Fluorophores from aging human articular cartilage.

Human articular cartilages of various ages were digested with collagenase, and the fluorescence of the digests was measured as a function of age. At acidic pH, all collagenase-treated fractions were found to contain two main fluorophores with fluorescence maxima at 395 and 385 nm (excitation at 295 and 335 nm, respectively). Each fluorophore was isolated from the hydrolysate and its structure was deduced from spectral and chemical data. The 395/295 nm fluorophore was identified as pyridinoline, which is one of the non-reducible cross-linkages in collagen. The 385/335 nm fluorophore was identical to pentosidine, which was isolated from human dura mater and characterized by Sell and Monnier in 1989. Our results showed that the amount of pentosidine per collagen in human articular cartilage increases linearly with age (r = 0.929, p less than 0.005), while the amount of pyridinoline per collagen remained constant and was not correlated with age (r = 0.20). On the other hand, the amount of pentosidine per pyridinoline increased exponentially during life (r2 = 0.839, p less than 0.05).     

Isolation of proteoglycans from human articular cartilage.

Proteoglycans were extracted from normal human articular cartilage of various ages with 4M-guanidinium chloride and were purified and characterized by using preformed linear CsCl density gradients. With advancing age, there was a decrease in high-density proteoglycans of low protein/uronic acid weight ratio and an increase in the proportion of lower-density proteoglycans, richer in keratan sulphate and protein. Proteoglycans of each age were also shown to disaggregate in 4M-guanidinium chloride and at low pH and to reaggregate in the presence of hyaluronic acid and/or low-density fractions. Osteoarthrotic-cartilage extracts had an increased content of higher-density proteoglycans compared with normal cartilage of the same age, and results also suggested that these were not mechanical or enzymic degradation products, but were possibly proteoglycans of an immature nature.     

Extractable proteoglycan from human femoral-head articular cartilage.

Proteoglycans were prepared from human femoral-head articular cartilage by using either guanidinium hydrochloride or MgCl2 as extractant, followed by density-gradient centrifugation. The proteoglycan subunit had a particle weight of 2.6 x 10(6), with a radius of gyration, RG, of 68.5 nm in 150 mM-NaCl/20 mM-sodium phosphate buffer, pH 7.0. The proteoglycan aggregate had a particle weight of 3.7 x 10(6) (RG 84 nm) for guanidinium hydrochloride extracts and 8.7 x 10(6) (RG 118 nm) for MgCl2 extracts in the same buffer. The addition of excess of high-molecular-weight hyaluronate did not significantly alter the particle size of the aggregate. The small increase in size probably reflects a rapid equilibrium between hyaluronate and proteoglycan monomers, and is not due to proteolytic cleavage producing non-aggregating units. Experiments that support the rapid-interaction hypothesis include analytical ultracentrifugation and column chromatography. This interaction does not appear to be pressure-sensitive at 20 degrees C, but is sensitive to temperature variation near the physiological range.     

Indentation testing of human articular cartilage: effects of probe tip geometry and indentation depth on intra-tissue strain

Experimental determination of intra-tissue deformation during clinically applicable rapid indentation testing would be useful for understanding indentation biomechanics and for designing safe indentation probes and protocols. The objectives of this study were to perform two-dimensional (2-D) indentation tests, using indenters and protocols that are analogous to those in clinically oriented probes, of normal adult-human articular cartilage in order to determine: (1) intra-tissue strain maps and regions of high strain magnitude, and (2) the effects on strain of indenter geometry (rectangular prismatic and cylindrical) and indentation depth (40-190 microm). Epifluorescence microscopy of samples undergoing indentation and subsequent video image correlation analysis allowed determination of strain maps. Regions of peak strain were near the "edges" of indenter contact with the cartilage surface, and the strain magnitude in these regions ranged from approximately 0.05 to approximately 0.30 in compression and shear, a range with known biological consequences. With increasing indentation displacement, strain magnitudes generally increased in all regions of the tissue. Compared to indentation using a rectangular prismatic tip, indentation with a cylindrical tip resulted in slightly higher peak strain magnitudes while influencing a smaller region of cartilage. These results may be used to refine clinical indenters and indentation protocols.     

Studies on cathepsin B in human articular cartilage.

The thiol proteinase cathepsin B (EC 3.4.22.1), previously called cathepsin B1, was assayed in human articular cartilage by its hydrolysis of the synthetic substrate alpha-N-benzoyl-DL-arginine 2-naphthylamide. The enzyme was activated by cysteine and EDTA and completely inhibited by iodoacetamide and HgCl2. It was also partially inhibited by whole human serum. Human osteoarthrotic cartilage had increased activity when compared with normal cartilage. Cathepsin B activity of normal cartilage was age-related, being high in juveniles and declining to low values in adult and elderly individuals. Cathepsin D and cathepsin B both exhibited a zonal variation through the cartilage depth; the surface cells appeared to contain more activity than those close to the subchondral bone.     

Electron microscopy of human articular cartilage]

Scanning and transmission microscopy of the articular cartilage was performed in femoral condyles of persons at the age of 30-50 years. It was demonstrated that hyaline cartilage is covered with a protective fibrillar layer consisting of tightly pressed collagenous fibrillae with an underlying layer of fibroblastic cells. In the intracellular substance of the hyaline cartilage fibrillar structures form a complex reticular web with vertical arrangement of the main collagenous fasiculi. In the superficial layer of the hyaline cartilage the collagenous fibrillae and their fasciculi form arcade-like structures. Lacunar chondrocytes have a rough villose surface, cellular secrete is discharged as round granules through cytoplasmic membrane. Ultrastructural changes in chondrocytes are observed simultaneously with their degenerative-dystrophic changes.     

Degradome expression profiling in human articular cartilage

Introduction

The molecular mechanisms underlying cartilage destruction in osteoarthritis are poorly understood. Proteolysis is a key feature in the turnover and degradation of cartilage extracellular matrix where the focus of research has been on the metzincin family of metalloproteinases. However, there is strong evidence to indicate important roles for other catalytic classes of proteases, with both extracellular and intracellular activities. The aim of this study was to profile the expression of the majority of protease genes in all catalytic classes in normal human cartilage and that from patients with osteoarthritis (OA) using a quantitative method.

Methods

Human cartilage was obtained from femoral heads at joint replacement for either osteoarthritis or following fracture to the neck of femur (NOF). Total RNA was purified, and expression of genes assayed using Taqman^® low-density array quantitative RT-PCR.

Results

A total of 538 protease genes were profiled, of which 431 were expressed in cartilage. A total of 179 genes were differentially expressed in OA versus NOF cartilage: eight aspartic proteases, 44 cysteine proteases, 76 metalloproteases, 46 serine proteases and five threonine proteases. Wilcoxon ranking as well as the LogitBoost-NR machine learning approach were used to assign significance to each gene, with the most highly ranked genes broadly similar using each method.

Conclusions

This study is the most complete quantitative analysis of protease gene expression in cartilage to date. The data help give direction to future research on the specific function(s) of individual proteases or protease families in cartilage and may help to refine anti-proteolytic strategies in OA.     

600 MHz NMR studies of human articular cartilage keratan sulfates.

The use of high-field two-dimensional 1H-correlation data is described for the detailed comparison of intact keratan sulfate polymer chains derived from human articular cartilage sources as a function of age. For fetal material the nonreducing chain termini are shown to be sparsely capped by sialyl groups which, if present, are exclusively (alpha2-3)-linked to an unsulfated galactose residue. The asialo capping segment has the structure: Gal-GlcNAc6S-Gal-GlcNAc6S-. Examination of keratan sulfate from 10-year-old cartilage shows that capping by sialyl groups is complete, with (alpha2-3)-linkages predominant; for both this and the 38-year-old cartilage the three capping structures: NeuAc(alpha2-3)-Gal-GlcNAc6S-Gal-GlcNAc6S-, NeuAc(alpha2-3)-Gal-GlcNAc6S-Gal6S-GlcNAc6S-, and NeuAc(alpha2-3)-Gal6S-GlcNAc6S-Gal6S-GlcNAc6S- are clearly recognizable. The level of (alpha2-6)-linked chain capping sialyl groups is significant for 38-year-old cartilage keratan sulfate. Structural information concerning the linkage region to protein and the distribution of galactose environments is readily obtained from the spectra. Signal complexities severely limit the usefulness of two-dimensional correlation spectroscopy at 600 MHz for the examination of N-acetylglucosamine residues within the poly(N-acetyllactosamine) repeat sequence and signals representing fucose placements remain undifferentiated. This nondestructive approach complements current degradative methods for the structural examination of keratan sulfates.     

Abnormalities of DNA in human osteoarthritic articular cartilage

The normal amount of DNA in human diploid nuclei was determined by the use of the Feulgen reaction measured by microdensitometry. The DNA-content of nuclei in normal human articular cartilage was determined in nuclei of zones 3 and 4 of cartilage of the femoral head removed from osteoporotic fractured necks of femur. Analysis of the results indicated that a degree of synthesis of DNA occurred even in these zones of very elderly persons. Results on these zones in the articular cartilage of osteoarthritic joints indicated that different populations occurred. In some there was DNA-synthesis related to tetraploidy; in others, the DNA was very stable to acid hydrolysis with no sign of biosynthetic activity; in the last group, which contained erosions of the superficial zones, the DNA was unstable to hydrolysis.     

Type III collagen in normal human articular cartilage

Summary Type III collagen in normal human articular cartilage has been detected biochemically and its location in a diffuse area around the chondrocytes demonstrated by immunofluorescence. It can be found pericellularly throughout the depth of the cartilage and is evident in specimens ranging in age from 17 to 81 years.     

Sulphate diffusion and incorporation into human articular cartilage

The permeability coefficients of sulphate ion in post-mortem human articular cartilage were found to be the same whether cells were alive or dead; thus diffusion of solutes is not via active transport. From the diffusion coefficient and the thickness of cartilage, the minimum time of incubation necessary to obtain meaningful results on sulphate uptake and incorporation, could be calculated.The rate of ³⁵S-labelled sulphate incorporation was linear up to 8 h. In Eagle's medium, the mean rates of incorporation, in mmoles/gram of wet tissue per h were 2 · 10^?6 for the femoral head and 3.3 · 10^?6 for the femoral condyle. The faster turnover rate in the condyle correlates with a lower glycosaminoglycan content.Sulphate uptake was found to vary directly with the inorganic sulphate content. Since the latter by Donnan equilibrium, is in inverse ratio to the glycosaminoglycan content, this would explain why sulphate uptake was found to be lower where the glycosaminoglycan content was higher.The half-life of glycosaminoglycans was estimated at 200–300 days i.e. much higher than previously suggested.Zonal variations in uptake were studied both in normal and fibrillated tissue; the latter has a low rate of incorporation, throughout its depth, compared to healthy cartilage.     

Extracts of human articular cartilage contain an inhibitor of tissue metalloproteinases.

Vasopressin and angiotensin are able to lower the glucagon-induced increase of cyclic AMP levels in isolated hepatocytes. Results presented are in favour of an enhanced phosphodiesterase activity to account for this cyclic AMP lowering effect. In particular, vasopressin prevents exogenous cyclic AMP from activating glycogen phosphorylase: in the presence of phosphodiesterase inhibitors, the hormone becomes unable to decrease glucagon-induced cyclic AMP levels. This anti-glucagon effect of vasopressin and angiotensin might be physiologically more important than their glycogenolytic effect; indeed, the latter is very transient in nature and, in addition, requires higher hormone concentrations [Bréant, Keppens & De Wulf (1981) Biochem. J. 200, 509-514] than those needed for the anti-glucagon effect, as reported here.     

Mesenchymal progenitor cells in adult human articular cartilage

The transmembrane receptor Notch-1 regulates cell fate and differentiation and was suggested to identify a cell type with progenitor characteristics in newborn bovine articular cartilage. We show that Notch-1 is expressed on > 70% of BM-MSC in early passage monolayer culture. We also demonstrate that normal articular cartilage contains Notch-1+ cells and that the frequency is increased in OA. Most Notch-1+ cells in OA cartilage are located in the clusters of proliferating cells. These findings indicate that multipotential mesenchymal progenitor cells are present in articular cartilage from adult humans and that their frequency is increased in OA. This observation has implications for understanding the intrinsic repair capacity of articular cartilage and raises the possibility that these progenitor cells might be involved in the pathogenesis of arthritis.     

Glycosaminoglycan turn-over in articular cartilage.

Glycosaminoglycan turn-over has been studied both in vivo and in vitro, by using sodium [35S]sulphate as a precursor. The in vivo experiments were performed on rabbits and dogs, taking special care to monitor the 35S radioactivity in the serum throughout the experiment and to measure the radioactivity due to unincorporated inorganic [35S]sulphate in cartilage at the end of each experiment, in addition to that due to incorporated sulphate. The inorganic sulphate content of the serum was also determined as well as the distribution coefficient for the inorganic sulphate ion between cartilage and serum. From this information it was possible to calculate accurately the rate of sulphate uptake by cartilage in vivo and hence the turn-over rate. Experiments were then performed in vitro on cartilage from rabbits and dogs and the in vivo and in vitro results were compared. A very good agreement was obtained between the two sets of results. Studies were then carried out under exactly the same in vitro conditions on human articular cartilage and it was thus possible to obtain a turn-over rate for the latter which one could trust was close to the actual in vivo value. The mean half-lives thus obtained varied from 45 days for the young rabbit to 150 days for the adult dog and 800 days for the human femoral head. In human cartilage there were considerable variations in turn-over rate within a single joint as a function of depth below the surface, and between different joints. Thus, while the mean half-life for the human femoral head is 800 days, that for the femoral condyle is 300 days. Cartilage from osteoarthrosic femoral heads did not appear to differ much with respect to sulphate uptake from the normal specimens although the turn-over rates were somewhat higher.