Noncollagenous, nonproteoglycan macromolecules of cartilage

Extracellular matrix comprises approximately 90% of cartilage, with collagens and proteoglycans making up the bulk of the tissue. In recent years, several abundant cartilage proteins that are neither collagens nor proteoglycans have been characterized in detail. The putative roles of these proteins range from involvement in matrix organization or matrix-cell signaling (PRELP, chondroadherin, cartilage oligomeric protein and cartilage matrix protein) through to molecules that are likely to be involved with modulation of the chondrocyte phenotype (CD-RAP, CDMPs, chondromodulin and pleiotrophin). Other molecules, such as the cartilage-derived C-type lectin and cartilage intermediate layer protein have no role as yet. Due to the difficulties associated with experimentally manipulating a tissue that is 90% extracellular matrix in a manner that can be readily transferred to the whole organism, many of these molecules have been focused on by a surprisingly small number of researchers. This review focuses on newly discovered proteins and glycoproteins in cartilage, with a bias towards those that have structural roles or that are unique to cartilage. Received 7 January 1999; accepted 11 March 1999     

Aggrecan, aging and assembly in articular cartilage

The primary function of articular cartilage to act as a self-renewing, low frictional material that can distribute load efficiently at joints is critically dependent upon the composition and organisation of the extracellular matrix. Aggrecan is a major component of the extracellular matrix, forming high molecular weight aggregates necessary for the hydration of cartilage and to meet its weight-bearing mechanical demands. Aggregate assembly is a highly ordered process requiring the formation of a ternary complex between aggrecan, link protein and hyaluronan. There is extensive age-associated heterogeneity in the structure and molecular stoichiometry of these components in adult human articular cartilage, resulting in diverse populations of complexes with a range of stabilities that have implications for cartilage mechanobiology and integrity. Recent findings have demonstrated that aggrecan can form ligands with other matrix proteins. These findings provide new insights into mechanisms for aggregate assembly and functional protein networks in different cartilage compartments with maturation and aging.     

Articular cartilage canals — a new pathogenetic mechanism in infectious arthritis

Summary In experimentally-induced erysipelas polyarthritis, preexisting cartilage canals in articular cartilage play a crucial role during the very onset of the disease. This observation might have some implications for the pathogenesis of other infectious arthritides in young animals or even rheumatoid arthritis in man.     

Molecular basis of osteoarthritis: biomechanical aspects

The unique biomechanical properties of healthy cartilage ensure that articular cartilage is able to transmit force between the joints while maintaining almost friction-free limb movement. In osteoarthritis, the biomechanical properties are compromised, but we still do not understood whether this precedes the onset of the disease or is a result of it. This review focuses on the physical changes to cartilage with age, disease, and mechanical loading, with specific reference to the increased collagen cross-linking that occurs with age (nonenzymatic glycation), and the response of chondrocytes to physiological and pathological loads. In addition, the biomechanical properties and matrix biosynthesis of cartilage from various joint surfaces of the knee and ankle are compared to elucidate reasons why the ankle is less affected by progressive osteoarthritis than the knee.     

Molecular pathology and pathobiology of osteoarthritic cartilage

The biochemical properties of articular cartilage rely on the biochemical composition and integrity of its extracellular matrix. This matrix consists mainly of a collagen network and the proteoglycan-rich ground substance. In osteoarthritis, ongoing cartilage matrix destruction takes place, leading to a progressive loss in joint function. Beside the degradation of molecular matrix components, destabilization of supramolecular structures such as the collagen network and changes in the expression profile of matrix molecules also take place. These processes, as well as the pattern of cellular reaction, explain the pathology of osteoarthritic cartilage degeneration. The loss of histochemical proteoglycan staining reflects the damage at the molecular level, whereas the supramolecular matrix destruction leads to fissuring and finally to the loss of the cartilage. Chondrocytes react by increasing matrix synthesis, proliferating, and changing their cellular phenotype. Gene expression mapping in situ and gene expression profiling allows characterization of the osteoarthritic cellular phenotype, a key determinant for understanding and manipulating the osteoarthritic disease process.     

Cartilage biology, pathology, and repair

Osteoarthritis is one of the most common forms of musculoskeletal disease and the most prominent type of arthritis encountered in all countries. Although great efforts have been made to investigate cartilage biology and osteoarthritis pathology, the treatment has lagged behind that of other arthritides, as there is a lack of effective disease-modifying therapies. Numerous approaches for dealing with cartilage degradation have been tried, but enjoyed very little success to develop approved OA treatments with not only symptomatic improvement but also structure-modifying effect. In this review we discuss the most recent findings regarding the regulation of cartilage biology and pathology and highlight their potential therapeutic values.     

Der Einbau von radioaktiv markiertem Schwefel (35S) in den Knorpel normaler und Vitamin-C-frei ernährter Meerschweinchen

Summary The utilization of sulphate labelled with S³⁵ to the synthesis of chondroitin sulphate of the cartilage of normal and scorbutic guinea pigs has been examined. The average incorporation of S³⁵ in the costal cartilage in the deficient animal was about one half that of the normal.     

Inhibition of new blood vessel formation in mice by systemic administration of human rib cartilage extract

Summary 1 M HCl-guanidine extract of human funnel chest rib cartilage administered i.v. to mice decreased specifically vasoproliferation induced by intradermal injection of allogeneic murine lymphocytes.Acknowledgments. This work was supported by grant No. 10.5. from the Polish Academy of Sciences. We wish to acknowledge the valuable help of Dr A. Piasek in cartilage extract preparation.     

Reinterpretation of the ultrastructure of cartilage matrix.

The epiphyseal cartilage from new-born mouse was treated with collagenase in two ways: either before fixation or after glutaraldehyde fixation. The electron dense granules of the matrix were not seen in the micrographs of cartilage treated with collagenase before fixation. It is concluded that collagen plays a definite role in the formation of the granules at the time of tissue fixation and that the granules are fixation artifacts.     

Molecular basis for differences between human joints

The molecular program of a cell determines responses including induction or inhibition of genes for function and activity, and this is true of the cells within articular cartilage, a major functional component of the joint. While our studies have previously focussed on differences in the molecular programs of the cells within the superficial and deep zones, we have recently begun to focus on relative differences between joints, such as the knee and ankle. In the human, these joints vary greatly in their susceptibility to joint diseases, such as osteoarthritis (OA). We have predicted that there would be a molecular basis for differences between joints that could lead to differences in susceptibility to OA, if inherent pathways locked into the resident cells induce differences in their response to their environment. We have been able to show that there are differences between the matrix components and water content; these properties correspond to a higher equilibrium modulus and dynamic stiffness but lower hydraulic permeability and serve to make the ankle cartilage stiffer, slowing movement of molecules through the cartilage. In addition to these biochemical differences in the cartilage matrix, we have also identified relative differences in the strength of the response to stimulation of chondrocytes from knee and ankle. The stronger response of the knee chondrocytes includes factors that increase damage to the cartilage matrix, such as a depression of matrix synthesis and increased enzyme activity. This response by the knee chondrocytes results in enzyme damage to the matrix that the cells may not be able to repair, while the weaker response of the ankle chondrocytes may allow the cells to repair their matrix damage.     

Hyaluronic acid in elastic cartilage

Summary Bovine ear cartilage contains more hyaluronic acid than do hyaline cartilages of the same animal. Most of it is in the elastin-rich residue not extractable by 4 M guanidinium chloride where it is associated with chondroitin sulphate in low relative concentration and of lower molecular weight than in non-elastic cartilage residue.G. C. G. is grateful to the Medical Research Council for a research studentship.     

Alkaline phosphatase binds to collagen; a hypothesis on the mechanism of extravesicular mineralization in epiphyseal cartilage

Affinity chromatography on Sepharose 4B-collagen gels was used to test the affinity of alkaline phosphatase for collagen. Results indicate that alkaline phosphatase of preosseous cartilage binds to collagen probably by electrostatic interactions, this interaction is inhibited by proteoglycan subunits. These results suggest that, in vivo, the formation of a collagen-alkaline phosphatase complex may be a step of the process leading to cartilage calcification.     

Calcification of the deep zone in pig femoral head cartilage

Summary X-Ray diffraction shows an almost random arrangement of collagen fibrils in the region of uncalcified pig femoral head cartilage furthest from the articular surface. The characteristic radial orientiation of the deep zone of articular cartilage is revealed in the underlying tissue after decalcification.Research supported by an M.R.C. project grant; R.M.A. held an S.R.C. studentship.     

Fate of cartilage cells in limb regeneration in the axolotl (Ambystoma mexicanum)

Résumé Nous avons suivi de près, pendant la régénération, le comportement du cartilage triploïde greffé dans les membres diploïdes en nous servant du nombre nucléolaire comme marque cellulaire. La greffe de cartilage a fourni des cellules de cartilage au régénérat, mais elle n'a pas contribué à la découverte de cellules d'autres espèces.     

In vivo matrix-guided human mesenchymal stem cells

Microfracture of subchondral bone results in intrinsic repair of cartilage defects. Stem or progenitor cells from bone marrow have been proposed to be involved in this regenerative process. Here, we demonstrate for the first time that mesenchymal stem (MS) cells can in fact be recovered from matrix material saturated with cells from bone marrow after microfracture. This also introduces a new technique for MS cell isolation during arthroscopic treatment. MS cells were phenotyped using specific cell surface antibodies. Differentiation of the MS cells into the adipogenic, chondrogenic and osteogenic lineage could be demonstrated by cultivation of MS cells as a monolayer, as micromass bodies or mesenchymal microspheres. This study demonstrates that MS cells can be attracted to a cartilage defect by guidance of a collagenous matrix after perforating subchondral bone. Protocols for application of MS cells in restoration of cartilage tissue include an initial invasive biopsy to obtain the MS cells and time-wasting in vitro proliferation and possibly differentiation of the cells before implantation. The new technique already includes attraction of MS cells to sites of cartilage defects and therefore may overcome the necessity of in vitro proliferation and differentiation of MS cells prior to transplantation. Received 3 November 2005; received after revision 15 December 2005; accepted 4 January 2006     

Reinterpretation of the ultrastructure of cartilage matrix

Summary The epiphyseal cartilage from new-born mouse was treated with collagenase in two ways: either before fixation or after glutaraldehyde fixation. The electron dense granules of the matrix were not seen in the micrographs of cartilage treated with collagenase before fixation. It is concluded that collagen plays a definite role in the formation of the granules at the time of tissue fixation and that the granules are fixation artifacts.Commonwealth Academic Staff Fellow. Permanent address: Department of Zoology, University of Poona, Poona 411007, India.     

CD44 and integrin matrix receptors participate in cartilage homeostasis

Articular chondrocytes express the matrix receptors CD44 and integrins. Both of these receptors exhibit interactions with adjacent extracellular matrix macromolecules. In addition, both integrins and CD44 have the capacity for signal transduction as well as modulated interactions with the actin cytoskeleton. As such, both receptor families provide the chondrocytes a means to detect changes in matrix composition or to function as mechanotransducers. Disruption of CD44 or integrin-mediated cell-matrix interactions, either experimentally induced or when present in osteoarthritis, have profound effects on cartilage metabolism. Thus, CD44 and integrin receptors play a critical role in maintaining cartilage homeostasis.     

Alkaline phosphatase binds to collagen; a hypothesis on the mechanism of extravesicular mineralization in epiphyseal cartilage

Summary Affinity chromatography on Sepharose 4B-collagen gels was used to test the affinity of alkaline phosphatase for collagen. Results indicate that 1) alkaline phosphatase of preosseous cartilage binds to collagen probably by electrostatic interactions, 2) this interaction is inhibited by proteoglycan subunits. These results suggest that, in vivo, the formation of a collagen-alkaline phosphatase complex may be a step of the process leading to cartilage calcification.This investigation was supported by research grants of C.N.R. (C.T. 82.02437.04), of Ministero della Pubblica Istruzione and of the University of Trieste.To whom correspondence and reprint requests should be addressed.     

Nerve growth factor selectively stimulates the degradation of chondromucoprotein in the embryonic cartilage in vitro.

Nerve growth factor specifically stimulates the degradation of chondromucoprotein in the chick embryonic cartilage cultivated in vitro, with little effect on chondromucoprotein, RNA, DNA and protein synthesis.     

川芎嗪对IL-1β诱导的兔原代软骨细胞增殖和凋亡影响

目的 观察川芎嗪对白细胞介素-1β诱导的软骨细胞的增殖及凋亡的影响.方法 兔原代软骨细胞培养及鉴定,用IL-1β10ng/ml和/或不同浓度川芎嗪共培养兔原代软骨细胞48h后,利用流式细胞仪检测各组软骨细胞的周期及凋亡率;利用MTT法检测软骨细胞的生长状态.结果 与对照组比较,IL-1β诱导下软骨细胞的凋亡率显著增加,差异具有显著统计学意义(P＜0.01);加入川芎嗪能明显降低IL-1β诱导的软骨细胞凋亡率,有显著统计学意义(P＜0.01);与对照组比较,IL-1β诱导下软骨细胞被明显阻滞在G1期(P＜0.01);加入川芎嗪能明显降低IL-1β对软骨细胞G1期的阻滞作用,细胞增殖指数明显增加(P＜0.05或P＜0.01).结论 川芎嗪对IL-1β诱导的兔原代软骨细胞抑制凋亡并促进生长.