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 gycosylations 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 glucosylgalactosylhydroxylysine nevertheless seemed to be determined by the available acceptor sites, i.e., the amount of galactosylhydroxylysine. In further experiments with 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 hydrosylysyl galactosyltransferase is not saturating in respect of the catalyzed reaction. Experiments on the addition of Fe2+ or its chelation by alpha, alpha'-dipyridyl gave indications that the presence of this co-factor is not required for either glycosylation reaction in isolated tendon cells.

Evidence for a relative excess of lysyl hydroxylase in chick embryo tendon and cartilage compared with bone and skin.

Various chick embryo tissues were incubated in vitro with a range of Zn2+ concentrations, and inhibition of the hydroxylations of collagen proline and lysine residues was studied in the intact tissues. At an constant inhibition level of proline hydroxylation, lysine hydroxylation proved to be inhibited more in the skin and bone than in the tendon and cartilage. The ratios of lysyl hydroxylase to prolyl hydroxylase activity were also distinctly lower in the former than in the latter. The variations observed in the reduction of lysine hydroxylation by Zn2+ thus correlate well with the differences seen in the enzyme activity ratios. No differences are found in the Ki values for Zn2+ between purified prolyl and lysyl hydroxylases or between the same enzymes from different tissues, and consequently the differences in lysine hydroxylation inhibition between the various tissues cannot be explained by differences in the kinetic constants. Recent studies also suggest that the existence of tissue-specific lysyl hydroxylase isoenzymes is improbable. The data thus suggest that there is a relative excess of lysyl hydroxylase activity in tissues such as tendon and cartilage, in which the lysine hydroxylation was less sensitive to Zn2+ inhibition, compared with skin and bone, where lysine hydroxylation was inhibited to a greater extent. These data are in a good agreement with the findings concerning variation in the reduction in lysine hydroxylation in different tissues with age or in the Ehlers-Danlos Syndrome Type VI.

Effects of divalent cations on collagen biosynthesis in isolated chick embryo tendon cells.

Isolated chick embryo tendon cells were used in [14C]proline and [14C]lysine labelling experiments to investigate the effect of divalent cations on collagen biosynthesis with a special reference to prolyl hydroxylation and lysyl modifications. The following metals were studied by adding them to the incubation medium of the cells: Ca2+, Cd2+, Co2+, Hg2+, Mg2+, Mn2+, Ni2+, Pb2+ and Zn2+. Zn2+ caused a potent reductin in collagen prolyl hydroxylation with a concomitant increased cellular retention of collagenase-digestible material. These effects were detectable even at physiological concentrations. At the same concentrations of Zn2+, lysyl hydroxylation was considerably less inhibited than prolyl hydroxylation, and the extent of hydroxylysyl glycosylation was even increased. Co2+ was also an efficient inhibitor of collagen prolyl hydroxylation, but at concentrations ten times higher than those of Zn2+. In the presence of other metal ions, no or only up to 10% inhibition of prolyl hydroxylation was noted even at those concentrations at which [14C]proline incorporation into the protein was decreased. However, an increased cellular retention of collagen was detected in the presence of some metal ions. No reduction in lysyl hydroxylation was found in the presence of Ca2+ or Mg2+.

Affinity chromatography of collagen glucosyltransferase on a UDP-glucose derivative coupled to agarose.

UDP-glucuronic acid from the carboxyl group was coupled to agarose via a six-carbon atom spacer, and columns prepared from this material were used in an affinity chromatography of collagen glucosyltransferase. The enzyme was found to have a high affinity for such columns in the presence of Mn2+ in the buffer, whereas a considerably lower affinity was noted in the absence of such ions. The enzyme could be eluted from the column with either EDTA, UDP-glucose, or small peptides prepared from collagen, the peptides being the most effective eluting agent. After elution the enzyme was separated from the peptides by gel filtration. With this procedure a collagen glucosyltransferase putification of about 3000-fold was obtained from extract of chick embryos by relatively simple steps. Collagen galactosyltransferase was found to have no affinity for the column, suggesting that the binding was not only due to the UDP moiety, but that the uronic acid derivate of glucose also contributed to its specificity.

Differences between proline and lysine hydroxylations in their inhibition by zinc or by ascorbate deficiency during collagen synthesis in various cell types.

The addition of Zn2+ inhibited lysine hydroxylation markedly less effectively than it did proline hydroxylation in chick embryo tendon cells, 3T6 fibroblasts and lysyl hydroxylase-deficient Ehlers-Danlos Syndrome Type VI fibroblasts. With low Zn2+ concentrations, a similar difference was also seen in chick embryo cartilage cells, whereas with high concentrations both hydroxylations were affected to the same extent in this cell type. Ascorbate deficiency likewise had a much less effect on lysine than proline hydroxylation when studied with 3T6 fibroblasts. As these two effectors involve quite different mechanisms, it is suggested that relative insensitivity to inhibition may be a property of lysine hydroxylation seen in many cell types with a number of agents. Studies on the mechanism of the difference in the inhibition indicates that the phenomenon is probably not due to differences in the kinetic constants of Zn2+ and ascorbate for the two enzymes. Neither is it probably to any major extent due to delayed procollagen triple helix formation nor a difference in the location of the two hydroxylases within the cisternae of the rough endoplasmic reticulum. The difference similarly cannot be explained solely by an excess of lysyl hydroxylase in the cell. It may thus be due either to some other intracellular property or to the combined effect of several factors.

Isolation of collagen glucosyltransferase as a homogeneous protein from chick embryos.

Collagen glucosyltransferase was isolated as a homogeneous protein from chick embryos by a procedure consisting of ammonium sulphate fractionation, two affinity chromatographies and two gel filtrations. The specific activity of the purified enzyme was 32,000 times that of the 15,000 x g supernatant of the embryo homogenate, and the enzyme was pure when examined by sodium dodecyl sulphate polyacrylamide gel electrophoresis using three different gel compositions. The molecular weight of the enzyme was about 72,000-78,000 by sodium dodecyl sulphate polyacrylamide gel electrophoresis, the value being dependent on the gel composition. The apparent molecular weight by gel filtration was dependent on the purity and protein concentration. The sedimentation coefficient S20,w was 4.7. The data suggest that the enzyme molecule consists of one polypeptide chain.

Affinity chromatography of lysyl hydroxylase on concanavalin A-agarose.

Lysyl hydroxylase (peptidyllysine, 2-oxoglutarate: oxygen 5-oxidoreductase, EC 1.14.11.4) has a high affinity for columns of concanavalin A-agarose, which was markedly reduced in the presence of alpha-methyl-D-mannoside, suggesting that the enzyme is a glycoprotein. Once bound, the enzyme could not be eluted with the glycoside alone, whereas an effective elution was achieved by a combination of alpha-methyl-D-mannoside and ethylene glycol. The data thus suggest that hydrophobic interaction stabilized the complex of the enzyme with the column. This information was applied to obtain a lysyl hydroxylase purification of about 3000-fold with a recovery of more than 10% from extract of chick embryos by relatively simple steps.

Age-related changes in human skin collagen galactosyltransferase and collagen glucosyltransferase activities.

Collagen galactosyltransferase and collagen glucosyltransferase activities were assayed in human skin specimens of about 100 mg wet weight. The assay of the glucosyltransferase activity was found to be highly specific. The assay of the galactosyltransferase activity was somewhat less specific, but there was no difference in specificity between the foetal and adult human skin samples. The activities of the two collagen glycosyltransferases in human skin extract were found to vary with age, being highest in foetal skin, and higher in the skin of young children that in that of adults. The galactosyltransferase and glucosyltransferase activities in foetal skin were respectively about 4 times and 6 times those in adult skin. The magnitudes of the changes with age in the two collagen glycosyltransferase activities were smaller than those occurring in the activities of the two other intracellular enzymes of collagen biosynthesis namely prolyl and lysyl hydroxylase. This difference suggests that the four intracellular enzyme activities of collagen biosynthesis are not regulated in an identical manner.

Elevated serum galactosylhydroxylysyl glucosyltransferase, a collagen synthesis marker, in fibrosing lung diseases.

The activity of galactosylhydroxylysyl glucosyltransferase, an enzyme catalyzing collagen biosynthesis, was measured in the sera of 101 patients with various pulmonary diseases to study whether detectable enzyme amounts are liberated into the serum from the lung tissue, and whether this is associated with the development of lung fibrosis. Increased serum galactosylhydroxylysyl glucosyltransferase activity was found in all the patients with progressive pulmonary fibrosis and in about half of the patients with acute stages of farmer's lung and infectious pneumonia. In one third of the patients with stage I sarcoidosis the serum enzyme activity was slightly increased, whereas in bronchial asthma and chronic bronchitis the values were mostly within the normal range. In conclusion, elevated serum enzyme activity was demonstrated in connection with those respiratory diseases in which pulmonary fibrosis was already verifiable or relatively often develops later. Measurements of serum galactosylhydroxylysyl glucosyltransferase may, thus, be useful in evaluating actual lung collagen synthesis in human pulmonary diseases.

Stimulation of collagen galactosyltransferase and glucosyltransferase activities by lysophosphatidylcholine.

Lysophosphatidylcholine stimulated the activities of collagen galactosyl- and glucosyl-transferases in chick-embryo extract and its particulate fractions in vitro, whereas essentially no stimulation was noted in the high-speed supernatant, where the enzymes are soluble and membrane-free. The stimulatory effect of lysophosphatidylcholine was masked by 0.1% Triton X-100. In kinetic experiments lysophosphatidylcholine raised the maximum velocities with respect to the substrates and co-substrates, whereas no changes were observed in the apparant Km values. Phospholipase A preincubation of the chick-embryo extract resulted in stimulation of both transferase activities, probably gy generating lysophosphatides from endogenous phospholipids. No stimulation by lysophosphatidylcholine was found when tested with 500-fold-purified glycosyltransferase. The results suggest that collagen glycosyltransferases must be associated with the membrane structures of the cell in order to be stimulated by lysophosphatidylcholine. Lysophosphatidylcholine could have some regulatory significance in vivo, since its concentration in the cell is comparable with that which produced marked stimulation in vitro.

Further characterization of galactosylhydroxylysyl glucosyltransferase from chick embryos. Amino acid composition and acceptor specificity.

A modified purification procedure, consisting of affinity chromatographies on concanavalin A-agarose, collagen-agarose and UDP-glucose-derivative-agarose and one gel filtration, is reported for galactosylhydroxylysyl glucosyltransferase. The enzyme obtained is entirely pure when studied by sodium dodecyl sulphate/polyacrylamide-gel electrophoresis. The enzyme protein was rich in glutamic acid + glutamine, aspartic acid + asparagine, glycine and alanine. The enzyme catalysed no significant glucose transfer to any of the glycoproteins tested, except for collagens. This included all the glycoproteins that have previously served as glucosyl acceptors for impure enzyme preparations, thus indicating a high degree of specificity of the enzyme for galactosylhydroxylysine. Galactosylsphingosine would act as a glucosyl acceptor, however. This compound has a close structural similarity to galactosylhydroxylysine in that they both have an unsubstituted amino group next to the hydroxy group to which the galactose is attached.

Serum galactosylhydroxylysyl glucosyltransferase in acute myocardial infarction and during subsequent collagen scar formation.

Changes in serum galactosylhydroxylysyl glucosyltransferase, an enzyme catalysing one of the intracellular post-translational modifications in collagen biosynthesis, were studied in twenty-four patients with acute myocardial infarction. The enzyme activity was monitored for 18 days from the onset of infarction, and at least a two-peaked pattern was observed. The first peak corresponded to the stage of acute myocardial injury, there being a highly significant correlation between the maximal values for serum glucosyltransferase and alpha-hydroxybutyrate dehydrogenase. An average decreasing in serum glucosyltransferase activity of 41%, was noted during the following 24 h. A new gradual rise in serum glucosyltransferase activity, interpreted as indicating myocardial collagen scar formation, was observed 5 days after the onset of infarction, when the serum enzyme activities indicating myocardial injury had already declined. The average daily values for serum glucosyltransferase between 6 and 18 days correlated highly significantly with the maximal value for serum alpha-hydroxybutyrate dehydrogenase, which serves as a relative estimate of the size of the original myocardial infarction area. The data further suggest that certain other factors including heart failure and/or various drug treatments may also affect the magnitude of this second peak.

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.

Intracellular enzymes of collagen biosynthesis in human platelets.

Activities of four intracellular enzymes of collagen biosynthesis--prolyl hydroxylase, lysyl hydroxylase, collagen galactosyltransferase, and collagen glucosyltransferase--were demonstrated in human platelets, and the presence of prolyl hydroxylase protein was further demonstrated by direct radioimmunoassay. The ratio of the specific activities of the four enzymes in the four enzymes in the human platelet extract to those in human adult skin extract varied from about 0.1 to 1, the lowest relative activity being found with prolyl hydroxylase and the highest with collagen glucosyltransferase. Only a very small amount of prolyl hydroxylase protein, probably 1%, was in the form of the active enzyme tetramer. The collagen glucosyltransferase from human platelets readily glucosylated galactosylhydroxylysine in denatured collagen, but did not glucosylate native collagen. Also, native collagen did not act as an inhibitor of the glucosylation reaction. Therefore, platelet collagen glucosyltransferase cannot form either an enzyme--substrate complex or an enzyme--inhibitor complex with native collagen. The results thus argue against the theory which maintains that platelet collagen glucosyltransferase is involved in collagen--platelet adhesion.

Effect of L-azetidine-2-carboxylic acid on glycosylations of collagen in chick-embryo tendon cells.

The glycosylations of hydroxylysine during collagen biosynthesis in isolated chick-embryo tendon cells were studied by using pulse-chase labelling experiments with [14C]-lysine. The hydroxylation of lysine and the glycosylations of hydroxylysine continued after a 5 min pulse label for up to about 10 min during the chase period. These data differ from those obtained previously in isolated chick-embryo cartilage cells, in which, after a similar 5 min pulse label, these reactions continued during the chase period for up to about 20 min. The collagen synthesized by the isolated chick-embryo tendon cells differed markedly from the type I collagen of adult tissues in its degree of hydroxylation of lysine residues and glycosylations of hydroxylysine residues. When the isolated tendon cells were incubated in the presence of L-azetidine-2-carboxylic acid, the degree of glycosylations of hydroxylysine during the first 10 min of the chase period was identical with that in cells incubated without thcarboxylic acid for at least 60 min, whereas no additional glycosylations took place in the control cells after the 10 min time-point. As a consequence, the collagen synthesized in the presence of this compound contained more carbohydrate than did the collagen synthesized by the control cells. Additional experiments indicated that azetidine-2-carboxylic acid did not increase the collagen glycosyltransferase activities in the tendon cells or the rate of glycosylation reactions when added directly to the enzyme incubation mixture. Control experiments with colchicine indicated that the delay in the rate of collagen secretion, which was observed in the presence of azetidine-2-carboxylic acid, did not in itself affect the degree of glycosylations of collagen. The results thus suggest that the increased glycosylations were due to inhibition of the collagen triple-helix formation, which is known to occur in the presence of azetidine-2-carboxylic acid.

Hydroxylation of lysine and glycosylation of hydroxylysine during collagen biosynthesis in isolated chick-embryo cartilage cells.

Hydroxylation of lysine and glycosylation of hydroxylysine during collagen biosynthesis in isolated chick-embryo cartilage cells were studied by using continuous labelling and pulse-chase labelling experiments with [14C]lysine. Control experiments with [14C]proline indicated that in continuous labelling the hydroxylation of [14C]proline became linear with time after about 4 min and the secretion of collagen after about 35 min, as reported previously. In similar experiments with [14C]lysine the hydroxylation of [14C]lysine and the glycosylations of hydroxy[14C]lysine became linear at about 4 min, suggesting that these reactions were initiated while the polypeptide chains were growing on the ribosomes. Pulse-chase labelling experiments with [14C]lysine indicated that after a 5 min pulse-label the hydroxylation of [14C]lysine and the glycosylations of hydroxyl[14C]lysine continued during the chase period for about 20 min. The data suggest that these reactions are continued after the release of complete polypeptide chains into the cisternae of the endoplasmic reticulum, whereas the reactions are probably not continued after the formation of the triple helix and the movement of the molecules into the Golgi vacuoles.

Prolonged exercise causes an increase in the activity of galactosylhydroxylysyl glucosyltransferase and in the concentration of type III procollagen aminopropeptide in human serum.

The effect of prolonged heavy physical exercise on serum galactosylhydroxylysyl glucosyltransferase activity (S-GGT) and serum type III procollagen aminoterminal propeptide (S-Pro(III)-N-P) concentration was studied in healthy male long-distance runners. S-GGT increased gradually by about 70% (p less than 0.01) during a competitive 24-h run, and a rising trend was also observed in S-Pro(III)-N-P. After the termination of the run S-GGT was normalized in two days, but the increase in S-Pro(III)-N-P continued up to one day after the race, reaching nearly 40% (p less than 0.005). The alterations in S-GGT and S-Pro(III)-N-P showed no significant correlation with S-CK, S-LDH or the distance run. The most likely explanation for the increases in S-GGT and S-Pro(III)-N-P is that prolonged heavy exercise injures the collagen-synthesizing cells of the connective tissue, leading to a short-term increase in type III procollagen production.