scholarly journals Co-polymeric glycosaminoglycans in transformed cells. Transformation-dependent changes in the co-polymeric structure of heparan sulphate

1982 ◽  
Vol 201 (1) ◽  
pp. 233-240 ◽  
Author(s):  
Lars-Ȧke Fransson ◽  
Birgitta Havsmark ◽  
Vincenzo P. Chiarugi
Keyword(s):  
Heparan Sulphate ◽  
Periodate Oxidation ◽  
Ion Exchange Chromatography ◽  
Exchange Chromatography ◽  
Transformed Cells ◽  
Large Contribution ◽  
3T3 Cells ◽  
Normal Case ◽  
3T3 Fibroblasts ◽  
Lower Charge

1. Heparan sulphates from normal 3T3 fibroblasts are association-prone as indicated by their affinity for agarose gels substituted with cognate heparan sulphate species. Heparan sulphates from SV40-transformed or polyoma-virus-transformed cells have no affinity for the same gels. 2. Heparan sulphates from the medium, the pericellular and intracellular pools of normal, SV40-transformed and polyoma-transformed 3T3 cells were separated into four subfractions (HS1–HS4) by ion-exchange chromatography. In general, HS1–HS3 were found in cell-derived heparan sulphates, whereas HS3–HS4 were present in the medium. The heparan sulphates from transformed cells were more heterogeneous and of lower charge density than those from the normal counterpart. 3. Degradations via periodate oxidation/alkaline elimination yielded the oligomers glucosamine-(hexuronate–glucosamine)n-R with n=1–5 and a large proportion of N-sulphate groups. There was a large contribution of fragments n=4–5 from heparan sulphates of normal cells. These fragments were less common in low-sulphated heparan sulphates of transformed cells. In the case of medium-drived heparan sulphates all species had a low content of fragments n=4–5. 4. The size distribution of (glucuronate–N-acetylglucosamine)n regions was assessed after deaminative cleavage. It was broad and ranged from n=1–10 for all heparan sulphate species. In the case of medium-derived heparan sulphates there were distinct differences between normal and transformed cells. In the latter chains the N-acetyl-rich segments were both shorter and longer than in the normal case. The shape of the disaccharide peak was consistent with a lower content of O-sulphate in the heparan sulphates from transformed cells. 5. It was concluded that heparan sulphates from medium or transformed cells exhibit the greatest structural deviation from the normal case. The finding of lower proportions of extended, iduronate/glucuronate-bearing, N-sulphate-rich segments in heparan sulphates of transformed cells was particularly interesting in view of the fact that these elements have been associated with ability to self-interact.

scholarly journals 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

1980 ◽  
Vol 191 (1) ◽  
pp. 103-110 ◽  
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.

scholarly journals 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

1977 ◽  
Vol 167 (2) ◽  
pp. 383-392 ◽  
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.

scholarly journals The structure of C-polysaccharide from the walls of Streptococcus pneumoniae

1978 ◽  
Vol 175 (3) ◽  
pp. 1033-1042 ◽  
Author(s):  
I R Poxton ◽  
E Tarelli ◽  
J Baddiley
Keyword(s):  
Cell Walls ◽  
Active Component ◽  
Alkali Treatment ◽  
Teichoic Acid ◽  
Periodate Oxidation ◽  
Structural Features ◽  
Ion Exchange Chromatography ◽  
Exchange Chromatography ◽  
Chemical Degradation ◽  
Acid And Alkali Treatment

The well-known immologically active component of pneumococci, C-polysaccharide, is a teichoic acid that can be isolated from the cell walls and purified by Sephadex and ion-exchange chromatography. Further details of the structure of C-teichoic acid were established by chemical degradation, including hydrolysis in acid and alkali, treatment with HF, periodate oxidation and methylation. In addition, the use of 13C n.m.r. has confirmed some of these structural features and resulted in a proposal for the order of substituents, the location of positions of substitution and the configuration of anomeric centres in the repeating unit of the polymer.

Studies on an Inhibitor of Plasminogen Activation in Human Serum

1973 ◽  
Vol 30 (02) ◽  
pp. 414-424 ◽  
Author(s):  
Ulla Hedner
Keyword(s):  
Ion Exchange ◽  
Human Serum ◽  
Antithrombin Iii ◽  
Gel Filtration ◽  
Ion Exchange Chromatography ◽  
Exchange Chromatography ◽  
Specific Adsorption ◽  
Partial Purification ◽  
Plasminogen Activation ◽  
Preparative Electrophoresis

SummaryA procedure is described for partial purification of an inhibitor of the activation of plasminogen by urokinase and streptokinase. The method involves specific adsorption of contammants, ion-exchange chromatography on DEAE-Sephadex, gel filtration on Sephadex G-200 and preparative electrophoresis. The inhibitor fraction contained no antiplasmin, no plasminogen, no α1-antitrypsin, no antithrombin-III and was shown not to be α2 M or inter-α-inhibitor. It contained traces of prothrombin and cerulo-plasmin. An antiserum against the inhibitor fraction capable of neutralising the inhibitor in serum was raised in rabbits.

Preparation and Characterization of NH2-Terminal Fibrinogen Bβ Fragments from N-DSK of Human Fibrinogen

1984 ◽  
Vol 51 (01) ◽  
pp. 016-021 ◽  
Author(s):  
S Birken ◽  
G Agosto ◽  
B Lahiri ◽  
R Canfield
Keyword(s):  
High Performance ◽  
Gel Filtration ◽  
Ion Exchange Chromatography ◽  
Exchange Chromatography ◽  
Reverse Phase ◽  
Human Fibrinogen ◽  
Human Volunteers ◽  
Cnbr Cleavage ◽  
Two Peaks

SummaryIn order to investigate the early release of NH2-terminal plasmic fragments from the Bβ chain of fibrinogen, substantial quantities of Bβ 1-42 and Bβ 1-21 are required as immunogens, as radioimmunoassay standards and for infusion into human volunteers to determine the half-lives of these peptides. Towards this end methods that employ selective proteolytic cleavage of these fragments from fibrinogen have been developed. Both the N-DSK fragment, produced by CNBr cleavage of fibrinogen, and Bβ 1-118 were employed as substrates for plasmin with the finding of higher yields from N-DSK. Bβ 1-42 and Bβ 1-21 were purified by gel filtration and ion-exchange chromatography on SP-Sephadex using volatile buffers. When the purified preparation of Bβ 1-42 was chromatographed on reverse-phase high performance liquid chromatography, two peaks of identical amino acid composition were separated, presumably due either to pyroglutamate or to amide differences.

Review on the Application of Mixed-mode Chromatography for Separation of Structure Isoforms

2018 ◽  
Vol 20 (1) ◽  
pp. 56-60 ◽  
Author(s):  
Tsutomu Arakawa
Keyword(s):  
Ion Exchange ◽  
Mixed Mode ◽  
Ion Exchange Chromatography ◽  
Exchange Chromatography ◽  
Charged State ◽  
Partial Structure ◽  
Reverse Phase ◽  
Oligomer Formation ◽  
Structure Rearrangement ◽  
Disulfide Scrambling

Proteins often generate structure isoforms naturally or artificially due to, for example, different glycosylation, disulfide scrambling, partial structure rearrangement, oligomer formation or chemical modification. The isoform formations are normally accompanied by alterations in charged state or hydrophobicity. Thus, isoforms can be fractionated by reverse-phase, hydrophobic interaction or ion exchange chromatography. We have applied mixed-mode chromatography for fractionation of isoforms for several model proteins and observed that cation exchange Capto MMC and anion exchange Capto adhere columns are effective in separating conformational isoforms and self-associated oligomers.

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