The use of caesium sulphate density gradient centrifugation to analyse proteoglycans from human articular cartilages of different ages

Analysis of aggrecan in human knee cartilage and synovial fluid indicates that aggrecanase (ADAMTS) activity is responsible for the catabolic turnover and loss of whole aggrecan whereas other protease activity is required for C-terminal processing in vivo

Studies of aggrecan proteolysis in human joints have implicated both the aggrecanase [ADAMTS, a disintegrin-like and metalloprotease (reprolysin-type) with thrombospondin type 1 motif] and matrix metalloproteinase (MMP) families. We have analysed the aggrecan core protein species present in vivo in both articular cartilage and synovial fluids from normal, acutely injured and osteoarthritic joints. Normal cartilage contains at least seven major G1 domain (the N-terminal globular domain of aggrecan)-bearing species, of which three (full-length core, G1-NITEGE(373) and G1-VDIPEN(341)) have been identified. The C-terminals of the others are unknown but digestion of fetal human aggrecan with MMP-3 and crude aggrecanase suggests that they are products of MMP-like activity in vivo. Normal synovial fluids contain at least 10 species, of which nine result from ADAMTS-dependent cleavage, and this cleavage occurs at all of the five known aggrecanase sites. Aggrecan fragments in the cartilage and synovial fluids of acutely injured joints are generally similar to normal, but all contain a markedly increased ratio of G1-NITEGE to G1-VDIPEN. Aggrecan from the cartilage of late-stage osteoarthritis patients is remarkably similar to normal, whereas the synovial fluid aggrecan is more fragmented than that from normal or injured knees. The analyses suggest that the role of the ADAMTS and these MMP-like activities in human cartilage are distinctly different. Excessive ADAMTS activity in vivo is destructive to cartilage matrix, since the bulk of the glycosaminoglycan (GAG)-bearing products are released from the tissue into the synovial fluid following cleavage of the Glu(373)-Ala(374) bond. In contrast, the MMP-like activity appears to be essentially non-destructive, since much of the GAG-bearing product is retained in the tissue following cleavages that are in the more C-terminal regions of the molecule.

Influence of aging on the synthesis and morphology of the aggrecans synthesized by differentiated human articular chondrocytes

OBJECTIVE

Synthesis rates of aggrecans by phenotypically stable human articular chondrocytes and the immobilization of these aggrecans in large aggregates were used as variables reflecting the capability of these cells of restoring the extracellular matrix of articular cartilage in vivo in an aging population.

DESIGN

Human articular chondrocytes were isolated from articular cartilage obtained from 33 different donors at autopsy. The chondrocytes were cultured in gelled agarose. Synthesis of aggrecans was investigated using Na(2)(35)SO(4)as a radioactive precursor after a 2-week culture period. Electron microscopic study of aggrecan aggregates was done on the macromolecules accumulated over 3 weeks in culture by the chondrocytes obtained from eight other donors with increasing ages.

RESULTS

Sulfate incorporation rates into aggrecans correlated inversely with the age of the donor. The value of sulfate incorporation in aggrecans for chondrocytes obtained from mature cartilage of a 20-year-old individual in this system drops to 50% and 25% for chondrocytes obtained from 45- and 69-year-old individuals respectively. Electron microscopic study of aggrecan aggregates showed that the 'de novo' synthesized hyaluronan molecules were fully loaded with aggrecans. Mature human articular cartilage cells were found to synthesize an aggrecan aggregate which carried an average number of 11.7 to 13.1 aggrecans. Cells obtained from immature donors synthesized aggrecan aggregates of which the hyaluronan chain carried twice the amount of aggrecans. These immature human articular cartilage cells were also found to synthesize significant proportions of large aggrecan aggregates with 20 to over 100 aggrecans immobilized on a single hyaluronan chain. The proportions of these large aggrecan aggregates decreased with increasing age of the donors of the chondrocytes.

CONCLUSION

The declining aggrecan synthesis rates and the decreased capability of assembling large molecular size aggregates with increasing age in humans illustrates a progressive failure of the repair function of articular cartilage cells in humans.

Augmentative effects of L-cysteine and methylmethionine sulfonium chloride on mucin secretion in rabbit gastric mucous cells

BACKGROUND

Our previous study showed that L-cysteine (Cys) and methylmethionine sulfonium chloride (MMSC) inhibited ethanol-induced gastric mucosal damage and increased the amount of surface mucin in rats. This study examined whether Cys and MMSC augmented mucin secretion and changed distribution of mucin vesicles ultrastructurally in mucous cells by using primary cultured mucous cells from rabbit glandular stomach. Changes in intracellular cyclic adenosine 3',5'-monophosphate (cAMP) and in levels of cytosolic free Ca2+ were investigated by treatment with Cys and MMSC.

METHODS

Mucin content was measured by an enzyme-linked lectin assay. Transmission electron micrography was used to examine ultrastructural distribution of mucin granules. The amount of cAMP or levels of free Ca2+ were measured by enzyme immunoassay or by fura-2. 16,16-Dimethyl prostaglandin E2 (dmPGE2) or ATP was used as the positive control.

RESULTS

L-Cysteine and MMSC increased mucin secretion and decreased cellular mucin content. The same was noted for dmPGE2. Accelerated mucin granule movements toward the plasma membrane were shown by these agents. Intracellular cAMP increased with exposure to dmPGE2 for 20 min, while neither Cys nor MMSC increased cAMP. No increase in cytosolic free Ca2+ levels occurred after treatment with Cys or MMSC, but an increase was induced 10 s after the addition of ATP.

CONCLUSIONS

The present findings indicate that the increase in mucin secretion by Cys and MMSC was not mediated through the cAMP or Ca2+ signal transduction pathway, but might occur through non-receptor-mediated mechanisms.

Proteoglycans from osteoarthritic human articular cartilage influence type II collagen in vitro fibrillogenesis

Collagen fibrils were formed in the presence of dermatan sulfate (DSPG) and high density (HDPG) proteoglycans isolated from human adult knee femoral articular cartilage. Eroded cartilage had a higher percentage of DSPGs in the extracted proteoglycans than normal cartilage (p = .018). The dermatan sulfate proteoglycans (DS-PGI and DS-PGII) were detected in normal and osteoarthritic cartilage. DSPGs compared to HDPG inhibited in vitro collagen fibrillogenesis producing a longer lag phase (p less than .05) and a slower rate of fibril formation (p less than .05). DSPGs from eroded osteoarthritic cartilage alone or in combination with HDPG produced a longer lag phase than DSPGs from normal cartilage alone or in combination with HDPG (p less than .05). The inhibition of fibrillogenesis by DSPGs suggests that collagen fibril formation in vivo may be abnormal due to the influence of molecular changes in proteoglycan as well as an increased proportion of DSPGs occurring in osteoarthritic cartilage. Abnormal fibril formation may produce a weakened cartilage matrix, thus contributing to an accelerated process of cartilage degeneration in osteoarthritis.

Proteoglycans of the human intervertebral disc. Electrophoretic heterogeneity of the aggregating proteoglycans of the nucleus pulposus

Nuclei pulposi were dissected from lumbar discs of radiologically normal human spines of cadavers aged 17, 20 and 21 years. Proteoglycans were extracted with 4 M guanidine hydrochloride (dissociative conditions) with proteinase inhibitors and isolated as A1 fractions by associative density-gradient centrifugation. Aggregating and non-aggregating proteoglycans were separated by Sepharose 2B chromatography. Both aggregating and non-aggregating proteoglycans contained a keratan sulphate-rich region as isolated by chondroitinase/trypsin/chymotrypsin digestion and Sepharose CL-6B chromatography. Agarose/acrylamide-gel electrophoresis of individual fractions of a Bio-Gel A-50m dissociative-column separation of the aggregating proteoglycans revealed two, well-separated bands: S and F, the slower and faster migrating bands respectively. The non-aggregating proteoglycan fractions were eluted under associative conditions (0.5 M-sodium acetate, pH 6.8) and migrated as a single band in the electrophoretic system. The gel-electrophoretic heterogeneity of the aggregating proteoglycans was still evident after hydroxylamine fragmentation and removal of the hyaluronate-binding portion of the molecule. Dissociative density-gradient centrifugation of the aggregating proteoglycans partially separated the Band-S proteoglycans from the Band-F population. Subsequent dissociative chromatography of the high-buoyant-density Band F proteoglycans permitted discrimination of this band into two gel-electrophoresis-distinguishable populations (Bands F-1 and F-2). Enzyme-linked immunosorbent assays with a monoclonal antibody that recognized keratan sulphate demonstrated that the D1 fraction containing the Band F-1 proteoglycans was enriched in keratan sulphate compared with the total aggregating or non-aggregating pool of proteoglycans. The proteoglycans of young adult nucleus pulposus could then be ascribed to one of four structurally and/or electrophoretically distinct populations: (1) the non-aggregating population, which comprised about 70% of the total extractable proteoglycans; (2) the aggregating pool, comprising: (a) Band F-1 proteoglycans, which had a relatively large hydrodynamic size, uronate/protein weight ratio, were enriched in keratan sulphate and had a high buoyant density; (b) Band S proteoglycans, which migrated slower in agarose/acrylamide gels, had a smaller hydrodynamic size, lower buoyant density and a lower uronate/protein ratio than the Band F-1 population; (c) Band F-2 proteoglycans, which were lower in buoyant density, smaller in hydrodynamic size and slightly faster in electrophoretic mobility than the Band F-1 proteoglycans.

Electron-microscopic and electrophoretic studies of bovine femoral-head cartilage proteoglycan fractions

Proteoglycans (A1D1) extracted from bovine femoral-head cartilage were examined by electron microscopy using benzyldimethylammonium chloride as a spreading agent. The preparation contained a mixture of particles, some with a 'beaded' structure and a contiguous filamentous 'tail' at one end and others which appeared as round 'blobs', some of which also had filamentous tails. Previous electron-microscopic studies of proteoglycan monomers have indicated that their length distributions were apparently unimodal, a finding that contrasted with agarose/polyacrylamide-gel-electrophoresis results, which generally indicated two bands. In the present study proteoglycans isolated from the slowly migrating electrophoretic band were shown to be predominantly the larger molecules of beaded appearance, whereas the rapidly migrating proteoglycans were predominantly molecules with the 'blob-like' appearance. Gel-filtration, isopycnic-density-gradient-centrifugation and rate-zonal-centrifugation techniques were evaluated as means of proteoglycan fractionation by electron microscopy and agarose-gel electrophoresis. Rate-zonal centrifugation in mixed-salt gradients of caesium chloride/4 M-guanidinium chloride yielded the most effective fractionation.

A comparison of proteoglycan from chick cartilage of different types and a study of the effect of vitamin D on proteoglycan structure

Normal chick growth cartilage contains mainly large proteoglycans that interact well with hyaluronic acid. In contrast normal articular and sternal cartilages contain mainly smaller molecules that interact poorly with hyaluronic acid. Similar smaller proteoglycans are present in all the cartilages in the rachitic state. The smaller proteoglycans all appear to be synthesized as such, and not to arise from degradation of larger molecules unless such degradation occurs extremely rapidly after synthesis. Supplementation of the vitamin D-deplete animals with calcium resulted in the production of large proteoglycans by the growth cartilage, but did not affect the size of the proteoglycan produced by the articular or sternal cartilages. It would appear that in these chicks the chondrocytes of the growth cartilage may be unique in their ability to produce large aggregating proteoglycans, and in their response to plasma calcium levels.

Density gradient analysis of secretions produced in vitro by human and canine airway mucosa: identification of lipids and proteoglycans in such secretions

Human and canine airway mucosal explants synthesize and secrete high molecular weight glycoconjugates, incorporating 14C-glucosamine, a radioactive precursor to epithelial glycoprotein. Our examination of secretions produced by several individual specimens, however, did not reveal epithelial glycoprotein of typical buoyant density (1.5 g/ml in CsBr); only a high-density component with features of glycoprotein and proteoglycan. To provide sufficient material for characterization, secretions from several specimens of human and canine explants were separately pooled and subjected to DGU in CsBr. After removal of lipids and proteins, the glycoconjugates were recovered into five fractions of different density. 14C-glucosamine had been incorporated in all five fractions. Fractions 1-4 together accounted for 88% of the radiolabel but gas chromatography indicated that none of these contained epithelial glycoprotein. Their amino acid compositions were similar to those of proteoglycans and electrophoresis confirmed the presence of chondroitin sulfates A, B, C, heparan sulfate and hyaluronic acid. Sugars typical of epithelial glycoprotein were identified only in the glycoconjugate subfraction 5 of lowest density (and also lowest in yield) in which glycosaminoglycans were also identified. By addition of radioactive precursors, 14C acetate, 14C palmitate and 14C mevalonic acid to the culture medium and autoradiography of the secreted lipids we have shown that the tracheal explants actively synthesize lipids. Lipids accounted for a high proportion, almost half by weight, of the explant secretion. While neutral and phospholipids predominate, glycolipids were also identified.

Glycosaminoglycan distribution in substratum adhesion sites of aging human skin fibroblasts, including papillary and reticular subpopulations

Glycosaminoglycan (GAG) distribution has been analyzed in the adhesion sites, left substratum-bound after EGTA-mediated detachment, of various human skin fibroblast populations grown in vitro in the presence (asc+) or absence (asc-) of ascorbate. Examination of these skin fibroblasts during the EGTA treatment by scanning electron microscopy reveals that (a) asc+ cells detach much more rapidly than asc- cells, but (b) asc- or asc+ cells leave the same two types of structures in longterm culture-generated substratum-attached material (L-SAM)--long linear retraction fibers and "footpad-like" structures. Most of the [3H]glucosamine-radiolabeled polysaccharides in L-SAM were shown to be GAGs. Fibroblasts from a full-thickness skin sample from a very young patient (AG4449) have similar distributions of the GAGs in both the EGTA-suspended cell and L-SAM fractions; however, asc+ cell and L-SAM fractions contain relatively more heparan sulfate than the asc- fractions. In contrast, full-thickness skin fibroblasts from an elderly patient (AG2261) generate GAG distributions in their L-SAMs (with greatly elevated levels of hyaluronate and chondroitin sulfate) that are very different from those of the cell fractions and from those of AG4449; furthermore, these distributions in AG2261 fractions do not change when shifted from asc- to asc+ medium. These studies led to analyses of the two major fibroblast subsets--papillary (PAP) or reticular (RET)--that can be isolated from the dermis of a newborn infant (patient 5). The GAG distributions in the RET fractions were different from those in PAP fractions; of special note was the greater length of heparan sulfate chains from all RET fractions examined when compared to PAP fractions. There was a remarkable similarity in the GAG distributions of asc+ RET fractions when compared to the full-thickness AG2261 cell fractions. In summary, these studies demonstrate that asc- or asc+ "young" cells generate different GAG distributions in their substratum adhesion sites, whereas "old" cells from a full-thickness skin sample do not alter their distribution when shifted from asc- to asc+ (this distribution is different from that of "young" cells). Furthermore, analyses of GAGs in papillary and reticular cell fractions reveal significant differences between the two, with considerable similarity of asc+ reticular fractions to the full-thickness AG2261 fibroblasts, which is consistent with the enrichment of reticular fibroblasts in the skin of aging individuals.

Cesium: a bibliography update

A brief outline of both industrial and medicinal uses is given. This is followed by a survey of literature on cesium salts for the period between January 1981 to May 1984. The bibliography searched indicates an interesting pharmacological and behavioral effect for Cs-salts in addition to its well known physiological and itopic effects. A pattern of clinical trials suggests the potential of cesium salts in certain cancer therapies, affective disorders, tumor imaging, radiotherapy and certain cardiovascular usages. The need for continued probing into the biological activity of this alkalimetal is suggested.