Your search keyword '"Grodzinsky AJ"' showing total 24 results

1. Creb5 establishes the competence for Prg4 expression in articular cartilage.

Author

Zhang CH, Gao Y, Jadhav U, Hung HH, Holton KM, Grodzinsky AJ, Shivdasani RA, and Lassar AB

Subjects

Animals, Binding Sites, Cartilage, Articular drug effects, Cattle, Cells, Cultured, Chondrocytes drug effects, Cyclic AMP Response Element-Binding Protein A genetics, Gene Expression Regulation, Mitogen-Activated Protein Kinases metabolism, Phosphorylation, Promoter Regions, Genetic, Proteoglycans genetics, Transforming Growth Factor alpha pharmacology, Transforming Growth Factor beta2 pharmacology, Cartilage, Articular metabolism, Chondrocytes metabolism, Cyclic AMP Response Element-Binding Protein A metabolism, Proteoglycans metabolism

Abstract

A hallmark of cells comprising the superficial zone of articular cartilage is their expression of lubricin, encoded by the Prg4 gene, that lubricates the joint and protects against the development of arthritis. Here, we identify Creb5 as a transcription factor that is specifically expressed in superficial zone articular chondrocytes and is required for TGF-β and EGFR signaling to induce Prg4 expression. Notably, forced expression of Creb5 in chondrocytes derived from the deep zone of the articular cartilage confers the competence for TGF-β and EGFR signals to induce Prg4 expression. Chromatin-IP and ATAC-Seq analyses have revealed that Creb5 directly binds to two Prg4 promoter-proximal regulatory elements, that display an open chromatin conformation specifically in superficial zone articular chondrocytes; and which work in combination with a more distal regulatory element to drive induction of Prg4 by TGF-β. Our results indicate that Creb5 is a critical regulator of Prg4/lubricin expression in the articular cartilage.

Published

2021

2. A novel mechanobiological model can predict how physiologically relevant dynamic loading causes proteoglycan loss in mechanically injured articular cartilage.

Author

Orozco GA, Tanska P, Florea C, Grodzinsky AJ, and Korhonen RK

Subjects

Animals, Biophysics methods, Cattle, Models, Biological, Time Factors, Cartilage, Articular injuries, Cartilage, Articular pathology, Proteoglycans analysis, Stress, Mechanical

Abstract

Cartilage provides low-friction properties and plays an essential role in diarthrodial joints. A hydrated ground substance composed mainly of proteoglycans (PGs) and a fibrillar collagen network are the main constituents of cartilage. Unfortunately, traumatic joint loading can destroy this complex structure and produce lesions in tissue, leading later to changes in tissue composition and, ultimately, to post-traumatic osteoarthritis (PTOA). Consequently, the fixed charge density (FCD) of PGs may decrease near the lesion. However, the underlying mechanisms leading to these tissue changes are unknown. Here, knee cartilage disks from bovine calves were injuriously compressed, followed by a physiologically relevant dynamic compression for twelve days. FCD content at different follow-up time points was assessed using digital densitometry. A novel cartilage degeneration model was developed by implementing deviatoric and maximum shear strain, as well as fluid velocity controlled algorithms to simulate the FCD loss as a function of time. Predicted loss of FCD was quite uniform around the cartilage lesions when the degeneration algorithm was driven by the fluid velocity, while the deviatoric and shear strain driven mechanisms exhibited slightly discontinuous FCD loss around cracks. Our degeneration algorithm predictions fitted well with the FCD content measured from the experiments. The developed model could subsequently be applied for prediction of FCD depletion around different cartilage lesions and for suggesting optimal rehabilitation protocols.

Published

2018

3. Mechanical motion promotes expression of Prg4 in articular cartilage via multiple CREB-dependent, fluid flow shear stress-induced signaling pathways.

Author

Ogawa H, Kozhemyakina E, Hung HH, Grodzinsky AJ, and Lassar AB

Subjects

Adenosine Triphosphate metabolism, Alleles, Animals, CREB-Binding Protein metabolism, Calcium metabolism, Cells, Cultured, Chondrocytes metabolism, Female, Gene Knockdown Techniques, Male, Mice, Motor Activity genetics, Recombination, Genetic genetics, Stress, Physiological genetics, Cartilage, Articular metabolism, Gene Expression Regulation, Proteoglycans genetics, Proteoglycans metabolism, Signal Transduction

Abstract

Lubricin is a secreted proteoglycan encoded by the Prg4 locus that is abundantly expressed by superficial zone articular chondrocytes and has been noted to both be sensitive to mechanical loading and protect against the development of osteoarthritis. In this study, we document that running induces maximal expression of Prg4 in the superficial zone of knee joint articular cartilage in a COX-2-dependent fashion, which correlates with augmented levels of phospho-S133 CREB and increased nuclear localization of CREB-regulated transcriptional coactivators (CRTCs) in this tissue. Furthermore, we found that fluid flow shear stress (FFSS) increases secretion of extracellular PGE2, PTHrP, and ATP (by epiphyseal chondrocytes), which together engage both PKA- and Ca(++)-regulated signaling pathways that work in combination to promote CREB-dependent induction of Prg4, specifically in superficial zone articular chondrocytes. Because running and FFSS both boost Prg4 expression in a COX-2-dependent fashion, our results suggest that mechanical motion may induce Prg4 expression in the superficial zone of articular cartilage by engaging the same signaling pathways activated in vitro by FFSS that promote CREB-dependent gene expression in this tissue.

Published

2014

4. Estrogen reduces mechanical injury-related cell death and proteoglycan degradation in mature articular cartilage independent of the presence of the superficial zone tissue.

Author

Imgenberg J, Rolauffs B, Grodzinsky AJ, Schünke M, and Kurz B

Subjects

Animals, Cartilage, Articular injuries, Cartilage, Articular metabolism, Cartilage, Articular pathology, Cattle, Cell Death drug effects, Estradiol analogs & derivatives, Estrogen Antagonists pharmacology, Fulvestrant, Glycosaminoglycans metabolism, Stress, Mechanical, Tissue Culture Techniques, Cartilage, Articular drug effects, Estradiol pharmacology, Proteoglycans metabolism

Abstract

Objective: To study the effect of 17β-estradiol (E2) and the superficial zone (SFZ) on cell death and proteoglycan degradation in articular cartilage after a single injurious compression in vitro., Method: Cartilage explants from the femoropatellar groove of 2 year old cows with or without the SFZ were cultured serum-free with physiological concentrations of E2 and injured by an unconfined single load compression (strain 50%, velocity 2 mm/s). After 96 h cell death was measured histomorphometrically (nuclear blebbing (NB) and TUNEL staining) and release of glycosaminoglycans (GAG) by DMMB assay., Results: Injurious compression increased significantly the number of cells with NB and TUNEL staining and release of GAG. Physiological concentrations of E2 prevented the injury-related cell death and reduced the GAG release significantly in a receptor-mediated manner (shown by co-stimulation with the antiestrogen fulvestrant/faslodex/ICI-182,780). The presence of the SFZ did not alter the NB response to either the mechanical injury or E2, but reduced the overall release of GAG significantly., Conclusion: E2 prevents injury-related cell death and GAG release, and might be useful for the development of treatment options for either cartilage-related sports injuries or osteoarthritis (OA). The SFZ does not seem to play an important role in (1) the E2-related tissue response and (2) the mechanically-induced cell death in deeper regions of the explants and GAG release. The latter might be related to the unconfined nature of the injury model., (Copyright © 2013 Osteoarthritis Research Society International. Published by Elsevier Ltd. All rights reserved.)

Published

2013

5. Alphav and beta1 integrins regulate dynamic compression-induced proteoglycan synthesis in 3D gel culture by distinct complementary pathways.

Author

Chai DH, Arner EC, Griggs DW, and Grodzinsky AJ

Subjects

Animals, Cartilage, Articular cytology, Cattle, Cells, Cultured, Chondrocytes, Compressive Strength physiology, Culture Techniques methods, Sepharose chemistry, Stress, Mechanical, Cartilage, Articular physiology, Glycosaminoglycans biosynthesis, Integrins antagonists & inhibitors, Proteoglycans biosynthesis

Abstract

Objective: Our goal was to test the hypothesis that specific integrin receptors regulate chondrocyte biosynthetic response to dynamic compression at early times in 3D gel culture, during initial evolution of the pericellular matrix, but prior to significant accumulation of further-removed matrix. The study was motivated by increased use of dynamic loading, in vitro, for early stimulation of tissue engineered cartilage, and the need to understand the effects of loading, in vivo, at early times after implantation of constructs., Methods: Bovine articular chondrocytes were seeded in 2% agarose gels (15x10(6)cells/mL) and incubated for 18 h with and without the presence of specific integrin blockers (small-molecule peptidomimetics, function-blocking antibodies, and RGD-containing disintegrins). Samples were then subjected to a 24-h dynamic compression regime found previously to stimulate chondrocyte biosynthesis in 3D gel as well as cartilage explant culture (1 Hz, 2.5% dynamic strain amplitude, 7% static offset strain). At the end of loading, proteoglycan (PG) synthesis ((35)S-sulfate incorporation), protein synthesis ((3)H-proline incorporation), DNA content (Hoechst dye 33258) and total glycosaminoglycan (GAG) content (dimethyl methylene blue (DMMB) dye binding) were assessed., Results: Consistent with previous studies, dynamic compression increased PG synthesis and total GAG accumulation compared to free-swelling controls. Blocking alphavbeta3 abolished this response, independent of effects on controls, while blocking beta1 abolished the relative changes in synthesis when changes in free-swelling synthesis rates were observed., Conclusions: This study suggests that both alphavbeta3 and beta1 play a role in pathways that regulate stimulation of PG synthesis and accumulation by dynamic compression, but through distinct complementary mechanisms., (Copyright 2009 Osteoarthritis Research Society International. Published by Elsevier Ltd. All rights reserved.)

Published

2010

6. Dynamic compression stimulates proteoglycan synthesis by mesenchymal stem cells in the absence of chondrogenic cytokines.

Author

Kisiday JD, Frisbie DD, McIlwraith CW, and Grodzinsky AJ

Subjects

Animals, Biomechanical Phenomena, Cell Survival, Cells, Cultured, Chondrogenesis drug effects, Horses, Mesenchymal Stem Cells drug effects, Pressure, Tissue Engineering, Chondrogenesis physiology, Mesenchymal Stem Cells metabolism, Proteoglycans biosynthesis, Stress, Mechanical, Transforming Growth Factor beta pharmacology

Abstract

The objective of this study was to evaluate the effect of dynamic compression on mesenchymal stem cell (MSC) chondrogenesis. Dynamic compression was applied to agarose hydrogels seeded with bone marrow-derived adult equine MSCs. In the absence of the chondrogenic cytokine transforming growth factor beta (TGFbeta), dynamic compression applied for 12 h per day led to significantly greater proteoglycan synthesis than in unloaded TGFbeta-free cultures, although at a rate that was approximately 20% to 35% of unloaded TGFbeta cultures. These data suggest that the emergence of aggrecan dominated a chondrogenic response to loading as increases in proteoglycan synthesis. Cross-sectional analyses were conducted to subjectively identify potential spatial distributions of heterogeneous differentiation. In loaded samples, cell viability and metachromatic staining was low near the porous compression platen interface but increased with depth, reaching levels in the lower portion of the hydrogel that resembled unloaded TGFbeta cultures. These results suggest that the combination of high hydrostatic pressure and low dynamic strain and fluid flow had a stronger effect on chondrogenesis than did low hydrostatic pressure coupled with high dynamic strain and fluid flow. Next, the 12-h per day loading protocol was applied in the presence of TGFbeta. Biosynthesis in loaded cultures was less than in unloaded TGFbeta samples. Taken together, these data suggest that the duration of loading necessary to stimulate mechanoinduction of MSCs may not be optimal for neo-tissue accumulation in the presence of chondrogenic cytokines.

Published

2009

7. Mechanical injury potentiates proteoglycan catabolism induced by interleukin-6 with soluble interleukin-6 receptor and tumor necrosis factor alpha in immature bovine and adult human articular cartilage.

Author

Sui Y, Lee JH, DiMicco MA, Vanderploeg EJ, Blake SM, Hung HH, Plaas AH, James IE, Song XY, Lark MW, and Grodzinsky AJ

Subjects

Adult, Animals, Ankle Injuries metabolism, Ankle Injuries pathology, Biomechanical Phenomena, Cartilage, Articular drug effects, Cartilage, Articular pathology, Cattle, Cells, Cultured, Chondrocytes metabolism, Chondrocytes pathology, Disease Models, Animal, Female, Glycosaminoglycans metabolism, Humans, Interleukin-6 pharmacology, Knee Injuries metabolism, Knee Injuries pathology, Male, Middle Aged, Tumor Necrosis Factor-alpha pharmacology, Cartilage, Articular metabolism, Interleukin-6 metabolism, Joints injuries, Proteoglycans metabolism, Receptors, Interleukin-6 metabolism, Tumor Necrosis Factor-alpha metabolism

Abstract

Objective: Traumatic joint injury can damage cartilage and release inflammatory cytokines from adjacent joint tissue. The present study was undertaken to study the combined effects of compression injury, tumor necrosis factor alpha (TNFalpha), and interleukin-6 (IL-6) and its soluble receptor (sIL-6R) on immature bovine and adult human knee and ankle cartilage, using an in vitro model, and to test the hypothesis that endogenous IL-6 plays a role in proteoglycan loss caused by a combination of injury and TNFalpha., Methods: Injured or uninjured cartilage disks were incubated with or without TNFalpha and/or IL-6/sIL-6R. Additional samples were preincubated with an IL-6-blocking antibody Fab fragment and subjected to injury and TNFalpha treatment. Treatment effects were assessed by histologic analysis, measurement of glycosaminoglycan (GAG) loss, Western blot to determine proteoglycan degradation, zymography, radiolabeling to determine chondrocyte biosynthesis, and Western blot and enzyme-linked immunosorbent assay to determine chondrocyte production of IL-6., Results: In bovine cartilage samples, injury combined with TNFalpha and IL-6/sIL-6R exposure caused the most severe GAG loss. Findings in human knee and ankle cartilage were strikingly similar to those in bovine samples, although in human ankle tissue, the GAG loss was less severe than that observed in human knee tissue. Without exogenous IL-6/sIL-6R, injury plus TNFalpha exposure up-regulated chondrocyte production of IL-6, but incubation with the IL-6-blocking Fab significantly reduced proteoglycan degradation., Conclusion: Our findings indicate that mechanical injury potentiates the catabolic effects of TNFalpha and IL-6/sIL-6R in causing proteoglycan degradation in human and bovine cartilage. The temporal and spatial evolution of degradation suggests the importance of transport of biomolecules, which may be altered by overload injury. The catabolic effects of injury plus TNFalpha appeared partly due to endogenous IL-6, since GAG loss was partially abrogated by an IL-6-blocking Fab.

Published

2009

8. Analysis of the relationship between peak stress and proteoglycan loss following injurious compression of human post-mortem knee and ankle cartilage.

Author

Patwari P, Cheng DM, Cole AA, Kuettner KE, and Grodzinsky AJ

Subjects

Compressive Strength, Glycosaminoglycans metabolism, Humans, Regression Analysis, Stress, Mechanical, Ankle pathology, Cartilage pathology, Knee pathology, Proteoglycans metabolism

Abstract

While traumatic joint injuries are known to increase the risk of osteoarthritis (OA), the mechanism is not known. Models for injurious compression of cartilage may identify predictors of injury that suggest a clinical mechanism. We investigated the relationship between peak stress during compression and glycosaminoglycan (GAG) loss after injury for knee and ankle cartilages. Human cartilage explant disks were harvested post-mortem from the knee and ankle of three organ donors with no history of OA and subjected to injurious compression to 65% strain in uniaxial unconfined compression at 2 mm/s (400%/s). The GAG content of the conditioned medium was measured 3 days after injury. After injury of knee cartilage disks, damage was visible in 18 of 39 disks (36%). Three days after injury, the increase in GAG loss to the medium (GAG loss from injured disks minus GAG loss from location-matched uncompressed controls) was 1.5+/-0.3 microg/disk (mean +/- SEM). With final strain and compression velocity held constant, we observed that increasing peak stress during injury was associated with less GAG loss after injury (P<0.001). In contrast, ankle cartilage appeared damaged after injury in only 1 of 16 disks (6%), there was no increase in GAG loss (0.0+/-0.3 microg/disk), and no relationship between peak stress and increase in GAG loss was detected (P=0.51). By itself, increasing peak stress did not appear to be an important cause of GAG loss from human cartilage in our injurious compression model. However, we observed further evidence for differences in the response of knee and ankle cartilages to injury.

Published

2007

9. Analysis of ADAMTS4 and MT4-MMP indicates that both are involved in aggrecanolysis in interleukin-1-treated bovine cartilage.

Author

Patwari P, Gao G, Lee JH, Grodzinsky AJ, and Sandy JD

Subjects

ADAM Proteins, ADAMTS4 Protein, Aggrecans, Animals, Animals, Newborn, Blotting, Western, Cartilage, Articular metabolism, Cattle, Interleukin-1 antagonists & inhibitors, Lectins, C-Type, Matrix Metalloproteinases analysis, Polymerase Chain Reaction methods, Procollagen N-Endopeptidase analysis, Recombinant Proteins pharmacology, Tissue Culture Techniques, Umbelliferones pharmacology, Cartilage, Articular drug effects, Extracellular Matrix Proteins metabolism, Interleukin-1 pharmacology, Matrix Metalloproteinases physiology, Procollagen N-Endopeptidase physiology, Proteoglycans metabolism

Abstract

Objective: To investigate the mechanism of aggrecanolysis in interleukin-1 (IL-1)-treated cartilage tissue by examining the time course of aggrecan cleavages and the tissue and medium content of membrane type 4-matrix metalloproteinases (MT4-MMP) and a disintegrin and metalloproteinase with thrombospondin type I motifs (ADAMTS)4., Methods: Articular cartilage explants were harvested from newborn bovine femoropatellar groove. The effects of IL-1 treatment with or without aggrecanase blockade were investigated by Western analysis of aggrecan fragment generation, ADAMTS4 species (p68 and p53), and MT4-MMP, as well as by realtime PCR (polymerase chain reaction) for ADAMTS4 and 5. Aggrecanase was blocked with mannosamine (ManN), an inhibitor of glycosylphosphatidylinositol anchor synthesis, and esculetin (EST), an inhibitor of MMP-1, MMP-3, and MMP-13 gene expression., Results: IL-1 treatment caused a major increase in MT4-MMP abundance in the tissue and medium. ADAMTS4 (p68) was abundant in fresh cartilage and this was retained in the tissue in untreated cartilage. IL-1 treatment for 6 days caused a marked loss of p68 from the cartilage and the appearance of p53 in the medium. Addition of either 1.35 mM ManN or 31-500 microM EST blocked IL-1-mediated aggrecanolysis and this was accompanied by nearly complete inhibition of the MT4-MMP increase, the p68 loss and the formation of p53. IL-1 treatment increased mRNA abundance for ADAMTS4 ( approximately 3-fold) and ADAMTS5 ( approximately 10-fold) but this was not accompanied by a marked change in enzyme protein abundance., Conclusion: These studies support a central role for MT4-MMP in IL-1-induced cartilage aggrecanolysis and are consistent with the identification of p68 as the aggrecanase that cleaves within the CS2 domain, and of p53 as the aggrecanase that generates G1-NITEGE. Since the induction by IL-1 was not accompanied by marked changes in total ADAMTS4 protein, but rather in partial conversion of p68 to p53 and release of both from the tissue, we conclude that aggrecanolysis in this model system results from MT4-MMP-mediated processing of a resident pool of ADAMTS4 and release of the p68 and p53 from their normal association with the cell surface.

Published

2005

10. Individual cartilage aggrecan macromolecules and their constituent glycosaminoglycans visualized via atomic force microscopy.

Author

Ng L, Grodzinsky AJ, Patwari P, Sandy J, Plaas A, and Ortiz C

Subjects

Aggrecans, Animals, Cattle, Glycosaminoglycans ultrastructure, Image Processing, Computer-Assisted, Lectins, C-Type, Macromolecular Substances, Microscopy, Atomic Force, Molecular Structure, Particle Size, Proteoglycans isolation & purification, Proteoglycans ultrastructure, Cartilage chemistry, Extracellular Matrix Proteins, Glycosaminoglycans chemistry, Proteoglycans chemistry

Abstract

Atomic force microscopy was used in ambient conditions to directly image dense and sparse monolayers of bovine fetal epiphyseal and mature nasal cartilage aggrecan macromolecules adsorbed on mica substrates. Distinct resolution of the non-glycosylated N-terminal region from the glycosaminoglycan (GAG) brush of individual aggrecan monomers was achieved, as well as nanometer-scale resolution of individual GAG chain conformation and spacing. Fetal aggrecan core protein trace length (398+/-57 nm) and end-to-end length (257+/-87 nm) were both larger than that of mature aggrecan (352+/-88 and 226+/-81 nm, respectively). Similarly, fetal aggrecan GAG chain trace length (41+/-7 nm) and end-to-end (32+/-8 nm) length were both larger than that of mature aggrecan GAG (32+/-5 and 26+/-7 nm, respectively). GAG-GAG spacing along the core protein was significantly smaller in fetal compared to mature aggrecan (3.2+/-0.8 and 4.4+/-1.2nm, respectively). Together, these differences between the two aggrecan types were likely responsible for the greater persistence length of the fetal aggrecan (110 nm) compared to mature aggrecan (82 nm) calculated using the worm-like chain model. Measured dimensions and polymer statistical analyses were used in conjunction with the results of Western analyses, chromatographic, and carbohydrate electrophoresis measurements to better understand the dependence of aggrecan structure and properties on its constituent GAG chains.

Published

2003

11. Proteoglycan degradation after injurious compression of bovine and human articular cartilage in vitro: interaction with exogenous cytokines.

Author

Patwari P, Cook MN, DiMicco MA, Blake SM, James IE, Kumar S, Cole AA, Lark MW, and Grodzinsky AJ

Subjects

Adult, Animals, Animals, Newborn, Ankle Joint, Cartilage, Articular drug effects, Cartilage, Articular injuries, Cattle, Collagenases genetics, Collagenases metabolism, Culture Media, Conditioned chemistry, Cycloheximide pharmacology, Humans, In Vitro Techniques, Knee Joint, Matrix Metalloproteinase 13, Matrix Metalloproteinase 3 genetics, Matrix Metalloproteinase 3 metabolism, Protein Synthesis Inhibitors pharmacology, RNA, Messenger metabolism, Stress, Mechanical, Up-Regulation, Cartilage, Articular metabolism, Interleukin-1 pharmacology, Proteoglycans metabolism, Tumor Necrosis Factor-alpha pharmacology

Abstract

Objective: Traumatic joint injury leads to an increased risk of osteoarthritis (OA), but the progression to OA is not well understood. We undertook this study to measure aspects of proteoglycan (PG) degradation after in vitro injurious mechanical compression, including up-regulation of enzymatic degradative expression and cytokine-stimulated degradation., Methods: Articular cartilage tissue explants were obtained from newborn bovine femoropatellar groove and from adult normal human donor knee and ankle tissue. Following injurious compression of the cartilage, matrix metalloproteinase 3 (MMP-3) and MMP-13 messenger RNA (mRNA) expression levels were measured by Northern analysis, and PG loss to the medium after cartilage injury was measured in the presence and absence of added exogenous cytokine (interleukin-1alpha [IL-1alpha] or tumor necrosis factor alpha [TNFalpha])., Results: During the first 24 hours after injury in bovine cartilage, MMP-3 mRNA levels increased 10-fold over the levels in control cartilage (n = 3 experiments), whereas MMP-13 mRNA levels were unchanged. PG loss was significantly increased after injury, but only by 2% of the total PG content and only for the first 3 days following injury. However, compared with injury alone or cytokine treatment alone, treatment of injured tissue with either 1 ng/ml IL-1alpha or 100 ng/ml TNFalpha caused marked increases in PG loss (35% and 54%, respectively, of the total cartilage PG content). These interactions between cytokine treatment and injury were statistically significant. In human knee cartilage, the interaction was also significant for both IL-1alpha and TNFalpha, although the magnitude of increase in PG loss was lower than that in bovine cartilage. In contrast, in human ankle cartilage, there was no significant interaction between injury and IL-1alpha., Conclusion: The cytokines IL-1alpha and TNFalpha can cause a synergistic loss of PG from mechanically injured bovine and human cartilage. By attempting to incorporate interactions with other joint tissues that may be sources of cytokines, in vitro models of mechanical cartilage injury may explain aspects of the interactions between mechanical forces and degradative pathways which lead to OA progression.

Published

2003

12. Biosynthetic response of passaged chondrocytes in a type II collagen scaffold to mechanical compression.

Author

Lee CR, Grodzinsky AJ, and Spector M

Subjects

Animals, Biocompatible Materials metabolism, Biomechanical Phenomena, Cartilage, Articular cytology, Cells, Cultured, Chondrocytes cytology, Compressive Strength, Dogs, Materials Testing, Proline metabolism, Stress, Mechanical, Sulfates metabolism, Chondrocytes metabolism, Collagen Type II metabolism, Proteins metabolism, Proteoglycans metabolism, Tissue Engineering

Abstract

To investigate the potential utility of mechanical loading in articular cartilage tissue engineering, porous type II collagen scaffolds seeded with adult canine passaged chondrocytes were subjected to static and dynamic compressions of varying magnitudes (0-50% static strain) and durations (1-24 h), and at different times during culture (2-30 days postseeding). The effects of mechanical compression on the biosynthetic activity of the chondrocytes were evaluated by measuring the amount of (3)H-proline-labeled proteins and (35)S-sulfate-labeled proteoglycans that accumulated in the cell-scaffold construct and was released to the medium during the loading period. Similar to published results on loading of articular cartilage explants, static compression decreased protein and proteoglycan biosynthesis in a time- and dose-dependent manner (each p < 0.005), and selected dynamic compression protocols were able to increase rates of biosynthesis (p < 0.05). The main difference between the results seen for this tissue engineering system and cartilage explants was in the amount of newly synthesized matrix molecules that accumulated within the construct under dynamic loading, with less accumulating in the type II collagen scaffold. In summary, the general biosynthetic response of passaged chondrocytes in the porous type II collagen scaffolds is similar to that seen for chondrocytes in their native environment. Future work needs to be directed to modifications of the cell-seeded construct to allow for the capture of the newly synthesized matrix molecules by the scaffold., (Copyright 2003 Wiley Periodicals, Inc.)

Published

2003

13. Proteoglycan deposition around chondrocytes in agarose culture: construction of a physical and biological interface for mechanotransduction in cartilage.

Author

Quinn TM, Schmid P, Hunziker EB, and Grodzinsky AJ

Subjects

Animals, Cattle, Cell Size, Cells, Cultured, Time Factors, Cartilage, Articular metabolism, Chondrocytes physiology, Extracellular Matrix Proteins metabolism, Proteoglycans metabolism, Tissue Engineering

Abstract

With a view towards the development of methods for cartilage tissue engineering, matrix deposition around individual chondrocytes was studied during de novo matrix synthesis in agarose suspension culture. At a range of times in culture from 2 days to 1 month (long enough for cartilage-like material properties to begin to emerge), pericellular distributions of proteoglycan and matrix protein deposition were measured by quantitative autoradiography, while matrix accumulation and cell volumes were estimated by stereological methods. Consistent with previous work, tissue-average rates of matrix synthesis generally decreased asymptotically with time in culture, as de novo matrix accumulated. Cell-scale analysis revealed that this evolution was accompanied by a transition from predominantly pericellular matrix (within a few microm from the cell membrane) deposition early in culture towards proteoglycan and protein deposition patterns more similar to those observed in cartilage explants at later times. This finding may suggest a differential recruitment of different proteoglycan metabolic pools as matrix assembly progresses. Cell volumes increased with time in culture, suggestive of alterations in volume regulatory processes associated with changes in the microphysical environment. Results emphasize a pattern of de novo matrix construction which proceeds outward from the pericellular matrix in a progressive fashion. These findings provide cell-scale insight into the mechanisms of assembly of matrix proteins and proteoglycans in de novo matrix, and may aid in the development of tissue engineering methods for cartilage repair.

Published

2002

14. Down-regulation of chondrocyte aggrecan and type-II collagen gene expression correlates with increases in static compression magnitude and duration.

Author

Ragan PM, Badger AM, Cook M, Chin VI, Gowen M, Grodzinsky AJ, and Lark MW

Subjects

Aggrecans, Animals, Cattle, Down-Regulation, Lectins, C-Type, Proline metabolism, Stress, Mechanical, Sulfates metabolism, Time Factors, Chondrocytes metabolism, Collagen genetics, Extracellular Matrix Proteins, Gene Expression Regulation, Proteoglycans genetics

Abstract

The goal of this study was to examine the simultaneous effects of mechanical compression of chondrocytes on mRNA expression and macromolecular synthesis of aggrecan and type-II collagen. Bovine cartilage explants were exposed to different magnitudes and durations of applied mechanical compression, and levels of aggrecan and type-IIa collagen mRNA normalized to glyceraldehyde-3-phosphate dehydrogenase were measured and quantified by Northern blot analysis. Synthesis of aggrecan and type-II collagen protein was measured by radiolabel incorporation of [35S]sulfate and [3H]proline into macromolecules. The results showed a dose-dependent decrease in mRNA levels for aggrecan and type-II collagen, with increasing compression relative to physiological cut thickness applied for 24 hours. Radiolabel incorporation into glycosaminoglycans and collagen also decreased with increasing compression in a dose-related manner similar to the changes seen in mRNA expression. The modulation of aggrecan and type-II collagen mRNA and protein synthesis were dependent on the duration of the compression. Aggrecan and type-II collagen mRNA expression increased during the initial 0.5 hours of static compression; however, 4-24 hours after compression was applied total mRNA levels had significantly decreased. The synthesis of aggrecan and collagen protein decreased more rapidly than did mRNA levels after the application of a step compression. Together, these results suggest that mechanical compression rapidly alters chondrocyte aggrecan and type-II collagen gene expression on application of load. However, our results indicate that the observed decreases in biosynthesis may not be related solely to changes in mRNA expression. The mechanisms by which mechanical forces affect different segments of the biosynthetic pathways remain to be determined.

Published

1999

15. Physical and biological regulation of proteoglycan turnover around chondrocytes in cartilage explants. Implications for tissue degradation and repair.

Author

Quinn TM, Maung AA, Grodzinsky AJ, Hunziker EB, and Sandy JD

Subjects

Animals, Cartilage, Articular cytology, Cattle, Cell Membrane metabolism, Extracellular Matrix metabolism, Glycosaminoglycans biosynthesis, Kinetics, Male, Organ Culture Techniques, Proteoglycans biosynthesis, Radioisotope Dilution Technique, Sulfates metabolism, Sulfur Radioisotopes, Time Factors, Cartilage, Articular metabolism, Glycosaminoglycans metabolism, Proteoglycans metabolism

Abstract

The development of clinical strategies for cartilage repair and inhibition of matrix degradation may be facilitated by a better understanding of (1) the chondrocyte phenotype in the context of a damaged extracellular matrix, and (2) the roles of biochemical and biomechanical pathways by which matrix metabolism is mediated. Using methods of quantitative autoradiography, we examined the cell-length scale patterns of proteoglycan deposition and turnover in the cell-associated matrices of chondrocytes in adult bovine and calf cartilage explants. Results highlight a rapid turnover in the pericellular matrix, which may indicate spatial organization of PG metabolic pools, and specific biomechanical roles for different matrix regions. Subsequent to injurious compression of calf explants, which resulted in grossly visible tissue cracks and caused a decrease in the number of viable chondrocytes within explants, cell-mediated matrix catabolic processes appeared to increase, resulting in apparently increased rates of proteoglycan turnover around active cells. Furthermore, the influences of cell-stimulatory factors such as IL-1 beta appeared to be delayed in their effects subsequent to injurious compression, suggesting interactions between biomechanical and biochemical pathways of PG degradation. These results may provide a useful reference point in the development of in vitro models for cartilage injury and disease, and hint at possible new approaches in the development of cartilage repair strategies.

Published

1999

16. Stimulation of aggrecan synthesis in cartilage explants by cyclic loading is localized to regions of high interstitial fluid flow.

Author

Buschmann MD, Kim YJ, Wong M, Frank E, Hunziker EB, and Grodzinsky AJ

Subjects

Aggrecans, Animals, Cattle, Culture Techniques, Femur, Lectins, C-Type, Patella, Pulsatile Flow, Weight-Bearing, Cartilage physiology, Extracellular Matrix Proteins, Extracellular Space physiology, Proteoglycans biosynthesis

Abstract

Chondrogenesis in cartilage development and repair and cartilage degeneration in arthritis can be regulated by mechanical-load-induced physical factors such as tissue deformation, interstitial fluid flow and pressure, and electrical fields or streaming potentials. Previous animal and tissue explant studies have shown that time-varying dynamic tissue loading can increase the synthesis and deposition of matrix molecules in an amplitude-, frequency-, and spatially dependent manner. To provide information on the cell-level physical factors which may stimulate chondrocytes to increase production and export of aggrecan, the main proteoglycan component of the cartilage matrix, we characterized local changes in aggrecan synthesis within cyclically loaded tissue explant disks and compared those changes to values of predicted local physical factors. Aggrecan synthesis following a 23-h compression/radiolabel protocol was measured with a spatial resolution of approximately 0.1 mm across the 1.5-mm radius of explanted disks using a quantitative autoradiography method. A uniform stimulation of aggrecan synthesis was observed at an intermediate frequency of 0.01 Hz, while, at a higher frequency of 0.1 Hz, stimulation was only seen at peripheral radial positions. Profiles of radial solid matrix deformation and interstitial fluid pressure and velocity predicted to be occurring across the radius of the disk during sinusoidal loading were estimated using a composite poroelastic model. Tissue regions experiencing high interstitial fluid velocities corresponded to those displaying increased aggrecan synthesis. These results reinforce the role of load-induced flow of interstitial fluid in the stimulation of aggrecan production during dynamic loading of cartilage., (Copyright 1999 Academic Press.)

Published

1999

17. Mechanical compression alters proteoglycan deposition and matrix deformation around individual cells in cartilage explants.

Author

Quinn TM, Grodzinsky AJ, Buschmann MD, Kim YJ, and Hunziker EB

Subjects

Animals, Autoradiography, Cattle, Chondrocytes ultrastructure, Physical Stimulation, Proteoglycans biosynthesis, Stress, Mechanical, Cartilage cytology, Chondrocytes metabolism, Extracellular Matrix ultrastructure, Proteoglycans metabolism

Abstract

We have used new techniques of cell-length scale quantitative autoradiography to assess matrix synthesis, deposition, and deformation around individual chondrocytes in mechanically compressed cartilage explants. Our objectives were to: (1) quantify the effects of static and dynamic compression on the deposition of newly synthesized proteoglycans into cell-associated and further-removed matrices; (2) measure cell-length scale matrix strains and morphological changes of the cell and matrix associated with tissue compression; and (3) relate microscopic physical stimuli to changes in proteoglycan synthesis as functions of compression level and position within mechanically compressed explants. Results indicate a high degree of structural organization in the extracellular matrix, with the pericellular matrix associated with the most rapid rates of proteoglycan deposition, and greatest sensitivity to mechanical compression. Static compression could stimulate directional deposition of secreted proteoglycans around chondrocytes, superimposed on an inhibition of proteoglycan synthesis; these events followed trends for compressive strain in the cell-associated matrix. Conversely, proteoglycan synthesis and pericellular deposition was stimulated by dynamic compression. Results suggest that cell-matrix interactions in the cell-associated matrix may be a particularly important aspect of the chondrocyte response to mechanical compression, possibly involving macromolecular transport limitations and morphological changes associated with fluid flow and local compaction of the matrix around cells.

Published

1998

18. Compression of cartilage results in differential effects on biosynthetic pathways for aggrecan, link protein, and hyaluronan.

Author

Kim YJ, Grodzinsky AJ, and Plaas AH

Subjects

Aggrecans, Animals, Cartilage, Articular drug effects, Cartilage, Articular metabolism, Cattle, Cycloheximide pharmacology, Kinetics, Lectins, C-Type, Leucine metabolism, Organ Culture Techniques, Stress, Mechanical, Sulfates metabolism, Sulfur Radioisotopes, Time Factors, Tritium, Cartilage, Articular physiology, Extracellular Matrix Proteins, Hyaluronic Acid biosynthesis, Protein Biosynthesis, Proteoglycans biosynthesis

Abstract

The differential effects of static compression and recovery from compression on biosynthesis and biosynthetic pathways of aggrecan, link protein, and hyaluronan were assessed. During compression, biosynthesis of aggrecan and link protein were inhibited to approximately 25 and approximately 40%, respectively, of free-swelling control levels. In marked contrast, hyaluronan synthesis was unaffected by static compression. After release from 12-h 50% static compression, aggrecan synthesis remained inhibited for up to 2.5 days; however, link protein synthesis completely recovered to free-swelling control levels within 8 h after release. Hyaluronan synthesis remained at control levels after release of compression. During compression, aggrecan core protein pool size was decreased, whereas the rate of processing into the proteoglycan form remained essentially the same as in free swelling control tissue. Four hours after release from compression, aggrecan core protein pool size remained small and the rate of intracellular processing of aggrecan had become slower than that of free swelling control tissue. Due to the altered core-protein processing kinetics, fewer but longer chondroitin sulfate chains were added to the core proteins. Sulfation was not markedly altered. The differential effects of static compression and release on the biosynthesis of aggrecan, link protein, and hyaluronan are similar to the changes in the biosynthetic pathways that are affected in response to IL-1 treatment, suggesting that the response to static compression is not a general inhibition of cellular activity, but appears to be part of a specific transduction mechanism.

Published

1996

19. Altered aggrecan synthesis correlates with cell and nucleus structure in statically compressed cartilage.

Author

Buschmann MD, Hunziker EB, Kim YJ, and Grodzinsky AJ

Subjects

Aggrecans, Animals, Cartilage ultrastructure, Cattle, Cell Nucleus metabolism, Cells metabolism, Culture Techniques, Dehydration, Epoxy Resins, Lectins, C-Type, Microtomy, Plastic Embedding, Tissue Fixation, Cartilage metabolism, Extracellular Matrix Proteins, Proteoglycans biosynthesis

Abstract

Previous studies have shown that static equilibrium compression of cartilage tissue in vivo and in vitro decreases chondrocyte synthesis of aggrecan molecules. In order to identify mechanisms of cellular response to loading, we have investigated alterations in cell and nucleus structure and the accompanying changes in the synthesis of aggrecan in statically compressed cartilage explants. Using glutaraldehyde fixation and quantitative autoradiography of compressed and radiolabeled cartilage disks we spatially localized newly synthesized aggrecan. Using stereological tools to analyze these same specimens we estimated the cell and nucleus volume, surface area and directional radii. We found that aggrecan synthesis was reduced overall in compressed tissue disks. However, the compression induced a spatial (radial) inhomogeneity in aggrecan synthesis which was not present in uncompressed disks. This spatial inhomogeneity appeared to be directly related to mechanical boundary conditions and the manner in which the load was applied and, therefore, may represent a spatially specific functional adaptation to mechanical loading. Coincident with reduced aggrecan synthesis, we observed reductions in cell and nucleus volume and radii in the direction of compression which were in approximate proportion to the reduction in tissue thickness. Cell and nucleus dimensions perpendicular to the direction of compression did not change significantly. Therefore the observed deformation of the cell and nucleus in statically compressed cartilage approximately followed the dimensional changes imposed on external specimen surfaces. The strong correlation observed between local changes in aggrecan synthesis and alterations in cell and nucleus structure also lend support to certain hypotheses regarding the intracellular signal transduction pathways that may be important in the biosynthetic response of chondrocytes to mechanical loading.

Published

1996

20. A molecular model of proteoglycan-associated electrostatic forces in cartilage mechanics.

Author

Buschmann MD and Grodzinsky AJ

Subjects

Animals, Biomechanical Phenomena, Biomedical Engineering, Cattle, Electrochemistry, In Vitro Techniques, Osmotic Pressure, Solutions, Stress, Mechanical, Cartilage, Articular metabolism, Cartilage, Articular physiology, Models, Biological, Proteoglycans metabolism

Abstract

Measured values of the swelling pressure of charged proteoglycans (PG) in solution (Williams RPW, and Comper WD; Biophysical Chemistry 36:223, 1990) and the ionic strength dependence of the equilibrium modulus of PG-rich articular cartilage (Eisenberg SR, and Grodzinsky AJ; J Orthop Res 3: 148, 1985) are compared to the predictions of two models. Each model is a representation of electrostatic forces arising from charge present on spatially fixed macromolecules and spatially mobile micro-ions. The first is a macroscopic continuum model based on Donnan equilibrium that includes no molecular-level structure and assumes that the electrical potential is spatially invariant within the polyelectrolyte medium (i.e. zero electric field). The second model is based on a microstructural, molecular-level solution of the Poisson-Boltzmann (PB) equation within a unit cell containing a charged glycosaminoglycan (GAG) molecule and its surrounding atmosphere of mobile ions. This latter approach accounts for the space-varying electrical potential and electrical field between the GAG constituents of the PG. In computations involving no adjustable parameters, the PB-cell model agrees with the measured pressure of PG solutions to within experimental error (10%), whereas the ideal Donnan model overestimates the pressure by up to 3-fold. In computations involving one adjustable parameter for each model, the PB-cell model predicts the ionic strength dependence of the equilibrium modulus of articular cartilage. Near physiological ionic strength, the Donnan model overpredicts the modulus data by 2-fold, but the two models coincide for low ionic strengths (C0 < 0.025M) where the spatially invariant Donnan potential is a closer approximation to the PB potential distribution. The PB-cell model result indicates that electrostatic forces between adjacent GAGs predominate in determining the swelling pressure of PG in the concentration range found in articular cartilage (20-80 mg/ml). The PB-cell model is also consistent with data (Eisenberg and Grodzinsky, 1985, Lai WM, Hou JS, and Mow VC; J Biomech Eng 113: 245, 1991) showing that these electrostatic forces account for approximately 1/2 (290kPa) the equilibrium modulus of cartilage at physiological ionic strength while absolute swelling pressures may be as low as approximately 25-100kPa. This important property of electrostatic repulsion between GAGs that are highly charged but spaced a few Debye lengths apart allows cartilage to resist compression (high modulus) without generating excessive intratissue swelling pressures.

Published

1995

21. Mechanical compression modulates matrix biosynthesis in chondrocyte/agarose culture.

Author

Buschmann MD, Gluzband YA, Grodzinsky AJ, and Hunziker EB

Subjects

Animals, Cartilage, Articular cytology, Cartilage, Articular ultrastructure, Cattle, Cells, Cultured, Culture Techniques methods, Extracellular Matrix Proteins antagonists & inhibitors, Kinetics, Microscopy, Electron, Proline metabolism, Sepharose, Stress, Mechanical, Sulfates metabolism, Sulfur Radioisotopes, Time Factors, Tritium, Cartilage, Articular physiology, Extracellular Matrix Proteins biosynthesis, Glycosaminoglycans biosynthesis, Proteoglycans biosynthesis

Abstract

This study focuses on the effect of static and dynamic mechanical compression on the biosynthetic activity of chondrocytes cultured within agarose gel. Chondrocyte/agarose disks (3 mm diameter) were placed between impermeable platens and subjected to uniaxial unconfined compression at various times in culture (2-43 days). [35S]sulfate and [3H]proline radiolabel incorporation were used as measures of proteoglycan and protein synthesis, respectively. Graded levels of static compression (up to 50%) produced little or no change in biosynthesis at very early times, but resulted in significant decreases in synthesis with increasing compression amplitude at later times in culture; the latter observation was qualitatively similar to that seen in intact cartilage explants. Dynamic compression of approximately 3% dynamic strain amplitude (approximately equal to 30 microns displacement amplitude) at 0.01-1.0 Hz, superimposed on a static offset compression, stimulated radiolabel incorporation by an amount that increased with time in culture prior to loading as more matrix was deposited around and near the cells. This stimulation was also similar to that observed in cartilage explants. The presence of greater matrix content at later times in culture also created differences in biosynthetic response at the center versus near the periphery of the 3 mm chondrocyte/agarose disks. The fact that chondrocyte response to static compression was significantly affected by the presence or absence of matrix, as were the physical properties of the disks, suggested that cell-matrix interactions (e.g. mechanical and/or receptor mediated) and extracellular physicochemical effects (increased [Na+], reduced pH) may be more important than matrix-independent cell deformation and transport limitations in determining the biosynthetic response to static compression. For dynamic compression, fluid flow, streaming potentials, and cell-matrix interactions appeared to be more significant as stimuli than the small increase in fluid pressure, altered molecular transport, and matrix-independent cell deformation. The qualitative similarity in the biosynthetic response to mechanical compression of chondrocytes cultured in agarose gel and chondrocytes in intact cartilage further indicates that gel culture preserves certain physiological features of chondrocyte behavior and can be used to investigate chondrocyte response to physical and chemical stimuli in a controlled manner.

Published

1995

22. Differential effects of bFGF and IGF-I on matrix metabolism in calf and adult bovine cartilage explants.

Author

Sah RL, Chen AC, Grodzinsky AJ, and Trippel SB

Subjects

Aging metabolism, Cartilage, Articular cytology, Cartilage, Articular drug effects, Collagen biosynthesis, Dose-Response Relationship, Drug, Extracellular Matrix drug effects, Extracellular Matrix metabolism, Hydroxyproline metabolism, Kinetics, Mitosis drug effects, Organ Culture Techniques, Proline metabolism, Proteoglycans biosynthesis, Sulfates metabolism, Sulfur Radioisotopes, Tritium, Cartilage, Articular metabolism, Collagen metabolism, Fibroblast Growth Factor 2 pharmacology, Insulin-Like Growth Factor I pharmacology, Proteoglycans metabolism

Abstract

The effects of basic fibroblast growth factor (bFGF) and insulin-like growth factor-I (IGF-I) on cell and matrix metabolism in calf and adult bovine cartilage explants were examined. In calf cartilage, bFGF elicited dose-dependent and bi-directional effects on mitotic activity and anabolic processes. Addition of bFGF at 3 ng/ml stimulated cell mitotic activity (total DNA) and synthesis of proteoglycan ([35S]sulfate incorporation), protein ([3H]proline incorporation), and collagen (formation of [3H]hydroxyproline), and resulted in a slight increase in proteoglycan deposition compared to basal medium. However, 30-300 ng/ml of bFGF inhibited mitotic activity and synthetic processes, accelerated [35S]proteoglycan release compared to basal medium, and resulted in an inhibition of proteoglycan deposition during the culture period. In contrast, treatment of adult cartilage with 3-300 ng/ml of bFGF did not affect the DNA content but did stimulate synthetic processes in a dose-dependent manner. Basic FGF also had bidirectional effects on matrix catabolism in adult cartilage, with 3 ng/ml accelerating [35S]proteoglycan release, but 30-300 ng/ml of bFGF resulting in release rates comparable to that in basal medium. Nonetheless, even with maximal bFGF stimulation, adult bovine cartilage suffered a net loss of proteoglycan during culture. Addition of 3-300 ng/ml of IGF-I to either calf or adult bovine cartilage stimulated synthetic processes and shifted the metabolic balance toward a net deposition of proteoglycan. Neither bFGF nor IGF-I altered the low basal rate of [3H]hydroxyproline release from either calf or adult bovine cartilage. Thus, (i) the regulatory effects of bFGF and IGF-I on bovine articular cartilage appear age-dependent, and (ii) bFGF is capable of promoting either anabolic or catabolic processes, and may therefore serve a dual role in the regulation of cartilage metabolism.

Published

1994

23. Effects of compression on the loss of newly synthesized proteoglycans and proteins from cartilage explants.

Author

Sah RL, Doong JY, Grodzinsky AJ, Plaas AH, and Sandy JD

Subjects

Animals, Cattle, Hydroxyproline analysis, Kinetics, Organ Culture Techniques, Pressure, Proline metabolism, Proteins isolation & purification, Proteoglycans isolation & purification, Stress, Mechanical, Sulfates metabolism, Sulfur Radioisotopes, Tritium, Cartilage, Articular metabolism, Protein Biosynthesis, Proteoglycans biosynthesis

Abstract

The effects of mechanical compression of calf cartilage explants on the catabolism and loss into the medium of proteoglycans and proteins radiolabeled with [35S]sulfate and [3H]proline were examined. A single 2- or 12-h compression of 3-mm diameter cartilage disks from a thickness of 1.25 to 0.50 mm, or slow cyclic compression (2 h on/2 h off) from 1.25 mm to 1.00, 0.75, or 0.50 mm for 24 h led to transient alterations and/or sustained increases in loss of radiolabeled macromolecules. The effects of imposing or removing loads were consistent with several compression-induced physical mediators including fluid flow, diffusion, and matrix disruption. Cyclic compression induced convective fluid flow and enhanced the loss of 35S- and 3H-labeled macromolecules from tissue into medium. In contrast, prolonged static compression induced matrix consolidation and appeared to hinder the diffusional transport and loss of 35S- and 3H-labeled macromolecules. Since high amplitude cyclic compression led to a sustained increase in the rate of loss of 3H- and 35S-labeled macromolecules that was accompanied by an increase in the rate of loss of [3H]hydroxyproline residues and an increase in tissue hydration, such compression may have caused disruption of the collagen meshwork. The 35S-labeled proteoglycans lost during such cyclic compression were of smaller average size than those from controls, but contained a similarly low proportion (approximately 15%) that could form aggregates with excess hyaluronate and link protein. The size distribution and aggregability of the remaining tissue proteoglycans and 35S-labeled proteoglycans were not markedly affected. The loss of tissue proteoglycan paralleled the loss of 35S-labeled macromolecules. This study provides a framework for elucidating the biophysical mechanisms involved in the redistribution, catabolism, and loss of macromolecules during cartilage compression.

Published

1991

24. Effects of tissue compression on the hyaluronate-binding properties of newly synthesized proteoglycans in cartilage explants.

Author

Sah RL, Grodzinsky AJ, Plaas AH, and Sandy JD

Subjects

Animals, Cattle, Hydrogen-Ion Concentration, In Vitro Techniques, Pressure, Proteoglycans isolation & purification, Sulfur Radioisotopes, Cartilage metabolism, Hyaluronic Acid metabolism, Proteoglycans metabolism

Abstract

The effects of tissue compression on the hyaluronate-binding properties of newly synthesized proteoglycans in calf cartilage explants were examined. Pulse-chase experiments showed that conversion of low-affinity monomers to the high-affinity form (that is, to a form capable of forming aggregates with 1.6% hyaluronate on Sephacryl S-1000) occurred with a t1/2 of about 5.7 h in free-swelling discs at pH 7.45. Static compression during chase (in pH 7.45 medium) slowed the conversion, as did incubation in acidic medium (without compression). Both effects were dose-dependent. For example, the t1/2 for conversion was increased to about 11 h by either (1) compression from a thickness of 1.25 mm to 0.5 mm or (2) medium acidification from pH 7.45 to 6.99. Oscillatory compression of 2% amplitude at 0.001, 0.01, or 0.1 cycles/s during chase did not, however, affect the conversion. Changes in the hyaluronate-binding affinity of [35S]proteoglycans in these experiments were accompanied by no marked change in the high percentage (approximately 80%) of monomers which could form aggregates with excess hyaluronate and link protein. Since static tissue compression would result in an increased matrix proteoglycan concentration and thereby a lower intra-tissue pH [Gray, Pizzanelli, Grodzinsky & Lee (1988) J. Orthop. Res. 6, 777-792], it seems likely that matrix pH may influence proteoglycan aggregate assembly by an effect on the hyaluronate-binding affinity of proteoglycan monomer. Such a pH mechanism might have a physiological role, promoting proteoglycan deposition in regions of low proteoglycan concentration.

Published

1990