Abstract
CD8+ T cells play a central role in beta-cell destruction in type 1 diabetes. CD8+ T cells use two main effector pathways to kill target cells, perforin plus granzymes and FAS ligand (FASL). We and others have established that in non-obese diabetic (NOD) mice, perforin is the dominant effector molecule by which autoreactive CD8+ T cells kill beta cells. However, blocking FASL pharmacologically was shown to protect NOD mice from diabetes, indicating that FASL may have some role. FASL can engage with its receptor FAS on target cells either as membrane bound or soluble FASL. It has been shown that membrane-bound FASL is required to stimulate FAS-induced apoptosis in target cells, whereas excessive soluble FASL can induce NF-κB-dependent gene expression and inflammation. Because islet inflammation is a feature of autoimmune diabetes, we tested whether soluble FASL could be important in disease pathogenesis independent of its cell death function. We generated NOD mice deficient in soluble FASL, while maintaining expression of membrane-bound FASL due to a mutation in the FASL sequence required for cleavage by metalloproteinase. NOD mice lacking soluble FASL had normal numbers of lymphocytes in their spleen and thymus. Soluble FASL deficient NOD mice had similar islet inflammation as wild-type NOD mice and were not protected from diabetes. Our data indicate that soluble FASL is not required in development of autoimmune diabetes.
Highlights
Introduction Type1 diabetes results from destruction of insulin producing beta cells by autoreactive T cells[1,2]
Our results suggest that soluble FASL (sFASL) does not play a significant role in islet inflammation or beta-cell destruction in the pathogenesis of autoimmune diabetes in non-obese diabetic (NOD) mice
Because inflammation and proinflammatory cytokines are thought to drive autoimmunity, we studied the role of sFASL in autoimmune diabetes using NOD mice that lack sFASL while maintaining membrane-bound FASL (mFASL) and normal immune homoeostasis
Summary
Loss of soluble FASL does not affect immune homoeostasis in NOD mice We generated NOD mice deficient in secreted FASL (sFASL) by backcrossing gene-targeted C57BL/6 mice unable to shed FASL from the surface of the cells while retaining cell surface membrane-bound FASL (mFASL) onto the NOD/Lt genetic background (NOD.FasLΔs/Δs). These mice have a mutation in the sequences required for metalloprotease-mediated cleavage in the fasl gene[9]. Cumulative diabetes incidence was not different between NOD.FasLΔs/Δs and wild-type NOD mice (Fig. 2c) This is despite a slight but not significant increase in the expression of mFASL on the surface of isletinfiltrating CD4+ but not CD8+ T cells (Fig. 2d, e). Our results suggest that sFASL does not play a significant role in islet inflammation or beta-cell destruction in the pathogenesis of autoimmune diabetes in NOD mice
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