Autoimmunity stimulated by adoptively transferred dendritic cells is initiated by both alphabeta and gammadelta T cells but does not require MyD88 signaling

Vaccination of nonautoimmune prone mice with syngeneic dendritic cells (DC) readily induces anti-DNA autoantibodies but does not trigger systemic disease. We observed that anti-DNA autoantibody generation absolutely required alphabeta T cells and that gammadelta T cells also contributed to the response, but that regulatory T cells restrained autoantibody production. Although both NZB/W F(1) mice and DC vaccinated C57/BL6 mice produced autoantibodies against dsDNA, vaccinated mice had higher levels of Abs against H1 histone and lower levels of antinucleosome Abs than NZB/W F(1) mice. Despite a 100-fold increase in IL-12 and Th1 skewing to a foreign Ag, OVA, synergistic TLR activation of DC in vitro failed to augment anti-DNA Abs or promote class switching beyond that induced by LPS alone. TLR stimulation was not absolutely required for the initial loss of B cell tolerance because anti-DNA levels were similar when wild-type (WT) or MyD88-deficient DC were used for vaccination or WT and MyD88-deficient recipients were vaccinated with WT DC. In contrast, systemic administration of LPS, augmented anti-DNA Ab levels and promoted class switching, and this response was dependent on donor DC signaling via MyD88. LPS also augmented responses in the MyD88-deficient recipients, suggesting that LPS likely exerts its effects on both transferred DC and host B cells in vivo. These results indicate that both the alphabeta and gammadelta subsets are necessary for promoting autoantibody production by DC vaccination, and that although TLR/MyD88 signaling is not absolutely required for initiation, this pathway does promote augmentation, and Th1-mediated skewing, of anti-DNA autoantibodies.     

Smad-dependent cooperative regulation of interleukin 2 receptor alpha chain gene expression by T cell receptor and transforming growth factor-beta

The interleukin 2 receptor alpha chain (IL-2Ralpha) is a component of high affinity IL-2 receptors and thus critically regulates T cell growth and other lymphoid functions. Five positive regulatory regions together control lineage-restricted and activation-dependent IL-2Ralpha induction in response to antigen and IL-2. We now show that TGF-beta cooperates with T cell receptor (TCR) signaling to increase IL-2Ralpha gene expression. Moreover, we identify a sixth positive regulatory region that regulates IL-2Ralpha expression in cells treated with anti-CD3 + anti-CD28 as well as TGF-beta and show that this region contains binding sites for Smad3, AP-1, and cAMP-responsive element-binding protein/ATF proteins. The importance of Smad complexes is indicated by impaired IL-2Ralpha induction by TGF-beta in CD4+ T cells from both Smad3-/- and Smad4-/- mice. Thus, we have identified a novel positive regulatory region in the IL-2Ralpha gene that mediates TGF-beta-dependent induction of the gene. These findings have implications related to IL-2Ralpha expression on activated T cells and regulatory T cells.     

Cutting edge: memory CD8 T cell maturation occurs independently of CD8alphaalpha

As memory CD8 T cells form during acute viral infection, several changes in gene expression and function occur, but little is known about the control of this process. It was reported previously that the homodimer CD8alphaalpha was involved in generating IL-7Ralphahigh memory CD8 T cell precursors, and consequently, protective memory CD8 T cells did not form in animals significantly impaired in CD8alphaalpha expression (E8(I)-/- mice). However, the precise contribution of CD8alphaalpha to sustained IL-7Ralpha expression and other memory CD8 T cell-associated changes has not been investigated. We found that IL-7Ralpha expression and generation of memory CD8 T cells that protect against secondary viral infection was considerably normal in E8(I)-/- animals. Interestingly, virus-specific CD4 T cell responses were elevated, and the relative surface levels of CD8alphabeta in activated T cells were reduced in E8(I)-/- mice compared with wild-type animals. Our results indicate that memory CD8 T cell development can occur independently of CD8alphaalpha.     

Cutting edge: IL-7-independent regulation of IL-7 receptor alpha expression and memory CD8 T cell development

Expression of IL-7Ralpha on a subset of Ag-specific effector CD8 T cells is believed to identify memory cell precursors. However, whether IL-7 regulates IL-7Ralpha expression in vivo and is responsible for selective survival of IL-7Ralpha(+) effector cells is unknown. Our results show that in the absence of IL-7, IL-7Ralpha expression was extinguished on the majority of CD8 T cells responding to virus infection, sustained on a subset of effector cells transitioning to memory, and expressed at high levels by memory cells. Additionally, an IL-7-deficient environment was capable of supporting bcl-2 up-regulation and memory cell development in response to virus infection. Thus, IL-7Ralpha regulation occurs independently of IL-7 in responding CD8 T cells, indicating that CD8 memory T cell precursors are not selected by IL-7/IL-7Ralpha interactions.     

Down-regulation of IL-7Ralpha expression in human T cells via DNA methylation

IL-7 is critical for the development and survival of T cells. Recently, we found two subsets of human CD8+ T cells expressing IL-7Ralpha(high) and IL-7Ralpha(low) with different cell survival responses to IL-7. Although these CD8+ T cell subsets have differential IL-7Ralpha gene expression, the mechanism for this is unknown. DNA methylation is an important gene regulatory mechanism and is associated with the inactivation of gene expression. Thus, we investigated a role for DNA methylation in differentially regulating IL-7Ralpha gene expression in human CD8+ T cells and Jurkat T cells. IL-7Ralpha(high)CD8+ T cells had decreased methylation in the IL-7Ralpha gene promoter compared with IL-7Ralpha(low)CD8+ T cells and Jurkat T cells with low levels of IL-7Ralpha. Treating Jurkat T cells with 5-aza-2'-deoxycytidine, which reduced DNA methylation, increased IL-7Ralpha expression. Plus, the unmethylated IL-7Ralpha gene promoter construct had higher levels of promoter activity than the methylated one as measured by a luciferase reporter assay. These findings suggest that DNA methylation is involved in regulating IL-7Ralpha expression in T cells via affecting IL-7Ralpha gene promoter activity, and that the methylation of this gene promoter could be a potential target for modifying IL-7-mediated T cell development and survival.     

Regulation of T cell-dependent autoantibody production by a gammadelta T cell line derived from lupus-prone mice

Lupus-prone (MRLxC57BL/6) F(1) mice lacking gammadelta T cells show more severe lupus than their T cell-intact counterparts, suggesting that gammadelta T cells down-modulate murine lupus. To determine the mechanisms for this effect, we assessed the capacity of gammadelta T cell lines derived from spleens of alphabeta T cell-deficient MRL/Mp-Fas(lpr) (MRL/Fas(lpr)) mice to down-regulate anti-dsDNA production generated by CD4(+)alphabeta T helper cell lines and activated B cells from wild-type MRL/Fas(lpr) mice. One line, GD12 (gd TCR(+), CD4(-)CD8(-)), had the capacity to reduce anti-dsDNA production in a contact-dependent manner. GD12 also killed activated MRL/Fas(lpr) (H-2(k)) B cells, with less cytolysis of resting B cells than that generated by in comparison to cytokine-matched gammadelta T cell lines. In addition, GD12 also killed activated B cells derived from C57BL/6-Fas(lpr) (H-2(b)) or beta(2)-microglobulin (beta(2) M)-deficient MRL/Fas(lpr) mice, suggesting cytolysis was neither MHC- nor CD1-restricted. Killing by GD12 was inhibited by anti-TNFalpha and anti-TNF-R1, and partially blocked by anti-gd TCR Fab fragments, but not by anti-FasL, anti-TNF-R2 (p75) or concanamycin A. IL-10 produced by GD12 also partially inhibited alphabeta Th1-dependent but not alphabeta Th2-dependent autoantibody production. These findings prove that we have identtified a gammadelta T cell line that suppresses autoantibody synthesis by alphabeta T-B cell collaboration in vitro.     

The type 1 cysteinyl leukotriene receptor triggers calcium influx and chemotaxis in mouse alpha beta- and gamma delta effector T cells

Linker for activation of T cells (LAT) is essential for T cell activation. Mice with mutations of distinct LAT tyrosine residues (LatY136F and Lat3YF) develop lymphoproliferative disorders involving TCR alphabeta or gammadelta T cells that trigger symptoms resembling allergic inflammation. We analyzed whether these T cells share a pattern of gene expression that may account for their pathogenic properties. Both LatY136F alphabeta and Lat3YF gammadelta T cells expressed high levels of the type 1 cysteinyl leukotriene receptor (CysLT(1)). Upon binding to the 5(S)-hydroxy-6(R)-S-cysteinylglycyl-7,9-trans-11,14-cis-eicosatetraenoic acid (LTD(4)) cysteinyl leukotriene, CysLT(1) induced Ca(2+) flux and caused chemotaxis in both LatY136F alphabeta and Lat3YF gammadelta T cells. Wild-type in vitro-activated T cells, but not resting T cells, also migrated toward LTD(4) however with a lower magnitude than T cells freshly isolated from LatY136F and Lat3YF mice. These results suggest that CysLT(1) is likely involved in the recruitment of activated alphabeta and gammadelta T cells to inflamed tissues.