Prevention of toxic epidermal necrolysis by regulatory T cells

To analyze immunoregulation of autoreactive T cells specific for epidermal skin antigens, we crossed transgenic mice expressing ovalbumin selectively in keratinocytes under the keratin 5 promoter (K5-mOVA) with mice expressing a K(b)-restricted OVA-specific T cell receptor transgene (OT-I). In athymic double-transgenic mice, OT-I cells developed extrathymically and, at 8-12 weeks of age, initiated severe epidermal damage mimicking toxic epidermal necrolysis (TEN). In contrast, euthymic double-transgenic mice showed thymic deletion of OT-I cells, had few of these cells in the periphery, and never developed skin changes mimicking TEN. Adoptive transfer of OT-I cells isolated from euthymic double-transgenic mice induced TEN in athymic K5-mOVA single-transgenic mice. This spontaneous disease in athymic double-transgenic mice was prevented by transferring lymph node cells from euthymic mice, but was not prevented when CD4(+) or CD25(+) cells were depleted from this population. Although purified CD4(+)CD25(+) cells scarcely prevented the skin disease induced by adoptive transfer of OT-I cells, they efficiently prevented the disease when co-transferred with CD11c(+) dendritic cells. These results suggested that thymus-derived regulatory T cells cooperate with CD11c(+) dendritic cells to prevent life-threatening skin damage such as TEN.     

Plasmacytoid dendritic cells mediate oral tolerance

Oral tolerance prevents oral sensitization to dietary antigens (Ags), including proteins and haptens, and development of delayed-type hypersensitivity (DTH) responses. We showed here that plasmacytoid dendritic cells (pDCs) prevented oral T cell priming and were responsible for systemic tolerance to CD4(+) and CD8(+) T cell-mediated DTH responses induced by Ag feeding. Systemic depletion of pDCs prevented induction of tolerance by antigen feeding. Transfer of oral Ag-loaded liver pDCs to naive recipient mice induced Ag-specific suppression of CD4(+) and CD8(+) T cell responses to protein and hapten, respectively. Liver is a site of oral Ag presentation, and pDCs appeared to induce anergy or deletion of Ag-specific T cells in the liver relatively rapidly via a CD4(+) T cell-independent mechanism. These data demonstrate that oral tolerance relies on Ag presentation by pDC to T cells and suggest that pDC could represent a key therapeutic target for intestinal and systemic inflammatory diseases.     

Different perforin expression in peripheral blood and prostate tissue in patients with benign prostatic hyperplasia and prostate cancer

Perforin (P) is a prototypical cytotoxic molecule involved in cell-mediated immunity against various pathogens, alloantigens and particularly different tumours. The purpose of this study was to determine P expression in different lymphocyte subpopulations isolated from peripheral blood and prostate tissue of patients with benign prostatic hyperplasia (BPH) and prostate cancer (PCa) and compare it with the P expression found in the control group. Twenty subjects were recruited in each of the groups. Prostate mononuclear cells of the BPH and PCa tissues were isolated by enzymatic digestion and gradient density centrifugation, whereas peripheral blood mononuclear cells were isolated by gradient density centrifugation alone. Cells and tissue samples were labelled using monoclonal antibodies against P and different surface antigens (CD3, CD4, CD8 and CD56) and analysed by immunofluorescence and flow cytometry. Total P expression in peripheral blood lymphocytes did not differ significantly between BPH/PCa patients and control group, although the BPH and PCa tissue showed lower P expression level. A negative correlation between prostate-specific antigen levels and the overall percentage of P(+), CD3(+) CD56(-) P(+) , and CD3(-) CD56(+) P(+) cells in the prostate tissue was observed only in patients with PCa. Our findings indicate that the low frequency of P(+) lymphocytes, including T, NKT and NK cells, in the prostate tissue of patients with BPH and, particularly, PCa could be the consequence of local tissue microenvironment and one of the mechanisms involved in the pathogenesis of prostate hyperplasia following malignant alteration.     

Resting dendritic cells induce peripheral CD8+ T cell tolerance through PD-1 and CTLA-4

T cells recognizing self proteins exist without causing autoimmunity in healthy individuals. These autoreactive T cells are kept in check by peripheral tolerance. Using a model for peripheral CD8(+) T cell tolerance resulting from antigen presentation by resting dendritic cells in vivo, we show here that CD8(+) T cell tolerance operates through T cell-intrinsic mechanisms such as deletion or functional inactivation. Peripheral CD8(+) T cell tolerance depended on signaling via the costimulatory molecule PD-1, as an absence of PD-1 converted tolerance induction into priming. Blocking of the costimulatory molecule CTLA-4 resulted in impaired tolerance and enhanced the effect of the absence of PD-1, suggesting that PD-1 and CTLA-4 act synergistically. Thus PD-1 and CTLA-4 are crucial molecules for peripheral CD8(+) T cell tolerance induced by resting dendritic cells.     

T cells with low avidity for a tissue-restricted antigen routinely evade central and peripheral tolerance and cause autoimmunity

T cells causing autoimmunity must escape tolerance. We observed that CD8(+) T cells with high avidity for an antigen expressed in the pancreas, kidney, and thymic medulla were efficiently removed from a polyclonal repertoire by central and peripheral tolerance mechanisms. However, both mechanisms spared low-avidity T cells from elimination. Neither the introduction of activated, self-antigen-specific CD4(+) helper T cells nor a global inflammatory stimulus were sufficient to activate the low-avidity CD8(+) T cells and did not break tolerance. In contrast, challenge with a recombinant bacterium expressing the self antigen primed the low-avidity T cells, and the animals rapidly developed autoimmune diabetes. We suggest that whereas thymic and peripheral tolerance mechanisms remove cells that can be primed by endogenous amounts of self antigen, they do not guard against tissue destruction by low-avidity effector T cells, which have been primed by higher amounts of self antigen or by crossreactive antigens.     

Peripheral antigen display by lymph node stroma promotes T cell tolerance to intestinal self

The intestinal epithelium functions to absorb nutrients and to protect the organism against microbes. To prevent autoimmune attack on this vital tissue, T cell tolerance to intestinal self-antigens must be established. Central tolerance mechanisms involve medullary thymic epithelial cells (mTECs), which use endogenously expressed peripheral-tissue antigens (PTAs) to delete self-reactive thymocytes. The prevailing model for the induction of peripheral tolerance involves cross-presentation of tissue antigens by quiescent dendritic cells. Here we show that lymph node stromal cells present endogenously expressed PTAs to T cells. Moreover, antigen presentation by lymph node stroma is sufficient to induce primary activation and subsequent tolerance among CD8(+) T cells. Thus, lymph node stromal cells are functionally akin to mTECs and provide a direct strategy for purging the peripheral repertoire of self-reactive T cells.     

Antigen requirements for efficient priming of CD8+ T cells by Leishmania major-infected dendritic cells

CD4(+) and CD8(+) T-cell responses have been shown to be critical for the development and maintenance of acquired resistance to infections with the protozoan parasite Leishmania major. Monitoring the development of immunodominant or clonally restricted T-cell subsets in response to infection has been difficult, however, due to the paucity of known epitopes. We have analyzed the potential of L. major transgenic parasites, expressing the model antigen ovalbumin (OVA), to be presented by antigen-presenting cells to OVA-specific OT-II CD4(+) or OT-I CD8(+) T cells. Truncated OVA was expressed in L. major as part of a secreted or nonsecreted chimeric protein with L. donovani 3' nucleotidase (NT-OVA). Dendritic cells (DC) but not macrophages infected with L. major that secreted NT-OVA could prime OT-I T cells to proliferate and release gamma interferon. A diminished T-cell response was observed when DC were infected with parasites expressing nonsecreted NT-OVA or with heat-killed parasites. Inoculation of mice with transgenic parasites elicited the proliferation of adoptively transferred OT-I T cells and their recruitment to the site of infection in the skin. Together, these results demonstrate the possibility of targeting heterologous antigens to specific cellular compartments in L. major and suggest that proteins secreted or released by L. major in infected DC are a major source of peptides for the generation of parasite-specific CD8(+) T cells. The ability of L. major transgenic parasites to activate OT-I CD8(+) T cells in vivo will permit the analysis of parasite-driven T-cell expansion, differentiation, and recruitment at the clonal level.     

Lymphopenia-driven CD8(+) T cells are resistant to antigen-induced tolerance in NOD.scid mice

T cells undergoing lymphopenia-driven proliferation acquire effector and memory properties that can be pathogenic. Indeed, generalized lymphopenia is associated with a variety of autoimmune diseases such as type 1 diabetes. The current study was carried out to determine how CD8(+) T cells undergoing acute lymphopenic expansion respond to antigen under tolerizing conditions in vivo. Adoptive transfer of diabetes by TCR-transgenic CD8(+) T cells was enhanced following treatment of NOD. scid recipients with a high dose of soluble peptide. Furthermore, whereas TCR-transgenic CD8(+) T cells underwent clonal deletion and failed to differentiate into CTL in peptide-treated lymphoreplete recipient mice, TCR-transgenic CD8(+) T cells in a lymphopenic environment were resistant to clonal deletion, and CTL differentiation was enhanced by a high dose of soluble peptide. Moreover, peptide treatment had distinct effects on expression of the anti-apoptotic protein Bcl-X(L) in TCR-transgenic CD8(+) T cells under lymphopenic versus lymphoreplete conditions. These results demonstrate that CD8(+) T cells undergoing lymphopenia-driven expansion in NOD. scid recipients are resistant to antigen-induced tolerance, and readily differentiate into CTL upon stimulation with a high dose of soluble peptide.     

Caspase 3 is not essential for the induction of anergy or multiple pathways of CD8+ T-cell death

T-cell death is a fundamental process that is intricately regulated at multiple phases during T-cell differentiation, tolerance induction and the decline of the immune response. Caspase 3 is a crucial molecule regulating both mitochondrial and death receptor apoptotic pathways and therefore we were interested in examining the role of caspase 3 in T cells. Using P14 and H-Y CD8(+) TCR-transgenic models, our analysis has shown that caspase 3 is not required for thymic negative selection. In addition, caspase 3 does not play a prominent role in the contraction phase following acute viral infection, nor clonal deletion of CD8(+) T cells under tolerizing conditions. Surprisingly, our studies demonstrate that caspase 3 was not required for the induction of CD8(+) T-cell anergy in vivo, contrary to published reports using CD4(+) T cells. Therefore, these results demonstrate that caspase 3 is not essential in CD8(+) T cells for multiple forms of thymic or peripheral tolerance, nor the contraction phase after an acute anti-viral response.     

TNF receptor 1 (TNFR1) and CD95 are not required for T cell deletion after virus infection but contribute to peptide-induced deletion under limited conditions

Deletion of mature T cells maintains cellular homeostasis and is involved in the maintenance of self tolerance to some peripheral self antigens. Previous studies have presented conflicting evidence for a role of the tumor necrosis factor receptor (TNFR) family member CD95 (Fas) in peripheral T cell deletion using CD95-deficient mice. To evaluate cooperation between CD95 and another TNFR family molecule, TNFR1, we generated mice deficient for both CD95 and TNFR1. We showed that TNFR1 and CD95 do not contribute to the decline of antigen-specific cytotoxic T lymphocytes after virus infection. Using TNFR1 / CD95-deficient mice expressing the P14 TCR specific for a lymphocytic choriomeningitis virus-derived peptide (p33) we showed that deletion of p33-specific CD8(+) T cells following high dose p33 administration is also normal. However, in non-TCR-transgenic TNFR1 / CD95-deficient mice treated with the same p33 regimen, tolerance induction was defective. These data indicate that TNFR1 and CD95 are dispensable for deletion of antigen-specific T cells after viral infection. However, under certain conditions, both TNFR1 and CD95 appear to cooperate in CD8(+) T cell deletion.     

Selection of Foxp3+ regulatory T cells specific for self antigen expressed and presented by Aire+ medullary thymic epithelial cells

The parameters specifying whether autoreactive CD4(+) thymocytes are deleted (recessive tolerance) or differentiate into regulatory T cells (dominant tolerance) remain unresolved. Dendritic cells directly delete thymocytes, partly through cross-presentation of peripheral antigens 'promiscuously' expressed in medullary thymic epithelial cells (mTECs) positive for the autoimmune regulator Aire. It is unclear if and how mTECs themselves act as antigen-presenting cells during tolerance induction. Here we found that an absence of major histocompatibility class II molecules on mTECs resulted in fewer polyclonal regulatory T cells. Furthermore, targeting of a model antigen to Aire(+) mTECs led to the generation of specific regulatory T cells independently of antigen transfer to dendritic cells. Thus, 'routing' of mTEC-derived self antigens may determine whether specific thymocytes are deleted or enter the regulatory T cell lineage.     

Ex vivo induction of viral antigen-specific CD8 T cell responses using mRNA-electroporated CD40-activated B cells

Cell-based immunotherapy, in which antigen-loaded antigen-presenting cells (APC) are used to elicit T cell responses, has become part of the search for alternative cancer and infectious disease treatments. Here, we report on the feasibility of using mRNA-electroporated CD40-activated B cells (CD40-B cells) as alternative APC for the ex vivo induction of antigen-specific CD8(+) T cell responses. The potential of CD40-B cells as APC is reflected in their phenotypic analysis, showing a polyclonal, strongly activated B cell population with high expression of MHC and co-stimulatory molecules. Flow cytometric analysis of EGFP expression 24 h after EGFP mRNA-electroporation showed that CD40-B cells can be RNA transfected with high gene transfer efficiency. No difference in transfection efficiency or postelectroporation viability was observed between CD40-B cells and monocyte-derived dendritic cells (DC). Our first series of experiments show clearly that peptide-pulsed CD40-B cells are able to (re)activate both CD8+ and CD4(+) T cells against influenza and cytomegalovirus (CMV) antigens. To demonstrate the ability of viral antigen mRNA-electroporated CD40-B cells to induce virus-specific CD8+ T cell responses, these antigen-loaded cells were co-cultured in vitro with autologous peripheral blood mononuclear cells (PBMC) for 7 days followed by analysis of T cell antigen-specificity. These experiments show that CD40-B cells electroporated with influenza M1 mRNA or with CMV pp65 mRNA are able to activate antigen-specific interferon (IFN)-gamma-producing CD8(+) T cells. These findings demonstrate that mRNA-electroporated CD40-B cells can be used as alternative APC for the induction of antigen-specific (memory) CD8(+) T cell responses, which might overcome some of the drawbacks inherent to DC immunotherapy protocols.     

Expression of intestine-specific antigen reveals novel pathways of CD8 T cell tolerance induction

Reactivity to intestinal epithelium-specific antigen was studied by transgenic expression of cytosolic ovalbumin controlled by an enterocyte-specific promoter. Transferred OVA-specific CD8 cells (OT-I) preferentially expanded in mucosal lymphoid tissues and the epithelium but failed to cause tissue damage. In contrast, concomitant VSV-ova infection induced OT-I-mediated epithelial cell destruction that correlated with antigen density. OT-I cells retained in the epithelium exhibited high levels of lytic activity but were unable to produce cytokines. The mice were systemically tolerant to OVA since endogenous CD8 cells were nonresponsive to VSV-ova infection. Thus, intestinal antigen gained access to peripheral tissues via absorption from effete epithelial cells. This system demonstrated a requirement for inflammation to drive pathogenic autoreactivity against enterocytes and identified pathways of intestine-specific immunoregulation.     

Antigen‐specific Treg impair CD8+ T‐cell priming by blocking early T‐cell expansion

Foxp3⁺ Treg are crucial for the maintenance of self‐tolerance and have been shown to control CD8⁺ T‐cell effector functions. In addition, Treg are thought to control the priming of CD8⁺ T cells, which recognize the same antigens as Treg. Taking advantage of our model of peripheral tolerance induction to influenza hemagglutinin (HA) after HA gene transfer, we found that HA‐specific Treg suppress antigen‐linked CTL responses through early blockade of CD8⁺ T‐cell expansion. Confronted with their cognate antigen, Treg expand more rapidly than CD8⁺ T cells and are highly suppressive only during the initial stages of immune priming. They nullify HA‐specific CD8⁺ T‐cell responses, local inflammatory responses and rejection of HA transduced cells. When HA gene transfer is performed with extensive tissue inflammation, HA‐specific Treg are less effective but still reduce the frequency of newly primed HA‐specific CD8⁺ T cells and the ensuing frequency of memory CD8⁺ T cells. Our results demonstrate that Treg control CTL priming in an antigen‐specific manner at the level of T‐cell expansion, highlighting how self‐reactive Treg could prevent the induction of autoimmune responses through selective blockade of autoreactive T‐cell proliferation.     

CD 30 prevents T-cell responses to non-lymphoid tissues

Summary: Self antigens can induce T-cell tolerance via a mechanism termed cross-tolerance. This involves the transfer of peripheral tissue antigens to professional APC for presentation in the draining lymph nodes. In this site, CD8⁺ T cells are activated, proliferate, and are slowly deleted by a CD95-dependent mechanism. Prior to their deletion, some activated cells leave the lymph nodes and encounter antigens on peripheral parenchymal tissues. Without functional CD30, these cells proliferate extensively and cause substantial tissue damage. Thus, CD30 limits autoreactivity, acting as a 'brake' on T-cell proliferation after recognition of autoantigens on parenchymal tissues.     

PTPN2 restrains CD8+ T cell responses after antigen cross-presentation for the maintenance of peripheral tolerance in mice

Antigen cross-presentation by dendritic cells is crucial for priming cytotoxic CD8⁺ T cells to invading pathogens and tumour antigens, as well as mediating peripheral tolerance to self-antigens. The protein tyrosine phosphatase N2 (PTPN2) attenuates T cell receptor (TCR) signalling and tunes CD8⁺ T cell responses in vivo. In this study we have examined the role of PTPN2 in the maintenance of peripheral tolerance after the cross-presentation of pancreatic β-cell antigens. The transfer of OVA-specific OT-I CD8⁺ T cells (C57BL/6) into RIP-mOVA recipients expressing OVA in pancreatic β-cells only results in islet destruction when OVA-specific CD4⁺ T cells are co-transferred. Herein we report that PTPN2-deficient OT-I CD8⁺ T cells transferred into RIP-mOVA recipients acquire CTL activity and result in β cell destruction and the development of diabetes in the absence of CD4⁺ help. These studies identify PTPN2 as a critical mediator of peripheral T cell tolerance limiting CD8⁺ T cell responses after the cross-presentation of self-antigens. Our findings reveal a mechanism by which PTPN2 SNPs might convert a tolerogenic CD8⁺ T cell response into one capable of causing the destruction of pancreatic β-cells. Moreover, our results provide insight into potential approaches for enhancing T cell-mediated immunity and/or T cell adoptive tumour immunotherapy.     

B7-H1 determines accumulation and deletion of intrahepatic CD8(+) T lymphocytes

Upon systemic activation by antigens, CD8(+), but not CD4(+), T cells selectively accumulate and undergo apoptosis in the liver, a mechanism associated with the induction of hepatic tolerance and chronic infection. The molecular basis for CD8(+) T cell preference in this process is unknown. We prepared B7-H1-deficient mice by gene targeting and found spontaneous accumulation of CD8(+) T cells in the liver while CD4(+) T cell levels remained normal. Moreover, antigen-driven CD8(+) T cells proliferated normally while apoptotic levels during the contraction phase was selectively impaired in the liver, leading to accelerated hepatocyte damage in experimental autoimmune hepatitis. Therefore, B7-H1 is a key protein selectively regulating the accumulation and deletion of intrahepatic CD8(+) T cells and may also contribute to inflammation, autoimmune diseases, and tolerance in the liver.     

Serrate1-induced notch signalling regulates the decision between immunity and tolerance made by peripheral CD4(+) T cells

Signals derived from antigen-presenting cells (APC) influence the functional differentiation of CD4(+) T cells. We report here that Serrate1 (Jagged1), a ligand for the Notch1 receptor, may contribute to the differentiation of peripheral CD4(+) T cells into either helper or regulatory cells. Our findings demonstrate that antigen presented by murine APC overexpressing human Serrate1 induces naive peripheral CD4(+) T cells to become regulatory cells. These cells can inhibit primary and secondary immune responses, and transfer antigen-specific tolerance to recipient mice. Our results show that Notch signalling may help explain 'linked' suppression in peripheral tolerance, whereby tolerance induced to one epitope encompasses all epitopes on that antigen during the course of an immune response.     

Peripheral T cell tolerance occurs early during spontaneous prostate cancer development and can be rescued by dendritic cell immunization

In the tumor-prone transgenic adenocarcinoma mouse prostate (TRAMP) mouse model we followed the fate of the immune response against the SV40 large T antigen (Tag) selectively expressed in the prostate epithelium during the endogenous transformation from normal cells to tumors. Young (5-7-week-old) male TRAMP mice, despite a dim and patchy expression of Tag overlapping foci of mouse prostate intraepithelial neoplasia, displayed a strong Tag-specific cytotoxic T lymphocyte (CTL) response after an intradermal injection of peptide-pulsed dendritic cells (DC). This response was weaker than the one found in vaccinated wild-type littermates, and was characterized by a reduced frequency and avidity of Tag-specific CTL. Early DC vaccination also subverted the profound state of peripheral tolerance typically found in TRAMP mice older than 9-10 weeks. The DC-induced CTL response indeed was still detectable in TRAMP mice of 16 weeks, and was associated with histology evidence of reduced disease progression. Our findings suggest that tumor antigens are handled as self antigens, and peripheral tolerance is associated with in situ antigen overexpression and cancer progression. Our data also support a relevant role for DC-based vaccines in controlling the induction of peripheral tolerance to tumor antigens.     

T-cell tolerance and autoimmunity to systemic and tissue-restricted self-antigens

Summary: We have used transgenic mouse models to examine the mechanisms of tolerance in CD4⁺ T lymphocytes to soluble, systemic and cell‐associated, tissue‐restricted self‐antigens. Anergy to an islet antigen, as a model of a tissue antigen, is dependent on the inhibitory receptor cytotoxic T‐lymphocyte antigen‐4 (CTLA‐4), and tissue‐restricted autoimmunity is inhibited by regulatory T lymphocytes. Anergy to a circulating systemic antigen can occur independently of CTLA‐4 signals, and it is induced primarily by a block in proximal receptor‐initiated signals. CD4⁺CD25⁺ regulatory T cells are generated in response to both forms of self‐antigens, but the induction is much more efficient with the tissue antigen. Receptor desensitization can be induced by the systemic antigen even in the absence of regulatory T cells, but tolerance can be broken by immunization much more easily if these cells are absent. Deletion of mature T cells is striking with the systemic antigen; there is little evidence to support peripheral deletion as a mechanism of tolerance to the tissue antigen. Thus, both distinct and overlapping mechanisms account for unresponsiveness to different forms of self‐antigens. These results establish a foundation for searching for genetic influences and pathogenic mechanisms in organ‐specific and systemic autoimmune diseases.