Synthesis of glycosaminoglycans by human skin fibroblasts cultured on collagen gels.

A comparison has been made of the synthesis of glycosaminoglycans by human skin fibroblasts cultured on plastic or collagen gel substrata. Confluent cultures were incubated with [3H]glucosamine and Na235SO4 for 48h. Radiolabelled glycosaminoglycans were then analysed in the spent media and trypsin extracts from cells on plastic and in the medium, trypsin and collagenase extracts from cells on collagen gels. All enzyme extracts and spent media contained hyaluronic acid, heparan sulphate and dermatan sulphate. Hyaluronic acid was the main 3H-labelled component in media and enzyme extracts from cells on both substrata, although it was distributed mainly to the media fractions. Heparan sulphate was the major [35S]sulphated glycosaminoglycan in trypsin extracts of cells on plastic, and dermatan sulphate was the minor component. In contrast, dermatan sulphate was the principal [35S]sulphated glycosaminoglycan in trypsin and collagenase extracts of cells on collagen gels. The culture substratum also influenced the amounts of [35S]sulphated glycosaminoglycans in media and enzyme extracts. With cells on plastic, the medium contained most of the heparan sulphate (75%) and dermatan sulphate (> 90%), whereas the collagenase extract was the main source of heparan sulphate (60%) and dermatan sulphate (80%) from cells on collagen gels; when cells were grown on collagen, the medium contained only 5-20% of the total [35S]sulphated glycosaminoglycans. Depletion of the medium pool was probably caused by binding of [35S]sulphated glycosaminoglycans to the network of native collagen fibres that formed the insoluble fraction of the collagen gel. Furthermore, cells on collagen showed a 3-fold increase in dermatan sulphate synthesis, which could be due to a positive-feedback mechanism activated by the accumulation of dermatan sulphate in the microenvironment of the cultured cells. For comparative structural analyses of glycosaminoglycans synthesized on different substrata labelling experiments were carried out by incubating cells on plastic with [3H]glucosamine, and cells on collagen gels with [14C]glucosamine. Co-chromatography on DEAE-cellulose of mixed media and enzyme extracts showed that heparan sulphate from cells on collagen gels eluted at a lower salt concentration than did heparan sulphate from cells on plastic, whereas with dermatan sulphate the opposite result was obtained, with dermatan sulphate from cells on collagen eluting at a higher salt concentration than dermatan sulphate from cells on plastic. These differences did not correspond to changes in the molecular size of the glycosaminoglycan chains, but they may be caused by alterations in polymer sulphation.     

Type I collagen reduces the degradation of basal lamina proteoglycan by mammary epithelial cells

When mouse mammary epithelial cells are cultured on a plastic substratum, no basal lamina forms. When cultured on a type I collagen gel, the rate of glycosaminoglycan (GAG) synthesis is unchanged, but the rate of GAG degradation is markedly reduced and a GAG-rich, basal lamina-like structure accumulates. This effect of collagen was investigated by comparing the culture distribution, nature, and metabolic stability of the 35S-GAG-containing molecules produced by cells on plastic and collagen. During 48 h of labeling with 35SO4, cultures on collagen accumulate 1.4-fold more 35S-GAG per microgram of DNA. In these cultures, most of the extracellular 35S-GAG is immobilized with the lamina and collagen gel, whereas in cultures on plastic all extracellular 35S-GAG is soluble. On both substrata, the cells produce several heparan sulfate-rich 35S-proteoglycan fractions that are distinct by Sepharose CL-4B chromatography. The culture types contain similar amounts of each fraction, except that collagen cultures contain nearly four times more of a fraction that is found largely bound to the lamina and collagen gel. During a chase this proteoglycan fraction is stable in cultures on collagen, but is extensively degraded in cultures on plastic. Thus, collagen-induced formation of a basal lamina correlates with reduced degradation and enhanced accumulation of a specific heparan sulfate-rich proteoglycan fraction. Immobilization and stabilization of basal laminar proteoglycan(s) by interstitial collagen may be a physiological mechanism of basal lamina maintenance and assembly.     

Turnover of proteoglycans by chick lens epithelial cells in cell culture and intact lens

Chick lens epithelial cells were cultured on plastic and type IV collagen substrata, and the confluent cultures were labeled continuously with [35S]sulfate for 20 h. Intact lenses were also labeled in the same way. 35S-Proteoglycans isolated from those cultures were compared for their molecular sizes and glycosaminoglycan compositions. The results have shown that: 1) Proteoglycans synthesized by cells on type IV collagen were significantly smaller than those by cells on plastic. 2) Proteoglycans of intact lens showed a broad distribution of molecular size and contained a high proportion of chondroitin sulfate in the medium fraction compared to those of the two cell cultures. In order to explain such differences between proteoglycans from cultures, label-chase experiments with [35S]sulfate were done for proteoglycans synthesized. 35S-Proteoglycans isolated at each chase time 0, 2.5, and 17 h) were compared and the following results were found: 1) The cell layers of both "plastic" and "type IV collagen" cultures contained glycosaminoglycan species predominantly at each chase time rather than proteoglycans. 2) Changes in the glycosaminoglycan compositions of medium fractions of cell cultures were observed during the chase period; in medium of the "plastic" culture, proteoheparan sulfate increased with chase time, whereas in medium of the "type IV collagen" culture, chondroitin sulfate glycosaminoglycan (not proteoglycan) increased with chase time. 3) In intact lens culture, lens capsule fraction at every chase time contained a proteoglycan unique in molecular size, which was not found in cell culture fractions. 4) All fractions from intact lens cultures contained a higher content of chondroitin sulfate at every chase time than the respective fractions from cell cultures. These results suggest that adhesion of the cells to type IV collagen or lens capsule influences the degradation and secretion of proteoglycans. In addition, they can account partially for the above-described differences in molecular sizes and glycosaminoglycan compositions between 35S-proteoglycans from various cultures continuously labeled with [35S]sulfate.     

Collagen metabolism and basement membrane formation in cultures of mouse mammary epithelial cells : Induction of ‘Assembly’ on fibrillar type I collagen substrata

Collagen metabolism was compared in cultures of mouse mammary epithelial cells maintained on plastic or fibrillar type I collagen gel substrata. The accumulation of dialysable and non-dialysable [3H]hydroxyproline and the identification of the collagens produced suggest no difference between substrata in the all over rates of collagen synthesis and degradation. The proportion of the [3H]collagen which accumulates in the monolayers of cultures on collagen, however, markedly exceeds that of cultures on plastic. Cultures on collagen deposit a sheet-like layer of extracellular matrix materials on the surface of the collagen fibres. Immunoprecipitation of the labelled extracts, electrophoresis, indirect immunofluorescence and immunoperoxidase techniques reveal the presence of type IV collagen, along with laminin and heparan sulfate proteoglycan in this layer, in excess over the amounts detectable on cells cultured on plastic. Transformed cells on collagen produce and accumulate more [3H]collagen, yet are less effective in basement membrane formation than normal cells, indicating that the accumulation of collagen alone and the effect of interstitial collagen thereupon do not suffice. Thus, exogenous fibrillar collagen appears to enhance, but is not sufficient for proper assembly of collagenous basement membrane components near the basal epithelial cell surface.     

Influence of collagen gel substrata on certain biochemical activities of hepatocytes in primary culture

In order to study the influence of cell shape as modulated by the extracellular matrix on the cellular activity, hepatocytes isolated from liver were maintained on collagen I coated plastic substrata and collage I gel substrata and certain hepatocyte specific functions were investigated. The incorporation of³[H]-leucine into total proteins and albumin secreted by cells maintained on collagen gel was found to be significantly higher compared to those maintained on a collagen coated plastic substrata, indicating that hepatocytes on collagen gel have an enhanced albumin synthesizing capacity. Increased incorporation of³⁵[S]-sulphate into total proteoglycans (PG) and a relatively higher fraction of the³⁵[S]-PG in the extracellular space showed an increased rate of synthesis and secretion of sulphated PGs by cells maintained on collagen gels. But in contrast to the above results, the incorporation of³[H]-leucine into cytokeratins C₈, C₁₈ and actin were significantly low in cells maintained on collagen gel. The tyrosine amino transferase activity exhibited by hepatocytes preincubated with dexamethasone on collagen gel was also significantly low. The different forms of collagen substrata appeared to have no effect on the amino acid transport by hepatocytes, further suggesting that the various hepatocyte specific functions are not uniformly altered when hepatocytes are maintained on three-dimensional collagen gel substrata. These results indicate that the shape of the cell as determined by the nature of the matrix substratum influences the synthetic activity of secretory proteins and those remaining intracellularly, differently.     

Collagenous substrata regulate the nature and distribution of glycosaminoglycans produced by differentiated cultures of mouse mammary epithelial cells

We have investigated the influence of culture substrata upon glycosaminoglycans produced in primary cultures of mouse mammary epithelial cells isolated from the glands of late pregnant mice. Three substrata have been used for experiments: tissue culture plastic, collagen (type I) gels attached to culture dishes, and collagen (type I) gels that have been floated in the culture medium after cell attachment. These latter gels contract significantly. Cells cultured on all three substrata produce hyaluronic acid, heparan sulfate, chondroitin sulfates and dermatan sulfate but the relative quantities accumulated and their distribution among cellular and extracellular compartments differ according to the nature of the culture substratum. Notably most of the glycosaminoglycans accumulated by cells on plastic are secreted into the culture medium, while cells on floating gels incorporate almost all their glycosaminoglycans into an extracellular matrix fraction. Cells on attached collagen gels secrete approx. 30% of their glycosaminoglycans and assemble most of the remainder into an extracellular matrix. Hyaluronic acid is produced in significant quantities by cells on plastic and attached gels but in relatively reduced quantity by cells on floating gels. In contrast, iduronyl-rich dermatan sulfate is accumulated by cells on floating gels, where it is primarily associated with the extracellular matrix fraction, but is proportionally reduced in cells on plastic and attached gels. The results are discussed in terms of polarized assembly of a morphologically distinct basal lamina, a process that occurs primarily when cells are on floating gels. In addition, as these cultures secrete certain milk proteins only when cultured on floating gels, we discuss the possibility that cell synthesized glycosaminoglycans and proteoglycans may play a role in the maintenance of a differentiated phenotype.     

Adhesion sites of murine fibroblasts on cold insoluble globulin-adsorbed substrata

The attachment and detachment behavior of three mouse fibroblast cell lines adhering to plastic tissue culture substrata coated with the serum protein cold-insoluble globulin (CIg) resembles that seen on the usual serumcoated substrata. The transformed cell line SVT2 spreads more extensively on the CIg-coated than on the serum-coated substratum, while the nontransformed Balb/c 3T3 line and concanavalin A-selected “revertant” of SVT2 are equally well spread on both substrata. In all three cases, immunofluorescence microscopy using antibodies to CIg suggests that the cells are more tightly apposed to the CIg-coated substratum than to the serum-coated substratum. Substrate-attached material (SAM), which contains cell-substratum adhesion sites and which is left after EGTA-mediated detachment of cells, is enriched for cell surface fibronectin and glycosaminoglycans (GAG). When cells are seeded onto CIg-coated substrata rather than serum-coated substrata, there is an increased deposition of GAG but a comparable deposition of cellular proteins. The protein distribution of the two types of SAM are identical as analyzed by sodium dodecyl sulfate/polyacrylamide gel electrophoresis, including fibronectin content. This indicates that substratum-bound CIg cannot functionally substitute for cell surface fibronectin in these adhesion sites. Analysis of the GAG deposited on CIg-coated substrata reveals that hyaluronate and the chondroitins are increased to a much greater extent than heparan sulfate; however, the ratio of hyaluronate to the various chondroitin species is invariant. These data provide further evidence that hyaluronate and the chondroitins are deposited in adhesion sites in well-defined stoichiometric proportions, possibly as supramolecular complexes, and that CIg may mediate adhesion of cells in the serum layer by binding to GAG-containing proteoglycans.     

Regulation of growth and differentiation of a rat hepatoma cell line by the synergistic interactions of hormones and collagenous substrata

Serum-free, hormonally defined media have been developed for optimal growth of a rat hepatoma cell line. The cells' hormonal requirements for growth are dramatically altered both qualitatively and quantitatively by whether they were plated onto tissue culture plastic or collagenous substrata. On collagenous substrata, the cells required insulin, glucagon, growth hormone, prolactin, and linoleic acid (bound to BSA), and zinc, copper, and selenium. For growth on tissue culture plastic, the cells required the above factors at higher concentrations plus several additional factors: transferrin, hydrocortisone, and triiodothyronine. To ascertain the relative influence of hormones versus substratum on the growth and differentiation of rat hepatoma cells, various parameters of growth and of liver-specific and housekeeping functions were compared in cells grown in serum-free, hormonally supplemented, or serum-supplemented medium and on either tissue culture plastic or type I collagen gels. The substratum was found to be the primary determinant of attachment and survival of the cells. Even in serum-free media, the cells showed attachment and survival efficiencies of 40-50% at low seeding densities and even higher efficiencies at high seeding densities when the cells were plated onto collagenous substrata. However, optimal attachment and survival efficiencies of the cells on collagenous substrata still required either serum or hormonal supplements. On tissue culture plastic, there was no survival of the cells at any seeding density without either serum or hormonal supplements added to the medium. A defined medium designed for cells plated on tissue culture plastic, containing increased levels of hormones plus additional factors over those in the defined medium designed for cells on collagenous substrata, was found to permit attachment and survival of the cells plated into serum-free medium and onto tissue culture plastic. Growth of the cells was influenced by both substrata and hormones. When plated onto collagen gel substrata as compared with tissue culture plastic, the cells required fewer hormones and growth factors in the serum-free, hormone-supplemented media to achieve optimal growth rates. Growth rates of the cells at low and high seeding densities were equivalent in the hormonally and serum-supplemented media as long as comparisons were made on the same substratum and the hormonally supplemented medium used was the one designed for that substratum. For a given medium, either serum or hormonally supplemented, the saturation densities were highest for tissue culture plastic as compared with collagen gels.(ABSTRACT TRUNCATED AT 400 WORDS)     

Microporosity of the substratum regulates differentiation of MDCK cells in vitro

Summary We have analyzed the ability of the physical substratum to modulate both the ultrastructural and protein synthetic characteristics of the Madin-Darby canine kidney (MDCK) renal cell line. When MDCK cells were seeded on Millipore Millicell CM microporous membrane cell culture inserts they demonstrated a more columnar organization with an increase in cell density sixfold greater than the same cells seeded on conventional plastic substrata. After 1 wk postseeding on the microporous membrane a partial basal lamina was noted, with a contiguous basement membrane being apparent after 2 wk. One-dimensional sodium dodecyl sulfate gel electrophoresis was used to analyze detergent-solubilized proteins from MDCK cells maintained on plastic substrata vs. microporous membranes. When proteins were pulse-labeled with [³⁵S]methionine, a 55 kDa protein was evident in the cytosolic extract of cells grown on collagen, laminin, and nontreated plastic substrata; but this labeled protein was not evident in similar extracts from cells grown on collagen and laminin-coated microporous membranes. To test if the polarized, basement-membrane secreting phenotype of the MDCK cells could be generated on a microporous membrane without pretreatment with any extracellular matrix (ECM) components, cells were seeded on the Millipore Millicell HA (cellulosic) microporous membrane. This type of substrata does not need a coating of ECM components for cell attachment. A partial basement membrane was formed below cells where the basal surface of the cell was planar, but not in areas where the cell formed large cytoplasmic extensions into the filter. This led us to the conclusion that the microporous nature of the substrata can dictate both ultrastructural and protein synthetic activities of MDCK cells. Furthermore, we suggest that both the planar nature of the basal surface and the microporosity of the substrate are corequisites for the deposition of the basement membrane.     

Modulation of sulfated glycosaminoglycan and small proteoglycan synthesis by the extracellular matrix

Cell culture in collagen lattice is known to be a more physiological model than monolayer for studying the regulation of extracellular matrix protein deposition. The synthesis of sulfated glycosaminoglycans (GAG) and dermatan sulfate (DS) proteoglycans by 3 cell strains were studied in confluent monolayers grown on plastic surface, in comparison to fully retracted collagen lattices. Cells were labelled with³⁵S-sulfate, followed by GAG and proteoglycan analysis by cellulose acetate and SDS-polyacrylamide gel electrophoresis, respectively. The 3 cell strains contracted the lattice in a similar way. In monolayer cultures, the major part of GAG was secreted into culture medium whereas in lattice cultures of dermal fibroblasts and osteosarcoma MG-63 cells but not fibrosarcoma HT-1080 cells, a higher proportion of GAGs, including dermatan sulfate, was retained within the lattices. Small DS proteoglycans, decorin and biglycan, were detected in fibroblasts and MG-63 cultures. They were preferentially trapped within the collagen gel. In retracted lattices, decorin had a higher M_r than in monolayer. Biglycan was detected in monolayer and lattice cultures of MG-63 cells but in lattice cultures only in the case of fibroblasts. In this last case, an up regulation of biglycan mRNA steady state level and down regulation of decorin mRNA was observed, in comparison to monolayers, indicating that collagen can modulate the phenotypical expression of small proteoglycan genes.Supported by a fellowship from the Centre National de la Recherche Scientifique     

Incorporation of radioactive precursors into glycosaminoglycans by rat muscle fibroblasts exposed to a solubilized rat bone matrix fraction

Confluent cultures of rat muscle fibroblastic cells respond by increased glycosaminoglycan (GAG) synthesis when cultured in medium containing a solubilized bone matrix fraction (SBM) at a concentration of 100 micrograms/ml. The metabolism of the GAG associated with the cell pellet, the cell surface and the tissue culture medium fractions was studied, in the presence and absence of SBM, by measuring the incorporation of radioactivity from [3H]glucosamine and [35S]SO4 into the isolated GAG. Net synthesis of hyaluronic acid and of chondroitin sulfate in the medium fraction increased more rapidly in cultures containing SBM compared to controls, and the accumulation of labelled GAG in the medium of the treated cultures was approximately linear with respect to the length of incubation. The addition of SBM also resulted in increased incorporation of 3H and of 35S into the GAG of the cell surface and cell pellet fractions. In these fractions, stimulation of incorporation of radioactivity occurred in two waves: an early, relatively minor increase and a later relatively major increase. The relatively major stimulation of radioactivity into the GAG of the cell surface fraction occurred between 24 and 48 h and was independent of any apparent effect of serum.     

The effect of aging on the synthesis of hexosamine-containing substances from rat costal cartilage. A decrease in sulfation of chondroitin sulfate with aging.

The amount of glycosaminoglycan (GAG) in dry costal cartilage tissue of rats decreased with aging, while the GAG content in mg DNA (unit cartilage cell) remained the same with aging. These results can be explained by the finding that the total number of cartilage cells decreased with aging. Electrophoretic analysis showed that chondroitin 4-sulfate was the major GAG in rat costal cartilage of various ages. Rat costal cartilage of different ages was incubated with radioactive precursors, and newly synthesized GAG was prepared and the radioactivity analyzed to determine the biosynthetic activity. As to changes in the radioactivity uptake with aging per mg dry cartilage tissue, aging influenced [35S]sulfate incorporation into GAG more significantly than [3H]glucosamine incorporation into GAG. There was a significant decrease in the specific radioactivity of [35S]sulfate per mg DNA (unit cartilage cell), whereas the specific radioactivity of [3H]glucosamine per mg DNA did not change significantly with aging. Both the total sulfotransferase activity and the specific activity per mg DNA decreased significantly with aging. Analysis of disaccharide units formed after chondroitinase ABC digestion of labeled GAG isolated from young and old cartilage showed that the percentage of incorporation of [3H]glucosamine into deltaDi-OS increased significantly with aging. These results suggested that the appearance of nonsulfated positions in the structure of the chondroitin sulfate chain increased with aging. On the basis of gel chromatography on Bio-Gel A-1.5 m no significant difference in the approximate molecular size of chondroitin sulfate was observed between the young and old GAG samples. The present study indicated that the sulfation of chondroitin sulfate chains from rat costal cartilage decreased with the process of aging.     

Glycosaminoglycan accumulation by normal and malignant human mammary epithelial cells in primary culture

The effects of glycosaminoglycans (GAGs) on cell growth and differentiation appear to vary with cell type and stage of development. This study describes the types and distribution of GAGs accumulated by normal and malignant human mammary epithelial cells in primary culture during their exponential and stationary phases of growth. Cultures incubated with [3H]glucosamine or [35S]sulfate were separated into medium, extracellular matrix (ECM), and cell fractions. Labelled GAGs were identified by chemical and enzymatic degradations and cellulose acetate electrophoresis. Cultures of normal cells in the exponential phase of growth released the most labelled GAGs into the medium fraction, the majority of which was hyaluronic acid (HA). The increase in labelled GAG accumulation, the increase in sulfated GAGs localized in the ECM fraction correlated with the reduced proliferative activity and increased cell density of cells in stationary cultures. In contrast, cultures of mammary tumour cells had the same labelled GAG profile, regardless of their growth status. Although there was variation among tumours, in general, the majority of the labelled GAGs were secreted into the medium fraction and the predominant GAG was HA. The results are comparable with those obtained from studies on mammary tissue in vivo. Primary cultures of human mammary epithelial cells should be useful for determining how modulations of GAGs affect growth and differentiation of these cells.     

Effects of vanadate on tyrosine phosphorylation and the pattern of glycosaminoglycan synthesis in rabbit chondrocytes in culture

The present study examined the effects of high doses of vanadate on glycosaminoglycan (GAG) synthesis and tyrosine phosphorylation in rabbit chondrocytes in confluent cultures. Although 6 microM vanadate increased the incorporation of [3H]glucosamine into chondroitin sulfate proteoglycans twofold, 40-60 microM vanadate suppressed this incorporation fourfold. Although 6 microM vanadate had little effect on [3H]glucosamine incorporation into hyaluronate, 40-60 microM vanadate increased this incorporation threefold. Chemical analyses confirmed that the increase in [3H]glucosamine incorporation into hyaluronate and the decrease in the incorporation into chondroitin sulfate proteoglycan correlated with increased hyaluronate content and decreased chondroitin sulfate content in the cell layers of vanadate-transformed cells. Chondrocytes exposed to 40-60 microM vanadate became typically transformed spindlelike cells. Furthermore, vanadate, at 6 and 60 microM, increased the overall level of phosphotyrosine by 8- and 31-fold, respectively, and 60 microM vanadate enhanced phosphorylation of many phosphotyrosine-containing proteins. These observations suggest that vanadate induces transformation-associated changes in the pattern of GAG synthesis when it induces excess phosphorylation on tyrosine in chondrocyte proteins.     

The synthesis of subendothelial matrix by bovine aortic endothelial cells in culture

Bovine aortic endothelial cells cultured on collagenous or plastic substrata continuously synthesize and deposit a subendothelial matrix, independently of whether the cells are in the logarithmic or the stationary phase of growth. This subendothelial matrix contains fibrillar and amorphous elements comparable with those observed in the subendothelium in vivo. Deposition of subendothelial matrix on a collagen gel substratum both started earlier and progressed at approximately double the rate than that on denatured collagen. The relative composition of the subendothelial matrix was assessed by sequential incubation with trypsin, elastase and collagenase (Jones et al., 1979). The subendothelial matrix deposited on collagen gels by early confluent cultures and late post-confluent cultures differed in their enzyme sensitivity. These age-related changes in the enzyme sensitivity of the subendothelial matrix were characteristic for each cloned cell population examined. Comparable variations in the composition of the subendothelial matrix were not observed when the cells were cultured on plastic or gelatin-coated dishes; the subendothelial matrix deposited on these two substrata contained considerably more trypsin-sensitive material and less elastase and collagenase-sensitive material than the matrix deposited on native collagen gels. Age-related changes in the enzyme sensitivity of the subendothelial matrix deposited on collagen gels was found to be a function of the time elapsed since confluence and it was not related to the time elapsed since plating or to the number of cells present.     

Time-related distribution profiles of sulfated glycosaminoglycans in cells, cell surfaces, and media of cultured rat liver fat-storing cells

Fat-storing cells (perisinusoidal lipocytes, Ito cells), the principal proteoglycan-producing cell type in liver, were maintained for various times in primary and secondary culture to monitor the amount and pattern of [35S]sulfate-labeled glycosaminoglycans (GAG) in the cells, on the cell surface, and in the medium. In parallel with the phenotypic modulation of fat-storing cells toward myofibroblast-like cells, intracellular GAG decrease progressively, whereas cell surface-bound and medium GAG increase several-fold. These changes are associated with time-dependent alterations of the pattern of GAG in the various compartments. Dermatan sulfate is the most prominent intracellular GAG type in primary cultures, but on the cell surface and in the medium chondroitin sulfate prevails and reaches almost 70% of all medium GAG in secondary cultures. The results point to a highly dynamic expression of the specific types of GAG in the cellular and extracellular compartments of fat-storing cell cultures that seems to accompany the spontaneous transformation into myofibroblast-like cells. The latter one is a mainly chondroitin sulfate-producing cell type, whereas the initial fat-storing cell generates predominantly dermatan sulfate.     

Glycoproteins released into the culture medium of differentiating murine neuroblastoma cells.

C-1300 murine neuroblastoma cells release glycoproteins into the culture medium. The process was studied by prelabeling spinner cultures for 12 to 60 hours with [3H]glucosamine. Then, the medium was removed and replaced with fresh medium lacking radioactive isotope. Soluble material released into the medium during the subsequent 2-hour incubation was collected by trichloroacetic acid precipitation. The released proteins were then separated by discontinuous polyacrylamide gel electrophoresis in buffers containing sodium dodecyl sulfate. The electrophoretograms of glycoproteins obtained from cultures labeled for different lengths of time were very similar; three major radioactive regions centered about molecular weights 87,000, 66,000, and 55,000 were present. When spinner cells were transferred to monolayer culture in the presence of N6,O2' dibutyryl adenosine 3':5'-monophosphate (Bt2cAMP), differentiation (extension of neurites twice the diameter of the perikaryon) was observed. Monolayer cultures grown in the presence of Bt2cAMP and [3H]glucosamine for 12 hours released glycoproteins which gave a gel electrophoresis pattern similar to that obtained using spinner cultures. However, after 60 hours in the presence of Bt2cAMP and [3H]glucosamine, the released radioactive material consisted almost exclusively of glycoproteins of the 66,000 molecular weight class. Similar results were obtained if [3H]fucose was substituted for [3H]glucosamine, or if bromodeoxyuridine (which also induced differentiation) was substituted for Bt2cAMP. Similar experiments using radioactive amino acids were conducted with both spinner and monolayer cultures. Much of the released radioactive material was contained in the same three molecular weight classes as the glycoproteins released by spinner cells prelabeled with [3H]glucosamine, and this pattern did not vary with length of labeling period or type of culture. These results may imply that the glycosylation of released proteins is influenced by agents which can induce differentiation. The origin of this released material is discussed. [3H]Glucosamine-labeled glycoproteins of the molecular weight class centered about 55,000 (discussed above) were isolated by preparative gel electrophoresis. They co-migrated with authentic mouse brain microtubular protein as two closely spaced bands on a number of different electrophoretic systems. This protein fraction was also characterized as complexing with a monospecific antitubulin antibody.     

Proteoglycan biosynthesis by chick embryo retina glial-like cells

In this report we present biochemical evidence that purified cultures of chick embryo retina glial-like cells actively synthesize heparan sulfate (HS) and chondroitin sulfate/dermatan sulfate (CS/DS) proteoglycans as well as hyaluronic acid. Glial-like cell cultures were metabolically labeled with [3H]glucosamine and 35SO4, and the medium, cell layer, and substratum-bound fractions were analyzed separately. Proteoglycans were characterized according to charge, apparent molecular size, and glycosaminoglycan (GAG) composition and were found to be differentially distributed among the cellular compartments. HS was the predominant GAG overall and was the major species found in the cell layer and substratum-bound fractions. CS/DS was also present in each fraction and comprised the largest proportion of GAGs in the medium. The major GAG-containing material resolved into three different size classes. The first, found in the cell layer and substratum-bound fractions, contained both CS/DS and HS and was of large size. A second, intermediately sized class with a higher CS/DS:HS ratio was found in the medium. The smallest class was found in the cell layer fraction and comprised HS, most likely present as free GAG chains. In addition, each fraction contained hyaluronic acid. Characteristics of these macromolecules differ from those produced by purified cultures of chick embryo retina neurons and photoreceptors in terms of size, compartmental distribution, and presence of hyaluronic acid.     

Glycosaminoglycans synthesized by cultured bovine corneal endothelial cells

Bovine corneal endothelial (BCE) cells seeded and grown on plastic dishes were labeled with 35S-sulfate or 3H-glucosamine for 48 h at various phases of growth of the cultures. Newly synthesized proteoglycans were isolated from the culture medium and from the extracellular matrix (ECM) produced by the BCE cells, and the glycosaminoglycan (GAG) component of the proteoglycans was analyzed. Cells actively proliferating on plastic surfaces secreted an ECM that contained heparan sulfate as the major 35S-labeled GAG (86%) and dermatan sulfate as a minor component (13%). Upon reaching confluence, the BCE cells incorporated 35S-labeled chondroitin sulfate (20%), as well as heparan sulfate (66%) and dermatan sulfate (14%), into the EC. Seven-day postconfluent cells incorporated newly synthesized heparan sulfate and dermatan sulfate into the matrix in approximately equal proportions. Dermatan sulfate was the main 35S-labeled GAG (60-65%) in the medium of both confluent and postconfluent cultures. 35S-Labeled chondroitin sulfate (20-25%) and heparan sulfate (15%) were also secreted into the culture medium. The type of GAG incorporated into newly synthesized ECM was affected when BCE cells were seeded onto ECM-coated dishes instead of plastic. BCE cells actively proliferating on ECM-coated dishes incorporated newly synthesized heparan sulfate and dermatan sulfate into the ECM in a ratio that was very similar to the ratio of these GAGs in the underlying ECM. Addition of mitogens such as fibroblast growth factor (FGF) to the culture medium altered the type of GAG synthesized and incorporated into the ECM by BCE cells seeded onto ECM-coated dishes if the cells were actively growing, but had no effect on postconfluent cultures.