Synthesis of procollagen by matrix-free cells from embryonic-chick arteries

Cells were isolated from the major arteries of 17-day chick embryos by digestion of the tissue with collagenase and trypsin. The cells, when examined immediately after isolation, exhibited a high degree of viability and they were shown to synthesize and secrete procollagen at a high and constant rate for several hours when incubated in suspension in modified Krebs medium. Continuous labelling of the cells with [(14)C]proline demonstrated a lag of about 30min between the time at which the synthesis of non-diffusible peptide-bound hydroxy[(14)C]proline became linear and the time at which its secretion into the medium became linear. This lag time compares with that of 18min observed for freshly isolated matrix-free cells from embryonic-chick tendon, which synthesize and secrete the same type of collagen. Gel-filtration chromatography and polyacrylamide-gel electrophoresis indicated that the collagenous polypeptides secreted into the medium were in the precursor form, known as procollagen, and that the constituent pro-alpha-chains were linked by interchain disulphide bonds and were also in a triple-helical conformation. Characterization of the secreted procollagen by gel-filtration chromatography, polyacrylamide-gel electrophoresis, DEAE-agarose chromatography, and polyacrylamide-gel electrophoresis of peptides obtained by CNBr cleavage, indicated that the predominant form was type-I procollagen. This work extends the range of freshly isolated matrix-free cell systems, which have been characterized for use in studies on the biosynthesis and secretion of procollagen, and it indicates differences in the rates of secretion of procollagen in different cell types secreting the same type of procollagen.

The disulphide-bonded nature of procollagen and the role of the extension peptides in the assembly of the molecule

1. The molecular weights of chick tendon and cartilage procollagens, and their constituent polypeptides, were determined by gel filtration and gel electrophoresis. The values obtained are in good agreement and indicate that the mol.wts. of the secreted procollagens (types I and II) and their individual pro-alpha-chains are of the order of 405 000-445 000 and 137 000-145 000 respectively.2. Digestion of tendon procollagen with human rheumatoid synovial collagenase gave products consistent with the presence of large non-helical peptide extensions at both N-and C-termini. Electrophoretic analysis gave apparent mol.wts. of 17 500 and 36 000 for the respective N- and C-terminal extensions of pro-alpha1(I)-and pro-alpha2-chains, and inter-chain disulphide bonds were restricted to the C-terminal location. 3. During the biosynthesis of procollagen by tendon and cartilage cells a close correlation was observed between the extent of inter-chain disulphide bonding and the proportion of procollagen polypeptides having a triple-helical conformation. These processes appeared to commence in the rough endoplasmic reticulum and be completed in the smooth endoplasmic reticulum, but the rate at which they occur in cartilage cells is markedly slower than that found in tendon cells. 4. When the intracellular [14C]procollagen polypeptides present in the rough-endoplasmic-reticulum fractions of tendon and cartilage cells were analysed under non-reducing conditions on agarose/polyacrylamide composite gels, no significant pools of dimeric intermediates were detected. 5. In both cell types, inter-chain disulphide-bond formation occurred even when hydroxylation, and hence triple-helix formation, was inhibited. The presence of pro-alpha1- and pro-alpha2-components in a ratio of 2:1 in the disulphide-linked unhydroxylated procollagen isolated from tendon cells demonstrated that correct chain association occurs in the absence of hydroxylation. This observation is consistent with a model for the assembly of pro-gamma112-chains in which the recognition and selection of pro-alpha1-and pro-alpha2-chains in a 2:1 ratio are directed by the non-helical C-terminal extension peptides of tendon procollagen.

Characterisation of the major collagen species present in porcine aortae and the synthesis of their precursors by smooth muscle cells in culture

Porcine aortae were digested with pepsin and the solubilised collagen molecules separated by differential salt precipitation at pH7.5. The fraction precipitated at 1.71 M NaCl was shown to comprise collagen type III as judged by its elution characteristics from CM-cellulose, its alpha-chain composition on sodium dodeclysulphate polyacrylamide gel electrophoresis, and amino acid analyses. Pepsin-derived type I collagen was recovered by precipitation at 2.56 M NaCl and similarly characterised. cultures of porcine arterial smooth muscle cells have been established and radiolabelling studies with [14Clproline have demonstrated that these cells synthesis and secrete the precursors of collagen types I and III into the culture medium. Ion-exchange chromatography of these secreted collagen molecules and gel filtration of their pepsin-derived alpha-chains have demonstrated that type III is the major collagen species present in the medium.

The route of secretion of procollagen. The influence of alphaalpha'-bipyridyl, colchicine and antimycin A on the secretory process in embryonic-chick tendon and cartilage cells

I. Embryonic-chick tendon cells were pulse-labelled for 4 min with [14C]proline and the 14C-labelled polypeptides were chased with unlabelled proline for up to 30 min. Isolation of subcellular fractions during the chase period and their subsequent analysis for bacterial collagenase-susceptible 14C-labelled peptides demonstrated the transfer of procollagen polypeptides from rough to smooth microsomal fractions and thence to the extracellular medium. Parallel analyses of Golgi-enriched fractions indicated the involvement of this organelle in the secretory pathway of procollagen. Sodium dodecylsulphate/polyacrylamide-gel electrophoresis of the 14C-labelled polypeptides present in the Golgi-enriched fractions demonstrated that the procollagen polypeptides were all present as disulphide-linked pro-gamma components. 2. When similar kinetic studies of the intracellular transport of procollagen were conducted with embryonic-chick cartilage cells almost identical results were obtained, but the rate of translocation of cartilage procollagen was significantly slower than that observed for tendon procollagen. 3. When hydroxylation of procollagen polypeptides was inhibited by alphaalpha'-bipyridyl, the nascent polypeptides accumulated in the rough microsomal fraction. 4. When cells were pulse-labelled for 4min with [14C)proline and the label was chased in the presence of colchicine, secretion of procollagen was inhibited and an intracellular accumulation of procollagen 14C-labelled polypeptides was observed in the Golgi-enriched fractions. 5. The energy-dependence of the intracellular transport of procollagen was demonstrated in experiments in which antimycin A was found to inhibit the transfer of procollagen polypeptides from rough to smooth endoplasmic reticulum. 6. It is concluded that procollagen follows the classical route of secretion taken by other extracellular proteins.

Studies on the glycosylation of hydroxylysine residues during collagen biosynthesis and the subcellular localization of collagen galactosyltransferase and collagen glucosyltransferase in tendon and cartilage cells

1. The glycosylation of hydroxylysine during the biosynthesis of procollagen by embryonic chick tendon and cartilage cells was examined. When free and membrane-bound ribosomes isolated from cells labelled for 4min with [(14)C]lysine were assayed for hydroxy[(14)C]lysine and hydroxy[(14)C]lysine glycosides, it was found that hydroxylation took place only on membrane-bound ribosomes and that some synthesis of galactosylhydroxy[(14)C]lysine and glucosylgalactosylhydroxy[(14)C]lysine had occurred on the nascent peptides. 2. Assays of subcellular fractions isolated from tendon and cartilage cells labelled for 2h with [(14)C]lysine demonstrated that the glycosylation of procollagen polypeptides began in the rough endoplasmic reticulum. (14)C-labelled polypeptides present in the smooth endoplasmic reticulum and Golgi fractions were glycosylated to extents almost identical with the respective secreted procollagens. 3. Assays specific for collagen galactosyltransferase and collagen glucosyltransferase are described, using as substrate chemically treated bovine anterior-lens-capsule collagen. 4. When homogenates were assayed for the collagen glycosyltransferase activities, addition of Triton X-100 (0.01%, w/v) was found to stimulate enzyme activities by up to 45%, suggesting that the enzymes were probably membrane-bound. 5. Assays of subcellular fractions obtained by differential centrifugation for collagen galactosyltransferase activity indicated the specific activity to be highest in the microsomal fractions. Similar results were obtained for collagen glucosyltransferase activity. 6. When submicrosomal fractions obtained by discontinuous-sucrose-density-gradient-centrifugation procedures were assayed for these enzymic activities, the collagen galactosyltransferase was found to be distributed in the approximate ratio 7:3 between rough and smooth endoplasmic reticulum of both cell types. Similar determinations of collagen glucosyltransferase indicated a distribution in the approximate ratio 3:2 between rough and smooth microsomal fractions. 7. Assays of subcellular fractions for the plasma-membrane marker 5'-nucleotidase revealed a distribution markedly different from the distributions obtained for the collagen glycosyltransferase. 8. The studies described here demonstrate that glycosylation occurs early in the intracellular processing of procollagen polypeptides rather than at the plasma membrane, as was previously suggested.

Ehlers-Danlos syndrome in two siblings with deficient lysyl hydroxylase activity in cultured skin fibroblasts but only mild hydroxylysine deficit in skin

Two siblings suffered from Ehlers-Danlos syndrome characterized by skin fragility, joint laxity and dermal hyperelasticity. The association with microcornea and muscle hypotonia allowed the preliminary classification into type VI according to McKusick. Ultrastructure analysis of skin biopsies revealed poor integration of collagen fibrils into fibres; accordingly, the texture of the connective tissue appeared irregular. Lysyl hydroxylase activity of cultured skin fibroblasts was markedly reduced in the cells of the two patients. Preliminary studies revealed intermediate activity in the cells cultured from the skin of the parents. This finding suggested an autosomal recessive mode of inheritance. Unexpectedly and in contrast to the 3 cases reported in the literature, the hydroxylysine deficit in the patients' skin was, for reasons not yet understood, only mild. Therefore, amino acid analysis of skin is not adequate for the diagnosis of lysyl hydroxylase-deficient Ehlers-Danlos syndrome type VI.

The biosynthesis of basement-membrane collagen by isolated rat glomeruli

A technique is described for the rapid isolation of highly purified preparations of viable glomeruli from rat kidney cortex. The synthesis of protein as judged by the incorporation of [14C]proline into non-diffusible material was shown to be linear for up to 6 h. The synthesis of collagen, measured as non-diffusible 4-hydroxy[14C]proline, was also linear over this period but represented only a small proportion of total protein synthesis. Similar studies conducted in vivo confirmed that collagen synthesis accounted for less than 5% of total protein synthesis in glomeruli. When isolated glomeruli were incubated with [14C]proline, it was found that approximately 16% of the hydroxyproline present in the collagenous component occurred as the 3-isomer. When glomeruli were incubated with [14C]lysine over 90% of the hydroxy[14C]lysine synthesised was glycosylated and most of the glycosylated hydroxy[14C]lysine was present as glucosyl-galactosyl-hydroxy[14C]lysine. The size of the basement membrane collagen synthesised by the isolated glomeruli was estimated by treating the 14C-labelled protein with mercaptoethanol and sodium dodecyl sulphate and then chromatographing the 14C-labelled protein on an agarose column equilibrated and eluted with buffer containing 0.1% (w/v) sodium dodecyl sulphate. The initial form of [14C]collagen synthesised was found to consist of polypeptide chains which had molecular weights of approximately 140 000 and which were shown to be distinctly larger than the polypeptide chains from embryonic chick tendon procollagen. Also when glomeruli were labelled with [14C]proline for 2 h and chased with unlabelled proline for 4 h there was a time-dependent conversion of the initially synthesised collagen moiety to collagen polypeptide chains which co-chromatograph with tendon pro-alpha chains (molecular weight approx. 120 000).

The synthesis and secretion of cartilage procollagen

1. Isolation of free and membrane-bound ribosomes from embryonic chick sternal-cartilage cells labelled for 4min with [14C]proline and their subsequent analysis for hydroxy[14C]proline indicated that cartilage procollagen biosynthesis occurs on bound ribosomes. 2. Nascent procollagen polypeptides on bound ribosomes isolated from cells labelled with [14C]lysine were found to contain hydroxy[14C]lysine indicating that hydroxylation of lysine commences while the growing chains are still attached to the ribosomes. 3. Analysis of bound ribosomes labelled with either [14C]proline or [14C]lysine on sucrose density gradients indicated that cartilage procollagen is synthesized on large polyribosomes in the range 250-400S. 4. Microsomal preparations isolated from cells pulse-labelled for 4 min with [14C]proline were used to determine the direction of release of nascent procollagen polypeptides. Puromycin induced the vectorial release of nascent procollagen polypeptides into the microsomal vesicles suggesting that the first step in the secretion of procollagen polypeptides is their transfer from the ribosomes through the membrane of the endoplasmic reticulum into the cisternal space. 5. The procollagen polypeptides secreted by cartilage cells were shown to be linked by inter-chain disulphide bonds. 6. Examination of the state of aggregation of pro-alpha chains in subcellular fractions isolated from cartilage cells labelled with [14C]proline for various periods of time have provided data on the timing and location of inter-chain disulphide-bond formation. This process commences in the rough endoplasmic reticulum after the release of completed pro-alpha chains from membrane-bound ribosomes. Pro-alpha chains isolated from fractions of smooth endoplasmic reticulum were virtually all present as disulphide-bonded aggregates, suggesting that either disulphide bonding is completed in this cellular compartment, or that procollagen needs to be in a disulphide-bonded form to be transferred to this region of the endoplasmic reticulum. 7. Comparison of these results with previously published data on disulphide bonding in tendon cells suggest that the rate of inter-chain disulphide-bond formation is significantly slower in cartilage cells.

Collagen biosynthesis. Characterization of subcellular fractions from embyonic chick fibroblasts and the intracellular localization of protocollagen prolyl and protocollagen lysyl hydroxylases

1. Subcellular fractions of freshly isolated matrix-free embryonic chick tendon and sternal cartilage cells have been characterized by chemical analysis, electron microscopy and the location of specific marker enzymes. These data indicate the fractions to be of a high degree of purity comparable with those obtained from other tissues, e.g. liver and kidney. 2. When homogenates were assayed for protocollagen prolyl hydroxylase and protocollagen lysyl hydroxylase activities, addition of Triton X-100 (0.1%, w/v) was found to stimulate enzyme activities by up to 60% suggesting that the enzymes were probably membrane-bound. 3. Assay of subcellular fractions obtained by differential centrifugation for protocollagen prolyl hydroxylase activity indicated the specific activity to be highest in the microsomal fraction. Similar results were obtained for protocollagen lysyl hydroxylase activity. 4. Submicrosomal fractions obtained by discontinuous sucrose-gradient centrifugation were assayed for the two enzymes and protocollagen prolyl hydroxylase and protocollagen lysyl hydroxylase were found to be associated almost exclusively with the rough endoplasmic reticulum fraction in both tendon and cartilage cells.

Influence of ascorbic acid on ribosomal patterns and collagen biosynthesis in healing wounds of scorbutic guinea pigs

Scorbutic guinea pigs were wounded and the influence of administering ascorbic acid 6 days later was studied with respect to cellular morphology, ribosomal distribution and protein synthesis. Electron-microscopic studies revealed that the dilated endoplasmic reticulum observed in the fibroblasts of scorbutic wound tissue had reverted to a normal configuration 24h after intraperitoneal injection of 100mg of ascorbate. Quantitative determination of the distribution of free and membrane-bound ribosomes indicated a significant increase in membrane-bound ribosomes in wound tissue from ascorbate-supplemented (recovery) animals. Sucrose-density-gradient centrifugation indicated a significant increase in the proportion of large membrane-bound polyribosomes in the range 300-350S and a concomitant decrease in 80S monoribosomes in the ribosome sedimentation profile of recovery tissue. Determination of the synthesis of non-diffusible [(3)H]hydroxyproline in scorbutic and recovery wounds showed a 3-4-fold stimulation in peptidyl-proline hydroxylation in recovery tissues. Studies carried out in which scorbutic and recovery tissues were incubated with [(14)C]leucine indicated that general protein synthesis, as measured by (14)C incorporated into non-diffusible material/mug of DNA, was unaltered by ascorbate supplementation. Similar studies of [(3)H]proline incorporation suggested that in recovery tissues there was a small but significant increase in [(3)H]proline incorporated/mug of DNA, which probably represents an increase in protocollagen synthesis. This observation correlates well with the increase seen in recovery tissues of large polyribosomes on which collagen precursor polypeptides are known to be synthesized. Preliminary characterization of the repair collagen synthesized by recovery animals showed it to be a typical Type I collagen having the chain composition (alpha(1))(2)alpha(2). The extent of glycosylation of the hydroxylysine of the newly synthesized collagen was greater than that reported for either normal guinea-pig dermal collagen or dermal scar collagen.