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.     

Further studies on the effect of the collagen triple-helix formation on the hydroxylation of lysine and the glycosylations of hydroxylysine in chick-embryo tendon and cartilage cells

The hydroxylation of lysine and glycosylations of hydroxylysine were studied in isolated chick-embryo tendon and cartilage cells under conditions in which collagen triple-helix formation was either inhibited or accelerated. The former situation was obtained by incubating the tendon cells with 0.6mm-dithiothreitol, thus decreasing their proline hydroxylase activity by about 99%. After labelling with [(14)C]proline, the formation of hydroxy[(14)C]proline was found to have declined by about 95%. Since the hydroxylation of a relatively large number of proline residues is required for triple-helix formation at 37 degrees C, the pro-alpha-chains synthesized under these conditions apparently cannot form triple-helical molecules. Labelling experiments with [(14)C]lysine indicated that the degree of hydroxylation of the lysine residues in the collagen synthesized was slightly increased and the degree of the glycosylations of the hydroxylysine residues more than doubled, the largest increase being in the content of glucosylgalactosylhydroxylysine. Recovery of chick-embryo cartilage cells from temporary anoxia was used to obtain accelerated triple-helix formation. A marked decrease was found in the extent of hydroxylation of the lysine residues in the collagen synthesized under these conditions, and an even larger decrease occurred in the glycosylations of the hydroxylysine residues. The results support the previous suggestion that the triple-helix formation of the pro-alpha-chains prevents further hydroxylation of lysine residues and glycosylations of hydroxylysine residues during collagen biosynthesis.     

The intracellular location of the glycosylation of hydroxylysine of collagen.

The subcellular location at which hydroxylysine residues of collagen are glycosylated was studied in chick embryo fibroblasts. Ribosomes were isolated from ¹⁴C-lysine pulse-labeled cells in tissue culture. Alkaline hydrolysis followed by amino acid analysis and scintillation counting of the effluent showed that glucosylgalactosyl hydroxylysine and galactosyl hydroxylysine as well as hydroxylysine and lysine were the major ¹⁴C-labeled components. Acid hydrolysis destroyed the glycoconjugates and yielded only free ¹⁴C-hydroxylysine and ¹⁴C-lysine. These data indicate that glycosylation of peptide-bound hydroxylysine is initiated while the polypeptide chain is still in the stages of assembly on the ribosome.     

Regulation of the glycosylations of collagen hydroxylysine in chick embryo tendon and cartilage cells

The regulation of the glycosylations of hydroxylysine was studied in isolated chick-embryo cells by labelling with a [¹⁴C]lysine pulse. The course of the procollagen lysyl modifications was compared in tendon and cartilage cells, and the effect on the glycosylations of the degree of lysyl hydroxylation and the concentration of Mn²⁺ and Fe²⁺ were also studied, in tendon cells. Procollagen triple helix formation was inhibited in most experiments in order to eliminate the effect of this process on the continuation of the reactions.Both in the tendon and cartilage cells the intracellular lysyl modifications proceeded in a biphasic fashion. After an initial sharp linear increase, the reactions did not cease but were protracted at a slower but constant rate. Lysyl hydroxylation was followed by rapid galactosylation in both cell types and this was followed almost immediately by rapid glucosylation, suggesting a close association of the corresponding enzymes. The data further suggest that other factors must also exist, in addition to the differences in the timing of triple helix formation and the actual hydroxylysine content, which are responsible for the different amounts of galactose in the collagens synthesized by these cell types. The amount of glycosylgalactosylhydroxylysine nevertheless seemed to be determined by the available acceptor sites, i.e., the amount of galactosylhydroxylysine.In further experiments wiht tendon cells the oxygen participating in lysyl hydroxylation was displaced by nitrogen at various points in time. When the degree of lysyl hydroxylation was reduced to less than one-third of the original, the total amounts of glycosylated residues decreased correspondingly, but their proportion relative to total hydroxylysine remained unchanged.Extra Mn²⁺ increased the proportion of galactosylated hydroxylysine, suggesting that the activity of hydroxylysyl galactosyltransferase is not saturating in respect of the catalyzed reaction. Experiments on the addition of Fe²⁺ or its chelation by α, α′-dipyridyl gave indications that the presence of this co-factor is not required for either glycosylation reaction in isolated tendon cells.     

Regulation of collagen post-translational modification in transformed human and chick-embryo cells.

Changes in the regulation of collagen post-translational modification in transformed cells were studied in three established human sarcoma cell lines and in chick-embryo fibroblasts freshly transformed by Rous sarcoma virus. The collagens synthesized by all but one of these and by all the control human and chick-embryo cell lines were almost exclusively of types I and/or III. The relative rate of collagen synthesis and the amounts of prolyl hydroxylase activity and immunoreactive protein were markedly low in all the transformed human cell lines. The other enzymes studied, lysyl hydroxylase, hydroxylysyl galactosyltransferase and galactosylhydroxylysyl glucosyltransferase, never showed as large a decrease in activity as did prolyl hydroxylase, suggesting a more efficient regulation of the last enzyme than of the three others. The chick-embryo fibroblasts freshly transformed by Rous sarcoma virus differed from the human sarcoma cells in that prolyl hydroxylase activity was distinctly increased, whereas the decreases in immunoreactive prolyl hydroxylase protein and the three other enzyme activities were very similar to those in the simian-virus-40-transformed human fibroblasts. It seems possible that this increased prolyl hydroxylase activity is only a temporary phenomenon occurring shortly after the transformation, and may be followed by a decrease in activity later. The newly synthesized collagens of all the transformed cells that produced almost exclusively collagen types I and/or III had high extents of lysyl hydroxylation, and there was also an increase in the ratio of glycosylated to non-glycosylated hydroxylysine. The data suggest that one critical factor affecting modification is the rate of collagen synthesis, which affects the ratio of enzyme to substrate in the cell.     

The biosynthesis of cartilage type collagen during limb regeneration in the larval salamander

In order to determine the relationships between the biosynthesis of cell-specific products and the morphological and cytological appearance of cells, the synthesis of cartilage type collagen was examined during different stages of regeneration of larval amphibian limbs. We have found that during blastemal formation, chondrocytes cease their synthesis of detectible levels of cartilage type collagen. This was accomplished by analyzing the radioactively labeled collagens synthesized in short-term culture by pieces of limbs containing a cross section of all limb tissues present, and comparing these collagens to the collagens synthesized by blastemas from corresponding limbs. The labeled collagens were extracted, purified, and analyzed by chromatography on carboxymethyl cellulose columns. Whereas all of the pieces of limbs analyzed, either before regeneration was initiated or after redifferentiation of cartilage had begun, synthesized clearly detectible levels of cartilage type collagen, none of the blastemas produced detectible levels of this cartilage-specific molecule. Thus, it seems that the normal production of (α1)₃, cartilage type collagen, is inhibited during the blastemal stage of amphibian limb regeneration.     

Labelling of prolyl hydroxylase tetrameric subunits in freshly isolated chick-embryo tendon cells and in certain chick-embryo tissues in vivo.

Diadenosine 5',5"'-P1,P4-tetraphosphate (Ap4A) may be formed in the back reaction of the amino acid-activation reaction [Zamecnik, Stephenson, Janeway & Randerath (1966) Biochem. Biophys. Res. Commun. 24, 91-98]. On the basis of a number of observations of the properties of Ap4A it has been suggested that it may have a signal function for the initiation of DNA replication in eukaryotic cells] Grummt (1978) Proc. Natl. Acad. Sci. U.S.A. 75, 371-375]. In the present paper human platelets have been shown to contain relatively large amounts of Ap4A. The compound is apparently metabolic inactive in platelets, but it is almost quantitatively released when platelets are activated to aggregate by treatment with thrombin. The results are discussed in connection with the known growth-stimulating activity of platelets.     

Hydroxylation in isolated liver cells]

Ethylenediamine tetraacetate and mechanical treatment were applied to obtain the isolated hepatocytes. Oxidative phosphorylation was found to be preserved in the isolated cells. Hepatocytes were capable of hydroxylation of dimethylaniline (DMA), ethylmorphine and aminopyrine. VMAX for the hydroxylation of DMA calculated as per 1 nmol of the cytochrome P--450 was higher in the cells than in the microsomes. NADH formed during the oxidation of glutamate and malate can be used for hydroxylation.     

Purification and characterization of the low-molecular-mass (type X) collagen from chick-embryo tibial cartilage

Type X collagen, synthesized in large amount by cultured tibial chondrocytes, is deposited in vivo in the epiphyseal cartilages of 17-day-old chick embryo tibiae. Here we report the extraction of this collagen from these cartilages by limited pepsin digestion and its purification to electrophoretic homogeneity by salt precipitation followed by agarose gel filtration. Identity of the collagen purified from cartilage with the type X collagen synthesized by cultured chondrocytes is confirmed by comparison of the amino acid compositions. The high glycosylation extent of type X collagen is reminiscent of the glycosylation extent of pericellular collagens. The possible role of type X collagen is discussed.     

Age-related variations in glycosylation of hydroxylysine in human and rat skin collagens.

The extent of glycosylation of hydroxylysine in human skin collagen rapidly decreased during maturation and then gradually increased in proportion to the age. This decrease of glycosylation observed during maturation was also confirmed in whole, soluble and insoluble collagens from rat skin. These findings may contribute to the investigations on the functional role of glycosylation and also on the mechanism of maturational as well as senile processes.     

Dynamic change in promoter activation during lysine biosynthesis in Escherichia coli cells

We investigated the expression dynamics of genes involved in lysine biosynthesis in Escherichia coli cells to obtain a quantitative understanding of the gene regulatory system. By constructing reporter strains expressing the green fluorescence protein (gfp) gene under the control of the promoter regions of those genes associated with lysine biosynthesis, time-dependent changes in gene expression in response to changes in lysine concentration in the medium were monitored by flow cytometry. Five promoters involved in lysine biosynthesis respond to the changes in lysine concentration in the medium. For these five promoters, time-dependent gene expression data were fitted to a simple dynamical model of gene expression to estimate the parameters of the gene regulatory system. According to the fitting parameters, dapD shows a significantly larger coefficient of repression than the other genes in the lysine synthesis pathway, which indicates the weak binding activity of the repressor to the dapD promoter region. Moreover, there is a trend that the closer an enzyme is to the start of the lysine biosynthesis pathway, the smaller its maximal promoter activity is. The results provide a better quantitative understanding of the expression dynamics in the lysine biosynthesis pathway.     

Acid mucopolysaccharides of chick-embryo cartilage in osteolathyrism

1. In view of the suggested association between collagen and acid mucopolysaccharides in the connective tissues, this study was designed to see whether the lathyrus factor, beta-aminopropionitrile, affected the acid mucopolysaccharides as well as inhibiting the normal polymerization of collagen. The changing pattern of these two components of cartilage from normal and lathyritic chick embryos aged 14-20 days is described. The chondroitin sulphates and their protein complexes have been isolated from these cartilages, characterized and compared, particularly with respect to their sulphate content; no significant differences in quality or quantity were detectable. 2. Saline extracts of normal and lathyritic cartilages were also compared; whereas the collagen content of lathyritic extracts was increased to ten times that in the normal, the acid mucopolysaccharide content of both extracts was always the same. 3. It therefore appears that in the chick embryo beta-aminopropionitrile does not affect the acid mucopolysaccharides of the developing cartilage.