The copolymeric structure of dermatan sulphate produced by cultured human fibroblasts. Different distribution of iduronic acid- and glucuronic acid-containing units in soluble and cell-associated glycans

The structure of dermatan [35S]sulphate-chondroitin [35S]sulphate copolymers synthesized and secreted by fibroblasts in culture was studied. 35S-labelled glycosaminoglycans were isolated from the medium, a trypsin digest of the cells and the cell residue after 72h of 35SO42-incorporation. The galactosaminoglycan component (dermatan sulphatechondroitin sulphate copolymers) was isolated and subjected to various degradation procedures including digestion with testicular hyaluronidase, chondroitinase-AC and-ABC and periodate oxidation followed by alkaline elimination. The galactosaminoglycans from the various sources displayed significant structural differences with regard to the distribution of various repeating units, i.e. IdUA-GalNAc-SO4 (L-iduronic acid-N-acetyl-galactosamine sulphate), GlcUA-GalNAc-SO4 (D-glucuronic acid-N-acetylgalactosamine-sulphate) and IdUA(-SO4)-GalNAc (L-iduronosulphate-N-acetylgalactosamine). The galactosaminoglycans of the cell residue contained larger amounts of IdUA-GalNAc-SO4 than did those isolated from the medium or those released by trypsin. In contrast, the glycans from the latter 2 sources contained large proportions of periodate-resistant repeat periods [GlcUA-GalNAc-SO4 and IdUA(-SO4)-GalNAc]. Periods containing L-iduronic acid sulphate were particularly prominent in copolymers found in the medium. Kinetic studies indicated that the 35S-labelled glycosaminoglycan of the cell residue accumulated radioactivity more slowly than did the glycans of other fractions, indicating that the material remaining with the cells was not exclusively a precursor of the secreted polymers. The presence of copolymers rich in glucuronic acid or iduronic acid sulphate residues in the soluble fractions may be the result of selective secretion from the cells. Alternatively, extracellular, polymer-level modifications such as C-5 inversion of L-iduronic acid to D-glucuronic acid, or sulphate rearrangements, would yield similar results.

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Structural studies on heparan sulphate from human lung fibroblasts. Characterization of oligosaccharides obtained by selective periodate oxidation of d-glucuronic acid residues followed by scission in alkali

Biochemical Journal ◽

10.1042/bj1910103 ◽

1980 ◽

Vol 191 (1) ◽

pp. 103-110 ◽

Cited By ~ 15

Author(s):

Ingrid Sjöberg ◽

Lars-Ȧke Fransson

Keyword(s):

Uronic Acid ◽

Glucuronic Acid ◽

Human Lung ◽

General Structure ◽

Heparan Sulphate ◽

Periodate Oxidation ◽

Exchange Chromatography ◽

Lung Fibroblasts ◽

Human Lung Fibroblasts ◽

Iduronic Acid

1. 3H- and 35S-labelled heparan sulphate was isolated from monolayers of human lung fibroblasts and subjected to degradations by (a) deaminative cleavage and (b) periodate oxidation/alkaline elimination. Fragments were resolved by gel- and ion-exchange-chromatography. 2. Deaminative cleavage of the radioactive glycan afforded mainly disaccharides with a low content of ester-sulphate and free sulphate, indicating that a large part (approx. 80%) of the repeating units consisted of uronosyl-glucosamine-N-sulphate. Blocks of non-sulphated [glucuronosyl-N-acetyl glucosamine] repeats (3–4 consecutive units) accounted for the remainder of the chains. 3. By selective oxidation of glucuronic acid residues associated with N-acetylglucosamine, followed by scission in alkali, the radioactive glycan was degraded into a series of fragments. The glucuronosyl-N-acetylglucosamine-containing block regions yielded a compound N-acetylglucosamine–R, where R is the remnant of an oxidized and degraded glucuronic acid. Periodate-insensitive uronic acid residues were recovered in saccharides of the general structure glucosamine–(uronic acid–glucosamine)n–R. 4. Further degradations of these saccharides via deaminative cleavage and re-oxidations with periodate revealed that iduronic acid may be located in sequences such as glucosamine-N-sulphate→iduronic acid→N-acetylglucosamine. Occasionally the iduronic acid was sulphated. Blocks of iduronic acid-containing repeats may contain up to five consecutive units. Alternating arrangements of iduronic acid- and glucuronic acid-containing repeats were also observed. 5. 3H- and 35S-labelled heparan sulphates from sequential extracts of fibroblasts (medium, EDTA, trypsin digest, dithiothreitol extract, cell-soluble and cell-insoluble material) afforded similar profiles after both periodate oxidation/alkaline elimination and deaminative cleavage.

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Synthesis of glycosaminoglycans by human embryonic lung fibroblasts. Different distribution of heparan sulphate, chondroitin sulphate and dermatan sulphate in various fractions of the cell culture

Biochemical Journal ◽

10.1042/bj1670383 ◽

1977 ◽

Vol 167 (2) ◽

pp. 383-392 ◽

Cited By ~ 28

Author(s):

Ingrid Sjöberg ◽

Lars-Åke Fransson

Keyword(s):

Glucuronic Acid ◽

Chondroitin Sulphate ◽

Heparan Sulphate ◽

Periodate Oxidation ◽

Exchange Chromatography ◽

Lung Fibroblasts ◽

Relative Distribution ◽

Dermatan Sulphate ◽

Human Embryonic Lung ◽

Iduronic Acid

Foetal human lung fibroblasts, grown in monolayer, were allowed to incorporate 35SO42− for various periods of time. 35S-labelled macromolecular anionic products were isolated from the medium, a trypsin digest of the cells in monolayer and the cell residue. The various radioactive polysaccharides were identified as heparan sulphate and a galactosaminoglycan population (chondroitin sulphate and dermatan sulphate) by ion-exchange chromatography and by differential degradations with HNO2 and chondroitinase ABC. Most of the heparan sulphate was found in the trypsin digest, whereas the galactosaminoglycan components were largely confined to the medium. Electrophoretic studies on the various 35S-labelled galactosaminoglycans suggested the presence of a separate chondroitin sulphate component (i.e. a glucuronic acid-rich galactosaminoglycan). The 35S-labelled galactosaminoglycans were subjected to periodate oxidation of l-iduronic acid residues followed by scission in alkali. A periodate-resistant polymer fraction was obtained, which could be degraded to disaccharides by chondroitinase AC. However, most of the 35S-labelled galactosaminoglycans were extensively degraded by periodate oxidation–alkaline elimination. The oligosaccharides obtained were essentially resistant to chondroitinase AC, indicating that the iduronic acid-rich galactosaminoglycans (i.e. dermatan sulphate) were composed largely of repeating units containing sulphated or non-sulphated l-iduronic acid residues. The l-iduronic acid residues present in dermatan sulphate derived from the medium and the trypsin digest contained twice as much ester sulphate as did material associated with the cells. The content of d-glucuronic acid was low and similar in all three fractions. The relative distribution of glycosaminoglycans among the various fractions obtained from cultured lung fibroblasts was distinctly different from that of skin fibroblasts [Malmström, Carlstedt, Åberg & Fransson (1975) Biochem. J.151, 477–489]. Moreover, subtle differences in co-polymeric structure of dermatan sulphate isolated from the two cell types could be detected.

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The copolymeric structure of pig skin dermatan sulphate. Characterization of d-glucuronic acid-containing oligosaccharides isolated after controlled degradation of oxydermatan sulphate

Biochemical Journal ◽

10.1042/bj1430369 ◽

1974 ◽

Vol 143 (2) ◽

pp. 369-378 ◽

Cited By ~ 15

Author(s):

Lars-Åke Fransson ◽

Lars Cöster ◽

Anders Malmström ◽

Ingrid Sjöberg

Keyword(s):

General Formula ◽

Glucuronic Acid ◽

Periodate Oxidation ◽

Dermatan Sulphate ◽

Chondroitinase Abc ◽

Pig Skin ◽

Iduronic Acid ◽

Unsaturated Disaccharide ◽

Selective Periodate Oxidation

Selective periodate oxidation of unsubstituted l-iduronic acid residues in copolymeric dermatan sulphate chains was followed by reduction-hydrolysis or alkaline elimination. By this procedure the glucuronic acid-containing periods were isolated in oligosaccharide form; general formula: [Formula: see text] Further degradation of these oligosaccharides with chondroitinase-AC yielded three types of products: (a) sulphated trisaccharide containing an unsaturated uronosyl moiety in the non-reducing terminal and a C4 fragment in the reducing terminal, ΔUA-GalNAc-(-SO4)-R; (b) monosulphated, unsaturated disaccharide, ΔUA-GalNAc-SO4 when n is greater than or equal to 2; and (c) N-acetylgalactosamine with or without sulphate. Oligosaccharides containing a single glucuronic acid residue (n=1) comprised more than half of the glucuronic acid-containing oligosaccharides. The terminal N-acetylgalactosamine moiety of the shortest oligosaccharide was largely 4-sulphated, whereas higher oligosaccharides primarily contained 6-sulphated or unsulphated hexosamine moieties in the same position. Moreover, IdUA-SO4-containing oligosaccharides were encountered. These oligosaccharides were resistant to the action of chondroitinase-ABC.

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Biosynthesis of dermatan sulphate. Loss of C-5 hydrogen during conversion of d-glucuronate to l-iduronate

Biochemical Journal ◽

10.1042/bj1980669 ◽

1981 ◽

Vol 198 (3) ◽

pp. 669-675 ◽

Cited By ~ 20

Author(s):

A Malmström

Keyword(s):

Ion Exchange ◽

Paper Chromatography ◽

Glucuronic Acid ◽

Human Fibroblasts ◽

Ion Exchange Chromatography ◽

Exchange Chromatography ◽

Dermatan Sulphate ◽

Microsomal Preparation ◽

Iduronic Acid

The formation of L-iduronic acid during biosynthesis of dermatan sulphate has been studied in culture human fibroblasts and in microsomes from the same cells. The cells were incubated with D-[14C]glucose and D-[5-3H]glucose for 72 h. The [14C,3H]dermatan sulphate was hydrolysed and the disaccharides obtained were acetylated and separated by ion-exchange chromatography. The ratio of 3H/14C was 0.36 for N-acetyldermosine and 1.36 N-acetylchondrosine. A microsomal preparation from the fibroblasts was incubated with UDP-D-[5-3H]glucuronic acid, UDP-D-[14C]glucuronic acid, UDP-N-acetyl-D-galactosamine and 3′-phospho-5′-adenylyl sulphate. The polymeric products were separated into nonsulphated and sulphated components which had 3H/14C ratios of 0.51 and 0.20 and contained 9% and 70% of their uronosyl residues in the L-ido-configuration, respectively. Chondroitinase-AC digestion of these polymers liberated all of the remaining 3H activity. Hydrolysis and N-acetylation followed by paper chromatography showed that the L-iduronic acid-containing products were devoid of 3H. The data obtained indicate that the epimerization of D-glucuronosyl to L-iduronosyl residues during biosynthesis of dermatan sulphate involves an abstraction of the C-5 hydrogen of the uronosyl residue.

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Structure and metabolism of sulphated glycosaminoglycans in cultures of human fibroblasts. Structural characteristics of co-polymeric galactosaminoglycans in sequential extracts of fibroblasts during pulse-chase experiments

Biochemical Journal ◽

10.1042/bj1780257 ◽

1979 ◽

Vol 178 (2) ◽

pp. 257-270 ◽

Cited By ~ 22

Author(s):

I Sjöberg ◽

I Carlstedt ◽

L Cöster ◽

A Malmström ◽

L A Fransson

Keyword(s):

Structural Characteristics ◽

Human Fibroblasts ◽

Heparan Sulphate ◽

Periodate Oxidation ◽

Cell Fraction ◽

Human Embryonic Lung ◽

Chase Period ◽

Soluble Cell ◽

Dominant Component ◽

Iduronic Acid

1. Human embryonic lung and skin fibroblasts were allowed to incorporate 32SO42- or 35SO42- and D-[1-3H]glucosamine. After removal of the medium the monolayer was subjected to sequential extractions by using EDTA, brief trypsin digestion, extraction with dithiothreitol ofllowed by freeze–thawing and extraction with trichloroacetic acid. The heparan sulphate and galactosaminoglycan contents of the various extracts were estimated after deaminative cleavage of the former component. Heparan sulphate was the major component of the trypsin digest, whereas galactosaminoglycans were the dominant component of other fractions. 2. Galactosaminoglycans of the various fractions were subjected to chemical (periodate oxidation/alkaline elimination) and enzymic (chondroitinase-AC and -ABC, as well as testicular hyaluronidase) degradations. Galactosaminoglycans from the insoluble cell fraction and the dithiothreitol extract contained larger amounts of L-iduronic acid than did those of other fractions. 3. Pulse-chase experiments were performed with and without replating of the cells at the start of the chase period. Radioactive glycans were isolated from the various extracts during the chase period. The half-lives of glycans of the insoluble cell fraction and the dithioreitol extract were shorter (5–8h) than were those of the trypsin digest and the EDTA extract (22h and 11h respectively). After replating of the cells in chase medium, radioactive cell-associated glycans were secreted from the cells and could be recovered in the trypsin digest, the EDTA extract and the medium. Furthermore, 35S/3H ratios of glycans from all these fractions decreased during the chase period. The following conclusions were reached. The insoluble cell fraction contains the synthesis pool and some structural material, whereas the soluble cell fraction is the storage and degradation pool. The dithiothreitol extract appears to contain the immediate precursors of secreted material. The trypsin-released glycans comprise structural components as well as material destined for pinocytosis or secretion into the medium. The EDTA extract is considered to consist of glycans en route to the medium. 4. The two presumptive precursor pools were preferentially depleted of L-iduronic acid-rich galactosaminoglycans during the chase. Glycans recovered from the trypsin digest, the EDTA extract and the medium during the chase contained larger amounts of periodate-resistant uronic acid residues (D-glucuronic acid and/or L-iduronic acid O-sulphate) than did their precursors. It is proposed that polymer-level modifications of secreted glycans are partly responsible for the results.

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The co-polymeric structure of pig skin dermatan sulphate. Distribution of L-iduronic acid sulphate residues in co-polymeric chains

Biochemical Journal ◽

10.1042/bj1450379 ◽

1975 ◽

Vol 145 (2) ◽

pp. 379-389 ◽

Cited By ~ 24

Author(s):

L Cöster ◽

A Malmström ◽

I Sjöberg ◽

L Fransson

Keyword(s):

Periodate Oxidation ◽

Low Molecular Weight ◽

Dermatan Sulphate ◽

Radioactive Product ◽

Chondroitinase Abc ◽

Pig Skin ◽

Iduronic Acid ◽

Polymeric Chains ◽

Complete Digestion ◽

Testicular Hyaluronidase

1. Pig skin dermatan sulphate was degraded by periodate oxidation followed by alkaline elimination or by chondroitinase-ABC to quantify irregular repeating units, i.e. those containing D-GlcUA (D-glucuronic acid) and L-IdUA-SO4 (sulphated iduronic acid). 2. Previous results of periodate oxidation (Fransson, 1974) indicated repeating sequences in pig skin dermatan sulphate containing, on average, 3D-GlcUA, 9 L-IdUA-SO4 or 28 L-IdUA units in addition to N-acetylgalactosamine sulphate. However, complete digestion with chondroitinase-ABC yielded, at the most, 3-4 disulphated disaccharides/chain. Consequently, more than one-half of the L-IdUA-SO4 residues were present in monosulphated periods, i.e. IdUA-(SO4)-GalNAc. 3. To determine the location of L-IdUA-SO4 residues along the copolymeric chain dermatan sulphate was digested with testicular hyaluronidase. (This enzyme cleaves GalNAc-GlcUA bonds within block regions containing D-GlcUA.) By NaB3H4 reduction GalNAc residues located in the reducing end of the fragments were converted into [3H]GalNAcOH (N-acetylgalactosaminitol). Finally, the radioactive product was fragmented by periodate oxidation followed by alkaline elimination. The bulk of the radioactivity was associated with periodate-resistant oligosaccharides indicating that clusters of GlcUA-GalNAc-SO4 periods are often adjacent to a varying number of (n = 1-4) of L-IdUA-SO4-containing periods. 4. To study the distribution of L-IdUA-SO4-containing periods in relation to blocks of IdUA-GalNAc-SO4 periods different fractions of hyaluronidase-degraded dermatan sulphate were degraded separately. In all types of fragments (mol. wts. 1,500-10,000) L-IdUA-SO4-containing periods were demonstrated. In short fragments reducing terminal GalNAc-6-SO4 (6-sulphated N-acetylgalactosamine) was found confirming that these sequences were joined to relatively long D-GlcUA-containing block sequences via GalNAc-6-SO4. Moreover, low-molecular-weight oligosaccharides composed of alternating sequences were encountered. An octasaccharide derived from the carbohydrate sequence -GalNAc-GlcUA-GalNAc-IdUA-GalNAc-GlcUA-GalNAc-IdUA-GalNAc-GlcUA-GalNAc (- indicates the position of cleavage by hyaluronidase) was identified.

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