Loss of spatial organization and destruction of the pericellular matrix in early osteoarthritis in vivo and in a novel in vitro methodology.

OBJECTIVES: Current repair procedures for articular cartilage (AC) cannot restore the tissue's original form and function because neither changes in its architectural blueprint throughout life nor the respective biological understanding is fully available. We asked whether two unique elements of human cartilage architecture, the chondrocyte-surrounding pericellular matrix (PCM) and the superficial chondrocyte spatial organization (SCSO) beneath the articular surface (AS) are congenital, stable or dynamic throughout life. We hypothesized that inducing chondrocyte proliferation in vitro impairs organization and PCM and induces an advanced osteoarthritis (OA)-like structural phenotype of human cartilage. METHODS: We recorded propidium-iodine-stained fetal and adult cartilage explants, arranged stages of organization into a sequence, and created a lifetime-summarizing SCSO model. To replicate the OA-associated dynamics revealed by our model, and to test our hypothesis, we transduced specifically early OA-explants with hFGF-2 for inducing proliferation. The PCM was examined using immuno- and auto-fluorescence, multiphoton second-harmonic-generation (SHG), and scanning electron microscopy (SEM). RESULTS: Spatial organization evolved from fetal homogeneity, peaked with adult string-like arrangements, but was completely lost in OA. Loss of organization included PCM perforation (local micro-fibrillar collagen intensity decrease) and destruction [regional collagen type VI (CollVI) signal weakness or absence]. Importantly, both loss of organization and PCM destruction were successfully recapitulated in FGF-2-transduced explants. CONCLUSION: Induced proliferation of spatially characterized early OA-chondrocytes within standardized explants recapitulated the full range of loss of SCSO and PCM destruction, introducing a novel in vitro methodology. This methodology induces a structural phenotype of human cartilage that is similar to advanced OA and potentially of significance and utility.

Hypoxia reduces the inhibitory effect of IL-1beta on chondrogenic differentiation of FCS-free expanded MSC.

OBJECTIVE: Mesenchymal stromal cells (MSC) are a promising tool for tissue engineering of the intervertebral disc (ID). The IDs are characterized by hypoxia and, after degeneration, by an inflammatory environment as well. We therefore investigated the effects of inflammation induced with interleukin (IL)-1beta and of hypoxia (2% O(2)) on the chondrogenic differentiation of MSC. METHODS: Bone-marrow-derived MSC (bmMSC) were cultured in a fetal-calf-serum-free medium and characterized according to the minimal criteria for multipotent MSC. Chondrogenic differentiation of MSC was induced following standard protocols, under hypoxic conditions, with or without IL-1beta supplementation. After 28 days of differentiation, micromasses were analyzed by histochemical staining and immunohistochemistry and by determining the mRNA level of chondrogenic marker genes utilizing quantitative RT-PCR. RESULTS: Micromasses differentiated under IL-1beta supplementation are smaller and express less extracellular matrix (ECM) protein. Micromasses differentiated under hypoxia appear larger in size, display a denser ECM and express marker genes comparable to controls. The combination of hypoxia and IL-1beta supplementation improved chondrogenesis compared to IL-1beta supplementation alone. Micromasses differentiated under standard conditions served as controls. CONCLUSION: Inflammatory processes inhibit the chondrogenic differentiation of MSC. This may lessen the regenerative potential of MSC in situ. Thus, for the cell therapy of IDs using MSC to be effective it will be necessary to manage the inflammatory conditions in situ. In contrast, hypoxic conditions exert beneficial effects on chondrogenesis and phenotype stability of transplanted MSC, and may improve the quality of the generated ECM.

DNA degradation during maturation of erythrocytes - molecular cytogenetic characterization of Howell-Jolly bodies.

Howell-Jolly bodies (HJBs) are small DNA-containing inclusions of erythrocytes and are often present after splenectomy. The genetic composition of HJBs is unknown at present. We isolated individual erythrocytes that had inclusion bodies from five splenectomized patients and performed DNA amplification using degenerate oligonucleotide primed polymerase chain reaction (DOP-PCR) with subsequent reverse painting on normal male metaphase spreads. We also measured the sizes of HJBs in erythrocytes from a splenectomized patient using an inverted microscope. Two-dimensional positions of HJBs were projected onto a virtual erythrocyte. The average size of HJBs was 0.73 +/- 0.17 microm (range 0.4-1.1 microm). Inside the erythrocyte the HJBs were found to be equally distributed. Small HJBs contained DNA from one or two centromeres and larger HJBs contained DNA from up to eight different centromeres. Centromeric DNA from chromosomes 1/5, 7, 8, and 18 was most frequently observed. Signals from the centromeric regions of chromosomes 3, 4, 9, and 10 were not observed. Signals from euchromatic regions were detected in a few cases. We hypothesize that in addition to enucleation and nucleus fragmentation DNA degradation during maturation of erythrocytes preferentially eliminates euchromatic DNA. Similarities between these processes and those described for embryonic stem cells suggest that most stem cells are able to degrade DNA in a genetically controlled manner.