Inhibition of S-phase kinase-associated protein 2 (Skp2) reprograms and converts diabetogenic T cells to Foxp3+ regulatory T cells.

Autoreactive pathogenic T cells (Tpaths) and regulatory T cells (Tregs) express a distinct gene profiles; however, the genes and associated genetic/signaling pathways responsible for the functional determination of Tpaths vs. Tregs remain unknown. Here we show that Skp2, an E3 ubiquitin ligase that affects cell cycle control and death, plays a critical role in the function of diabetogenic Tpaths and Tregs. Down-regulation of Skp2 in diabetogenic Tpaths converts them into Foxp3-expressing Tregs. The suppressive function of the Tpath-converted Tregs is dependent on increased production of TGF-ß/IL-10, and these Tregs are able to inhibit spontaneous diabetes in NOD mice. Like naturally arising Foxp3(+) nTregs, the converted Tregs are anergic cells with decreased proliferation and activation-induced cell death. Skp2 down-regulation leads to Tpath-Treg conversion due at least in part to up-regulation of several genes involved in cell cycle control and genes in the Foxo family. Down-regulation of the cyclin-dependent kinase inhibitor p27 alone significantly attenuates the effect of Skp2 on Tpaths and reduces the suppressive function of converted Tregs; its effect is further improved with concomitant down-regulation of p21, Foxo1, and Foxo3. In comparison, Skp2 overexpression does not change Tpath function, but significantly decreases Foxp3 expression and abrogates the suppressive function of nTregs. These findings support the critical role of Skp2 in functional specification of Tpaths and Tregs, and demonstrate an important molecular mechanism mediating Skp2 function in balancing immune tolerance during autoimmune disease development.

Killer cell Ig-like receptor (KIR) 3DL1 down-regulation enhances inhibition of type 1 diabetes by autoantigen-specific regulatory T cells.

Both Foxp3(+) regulatory T cells (Tregs) and antigen-expanded Foxp3(-) Tregs play an important role in regulating immune responses as well as in preventing autoimmune diseases and graft rejection. Molecular mechanisms modulating Treg function remain largely unclear, however. We report here on the expression and function of an inhibitory killer cell Ig-like receptor, KIR3DL1, in a nonobese diabetic (NOD) mouse-derived autoantigen-specific Treg (2D2), which protects from type 1 diabetes (T1D) in adoptive transfer experiments. This gene is not expressed in T1D pathogenic T cells (Tpaths) or non-Tpath T cells. KIR genes are known to play an important role in regulating natural killer (NK) cell function, but their role in Tregs and T1D is unknown. To examine whether KIR3DL1 expression may modulate Treg function, we used shRNA to down-regulate KIR3DL1 expression (2D2-shKIR). We find that KIR3DL1 down-regulation enhances in vitro function, as measured by improved suppression of target cell proliferation. Antibody blockade of IL-10 but not IL-4 partially abrogated suppressive function. In vivo function is also improved. Adoptive transfer of 2D2-shKIR into 10-wk-old NOD mice prevented spontaneous insulitis and T1D, and the inhibitory effect was further improved if the cells were transferred earlier into 6-wk-old NOD mice. These studies indicate that KIR3DL1 expression may negatively regulate Treg function and suggest a previously undescribed target for improving immune tolerance for potential treatment of autoimmune diseases like T1D.

CD4+ CD25+ regulatory T cells prevent type 1 diabetes preceded by dendritic cell-dominant invasive insulitis by affecting chemotaxis and local invasiveness of dendritic cells.

Development of type 1 diabetes (T1D) is preceded by invasive insulitis. Although CD4(+)CD25(+) regulatory T cells (nTregs) induce tolerance that inhibits insulitis and T1D, the in vivo cellular mechanisms underlying this process remain largely unclear. Using an adoptive transfer model and noninvasive imaging-guided longitudinal analyses, we found nTreg depletion did not affect systemic trafficking and tissue localization of diabetogenic CD4(+) BDC2.5 T (BDC) cells in recipient mice prior to development of T1D. In addition, neither the initial expansion/activation of BDC cells nor the number of CD11c(+) or NK cells in islets and pancreatic lymph nodes were altered. Unexpectedly, our results showed nTreg depletion led to accelerated invasive insulitis dominated by CD11c(+) dendritic cells (ISL-DCs), not BDC cells, which stayed in the islet periphery. Compared with control mice, the phenotype of ISL-DCs and their ability to stimulate BDC cells did not change during invasive insulitis development. However, ISL-DCs from nTreg-deficient recipient mice showed increased in vitro migration toward CCL19 and CCL21. These results demonstrated invasive insulitis dominated by DCs, not CD4(+) T cells, preceded T1D onset in the absence of nTregs, and suggested a novel in vivo function of nTregs in T1D prevention by regulating local invasiveness of DCs into islets, at least partly, through regulation of DC chemotaxis toward CCL19/CCL21 produced by the islets.

Glutamic acid decarboxylase-specific CD4+ regulatory T cells.

It is known that CD4(+) regulatory T cells (Tr cells) play a central role in inducing immune tolerance in animals and humans. Compared to polyclonal Tr cells, autoantigen-specific Tr cells are more potent at blocking pathogenic immune responses. In order to better understand the role of Tr cells in controlling type 1 diabetes development and to help design effective antigen-specific cell-based therapeutic methods to treat the disease, it is necessary to: (a) determine the antigen specificity of Tr cells; (b) study how antigen-specific Tr cells behave in vivo; (c) investigate the interaction of Tr cells with pathogenic T cells (Tpath cells) and determine whether such interaction correlates with the progression or inhibition of diabetes; and (d) determine the cellular and molecular mechanisms underlying the regulation of diabetes by Tr cells. We have addressed these questions with a focus on the studies of glutamic acid decarboxylase (GAD)-specific T cells. Previous studies have suggested that GAD-specific T cells play a key role in type 1 diabetes. Treatment of NOD mice with GAD or its peptides can prevent the progression toward overt disease. The preventive effect could be due to either the deletion of antigen-specific pathogenic T cells or the induction of potent antigen-specific Tr cells. Using antigen-specific I-Ag7 tetramers we have isolated several populations of GAD peptide-specific T cells from diabetes-prone NOD and diabetes-resistant NOR mice. Herein, we summarize our studies on the role of these GAD peptide-specific T cells in type 1 diabetes. We present evidence that supports the hypothesis that the repertoire of T cells specific for these GAD peptides is biased toward Tr cells that inhibit diabetes rather than toward pathogenic T cells that induce diabetes.

Maintenance of CD8+ T cells during acute viral infection of the central nervous system requires CD4+ T cells but not interleukin-2.

The JHM strain of mouse hepatitis virus (JHMV) is rapidly cleared from the central nervous system (CNS) by CD8(+) T cells. In the absence of CD4(+) T cells, fewer CD8(+) T cells are found within the CNS in association with a coordinate increase in apoptotic lymphocytes. Previous data suggested that CD4(+) T cells may support CD8(+) T cells through secretion of interleukin-2 (IL-2). To determine the in vivo role of IL-2 during CNS infection, IL-2 signaling was inhibited via administration of a neutralizing IL-2-specific monoclonal antibody (mAb). In contrast to depletion of CD4(+) T cells, inhibition of IL-2 signaling did not influence CD8(+) T cell infiltration, effector cell function or survival within the CNS. These data suggest that the cellular immune response to acute neurotropic JHMV infection requires a distinct CD4(+) T cell component, but is independent of a requirement for IL-2 for induction, activation, recruitment, and/or maintenance of CD8(+) T cells within the CNS during acute infection.

Mammalian target of rapamycin complex 2 (mTORC2) regulates LPS-induced expression of IL-12 and IL-23 in human dendritic cells.

IL-12 p40, a common subunit for both IL-12 p70 and IL-23, plays a critical role in the development of Th1 and Th17 cells and autoimmune diseases. Regulation of IL-12 p40 expression is thus considered to be a strategy for developing therapies for Th1- and Th17-mediated autoimmune diseases. The mTOR protein is a subunit mTORC1 and mTORC2. Although mTORC1 has been shown to mediate IL-12 p40 expression in DCs and relevant signaling, the role of mTORC2 in IL-12 p40 expression remains largely unclear. In the present study, we demonstrate that blocking mTORC2 activity using the phytochemical cytopiloyne can specifically inhibit LPS-induced expression of IL-12 p70, IL-23, and IL-12 p40 in human DCs. This regulation by mTORC2 involving Akt activation and the persistent phase of NF-κB activation is further confirmed by siRNA knockdown of Rictor and Sin1 gene expression and the use of alternative inhibition approaches. In terms of IL-12 p40 expression, our findings reveal a new role for the mTORC2 pathway that is antagonistic to that of mTORC1. Our study provides new insight into mTOR regulation of IL-12 p40-mediated Th1 (IFN-γ) and Th17 (IL-17) responses and suggests that the phytochemical cytopiloyne might have useful applications in therapies for Th1 and Th17 cell-mediated inflammatory diseases.

Characterization of proteolipid protein-peptide-specific CD(4)(+) T cell of experimental allergic encephalomyelitis in Biozzi AB/H mice.

OBJECTIVE: To detect the function of proteolipid protein (PLP) peptide (residues 56 - 70)-specific CD(4)(+) T cells in experimental allergic encephalomyelitis (EAE) in Biozzi AB/H mice (H-2A(g7)). METHODS: Biozzi AB/H mice were immunized by synthetic PLP(56 - 70) peptide (DYEYLINVIHAFQYV) which was emulsified by sonication with complete Freund's adjuvant, a EAE model proven histologically and clinically. Murine splenocytes and spinal cord infiltrated (SCI) T cells were stimulated by PLP(56 - 70), then the CD(4)(+) T cells were isolated by Dynabeads, and confirmed by staining with anti-CD(4) antibody. Finally, the IL2 bioassay and IFN-gamma/IL4 ELISA were done to detect T cell proliferation and cytokine secretion after PLP(56 - 70) stimulation. RESULTS: The histology of murine spinal cord showed a great number of lymphocytes infiltrated the spinal cord; the clinical signs showed high scores (4.3) on the peak, as well as a good EAE model. After being isolated by Dynabeads, CD(4)(+) T cells showed high purification (> 99%) by staining with anti-CD(4) antibody. IL2 bioassay showed that those T cells were PLP(56 - 70)-specific T cells. ELISA showed that those T cells had high IFN-gamma/IL4 ratio, indicating that they are T helper 1 (Th1) cells. CONCLUSIONS: PLP(56 - 70)-specific splenocytes and SCI CD(4)(+) T cells in EAE from Biozzi AB/H mice were detected and showed that both of them were PLP(56 - 70)-specific Th1 cells. It is beneficial to understand what kind of role these T cells play in the development of EAE.

The cross-reactivity of I-A(g7) and I-A(d) tetramers.

OBJECTIVE: To investigate the cross-reactivity between glutamic acid decarboxylase (GAD)-I-A(g7) and I-A(d) tetramer in diabetes-prone non-obese diabetic (NOD) mice (I-A(g7)) and diabetes-free Balb/c mice (I-A(d)). METHODS: Two GAD peptide I-A(g7) and I-A(d) tetramers were generated and compared for phenotype and function of sorted GAD peptide I-A(g7) and I-A(d) tetramer-positive (tet+) T cells. RESULTS: The cross-reactivity is shown in either tetramer positive percentage or tetramer staining intensity. The NOD and Balb/c derived-tet+ T cells were able to be cross-stained by GAD peptide I-A(g7) and I-A(d) tetramers, and responded to both irradiated NOD and Balb/c splenotyes under stimulation by synthetic and recombinant GAD peptides. CONCLUSION: Although I-A(g7) and I-A(d) are closely related in biochemical and biological aspects, their most notable difference is the presence or absence of a negatively charged residue at position beta57 that links to insulin-dependent diabetes mellitus.

Foxp3+ Treg expanded from patients with established diabetes reduce Helios expression while retaining normal function compared to healthy individuals.

Foxp3(+) regulatory T cells (Treg) play a crucial role in regulating immune tolerance. The use of Treg to restore immune tolerance is considered an attractive novel approach to inhibit autoimmune disease, including type 1 diabetes (T1D), and to prevent rejection of organ transplants. In view of the goal of developing autologous Treg-based cell therapy for patients with long-term (>15 years) T1D, it will be necessary to expand a sufficient amount of functional Treg in vitro in order to study and compare Treg from T1D patients and healthy subjects. Our results have demonstrated that there is a comparable frequency of Treg in the peripheral blood lymphocytes (PBLs) of patients with long-term T1D relative to those in healthy subjects; however, Th1 cells, but not Th17 cells, were increased in the T1D patients. Further, more Treg in PBLs from T1D patients than from healthy subjects expressed the CD45RO(+) memory cell phenotype, suggesting they were antigen-experienced cells. After isolation, Treg from both T1D patients and healthy subjects were successfully expanded with high purity. Although there was no difference in Helios expression on Treg in PBLs, in vitro expansion led to fewer Helios-expressing Treg from T1D patients than healthy subjects. While more Th1-like Treg expressing IFN-γ or TNF-α were found in the PBLs of T1D patients than healthy controls, there was no such difference in the expanded Treg. Importantly, expanded Treg from both subject groups were able to suppress autologous or allogeneic CD8(+) effector T cells equally well. Our findings demonstrate that a large number of ex vivo expanded functional Treg can be obtained from long-term T1D patients, although fewer expanded Treg expressed a high level of Helios. Thus, based on the positive outcomes, these potent expanded Treg from diabetic human patients may be useful in treating T1D or preventing islet graft rejection.

Mesenchymal stem cells facilitate mixed hematopoietic chimerism induction and prevent onset of diabetes in nonobese diabetic mice.

OBJECTIVES: Allogeneic mesenchymal stem cells (MSCs) and bone marrow cells (BMCs) were cotransplanted in nonobese diabetic mice after none myeloablative preconditioning and the development of chimerism, insulitis, diabetes, and graft-versus-host disease (GVHD) were monitored. METHODS: Eight-week-old female nonobese diabetic mice were injected intravenously with 2 × 10 BMCs and 5 × 10 MSCs from C57BL/6 mice after treatment with 2 intraperitoneal injections of anti-CD3 antibody (days -7 and -4) and 3-Gy total body irradiation (day -1). Thereafter, blood glucose and chimerism were monitored on peripheral blood samples. RESULTS: Stable mixed chimerism (3->90% of donor phenotype) was induced in 63.2% of BMCs-MSCs recipients (n = 19) and 45.0% of BMCs-alone recipients (n = 20, P = 0.256). Insulitis was prevented, and euglycemia persisted for more than 18 weeks in 89.5% of BMCs-MSCs recipients including those with less than 3% chimerism and 55% of BM-alone recipients (P < 0.05). In controls, 9.1% of mice receiving preconditioning treatment alone (n = 11) and 16.7% of preconditioned mice receiving only MSCs (n = 12) were nondiabetic. Graft-versus-host disease was not detected in all mice. CONCLUSIONS: Coinjection of MSCs and BMCs increased the success rate in inducing chimerism and preventing insulitis and overt diabetes with no incidence of GVHD. Results also indicated that even microchimerism with less than 3% donor cells is sufficient for blocking autoimmunity.

Comparative analyses of differentially induced T-cell receptor-mediated phosphorylation pathways in T lymphoma cells.

Activation of T lymphoma cells expressing Syk, but not ZAP-70 tyrosine kinase, has been shown to negatively regulate cell activation and activation-induced cell death (AICD), perhaps due to differential induction of tyrosine phosphorylation modified proteins. To better understand the role of these proteins and their associated molecules/pathways, we studied a previously described model of T lymphoma cells expressing either a kinase-activated chimeric Syk or ZAP-70 genetically linked to T-cell receptor (TCR) ζ chain (Z/Syk or Z/ZAP cells, respectively). To help identify molecules and pathways linked to cell activation or AICD, a comparative semi-quantitative proteomics-based approach was utilized to analyze tyrosine-phosphorylated protein immunoprecipitates from two-minute short-term activated Z/Syk or Z/ZAP cells. Using the resulting bioinformatics data-sets, we identified several differentially immunoprecipitated proteins that could be validated biochemically. More tyrosine-phosphorylated and phosphotyrosine-associated proteins were found in Z/Syk than in Z/ZAP cells. Proteins involved in different unique functional pathways were induced in these cells and showed altered intermolecular interactions in varied pathways. Remarkably, 41% of differentially identified proteins in Z/Syk cells belonged to cell cycle or vesicle/trafficking pathways. In contrast, 21% of such proteins in Z/ZAP cells belonged to metabolism pathways. Therefore, molecular pathways involved in post-translational modifications linked to distinct cellular/physiological functions are differentially activated, which may contribute to varied activation and AICD responses of these cells. In summary, we identified proteins belonging to novel differentially activated pathways involved in TCR-mediated signaling, which may be targets for regulating activation and AICD of T lymphoma cells and for potential cancer therapy.

Regulatory function of a novel population of mouse autoantigen-specific Foxp3 regulatory T cells depends on IFN-gamma, NO, and contact with target cells.

BACKGROUND: Both naturally arising Foxp3(+) and antigen-induced Foxp3(-) regulatory T cells (Treg) play a critical role in regulating immune responses, as well as in preventing autoimmune diseases and graft rejection. It is known that antigen-specific Treg are more potent than polyclonal Treg in suppressing pathogenic immune responses that cause autoimmunity and inflammation. However, difficulty in identifying and isolating a sufficient number of antigen-specific Treg has limited their use in research to elucidate the mechanisms underlying their regulatory function and their potential role in therapy. METHODOLOGY/PRINCIPAL FINDINGS: Using a novel class II MHC tetramer, we have isolated a population of CD4(+) Foxp3(-) T cells specific for the autoantigen glutamic acid decarboxylase p286-300 peptide (NR286 T cells) from diabetes-resistant non-obese resistant (NOR) mice. These Foxp3(-) NR286 T cells functioned as Treg that were able to suppress target T cell proliferation in vitro and inhibit type 1 diabetes in animals. Unexpected results from mechanistic studies in vitro showed that their regulatory function was dependent on not only IFN-gamma and nitric oxide, but also on cell contact with target cells. In addition, separating NR286 Treg from target T cells in transwell assays abolished both production of NO and suppression of target T cells, regardless of whether IFN-gamma was produced in cell cultures. Therefore, production of NO, not IFN-gamma, was cell contact dependent, suggesting that NO may function downstream of IFN-gamma in mediating regulatory function of NR286 Treg. CONCLUSIONS/SIGNIFICANCE: These studies identified a unique population of autoantigen-specific Foxp3(-) Treg that can exert their regulatory function dependent on not only IFN-gamma and NO but also cell contact with target cells.

All-trans retinoic acid inhibits type 1 diabetes by T regulatory (Treg)-dependent suppression of interferon-gamma-producing T-cells without affecting Th17 cells.

OBJECTIVE: All-trans retinoic acid (ATRA), a potent derivative of vitamin A, can regulate immune responses. However, its role in inducing immune tolerance associated with the prevention of islet inflammation and inhibition of type 1 diabetes remains unclear. RESEARCH DESIGN AND METHODS: We investigated the mechanisms underlying the potential immunoregulatory effect of ATRA on type 1 diabetes using an adoptive transfer animal model of the disease. RESULTS: Our data demonstrated that ATRA treatment inhibited diabetes in NOD mice with established insulitis. In addition, it suppressed interferon (IFN)-gamma-producing CD4(+) and CD8(+) T effector (Teff) cells and expanded T regulatory (Treg) cells in recipient mice transferred with diabetic NOD splenocytes, without affecting either interleukin (IL)-17--or IL-4-producing cells. Consistent with these results, ATRA reduced T-bet and STAT4 expression in T-cells and decreased islet-infiltrating CD8(+) T-cells, suppressing their activation and IFN-gamma/granzyme B expression. Depletion of CD4(+)CD25(+) Treg cells impaired the inhibitory effect of ATRA on islet-infiltrating T-cells and blocked its protective effect on diabetes. Therefore, ATRA treatment induced Treg cell-dependent immune tolerance by suppressing both CD4(+) and CD8(+) Teff cells while promoting Treg cell expansion. CONCLUSIONS: These results demonstrate that ATRA treatment promoted in vivo expansion of Treg cells and induced Treg cell-dependent immune tolerance by suppressing IFN-gamma-producing T-cells, without affecting Th17 cells. Our study also provides novel insights into how ATRA induces immune tolerance in vivo via its effects on Teff and Treg cells.

Mesenchymal stem cells suppress B-cell terminal differentiation.

OBJECTIVE: Mesenchymal stem cells (MSCs) have been shown to possess immunomodulatory properties on a diverse array of immune cell lineages. However, their effect on B lymphocytes remains unclear. We investigated the effect of MSCs on B-cell modulation with a special emphasis on gene regulation mediated by MSC humoral factors. MATERIALS AND METHODS: MSCs were isolated from C57BL/6 bone marrow and expanded in culture. Splenic B cells were purified using anti-CD43 antibody and immunomagnetic beads. B cells and MSCs were cocultured in separate compartments in a transwell system. For B-cell stimulation, lipopolysaccharide was used in vitro and T-dependent and T-independent antigens were used in vivo. RESULTS: In MSC cocultures, lipopolysaccharide-stimulated B-cell proliferation was suppressed, CD138(+) cell percentage decreased, and the number of apoptotic CD138(+) cells decreased. In the B/MSC coculture, the IgM(+) cell percentage was higher and the IgM amount released in the medium was lower than in the control. The B-lymphocyte-induced maturation protein-1 messenger RNA expression in the coculture was suppressed throughout the 3-day culture period. Conditioned media derived from MSC cultures prevented terminal differentiation of B cells in vitro and significantly suppressed the antigen-specific immunoglobulin M and immunoglobulin G1 secretion in mice immunized with T-cell-independent as well as T-cell-dependent antigens in vivo. CONCLUSION: Results indicate that humoral factor(s) released by MSCs exert a suppressive effect on the B-cell terminal differentiation. Suppression may be mediated through inhibition of B-lymphocyte-induced maturation protein-1 expression, but the nature of the factor(s) is yet to be determined.

Key role of the GITR/GITRLigand pathway in the development of murine autoimmune diabetes: a potential therapeutic target.

BACKGROUND: The cross-talk between pathogenic T lymphocytes and regulatory T cells (Tregs) plays a major role in the progression of autoimmune diseases. Our objective is to identify molecules and/or pathways involved in this interaction and representing potential targets for innovative therapies. Glucocorticoid-induced tumor necrosis factor receptor (GITR) and its ligand are key players in the T effector/Treg interaction. GITR is expressed at low levels on resting T cells and is significantly up-regulated upon activation. Constitutive high expression of GITR is detected only on Tregs. GITR interacts with its ligand mainly expressed on antigen presenting cells and endothelial cells. It has been suggested that GITR triggering activates effector T lymphocytes while inhibiting Tregs thus contributing to the amplification of immune responses. In this study, we examined the role of GITR/GITRLigand interaction in the progression of autoimmune diabetes. METHODS AND FINDINGS: Treatment of 10-day-old non-obese diabetic (NOD) mice, which spontaneously develop diabetes, with an agonistic GITR-specific antibody induced a significant acceleration of disease onset (80% at 12 weeks of age). This activity was not due to a decline in the numbers or functional capacity of CD4(+)CD25(+)Foxp3(+) Tregs but rather to a major activation of 'diabetogenic' T cells. This conclusion was supported by results showing that anti-GITR antibody exacerbates diabetes also in CD28(-/-) NOD mice, which lack Tregs. In addition, treatment of NOD mice, infused with the diabetogenic CD4(+)BDC2.5 T cell clone, with GITR-specific antibody substantially increased their migration, proliferation and activation within the pancreatic islets and draining lymph nodes. As a mirror image, blockade of the GITR/GITRLigand pathway using a neutralizing GITRLigand-specific antibody significantly protected from diabetes even at late stages of disease progression. Experiments using the BDC2.5 T cell transfer model suggested that the GITRLigand antibody acted by limiting the homing and proliferation of pathogenic T cells in pancreatic lymph nodes. CONCLUSION: GITR triggering plays an important costimulatory role on diabetogenic T cells contributing to the development of autoimmune responses. Therefore, blockade of the GITR/GITRLigand pathway appears as a novel promising clinically oriented strategy as GITRLigand-specific antibody applied at an advanced stage of disease progression can prevent overt diabetes.

Image-guided analyses reveal that non-CD4 splenocytes contribute to CD4+ T cell-mediated inflammation leading to islet destruction by altering their local function and not systemic trafficking patterns.

Recruitment of CD4(+) T cells into islets is a critical component of islet inflammation (insulitis) leading to type 1 diabetes; therefore, determining if conditions used to treat diabetes change their trafficking patterns is relevant to the outcome. Cotransfer of CD4(+)BDC2.5 (BDC) cells with non-CD4 splenocytes obtained from newly diabetic NOD mice, but not when they are transferred alone, induces accelerated diabetes. It is unclear whether these splenocytes affect diabetes development by altering the systemic and/or local trafficking and proliferation patterns of BDC cells in target and nontarget tissues. To address these questions, we developed an animal model to visualize BDC cell trafficking and proliferation using whole-body in vivo bioluminescence imaging and used the images to direct tissue sampling for further analyses of the cell distribution within tissues. The whole-body, or macroscopic, trafficking patterns were not dramatically altered in both groups of recipient mice. However, the local patterns of cell distribution were distinct, which led to invasive insulitis only in cotransferred mice with an increased number of islet-infiltrating CD11b(+) and CD11c(+) cells. Taken together, the non-CD4 splenocytes act locally by promoting invasive insulitis without altering the systemic trafficking patterns or proliferation of BDC cells and thus contributing to diabetes by altering the localization within the tissue.

Regulatory T cells can mediate their function through the stimulation of APCs to produce immunosuppressive nitric oxide.

Regulatory T cells (Tr cells) play a critical role in inducing immune tolerance. It remains largely unclear how various types of Tr cells perform their regulatory function. We have studied the underlying regulatory mechanism of a population of autoantigen-specific CD4+ Tr cells. These T cells are specific for the glutamic acid decarboxylase p206-220 peptide and are isolated from the diabetes-resistant nonobese-resistant mice. Although these T cells express T-bet and display a Th1 phenotype, they are able to inhibit diabetes. Their regulatory function is dependent on both IFN-gamma and cell contact with target cells. These Tr cells can mediate their cell contact-dependent regulatory function by secreting IFN-gamma which stimulates APCs to produce NO. NO is necessary for the Tr cells to inhibit the proliferation of pathogenic T cells and the development of diabetes. Therefore, we have identified a novel mechanism by which these Tr cells can exert their regulatory function. These results also provide an explanation as to why IFN-gamma may play both pathogenic and immunomodulatory roles in autoimmune diseases.

Polarized development of memory cell-like IFN-gamma-producing cells in the absence of TCR zeta-chain.

TCR/CD3 complex-mediated signals play critical roles in regulating CD4(+) Th cell differentiation. In this report, we have examined the in vivo role of a key TCR/CD3 complex molecule zeta-chain in regulating the differentiation of Th cells. We have studied T cells from zeta-chain-deficient mice (zetaKO mice), zeta-chain-bearing mice (zeta(+) mice), and from zetaKO mice expressing a FcRgamma chain transgene (FcRgammaTG, zetaKO mice). Our results demonstrated that, compared with those of control mice, CD4(+) T cells and not CD8(+) T cells from zetaKO mice were polarized into IFN-gamma-producing cells. Some of these IFN-gamma-producing cells could also secrete IL-10. Interestingly, zetaKO mouse T cells produced IFN-gamma even after they were cultured in a Th2 condition. Our studies to determine the molecular mechanisms underlying the polarized IFN-gamma production revealed that the expression level of STAT4 and T-bet were up-regulated in freshly isolated T cells from zetaKO mice. Further studies showed that noncultured zetaKO mice CD4(+) T cells and thymocytes bore a unique memory cell-like CD44(high), CD62L(low/neg) phenotype. Altogether, these results suggest that, in the absence of the zeta-chain, CD4(+) T cells develop as polarized IFN-gamma-producing cells that bear a memory cell-like phenotype. The zeta-chain-bearing T cells may produce a large amount of IFN-gamma only after they are cultured in a condition favoring Th1 cell differentiation. This study may provide important implications for the down-regulation of zeta-chain in T cells of patients bearing a variety of tumors, chronic inflammatory and infectious diseases.

Development of T cells expressing an altered TCR complex.

Normal mouse T cells may express alternative TCR complexes containing the FcepsilonR gamma chain (FcRgamma) rather than the zeta homodimer that is present in conventional TCR complexes. While these T cells could play critical roles in regulating immunity, the role of alternative TCR complexes and their requirement for signaling molecules in T cell development remains unknown. We show thatexpression of an FcRgamma transgene in zeta chain-deficient mice (FcRgammaTG, zetaKO mice) reduced the percentage and number of CD4(+) T cells present in these animals, when compared to C57BL/6 mice. Further studies of FcRgammaTG, zetaKO mice expressing the DO11.10 TCR (DOTCR) transgene showed that, when compared to mice expressing conventional TCR complexes, the development of CD4(+), DOTCR(+) thymocytes was altered in mice of different MHC backgrounds and required the presence of zeta-associated protein (ZAP)-70 and lck kinases. The CD4(+), DOTCR(+) T cells bearing alternative TCR complexes have impaired Ca(2+) flux and proliferative response to stimulation. Altogether, these results suggest that the altered development of CD4(+) T cells is not due to qualitative differences in TCR-mediated signals, but more consistent with the hypothesis that it is due to reduced signaling strength mediated through the FcRgamma chain containing only one immunoreceptor tyrosine-based activation motif.

Induction of autoantigen-specific Th2 and Tr1 regulatory T cells and modulation of autoimmune diabetes.

Autoantigen-based immunotherapy can modulate autoimmune diabetes, perhaps due to the activation of Ag-specific regulatory T cells. Studies of these regulatory T cells should help us understand their roles in diabetes and aid in designing a more effective immunotherapy. We have used class II MHC tetramers to isolate Ag-specific T cells from nonobese diabetic (NOD) mice and BALB/c mice treated with glutamic acid decarboxylase 65 peptides (p206 and p221). Based on their cytokine secretion profiles, immunization of NOD mice with the same peptide induced different T cell subsets than in BALB/c mice. Treatment of NOD mice induced not only Th2 cells but also IFN-gamma/IL-10-secreting T regulatory type 1 (Tr1) cells. Adoptive transfer experiments showed that isolated tetramer(+) T cells specific for p206 or p221 could inhibit diabetes development. These cells were able to suppress the in vitro proliferation of other NOD mouse T cells without cell-cell contact. They performed their regulatory functions probably by secreting cytokines, and Abs against these cytokines could block their suppressive effect. Interestingly, the presence of both anti-IL-10 and anti-IFN-gamma could enhance the target cell proliferation, suggesting that Tr1 cells play an important role. Further in vivo experiments showed that the tetramer(+) T cells could block diabetogenic T cell migration into lymph nodes. Therefore, treatment of NOD mice with autoantigen could induce Th2 and Tr1 regulatory cells that can suppress the function and/or block the migration of other T cells, including diabetogenic T cells, and inhibit diabetes development.