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Characterization of Collagenous Matrix Assembly in a Chondrocyte Model System
Journal of Biomedical Materials Research Part A
  • Sorcha Yingst, Boise State University
  • Kaci Bloxham, Boise State University
  • Lisa R. Warner, Boise State University
  • Raquel J. Brown, Boise State University
  • Jennifer Cole, Boise State University
  • Linda Kenoyer, Boise State University
  • William B. Knowlton, Boise State University
  • Julia T. Oxford, Boise State University
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Collagen is a major component of the newly synthesized pericellular microenvironment of chondrocytes. Collagen types II, IX, and XI are synthesized and assembled into higher ordered complexes by a mechanism in which type XI collagen plays a role in nucleation of new fibrils, and in limiting fibril diameter. This study utilizes a cell line derived from the Swarm rat chondrosarcoma that allows the accumulation and assembly of pericellular matrix. Immunofluorescence and atomic force microscopy were used to assess early intermediates of fibril formation. Results indicate that this cell line synthesizes and secretes chondrocyte-specific pericellular matrix molecules including types II, IX, and XI collagen and is suitable for the study of newly synthesized collagen matrix under the experimental conditions used. AFM data indicate that small fibrils or assemblies of microfibrils are detectable and may represent precursors of the ∼20 nm thin fibrils reported in cartilage. Treatment with hyaluronidase indicates that the dimensions of the small fibrils may be dependent upon the presence of hyaluronan within the matrix. This study provides information on the composition and organization of the newly synthesized extracellular matrix that plays a role in establishing the material properties and performance of biological materials such as cartilage.

Citation Information
Sorcha Yingst, Kaci Bloxham, Lisa R. Warner, Raquel J. Brown, et al.. "Characterization of Collagenous Matrix Assembly in a Chondrocyte Model System" Journal of Biomedical Materials Research Part A (2009)
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