TCR-induced downregulation of protein tyrosine phosphatase PEST augments secondary T cell responses

We report that the protein tyrosine phosphatase PTP-PEST is expressed in resting human and mouse CD4(+) and CD8(+) T cells, but not in Jurkat T leukemia cells, and that PTP-PEST protein, but not mRNA, was dramatically downregulated in CD4(+) and CD8(+) primary human T cells upon T cell activation. This was also true in mouse CD4(+) T cells, but less striking in mouse CD8(+) T cells. PTP-PEST reintroduced into Jurkat at levels similar to those in primary human T cells, was a potent inhibitor of TCR-induced transactivation of reporter genes driven by NFAT/AP-1 and NF-kappaB elements and by the entire IL-2 gene promoter. Introduction of PTP-PEST into previously activated primary human T cells also reduced subsequent IL-2 production by these cells in response to TCR and CD28 stimulation. The inhibitory effect of PTP-PEST was associated with dephosphorylation the Lck kinase at its activation loop site (Y394), reduced early TCR-induced tyrosine phosphorylation, reduced ZAP-70 phosphorylation and inhibition of MAP kinase activation. We propose that PTP-PEST tempers T cell activation by dephosphorylating TCR-proximal signaling molecules, such as Lck, and that down-regulation of PTP-PEST may be a reason for the increased response to TCR triggering of previously activated T cells.     

IL-12 reverses anergy to T cell receptor triggering in human lung tumor-associated memory T cells

Memory T cells in human non-small cell lung cancer are unresponsive to progressing tumors. T cells were evaluated at the single cell level by imaging the nuclear translocation of NF-kappaB and NFAT via immunofluorescence confocal microscopy as an early measure of responsiveness to T cell receptor triggering. Little translocation of NF-kappaB or NFAT occurred in tumor-associated T cells in response to CD3+CD28 cross-linking under conditions which led to maximal translocation in normal donor peripheral blood T cells. TNF-alpha induced maximal NF-kappaB translocation in these T cells, indicating that they remain receptive to alternative signaling pathways, and pulsing with IL-12 prior to TCR triggering reversed their apparent anergy. T cells from additional chronic inflammatory microenvironments demonstrated a similar refractoriness to TCR activation, suggesting either that a common regulatory mechanism present within the microenvironment controls these cells or that with continuous antigen exposure, they remain refractory to activation via the TCR.     

Impaired IL-4 production by CD8+ T cells in NOD mice is related to a defect of c-Maf binding to the IL-4 promoter

CD8(+) T cells play an important role in the induction of the autoimmune response in non-obese diabetic (NOD) mice. Here we describe abnormalities in the control of cytokine production by NOD CD8(+) T cells. NOD CD8(+) T cells had an increased propensity to produce IFN-gamma upon TCR activation, in both adult and 2-week-old mice. NOD CD8(+) T cells had a reduced capacity to produce IL-4 in type 2 conditions compared to CD8(+) T cells from the diabetes-resistant strains BALB/c and C57BL/6. Both GATA-3 and c-Maf, two positive transactivators for IL-4 gene expression, were expressed in type 2 conditions at comparable levels in NOD CD8(+) T cells. The GATA-3 was functional since normal levels of IL-5 were produced and the IL-4 promoter was hyperacetylated in NOD CD8(+) T cells. In contrast, c-Maf failed to bind to its responsive element as determined by chromatin immunoprecipitation (ChIP) assay. These results suggest that NOD CD8(+) T cells possess an increased propensity to produce IFN-gamma and impaired c-Maf-dependent DNA binding activities in vivo that lead to reduced IL-4 production following TCR activation. These defects may facilitate the development of the autoimmune response by inducing an overall type 1-biased immune response in NOD mice.     

WSX-1 over-expression in CD4(+) T cells leads to hyperproliferation and cytokine hyperproduction in response to TCR stimulation

WSX-1 is a component of the IL-27R. Analyses of WSX-1 knockout (WSX-1(-/-)) mice have shown that IL-27/WSX-1 signaling is essential for the proper development of T(h)1 responses and that WSX-1 can suppress cellular activation and pro-inflammatory cytokine production. We have generated transgenic mouse lines over-expressing the WSX-1 gene under the control of the T cell-specific CD2 promoter (WSX-1 Tg mice). Unexpectedly, like activated CD4(+) T cells from WSX-1(-/-) mice, activated CD4(+) T cells from WSX-1 Tg mice showed increased proliferation, augmented IL-2 production and up-regulated surface expression of activation markers. IL-27-mediated tyrosine phosphorylation of STAT1 was also enhanced in WSX-1 Tg CD4(+) T cells, but STAT3 activation was normal. Exogenous IL-27 supported the proliferation of wild-type CD4(+) T cells but suppressed that of WSX-1 Tg cells. WSX-1 over-expression increased IFN-gamma production in T(h)1-polarized CD4(+) T cells, but also promoted T(h)2 cytokine production under T(h)1-polarizing conditions. Importantly, WSX-1 over-expression failed to suppress T(h)2 cytokine production under T(h)2-polarizing conditions. Cytokine hyperproduction was also observed in vivo in WSX-1 Tg mice injected with Con A. Our data suggest that WSX-1 plays a pivotal role in regulating T cell responsiveness to TCR stimulation and that the correct balance of STAT1/STAT3 activation downstream of IL-27R engagement is crucial for the physiological function of IL-27.     

Proliferative arrest and cell cycle regulation in CD8(+)CD28(-) versus CD8(+)CD28(+) T cells

CD8(+)CD28(-) T cells have been characterized by oligoclonal expansions, impaired proliferative responses, but preserved cytotoxicity and reduced telomeres. To examine this subset further and define the underlying mechanisms of proliferation arrest, we investigated several features of this cell type compared with CD8(+)CD28(+) controls. We analyzed expression of various activation markers, thymidine incorporation upon activation, T-cell receptor (TCR) zeta-chain phosphorylation, cell cycle characteristics, and cell cycle related gene expression. Flow cytometry revealed higher expression of CD11b, CD29, CD57, and CD94, and lower expression of CD25 in CD8(+)CD28(-) compared with CD8(+)CD28(+) T cells. Sorted CD8(+)CD16(-)CD28(-) cells exhibited decreased phosphorylation of the TCR zeta-chain in three of four probands. Proliferation of these T cells was impaired, even when activated with mitogens that bypass TCR signaling. Cell cycle profiles demonstrated a lower percentage of cycling cells and significantly higher levels of cyclin dependent kinase inhibitor p16(INK4a) in the CD28(-) subset compared with the CD28(+) control. These observations suggest that expanded CD8(+)CD28(-) T cells in normal elderly individuals have reduced proliferation concomitant with increased p16(INK4a) expression. Defects in TCR signaling were associated with altered TCR zeta-chain phosphorylation.     

Control of T cell hyperactivation in IL-2-deficient mice by CD4(+)CD25(-) and CD4(+)CD25(+) T cells: evidence for two distinct regulatory mechanisms

In IL-2-deficient mice, antigen-activated CD4 T cells accumulate and cause lethal immune pathology. Wild-type cells of hematopoietic origin present in the same animal are able to prevent this hyperactivation of T cells, but the mechanisms and cells controlling the IL-2-deficient cells are unknown. Here we show that IL-2(-) CD4 cells with an ovalbumin-specific transgenic TCR (IL-2(-) OVAtg) undergo both clonal expansion and clonal contraction when transferred to euthymic recipients and challenged with antigen, but continuously expand in athymic hosts. Cotransfer of wild-type CD4 T cells prevents the accumulation of IL-2-deficient cells. On the residual IL-2(-) TCRtg cells CD69 and CD25 are up-regulated, suggesting that activation per se is not suppressed and that the cells had received an IL-2 signal. Since IL-2 is able to restore the defective antigen-induced cell death (AICD) of IL-2-deficient T cells in vitro, paracrine IL-2 provided by the wild-type CD4 cells may thus be able to allow clonal contraction of IL-2-deficient cells also in vivo. Interestingly however, regulatory CD4(+)CD25(+) cells also efficiently contain the clone size of antigen-stimulated IL-2-deficient T cells. Since CD4(+)CD25(+) cells do not produce IL-2, this suggests a mechanism of suppression distinct from paracrine IL-2 delivery. In keeping with this, the residual IL-2(-) TCRtg cells recovered after cotransfer of regulatory CD4(+)CD25(+) cells do not show increased CD25 or CD69 expression, suggesting that they had not received paracrine IL-2 and that clonal containment occurred at the level of initial activation rather than clonal contraction by AICD. IL-2 deficiency therefore may upset T cell homeostasis by two distinct mechanisms: the failure to program expanding T cells for apoptosis, and the failure to generate functional CD4(+)CD25(+) regulatory cells.     

IL-2 and IL-7 differentially induce CD4-CD8- alpha beta TCR+NK1.1+ large granular lymphocytes and IL-4-producing cells from CD4-CD8- alpha beta TCR+NK1.1- cells: implications for the regulation of Th1- and Th2- type responses

Effector functions of CD4-CD8- double negative (DN) alpha beta TCR+ cells were examined. Among mouse DN alpha beta TCR+ thymocytes, NK1.1+ cells expressing a canonical V alpha 14/J alpha 281 TCR but not NK1.1- cells produce IL-4 upon TCR cross-linking and IFN-gamma upon cross- linking of NK1.1 as well as TCR. Production of IL-4 but not IFN-gamma from DN alpha beta TCR+NK1.1+ cells was markedly suppressed by IL-2. Whereas V alpha 14/J alpha 281 TCR+ cells express NK1.1+, these cells are not the precursor of DN alpha beta TCR+NK1.1+CD16+B220+ large granular lymphocytes (LGL). IL-2 induces rapid proliferation and generation of NK1.1+ LGL from DN alpha beta TCR+NK1.1- but not from DN alpha beta TCR+NK1.1+ cells. LGL cells exhibit NK activity and produce IFN-gamma but not IL-4 upon cross-linking of surface TCR or NK1.1 molecules. In contrast to IL-2, IL-7 does not induce LGL cells or NK activity from DN alpha beta TCR+NK1.1- cells but induces the ability to produce high levels of IL-4 upon TCR cross-linking. Our results show that DN alpha beta TCR+ T cells have several distinct subpopulations, and that IL-2 and IL-7 differentially regulate the functions of DN alpha beta TCR+ T cells by inducing different types of effector cells.      

Immature thymocytes that fail to express TCRbeta and/or TCRgamma delta proteins die by apoptotic cell death in the CD44(-)CD25(-) (DN4) subset.

Pre-TCR/CD3 signals are essential for survival and maturation of (CD44(-)25(+)) DN3 thymocytes via the (CD44(-)25(-)) DN4 stage to CD4(+)CD8(+) (DP) cells, a process termed beta-selection. The exact developmental stages of apoptosis resulting from lack of pre-TCR/CD3 signals have so far not been determined. Here we analyzed apoptotic cell death in relation to expression of clonotypic TCR polypeptides and to cell cycle status in immature thymocyte subpopulations of wild type (wt) mice and of several strains of mice with compromised pre-TCR/CD3 signaling complexes. In wt mice or pre-TCR/CD3-deficient mice, apoptotic cells could not be detected among DN3 cells but accumulated in a subset of DN4 expressing CD69. Apoptotic CD69(+)DN4 cells were rare in wt mice and were found among DN4 cells that were negative or low for intracellular TCRbeta and negative for TCRgamma delta polypeptide chains. Apoptotic CD69(+)DN4 cells were abundant in pre-TCR/CD3 signaling-deficient mice in which most DN4 cells failed to express clonotypic TCR polypeptides. Survival of DN4 cells, but not maturation of DN3 cells to DN4, was found to depend on the expression of clonotypic TCR polypeptides in the same cell. The results suggest that thymocytes unsuccessful in alpha beta or in gamma delta lineage development die by apoptosis in the DN4 subset.     

The HIV-1 Nef protein has a dual role in T cell receptor signaling in infected CD4+ T lymphocytes

The phenotypic changes that are induced by immune activation in CD4⁺ T lymphocytes provide an optimal environment for efficient HIV-1 replication in these cells. The pathogenic Nef protein of HIV-1 modulates the T cell receptor (TCR) signaling, but whether this has a positive or negative effect on cellular activation is a matter of debate. Here we have investigated the response to TCR stimulation of primary CD4⁺ T lymphocytes infected with wt or Nef-deficient HIV-1. Results show that, in freshly isolated quiescent T cells, Nef superinduces NFAT and IL-2 production bypassing early TCR effector molecules. Conversely, the early phosphorylation of PLC-γ1, the induction of NFAT, and the expression of IL-2 are impaired by Nef in sub-optimally activated/resting T cells. Our data indicate that Nef has a dual role in the modulation of TCR signaling aimed at favoring HIV-1 replication and spread in both quiescent and metabolically active CD4⁺ T lymphocytes.     

Liver TCRγδ(+) CD3(+) CD4(-) CD8(-) T cells contribute to murine hepatitis virus strain 3-induced hepatic injury through a TNF-α-dependent pathway

The mechanisms of each subset of immune cells contributing to the pathogenesis of viral hepatitis remain incompletely understood. In this study, we examined the role of liver CD4(-) CD8(-) (double negative, DN) T cells during murine hepatitis virus strain 3 (MHV-3)-induced hepatitis in C3H/HeJ mice. We demonstrate that predominant population of DN T cells in the liver of healthy or MHV-3-infected mice express TCRγδ(+). The proportion of TCRγδ(+) DN T cells in liver CD3(+) T cells was markedly increased after MHV-3 infection. Adoptive transfer of TCRγδ(+) DN T cells led to dramatically decreased survival in MHV-3-infected mice, accompanied by deteriorated histopathology and elevated ALT and AST levels. It was found that these cells were hyperactivated after MHV-3 infection with a production of TNF-α, IFN-γ, IL-2 and IL-17A. Highly activated liver TCRγδ(+) DN T cells were cytotoxic to MHV-3-infected hepatocytes in vitro and this effect did not require cell-cell contact. Moreover, the cytotoxic effect of liver TCRγδ(+) DN T cells against hepatocytes involves TNF-α pathway, but not IL-17A or IFN-γ. These results indicate that liver TCRγδ(+) DN T cells play a critical role in the liver injury in MHV-3-induced hepatitis, via a TNF-α dependent pathway.     

Characterization of CD4- CD8- CD3+ T-cell receptor-alphabeta+ T cells in murine cytomegalovirus infection

In this study, we have investigated that after the intraperitoneal infection with murine cytomegalovirus (MCMV), the CD3+ CD4- CD8-(double negative; DN) T-cell receptor (TCR)alphabeta+ T cells increased in peritoneal cavity, liver and spleen in both resistant C57BL/6 and susceptible BALB/c mice. The total cellular population of these cells showed peak levels around day 5 after infection in all the three investigated organs and the following phenotypical and functional characteristics emerged. The peritoneal DN TCRalphabeta+ T cells expressed highly skewed TCRVbeta8 on day 5 after infection compared with the uninfected mice, but those in spleen and liver showed moderate and low skewed TCRVbeta8, respectively. The percentages of NK1.1+ DN TCRalphabeta+ T cells gradually decreased as did modulation of some of their activation markers consistent with an activated cell phenotype. The peritoneal DN TCRalphabeta+ T cells on day 5 after infection expressed the genes of interferon-gamma (IFN-gamma), tumour necrosis factor-alpha, Eta-1 (early T-cell activation-1) and MCP-1 (monocyte chemoattractant protein 1) but lacked expression of interleukin-4 (IL-4). After in vitro stimulation with phorbol 12-myristate 13-acetate and calcium ionophore in the presence of Brefeldin A, higher frequencies of intracellular IFN-gamma+ DN TCRalphabeta+ T cells were detected in all three investigated organs of infected mice compared with those of uninfected mice. Stimulation of peritoneal DN TCRalphabeta+ T cells with plate-bound anti-TCRbeta monoclonal antibodies showed proliferation and also produced IFN-gamma but not IL-4. These results suggest that DN TCRalphabeta+ T cells were activated and may have an antiviral effect through producing IFN-gamma and some macrophage-activating factors during an early phase of MCMV infection.