Effect of phase of growth and hyperlipidemic serum on the synthesis of collagen in rabbit aortic smooth muscle cells in culture

The aim of this study was to elucidate wheter long-term cultivation in the presence of hyperlipidemic serum is able to induce changes in the rate of synthesis of collagen and other proteins by arterial smooth muscle cells. Rabbit aortic medial cells were grown in 10% sera and their collagen and total protein synthesis were studied by incubation of the cells with radioactive proline. When the cells were grown in fetal calf serum, their collagen synthesis was low after trypsinization but reached a constant level in one week, whereafter it remained within 4--5% of total protein synthesis for up to 30 days. Cultivation in hyperlipidemic rabbit serum for up to 14 days caused an accumulation of lipid droplets in the cells, but there were no detectable changes in the rate of collagen of total protein synthesis when compared with cells grown in normal rabbit serum.     

The effect of intermittent changes in tension on protein and collagen synthesis in isolated rabbit muscles.

Isolated intact rabbit muscles were incubated in a medium containing radioactive proline. The rates of synthesis of collagen and total muscle protein after incubation with a constant tension or intermittent mechanical stretching were compared with the rates in vivo. Muscles incubated under a constant tension synthesized protein at 22% of the rate observed in vivo; intermittent mechanical stretching resulted in an increase of 73% in the rate of protein synthesis, to 38% of that found in vivo. Collagen synthesis was affected in the same way as total protein synthesis by both types of incubation, therefore the relative rates of collagen and total protein synthesis were unchanged. ATP concentration in the isolate muscles and the uptake of glucose from the medium were increased by intermittent mechanical stretching. Incubating the muscles with a gas phase containing 5% O2 decreased the rate of protein synthesis, abolished the effect of intermittent mechanical stretching, lowered the concentration of ATP and increased the lactate concentration. The rate of protein synthesis in muscles maintained with a constant or intermittently applied tension was not affected by a previous period of incubation with the other type of stimulus.     

Liver proline oxidase activity and collagen synthesis in rats with cirrhosis induced by carbon tetrachloride

In rats treated with CCl₄ for 7 weeks, liver proline oxidase activity was drastically reduced 24 h after the initial administration of the toxic agent and remained low throughout the treatment period. This was accompanied by a larger accumulation of added proline in the incubation medium and a lesser release of ¹⁴CO₂ from [¹⁴C]proline during incubation.Collagen synthesis by liver slices of CCl₄-treated rats increased in proportion to proline concentration, a plateau being reached at 0.48 mM proline. The plateau did not occur within the range studied with liver slices of normal liver.Increased collagen synthesis in vitro was accompanied by increased deposition of collagen in vivo only during the first 3 weeks of CCl₄ treatment. No further increase in liver collagen content occurred thereafter. Discontinuance of CCl₄-administration was followed by a return to normal of proline oxidase activity and in vitro collagen synthesis within 2 weeks. Nevertheless, collagen content remained elevated.The results suggest that proline oxidase activity, together with the previously shown increased formation of proline from precursor amino acids, may control the amount of proline available for collagen biosynthesis; and that the rate of degradation of collagen, perhaps by collagenase, may determine the levels of collagen remaining after discontinuance of CCl₄-administration.     

Compartmentalization of proline pools and apparent rates of collagen and non-collagen protein synthesis in arterial smooth muscle cells in culture.

Rates of collagen and non-collagen protein synthesis in rabbit arterial smooth muscle cells (SMC) were determined by using the specific (radio)activity of [3H]proline in the extracellular, intracellular, and prolyl-tRNA pools. The intracellular free proline specific activity was only 25% of the extracellular value in cultures incubated for 12 h in 0.25 mM-proline. The specific activity of prolyl-tRNA was less than 10% of the extracellular specific activity. Increasing the extracellular proline concentration 10-fold (to 2.5 mM), while keeping the extracellular specific activity of proline constant, resulted in equilibration of the specific activities of intracellular and extracellular free proline, but the specific activity of prolyl-tRNA remained at less than 10% of the extracellular specific activity. Therefore, calculated rates of collagen and non-collagen protein synthesis were greatly underestimated using the intracellular or extracellular specific activity of proline. SMC were also incubated with 0.1 mM-[14C]ornithine in 0.25 nM or 2.5 mM non-labelled proline to examine synthesis de novo of proline and prolyl-tRNA from ornithine. In SMC cultures containing 0.25 mM unlabelled proline, the specific activity of intracellular ornithine was approx. 45% of the extracellular specific activity, due to the production of unlabelled ornithine. The specific activity of ornithine-derived intracellular free proline in SMC incubated with 2.5 mM-proline was significantly lower than in SMC incubated in 0.25 mM-proline, due to the influx of unlabelled proline. However, a corresponding difference in the specific activity of [14C]prolyl-tRNA between SMC in 0.25 mM- or 2.5 mM-proline was not observed. Ornithine-derived [14C]proline was incorporated into proteins in a manner different from that of exogenously added radiolabelled proline. A much higher proportion of the proline synthesized de novo was channelled into collagen synthesis relative to total protein synthesis. Together, these results show that intracellular proline pools are highly compartmentalized in arterial SMC. They also suggest that proline synthesized from ornithine may enter a prolyl-tRNA pool separate from that of proline entering from the extracellular medium.     

Biosynthesis of basement membrane collagen by rabbit corneal endothelium in vitro.

The synthesis of collagen has been demonstrated in endothelial cells of Descemet's membrane isolated from rabbit cornea. Incorporation of [14C]proline and [14C]lysine into nondialyzable protein was measured in the medium and cell fraction after incubating Descemet's membrane for up to 5 hours. In the [14C]collagen synthesized by the endothelium, 15% of the hydroxy[14C]proline was present as the 3-isomer. About 98% of the hydroxy[14C]lysine in the 14C-labeled-protein found in the medium was glycosylated; 95% of the glycosylated hydroxy[14C]lysine was in the form of the disaccharide glucosyl-galactosyl-hydroxy[14C]lysine. Time course experiments with [14C]proline indicated that there was a delay of about 60 min before significant amounts of [14C]collagen were secreted into the medium. The initial polypeptides of [14C]collagen synthesized by the corneal endothelium had an apparent molecular weight of 155,000. The chemical and physical properties of the [14C]collagen synthesized by rabbit corneal endothelium are consistent with those of basement membrane collagen synthesized by other cell types.     

Measurement of the synthesis rates of collagens and total protein in rabbit muscle.

1. Collagen- and total-protein-synthesis rates were determined in rabbit muscle by continuous infusion of radioactive proline. 2. The precursor pool of free proline used for collagen synthesis was defined by measuring the specific radioactivity of hydroxy-proline in isolated type I procollagen. The specific radioactivities of type I procollagen were about 40% of those for free proline in the homogenate. 3. The mean ratio (+/- S.E.M.) between the fractional synthesis rates of muscle collagen and total protein was 0.99 +/- 0.10, where the total protein values were based on specific radioactivities of the homogenate free proline pools. 4. Types I, III and V collagen were solubilized by pepsin and isolated by fractional precipitation with NaCl. The fractional synthesis rates of types I and III collagens were very similar. Type V collagen samples had higher specific radioactivities than the other collagens, but this was not necessarily indicative of a higher rate of synthesis because of uncertainty about the cellular origin of this collagen and, hence, the specific radioactivity of its precursor proline pool.     

A study of the biosynthesis of collagenous and non-collagenous proteins and of the proline/hydroxyproline ratios of collagens isolated from embryonic tissues

1. After incubation of chick-embryo skin slices with [(14)C]proline for 2hr. the specific activities of [(14)C]proline and [(14)C]hydroxyproline in soluble and insoluble collagens and [(14)C]proline in non-collagenous proteins were determined as well as the total amounts of both imino acids in these proteins. On the basis of these results it was demonstrated that soluble collagens having a high proline/hydroxyproline ratio are contaminated with non-collagenous proteins. 2. It was found that, in the presence of a mixture of amino acids in the incubation medium, the rate of synthesis of soluble collagen is significantly decreased. 3. The metabolic activity of collagenous proteins is related to their solubility, but that of non-collagenous proteins is not.     

Fibroblastic cell cycling in collagen gels

Abstract. Quiescent C3H10T1/2 mouse fibroblasts resume DNA synthesis and proliferation following incubation in medium containing fresh serum both when grown in monolayer and when grown in a collagen matrix. We observed that the rate of DNA synthesis is reduced at high initial cell densities and low initial collagen concentrations. In a collagen matrix, fibroblasts contract the matrix causing an increase in cell density and collagen concentration. We studied the chronological relationship between the kinetics of DNA synthesis and the collagen matrix contraction. The rate of collagen collection per cell changes in time, dependent on initial cell and collagen concentration. The kinetics of the collagen collection showed a positive correlation with the kinetics of DNA synthesis, 16 h later.     

The embryonic rat parietal yolk sac. The role of the parietal endoderm in the biosynthesis of basement membrane collagen and glycoprotein in vitro.

Basement membrane biosynthesis in vitro was studied in a rapidly growing embryonic tissue, the rat parietal yolk sac. This tissue consists of a thick, nonvascular basement membrane (Reichert's membrane) separating two cellular layers (parietal endoderm and trophoblast). Morphologically, Reichert's membrane appeared similar to other basement membranes. Previous analysis of the amino acid and carbohydrate composition of acellular Reichert's membrane showed it to be typical of basement membranes isolated from other tissues and species. Analysis of [14-C]proline incorporation and hydroxy [14-C]proline synthesis during the third quarter ogestation in vitro showed that basement membrane collagen synthesis in the parietal yolk sac was maximal around the 14th day of gestation. At this time, basement membrane collagen represented nearly 10% of the newly synthesized protein. The collagen synthesized in this system was characteristic of basement membrane collagen in that about 11% of the total hydroxy [14-C]proline was present as the 3-isomer. In addition, after incubation in the presence of [14-C]lysine, 83 to 94% of the hydroxy[14-C]lysine was glycosylated, with the predominant form being glucosylgalactosylhydroxy[14-C]lysine. When the parietal endoderm and trophoblast were incubated separately with [14-C]proline, it was determined that the former was solely responsible for the synthesis of basement membrane collagen since essentially all of the 4-hydroxy[14-C]proline was associated with this cell type. Autoradiographic experiments with [3-H]glucosamine also served to localize the synthesis of noncollagen basement membrane glycoprotein components to the parietal endoderm. As with the results reported for basement membrane collagen secretion in embryonic chick lens cells, there appeared to be approximately a 60-min delay between the incorporation of [14-C]proline into protein and the secretion of collagen as measured by the appearance of 4-hydroxy[14-C]proline in the culture medium. Experiments utilizing [3H]glucosamine to monitor glycoprotein synthesis did not show a delay between the incorporation of [3H]glucosamine and the secretion of nondialyzable 3-H into the medium. The results obtained using the parietal yolk sac system to study basement membrane biosynthesis were compared to those previously obtained using the kidney glomerular and embryonic chick lens systems. It was concluded that the parietal yolk sac system is superior for a number of reasons: (a) the extracellular matrix appeared to contain only basement membrane components; there was no contamination by acid mucopolysaccharides or other types of collagen; (b) only a single cell type appeared to be responsible for the synthesis of basement membrane components; and (c) a relatively large percentage of the newly synthesized protein was basement membrane collagen.     

An N-terminal peptide from link protein can stimulate biosynthesis of collagen by human articular cartilage

Previous studies have shown that a peptide identical in sequence to the N-terminal of link protein can function as a growth factor and up-regulate proteoglycan synthesis by human articular cartilage in explant culture (L. A. McKenna et al., Arthritis Rheum. 41, 157-162, 1998). The present study has extended these investigations to determine the effects of this peptide on the synthesis of collagen, another essential component of normal cartilage matrix. Explants from normal adult knee cartilage were maintained for periods of up to 8 days in medium with or without serum. Peptides were added during each day of culture. Synthesis of collagen was determined by the incorporation of [3H]proline into hydroxyproline and proteoglycans by incorporation of [35S]sulfate. The type of newly synthesized collagen was measured by SDS-polyacrylamide gel electrophoresis, fluorography, and immunoblotting. The link protein peptide stimulated synthesis of type II collagen in cartilage from a number of different subjects. Maximum up-regulation of synthesis was attained at a concentration of 100 ng/ml, similar to that observed previously for up-regulation of proteoglycan. Synthesis was up-regulated in both the presence and the absence of serum, although the overall rate of synthesis was greater when serum was added. The findings that this link peptide growth factor stimulated synthesis of proteins, including collagen, in a manner analogous to that shown previously for proteoglycans support the hypothesis that this peptide may have an important role in the feedback control of cartilage matrix synthesis.     

Effects of preformed proline and proline amino acid precursors (including glutamine) on collagen synthesis in human fibroblast cultures

A technique of derivatizing proline and 4-hydroxyproline with 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole was used to measure the radioactivities, concentrations and specific activities of proline and hydroxyproline. The technique was used to study the conditions of procollagen synthesis in cultured human foreskin fibroblasts. Procollagen synthesis appeared to be independent of the proline concentration in the medium, in the presence of glutamine, when monitored by the assay of non-dialyzable hydroxyproline, but not when monitored by [14C]proline incorporation. In the absence of unlabelled proline added to labelled proline in the medium, the specific activity of the secreted procollagen did not reach a plateau over a 24-h period. When the medium was supplemented with glutamine, glutamic acid, or aspartic acid, both the radioactivity and concentration of intracellular free proline decreased. Pyrrolidone-2-carboxylic acid and ornithine both induced a slight increase in concentration of the intracellular free proline. Glutamine competed with [14C]proline for incorporation into prolyl-tRNA and procollagen, independently of free intracellular proline, and it stimulated the biosynthesis of procollagen (expressed as non-dialyzable hydroxyproline) by a factor of 2.3.     

The appearance of free hydroxyproline as the major product of degradation of newly synthesized collagen in cell culture

Embryonic lung fibroblasts and rabbit vascular smooth muscle cells have the ability to degrade newly synthesized collagen. Analysis of 24-h pulse media from cultures given [¹⁴C]proline demonstrates that greater than 90% of the degraded collagen is represented by free hydroxyproline rather than the peptide-bound imino acid. The addition of cycloheximide or α-α-dipyridyl to the culture medium during the pulse period severely diminished the formation of the free hydroxyproline demonstrating its enzymatic and protein (collagen) origin. It is proposed that assessment of free hydroxyproline formation may allow us to distinguish between intracellular and extracellular collagen degradation.     

Collagen degradation in human lung fibroblasts: extent of degradation, role of lysosomal proteases, and evaluation of an alternate hypothesis

Experiments were conducted to determine the extent and variability of collagen degradation in human fetal lung fibroblasts. Cells were incubated with [14C]proline, and degradation was measured by determining the hydroxy[14C]proline in a low molecular weight fraction relative to total hydroxy[14C]proline. Average (basal) degradation in stationary phase HFL-1 cells incubated for 8 h was 16 +/- 3%, and substantial alterations in the composition of the labeling medium, e.g., omitting serum and varying pH between 6.8 and 7.8, had no effect. Organic buffers slightly lowered degradation in a manner that was independent of pH. Collagen degradation in two other lung cell lines, Wl-38 and lMR-90, did not differ from the level in HFL-1. Degradation was significantly higher (23 +/- 5%) in HFL-1 cultures labeled for 24 h rather than 8 h, and pulse-washout experiments showed that the rate of degradation was not uniform: after an 8-h pulse, 11% of the hydroxy [14C]proline in the medium was in the low molecular weight fraction, but 31% was in this fraction after a 16-h washout. The lack of effect of either serum deprivation or elevated pH suggests that lysosomal proteases have no direct role in basal degradation; however, NH4Cl decreased the enhanced degradation observed in ascorbate deficiency to basal level, indicating that abnormal molecules synthesized under those conditions are degraded by lysosomal proteases. The appearance of small hydroxy[14C]proline-containing molecules was inhibited by alpha alpha'dipyridyl and cycloheximide in a dose-dependent and reversible manner, demonstrating that their production depends on enzymatic hydroxylation of proline and protein synthesis.     

Effect of beta-D-xylosides on collagen synthesis in cultured fibroblasts.

Cultured normal human skin fibroblasts were incubated with [¹⁴C]proline in the presence and absence of 1.0 mM p-nitrophenyl-β-D-xylose. Formation of non-dialyzable hydroxyproline was used as a measure of collagen synthesis. Although total [¹⁴C]proline incorporation was similar in the two cultures, [¹⁴C]hydroxyproline formation was significantly decreased in the β-xyloside-treated cultures. Increasing the period of incubation increased the radioactivity of the insoluble collagen fraction in untreated fibroblasts, however, in β-xyloside-treated cultures no such increase was observed. In contrast to the decreased production of collagen, growth of cells in the presence of the β-xyloside induced the synthesis of high levels of soluble glycosaminoglycans as measured by ³⁵SO₄ incorporation into isolated polysaccharide.     

Effects of prostaglandin E1 on collagen production and degradation in human fetal lung fibroblasts

We examined the effects of prostaglandin E1 on the production and degradation of collagen in human fetal lung fibroblasts. Percentage collagen production was determined by incubating confluent cultures for 6 h with [3H]proline and either [14C]glycine or [14C]leucine and measuring the relative amounts of radioactivity incorporated into collagenase-sensitive and collagenase-insensitive material. Percentage collagen degradation was determined by measuring hydroxy[14C]proline in a low-molecular-weight fraction relative to total hydroxy[14C]proline. Prostaglandin E1, when present at a concentration as low as 0.25 micrograms/ml, reduced net collagen production by a factor of one-half, from 8 +/- 2 to 4 +/- 1% (P less than 0.05). In contrast, the change in percentage degradation was relatively gradual, rising steadily from the control value of 15 +/- 2 to 33 +/- 2% at 4 micrograms/ml (P less than 0.05). The increase in degradation, while significant, could not account for the total decrease in collagen production. We conclude that prostaglandin E1 exerts its inhibitory effect on collagen production in two essentially independent ways: lowering the rate of synthesis and increasing intracellular degradation. However, the decrease in synthesis is greater than the increase in degradation.     

Modulation of types I and III procollagen synthesis at various stages of arterial smooth muscle cell growth in vitro

Collagen synthesis was monitored in cultures of rabbit arterial smooth muscle cells (SMC). Both the rate of collagen synthesis per cell and collagen synthesis as a percent of total protein synthesis were measured at specific intervals from 1 to 14 days after inoculation of smooth muscle cells. The proportions of types I and III collagen present in the conditioned incubation medium and in the cell layer were also examined. After inoculation the cells displayed population expansion typical of SMC in which growth slowed but did not cease after the cells attained confluence. Collagen synthesis rates, expressed as [14C]hydroxyproline per cell, were eight-fold higher in preconfluent cells. In these cultures collagen accounted for more than 20% of the newly synthesized, 14C-labeled protein present as trichloroacetic acid (TCA)-insoluble material in 24 h culture media. In post-confluent cultures, this percentage was reduced to about 7% of the total protein synthesized. Synthesis rates of both collagen and non-collagen protein decreased with increasing time after inoculation. However, the rate of decline of collagen synthesis was three times greater than that seen for non-collagen protein. Early cultures synthesized relatively more type I than type III procollagen. The type I to type III ratio was highest at day 3 and declined after that time to day 14. While the synthesis of both types decreased with increasing age, type I declined at a greater rate resulting in a predominance of type III procollagen secretion by older cultures. We conclude that protein synthesis in general and collagen synthesis in particular are quantitatively and qualitatively dependent upon the growth stage of SMC in vitro.     

Dexamethasone modulates the metabolism of type IV collagen and fibronectin in human basement-membrane-forming fibrosarcoma (HT-1080) cells.

The effect of dexamethasone on the synthesis and degradation of type IV collagen was studied in human fibrosarcoma cells, HT-1080. A dexamethasone concentration as low as 0.1 microM markedly increased collagen synthesis in HT-1080 cells labelled with [14C]proline. The increase in type IV collagen synthesis was not specific, since total protein synthesis was also increased. Further studies indicated that part of the increase was due to an increase in the specific radioactivity of the intracellular proline pool, after dexamethasone treatment. In fact, with dexamethasone concentrations of 0.1-10 microM the relative collagen synthesis was decreased, indicating that synthesis of other protein was increased more than that of type IV collagen. This was also confirmed by measuring the relative amount of type IV collagen RNA by using recombinant plasmid cDNA specific for the human procollagen pro alpha l (IV) RNA. The results indicated that relative collagen synthesis and the relative amount of type IV collagen messenger RNA was decreased similarly, indicating that dexamethasone affected type IV collagen synthesis at the pre-translational level. The dexamethasone-induced effect on total protein and collagen synthesis was maximal after 12-24 h. Dexamethasone induced a marked accumulation of collagen into the cell layer, leading to diminished deposition of soluble collagen into the medium. Since bacterial-collagenase treatment of the cell layer drastically decreased the collagen content of the dexamethasone-treated cells, this indicates that dexamethasone caused an accumulation of collagen into the extracellular matrix of the cell layer. In contrast, the amount of fibronectin was markedly increased in the medium. Dexamethasone decreased the type IV collagen-degrading activity in HT-1080 cells. The HT-1080 cells contained glucocorticoid receptors, as demonstrated by two different methods: by a whole-cell binding assay and by using a cytosol-gel-filtration method. The number of specific binding sites was similar to that in human skin fibroblasts. In conclusion, glucocorticoids affect the metabolism of type IV collagen and fibronectin in HT-1080 cells, and, since these cells contain specific glucocorticoid receptors, the effects are apparently receptor-mediated.     

Decreased extracellular matrix production in scurvy involves a humoral factor other than ascorbate

Our recent studies suggested that decreased collagen synthesis in bone and cartilage of scorbutic guinea pigs was not related to ascorbate-dependent proline hydroxylation. The decrease paralleled scurvy-induced weight loss and reduced proteoglycan synthesis. Those results led us to propose that the effects of ascorbate deficiency on extracellular matrix synthesis were caused by changes in humoral factors similar to those that occur in fasting. Here we present evidence for this proposal. Exposure of chick embryo chondrocytes to scorbutic guinea pig serum, in the presence of ascorbate, led to effects on extracellular matrix synthesis similar to those seen in scorbutic animals. The rates of collagen and proteoglycan synthesis were reduced to approximately 30-50% of the levels in cells cultured in normal guinea pig serum plus ascorbate, but proline hydroxylation and procollagen secretion were unaffected. Similar results were obtained with serum from fasted guinea pigs supplemented in vivo with ascorbate. The growth rate of the chondrocytes was not significantly affected by scorbutic guinea pig serum.