Extracellular glycosaminoglycans (GAG) released by chick embryonic fibroblasts

Summary Administration of Concanavalin A (Con A) to cultured skin fibroblasts derived from chick embryos at two developmental stages produce variations in the relative concentration of individual glycosaminoglycan (GAG) secreted by the cells. This effect is different: at 7 days (increase of hyaluronic acid and dermatan sulphate and decrease of chondroitin sulphate) and at 14 days (dermatan sulphate is not detectable).All the cells bind the Con A specifically, but a different pattern of agglutination is present in fibroblasts of the two embryonic ages. Since Con A is well known to bind carbohydrate-containing surface proteins, the result suggests that the release of GAG by chick embryonic fibroblasts can be modulated by cell surface receptors.     

Synthesis of type III collagen by fibroblasts from the embryonic chick cornea

Synthesis of collagen types I, II, III, and IV in cells from the embryonic chick cornea was studied using specific antibodies and immunofluorescence. Synthesis of radioactively labeled collagen types I and III was followed by fluorographic detection of cyanogen bromide peptides on polyacrylamide slab gels and by carboxymethylcellulose chromatography followed by disc gel electrophoresis. Type III collagen had been detected previously by indirect immunofluorescence in the corneal epithelial cells at Hamburger-Hamilton stages 20--30 but not in the stroma at any age. Intact corneas from embryos older than stage 30 contain and synthesize type I collagen but no detectable type III collagen. However, whole stromata subjected to collagenase treatment and scraping (to remove epithelium and endothelium) and stromal fibroblasts from such corneas inoculated in vitro begin synthesis of type III collagen within a few hours while continuing to synthesize type I collagen. As demonstrated by double-antibody staining, most corneal fibroblasts contain collagen types I and III simultaneously. Collagen type III was identified biochemically in cell layers and media after chromatography on carboxymethylcellulose be detection of disulfide-linked alpha l (III)3 by SDS gel electrophoresis. The conditions under which the corneal fibroblasts gain the ability to synthesize type III collagen are the same as those under which they lose the ability to synthesize the specific proteoglycan of the cornea: the presence of corneal-type keratan sulfate.     

Exogenous glycosaminoglycans modulate extracellular and intracellular accumulation of newly synthesized glycosaminoglycans by embryonic chick skin fibroblasts

The effects of exogenous glycosaminoglycans (GAG) on newly synthesized GAG accumulation in intra- and extra-cellular compartments of 17 incubation days chick embryonic skin fibroblasts have been examined. Exogenous GAG are able to act on both total GAG synthesis and secretion by embryonic fibroblasts and on the relative concentration of individual GAG. A decline in hyaluronic acid and an increase in chondroitin sulfate plus dermatan sulfate in the cellular compartment for all GAG administered have been detected. There was also similar behaviour in the extracellular compartment after sulfated GAG administration.     

The nature and origin of the glycosaminoglycans of the embryonic chick vitreous body

Glycosaminoglycans of the embryonic chicken vitreous were characterized and then were used as markers to establish which tissues synthesize the vitreous humor during development. The glycosaminoglycans are predominantly chondroitin sulfates by several criteria. They are resistant to streptomyces hyaluronidase, an enzyme which degrades only hyaluronate, and are digested by testicular hyaluronidase and chondroitinase AC, enzymes which degrade hyaluronate plus chondroitin 4- and 6-sulfates. On electrophoresis on cellulose acetate in 0.15 M phosphate buffer, pH 6.7, the vitreous glycosaminoglycans migrate slightly slower than authentic chondroitin sulfate, but, in 0.1 N HCl, they migrate very close to chondroitin sulfate standards. Finally, the disaccharides produced by digestion of these radioactively labeled glycosaminoglycans with chondroitinases AC and ABC were identified as Δdi-4S and Δdi-6S, as expected for chondroitin 4- and 6-sulfate. By using incorporation of radioactive precursors into chondroitin sulfates in vitro, we than determined which tissues synthesize the vitreous humor in the developing eye. Late in development, on Day 12–13, the isolated vitreous is very active in chondroitin sulfate synthesis, while the neural retina, the lens, and the pecten are less active and produce a high proportion of enzyme-resistant GAG. The eye tissues isolated from embryos labeled in ovo retain similar amounts and types of glycosaminoglycans, indicating that cells within the vitreous synthesize the vitreous humor glycosaminoglycans at this time. Earlier in development, from Days 6 to 8, the isolated vitreous incorporates very low levels of radioactivity into GAG, but the neural retina incorporates high levels of radioactivity into chondroitin sulfate. When the embryos are labeled in ovo and the same tissues are isolated following incorporation, the vitreous retains more radioactive chondroitin sulfate than does the neural retina. Thus, the vitreous humour glycosaminoglycan is initially synthesized by the neural retina and is secreted into the vitreous space.     

Biosynthesis of glycosaminoglycans in bovine cornea. The effect of uridine diphosphate xylose

1. The role of UDP-xylose in the regulation of corneal glycosaminoglycan biosynthesis was investigated. Bovine corneas were incubated with [U-(14)C]-glucose in the presence and in the absence of the nucleotide, and the radioactivity of chondroitin, chondroitin sulphate and keratan sulphate, as well as of their monosaccharide constituents, was determined. 2. A decrease in the rate of biosynthesis of chondroitin and chondroitin sulphate and an increase in that of keratan sulphate were observed in the samples incubated with UDP-xylose. 3. The UDP-glucuronic acid isolated after the incubation in the presence of UDP-xylose showed a noticeable decrease in the amount of radioactivity incorporated; this result suggests that UDP-xylose inhibits the UDP-glucose dehydrogenase, causing an accumulation of UDP-glucose and consequently an increase in the formation of UDP-galactose and keratan sulphate. 4. Galactose and galactosamine isolated from the polysaccharides showed variations in the amount of radioactivity incorporated in accordance with those observed for the macromolecules; this fact confirms that in the system we used in vitro a real biosynthesis of the polysaccharide chain took place and that the regulatory effect of UDP-xylose was active at the monosaccharide level.     

Effect of forskolin on synthesis of xyloside-initiated glycosaminoglycans in embryonic chick chondrocytes

The synthesis of sulfated glycosaminoglycan (GAG) chains has been studied in the presence of various concentrations of the artificial acceptor 4-methylumbelliferyl beta-D-xyloside and of forskolin. Sulfated GAG chains formed in the presence of forskolin had a smaller hydrodynamic radius than controls, as revealed by chromatography on Sepharose CL-6B. Sulfated GAGs from both control and treated cultures behaved identically when chromatographed on DEAE.     

Nerve growth factor in skeletal tissues of the embryonic chick

Summary This study demonstrates, via immunohistochemistry and bioassay, the presence of NGF in embryonic bone and cartilage of the chick. Embryos were killed on days 6–9 of incubation at 12 h intervals, and on days 10–18 at 24 h intervals. Paraffin-embedded sections of hind limbs or buds were immunostained with a polyclonal antibody against NGF and the biotin-avidin-horseradish peroxidase technique. Immunostaining was positive in both bone and cartilage, with cartilage staining more intensely. For bioassay, bones from the hind limbs of 9- and 12-day embryos were fast-frozen, lyophilized, and homogenized with Medium 199 (M199). Dorsal root ganglia from 8-day embryos were cultured for 24–36 h with rooster plasma, M199, and varying concentrations of bone homogenate. Significant neurite outgrowth was seen, with the greatest response elicited by 12-day bone homogenate. Addition of anti-NGF to the cultures abolished neurite outgrowth. The results indicate that NGF is present in cartilage and bone of the chick embryo; it may determine the density of sympathetic innervation to the developing skeletal tissues.     

Biosynthesis of glycosaminoglycans by cultured mastocytoma cells

Biosynthesis of glycosaminoglycans by several lines of cultured neoplastic mouse mast cells was studied by incorporation of [³⁵S]sulphate (and in some cases [6-³H]glucosamine) into macromolecular materials found in both the cells and their growth media. Such intracellular and extracellular radioactively labelled materials (shown to be glycosaminoglycans by susceptibility to digestion with heparinase) were further characterized by ion-exchange chromatography and by digestion with testicular hyaluronidase and chondroitinase. All but one cell line produced chondroitin sulphate as the major sulphated glycosaminoglycan; the remainder of the glycosaminoglycan was heparin-like material. No [³H]hyaluronic acid was synthesized. Cells of a newly derived line, termed P815S, synthesized more glycosaminoglycan than the other lines. This glycosaminoglycan, found in both cells and growth medium, was almost entirely chondroitin 4-sulphate. No chondroitin 6-sulphate was found. The chondroitin 4-sulphate from the cells was shown by gel filtration to be smaller than the chondroitin 4-sulphate in the media of these cultures. This discovery of relatively high proportions of chondroitin 4-sulphate in these mastocytoma-derived cells is noteworthy, since mast cells have generally been considered to produce heparin as their major glycosaminoglycan.     

Biosynthesis of glycosaminoglycans and proteoglycans by the lymph node

Previous studies of hyaluronan uptake and catabolism by lymph nodes indicated that the nodes might also add some HA of low molecular weight to the unabsorbed fraction that passes through from afferent to efferent lymph vessels.The ability of lymph nodes to synthesise HA and proteoglycans was therefore examined (i) by perfusion of [³H] acetate through an afferent lymph vessel in vivo, and recovery of labeled products from the efferent lymph vessel and from the node after perfusion; and (ii) by tissue culture of lymph nodes with [³H] acetate.Perfusion of lymph nodes with [³H] acetate in situ yielded: (a), in outflowing lymph, small amounts of chondroitin/dermatan sulfate within the first hour which continued to be produced for up to 24[emsp4 ]h; heparin in the second hour and HA in the third. In the nodes removed 17 to 19[emsp4 ]h later, equal amounts of hyaluronan and chondroitin/dermatan sulfate and heparan sulfate proteoglycans were detected. In the tissue culture of lymph nodes: (1) HA, heparin and proteoglycans of heparan sulfate and chondroitin/dermatan sulfate were released into the medium but in the cell extract only heparan sulfate proteoglycan was detected; and (ii) molecular weight of the released hyaluronan ranged widely but was mostly less than 4–5×10⁵[emsp4 ]D; heparan sulfate proteoglycan was 2.8×10⁴ to 9.4×10⁵[emsp4 ]D; heparin 7.9×10⁴[emsp4 ]D and chondroitin sulfate 1.3×10⁴[emsp4 ]D, suggesting that the chondrotin sulfate were released from their proteoglycans core by enzymic degradation.It is concluded that lymph nodes can release HA, heparin, heparan sulfate and chondroitin/dermatan sulfate proteoglycans into efferent lymph but the amount of hyaluronan is likely to be small without immune or other stimulation and its molecular weight is lower than in other tissues.     

Matrices containing glycosaminoglycans in the developing anterior chambers of chick and Xenopus embryonic eyes.

The fibrous matrix present in the anterior chamber of the chick eye on the 4th day of development has been shown by autoradiography and histochemistry to contain chondroitin sulfate, protein, neutral polysaccharides, and possibly hyaluronic acid (HA). Its synthesis, probably by the mesenchyme of the angle of the eye, is completed by around 10 days of development. In the scanning electron microscope (SEM) it can be seen that, although the matrix thins as the eye grows, it does not disappear until the 15th day. The development of the Xenopus cornea is described; this animal has a matrix in its anterior chamber from soon after the formation of the inner cornea (stage 41) until metamorphosis 7 weeks later. In the SEM, this material appears as a dense, featureless aggregate rather than as a matrix of thick fibres; in the transmission electron microscope, it is seen to be a network of fine filaments containing small dark-staining granules. Histochemistry shows that it contains HA, protein, and neutral polysaccharides. The morphological evidence is compatible with the matrix being made by the inner cornea. The probable major role of the matrix is to separate lens from cornea in establishing the anterior chamber. In the chick embryo, at least, the matrix is also likely to help stabilise the endothelium during its formation.     

Developmental changes in glycosaminoglycans,collagen and collagenase activity in embryonic chick skin

In order to study remodelling of connective tissue during development, changes in glycosaminoglycans, collagen and collagenase activity in embryonic chick skin at various stages have been studied.Collagen content in the skin increased rapidly during days 14 to 18, then leveled off until hatching. Prior to the increase of collagen deposition in the skin, a sharp decrease in chondroitin sulfate was observed between days 11 and 14, while dermatan sulfate increased almost 4 fold during days 12 to 14, then increased steadily until hatching. Hyaluronic acid decreased progressively during the stages investigated (days 11 to 20).At the same stage as the rate of collagen deposition in the tissue became maximal (day 16), the amount of dialyzable hydroxyproline showed a maximum indicating that an increased rate of collagen deposition in the tissue was accompanied by accelerated collagenolysis.Culture of skin from various stages of embryonic development revealed that 16 day old tissue was potentially capable of secreting the highest levels of collagenase. This collagenase was mostly inactive against soluble collagen and collagen fibrils but could be activated by 3 M NaSCN treatment.     

An electron-microscopical analysis of embryonic chick tissues explanted in culture

Summary Three types of tissue (hypoblast, germ wall and epiblast) were dissected from early chick embryos and explanted on Falcon plastic dishes. After they had settled and spread, the explants were fixed, usually within 18–24 h after explantation, and sections were cut through the tissue and the Falcon dish. The closeness of the cells to the substrate varied even within the same explant, but the epiblast tended to be closer to the substrate than did the hypoblast or germ wall. Plaques were present in all three tissues in regions where the cell processes contacted the substrate. Extensive desmosomes were visible in the epiblast explants, small desmosomes were present in the germ wall explants, but desmosomes were never seen in hypoblast explants. These differences in cell/substrate and cell/cell morphology are discussed in relation to the different behavioural characteristics of the three tissues. Some mixed cultures were also examined by electron microscopy. When the epiblast was confronted with either hypoblast or germ wall, it underlapped them at the region of contact.     

Biosynthesis and proteolytic processing of type XI collagen in embryonic chick sterna

The biosynthesis and proteolytic processing of type XI procollagen was examined using pulse-chase labelling of 17-day embryonic chick sterna in organ culture with [3H]proline. Products of biosynthesis were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis with and without prior reduction of disulfide bonds. Pro-alpha chains, intermediates, and matrix forms were identified by cyanogen bromide or Staphylococcus aureus V8 protease digestion. The results show that type XI pro-alpha chains assemble into trimeric molecules with interchain disulfide bonds. Proteolytic processing begins at least 40 min after the start of labeling which is later than that of type II procollagen (25 min). This first processing step involves the loss of the domain containing the interchain disulfide bonds which most likely is the carboxyl propeptide. In the case of the pro-alpha 3 chain, this generates the matrix form, m alpha 3, which retains its amino propeptide. For the pro-alpha 1 and pro-alpha 2 chains, this step generates intermediate forms, p alpha 1 and p alpha 2, which undergo a second proteolytic conversion to m alpha 1 and m alpha 2, and yet retain a pepsin-labile domain. The conversion of p alpha 2 to m alpha 2 is largely complete 2 h after labeling. p alpha 1 is converted to m alpha 1 very slowly and is 50% complete after 18 h of chase in organ culture. The apparent proteolytic processing within the amino propeptide, and the differential rate of processing between two chains in the same molecule are unusual and distinguish type XI from collagen types I, II, and III. It is possible that the extremely slow processing of p alpha 1 affects the formation of the heterotypic cartilage collagen fibrils and may be related to the function of type XI collagen.     

Biosynthesis of glycosaminoglycans in the developing retina

The glycosaminoglycans of neural retinas from 5-, 7-, 10-, and 14-day chick embryos were labeled in culture with [³H]glucosamine and ³⁵SO₄, extracted, and isolated by gel filtration. The incorporation of label per retina into glycosaminoglycans increased with embryonic age, but that per cell and per unit weight of uronic acid decreased. Specific enzyme methods coupled with gel filtration and paper chromatography demonstrated that [³H]glucosamine incorporation into chondroitin sulfate increased between 5 and 14 days from 7 to 34% of the total incorporation into glycosaminoglycans. During this period, incorporation into chondroitin-4-sulfate increased relative to that into chondroitin-6-sulfate. Between 5 and 10 days, incorporation into heparan sulfate showed a relative decline from 89 to 61%. Incorporation into hyaluronic acid always represented less than 2% of the total. A twofold greater increase in galactosamine concentration than in glucosamine concentration in the glycosaminoglycan fraction between 7 and 14 days supports the conclusion that chondroitin sulfate was the most rapidly accumulating glycosaminoglycan. ECTEOLA-cellulose chromatography revealed a heterogeneity in the size and/or net charge of chondroitin sulfate and heparan sulfate. We conclude that incorporation of exogenous precursors into glycosaminoglycans in the chick retina decreases relative to cell number as differentiation progresses from a period of high mitotic activity to one of tissue specialization, and that it is accompanied by a net accumulation of glycosaminoglycan and a change in the pattern of its synthesis.