Increased Fli-1 mRNA is present in PBLs from systemic lupus erythematosus patients, and transgenic overexpression of Fli-1 in normal mice leads to a lupus-like disease. We report in this study that MRL/lpr mice, an animal model of systemic lupus erythematosus, have increased splenic expression of Fli-1 protein compared with BALB/c mice. Using mice with targeted gene disruption, we examined the effect of reduced Fli-1 expression on disease development in MRL/lpr mice. Complete knockout of Fli-1 is lethal in utero. Fli-1 protein expression in heterozygous MRL/lpr (Fli-1+/−) mice was reduced by 50% compared with wild-type MRL/lpr (Fli-1+/+) mice. Fli-1+/− MRL/lpr mice had significantly decreased serum levels of total IgG and anti-dsDNA Abs as disease progressed. Fli-1+/− MRL/lpr mice had significantly increased splenic CD8+ and naive T cells compared with Fli-1+/+ MRL/lpr mice. Both in vivo and in vitro production of MCP-1 were significantly decreased in Fli-1+/− MRL/lpr mice. The Fli-1+/− mice had markedly decreased proteinuria and significantly lower pathologic renal scores. At 48 wk of age, survival was significantly increased in the Fli-1+/− MRL/lpr mice, as 100% of Fli-1+/− MRL/lpr mice were alive, in contrast to only 27% of Fli-1+/+ mice. These findings indicate that Fli-1 expression is important in lupus-like disease development, and that modulation of Fli-1 expression profoundly decreases renal disease and improves survival in MRL/lpr mice.
Matrix remodeling, critical to embryonic morphogenesis and wound healing, is dependent on the expression of matrix components, their receptors, and matrix proteases. The collagen gel assay has provided an effective model for the examination of the functional role(s) of each of these groups of molecules in matrix remodeling. Previous investigations have indicated that collagen gel contraction involves the beta 1 integrin family of matrix receptors and is stimulated by several growth factors, including TGF-beta, PDGF, and angiotensin II. In particular, collagen gel remodeling by human cells involves the alpha 2 beta 1 and, to a lesser extent, the alpha 1 beta 1 integrin complexes. The present studies were undertaken to determine the role of the alpha 1 integrin chain, a collagen/laminin receptor, in collagen gel contraction by rodent and avian fibroblasts. A high degree of correlation was found between the expression of the alpha 1 beta 1 integrin complex and the relative ability of cells to contract collagen gels. Further studies using antibodies and antisense oligonucleotides against the alpha 1 integrin indicated a significant role for this integrin chain in contraction of collagen gels by rat cardiac fibroblasts. In addition, antibodies to the alpha 1 integrin chain inhibited migration of these fibroblasts on a collagen substratum, suggesting that at least one role of this integrin is in migration of cells in collagen gels. These results indicate that the alpha 1 beta 1 integrin complex plays a significant role in cellular interactions with interstitial collagen that are involved in matrix remodeling such as is seen during morphogenesis and wound healing.
Complement activation and tissue deposition of complement fragments occur during disease progression in lupus nephritis. Genetic deficiency of some complement components (e.g., Factor B) and infusion of complement inhibitors (e.g., Crry, anti-C5 Ab) protect against inflammatory renal disease. Paradoxically, genetic deficiencies of early components of the classical complement pathway (e.g., C1q, C4, and C2) are associated with an increased incidence of lupus in humans and lupus-like disease in murine knockout strains. Complement protein C3 is the converging point for activation of all three complement pathways and thus plays a critical role in biologic processes mediated by complement activation. To define the role of C3 in lupus nephritis, mice rendered C3 deficient by targeted deletion were backcrossed for eight generations to MRL/lpr mice, a mouse strain that spontaneously develops lupus-like disease. We derived homozygous knockout (C3−/−), heterozygous (C3+/−), and C3 wild-type (C3+/+) MRL/lpr mice. Serum levels of autoantibodies and circulating immune complexes were similar among the three groups. However, there was earlier and significantly greater albuminuria in the C3−/− mice compared with the other two groups. Glomerular IgG deposition was also significantly greater in the C3−/− mice than in the other two groups, although overall pathologic renal scores were similar. These results indicate that C3 and/or activation of C3 is not required for full expression of immune complex renal disease in MRL/lpr mice and may in fact play a beneficial role via clearance of immune complexes.
Fli-1 belongs to the Ets transcription factor family and is expressed primarily in hematopoietic cells, including most cells active in immunity. To assess the role of Fli-1 in lymphocyte development in vivo, we generated mice that express a truncated Fli-1 protein, lacking the C-terminal transcriptional activation domain (Fli-1ΔCTA). Fli-1ΔCTA/Fli-1ΔCTA mice had significantly fewer splenic follicular B cells, and an increased number of transitional and marginal zone B cells, compared with wild-type controls. Bone marrow reconstitution studies demonstrated that this phenotype is the result of lymphocyte intrinsic effects. Expression of Igα and other genes implicated in B cell development, including Pax-5, E2A, and Egr-1, are reduced, while Id1 and Id2 are increased in Fli-1ΔCTA/Fli-1ΔCTA mice. Proliferation of B cells from Fli-1ΔCTA/Fli-1ΔCTA mice was diminished, although intracellular Ca2+ flux in B cells from Fli-1ΔCTA/Fli-1ΔCTA mice was similar to that of wild-type controls after anti-IgM stimulation. Immune responses and in vitro class switch recombination were also altered in Fli-1ΔCTA/Fli-1ΔCTA mice. Thus, Fli-1 modulates B cell development both centrally and peripherally, resulting in a significant impact on the in vivo immune response.
Mesenchymal stem cells (MSCs) are useful in tissue repair, but also possess immunomodulatory properties. Murine and uncontrolled human trials suggest efficacy of MSCs in treating lupus. Autologous cells are preferable, however, recent studies suggest that lupus derived MSCs lack efficacy in treating disease. Thus, the optimum derivation of MSCs for use in lupus is unknown. It is also unknown which in vitro assays of MSC function predict in vivo efficacy. The objectives for this study were to provide insight into the optimum source of MSCs and to identify in vitro assays that predict in vivo efficacy. We derived MSCs from four umbilical cords (UC), four healthy bone marrows (HBM) and four lupus bone marrows (LBM). In diseased MRL/lpr mice, MSCs from HBM and UC significantly decreased renal disease, while LBM-MSCs only delayed disease. Current in vitro assays did not differentiate efficacy of the different MSCs. Inhibition of B cell proliferation did differentiate based on efficacy. Our results suggest that autologous MSCs from lupus patients are not effective in treating disease. Furthermore, standard in vitro assays for MSC licensing are not predictive of in vivo efficacy, while inhibiting B cell proliferation appears to differentiate effective from ineffective MSCs.
SummaryThe transcription factor Fli-1 is implicated in the pathogenesis of both murine and human lupus. Increased levels of Fli-1 mRNA were present in the peripheral blood lymphocytes from lupus patients; furthermore, transgenic overexpression of Fli-1 in normal mice resulted in the development of a lupus-like disease. Lupus nephritis is a major cause of death in both lupus patients as well as in animal models. In this study, we generated Fli-1 heterozygous knockout (Fli-1 +/-) NZM2410 mice (of which the wild-type is a widely used lupus murine model) that expressed decreased levels of Fli-1 and investigated the impact of Fli-1 expression on lupus nephritis development and survival. Ninety-three per cent of the Fli-1 +/-NZM2410 mice survived to the age of 52 weeks compared to only 35% of wild-type NZM2410 mice. Autoantibodies, including anti-dsDNA and anti-glomerular basement antigen, in Fli-1 +/-NZM2410 mice were statistically significantly lower when compared to wild-type NZM2410 mice at the ages of 30 and 34 weeks. Total B cell and activated B cell populations in the spleens from Fli-1 +/-NZM2410 mice were decreased significantly compared to wild-type NZM2410 mice. Fli-1 +/-NZM2410 mice also had remarkably diminished proteinuria and decreased renal pathological scores when compared with wild-type NZM2410 mice. Expression of early growth response 1 (Egr-1) was decreased significantly in the kidneys from Fli-1 +/-NZM2410 mice when compared to wildtype littermates. Our data indicate that expression of Fli-1 plays an important role in lupus disease development in NZM2410 mice.
The ETS factor FLI1 is a key modulator of lupus disease expression. Over-expressing FLI1 in healthy mice, results in the development of an autoimmune kidney disease similar to that observed in lupus. Lowering the global levels of FLI1 in two lupus strains (Fli1+/−) significantly improved kidney disease and prolonged survival. T cells from MRL/lpr Fli1+/− lupus mice have reduced activation and IL-4 production, Neuraminidase1 (Neu1) expression, and the levels of the glycosphingolipid (GSL) lactosylceramide (LacCer). Here we demonstrate that MRL/lpr Fli1+/− mice have significantly decreased renal Neu1 and LacCer levels. This corresponds with a significant decrease in the number of total CD3+ cells, as well as CD4+ and CD44+CD62L− T cell subsets in the kidney of MRL/lpr Fli1+/− mice compared to the Fli1+/+ nephritic mice. We further demonstrate that the percentage of CXCR3+ T cells and Cxcr3 message levels in T cells are significantly decreased and corresponds with a decrease in renal CXCR3+ cells and in Cxcl9 and Cxcl10 expression in the MRL/lpr Fli1+/− compared to the Fli1+/+ nephritic mice. Our results suggest that reducing the levels of FLI1 in MRL/lpr mice may be protective against development of nephritis in part through down-regulation of CXCR3, reducing renal T cell infiltration and GSL levels.
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