Synthesis and degradation of collagens in skin of healthy and protein-malnourished rats in vivo, studied by 18O2 labelling.

To explore the effects of growth retardation, caused by restricted protein intake, on collagen turnover in the whole skin, Sprague-Dawley rats (n = 20) were labelled with 18O2 and fed on either an adequate (18%) or a low (3%) lactalbumin diet. Skin biopsies were obtained at intervals during the following 6 months. Independent groups of animals (n = 186) were used to determine the size of the 0.5 M-acetic acid-soluble and -insoluble collagen pools in the entire skin of healthy and malnourished rats. Collagen was estimated by measurement of hydroxyproline. Soluble-collagen synthesis rates were equivalent to 99 +/- 8 mumol of hydroxyproline/day in healthy animals and 11 +/- 2 mumol/day in malnourished rats. Insoluble-collagen synthesis rates were 32 and 5 mumol of hydroxyproline/day in the healthy and protein-depleted rats respectively. The degradation of soluble collagen amounted to 37 +/- 8 and 6 +/- 2 mumol of hydroxyproline/day in the healthy and malnourished groups respectively. Efflux of collagen from the soluble collagen, defined as the sum of the rate of soluble collagen that is degraded plus that which matures into insoluble collagen, was 70 +/- 8 and 11 +/- 2 mumol of hydroxyproline/day in the healthy and malnourished groups respectively. Insoluble collagen was not degraded in either group. The fraction of soluble collagen leaving the pool that was converted into insoluble collagen was 0.46 in both diet groups. It is concluded that the turnover of soluble collagen is markedly decreased with malnutrition, but degradation and conversion into insoluble collagen account for the same proportions of efflux from the soluble-collagen pool as in rapidly growing rats.     

Quantitative and metabolic changes of hepatic collagens in rats after carbon tetrachloride poisoning

1. The collagen hydroxyproline in rat liver was composed of 3.5% neutral-soluble collagen, 4.9% acid-soluble collagen and 91.6% insoluble collagen. In labelling studies with [(14)C]proline in vitro, the specific radioactivities of neutral-soluble, acid-soluble and insoluble collagens in rat liver were found to be 233000, 69000 and 830d.p.m./mumol of hydroxyproline respectively after 1h. 2. During subacute carbon tetrachloride poisoning the hepatic content of insoluble collagen markedly increased, whereas those of soluble collagens did not change. During recovery from subacute poisoning hepatic contents of soluble collagens were markedly decreased. 3. After 8 weeks of carbon tetrachloride poisoning the specific radioactivities of hepatic soluble collagens increased, while that of insoluble collagen decreased. During recovery from subacute poisoning, the specific radioactivities of soluble collagens decreased to the normal range and that of insoluble collagen further decreased. 4. Hepatic collagenolytic activity solubilizing insoluble collagen, which differs from mammalian collagenase, decreased under the conditions of the subacute poisoning and also during recovery from subacute poisoning.     

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.     

Influence of bleomycin on the metabolism of dermal collagen in albino rats

The metabolism of collagen in male rats by treatment with bleomycin was studied following the injection of [3H]proline and the determination of specific and total activity of [3H]hydroxyproline in skin collagen fractions and urine. In the case of the bleomycin-treated animals, there was found to be an increase in the neutral salt soluble collagen content with no change in insoluble collagen content as compared to the control group. The specific and total radioactivity of [3H]hydroxyproline in soluble and insoluble collagen fractions was also increased. Examination of [3H]hydroxyproline activity in soluble and insoluble collagen showed that the conversion of soluble to insoluble collagen was improved by the bleomycin-treated group. It was found that this was accompanied by a decrease in urinary excretion of total hydroxyproline and [3H]hydroxyproline during the first 12 hr after the administration of [3H]proline. Therefore, the results of the present investigation clearly indicate that the maturation of soluble to insoluble collagen is promoted and accompanied by a decrease in the catabolism of soluble collagen in the bleomycin-treated animals. In addition, administration of bleomycin increased the synthesis of collagen.     

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.     

Proline recycling during collagen metabolism as determined by concurrent 18O2- and 3H-labeling

In a previous study where rat skin collagen was labeled with ¹⁸O in the hydroxyl group of the collagen hydroxyproline we noticed that the decay rate of this label was much faster than had been observed when the skin collagen hydroxyproline was labeled with ³H in the prolyl ring. In this study a rat was labeled concurrently with [¹⁸O₂] and [³H] proline and the rate of decline of both labels was determined in rat skin collagen hydroxyproline. After correction for growth dilution of the skin collagen the [¹⁸O] hydroxyproline was found to have a half-life of 27 days while the [³H] hydroxyproline had a half-life of 53 days. The decay rate of the [¹⁸O] hydroxyproline represents the true turnover rate of collagen since there is no possibility of recycling this label. Hence, the difference between this and the [³H] hydroxyproline decay rate is due to recycling of l-[³H] proline into new collagen. The efficiency of recycling of proline from catabolized collagen into new collagen was about 93%.     

Activation of collagen synthesis in primary culture of rat liver parenchymal cells (hepatocytes)

An increase in collagen synthesis by hepatic parenchymal cells (hepatocytes) was observed during 8 days in primary culture by the quantification of total [3H]hydroxyproline as a marker of total collagen synthesis and the ratio of [3H]hydroxyproline in the high-molecular-weight fraction to total [3H]hydroxyproline as a marker of collagen degradation after incubation of the cells with [3H]proline for 24 h. Type analysis of the collagen produced by the cells after 8 days in culture showed the presence of type I and type III collagens in addition to the components corresponding to type IV and type V (alpha A and alpha B) collagens. Only the latter two types were found in the collagens produced by the cells after 2 days in primary culture. The purity of the hepatocytes inoculated was 97%, and the majority of the contaminating small cells were erythrocytes. The rate of serum albumin synthesis, which is a typical function of the hepatocytes, was constant or increased during the culture period. Immuno-electron microscopic observation indicated the production of type I collagen by the hepatocytes after 8 days in primary culture. These results are explained only by the activation of collagen synthesis in the day-8 hepatocytes in primary culture.     

Rates of collagen synthesis in lung, skin and muscle obtained in vivo by a simplified method using [3H]proline.

Methods for measurement of rates of collagen synthesis in vivo have thus far been technically difficult and often subject to quite large errors. In this paper a simplified method is described for obtaining synthesis rates of collagen and non-collagen proteins, for tissues of rabbits. This involves an intravenous injection of [3H]proline, administered with a large dose of unlabelled proline, and measurement of the specific radioactivity of proline and hydroxyproline in body tissues up to 3 h later. The specific radioactivity of [3H]proline in plasma and the tissue free pools rises rapidly to a plateau value which is maintained for at least 2 h, when the specific radioactivity of the type I collagen precursors, isolated from the skin, was similar to that of the plasma and tissue-free pool. Furthermore, over this period, the increase in the specific radioactivity of proline in collagen and non-collagen protein was linear with respect to time. These results suggest that the large dose of proline floods the precursor pools for protein synthesis, and that this effect can be maintained for quite long periods of time. Such kinetics greatly simplified the method for obtaining collagen synthesis rates in vivo, which were calculated for lung, heart, skin and skeletal muscle, and shown to be quite rapid, ranging between about 3 and 10%/day. The lung was a particularly metabolically active tissue, with synthesis rates of about 10%/day for collagen and 35%/day for total non-collagen proteins, indicating rapid turnover of both intracellular and extracellular proteins of this tissue.     

Metabolism of rabbit skin collagen. Differences in the apparent turnover rates of type-I- and type-III-collagen precursors determined by constant intravenous infusion of labelled amino acids.

Growing rabbits were infused for up to 10 h with labelled proline, tyrosine and leucine to achieve plateau conditions within body free pools, for [3H]proline infusion, blood free-proline specific radioactivity remained constant after about 1 h. For individual animals, type-I- and type-III-collagen precursors were isolated by precipitation with (NH4)2SO4 and DEAE-cellulose chromatography. Experiments where 3H- and 14C-labelled proline and tyrosine were infused concurrently for different periods of time showed that type I procollagen reached plateau specific radioactivity within 3 h and 90% of the plateau value after 2 h infusion, corresponding to a calculated apparent t 1/2 of less than 26 min. Plateau values for type I procollagen were taken as precursor amino acid pool specific radioactivities. The type-III-collagen-precursor fractions consistently showed lower rates of label incorporation and, by assuming that both type I and type III collagens are synthesized from the same amino acid pools, kinetic analysis revealed an apparent t 1/2 for the isolated type-III-collagen precursors of 3.9 h. For proline, there were large variations between animals in the ratio between the precursor pool for collagen synthesis and the skin homogenate free pool (0.31 +/- 0.13, mean +/- S.D.), so that collagen-synthesis rates based solely on total tissue free-pool values for proline are subject to large and inconsistent errors.     

Studies in vivo on the biosynthesis of collagen and elastin in ascorbic acid-deficient guinea pigs. Evidence for the formation and degradation of a partially hydroxylated collagen

1. After the administration of l-[G-(3)H]proline to guinea pigs deprived of ascorbic acid for increasing periods of time, the specific radioactivities of proline and hydroxyproline in skin collagen and aortic elastin were determined at various time-intervals after administration of the labelled compound with a view to studying the formation and degradation of collagen and elastin both deficient in hydroxyproline. 2. As judged from the incorporation of radioactivity into elastin proline, elastin synthesis was not decreased in the ascorbic acid-deficient animals. There was however, a rapid decline in the specific radioactivity of elastin hydroxyproline. The proline/hydroxyproline specific-radioactivity ratio was approx. 1.5:1 after 6 days and 20:1 after 12 days of ascorbic acid deprivation, in contrast with the ratio of 1:1 in controls. The results suggested that the effect of ascorbic acid deficiency on elastin biosynthesis could be regarded as simply an elimination of hydroxylation of elastin proline with the formation and retention of a polymer increasingly deficient in hydroxyproline. 3. Collagen proline and hydroxyproline specific radioactivities were derived from material that was soluble in hot trichloroacetic acid, non-diffusible and collagenase-degradable. In contrast with elastin, there was a rapid decline in the specific radioactivity of proline as well as hydroxyproline in collagen from the ascorbic acid-deficient animals. However, the proline/hydroxyproline specific-radioactivity ratio in all samples from scorbutic animals was consistently slightly above 1:1. The results suggest the appearance in place of collagen, but in rapidly diminishing amounts, of a partially hydroxylated collagen in which the degree of hydroxylation may be decreased only by approx. 10%. 4. Incorporation of radioactivity into the diffusible hydroxyproline in skin remained relatively high despite the rapid decline in the incorporation of radioactivity into collagen. This observation is interpreted as indicative of an increasing degree of degradation of partially hydroxylated collagen to diffusible peptides. An alternative explanation might be that partially hydroxylated peptides are released to an increasing extent from ribosomes before they attain a length at least sufficient to render them non-diffusible. In either case it implies the accumulation in scurvy of low-molecular-weight peptides enriched in proline and deficient in hydroxyproline and could explain the failure to accumulate a high-molecular-weight collagen deficient in hydroxyproline. 5. It is thought, however, that, in addition, an inhibition of ribosomal amino acid incorporation leading to decreased synthesis of partially hydroxylated collagen may also occur, perhaps secondarily to impaired hydroxylation.     

In vivo labeling studies on the biosynthesis and degradation of collagen in experimental myocardial infarction.

The biosynthesis and degradation of myocardial collagen was studied in myocardium infarcted rats after a single intraperitoneal injection of 3H-proline. The incorporation of tritiated proline into collagen as 3H-hydroxyproline was regarded as a measure of collagen synthesis. The total content as well as total activity of hydroxyproline were measured in the whole homogenate, neutral salt soluble fraction, insoluble fraction and in urine collected at different time intervals and specific activities were calculated. Both collagen anabolism and catabolism were found to be affected in infarcted rat hearts. Degradation of existing collagen at the earlier stages of myocardial infarction and a simultaneous new collagen synthesis and deposition as insoluble form later took place.     

Biosynthesis of skin collagens in normal and diabetic mice.

Synthesis of collagens in vitro was studied on minced mouse skins incubated with [3H]-proline in organ-culture conditions. A comparative study was carried out on genetically diabetic mice (KK strain) and control mice (Swiss strain). After incubation, neutral-salt-soluble and acid-soluble collagens were extracted. The insoluble dermis was digested by pepsin and type I and type III collagens separated by differential precipitation in neutral salt solutions. Type I and Type III collagens were characterized by ion-exchange and molecular-sieve chromatography, amino acid analysis and by the characterization of CNBr peptides. In diabetic-mouse skin, the relative proportion of type III collagen was significantly higher than in control-mouse skin. The incorporation of radioactively labelled proline into hydroxyproline of type III collagen was significantly faster in diabetic-mouse skin than in control-mouse skin.No significant modifications in the total collagen content of the skin or of their rates of synthesis were observed between the two strains. Alteration in the ratio of type III to type I collagen in the diabetic-mouse skin can be interpreted as a sign of alteration of the regulation of collagen biosynthesis and may be related to the structural alterations observed in the diabetic intercellular matrix.     

The dynamics of formation of a collagen-phosphophoryn conjugate in relation to the passage of the mineralization front in rat incisor dentin

Dentin and predentin matrices contain Type I collagen and phosphophoryns as major constituents. A collagen-phosphophoryn conjugate is also present in small amounts. This conjugate has been implicated in the deposition of mineral. Its formation has been followed in rat incisors. Rats were labeled for varied time intervals with [3H]proline, followed by a 2-h pulse of [3H] serine. The soluble alpha- and beta-phosphophoryns were extracted under conditions minimizing degradation. The tooth residue was CNBr-treated and the collagen CNBr peptides alpha 1(I)CB7 and alpha 1(I)CB8 were collected along with the solubilized conjugate fraction. Each component was purified and the specific activities in [3H] proline, [3H]hydroxyproline, [3H]serine, and [3H]phosphoserine were determined. The collagen and alpha-phosphophoryn accumulated proline label linearly at the same rate over the entire period of labeling. Entry of [3H]proline into the conjugate fraction was delayed by approximately 9-10 h and then the label accumulated also linearly at the same rate. [3H]Serine was present at a different but constant level in each fraction; the conjugate had the lowest activity. These data indicate an extracellular formation of the conjugate at the mineralization front from precursors which followed different secretory pathways.     

Synthesis and turnover of collagen precursors in rabbit skin

1. The rate of synthesis of [(14)C]hydroxyproline by rabbit skin was studied in vitro and in vivo. 2. The soluble collagen fractions were shown to have a very rapid turnover. The 0.15m-sodium chloride-extractable collagen showed t((1/2)) values of 1.2hr. in vitro and 12hr. in vivo. The 0.5m-sodium chloride-extractable collagen exhibited a t((1/2)) value of 20hr. in vivo. 3. Under the conditions used it was not possible to obtain radioactive insoluble collagen in vitro. 4. A significant amount of soluble collagen is lost before it becomes insoluble. 5. These observations may help to explain why large amounts of peptide-bound hydroxyproline appear in the urine during periods of rapid collagen synthesis.     

Changes in synthesis of types-I and -III collagen during matrix-induced endochondral bone differentiation in rat.

The changes in rates of hydroxyproline formation and biosynthesis of types-I and -III collagen during bone matrix-induced sequential differentiation of cartilage, bone and bone marrow in rat were investigated. Biosynthesis of types-I and -III collagen at different stages of this sequence was studied by labelling in vivo and in vitro with [2,3-3H]proline. Pepsin-solubilized collagens were separated by sodium dodecyl sulphate/polyacrylamide-slab-gel electrophoresis. The results revealed that maximal amounts of type-III collagen were synthesized on day 3 during mesenchymal-cell proliferation. Thereafter, there was a gradual decline in type-III collagen synthesis. On days 9--20 during bone formation predominantly type-I collagen was synthesized. Similar results were obtained by the use of labelling techniques both in vivo and in vitro.     

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.     

Application of high-pressure liquid chromatography to studies of collagen production by isolated cells in culture

Techniques for assessing collagen production by cells in culture are usually based on evaluation of uptake of radiolabeled proline into collagen. Although simple in theory, this approach is often flawed because of uncertainties concerning the specific activity of labeled proline in the precursor pool for collagen synthesis. An alternative approach is to assess collagen production directly by measuring hydroxyproline in proteins secreted by cultured cells, although this has been difficult, due to the insensitivity of the methods available. Here we apply high-pressure liquid chromatography using reverse-phase elution of 7-chloro-4-nitrobenzo-2-oxa-1,3-diazole derivatives of hydroxyproline to measure collagen production by fibroblasts. The method is easy to perform and allows quantitation of hydroxyproline down to 5 pmol, making it applicable to fibroblasts in 12-well culture plates. Collagen production was shown to be constant over a period of 24 h, with a mean rate of 391 +/- 18 (SE n = 14) ng collagen/10(6) cells/h. Similar values were obtained using thin-layer chromatography and an enzyme-linked immunosorbent assay for type I collagen, but these techniques were judged to be less convenient and required additional assumptions compared with the technique described here in full.     

Effect of hyperbarism on collagenous protein metabolism in granulation tissue.

Rats with subcutaneously implanted polyurethane sponges were exposed 6 hours daily for 7 days to high ambient atmospheric pressures (1.5, 2, 2.5 and 3 ATA). Another group was exposed 4 hours daily for 4 weeks to 3 ATA before inducing granulation tissue formation. 14C-proline was administered 16 hours before terminating the experiment. Free hydroxyproline, soluble and insoluble collagen and total noncollagenous protein were isolated from the 7-day granuloma and the amount and radioactivity of 14C-hydroxyproline and 14C-proline were determined. Seven days' graduated hyperbarism did not affect collagen synthesis; the maturation of collagen to insoluble forms was inhibited at 2 and 2.5 ATA, but not at 3 ATA. Stimulated degradation of collagen (free hydroxyproline) was observed at 2, 2.5 and 3 ATA. In animals subjected to long-term exposure at 3 ATA pressure, the collagen in the granuloma matured to insoluble forms more quickly. Biochemical changes were correlated with changes in the fine structure of the granulation tissue. The appearance of the fibroblast proteosynthetic apparatus was not influenced by hyperbarism. Progressive spherical transformation, fusion of mitochondria and lysosomal activation in the pericapillary fibroblasts occurred at 2, 2.5 and 3 ATA. In short-term experiment, the formation of cytosegresomes and cellular necrosis also contributed to the effect at 3 ATA, which is thus already a toxic pressure for granulation tissue.     

Quantitative study of tissue collagen metabolism

A procedure for the quantification of various parameters of metabolism of collagen in fibrotic mouse liver has been developed. The method involves derivatization of hydroxyproline, a marker of collagen, with dansyl chloride, high-performance liquid chromatography of the derivative on an octadecyl C-18 column, and its detection by fluorescence. This assay improves upon existing procedures in several respects: It extends the analysis so that not only the collagen content of the tissue but also the metabolism of collagen is determined at levels found intracellularly. It is sensitive enough to quantify 0.1-10 nmol of hydroxyproline, and it includes three major amino acids (hydroxyproline, glycine, and proline) of collagen and two assay controls; it generates information on both the purity and quantity of collagen in each assay. The determination of specific activity of intracellular free [14C]proline, which is the precursor of protein-bound hydroxyproline, defines the specific activity of [14C]hydroxyproline of collagen converted from precursor residues of [14C]proline by the action of prolyl hydroxylase. The specific activity of [14C]hydroxyproline can be used for the evaluation of collagen synthesis and secretion and intracellular and extracellular degradation of the newly synthesized and secreted collagen in the tissue. The determination of specific activities of [14C]hydroxyproline and [14C]proline and of the ratio of [14C]hydroxyproline to [14C]proline of newly secreted collagen provides information concerning the extent of hydroxylation of [14C]proline residues of newly synthesized collagen.