The secreted glycoprotein lubricin protects cartilage surfaces and inhibits synovial cell overgrowth
David K. Rhee, … , Matthew L. Warman, John D. Carpten
David K. Rhee, … , Matthew L. Warman, John D. Carpten
Published March 1, 2005
Citation Information: J Clin Invest. 2005;115(3):622-631. https://doi.org/10.1172/JCI22263.
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Article Genetics

The secreted glycoprotein lubricin protects cartilage surfaces and inhibits synovial cell overgrowth

Abstract

The long-term integrity of an articulating joint is dependent upon the nourishment of its cartilage component and the protection of the cartilage surface from friction-induced wear. Loss-of-function mutations in lubricin (a secreted glycoprotein encoded by the gene PRG4) cause the human autosomal recessive disorder camptodactyly-arthropathy-coxa vara-pericarditis syndrome (CACP). A major feature of CACP is precocious joint failure. In order to delineate the mechanism by which lubricin protects joints, we studied the expression of Prg4 mRNA during mouse joint development, and we created lubricin-mutant mice. Prg4 began to be expressed in surface chondrocytes and synoviocytes after joint cavitation had occurred and remained strongly expressed by these cells postnatally. Mice lacking lubricin were viable and fertile. In the newborn period, their joints appeared normal. As the mice aged, we observed abnormal protein deposits on the cartilage surface and disappearance of underlying superficial zone chondrocytes. In addition to cartilage surface changes and subsequent cartilage deterioration, intimal cells in the synovium surrounding the joint space became hyperplastic, which further contributed to joint failure. Purified or recombinant lubricin inhibited the growth of these synoviocytes in vitro. Tendon and tendon sheath involvement was present in the ankle joints, where morphologic changes and abnormal calcification of these structures were observed. We conclude that lubricin has multiple functions in articulating joints and tendons that include the protection of surfaces and the control of synovial cell growth.

Authors

David K. Rhee, Jose Marcelino, MacArthur Baker, Yaoqin Gong, Patrick Smits, Véronique Lefebvre, Gregory D. Jay, Matthew Stewart, Hongwei Wang, Matthew L. Warman, John D. Carpten

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Figure 6

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PCNA staining within the knee synovium of 10-day-old heterozygous and Pr...
PCNA staining within the knee synovium of 10-day-old heterozygous and Prg4–/– mice. Images of sections from heterozygous and mutant mice visualized with DAPI fluorescence for nuclei (A, B, and C) and PCNA for proliferating cells (D, E, and F) were merged to visualize dividing cells and determine their number relative to the total cell number (G, H, and I). Note the synovial hyperplasia present in the 10-day-old Prg4–/– mouse (B) compared with the 10-day-old heterozygous mouse (A) (magnification, ×200). Also note the increased PCNA staining within the synovium of the Prg4–/– mouse (H and I) compared with the heterozygote (G). I shows the synovium at the suprapatellar reflection and G and H, the anterior synovium (the region indicated by arrows in Figure 4, A and B).