves a substantial effort, we have searched for readily available proteins with the -Ser-Gly-sequence, which might serve as alternative substrates. In the present work, it was found that silk fibroin from Bombyx mori, which consists, in large part, of the repeating hexapeptide, Ser-Gly-Ala-Gly-Ala-Gly, is an excellent substrate for the xylosyltransferase from embryonic chick cartilage. Pieces of silk were used directly in the reaction mixtures, and [14C]xylose transferred from UDP-D-[14C]xylose was measured by liquid scintillation spectrometry after rinsing the silk in 1 M NaCl and water. Substantially greater incorporation was observed with preparations of silk or fibroin which had been dissolved in 60% LiSCN and subsequently dialyzed exhaustively or diluted appropriately. Under standard reaction conditions, the Vmax for fibroin was 531 pmol/h/mg enzyme protein, as compared to 223 pmol/h/mg for Smith-degraded proteoglycan. Km values were 182 mg/liter (fibroin) and 143 mg/liter (Smith-degraded proteoglycan). The product of [14C]xylose transfer to silk was alkali labile, and [14C]xylitol was formed when [14C]xylosylsilk was treated with borohydride in alkali. Proteolytic digestion with papain, Pronase, leucine aminopeptidase, and carboxypeptidase A yielded a radioactive product which was identified as [14C]xylosylserine by electrophoresis and chromatography. The identity of the isolated [14C]xylosylserine was further supported by its resistance to treatment with alkali (0.5 M KOH; 100 degrees C; 8 h) and by acid hydrolysis which yielded [14C]xylose. Tryptic and chymotryptic fragments from fibroin were also good xylose acceptors and had Vmax values 60-70% of that observed for the intact protein. Substantial acceptor activity was displayed also by the sericin fraction of silk and by the silk sequence hexapeptide. Ser-Gly-Ala-Gly-Ala-Gly; the latter had a Vmax value close to 20% of that of intact fibroin.

Biosynthesis of heparin. Substrate specificity of heparosan N-sulfate D-glucuronosyl 5-epimerase

The substrate specificity of heparosan N-sulfate D-glucuronosyl 5-epimerase from a mouse mastocytoma was examined to determine the effects of N-acetyl and O-sulfate groups on substrate recognition by the enzyme. [5-3H]Glucuronosyl-labeled heparosan N-sulfate was prepared enzymatically and was modified chemically by partial N-desulfation and N-acetylation. After enzymatic release of tritium, the location of remaining label was determined by deaminative cleavage and analysis of resulting di-, tetra-, and higher oligosaccharides. This analysis indicated that a D-glucuronosyl residue is recognized as a substrate if it is linked at C-1 to an N-acetylated glucosamine residue and at C-4 to an N-sulfated unit. However, the reverse structure, in which the D-glucuronosyl moiety is bound at C-1 to an N-sulfated residue and at C-4 to N-acetylated glucosamine, is not a substrate. Similar studies with O-sulfated heparin intermediates showed that O-sulfate groups either at C-2 of the L-iduronosyl moieties or at C-6 of vicinal D-glucosaminyl moieties prevent 5-epimerization. These findings were confirmed by studies of the reverse reaction, in which tritium was incorporated from 3H2O into partially O-desulfated heparin and the location of incorporated radioactivity was determined. These and more direct experiments corroborated the previous conclusion that the L-iduronosyl moieties are formed after N-sulfation but before O-sulfation. Assessment of the influence of substrate size on the reaction further showed that a large substrate is preferred; an octasaccharide released tritium at a rate approximately 10% of that observed for the parent polysaccharide, and some release occurred also with smaller oligosaccharides.

Location of xylosyltransferase in the cisternae of the rough endoplasmic reticulum of embryonic cartilage cells

Purified antibodies were prepared to UDP-D-xylose: core protein xylosyltransferase, the enzyme which initiates the formation of chondroitin sulfate chains in the course of proteoglycan biosynthesis in cartilage. The purified antibodies were conjugated to ferritin with a two-step glutaraldehyde procedure, and conjugates were then used to locate xylosyltransferase in fragments of embryonic cartilage cells. The results indicated that the enzyme is located within the cisternae of the rough endoplasmic reticulum. The distribution of the enzyme was similar to that of prolyl hydroxylase in the same cell fragments, suggesting that procollagen synthesis and initiation of chondroitin sulfate chains occur in the same regions of the rough endoplasmic reticulum.

Assay of N-acetylheparosan deacetylase with a capsular polysaccharide from Escherichia coli K5 as substrate

A new substrate for the deacetylase which catalyzes the removal of the N-acetyl groups from N-acetylheparosan in the course of heparin biosynthesis has been prepared. The capsular polysaccharide from Escherichia coli 010:K5:H4, which is structurally identical to N-acetylheparosan, was partially N-deacetylated by hydrazinolysis and was then radioactively labeled by N-acetylation with [3H]acetic anhydride. Upon incubation of the labeled polysaccharide with microsomes from the Furth mastocytoma, [3H]acetyl groups were released, demonstrating that the bacterial polysaccharide was a substrate for the N-deacetylase. Reaction conditions were established which permitted the quantitative assay of N-deacetylase activity; a Km of 74 mg polysaccharide/liter was determined, which corresponds to 2.1 X 10(-4) M, expressed as concentration of uronic acid; Vmax was 3.4 nmol/mg protein/liter. In confirmation of previous results, it was observed (a) that the reaction was stimulated by 3'-phosphoadenylylsulfate (up to a maximum of 45% at a concentration of 0.5 mM), suggesting that N-sulfation occurred which facilitated continued action of the N-deacetylase, and (b) that NaCl and KCl inhibited the enzyme, with 50% reduction of activity at a concentration of 25 mM. In the course of this work, a simple, single-vial assay procedure was used. Released [3H]acetate was extracted from the acidified reaction mixture with a toluene- or xylene-based scintillation fluid containing 10% isoamyl alcohol and measured directly by scintillation spectrometry.

New oligosaccharides from heparin and heparan sulfate and their use as substrates for heparin-degrading enzymes

Oligosaccharides were isolated from heparin and heparan sulfate by a procedure consisting of three major steps: (a) acid hydrolysis; (b) gel chromatography; and (c) cation exchange chromatography on an amino acid analyzer. To date, six new oligosaccharides have been isolated by this procedure and have been sequenced by a combination of NaB3H4-labeling and deaminative cleavage with nitrous acid. The structures of these oligosaccharides were as follows: 1. GlcN-GlcUA-GlcN 2. GlcN-IdUA-GlcN 3. GlcN-GlcUA-GlcN-GlcUA-GlcN 4. GlcN-IdUA-GlcN-GlcUA-GlcN 5. GlcN-GlcUA-GlcN-IdUA-GlcN 6. GlcN-IdUA-GlcN-IdUA-GlcN The linkage positions and anomeric configurations were assumed to be the same as in the polysaccharides from which the oligosaccharides originated. The usefulness of some of these oligosaccharides as enzyme substrates was tested after appropriate modifications and radioactive labeling. Oligosaccharides 2 and 3 were N-[35S]sulfated and were found to serve as substrates for heparan N-sulfate sulfatase (heparin sulfamidase), with a homogenate of cultured skin fibroblasts as enzyme source. Similarly, reduction of oligosaccharide 2 with NaB3H4 yielded a substrate for acetyl-CoA:alpha-D-glucosaminide N-acetyltransferase. Finally, the previously known disaccharide, 4-O-alpha-D-glucosaminyl-L-iduronic acid, which was isolated in the course of this work, was N-acetylated with [3H] acetic anhydride and was shown to be a substrate for N-acetyl-alpha-D-glucosaminidase.

New assay for uronosyl 5-epimerases

Simple assays have been developed for the two uronosyl 5-epimerases which participate in the biosynthesis of heparin and dermatan sulfate (heparosan N-sulfate D-glucuronosyl 5-epimerase and chondroitin D-glucuronosyl 5-epimerase, respectively). Following previously published procedures, substrates labeled with tritium in the C-5 positions of the D-glucuronosyl and L-iduronosyl residues were prepared enzymatically by incubation of O-desulfated heparin and dermatan with 3H2O and crude epimerase preparations from bovine liver and human skin fibroblasts, respectively. In the new assays, 3H2O generated from these substrates during the epimerase reactions was quantitated by the method of Pollard et al. (Anal. Biochem. (1981) 110, 424-430). In this procedure, 3H2O in the aqueous reaction mixture is extracted into a toluene-based organic phase containing 25% isoamyl alcohol, while the polysaccharide substrate remains in the aqueous phase and does not generate scintillations. This procedure is much simpler than that used previously which involves distillation of each reaction mixture and quantitation of the radioactivity in the distillate. The new assays have been validated by the demonstration that conditions of linearity with time and enzyme concentration can be established for both epimerase reactions. Assays of this type should be useful in the study of any enzymatic reaction where 3H2O is formed from a 3H-labeled substrate and the unreacted substrate is not appreciably soluble in the organic phase.