Effects of fibronectin on articular cartilage chondrocyte proteoglycan synthesis and response to insulin-like growth factor-I

Fibronectin, a ubiquitous glycoprotein of the extracellular matrix, serves as a substrate for cell attachment. Binding to fibronectin through cell-surface receptors promotes a flattened cell shape, stimulates the phosphorylation of intracellular protein, and changes the pattern of gene expression. Although fibronectin is abundant in normal articular cartilage, its effects on chondrocytes are not well understood. Proteolytic fragments of fibronectin stimulate the catabolism of matrix in articular cartilage and may promote the degeneration of cartilage in osteoarthritis; however, intact fibronectin may regulate other aspects of matrix metabolism, including matrix synthesis. To determine whether intact fibronectin affects the synthetic activity of chondrocytes, as well as to determine the responses of chondrocytes to the anabolic growth factor.insulin-like growth factor-I, we compared the incorporation of [³⁵S] by articular chondrocytes of the rat culture.din the presence and absence of commercially prepared cellular fibronectin and 0, 10, or 100 ng/ml recomBinanf human insulin-like growth factor-I. Monolayer and alginate suspension cultures were compared to determine whether responses differed under conditions in which fibronectin promoted a flattened cell shape (monolayer culture) and under those in which cells maintained a spherical shape (alginate culture). In alginate cultures, fibronectin alone stimulated the incorporation of [³⁵S]. Fibronectin with 10 ng/ml insulin-like growth factor-I had additive effects in alginate culture, producing the maximum incorporation of [³⁵S]. In monolayer cultures, fibronectin did not stimulate incorporation and blocked stimulation by 100 ng/ml insulin-like growth factor-I. The cells from the monolayer culture were much less active synthetically (at all doses of the growth factor) than those culture in alginate. Thus, fibronectin enhanced proteoglycan synthesis and the response to insulin-like growth factor-I in alginate but inhibited the response to the growth factor in monolayers. These observations suggest intact fibronectin may contribute to the maintenance or repair of the matrix of articular cartilage by stimulating proteoglycan synthesis.     

Effects of long-term estrogen replacement therapy on articular cartilage IGFBP-2, IGFBP-3, collagen and proteoglycan levels in ovariectomized cynomolgus monkeys

OBJECTIVE: The purpose of this study was to determine the effects of long-term estrogen replacement therapy (ERT) on insulin-like growth factor binding protein (IGFBP)-2, IGFBP-3, collagen and proteoglycan levels in the articular cartilage of the knee joint in a well-characterized monkey model of naturally occurring osteoarthritis (OA). A secondary aim was to evaluate the effect of soy phytoestrogen treatment on these articular cartilage components. DESIGN: Monkeys were ovariectomized and given ERT, soy phytoestrogen treatment or no treatment (control) for 3 years. Ten animals were randomly selected from each of the three groups and the cartilage was dissected from the proximal tibia and distal femur of the knee. Levels of IGFBP-2, IGFBP-3, and total protein were measured in cartilage desorptions, and proteoglycan levels and collagen levels were measured in the cartilage tissue. Sections from the tibial plateau of the opposite knee were immunostained using antibodies directed against IGFBPs and evaluated subjectively. RESULTS: IGFBP-3 levels were significantly higher, and total protein levels were significantly lower in the cartilage desorption samples from the estrogen-treated animals compared to the control animals. There were no significant differences in IGFBP-2, collagen or proteoglycan levels between the estrogen-treated and control groups. Soy phytoestrogen treatment had no significant effect on the levels of any of the cartilage components that were measured. The staining patterns observed by immunohistochemistry suggested local production of IGFBP-2 and IGFBP-3 by articular cartilage chondrocytes. CONCLUSIONS: Long-term estrogen treatment results in increased IGFBP-3 levels in articular cartilage without a significant change in IGFBP-2, collagen or proteoglycan content, and IGFBP-3 appears to be synthesized by articular cartilage chondrocytes. Long-term soy phytoestrogen treatment did not have a statistically significant effect on the levels of IGFBP-2, IGFBP-3, collagen or proteoglycan.     

Effects of SKI 306X,a new herbal agent,on proteoglycan degradation in cartilage explant culture and collagenase-induced rabbit osteoarthritis model

OBJECTIVE: Protective effects of SKI 306X, a natural herbal product extracted from three herbs Clematis mandshurica, Trichosanthes kirilowii, and Prunella vulgaris, on articular cartilage was examined and compared with other osteoarthritis (OA) drugs using in vitro and in vivo models. METHODS: In vitro culture of rabbit articular cartilage explants was used as a model to measure the effects of drugs on the matrix degradation. The recombinant human interleukin-1alpha (rhIL-1alpha, 5 ng/ml) was added to induce proteoglycan (PG) degradation and the degree of PG degradation was assessed by measuring the amount of glycosaminoglycan (GAG) released into the culture medium. In in vivo experiment, collagenase was intraarticularly injected twice into the right knee joint of rabbits to induce OA-like change, and test agents were orally administered once a day for 28 days. The degrees of OA-like changes were evaluated through a histological examination. RESULTS: In vitro study revealed SKI 306X inhibited the degradation of PG in a concentration-dependent manner. Trichosanthes kirilowii, which is one of the major components of SKI 306X, also significantly inhibited the GAG release in cartilage explant culture at 0.3 and 0.1 mg/ml. Dexamethasone and NSAIDs, such as diclofenac and rofecoxib, had no significant effects on the suppression of PG degradation. In in vivo studies, OA-like degeneration of the articular cartilage and synovial tissue was induced by injecting collagenase into the right knee joint of mature rabbits. At a dose of 200 mg/kg, SKI 306X reduced the OA-like histological changes, whereas diclofenac had no effect at 10 mg/kg. CONCLUSION: These results indicate that SKI 306X inhibited PG degradation in cartilage explant culture, and its prophylactic administration significantly protected the knee joint of rabbit from OA-like change in collagenase-induced experimental OA model. This strongly suggests that SKI 306X can be a good OA agent with some cartilage protection activity.     

Effects of proteoglycan extraction on the tensile behavior of articular cartilage

We undertook an interdisciplinary biomechanical and biochemical study to explore the extent and manner in which the total pool of proteoglycans influences the kinetic and static behavior of bovine articular cartilage in tension. Two biomechanical tests were used: (a) the viscoelastic creep test and (b) a slow constant-rate uniaxial tension test; and two enzymatic proteoglycan extraction procedures were used: (a) chondroitinase ABC treatment and (b) a sequential enzymatic treatment with chondroitinase ABC, trypsin, and Streptomyces hyaluronidase. We found that the viscoelastic creep response of all cartilage specimens may be divided into two distinct phases: an initial phase (less than 15 s), characterized by a rapid increase in strain following load application, and a late phase (15 s less than or equal to t less than 25,000 s), characterized by a more gradual increase in strain. A major finding of this study is that the kinetics of the creep response is greatly influenced by the glycosaminoglycan content of the tissue. For untreated and control specimens, the initial response comprises about 50% of the total strain, while for chondroitinase ABC and sequentially extracted specimens, the initial response comprises up to 83% of the total strain. Furthermore, most untreated and control specimens did not reach equilibrium within the 25,000 s test period, while enzymatically digested specimens often reached equilibrium in less than 100 s. Thus, we conclude that through their physical restraints on collagen, the bulk of proteoglycan present in the tissue acts to retard fibrillar reorganization and alignment under tensile loading, thereby effectively preventing sudden extension of the collagen network. In contrast, the results of our slow constant-rate uniaxial tension experiment show that essentially complete extraction of proteoglycan glycosaminoglycans does not affect the intrinsic tensile stiffness and strength of cartilage specimens or the collagen network in a significant manner. Hence, an important function of the bulk proteoglycans (i.e., the large aggregating type) in cartilage is to retard the rate of stretch and alignment when a tensile load is suddenly applied. This mechanism may be useful in protecting the cartilage collagen network during physiological situations, where sudden impact forces are imposed on a joint.     

Effects of physical stimulation with electromagnetic field and insulin growth factor-I treatment on proteoglycan synthesis of bovine articular cartilage

OBJECTIVE: To investigate the single and combined effects of electromagnetic field (EMF) exposure and the insulin growth factor-I (IGF-I) on proteoglycan (PG) synthesis of bovine articular cartilage explants and chondrocytes cultured in monolayers. DESIGN: Bovine articular cartilage explants and chondrocyte monolayers were exposed to EMF (75Hz; 1.5mT) for 24h in the absence and in the presence of both 10% fetal bovine serum (FBS) and IGF-I (1-100ng/ml). PG synthesis was determined by Na(2)-(35)SO(4) incorporation. PG release into culture medium was determined by the dimethylmethylene blue (DMMB) assay. RESULTS: In cartilage explants, EMF significantly increased (35)S-sulfate incorporation both in the absence and in the presence of 10% FBS. Similarly, IGF-I increased (35)S-sulfate incorporation in a dose-dependent manner both in 0% and 10% FBS. At all doses of IGF-I, the combined effects of the two stimuli resulted additive. No effect was observed on medium PG release. Also in chondrocyte monolayers, IGF-I stimulated (35)S-sulfate incorporation in a dose-dependent manner, both in 0% and 10% FBS, however, this was not modified by EMF exposure. CONCLUSIONS: The results of this study show that EMF can act in concert with IGF-I in stimulating PG synthesis in bovine articular cartilage explants. As this effect is not maintained in chondrocyte monolayers, the native cell-matrix interactions in the tissue may be fundamental in driving the EMF effects. These data suggest that in vivo the combination of both EMF and IGF may exert a more chondroprotective effect than either treatment alone on articular cartilage.     

Effect of compressive loading and unloading on the synthesis of total protein,proteoglycan, and fibronectin by canine cartilage explants

Full-thickness canine articular cartilage explants were subjected to compressive loads equivalent to a uniaxial stress of 0.025–1.2 MPa. A single cycle (18 h) of unconfined compression resulted in inhibition of total protein, proteoglycan, and fibronectin synthesis. The inhibition of fibronectin synthesis followed that of total protein synthesis. The magnitude of inhibition increased nonlinearly with increasing load levels. The signal that depressed synthesis remained effective for several hours after removal of load, but by 24 h proteoglycan synthesis had partially recovered and fibronectin and protein synthesis had fully recovered and sometimes exceeded the rate of synthesis in free-swelling controls. Forty-eight hours after five cycles of intermittent unconfined compression with similar loads, proteoglycan content and synthesis did not differ in loaded disks and in disks that were never loaded in vitro. Interestingly, the percentage of water in disks that had never been loaded in vitro increased significantly after 10 days in culture, relative to the percentage of water in free-swelling disks on the day of harvest. Intermittent compressive loading in the range of 0.5–1.2 MPa partially prevented this increase. Our results confirmed the previously reported inhibition of biosynthesis with static loading but also suggested that exposure to intermittent compressive loading may help to maintain the normal ratio of dry to wet weight in the explant.     

Simultaneous changes in the mechanical properties, quantitative collagen organization, and proteoglycan concentration of articular cartilage following canine meniscectomy.

The mechanical properties and microstructure of articular cartilage from the canine tibial plateau were studied 12 weeks after total medial meniscectomy. The organization of the birefringent collagen network was measured with quantitative polarized light microscopy to determine the thickness and the degree of organization of the superficial and deep zones. The zonal concentration of sulfated glycosaminoglycan was quantified with digital densitometry of safranin-O staining. Equilibrium compressive and shear properties, as well as dynamic shear properties, were measured at sites adjacent to those of microstructural analysis. The results evinced significant loss of cartilage function following meniscectomy, with decreases of 20-50% in the compressive and shear moduli. There was no evidence of alterations in the degree of collagen fibrillar organization, although a complete loss of the surface zone was seen in 60% of the samples that underwent meniscectomy. Meniscectomy resulted in a decreased concentration of sulfated glycosaminoglycan, and significant positive correlations were found between the equilibrium compressive modulus and the glycosaminoglycan content. Furthermore, the shear properties of cartilage correlated directly with collagen fibrillar organization measured at the superficial zone of corresponding sites. These findings demonstrate that meniscectomy leads to impaired mechanical function of articular cartilage, with significant evidence of quantitative correlations between cartilage microstructure and mechanics.     

The proteoglycan synthesis repertoire of rabbit chondrocytes maintained in type II collagen gels

Repair of experimental articular cartilage lesions employing cultured rabbit articular chondrocytes requires a detailed knowledge of the phenotypic stability of these cells. A suitable matrix vehicle for use in chondrocyte transplantation is a much sought-after component of any transplantation paradigm. We studied the proteoglycan synthesis repertoire of young immature rabbit articular chondrocytes maintained in chick type II collagen gels or collagen gels supplemented with recombinant human transforming growth factor-beta 1 (rhTGF beta 1). Maintenance of chondrocytes in type II collagen gels increased the percentage 35SO4-labeled proteoglycans reaching equilibrium in the A1D1 or D1 fraction of CsCl density gradient when compared to chondrocytes maintained in polystyrene microwell cultures. Although rhTGF beta 1 supplementation increased the percentage of A1D1/D1 proteoglycan by chondrocytes grown on polystyrene, rhTGF beta 1 did not augment this percentage increase in A1D1/D1 when added to collagen II gels. Rabbit chondrocytes synthesized two core proteins derived from the high-density aggregatable proteoglycans. LI and LII have apparent molecular sizes of 480 kDa and 390 kDa, respectively. Both core protein forms were found in the medium fraction, but the predominant core protein form associated with the cell fraction was LI. Maintenance of chondrocytes in collagen II gels increased synthesis of both core proteins. In addition to the large core proteins, three other core proteins with properties on SDS PAGE characteristic of the small dermatan sulfate proteoglycans, biglycan and decorin, were identified. Synthesis of these core proteins was stimulated by maintenance in collagen gels. Furthermore, they were preferentially retained in the gel matrix. Chondrocytes maintained on glass or in type II collagen gels stained with monoclonal antibodies specific for chondroitin-6-sulfate, chondroitin-4-sulfate and keratan sulfate. However, while chondrocytes grown on glass slides failed to stain with monoclonal antibody 3B3 in the absence of chondroitinase ABC digestion, chondrocytes grown in collagen II gels stained intensely in the absence of enzyme pretreatment. These results were confirmed by Western blots.     

Alterations of proteoglycan synthesis in rabbit articular cartilage induced by intra-articular injection of papain

In order to investigate the biochemical alteration of proteoglycan (PG) synthesis during cartilage repair, reversible destruction was induced by injecting papain into the knee joint cavity of rabbits. The PG synthesis in the cartilage was examined using Na2 35SO4 and high performance liquid chromatography (HPLC). PGs labeled with 35SO4(2-) (35S-PGs) were extracted from normal and papain-treated cartilage, and the amount of synthesis, ability to aggregate with hyaluronan (HA), and the composition of glycosaminoglycan and chondroitin sulfate isomer labeled with 35SO4(2-) (35S-GAG and 35S-CS isomer) were analyzed. Synthesis of 35S-PGs, especially those that were unable to aggregate with HA (nonaggregating 35S-PGs), increased in papain-treated cartilage compared with that in normal cartilage. The acceleration and qualitative change in PG synthesis in the papain-treated cartilage are considered to be responses to the supplementation of the loss of cartilage PGs induced by papain. The compositions of 35S-GAG and 35S-CS isomer of the nonaggregating 35S-PGs differed from those of 35S-PGs which were able to aggregate with HA (aggregating 35S-PGs) in the papain-treated cartilage as well as in the normal cartilage. However, the compositions of both nonaggregating and aggregating 35S-PGs in the papain-treated and normal cartilage were similar. These results indicate that most of the nonaggregating 35S-PGs in papain-treated cartilage have properties similar to those in normal cartilage and are not simple degradation products of aggregating 35S-PGs; they also suggest that the supplementary reaction for PG content in the cartilage during its repair process is not simple acceleration in PG turn-over but the enhancement of PG synthesis accompanied by alterations in aggregating ability and the compositions of GAG and CS isomer.     

Effects of intermittently applied cyclic loading on proteoglycan metabolism and swelling behaviour of articular cartilage explants

OBJECTIVE: The aim of this study was to evaluate the effect of tissue load, frequency and load duration on the biosynthesis and release of proteoglycans (PGs) as well as on the swelling behaviour of cultured mature bovine articular cartilage superimposed with intermittent loads. METHODS: Cyclic compressive pressure was introduced for 1, 3 or 6 days using a sinusoidal waveform of 0.5 Hz-frequency with a peak stress of 0.1, 0.5 or 1.0 MPa. The loads were applied for a period of 10 seconds (s) followed by a load-free period of 10, 100 or 1000 s. The incorporation of [35S]-SO4 into glycosaminoglycans (GAGs) during the final 18 h, the content of GAGs and DNA as well as the deformation of loaded explants were determined. RESULTS: The PG synthesis is sensitive to changes in the loading conditions applied, whereas the release of newly synthesized PG is not. A maximum PG synthesis is observed at day 3, and under load-free intervals of 100 s. After 6 days of loading the release of endogenous PGs is significantly elevated, the viability of superficial chondrocytes decreased, and cartilage swelling is observed. CONCLUSIONS: Considering numerous reports of elevated PG levels synthesized as well as released from human and experimental osteoarthritic cartilage, our results implicate that degenerative processes can also be mimicked by applying well-defined mechanical conditions as described here.     

Induction of apoptosis of articular chondrocytes and suppression of articular cartilage proteoglycan synthesis by heat shock

We investigated cellular and matrix responses of articular cartilage to heat shock. Rat articular cartilage was pretreated at 37 degrees C for 24 h before being exposed to 48 degrees C for 10 min and subsequently incubated at 37 degrees C for 1, 2, 4, 7, 10, and 14 days. Following heat shock, a terminal deoxynucleotidyl transferase nick end labeling assay showed that articular chondrocyte apoptosis appeared at day 1, peaked at day 7, and declined by day 14. Analysis by transmission electron microscopy confirmed that the chondrocytes had characteristic morphological features of apoptosis; immunohistochemical staining revealed that caspase-3 activity in chondrocytes increased, 3-B-3-positive articular chondrocytes decreased in number, and the expression of 3-B-3 native epitope in articular chondrocytes was reduced. Safranin-O staining revealed that depletion of proteoglycans in the matrix was not found in any group. Morphological and biochemical evidence from this study suggested that heat shock at 48 degrees C induced articular chondrocyte apoptosis and suppressed proteoglycan synthesis of articular cartilage in vitro. This study thus provides evidence of the onset of osteoarthritis induced by heat shock and a basis for choosing a temperature at which malignant bone tumor cells can be killed with minimal damage to articular cartilage.     

Effects of free and bound insulin-like growth factors on proteoglycan metabolism in articular cartilage explants.

This article describes the effects of bound forms of insulin-like growth factors (IGFs) on proteoglycan metabolism by bovine articular cartilage in explant culture. When these growth factors were added to articular cartilage explants complexed with their native serum binding proteins (BPs), both IGF-I-BP complex and IGF-II-BP complex stimulated proteoglycan synthesis to different degrees over a 3-day period. When added to the medium of cultures of articular cartilage over 5 days, IGF-II-BP complex induced high rates of synthesis and low rates of catabolism of proteoglycans, giving rise to tissue levels of proteoglycan similar to those observed in fresh tissue. When articular cartilage was maintained in culture with the same concentration of IGF-I-BP complex, tissue levels of proteoglycans fell over the culture period because of lower rates of proteoglycan synthesis. Analysis of the proteoglycans synthesized by articular cartilage in the presence of free or bound IGF-I or IGF-II showed that these growth factors stimulated the rate of synthesis of the large proteoglycan species present in cartilage but did not affect the synthesis of the small proteoglycans.     

Effects of glucose on collagen mRNA levels and collagen secretion in EAhy 926 endothelial cell line

Diabetes mellitus (DM) is a complex metabolic disease associated with increased accumulation of extracellular matrix by endothelial cells and contributing to vascular complications of long-standing diabetes. On the other hand, DM is also associated with decreased accumulation of extracellular matrix in granulation tissue, which is suggested to be a consequence of impaired angiogenesis. The role of hyperglycemia in these situations is not fully understood. We examined the effects of high glucose concentrations on the gene expression and secretion of various collagens in cultured EAhy 926 endothelial cells. EAhy 926 endothelial cells expressed alpha 1(I) collagen mRNA at a low level and small amount of the corresponding peptide was secreted from the cells; mRNA was not affected but peptide secretion was increased by elevated glucose concentration. mRNAs for type III and VI collagens were not detected in the endothelial cells Furthermore, high glucose concentration in long term had no morphological effects on cultured endothelial cells but increased the expression of type IV collagen, which could rather be beneficial for angiogenesis in a healing wound. Our results suggest that high glucose concentration per se may contribute to increased accumulation of extracellular matrix in blood vessels but probably is not responsible for decreased angiogenesis and granulation tissue formation in diabetic patients.     

Cell culture of the intervertebral disc of rats: factors influencing culture, proteoglycan, collagen, and deoxyribonucleic acid synthesis.

To establish cell culture of the nucleus pulposus and anulus fibrosus of rat intervertebral disc, the effects of culture conditions on the growth of cells and the synthesis of DNA, proteoglycan, and collagen were studied. For cell culture of the nucleus pulposus, the use of 3-week-old rats and a medium adjusted to pH 7.0 was optimal. There was almost no difference in growth between cells in Ham's F12 medium and those in Dulbecco's Modified Eagle Medium. In cells isolated from the anulus fibrosus, a medium adjusted to pH 7.0-7.6 was preferable, but irrespective of rat age. Culture cells of the nucleus pulposus were composed of large cells with vacuoles and small polygonal cells. These cells had a slight growth activity and a fair capability of proteoglycan and collagen synthesis. Culture cells of the anulus fibrosus were composed of polygonal and spindle-shape cells, and the growth was more vigorous with the potentials for proteoglycan and collagen synthesis than the nucleus cells.     

Statin stimulates bone morphogenetic protein-2, aggrecan,and type 2 collagen gene expression and proteoglycan synthesis in rat chondrocytes

Statins increase bone morphogenetic protein-2 (BMP-2) mRNA expression and subsequently increase new bone formation in vitro. However, the action of statins on the BMP-2 mRNA regulation of cartilage matrix synthesis by chondrocytes is unknown. We evaluated regulation of BMP-2, aggrecan, and type II collagen (COL2) mRNA and ³⁵S-labeled proteoglycan (PG) synthesis by mevastatin using cultured chondrocytes obtained from articular cartilage of fetal rats. Expression of BMP-2, aggrecan, and COL2 mRNAs were increased in the presence of 2µM mevastatin on day 2. However, longer (10 day) culture in the presence of the drug decreased the expression of these mRNAs. PG synthesis was increased 3 days after treating the cells with mevastatin, which was also decreased with longer (10 day) mevastatin treatment. These results suggest that mevastatin increases mRNA expression of BMP-2, aggrecan, and COL2 as well as PG synthesis by fetal rat chondrocytes early in the treatment period. We suggest that statins have implications for fracture and cartilage repair.     

Local stimulation of proteoglycan synthesis in articular cartilage explants by dynamic compression in vitro.

Cultured bovine articular cartilage was subjected to 50 ms, 0.5-1.0 MPa compressions repeated at intervals of 2-60 s for 1.5 h and simultaneously labeled with 35SO4. The compression was delivered with a 4-mm-diameter nonporous loading head on an 8-mm-diameter cartilage explant. This method created directly compressed (central) and uncompressed (border) areas within the tissue. Analysis of the whole explant under a 0.5 MPa load showed significantly increased 35SO4 incorporation by compression repeated at 2- and 4-s but not at 20- and 60-s intervals. When the incorporation was studied separately in the border and central areas, a statistically significant stimulation was noticed in the central area with a 4-s cycle, while the border area was stimulated with a 2-s cycle. Autoradiography of the central area showed that the stimulation with 0.5 MPa and a 4-s cycle occurred through the whole depth of the cartilage, while raising the pressure to 1 MPa or the frequency to 2 s reduced the stimulation, particularly in the superficial cartilage. In the border area the stimulation with 0.5 MPa and a 2-s cycle was noted in the superficial zone only. The stimulation of proteoglycan synthesis is thus limited to certain loading frequencies and pressures and occurs in specific areas under and around the loaded site. Its rapid appearance suggests enhanced glycosylation or sulfation of core proteins or enhanced speed of posttranslational processing.     

Effect of link protein concentration on articular cartilage proteoglycan aggregation

Previous work has shown that alterations in proteoglycan aggregates are among the first changes detected with aging, disuse, and degeneration of articular cartilage, yet the cause or causes of these alterations remain unknown. To determine if differences in link protein concentration can explain alterations in the assembly, size, and stability of articular cartilage proteoglycan aggregates, we isolated proteoglycan monomer (aggrecan) and link protein from adult bovine articular cartilage and then assembled proteoglycan aggregates from aggrecan and 0.8% hyaluronan relative to aggrecan weight, in the presence of 0, 2, 4, 6, 8, 10, 15, and 20% concentrations of link protein relative to aggrecan weight. We determined the amount, sedimentation coefficient, and stability of the aggregates by analytical ultracentrifugation and measured their dimensions by electron microscopy with use of the monolayer technique. Increased aggregate size, as determined by ultracentrifugation, was directly correlated with an increased number of aggrecans per aggregate and with increased hyaluronan length, as determined by electron microscopy. The concentration of link protein significantly influenced aggregation: concentrations of 6–8% produced maximum aggregation, aggregate stability, and uniformity of aggrecan spacing; concentrations greater than 10% led to the formation of superaggregates (aggregates with sedimentation velocities greater than 100 S that may result from linking two or more hyaluronan filaments) but decreased aggregate stability; and concentrations of less than 4% link protein significantly decreased aggregation, the size and stability of aggregates, and the regularity of aggrecan spacing. The latter observations suggest that a decline in the concentration of link protein could decrease the organization and stability of the articular cartilage matrix.     

Treatment with calcitonin prevents the net loss of collagen, hyaluronan and proteoglycan aggregates from cartilage in the early stages of canine experimental osteoarthritis

OBJECTIVE: To evaluate the effect of calcitonin (CT) on the histology and biochemistry of articular cartilage from unstable operated and nonoperated knee in a canine model of experimental osteoarthritis (OA). METHODS: Eighteen dogs underwent anterior cruciate ligament transection (ACLT) of the right knee and were randomly distributed into three groups of six dogs each. From day-1 after surgery until sacrifice 84 days post-ACLT, each dog received a daily nasal spray that delivered the placebo, 100 units of CT or 400 units of CT. Histologic lesions were scored. Hyaluronan (HA) and antigenic keratan sulfate (AgKS) were quantified by enzyme-linked immunosorbent assays (ELISAs), whereas aggrecan molecules extracted under nondissociative conditions were characterized by velocity gradient centrifugation. RESULTS: All canine cruciate-deficient knees developed OA. At a daily dose of 400 units, CT had no effect on the size of osteophytes but significantly reduced the severity of cartilage histologic lesions in unstable knees. CT also enhanced the HA content as well as the size distribution and relative abundance of fast-sedimenting aggrecan aggregates in cartilage from both operated and nonoperated knees. On the other hand, in the CT-treated group, the cartilage content of AgKS increased in operated joints, but not in nonoperated joints. CONCLUSIONS: Because CT delivered as a nasal spray markedly reduced the severity of most OA changes, both at the histological and biochemical level, this form of therapy may have benefits for humans who have recently experienced a traumatic knee injury, and as well as for dogs who spontaneously rupture their ACL.     

Effect of vitamin D3 on proteoglycan degradation of growth cartilage

Degradation of proteoglycans in growth cartilage plays an important role during endochondral ossification. Degradation is controlled by certain enzymes secreted by macrophages. Vitamin D3 metabolites markedly enhance the degradation of proteoglycans by macrophages in vitro. However, this enhancing activity of D3 metabolites is eliminated when the growth cartilage cells are lysed with 0.2N NH4OH. Puromycin (10 micrograms/ml) also inhibits the enhancement effect. These results suggest that D3 metabolites stimulate the synthesis of a D3-dependent substance by growth cartilage cells and that subsequently this substance enhances the enzymatic degradation of proteoglycans by macrophages.