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Ann N Y Acad Sci. 2005 Jun;1051:291-8.

Investigation of arthritic joint destruction by a novel fibroblast-based model.

Author information

1
Medical Faculty, Institute of Clinical Immunology and Transfusion Medicine, University of Leipzig, Johannisallee 30, 04103 Leipzig, Germany. ulrich.sack@medizin.uni-leipzig.de

Abstract

The key pathologic mechanism in rheumatoid arthritis (RA) is the destruction of cartilage by fibroblasts. In a severe combined immunodeficient (SCID) mouse model, this process can be modulated by gene transfer using invasive LS48 fibroblasts. This study aims to investigate the effect of interleukins (IL) -11 and -12 on cartilage destruction when transferred into LS48, and of IL-15 when transfected into non-invasive 3T3 cells; to compare three transduction systems (a lentiviral vector system, a retroviral vector system, and a particle-mediated gene transfer); and to establish an in vitro cartilage destruction system based on LS48 cells. Transduced fibroblasts were injected into SCID mice knee joints, and disease progression assessed microscopically. Distinctive morphologic pattern revealed invasion of fibroblasts into the articular cartilage by transfected, as well as non-transfected, LS48 cells. IL-12 and IL-15 did not alter swelling or cartilage destruction. Animals treated with IL-11-transfected cells showed reduced cartilage damage but no changes in swelling. Efficacy of gene transfer to establish transfected fibroblasts was shown to be >85% for lentiviral transfer, compared to <10% for retroviral transfer and gene gun. Furthermore, cells were co-incubated with porcine cartilage. Transduction of IL-11 led to a reduction of apoptosis in chondrocytes. These findings suggest that cartilage destruction by invasive fibroblasts can be modulated by gene transfer. Lentiviral vector systems offer the most effective approach for gene transduction. In vitro fibroblast/cartilage co-cultures present a convenient system for the assessment of novel therapeutic strategies toward reduction of articular destruction.

PMID:
16126970
DOI:
10.1196/annals.1361.070
[Indexed for MEDLINE]

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