Differential partitioning and trafficking of GM gangliosides and cholesterol-rich lipid rafts in thymic and splenic CD4 T cells.

The GM gangliosides and cholesterol components of plasma membrane lipid rafts play an important role in the recruitment and signaling of protein receptors in eukaryotic cells. Herein, we have analyzed at the single-cell level the partitioning and intracellular trafficking of GM gangliosides and cholesterol in quiescent (CD4+CD69-) and CD3-activated (CD4+CD69+) thymic and splenic T cells. First, regardless the gender and the quiescent or activated status of T cells, the GM and cholesterol content in cytosol and plasma membrane as well as the expression levels of GM synthase, Sphingomyelin phosphodiestarase 2 and HMG Co-A reductase genes involved in GM and cholesterol synthesis were constantly lower in CD4 thymocytes than in CD4 splenocytes. Second, we detected variations in the balance between GM and cholesterol in plasma membrane depending on aging, and found that deprivation of cellular cholesterol does not necessarily affect the GM content in both quiescent CD4 thymocytes and splenocytes. Third, CD3 stimulation up-regulated the GM and little if any the cholesterol content in both thymic and splenic CD4 T cells, suggesting a cross talk between the CD3 signaling and GM but not cholesterol biosynthesis pathway. Fourth, partitioning and trafficking of GM to the plasma membrane depended on the transport of ceramide precursors from endoplasmic reticulum to Golgi network, as well as on the synthesis, glycosylation and vesicular assembly in trans-Golgi, and less on the cytoskeleton architecture in both quiescent and activated CD4 thymic and splenic T cells. Together, these findings suggest that the differential partitioning and intracellular trafficking of GM and cholesterol in thymic and splenic CD4 T cells may account for the stage of functional maturation.

Analysis of lipid rafts in T cells.

The plasma membrane of T cells is made of a combination of glycosphingolipids and protein receptors organized in glycolipoprotein microdomains termed lipid rafts. The structural assembly of lipid rafts was investigated by various physical and biochemical assays. Depending on the differentiation status of T cells, the lipid rafts seclude various protein receptors involved in T cell signaling, cytoskeleton reorganization, membrane trafficking, and the entry of infectious organisms into the cells. This review article summarizes the most common methods, and their limits and advantages for analyzing the composition and assembly of lipid rafts with protein receptors into lipid rafts microdomains in plasma membrane of T cells. It also includes new methods such as ELISA/Polysorp and flow cytometry, and a combined sucrose gradient centrifugation-FPLC-Western blot strategy developed in our laboratory to study non-covalent interactions between the GM1 glycosphingolipid and protein receptors in plasma membrane of T cells.

RNA degradation precedes DNA cleavage in autoreactive CD4 T cells suppressed by calicheamicin gamma1.

Calicheamicin gamma1 (Cal gamma1) is a hydrophobic enediyne antibiotic known to cleave the DNA and lead to apoptosis in a variety of cells. Herein, we show that Cal gamma1 exhibits a 1000-times stronger suppressogenic effect on antigen-specific (diabetogenic), and naïve CD4 T cells than Doxorubicin (Dox), another strong apoptotic drug. The thymic precursors and mature T cells incubated with Cal gamma1 for only 30 min showed a drastic decrease or loss of cytokine production and proliferation following stimulation with the immunogenic peptide, or with CD3 and CD28 antibodies. The suppressogenicity of Cal gamma1 correlated with a rapid and non-selective degradation of RNA, whereas the DNA cleavage occurred at a later time point and at higher doses. Cal gamma1 may represent a potential therapeutic agent to eliminate self-reactive T cells in autoimmune diseases, providing that is delivered by antigen-specific T-cell ligands. Targeting of highly suppressogenic drugs such as Cal gamma1 to autoreactive T cells may reduce considerable the therapeutic dose and the drug-related side effects.

Efficacy of clonal deletion vs. anergy of self-reactive CD4 T-cells for the prevention and reversal of autoimmune diabetes.

The self-reactive CD4 T-cells play an essential role in triggering and sustaining organ-specific autoimmune diseases. Silencing or elimination of these cells can prevent and reverse an autoimmune process. We have previously showed that a single dose-administration of a soluble dimeric MHC II-peptide chimera (DEF) in double-transgenic mice delayed the onset autoimmune diabetes, and restored the euglycemia in already diabetic mice for a period of 1 week. DEF dimer protection relied on induction of anergy of diabetogenic CD4 T-cells in spleen, and stimulation of IL-10-secreting T regulatory type 1 cells in pancreas. Herein, we show that an octameric form of DEF has doubled the period of protection and reversal of disease by clonal deletion of diabetogenic CD4 T-cells in both the thymic and peripheral compartments. Deletion occurred by activation-induced cell death subsequent to repartitioning and signaling of FAS-FADD apoptotic module in the plasma membrane lipid rafts. Our previous and present data indicated first, that DEF valence translates into various effects on the antigen-specific CD4 T-cells, i.e., Th2 immune deviation, anergy, and apoptosis. Second, the present findings argue for a better efficacy of clonal deletion than anergy of diabetogenic CD4 T-cells for the protection and reversal of autoimmune diabetes.

A model for antigen-specific T-cell anergy: displacement of CD4-p56(lck) signalosome from the lipid rafts by a soluble, dimeric peptide-MHC class II chimera.

Soluble, dimeric peptide-MHC chimeras were shown to induce Ag-specific T cell anergy in vitro and in vivo. In this study, we describe a mechanism by which a soluble, dimeric peptide MHC class II chimera (DEF) induces Ag-specific T cell anergy. The anergic cells showed a displacement of the CD4-p56(lck) signaling module from the GM1-rich plasma membrane microdomains (lipid rafts), and subsequently an increase in p59(fyn) kinase activity, a dominant expression of p21 inhibitory TCR zeta-chain, and a poor phosphorylation and recruitment of zeta-associated protein of 70 kDa kinase to the TCR's immunoreceptor tyrosine-based activation motifs. The Th1 and Th2 transcription was suppressed and the cells were arrested in the Th0 stage of differentiation. Recovery from DEF anergy occurred late and spontaneously at the expense of low thresholds for activation-induced cell death. In contrast to DEF, a combination of TCR and CD4 mAbs did not induce such alterations or anergy, indicating that the ligand-mediated topology of TCR and CD4 coengagement can differentially affect the T cell function. Our results argue for a model of anergy in which the defective partitioning of signaling molecules in lipid rafts is an early, negative signaling event in T cells. Physiological ligands like DEF chimeras may provide new tools for silencing the autoimmune processes, and may also help in deciphering new mechanisms of negative regulation in T cells.