Coordinate regulation of collagen and proteoglycan synthesis in costal cartilage of scorbutic and acutely fasted, vitamin C-supplemented guinea pigs

The effects of ascorbic acid deficiency and acute fasting (with ascorbate supplementation) on the synthesis of collagen and proteoglycan in costal cartilages from young guinea pigs was determined by in vitro labeling of these components with radioactive proline and sulfate, respectively. Both parameters were coordinately decreased by the second week on a vitamin C-free diet, with a continued decline to 20-30% of control values by the fourth week. These effects were quite specific, since incorporation of proline into noncollagenous protein was reduced by only 30% after 4 weeks on the deficient diet. The time course of the decrease in collagen and proteoglycan synthesis paralleled the loss of body weight induced by ascorbate deficiency. Hydroxylation of proline in collagen synthesized by scorbutic costal cartilage was reduced to about 60% of normal relatively early, and remained at that level thereafter. Neither collagen nor proteoglycan synthesis was returned to normal by the addition of ascorbate (0.2 mM) to cartilage in vitro. Administration of a single dose of ascorbate to scorbutic guinea pigs increased liver ascorbate and restored proline hydroxylation to normal levels by 24 h, but failed to increase the synthesis of collagen or proteoglycan. Synthesis of both extracellular matrix components was restored to control levels after four daily doses of ascorbate. A 96-h total fast, with ascorbate supplementation, produced rates of weight loss and decreases in the synthesis of these two components similar to those produced by acute scurvy. There was a linear correlation between changes in collagen and proteoglycan synthesis and changes in body weight during acute fasting, scurvy, and its reversal. These results suggest that it is the fasting state induced by ascorbate deficiency, rather than a direct action of the vitamin in either of these two biosynthetic pathways, which is the primary regulatory factor.     

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.     

Ascorbate-independent proline hydroxylation resulting from viral transformation of Balb 3T3 cells and unaffected by dibutyryl cAMP treatment.

Collagen synthesis, hydroxylation of proline in collagen, and collagen secretion were studied in the contact-inhibited mouse fibroblast line, Balb 3T3; the Kirsten virus transformed line, Ki-3T3; and dibutyryl cAMP (dbcAMP)-treated Ki-3T3 cells, during the various phases of the growth cycle. Transformed cells in both logarithmic and stationary phase produced lower levels of collagen than the parent line but 85-90% of the theoretically possible hydroxyproline residues of the collagen were formed even when ascorbic acid was not added to the culture medium. Moreover, the transformed cells showed only about a 20% increase of collagen secretion upon addition of ascorbate. This was in contrast to the ascorbate requirement for maximal proline hydroxylation and the 2-3 fold stimulation of collagen secretion by ascorbate in the parent Balb 3T3 cells. Although dbcAMP treatment caused Ki-3T3 cells to assume a more normal morphology and increased the relative rate of collagen synthesis to levels similar to that of 3T3, such treatment did not restore an ascorbate requirement for proline hydroxylation or collagen secretion. The specific activity of the enzyme prolyl hydroxylase also was not affected by dbcAMP treatment although collagen synthesis was increased by such treatment. In addition, it was found that ascorbic acid was not effective in activating prolyl hydroxylase derived from Ki-3T3 or dbcAMP-treated Ki-3T3 cell cultures either in logarithmic phase or stationary phase. Ki-3T3 cultures did not accumulate ascorbic acid in cells or medium nor was ascorbic acid synthesized from the precursor 14C-glucuronate in cell homogenates. The results suggest that virally transformed Balb 3T3 cells acquire the capacity to synthesize a reducing cofactor for prolyl hydroxylase and that this function may be related to the increased glycolytic metabolism of these cells since neither cellular metabolism nor ascrobate-independent hydroxylation was altered by treatment with dbcAMP.     

The biochemical and ultrastructural demonstration of collagen during early heart development

A correlative ultrastructural and biochemical study was made of cardiac collagen in the chick embryo, spanning stages 9- to 11 (6 to 13 somites). Analysis (carboxymethyl cellulose chromatography, SDS acrylamide gel electrophoresis and levels of proline hydroxylation) of collagen synthesized in situ permitted classification of this collagen as type I-like (α1:α2 = 2:1). Correlative electron microscopy of hearts fixed in situ showed the appearance of striated collagen fibrils in the cardiac jelly, thus complementing the biochemical findings. Although the electron microscope showed the presence of developing basal laminae and laminalike material, synthesis of the type of collagen reported as unique to basal laminae was not detected, and we propose that these basal laminae may lack type IV collagen. Embryonic stages 9- to 11 are the earliest stages in which collagen synthesis has been demonstrated, and this is the first report of the occurrence of collagen in cardiac jelly of early hearts.     

Alkaline phosphatase activation and collagen synthesis in human skin fibroblasts in culture

It has been noted in regenerating wounds that alkaline phosphatase activity in fibroblasts reaches a maximum when the collagen production is greatest. Tissue culture studies were carried out to show that prednisolone phosphate, while increasing the specific activity of alkaline phosphatase in human diploid skin fibroblasts, did not affect accumulation of collagen-hydroxyproline in monolayers or media. Addition of sodium ascorbate, resulted in rapid accumulation of hydroxyproline in the culture over a 13-day interval, while alkaline phosphatase activity increased only slightly over the last 6 days. When prednisolone and ascorbate were added in combination, alkaline phosphatase activity was significantly increased: but accumulation of hydroxyproline was no greater than in cultures to which ascorbate alone was added. Activation of alkaline phosphatase induced by prednisolone phosphate does not appear to be directly related to the biosynthesis of collagen in human skin fibroblasts in tissue culture.     

Effect of beta-aminopropionitrile and ascorbate on fibroblast migration

Ascorbate and beta-aminopropionitrile (BAPN) have direct, but diverse affects on collagen matrix production. Ascorbate is necessary for the intracellular hydroxylation of prolyl and lysyl residues during collagen biosynthesis whereas BAPN inhibits the enzyme lysyl oxidase in the extracellular space thus preventing collagen crosslink formation. To study the influence of these two agents on fibroplasia, an in vitro model was used to analyze fibroblast migration, proliferation, and collagen synthesis. Biopsies of chicken tendon were covered with a fibrin clot to simulate an in vivo wound environment, and then they were exposed to either ascorbate or BAPN for up to 7 days. Fibroblast migration into the fibrin clot was measured using a Zeiss Mopp II planimeter, DNA synthesis by 125IUDR incorporation, and collagen synthesis by [3H]proline incorporation into collagenase-digestible protein. Tendon biopsies treated daily with fresh ascorbate (0.1 mM) had significantly greater fibroblast migration than controls without ascorbate (P less than 0.05). Cellular proliferation, collagen synthesis, and total protein synthesis were not significantly altered by ascorbate treatment. In contrast, BAPN inhibited fibroblast migration in a dose-dependent fashion without inhibiting proliferation (0.25 and 0.5 mM), collagen, and noncollagen protein synthesis. Therefore, the effect of BAPN on migration does not appear to be due to generalized cytotoxicity. These combined studies suggest that compounds such as ascorbate and BAPN which can modify collagen may also modify fibroblast migration.     

Macromolecular synthesis in organ cultures of neonatal rat lung

Organ cultures of newborn rat lungs synthesize and accumulate DNA, RNA, collagen and noncollagenous proteins almost at a linear rate for at least 5 days. During this period the synthesis of collagen consistently exceeds the synthesis of noncollagenous proteins in a pattern similar to neonatal lung growth in vivo. Although some morphological characteristics of lung architecture are distorted after culture, fundamental structural similarities to lungs growing in intact animals are retained. When these cultures are maintained in atmospheres rich in oxygen, increased collagen synthesis is observed, a response similar to that of lungs in intact animals exposed to high oxygen concentrations in vivo. Our studies suggest that lung organ cultures may be a suitable system for investigating the biochemical aspects of lung tissue-environmental interaction.     

Morphological differentiation and changes in polypeptide synthesis pattern during regeneration of human epidermal tissue developed in vitro

By incubating multilayered primary cultures of human keratinocytes in low-calcium medium the suprabasal cell layers can be stripped off leaving a basal cell monolayer. When this monolayer is re-fed normal calcium medium a reproducible series of cell kinetic, morphological, and biochemical changes takes place resulting in the reestablishment of a multilayered tissue. Analysis of cell-cycle-specific proteins indicated that, during regeneration, a large cohort of cells became synchronized undergoing DNA replication after 3 days. Examination of culture morphology at the ultrastructural level confirmed the capacity of the basal cell monolayer to gradually reestablish a multilayered, differentiated epithelium. The ultrastructural appearance at 7 days poststripping was similar to that of unstripped cultures and was indicative of a tissue in steady state. Quantitation of cornified envelope formation at different times during regeneration showed that an increasing proportion of the cells were able to undergo terminal differentiation. In general, the pattern of keratin synthesis in the original epidermal explant labelled in vitro was similar to the pattern observed in human epidermis in vivo; however, in contrast to epidermis in vivo the explant also synthesized the hyperproliferative keratins 6 and 16. The in vitro differentiated keratinocytes showed underexpression of several proteins identified as differentiation markers, whereas several basal cell markers were overexpressed compared to the original explant. In addition, the in vitro differentiated keratinocytes synthesized some new proteins, notably keratins 7, 15 and 19. The basal layer remaining after stripping mainly expressed basal cell markers; however, during recovery, some of the differentiation-specific markers (e.g. keratin 10 and 15) were again expressed together with keratin no. 19, which is also expressed during wound healing in vivo. It is suggested that the present system of regenerating epidermal tissue cultures may serve as an experimental model to investigate certain aspects of the regulation of epidermal tissue homeostasis.     

Disruption of healed scars in scurvy -- the result of a disequilibrium in collagen metabolism.

Old scars break open in scorbutic patients because (1) the rate of collagen degradation is greater in an old scar than it is in normal skin, and (2) the rate of collagen synthesis is diminished throughout the body in ascorbate deficiency.     

Ascorbate deficiency results in decreased collagen production: under-hydroxylation of proline leads to increased intracellular degradation

Collagen production by cultured human lung fibroblasts was examined when the cells were made deficient in ascorbate. Cells grown in the absence of ascorbate produced 30% less collagen during a 6-h labeling period than cells incubated with as little as 1 microgram/ml ascorbate during the labeling period. Cells grown without ascorbate produced under-hydroxylated collagen which was subject to increased intracellular degradation from a basal level of 16% to an enhanced level of 49% of all newly synthesized collagen. The likely mechanism for increased intracellular degradation is the inability of under-hydroxylated collagen to assume a triple-helical conformation causing it to be susceptible to intracellular degradation. Measurement of collagen production by enzyme linked immunoassay (ELISA) using antibodies directed against triple-helical determinants of collagen showed that both types I and III collagens were affected. In contrast, another connective tissue component, fibronectin, was not affected. Analysis by ELISA showed a greater decrease in collagen production than did analysis by the collagenase method, suggesting that some non-helical collagen chains (detected by collagenase but not by ELISA) were secreted in the absence of ascorbate. These results provide a mechanism to account, in part, for the deficiency of collagen in connective tissues which occurs in a state of ascorbate deficiency.     

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

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

Zinc deficiency and the developing embryo

The effect ofin utero zinc deficiency on fetal development in rats is reviewed. Attention is paid to the primary biochemical lesion associated with zinc-related teratogenesis and special consideration is given to the central nervous system. Evidence is presented that the thymidine kinase salvage pathway, used for the synthesis of thymidine monophosphate in DNA synthesis, is depressed more in fetal brain tissue than in the liver. In addition, greater reliance appears to be placed on this pathway than onde novo synthesis in the fetal brain than in other tissues. Some consideration is given to the use of in vitro embryo culture in studies relating to neurogenesis, but evidence is presented of a greater capacity of explanted rat embryos to obtain zinc from maternal serum than occurs in vivo. The rapid onset of a teratogenic zinc deficiency following dietary zinc restriction is again highlighted and further studies are described which demonstrate the critical impact of a single feeding cycle, of 4 d duration, on maternal plasma zinc levels and on the extent and nature of the observed fetal abnormalities. Evidence is presented that by shifting the timing of the high dietary intake/low plasma zinc peak to coincide with a particular 48 h period between days 6 and 10 of pregnancy, the pattern of malformations thus obtained reflected the coincidence of the high dietary intake of zinc-deficient diet and the critical time of morphogenesis of several organ systems. Whereas diminished plasma zinc levels at term in zinc-deficient animals are generally well correlated with reduced growth and dysmorphogenesis of the offspring, the same is not always found in human studies. In some cases, elevated plasma zinc levels at parturition are found in mothers with growth-retarded children, or vice versa. Experimental studies with rats are reported that suggest that maternal zinc status at term may be higher in dams bearing pups stunted by exposure to a transient zinc deficiency early in pregnancy, which in turn may have reduced the demand for maternal zinc in the later stages of gestation. The protective effect of zinc on cadmium-induced teratogenesis is discussed, particularly in relation to findings concerning an interaction of these metals in the embryonic yolk sac and thus on preplacental embryonic nutrition. Possible interactions between alcohol and zinc deficiency are also considered and data are presented pointing to increased fetotoxicity and teratogenesis in the presence of both treatments and to a more specific interaction with respect to reduced cell numbers in the developing rat hippocampus. Malondialdehyde levels, which reflect the extent of lipid peroxidation in tissue, are reported to be substantially higher in microsomes from fetal rat livers whenin utero deficiency and gestational alcoholism are combined. The suggestion is made that alcohol and zinc deficiency act independently in the body, but overlap to some extent at the common biochemical locus of membrane lipid peroxidation.     

Novel bioactivity of phosvitin in connective tissue and bone organogenesis revealed by live calvarial bone organ culture models

Egg yolk phosvitin is one of the most highly phosphorylated extracellular matrix proteins known in nature with unique physico-chemical properties deemed to be critical during ex-vivo egg embryo development. We have utilized our unique live mouse calvarial bone organ culture models under conditions which dissociates the two bone remodeling stages, viz., resorption by osteoclasts and formation by osteoblasts, to highlight important and to date unknown critical biological functions of egg phosvitin. In our resorption model live bone cultures were grown in the absence of ascorbate and were stimulated by parathyroid hormone (PTH) to undergo rapid osteoclast formation/differentiation with bone resorption. In this resorption model native phosvitin potently inhibited PTH-induced osteoclastic bone resorption with simultaneous new osteoid/bone formation in the absence of ascorbate (vitamin C). These surprising and critical observations were extended using the bone formation model in the absence of ascorbate and in the presence of phosvitin which supported the above results. The results were corroborated by analyses for calcium release or uptake, tartrate-resistant acid phosphatase activity (marker for osteoclasts), alkaline phosphatase activity (marker for osteoblasts), collagen and hydroxyproline composition, and histological and quantitative histomorphometric evaluations. The data revealed that the discovered bioactivity of phosvitin mirrors that of ascorbate during collagen synthesis and the formation of new osteoid/bone. Complementing those studies use of the synthetic collagen peptide analog and cultured calvarial osteoblasts in conjunction with mass spectrometric analysis provided results that augmented the bone organ culture work and confirmed the capacity of phosvitin to stimulate differentiation of osteoblasts, collagen synthesis, hydroxyproline formation, and biomineralization. There are striking implications and interrelationships of this affect that relates to the evolutionary inactivation of the gene of an enzyme l-gulono-γ-lactone oxidase, which is involved in the final step of ascorbate biosynthesis, in many vertebrate species including passeriform birds, reptiles and teleost fish whose egg yolk contain phosvitin. These represent examples of how developing ex-vivo embryos of such species can achieve connective tissue and skeletal system formation in the absence of ascorbate.     

Transport and intracellular accumulation of vitamin C in endothelial cells: relevance to collagen synthesis

Endothelial cells preserve vascular integrity in part by synthesizing type IV collagen for the basement membrane of blood vessels. Vitamin C, which at physiologic pH is largely the ascorbate mono-anion, both protects these cells from oxidant stress and is required for collagen synthesis. Therefore, cultured endothelial cells were used to correlate intracellular concentrations of ascorbate with its uptake and ability to stimulate collagen release into the culture medium. The kinetics and inhibitor specificity of ascorbate transport into EA.hy926 endothelial cells were similar to those observed in other cell types, indicative of a specific high affinity transport process. Further, transport of the vitamin generated intracellular ascorbate concentrations that were 80-100-fold higher than concentrations in the medium following overnight culture, and transport inhibition with sulfinpyrazone and phloretin partially prevented such ascorbate accumulation. On the other hand, low millimolar intracellular concentrations of ascorbate impaired its transport measured after overnight culture. Synthesis and release of type IV collagen into the culture medium was markedly stimulated by ascorbate in a time-dependent manner, and was saturable with increasing medium concentrations of the vitamin. Optimal rates of collagen synthesis required intracellular concentrations of the vitamin up to 2 mM. Since such concentrations can only be generated by the ascorbate transporter, these results show the necessity of transport for this crucial function of the vitamin in endothelium.     

Collagen in tissue-engineered cartilage: Types,structure, and crosslinks

The function of articular cartilage as a weight-bearing tissue depends on the specific arrangement of collagen types II and IX into a three-dimensional organized collagen network that can balance the swelling pressure of the proteoglycan/ water gel. To determine whether cartilage engineered in vitro contains a functional collagen network, chondrocyte-polymer constructs were cultured for up to 6 weeks and analyzed with respect to the composition and ultrastructure of collagen by using biochemical and immunochemical methods and scanning electron microscopy. Total collagen content and the concentration of pyridinium crosslinks were significantly (57% and 70%, respectively) lower in tissue-engineered cartilage that in bovine calf articular cartilage. However, the fractions of collagen types II, IX, and X and the collagen network organization, density, and fibril diameter in engineered cartilage were not significantly different from those in natural articular cartilage. The implications of these findings for the field of tissue engineering are that differentiated chondrocytes are capable of forming a complex structure of collagen matrix in vitro, producing a tissue similar to natural articular cartilage on an ultrastructural scale. J. Cell. Biochem. 71:313–327, 1998. © 1998 Wiley-Liss, Inc.     

Ascorbate-generated endogenous extracellular matrix affects cell protein synthesis in calf aortic smooth muscle cells

Ascorbate supplementation of cultured fetal calf aortic smooth muscle cells leads to increased deposition of extracellular matrix proteins and stimulation of cellular protein synthesis (E. Schwartz et al., J cell biol 92 (1983) 462) [7]. In the present study, we have investigated this phenomenon at the level of gene expression. Cells were grown for three weeks on tissue culture plastic with or without ascorbate (50 micrograms/ml). When compared to controls, cells grown in presence of ascorbate had twice as much poly(A+) RNA per microgram of total RNA, and ascorbate led to a 50% increase in [35S]methionine incorporation when the total RNA was translated in the reticulocyte lysate system. SDS-PAGE revealed no change in the protein pattern under the two conditions. "Northern" hybridization revealed a two- to fivefold increase in the sequence content of beta-actin, alpha-tubulin and type I pro alpha 1-collagen in total RNA of ascorbate-supplemented cells, but no difference was observed in the mRNA sequence content for the three specific proteins when equal amounts of poly(A+) RNA from ascorbate and control cells were hybridized with the three cloned cDNAs. To evaluate the effect of an exogenous matrix, cells were also plated on collagen gels. RNA isolated from cells grown on collagen without added ascorbate exhibited translational activity and mRNA sequence content similar to cells grown with ascorbate on tissue culture plastic. In contrast, no differences from controls were found in cells grown for one week in the presence of ascorbate, at which time no significant deposition of collagen occurs in the extracellular matrix. These results suggest that the stimulation in protein synthesis in fetal calf smooth muscle cells supplemented with ascorbate is associated with an increase in the proportion of poly(A+) RNA in the total RNA pool, and that the production of an endogenous collagen-rich matrix in the presence of ascorbate may be the basis for these pretranslational changes.     

Ascorbate induction of collagen synthesis as a means for elucidating a mechanism of quantitative control of tissue-specific function.

Ascorbic acid displays the characteristics of an ideal inducer of tissue-specific function in primary avian tendon cells in culture. It is a highly specific, potent stimulator of collagen synthesis, it demonstrates slow reversible kinetics, and it has no effect on growth rate of the cultured cells. Kinetic analysis of ascorbate induction of collagen synthesis was used to determine the critical steps in this complex biosynthetic pathway. Full hydroxylation of the proline residues in collagen, although probably a necessary step for collagen induction, was in itself not sufficient for achieving either increased secretion or increased synthesis. On the other hand, an increase in secretion rate, which required both the presence of ascorbate and a high cell density, did correlate with the later stimulation in procollagen production. The process of procollagen secretion, therefore, meets the minimal requirements for the rate-limiting step. The fact that the cells maintained a large pool of intracellular procollagen despite changes in the rates of translation or secretion led us to postulate a possible feedback between the level of the internal procollagen pool and the rate of procollagen synthesis.     

T3 affects expression of collagen I and collagen cross-linking in bone cell cultures

Thyroid hormones (T3, T4) have a broad range of effects on bone, however, its role in determining the quality of bone matrix is poorly understood. In-vitro, the immortalized mouse osteoblast-like cell line MC3T3-E1 forms a tissue like structure, consisting of several cell layers, whose formation is affected by T3 significantly. In this culture system, we investigated the effects of T3 on cell multiplication, collagen synthesis, expression of genes related to the collagen cross-linking process and on the formation of cross-links.T3 compared to controls modulated cell multiplication, up-regulated collagen synthesis time and dose dependently, and stimulated protein synthesis. T3 increased mRNA expressions of procollagen-lysine-1,2-oxoglutarate 5-dioxygenase 2 (Plod2) and of lysyloxidase (Lox), both genes involved in post-translational modification of collagen. Moreover, it stimulated mRNA expression of bone morphogenetic protein 1 (Bmp1), the processing enzyme of the lysyloxidase-precursor and of procollagen. An increase in the collagen cross-link-ratio Pyr/deDHLNL indicates, that T3 modulated cross-link maturation in the MC3T3-E1 culture system. These results demonstrate that T3 directly regulates collagen synthesis and collagen cross-linking by up-regulating gene expression of the specific cross-link related enzymes, and underlines the importance of a well-balanced concentration of thyroid hormones for maintenance of bone quality.     

Alteration of the extracellular matrix of smooth muscle cells by ascorbate treatment

The protein composition in the extracellular matrix of cultured neonatal rat aortic smooth muscle cells has been monitored over time in culture. The influence of ascorbate on insoluble elastin and collagen has been described. In the absence of ascorbate, the cells accumulate an insoluble elastin component which can account for as much as 50% of the total protein in the extracellular matrix. In the presence of ascorbate, the amount of insoluble collagen increases, while the insoluble elastin content is significantly less. When ascorbate conditions are varied at different times during the culture, the extracellular matrices are altered with respect to collagen and elastin ratios. The decrease in elastin accumulation in the presence of ascorbate may be explained by an overhydroxylation of tropoelastin. Approximately 1/3 of the prolyl residues in the soluble elastin fractions isolated from cultures grown in the presence of ascorbate are hydroxylated. Since the insoluble elastin accumulated in these cultures contain the unique lysine-derived cross-links in amounts comparable to aortic tissue, this culture system proves ideal for studying the influence of extracellular matrix elastin on cell growth and metabolism.