Andrew J. Caton

Thymic selection of CD4+CD25+ regulatory T cells induced by an agonist self-peptide.

Despite accumulating evidence that regulatory T cells play a crucial role in preventing autoimmunity, the processes underlying their generation during immune repertoire formation are unknown. We show here that interactions with a single self-peptide can induce thymocytes that bear an autoreactive T cell receptor (TCR) to undergo selection to become CD4+CD25+ regulatory T cells. Selection of CD4+CD25+ thymocytes appears to require a TCR with high affinity for a self peptide because thymocytes that bear TCRs with low affinity do not undergo selection into this pathway. Our findings indicate that specificity for self-peptides directs the selection of CD4+CD25+ regulatory thymocytes by a process that is distinct from positive selection and deletion.

A role for non-MHC genetic polymorphism in susceptibility to spontaneous autoimmunity

Peripheral immunological tolerance is traditionally explained by mechanisms for deletion or inactivation of autoreactive T cell clones. Using an autoimmune disease model combining transgenic mice expressing a well-defined antigen, influenza hemagglutinin (HA), on islet beta cells (Ins-HA), and a T cell receptor transgene (TCR-HNT) specific for a class II-restricted HA peptide, we demonstrate that the conventional assumptions do not apply to this in vivo situation. Double transgenic mice displayed either resistance or susceptibility to spontaneous autoimmune disease, depending on genetic contributions from either of two common inbred mouse strains, BALB/c or B10.D2. Functional studies on autoreactive CD4+ T cells from resistant mice showed that, contrary to expectations, neither clonal anergy, clonal deletion, nor receptor desensitization was induced; rather, there was a non-MHC-encoded predisposition toward differentiation to a nonpathogenic effector (Th2 versus Th1) phenotype. T cells from resistant double transgenic mice showed evidence for prior activation by antigen, suggesting that disease may be actively suppressed by autoreactive Th2 cells. These findings shed light on functional aspects of genetically determined susceptibility to autoimmunity, and should lead to new therapeutic approaches aimed at controlling the differentiation of autoreactive CD4+ effector T cells in vivo.

The Impact of T Helper and T Regulatory Cells on the Regulation of Anti-Double-Stranded DNA B Cells

Autoreactive B cells that appear to be inactivated can be found in healthy individuals. In this study, we examined the potential of these anergic cells to become activated. We show that anergy of anti-double-stranded DNA (dsDNA) B cells in BALB/c mice is readily reversed, requiring only the provision of T cell help. We further show that spontaneous loss of anergy among anti-dsDNA B cells in autoimmune lpr/lpr mice occurs in two phases: an abortive initial response to T help followed by full loss of tolerance. Strikingly, the abortive response can be reproduced in nonautoimmune mice when CD4+CD25+ T regulatory cells are administered in conjunction with CD4+ T helper cells, suggesting that loss of B cell tolerance may require both the production of T cell help and the overcoming of T suppression.

Cutting Edge: The Natural Ligand for Glucocorticoid-Induced TNF Receptor-Related Protein Abrogates Regulatory T Cell Suppression

CD4+25+ regulatory T (Treg) cells maintain immunological self-tolerance through mechanisms that are only in part understood. Previous studies suggest that the glucocorticoid-induced TNFR-related protein (GITR), which is preferentially expressed on the surface of Treg cells, potentially provides a signal that abrogates Treg suppression. In this study, we show that a soluble form of mouse GITR ligand (sGITR-L) induces GITR-dependent NF-κB activation and blocks in vitro suppression mediated by both resting and preactivated polyclonal and Ag-specific Treg cells. Since sGITR-L along with rIL-2 induces proliferation of CD4+25+ cells, it appears that sGITR-L can break the anergic state of Treg cells. Because sGITR-L also up-regulates IL-2 secretion by activated CD4+25 −T cells, these two sGITR-L induced signals synergize to interfere with suppressor activity by CD4+25+ Treg cells.

Cutting Edge: Self-Peptides Drive the Peripheral Expansion of CD4+CD25+ Regulatory T Cells

CD4+CD25+ regulatory T cell selection is initiated by high-specificity interactions with self-peptides in the thymus, although how these cells respond to cytokine-derived signals and to re-exposure to self-peptide:MHC complexes in the periphery is not well understood. We have used a transgenic mouse system, in which the peptide that induces thymic selection of a clonal population of CD4+CD25+ regulatory T cells is known, to show that CD4+CD25+ T cells proliferate in response to their selecting self-peptide in vivo. Moreover, they do not proliferate in response to lymphopenia in the absence of the selecting self-peptide, reflecting a low level of expression of the high affinity receptor for IL-7 (CD127) relative to conventional CD4+ T cells. That their selecting self-peptide is both required for and promotes the peripheral expansion of CD4+CD25+ regulatory T cells may direct their accumulation in sites where the self-peptide is expressed.

Positive and Negative Regulation of the IL-27 Receptor during Lymphoid Cell Activation

Previous reports have focused on the ability of IL-27 to promote naive T cell responses but the present study reveals that surface expression of WSX-1, the ligand-specific component of the IL-27R, is low on these cells and that highest levels are found on effector and memory CD4+ and CD8+ T cells. Accordingly, during infection with Toxoplasma gondii, in vivo T cell activation is associated with enhanced expression of WSX-1, and, in vitro, TCR ligation can induce expression of WSX-1 regardless of the polarizing (Th1/Th2) environment present at the time of priming. However, while these data establish that mitogenic stimulation promotes expression of WSX-1 by T cells, activation of NK cells and NKT cells prompts a reduction in WSX-1 levels during acute toxoplasmosis. Together, with the finding that IL-2 can suppress expression of WSX-1 by activated CD4+ T cells, these studies indicate that surface levels of the IL-27R can be regulated by positive and negative signals associated with lymphoid cell activation. Additionally, since high levels of WSX-1 are evident on resting NK cells, resting NKT cells, effector T cells, regulatory T cells, and memory T cells, the current work demonstrates that IL-27 can influence multiple effector cells of innate and adaptive immunity.

Anergy and suppression regulate CD4 + T cell responses to a self peptide

To examine the role of cognate peptide in establishing CD4+ T cell tolerance, we have mated transgenic mice that express the major I‐Ed‐restricted determinant (S1) from the influenza virus PR8 hemagglutinin (HA28 mice) with mice expressing a S1‐specific T cell receptor (TS1 mice). Surprisingly, S1‐specific CD4+ T cells were not substantially deleted in TS1xHA28 mice; indeed, lymph node cells expressing the S1‐specific TCR were as abundant in TS1xHA28 mice as in TS1 mice. The S1‐specific T cells in TS1xHA28 mice were, however, impaired in their ability to respond to S1 peptide both in vitro and in vivo, and contained two distinct populations. Approximately half expressed a unique cell surface phenotype (CD25hi / CD45RBint) and had been anergized by the neo‐self S1 peptide. The remainder responded normally to the S1 peptide if purified away from the anergic T cells, but their proliferation was suppressed when the anergic T cells were also present in unfractionated lymphnode cells or in mixed cultures. These findings establish that anergy and suppression are coordinated mechanisms by which autoreactive CD4+ T cells are regulated and that anergic / suppressor CD4+ T cells can develop in response to self peptides.

Promotion of Allograft Survival by CD4+CD25+ Regulatory T Cells: Evidence for In Vivo Inhibition of Effector Cell Proliferation

Regulatory T cells preserve tolerance to peripheral self-Ags and may control the response to allogeneic tissues to promote transplantation tolerance. Although prior studies have demonstrated prolonged allograft survival in the presence of regulatory T cells (T-reg), data documenting the capacity of these cells to promote tolerance in immunocompetent transplant models are lacking, and the mechanism of suppression in vivo remains unclear. We used a TCR transgenic model of allograft rejection to characterize the in vivo activity of CD4+CD25+ T-reg. We demonstrate that graft Ag-specific T-reg effectively intercede in the rejection response of naive T cells to established skin allografts. Furthermore, CFSE labeling demonstrates impaired proliferation of naive graft Ag-specific T cells in the draining lymph node in the presence of T-reg. These results confirm the efficacy of T-reg in promoting graft survival and suggest that their suppressive action is accomplished in part through inhibition of proliferation.

Inducible MHC class II expression by mast cells supports effector and regulatory T cell activation

In addition to their well-established role as regulators of allergic response, recent evidence supports a role for mast cells in influencing the outcome of physiologic and pathologic T cell responses. One mechanism by which mast cells (MCs) influence T cell function is indirectly through secretion of various cytokines. It remains unclear, however, whether MCs can directly activate T cells through Ag presentation, as the expression of MHC class II by MCs has been controversial. In this report, we demonstrate that in vitro stimulation of mouse MCs with LPS and IFN-γ induces the expression of MHC class II and costimulatory molecules. Although freshly isolated peritoneal MCs do not express MHC class II, an in vivo inflammatory stimulus increases the number of MHC class II-positive MCs in situ. Expression of MHC class II granted MCs the ability to process and present Ags directly to T cells with preferential expansion of Ag-specific regulatory T cells over naive T cells. These data support the notion that, in the appropriate setting, MCs may regulate T cell responses through the direct presentation of Ag.

Role of TCR specificity in CD4+CD25+ regulatory T‐cell selection

Summary:  CD4+CD25+ regulatory T cells play a crucial role in preventing autoimmune disease and can also modulate immune responses in settings such as transplantation and infection. We have developed a transgenic mouse system in which the role that T‐cell receptor (TCR) specificity for self‐peptides plays in the formation of CD4+CD25+ regulatory T cells can be examined. We have shown that interactions with a single self‐peptide can induce thymocytes bearing an autoreactive TCR to undergo selection to become CD4+CD25+ regulatory T cells and that thymocytes bearing TCRs with low affinity for the selecting peptide do not appear to undergo selection into this pathway. In addition, thymocytes with identical specificity for the selecting self‐peptide can undergo overt deletion versus abundant selection to become CD4+CD25+ regulatory T cells in response to variations in expression of the selecting peptide in different lineages of transgenic mice. Finally, we have shown that CD4+CD25+ T cells proliferate in response to their selecting self‐peptide in the periphery, but these cells do not proliferate in response to lymphopenia in the absence of the selecting self‐peptide. These studies are determining how the specificity of the TCR for self‐peptides directs the thymic selection and peripheral expansion of CD4+CD25+ regulatory T cells.