Rate Of Proteoglycan Synthesis Research Articles

In vitro influence of ketoprofen on the proteoglycan metabolism of human normal and osteoarthritis cartilage

We investigated the influences of ketoprofen on the proteoglycan (PG) turnover of human articular cartilage explants in three groups: normal young with a high basal PG synthesis, normal adult and osteoarthritis cartilage, both with a low basal PG synthesis. Ketoprofen had no influence on the mean PG synthesis rate of normal adult and OA cartilage after 4 days of culture nor on the cartilage PG content after 8 days of culture. There was no relation between the histological grade of OA and effects of ketoprofen. In normal young cartilage ketoprofen induced an increase of the PG synthesis rate when added to the culture in a concentration of 10(-4) M. No correlation existed between the effect of ketoprofen and the basal PG synthesis of normal cartilage.

Effect of Temperature on the Metabolism of Proteoglycans in Explants of Bovine Articular Cartilage

The turnover of proteoglycans in bovine articular cartilage was determined in explant cultures, maintained at 32 degrees C or 37 degrees C. Both the rate of proteoglycan synthesis and the release of newly synthesized proteoglycans were decreased in cultures incubated at 32 degrees C compared to 37 degrees C. At both temperatures the newly synthesized proteoglycans were similar in hydrodynamic size and chain length of the glycosaminoglycans. However, the ratio of 6-sulfated disaccharides over 4-sulfated disaccharides of the newly synthesized glycosaminoglycans, differed less from the endogenous ratio at 32 degrees C than at 37 degrees C. At both temperatures, the incorporated 35S-sulfate is released from explants in two pools. Twenty-three percent of the 35S-radiolabel was released into the culture medium during an initial short phase (t1/2 = 1.1 day at 32 degrees C, 1.3 day at 37 degrees C), 77% had a much longer half-life. The lowered temperature markedly decreased the release of 35S-sulfate with a slow turnover (t1/2 = 60 days at 32 degrees C, 38 days at 37 degrees C).

Responses to protein deficiency of plasma and tissue insulinlike growth factor-I levels and proteoglycan synthesis rates in rat skeletal muscle and bone

The relative biological importance of plasma levels of insulin-like growth factors (IGFs) is uncertain since the IGFs may act through endocrine mechanisms involving circulating IGFs secreted by the liver, or by autocrine/paracrine mechanisms with IGF production in or close to their target cells. We report here studies in rats designed to examine this problem with an investigation of the changes in plasma and tissue concentrations of IGF-I in relation to the inhibition of bone and muscle growth and proteoglycan synthesis, a putative IGF-I-sensitive process, by protein deficiency. Over a 3-week period in young well-fed growing rats, there were marked increases in plasma IGF-I, whereas in the protein-deficient animals in which growth was inhibited concentrations fell markedly. In bone, concentrations of IGF-I were initially 20% of plasma, did not increase with age and were minimally influenced by protein deficiency. In skeletal muscle, concentrations of IGF-I were initially 3% of plasma, did not increase with age, but did fall with protein deficiency. In bone, the inhibition of proteoglycan synthesis by the protein deficiency was not correlated with changes in tissue IGF-I concentrations and was poorly correlated with changes in plasma hormone concentrations, although in the latter case an exponential relationship could be fitted to the data from the initial control and subsequent protein-deficient animals. In muscle, the changes in proteoglycan synthesis were significantly linearly correlated with changes in tissue IGF-I compared with an exponential relationship with plasma concentrations from the initial control and subsequent protein-deficient animals.(ABSTRACT TRUNCATED AT 250 WORDS)

Decrease in the basal levels of cytosolic free calcium in chondrocytes during aging in culture: Possible role as differentiation‐signal

Cell- and matrix-related parameters, which characterize the aging and differentiation process of cartilage in vivo, were measured in cultured chick epiphyseal chondrocytes during maintenance in a suspension culture for 34 days. A gradual decrease in the rates of proliferation and an increase in the size of the cells were observed. Ultrastructural examination revealed increased vacuolization and appearance of glycogen-storing pools. The rate of proteoglycan synthesis gradually increased. Age-related changes in the composition of the proteoglycan consisted of an increase in the ratio of keratan sulfate/chondroitin sulfate. The results indicate that the process of aging in culture resembles maturation and differentiation of cartilage tissue in vivo. The levels of cytosolic free calcium ions ([Ca2+]i) were measured in fura-2-loaded cells during the course of aging in culture. A gradual decrease in [Ca2+]i was observed. In 5-day cultures, a value of 184 nM [Ca2+]i was measured; this value decreased to 61 nM in 34-day cultures. On the basis of the present data and the previous results, which showed that cartilage-derived growth factors caused a decrease in [Ca2+]i, concomitantly with enhancing differentiation, whereas factors which elevated [Ca2+]i caused an increase in proliferation and a decrease in proteoglycan synthesis, we suggest a model for control of chondrocyte differentiation and aging. The model suggests that the rate of differentiation may be paced by changes in steady-state levels of [Ca2+]i.

Scorbutic and fasted guinea pig sera contain an insulin-like growth factor I-reversible inhibitor of proteoglycan and collagen synthesis in chick embryo chondrocytes and adult human skin fibroblasts

Chick embryo chondrocytes cultured in sera from scorbutic and fasted guinea pigs exhibited decreases in collagen and proteoglycan production to about 30–50% of control values (I. Oyamada et al., 1988, Biochem. Biophys. Res. Commun. 152, 1490–1496). Here we show by pulse-chase labeling experiments that in the chondrocyte system, as in the cartilage of scorbutic and fasted guinea pigs, decreased incorporation of precursor into collagen was due to decreased synthesis rather than to increased degradation. There was a concomitant decrease in type II procollagen mRNA to about 32% of the control level. As in scorbutic cartilage, proteoglycan synthesis by chondrocytes in scorbutic serum was blocked at the stage of glycosaminoglycan chain initiation. Scorbutic and fasted guinea pig sera also caused a 50–60% decrease in the rates of collagen and proteoglycan synthesis in adult human skin fibroblasts, which synthesize mainly type I collagen. Decreased matrix synthesis in both cell types resulted from the presence of an inhibitor in scorbutic and fasted sera. Elevated cortisol levels in these sera were not responsible for inhibition, as determined by the addition of dexamethasone to chondrocytes cultured in normal serum. Insulin-like growth factor I (IGF-I, 300–350 ng/ml) reversed the inhibition of extracellular matrix synthesis by scorbutic and fasted guinea pig sera in both cell types and prevented the decrease in type II procollagen mRNA in chondrocytes. Therefore, in addition to its established role in proteoglycan metabolism, IGF-I also regulates the synthesis of several collagen types. An increase in the circulating inhibitor of IGF-I action thus could lead to the negative regulation of collagen and cartilage proteoglycan synthesis that occurs in ascorbate-deficient and fasted guinea pigs.

Bovine sesamoid bones: A culture system for anatomically intact articular cartilage

Medial sesamoid bones from the metacarpophalangeal joints of calves were used for prolonged culture of anatomically intact articular cartilage on its natural bone support. The cartilage remained viable during culture, without signs of degeneration. After 1 wk of culture the cartilage showed an increased proteoglycan synthesis, and some minor changes in the composition of newly synthesized proteoglycans were observed. In the next 7 wk all studied parameters remained constant, except for the rate of proteoglycan synthesis, which declined between 4 and 8 wk to values just below those measured at the start of culture. Despite the fact that newly synthesized proteoglycans showed some altered biochemical properties, the composition of the total pool of proteoglycans did not change during 8 wk of culture. The significance of this phenomenon is discussed. This new in vitro model of intact articular cartilage offers a promising alternative to in vivo studies because in contrast to other in vitro models no surgical injury of the cartilage is introduced.

Growth and differentiation of stage 24 limb mesenchyme cells in a serum-free chemically defined medium

A serum-free defined medium which supports the differentiation of chick limb mesenchymal cells has been developed. In this medium, stage 24 embryonic limb mesenchymal cells which are plated at high density (5×10 6 cells/35-mm culture dish) differentiate into chondrocytes. Morphologically, these cultures appear only slightly different from those in which the cells are maintained in serum-containing medium. DNA levels and proline incorporation in cultures grown in defined medium are indistinguishable from control cultures. The rate of radiolabeled sulfate incorporation, a monitor of the rate of proteoglycan synthesis, in Day 8 high-density cultures maintained in defined medium is approximately 70–80% of control values. Additionally, growth and differentiation of intermediate-density (2× 10 6 cells/35-mm culture dish) and low-density (1× 10 6 cells/35-mm dish) cultures are also supported by this defined medium. The availability of this medium allows exploration of bioactive factors which affect or modulate mesenchymal cell differentiation and subsequent development.

Regulation of proteoglycan synthesis rate in cartilage in vitro: influence of extracellular ionic composition

Load-bearing cartilages regularly experience changes in fluid content as the result of changing load. It has been found that these changes in fluid content influence proteoglycan synthesis. The mechanism for this effect is not known. We have measured the influence of changes in cartilage hydration on the [ 35S]sulphate incorporation rate in both bovine nasal and human articular cartilage in medium whose concentration varied over the range 0.2–2-times physiological strength. In physiological medium the incorporation rate fell in proportion to fluid loss with a 10% fall in cartilage hydration resulting in a 30–50% decrease in 35S-incorporation rates. However, in medium of 0.5-times physiological strength, where the incorporation rate was only 40% of control values, the incorporation rate increased initially rather than falling as the cartilage lost fluid. These changes in hydration and hence proteoglycan content resulted in changes in the extracellular ionic composition of cartilage. When this was monitored in terms of [Na +] c, the internal sodium concentration, as a marker for changes in cartilage ionic composition, we found that incorporation rate varied with [Na +] c rather than directly with hydration.

Biochemical and morphological studies of steady state and lipopolysaccaride treated bovine articular cartilage explant cultures.

Explants of bovine articular cartilage were cultured for up to 50 days in 20% fetal calf serum in the presence or absence of the endotoxin lipopolysaccharide (LPS); or in various protocols involving different treatment times with LPS followed by recovery times in the absence of LPS. Cultures were measured in terms of rates of proteoglycan synthesis (incorporation of [35S]sulfate), proteoglycan contents and collagen contents. Histological sections were prepared for both light and electron microscopy. In fetal calf serum, the rates of synthesis and contents of proteoglycans per collagen remained constant, while for LPS treated cultures both parameters decreased. For recovery groups, the rates of proteoglycan synthesis increased during the time of recovery if the LPS treatment times were relatively short (2 weeks or less) and if the tissue was obtained from younger animals; net increase in proteoglycan contents occurred infrequently if at all during recovery protocols. Histological examinations revealed that chondrocytes in cultures maintained in fetal calf serum appeared normal with large stores of glycogen. In LPS treated cultures, chondrocytes were depleted of glycogen stores and contained numerous lipid droplets. In recovery cultures, chondrocytes replenished their glycogen contents, but the lipid droplets remained. For both LPS treated and recovery groups the extracellular matrix was depleted of proteoglycans with time in culture. The results provide further evidence for the ability of this explant culture system to maintain steady state metabolic parameters for proteoglycan metabolism over long time periods and for its utility to study reagents which regulate or perturb these parameters.

Potential influences of ketoprofen on human healthy and osteoarthritic cartilage in vitro.

Ketoprofen (Orudis, Rhône-Poulenc) is an anti-inflammatory drug with analgesic properties that is used in diseases such as rheumatoid arthritis and osteoarthritis (OA). It is therefore of interest to know whether ketoprofen has a direct influence on cartilage metabolism. We studied the effects of ketoprofen in therapeutic concentrations, on proteoglycan (PG) turnover in explants of human cartilage. The cartilage specimens were divided into three groups: healthy young (less than or equal to 3 yrs) n = 8, healthy old (mean 56 yrs) n = 13 and OA cartilage (greater than or equal to 65 yrs) n = 15. The rate of PG synthesis at day 4 of the culture was measured by the uptake of 35S sulphate. Cartilage PG content and PG release into the medium were determined over 8 days of culture. Ketoprofen stimulated the rate of PG synthesis of young cartilage, but not of old cartilage. In OA cartilage both stimulation and suppression occurred. Ketoprofen had no influence on cartilage PG content and PG release of healthy or OA cartilage during the 8 days of culture. The cartilage was examined histologically, and graded for severity of OA. There was no relation between the severity of OA and the effect of ketoprofen.

Slowing down aging of cultured embryonal chick chondrocytes by maintenance under lowered oxygen tension

Cultured epiphyseal-chondrocytes from embryonic chick may serve as a useful in vitro model to study aging processes in cartilage. The accelerated aging process in cultured chondrocytes is completed within a month and is manifested by typical changes in both cellular and extracellular compartments. Under common maintenance conditions, cells show a gradual loss of replicative capacity, increase in the rate of proteoglycan synthesis and age-dependent changes in the structure and composition of proteoglycan. An environmental factor — reduced oxygen tension — was found to slow down aging processes and preserve the young features of chondrocytes for a longer duration in culture. Cultures maintained under lower oxygen tension had higher proliferation rate, smaller cell size, lower rate of proteoglycan synthesis, and lower content of keratan sulfate side chains in the proteoglycan. In addition higher concentrations of free cytosolic calcium [Ca 2+] in as compared to control cultures, was found. It is suggested that the increased proliferation rate and the decrease in proteoglycan synthesis caused by low oxygen tension may be signalled by the higher [Ca 2+] in in these cells.

Aberrant regulation of the metabolism of the insulin receptor in Swarm rat chondrosarcoma chondrocytes.

Treatment of Swarm rat chondrosarcoma chondrocytes for 3 days in media containing either non-recombinant pig or recombinant human insulin (1 micrograms/ml) increased the rate of proteoglycan synthesis approximately 6-fold compared with cells cultured in the absence of insulin. The concentrations of human and pig insulin that stimulated the cells to double their rate of proteoglycan synthesis were approximately 1 ng/ml and approximately 2 ng/ml respectively. Because physiological concentrations of insulin do not influence proteoglycan synthesis in non-transformed chondrocytes, the findings indicated a possible abnormality in the insulin-dependent regulation of the insulin receptor in these tumour cells. Like most cells, chondrosarcoma chondrocytes down-regulated their insulin receptors when incubated with insulin for 30 min. However, the number of plasma-membrane and intracellular insulin receptors did not decrease when the chondrocytes were exposed to insulin chronically for 4 days. Chondrocytes were cultured in media containing 2H-, 13C- and 15N-labelled amino acids, and the heavy-isotope density-shift method was used to investigate both the rate of degradation and the rate of synthesis of the insulin receptor. Although the rate of synthesis of the receptor was slightly faster in the insulin-treated cultures, as assessed by a slightly faster rate of appearance of the 'heavy' receptor, the rate of degradation of the receptor was slower in the insulin-treated cultures. The half-lives for the 'light' receptors were approx. 18 h and 10 h for chondrocytes cultured in insulin-containing and insulin-free media respectively. These studies in vitro indicate that the apparent up-regulation of insulin receptors that occurs in this transformed cell upon long-term exposure to insulin is primarily the result of a decreased rate of receptor degradation.

IGF-1 concentrations in protein deficient rat plasma and tissues in relation to protein and proteoglycan synthesis rates

IGF-1 concentrations in protein deficient rat plasma and tissues in relation to protein and proteoglycan synthesis rates

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.

Synthesis of aberrant glycosaminoglycans during cartilage culture in 'sulfate free' medium.

Incorporation of radiolabeled sulfate into glycosaminoglycans is a widely accepted assay to measure the rate of proteoglycan synthesis. Although glycosaminoglycan synthesis is dependent on the quantity of inorganic sulfate available to proteoglycan synthesizing cells, 'sulfate free' medium is regularly used in studies regarding proteoglycan synthesis. In this study murine patellar cartilage glycosaminoglycans synthesized under 'sulfate free' conditions were compared with those synthesized at physiological sulfate concentration. Under 'sulfate free' conditions synthesis was not only decreased but low sulfated glycosaminoglycans were made that were not synthesized during incubation at physiological sulfate concentration. The use of 'sulfate free' medium should be avoided in proteoglycan synthesis studies.

Connective tissue remodelling in the ovine cervix during pregnancy and at term.

Cervical ripening and dilation in the ewe has been quantitated in terms of the connective tissue content of the tissue and the biosynthesis of the macromolecular components which make up the extracellular matrix of this tissue. During pregnancy there is a marked increase in the total tissue mass of the cervix along with the total mass of hydroxyproline (collagen) and hexuronate (proteoglycans and hyaluronate). The concentration of hydroxyproline of the cervix based on wet weight of the tissue decreases during pregnancy, however if based on dry weight, the concentration does not change until term. The hexuronate concentration based on both wet and dry weight of the tissue declines with pregnancy. The biosynthesis of collagen does not change during pregnancy but the rate of hyaluronate and proteoglycan synthesis by the cervix is increased in late pregnancy, and at term the rate of proteoglycan biosynthesis is elevated 10-fold. These data suggest that during cervical ripening and dilation a highly dynamic metabolic state exists within the tissue which allows for rapid tissue remodelling.

Effects of tiaprofenic acid and other NSAIDs on proteoglycan metabolism in articular cartilage explants.

Using in vitro methods, we have determined the effects of four NSAIDs on the biosynthesis and turnover of proteoglycans in articular cartilage explants. Over the concentration ranges examined (5 X 10(-7) to 10(-5) mol/L for tiaprofenic acid, naproxen and indomethacin; 5 X 10(-5) to 10(-3) mol/L for aspirin), all the drugs examined, except tiaprofenic acid, reduced the rate of proteoglycan synthesis compared with control tissue. All of the compounds examined reduced the turnover rate of newly synthesised proteoglycans. The products of turnover of explants treated with the various NSAIDs did not appear to be significantly different from those produced by control tissue, as assessed by gel chromatography and electrophoresis. There were some indications, however, of quantitative differences in distribution on both these analytical systems. These results indicate that with the exception of tiaprofenic acid all the NSAIDs examined produced a general reduction in chondrocyte metabolic activity. Thus it seems unlikely that tiaprofenic acid would have a direct detrimental effect on articular cartilage during long term administration.

Proteoglycan synthesis in organ cultures from regions of bovine tendon subjected to different mechanical forces.

Synthesis of proteoglycans by morphologically and chemically distinct regions of bovine flexor tendon was investigated in explant cultures. Proximal regions of the flexor tendon which experience only tensile forces and have low contents of proteoglycans initially exhibited relatively low rates of proteoglycan synthesis but high rates of collagen synthesis. The predominant proteoglycan produced by all proximal explants was of small hydrodynamic size and appeared similar to that extracted from proximal tissue. In contrast, explants derived from the distal tendon region, which experiences frictional and compressive forces in addition to tensile forces, and has a high content of proteoglycans, showed relatively high initial rates of proteoglycan synthesis and lower rates of collagen synthesis. These distal explants produced primarily large proteoglycans on the first day in culture. Turnover of newly synthesized proteoglycans was not detectable in proximal tissue, and was low in distal tissue. Loss of unlabelled proteoglycan from proximal and distal explants was not detected during the 12 days of culture. These observations suggest that the increase in specific types of proteoglycans in regions of tendon subjected to frictional and compressive forces is the result of elevated synthesis rates in this tissue. Two alterations in proteoglycan synthesis occurred during the 12-day culture period. (1) The rate of proteoglycan synthesis by all explants increased with time in culture. (2) The proportion of small proteoglycans synthesized by distal explants increased from 32% of the total proteoglycan produced on day 1, to 80% of that produced on day 12. Explants from proximal tendon continued to produce only small proteoglycans throughout the 12 days in culture. This switch in proteoglycan phenotype, resulting in decreased synthesis of large proteoglycans by the distal tissue, may be due to a lack of compressive forces on the cultured explants.

Use of Cultured Embryonal Chick Epiphyseal Chondrocytes as Grafts for Defects in Chick Articular Cartilage

Full-thickness defects in articular cartilage were repaired with cultured homologous embryonic chick epiphyseal chondrocytes embedded in a biological resorbable immobilization vehicle (BRIV). This graft was successfully transplanted in mechanically induced defects in the surface of condylar articular cartilage of the tibiotarsal joint of four-month-old roosters. Healing of the defects was observed macroscopically, histologically, and histochemically and with the use of biochemical analyses for six months. Chondrocyte proliferation was seen 48 hours after implantation, and a hyaline cartilage matrix surrounding the cells was present two weeks later. Within eight weeks, the defects were completely filled with hyaline cartilage, which integrated smoothly with the neighboring cartilage without the formation of fibrous tissue at the interface. The cell content and rate of proteoglycan synthesis remained high for four months, then declined slowly to the level of the surrounding cartilage. Six months after transplantation, the cartilaginous tissue in the wound at levels below the ossification front showed penetration by vascular elements and young bone trabeculae at the margins of the reparative tissue. No signs of immunogenic rejection of the implants were observed. These results may be related to the employment of a capable source of cells, i.e., cultured chondrocytes characterized by a high mitotic rate and an early stage of development. The transplanted cells grew well and maintained their initial rate of proliferation, with definite maturation and transformation. The resulting cartilage was structurally reorganized according to the host pattern and under the influence of multitudinous environmental conditions. The articular zone preserved its cartilaginous phenotype, whereas the subchondral regions were transformed into bone.

The effect of retinoic acid on proteoglycan biosynthesis in bovine articular cartilage cultures

The addition of retinoic acid to adult bovine articular cartilage cultures produces a concentration-dependent decrease in both proteoglycan synthesis and the proteoglycan content of the tissue. Total protein synthesis was not affected by the presence of retinoic acid, indicating that the inhibition of proteoglycan synthesis was not due to cytotoxicity. The proteoglycans synthesized in the presence of retinoic acid were similar in hydrodynamic size, ability to form aggregates with hyaluronate, and glycosaminoglycan composition to those of control cultures. However, the presence of larger glycosaminoglycan chains suggests that the core protein was substituted with fewer but longer glycosaminoglycan chains. In cultures maintained with retinoic acid, a decreased ratio of the large proteoglycan was synthesized relative to the small proteoglycan compared to that measured in control cultures. In cultures maintained with retinoic acid for 1 day And then switched to medium with 20% ( v v ) fetal calf serum, the rate of proteoglycan synthesis and hexuronate contents increased within 5 days to levels near those of control cultures. Within 2 days of switching to medium with 20% ( v v ) fetal calf serum, the relative proportions of the proteoglycan species were similar to those produced in cultures maintained in medium with 20% ( v v ) fetal calf serum throughout. The rate of proteoglycan synthesis by bovine articular cartilage cultures exhibited an exponential decay following exposure to retinoic acid, with estimated half-lives of 11.5 and 5.3 h for tissue previously maintained in medium alone or containing 20% ( v v ) fetal calf serum, respectively. The addition of 1 m m benzyl β- d-xyloside only partially reversed the retinoic acid-mediated inhibition of proteoglycan synthesis. This indicates that the inhibition of proteoglycan synthesis by retinoic acid was due to both a decreased availability of xylosylated core protein and a decreased capacity of the chondrocytes to synthesize chondroitin sulfate chains.