Interleukin-6 (IL-6) is overproduced in the joints of patients with rheumatoid arthritis (RA) and, based on its multiple stimulatory effects on cells of the immune system and on vascular endothelia, osteoclasts, and synovial fibroblasts, is believed to participate in the development and clinical manifestations of this disease. In this study we have analysed the effect of ablating cytokine production in two mouse models of arthritis: collagen-induced arthritis (CIA) in DBA/1J mice and the inflammatory polyarthritis of tumor necrosis factor α (TNF-α) transgenic mice. IL-6 was ablated by intercrossing an IL-6 null mutation into both arthritis-susceptible genetic backgrounds and disease development was monitored by measuring clinical, histological, and biochemical parameters. Two opposite responses were observed; while arthritis in TNF-α transgenic mice was not affected by inactivation of the IL-6 gene, DBA/1J, IL-6−/− mice were completely protected from CIA, accompanied by a reduced antibody response to type II collagen and the absence of inflammatory cells and tissue damage in knee joints. These results are discussed in the light of the present knowledge of cytokine networks in chronic inflammatory disorders and suggest that IL-6 receptor antagonists might be beneficial for the treatment of RA.
Stunted growth is a major complication of chronic inflammation and recurrent infections in children. Systemic juvenile rheumatoid arthritis is a chronic inflammatory disorder characterized by markedly elevated circulating levels of IL-6 and stunted growth. In this study we found that NSE/hIL-6 transgenic mouse lines expressing high levels of circulating IL-6 since early after birth presented a reduced growth rate that led to mice 50-70% the size of nontransgenic littermates. Administration of a monoclonal antibody to the murine IL-6 receptor partially reverted the growth defect. In NSE/hIL-6 transgenic mice, circulating IGF-I levels were significantly lower than those of nontransgenic littermates; on the contrary, the distribution of growth hormone pituitary cells, as well as circulating growth hormone levels, were normal. Treatment of nontransgenic mice of the same strain with IL-6 resulted in a significant decrease in IGF-I levels. Moreover, in patients with systemic juvenile rheumatoid arthritis, circulating IL-6 levels were negatively correlated with IGF-I levels. Our findings suggest that IL-6-mediated decrease in IGF-I production represents a major mechanism by which chronic inflammation affects growth. ( J. Clin. Invest. 1997. 99:643-650.) Key words: interleukin 6 • insulinlike growth factor-I • growth disorders • juvenile rheumatoid arthritis
C/EBP beta is considered a key element of interleukin‐6 (IL‐6) signalling as well as an important transcriptional regulator of the IL‐6 gene itself. We describe here how mice lacking C/EBP beta develop a pathology similar to mice overexpressing IL‐6 and nearly identical to multicentric Castleman's disease in human patients, with marked splenomegaly, peripheral lymphadenopathy and enhanced haemopoiesis. Humoral, innate and cellular immunity are also profoundly distorted, as shown by the defective activation of splenic macrophages, the strong impairement of IL‐12 production, the increased susceptibility to Candida albicans infection and the altered T‐helper function. Our data show that C/EBP beta is crucial for the correct functional regulation and homeostatic control of haemopoietic and lymphoid compartments.
We show that an electric treatment in the form of high-frequency, low-voltage electric pulses can increase more than 100-fold the production and secretion of a recombinant protein from mouse skeletal muscle. Therapeutical erythopoietin (EPO) levels were achieved in mice with a single injection of as little as 1 g of plasmid DNA, and the increase in hematocrit after EPO production was stable and long-lasting. Pharmacological regulation through a tetracycline-inducible promoter allowed regulation of serum EPO and hematocrit levels. Tissue damage after stimulation was transient. The method described thus provides a potentially safe and low-cost treatment for serum protein deficiencies.Genes can be transferred into skeletal muscle cells of rodents and primates by intramuscular injection of plasmid DNA, and the resulting gene expression has been reported to last as long as several months (1, 2). Similarly, various viral vectors such as adenoviral, retroviral, and AAV-based vectors (3), have been used to transduce myofibers in vivo. The i.m. injection of plasmid DNA, however, has several advantages over viral vectors. First, plasmid DNA vectors are easier to construct and can be prepared as pharmaceutical-grade solutions (4) without the risk of contamination with wild-type infectious particles. Second, previous infection by wild-type adenovirus or AAV may induce a neutralizing antibody response that could preclude administration of the recombinant virus. In contrast, anti-DNA antibodies have never been detected in experiments of muscle DNA injection (2), therefore it is possible to readminister plasmid DNA by i.m. injection if repeated therapy or escalation is required.Despite the promise of i.m. injection of plasmid vectors for treating serum protein deficiencies, several important issues remain to be addressed before this approach becomes feasible for human gene therapy. The potential clinical usefulness of direct gene transfer to muscle of plasmid DNA is in fact limited by the low and highly variable level of gene expression (1, 2, 5, 6). Therefore, although DNA injection is potentially very powerful as a vaccination method because a low level of gene expression is sufficient to trigger immunoresponses, it is necessary to increase the efficiency of DNA uptake after i.m. injection of plasmid vectors before using this technique as a standard gene correction procedure.One of the most efficient methods implemented to achieve gene transfer and expression in mammalian cells is based on electric pulses (7). Electroporation has been used to introduce foreign DNA in different cell types (7), but it has also recently met with some success in in vivo applications. Gene transfer by electrical permeabilization has been obtained in skin (8, 9), corneal endothelium (10), melanoma (11), brain (12), liver, (13) and muscle (14) of experimental animals.We have shown previously that electropermeabilization can increase severalfold the uptake by rat muscle of a plasmid encoding the Escherichia coli lacZ gene (15). In this study...
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