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OBJECTIVE: In previous studies, we suggested that cathepsin B, which is present at sites of cartilage remodeling in osteoarthritis (OA), may act as an antagonist of cartilage repair, an enhancer of the action of metalloproteinases, and a mediator of cartilage neovascularization and mineralization. Alternative splicing of cathepsin B pre-messenger RNA (pre-mRNA) and/or mRNA overexpression is a plausible regulatory mechanism. In the present study, we investigated the abundance of cathepsin B transcripts and the properties of cathepsin B protein in normal and OA cartilage, osteophytes, and cultured chondrocytes. METHODS: Cathepsin B mRNA splice variants containing the full-length transcript (CB) and the variants lacking either exon 2 (CB[-2]) or lacking exons 2 and 3 (CB[-2,3]) were measured by semiquantitative reverse transcription-polymerase chain reaction (RT-PCR) and Northern blot assays and were localized by in situ RT-PCR. Cathepsin B protein was analyzed by electrophoretic, Western blot, and chromatographic methods. RESULTS: The relative content of CB, CB(-2), and CB(-2,3) varied considerably in OA cartilage and osteophytes, with less variation in normal cartilage. The mean cathepsin B mRNA level was significantly higher in OA cartilage and osteophytes than in normal cartilage. Normal cultured chondrocytes attained cathepsin B mRNA levels similar to those in OA cartilage. Enzyme overexpression resulted in the secretion of procathepsin B, followed by activation to the proteolytically active form. CONCLUSION: The high levels of CB and CB(-2) are consistent with an overproduction of secreted procathepsin B in OA. Up-regulation of chondrocyte cathepsin B, which takes place at both the transcriptional and the translational level, suggests a leading role of the enzyme in the progression of OA.

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OBJECTIVE: Aseptic prosthesis loosening (APL) is related to the formation and aggressive growth of a synovial-like interface membrane (SLIM) between prosthesis and bone. However, investigation of the early phases of SLIM development in humans presents major difficulties. This study was undertaken to develop and characterize the usefulness of a novel animal model of APL that is based on an established model of defined exercise in a running wheel by Wistar rats that have been subjected to intracranial self-stimulation (ICSS). METHODS: Cemented tibial hemiarthroplasties were implanted into the left knees of 7 male Wistar rats. After 2 weeks, exercise in a running wheel was started in all rats, with a running-load of 2 hours/day for 5 days/week. Six months postoperatively, the knee joints were removed, decalcified, and embedded in paraffin. Histologic evaluation on hematoxylin and eosin-stained sections was performed to investigate the development of a SLIM and the presence of cement debris particles. To characterize the SLIM on a molecular level and investigate growth-regulating factors, the expression of transforming growth factor beta (TGFbeta) and the anti-apoptotic molecule Bcl-2 was analyzed by immunohistochemistry. RESULTS: Although the prostheses appeared mechanically stable after 6 months, the development of SLIM with areas of bone resorption was seen in all samples. Resembling human SLIM, these membranes consisted of loose fibrous tissue, with cement debris particles located particularly at sites originally attached to the prostheses. Immunohistochemistry studies revealed the expression of TGFbeta and Bcl-2 in all specimens. Interestingly, staining for TGFbeta and Bcl-2 was restricted to areas where the SLIM were attached to bone. In contrast, there was only negligible expression of both proteins at sites adjacent to the prostheses. CONCLUSION: Our findings demonstrate that the ICSS Wistar rat model constitutes a feasible tool for studying early stages of APL, and specifically the effect of defined running exercise on SLIM formation. The results further suggest that both cellular proliferation, as stimulated by TGFbeta, and altered apoptosis contribute to early stages of SLIM formation. The expression patterns of TGFbeta and Bcl-2 indicate that the growth of the SLIM is initiated and promoted from the bone rather than from the prosthesis.

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OBJECTIVE: To assess the activity of cysteine peptidases in cultured human articular chondrocytes as well as in osteoarthritic (OA) cartilage and subchondral bone, and to interpret their relative importance in cartilage destruction and remodeling of the subchondral region. METHODS: Intracellular and secreted cysteine peptidase activity was measured in chondrocytes using fluorimetric assays, and enzymes were immunolocalized using monospecific antibodies. Enzyme histochemistry in normal and OA femoral heads was used to characterize enzymatic activity in full thickness samples containing cartilage and subchondral bone. The zonal distribution of cathepsin activity was measured in tissue slices of normal and OA femoral heads cut parallel to the joint surface, using fluorogenic substrates. RESULTS: Cathepsins B and L were localized by immunohistochemistry with lysosome-like structures in dedifferentiated chondrocytes. Free cysteine peptidase activity (i.e., not requiring prior activation), secreted and intracellularly stored by chondrocytes, was due to cathepsin B, while cathepsin L contributed a minor fraction of the total activity, and was seen only after activation at acidic pH. Histochemistry and activity measurements confirmed cathepsin B as the major, active cysteine peptidase in OA cartilage, particularly at sites where matrix neosynthesis took place. However, free cathepsin L and/or cathepsin K activity was found subchondrally in association with cathepsin B in osteophytes, in zones undergoing bone remodeling, and at sites of inflammation. CONCLUSION: Cathepsin B, not cathepsin L or cathepsin K, is a candidate for articular cartilage catabolism in OA. While cathepsin K is the major osteoclastic cysteine peptidase, cathepsin L and cathepsin B may also participate in the remodeling processes of bone as well as in bone erosion by inflammatory cells.

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The influence of ionic strength and composition on the binding and inhibition of human leukocyte elastase by glycosaminoglycans with variable degree and position of sulfation was investigated. The kinetic mechanism of inhibition had a hyperbolic, mixed-type character with a competitive component that was promoted by low ionic strength, reduced by phosphate ions, and which also depended on the substrate and glycosaminoglycan structure. Enzyme binding was a cooperative phenomenon that varied with ionic strength and composition. The inhibition patterns correlated with the cationic character of elastase and with the distribution of arginines on its molecular surface, most notably with residues located in the vicinity of the substrate binding region. The order of affinity for elastase binding was chondroitin 4-sulfate < chondroitin 6-sulfate < dermatan sulfate, iduronate-containing derivatives being superior with respect to the glucuronate-containing counterparts. Additional sulfation at both the 4- and 6- positions or at the N- and 4-positions of the N-acetylgalactosamine moiety decidedly improved the inhibitory efficiency. The results highlight a fundamental physiological role of enzyme-glycosaminoglycan interactions. In the azurophil granule of the human polymorphonuclear neutrophil, elastase and other enzymes are bound to a matrix of chondroitin 4-sulfate because this is the only glycosaminoglycan that simultaneously offers good binding for enzyme compartmentalization together with prompt release from the bound state at the onset of phagocytosis.

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OBJECTIVES: To determine the quantitative topographical distribution of cathepsin B in human femoral head cartilage by measuring the zonal variation of enzyme activity in specimens taken from various anatomical regions of normal and osteoarthritic (OA) tissues, and to correlate this parameter with the severity of the OA lesions. METHODS: OA articular cartilage was obtained at surgery for total hip replacement and control cartilage obtained at postmortem. Cylinders of full thickness cartilage with underlying bone were retrieved with a biopsy trephine. Sections of cartilage were produced by cryocutting the tissue as slices parallel to the articular surface and assayed for cathepsin B with a specific, highly sensitive fluorogenic substrate. The severity of the OA lesions was graded according to the histopathological-histochemical method of Mankin. RESULTS: Zonal cathepsin B activity of normal cartilage was uniform and low in all regions of the femoral head. In apparently intact OA cartilage and in severely degraded tissue the zonal distribution and the amounts of enzyme were similar to control values. At sites with active disease, cathepsin B activity was much greater than in controls and its irregular zonal distribution correlated with tissue degeneration, hypercellularity, or cloning of chondrocytes as determined histochemically. Particularly high enzyme levels were observed at sites with regenerating cartilage, where some zonal peaks attained 20-fold activity with respect to controls. CONCLUSION: Cathepsin B may play a role in sustaining the chronicity of OA, not as an initiator, but rather as a perpetuator of the disease and as an antagonist of regeneration.

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OBJECTIVE: To localise the cysteine endopeptidase cathepsin B in chondrocytes and cartilage from normal and osteoarthritic (OA) human femoral heads in order to provide qualitative information on its cellular expression and distribution at possible sites of action. METHODS: OA articular cartilage was obtained at surgery for total hip replacement; control cartilage was obtained at postmortem. Chondrocytes were isolated by sequential enzymatic digestion and cathepsin B analysed by immunocytochemistry and activity staining with a fluorogenic substrate. Lysosomes were visualised by fluorescence microscopy after staining of living cells with acridine orange. Using a histochemical reaction, enzyme activity was measured in cryosections of full thickness cartilage. RESULTS: Chondrocytes from normal cartilage contained very few lysosomes and only a minor cell population was cathepsin B positive. A high proportion of chondrocytes from active OA cartilage contained a large number of lysosomes and an excess of cathepsin B in intracellular organelles; the enzyme was stored in an active form. In this respect, OA chondrocytes closely resembled normal cells that had been phenotypically modulated by serial subcultures. No cathepsin B activity could be detected by histochemistry in either chondrocytes or matrix of normal cartilage. While apparently intact and severely degraded OA cartilage was also cathepsin B negative, tissue at sites of active destruction and, particularly, at repair sites was highly positive. CONCLUSION: The presence and the particular distribution of active cathepsin B in OA cartilage at 'more involved' sites suggest a pathological role for this enzyme in sustaining and perpetuating cartilage degradation. While other stimuli may also be responsible for cathepsin B expression in OA chondrocytes, the similarity with artificially modulated cells indicates fibroblastic metaplasia as a plausible mechanism.

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Chondroitin sulfate was administered orally to six healthy volunteers, six patients with rheumatoid arthritis and six patients with osteoarthritis. Blood was collected at intervals before and after treatment and the glycosaminoglycan concentration was analyzed in serum using a sensitive assay based on the metachromatic reaction with 1,9-dimethylmethylene blue. The glycosaminoglycan concentration in serum before and after ingestion of chondroitin sulfate was statistically unchanged in all of the subjects studied. We suggest that chondroprotection by orally administered chondroitin sulfate is a biologically and pharmacologically unfounded theory. Any possible benefit to osteoarthritic patients after ingestion of chondroitin sulfate should be sought at the gastrointestinal rather than at the plasmatic or articular cartilage level.

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The cyclic thiolic compound 2-[3-thiophencarboxythio]-N-[dihydro-2(3H)-thiophenone-3-il] - propionamide (MR889) was investigated as inhibitor of endopeptidases. The activity of bovine pancreatic alpha-chymotrypsin, human leukocyte cathepsin G and rabbit liver cathepsin B was not affected by MR889, whereas porcine pancreatic elastase and human leukocyte elastase were inhibited. The kinetic mechanism of inhibition of human leukocyte elastase was of the reversible, slow-binding, fully competitive type. The rate constants for complex formation between MR889 and leukocyte elastase, determined by pre-steady-state kinetic analysis in the presence of a tetrapeptide substrate at 37 degrees and pH 7.40, were kon = 2363 +/- 15 M-1 sec-1, koff = 3.01 +/- 0.34 x 10(-3) sec-1. The inhibition equilibrium constant was Ki = koff/kon = 1.27 +/- 0.15 microM. Ki, calculated from steady-state kinetic experiments, was 1.38 microM. MR889 also inhibited the elastolytic activity of leukocyte elastase, as determined with insoluble elastin as the substrate.

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Rabbit articular cartilage does not secrete cathepsin B in organ culture. By established methods for modulating the chondrocyte phenotype in vitro, however, the synthesis, intracellular storage, and secretion of cathepsin B were followed up over a period of two months. With chondrocytes grown in monolayer cultures both the intracellular pool of the enzyme and its secretion were very small initially, but increased progressively to a factor of 110 after eight weeks. The secretion of cathepsin B was strongly depressed after transferring the cells from monolayer to collagen gel cultures. In contrast, collagenase was secreted in almost the same amounts during the whole period in both monolayer and collagen gel cultures. The cells cultured in collagen gels secreted more collagenase than those grown in monolayers. The reversible switch of cathepsin B secretion suggests that this enzyme, unlike collagenase, is a marker of the dedifferentiated chondrocyte phenotype. Cathepsin B was localised within cultured chondrocytes using antibodies raised against rabbit liver cathepsin B and shared with it many catalytic properties. Its Mr, however, was higher (34,000 compared with 27,000) and showed an unusual resistance to denaturation at neutral-alkaline pH, which may confer on this enzyme an important role in the degradation of cartilage matrix.

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