IL-10 Diminishes CTLA-4 Expression on Islet-Resident T Cells and Sustains Their Activation Rather Than Tolerance
http://www.100md.com
免疫学杂志 2005年第2期
Abstract
IL-10, a powerful anti-Th1 cytokine, has shown paradoxical effects against diabetes. The mechanism underlying such variable function remains largely undefined. An approach for controlled mobilization of endogenous IL-10 was applied to the NOD mouse and indicated that IL-10 encounter with diabetogenic T cells within the islets sustains activation, while encounter occurring peripheral to the islets induces tolerance. Insulin -chain (INS) 9-23 peptide was expressed on an Ig, and the aggregated (agg) form of the resulting Ig-INS triggered IL-10 production by APCs, and expanded IL-10-producing T regulatory cells. Consequently, agg Ig-INS delayed diabetes effectively in young NOD mice whose pathogenic T cells remain peripheral to the islets. However, agg Ig-INS was unable to suppress the disease in 10-wk-old insulitis-positive animals whose diabetogenic T cells have populated the islets. This is not due to irreversibility of the disease because soluble Ig-INS did delay diabetes in these older mice. Evidence is provided indicating that upon migration to the islet, T cells were activated and up-regulated CTLA-4 expression. IL-10, however, reverses such up-regulation, abolishing CTLA-4-inhibitory functions and sustaining activation of the islet T lymphocytes. Therefore, IL-10 supports T cell tolerance in the periphery, but its interplay with CTLA-4 sustains activation within the islets. As a result, IL-10 displays opposite functions against diabetes in young vs older insulitis-positive mice.
Introduction
Type 1 or insulin-dependent diabetes mellitus (IDDM)4 is regarded as an immune-mediated disease in which the cells of the pancreatic islets of Langerhans are destroyed as a consequence of inflammatory reactions triggered by activation of T cells specific for cell-associated Ags (1, 2). The NOD mouse develops spontaneous diabetes that shares many of the features associated with human IDDM, providing a well-characterized animal model for this complex autoimmune disease (3). In the NOD mouse model, like in human IDDM, self-reactive Th1 cells play a major role in the initial stages of the disease (4). IL-10, a powerful anti-Th1 cytokine, has in recent years shown variable effects against type 1 diabetes (5, 6, 7, 8, 9). The mode of delivery of the cytokine (5, 6, 7) as well as the age of the animals (8, 9) are believed to be contributing factors to the erratic behavior of IL-10. The question then is how IL-10 in the blood affects diabetes differently from IL-10 expressed in the islet. Also, how does IL-10 suppress diabetes in young animals whose diabetogenic T cells remain peripheral to the islets, but display no effectiveness in older animals whose diabetogenic T cells are spread both in the periphery and the islets? One potential response to these questions is that peripheral and islet-resident diabetogenic T cells display differential susceptibility to regulation by IL-10. The studies presented in this work devised a unique strategy for mobilizing and targeting endogenous IL-10 to diabetogenic T cells and attempted to explore this postulate.
We have previously shown that expression of myelin peptides on Ig facilitates internalization through FcR and increases peptide presentation to T cells (10). In addition, aggregation of the Ig-myelin chimera, which cross-links FcR, induced IL-10 production by APCs and sustained effective suppression of experimental allergic encephalomyelitis (11, 12, 13). Recently, IL-10 has been shown to serve as a growth factor for T regulatory (Treg) cells (14, 15). In fact, in vitro (16) as well as in vivo (17) regimens using IL-10 successfully induced Treg cells that produce IL-10 and support tolerance against pathogenic T cells.
In this study, the I-Ag7-restricted insulin -chain (INS) 9-23 peptide (18, 19) was genetically engineered into the V region of an Ig molecule, and the resulting Ig-INS was aggregated (agg) and tested for induction of IL-10-producing Treg cells and suppression of diabetes. Both young NOD mice that have not progressed to insulitis and older animals positive for insulin autoantibody (IAA), which is indicative of insulitis, were included in the studies. The results indicate that agg Ig-INS induced IL-10 production by APCs and sustained the development of IL-10-producing Treg cells in vivo. Moreover, when given to 4-wk-old NOD mice, agg Ig-INS suppressed diabetogenic T cells and protected the mice against diabetes. This effect is most likely due to down-regulation by IL-10 from APCs and/or Treg cells because: 1) soluble (sol) Ig-INS, not inducing IL-10, was less effective against the disease; 2) agg Ig-INS was unable to protect young IL-10-deficient mice from diabetes; and 3) depletion of Treg cells at young age also hinders agg Ig-INS-mediated delay of the disease. Surprisingly, however, agg Ig-INS was unable to delay diabetes in IAA-positive mice despite the fact that the disease remained reversible as the sol form of Ig-INS was able to reverse it. Evidence is provided indicating that T cells up-regulate CTLA-4 upon migration to the islets and agg Ig-INS reversed such expression both in vitro and in vivo through APC and/or Treg cell-derived IL-10. The end result is sustained activation of the diabetogenic T cells. Given the fact that IAA-positive IL-10–/– mice were able to reverse their diabetes upon treatment with agg Ig-INS, it is suggested that down-regulation of CTLA-4 by IL-10 nullifies its inhibitory functions and sustains T cell activation and lack of protection against diabetes.
Materials and Methods
Mice
NOD (H-2g7) and NOD.scid mice were purchased from The Jackson Laboratory, and IL-10-deficient (IL-10–/–) NOD mice were previously described (20). The experimental procedures performed on these animals were conducted according to the guidelines of the institutional animal care and use committee.
Assessment of diabetes
Mice are bled from the tail vein weekly, and the blood samples are used to assess glucose content using test strips and an Accu-Chek Advantage monitoring system (Roche Diagnostics). A mouse is considered diabetic when the blood glucose is above 300 mg/dl for 2 consecutive wk.
Antigens
Peptides. All peptides used in this study were purchased from Metabion and purified by HPLC to >90% purity. INS peptide encompasses the diabetogenic INS 9-23 amino acid sequence (SHLVEALYLVCGERG). Glutamic acid decarboxylase 2 (GAD2) peptide corresponds to aa residues 206–220 (TYEIAPVFVLLEYVT) of GAD65 (21). Hen egg lysozyme (HEL) peptide encompasses a nondiabetogenic epitope corresponding to aa residues 11–25 (AMKRHGLDNYRGYSL) of HEL (22). INS, GAD2, and HEL peptides are presented to T cells in association with I-Ag7 MHC class II molecules.
Ig chimeras. Ig-INS, Ig-GAD2, and Ig-HEL express INS, GAD2, and HEL peptide, respectively. Insertion of INS, GAD2, and HEL nucleotide sequences into the CDR3 of the H chain V region of the 91A3 IgG2b, Ig was conducted as described (10). Large-scale cultures of transfectoma cells were conducted in DMEM medium containing 10% iron-enriched calf serum (BioWhittaker). Purification of the chimeras was conducted on separate columns of rat anti-mouse -chain mAb coupled to CNBr-activated 4B Sepharose (Amersham Biosciences). Aggregation of the Ig chimeras was conducted by precipitation with 50% saturated (NH4)2SO4, as described (11).
T cell lines
T cell lines specific for INS, GAD2, and HEL peptides were generated by immunizing NOD mice s.c. with 100 μg of peptide in CFA and in vitro peptide stimulation, followed by resting, as described (11). These lines are of Th1-type T cells and produce IFN-, but not IL-4 or IL-10 upon stimulation with the corresponding peptide or sol Ig chimera (data not shown).
Isolation of T cells
CD4 and CD8 T lymphocytes were isolated from splenic or islet cells by positive selection on Miltenyi (Miltenyi Biotec) microbeads, according to the manufacturer’s instructions. Isolation of islet CD4 and CD8 T cells was performed, as described (23). Isolation of splenic CD4+CD25+ T cells was conducted by negative selection of CD4 T cells, followed by positive selection by anti-CD25 Ab coupled to microbeads, according to Miltenyi’s instructions.
Isolation of APCs
Splenic dendritic cells (DC) were purified, according to a standard collagenase/differential adherence method (13). Briefly, the spleen was disrupted in a collagenase solution, and isolated DC floated on a dense BSA gradient. Subsequently, the cells were allowed to adhere to petri dishes for 90 min at 37°C, washed, and incubated overnight. The DC were then harvested and further purified on anti-CD11c-coupled microbeads, according to Miltenyi’s instructions. Partial purification of splenic APCs was conducted by floating the cells on a dense BSA gradient as for the DC, and the cells were washed in plain culture medium and used in presentation assays. These APCs are designated BSA-APCs.
Flow cytometry analyses
For staining of CD4+CD25+ T cells, purified splenic CD4 T cells (1 x 106 cell/ml) were incubated with anti-CD4-FITC and anti-CD25-APC or isotype control rat IgG1 APC for 30 min at 4°C and washed with buffer. The cells were then fixed with 2% formaldehyde for 20 min at 25°C and then analyzed. Events (30–50 x 103) were collected on a FACSVantage flow cytometer (BD Biosciences) and analyzed using CellQuest software 3.3 (BD Biosciences). Staining for CTLA-4 was conducted, as follows: purified islet and splenic CD4 T cells (1 x 106 cells/ml) were incubated with anti-CTLA-4-PE or isotype control hamster IgG1 for 2 h at 37°C, followed by anti-CD4-FITC for 30 min at 4°C. The cells were then washed, fixed with 2% formaldehyde, and analyzed on a FACSVantage flow cytometer, as above.
Proliferation assays
For T cell line proliferation assay, irradiated (3000 rad) NOD female splenocytes (5 x 105 cells/50 μl/well) were incubated with graded amounts of either Ig-INS or Ig-HEL (100 μl/well), and 1 h later INS-specific T cells (5 x 104 cells/well/50 μl) were added. After 72 h, 1 μCi of [3H]thymidine was added per well, and the culture was continued for an additional 14.5 h. The cells were then harvested on a Trilux 1450 Microbeta Wallac Harvester, and incorporated [3H]thymidine was counted using the Microbeta 270.004 software (EG & G Wallac).
For evaluation of T cell responses in vivo, purified splenic CD4 T cells (2.5 x 105 cell/well) isolated from 16-wk-old untreated or agg Ig-INS-treated mice were stimulated with irradiated (3000 rad) BSA-APCs (5 x 105 cells/well) and 30 μg/ml peptide, and proliferation was measured, as above.
For proliferation of Treg cells, purified CD4+CD25+ and CD4+CD25– T cells (2 x 105 cells/well) were incubated for 72 h with 18 μM INS or HEL and irradiated (3000 rad) BSA-APCs (4 x 105 cells/well), and proliferation was assessed
T cell cytokine assays
All cytokine analyses were done by ELISA using anti-cytokine Abs from BD Pharmingen, as described (13).
Analysis of the effect of APC’s IL-10 on IFN- production was done as follows: the T cell line (0.2 x 105 cells/well) was incubated with purified NOD splenic DC (5 x 104 cells/well) and Ig chimeras for 24 h, and IFN- as well as IL-10 were measured by ELISA. In some experiments, blockade of IL-10 was performed by supplementing the culture with 40 μg/ml anti-IL-10 Ab JES5-2A5. The isotype control used 40 μg/ml rat IgG.
For evaluation of cytokine T cell responses in vivo, purified splenic CD4 T cells (2.5 x 105 cell/well) isolated from 16-wk-old untreated or agg Ig-INS-treated mice were stimulated with irradiated (3000 rad) BSA-APC (5 x 105 cells/well), and 30 μg/ml peptide and IFN- as well as IL-10 were measured by ELISA after 48-h incubation.
For assessment of IL-10 production by Treg cells, purified CD4+CD25+ and CD4+CD25– T cells (2 x 105 cells/well) were incubated for 48 h with 10 μg/ml plate-bound anti-CD3 Ab (2C11), and the cytokine was measured by ELISA.
For evaluation of IFN- production by islet-resident T cells, bulk islet cells (5 x 105 cells/well) were stimulated with 18 μM INS peptide or 1 μM Ig chimeras for 48 h, and IFN- was measured by ELISA. In the case of purified islet lymphocytes, the CD4 or CD8 T cells (2 x 105 cells/well) were incubated with irradiated BSA-APCs (5 x 105 cells/well) and 1 μM Ig chimeras. IFN- was measured 48 h later by ELISA.
RT-PCR for Foxp3 expression
Total RNA was extracted from cells using TRIzol reagent and used to determine relative mRNA levels of forkhead/winged helix transcription factor gene (Foxp3). Reverse transcription and DNA amplification were performed using 300 ng of total RNA, 100 ng of Foxp3 and -actin primers (24), and the QuantiTect SYBR Green RT-PCR kit from Qiagen, as described (25).
Adoptive transfer
CD4+CD25+ and CD4+CD25– T cells were purified from the spleen of 6-wk-old agg Ig-INS-treated mice, and 5 x 105 cells were cotransferred i.v. with 10 x 106 diabetic splenocytes into NOD.scid mice (4–8 wk of age). The animals were monitored for blood glucose levels weekly.
Depletion of Treg cells
For depletion of CD25+ T cells in vivo, NOD mice were given 1 mg/mouse anti-CD25 mAb (PC61) alone or concurrently with agg Ig-INS injection. Rat IgG (1 mg/mouse) was used as a control.
Detection of IAA
The following was conducted by ELISA: microtiter plates were coated with 50 μl of sodium bicarbonate solution (pH 9.6) containing 10 μg/ml porcine insulin (Sigma-Aldrich) for 16 h at 4°C. The plates were then washed three times with PBS-0.05% Tween 20 and saturated with 2.5% casein (in 0.3 M NaCl, pH 7) for 2 h. Serum samples (1/200 dilutions) were then added for 16 h at 4°C, followed by biotin-conjugated rat anti-mouse mAb (100 μl at 1 μg/ml). The plates were then incubated with avidin peroxidase (2.5 mg/ml) for 30 min at 25°C, and the assay was revealed by addition of ABTS substrate. The samples were read at 405 nm on a Spectramax 190. A sample is considered IAA positive when the OD405 is >0.2. This cutoff line of 0.2 was chosen because serum samples from 10 SJL mice, which are nonprone to diabetes development and presumably do not produce insulin-specific autoantibodies, never exceeded 0.05 OD405 (4-fold less than cutoff).
Statistical analysis
The 2 test was used for data analysis among experimental and control groups. Cytokine levels were compared using Student’s t test for unpaired samples.
Results
Agg Ig-INS triggers IL-10 production by APCs and supports the development of Treg cells
Recent studies have revealed that delivery of myelin peptides on Igs enhances presentation to T cells (12). Moreover, aggregation of Ig-myelin chimeras induced IL-10 production by APCs and sustained effective down-regulation of myelin-reactive T cells (11, 13). Because IL-10 can serve as a growth factor for Treg cells (14), delivery of self peptides on IL-10-inducing agg Igs could support the development of Treg cells and sustain additive tolerogenic functions that should be effective against complex autoimmunity such as type 1 diabetes. To test this premise, the I-Ag7-restricted diabetogenic INS peptide was expressed on an Ig and the resulting Ig-INS chimera was tested for presentation to INS-specific T cells, triggering of IL-10 production by APCs, and induction of Treg cells. Fig. 1A shows that Ig-INS, but not the control Ig-HEL, induced significant proliferation of INS-specific T cells. These results indicate that Ig-INS was taken up by the APCs and processed, and an INS peptide was generated and presented to T cells. Also, agg, but not sol Ig-INS induced IL-10 production by DC (Fig. 1B). As IL-10 can serve as a growth factor for Treg cells (14, 15), treatment with agg Ig-INS may support the development of Treg cells in vivo. Fig. 1, C and D, shows that agg Ig-INS increased CD4+CD25+ T cells from 4.4% in untreated to 7.1% in agg Ig-INS-treated nondiabetic NOD mice. Moreover, these CD4+CD25+ T cells had increased Foxp3 mRNA expression relative to their CD4+CD25– counterparts (Fig. 1E), but displayed reduced proliferation upon stimulation with INS peptide (Fig. 1F). CD4+CD25+ T cells from untreated mice also had 4-fold higher Foxp3 expression (data not shown). Interestingly, stimulation with anti-CD3 Ab induced increased IL-10 production by the expanded relative to the natural CD4+CD25+ T cells or the CD4+CD25– counterparts (Fig. 1G). The lack of increased IL-10 production by the natural CD4+CD25+ T cells may be related to lower frequency of IL-10-producing cells among this heterogeneous population, while treatment with agg Ig-INS specifically expands IL-10-producing T cells. Finally, upon transfer to NOD.scid mice, the CD4+CD25+, but not CD4+CD25– T cells conferred protection against passive diabetes mediated by diabetogenic splenocytes (Fig. 1H). Thus, these CD4+CD25+ T cells represent Tregs rather than activated CD4+ T cells because they have higher Foxp3 expression relative to their CD4+CD25– counterparts as did CD4+CD25+ T cells from untreated mice, were not proliferative upon stimulation with INS peptide, and suppressed diabetes upon transfer into NOD.scid mice along with pathogenic splenocytes. Overall, these results indicate that agg Ig-INS supports the development of IL-10-producing Treg cells endowed with suppressive functions.
FIGURE 1. Agg Ig-INS expands IL-10-producing Treg cells. A, Presentation of Ig-INS and the control Ig-HEL to INS-specific T cells by irradiated splenic NOD APCs was assessed by [3H]thymidine incorporation. B, The ability of agg and sol Ig-INS to induce IL-10 production by DC was measured by incubating 100 x 103 purified DC and measuring the cytokine 24 h later by ELISA. Each point represents the mean of triplicate wells. Detection of splenic CD4+CD25+ T cells from 16-wk-old NOD mice untreated (C) or treated (D) with agg Ig-INS at weeks 4, 5, and 6 of age was assessed by flow cytometry. Foxp3 mRNA expression (E) and proliferation (F) of CD4+CD25+ T cells in comparison with their CD4+CD25– counterparts were analyzed by real-time PCR and [3H]thymidine incorporation, respectively. For proliferation, both INS and the control HEL peptides were presented on irradiated NOD splenocytes. Each bar represents the mean ± SD of triplicates. G, Illustrates production of IL-10 by agg Ig-INS-expanded and natural (Nil) CD4+CD25+ T cells in comparison with their CD4+CD25– counterparts upon stimulation with plate-bound anti-CD3 Ab, as measured by ELISA. The bars represent the mean ± SD of triplicates. H, Agg Ig-INS-expanded splenic CD4+CD25+ and CD4+CD25– T cells were coinjected with diabetic splenocytes into NOD.scid mice, and blood glucose levels were monitored weekly. A recipient group injected with diabetic splenocytes only (No transfer) was included as a control. Shown is the percentage of mice free of diabetes.
Agg Ig-INS suppresses T cell responses
IL-10 produced by the DC upon presentation of agg Ig-INS displays down-regulatory functions on the activation of specific T cells engaged to the DC through INS peptide. Indeed, when an INS-specific Th1 cell line was incubated with DC and agg Ig-INS, the secretion of IFN- by the T cell line decreased as production of IL-10 by the DC increased (Fig. 2A). Such down-regulation of IFN- did not occur with sol Ig-INS, which did not induce IL-10 secretion by the DC (Fig. 2B). Neutralization of IL-10 during stimulation with agg Ig-INS restores IFN- production by the T cells (Fig. 2C).
FIGURE 2. Agg Ig-INS down-regulates INS-specific T cells both in vitro and in vivo. Down-regulation of INS-specific Th1 cell line in vitro by agg (A) or sol Ig-INS (B) was assessed by measurement of IFN- using ELISA. IL-10 production by the presenting DC was also measured in the same culture well by ELISA. C, The effect of DC’s IL-10 on IFN- secretion by the Th1 cell line was assessed by stimulation with graded amounts of agg Ig-INS in the presence of 40 μg of anti-IL-10 Ab or rat IgG control. Each bar represents the mean ± SD of triplicates. D–F, Mice were untreated (Nil) or given 300 μg of agg Ig-INS (Agg Ig-INS) at weeks 4, 5, and 6 of age, and their responses were analyzed on week 16. The analysis used purified splenic CD4 T cells that were stimulated with INS or HEL peptide presented on BSA-APCs. Splenic cells from untreated diabetic (Nil/dia) mice were included for comparison purposes. The proliferative responses (D) were measured by [3H]thymidine incorporation, while IFN- (E) and IL-10 (F) production were assessed by ELISA.
In vivo, when NOD mice were given agg Ig-INS at a young age and then tested for T cell responses at a later time point, there was effective suppression of proliferation and IFN- production (Fig. 2, D and E). Untreated mice, whether diabetic or not, developed significant proliferation and IFN- production upon stimulation with INS, but not HEL peptide. Interestingly, agg Ig-INS-treated, but not untreated mice developed IL-10 responses upon stimulation with INS, but not HEL peptide (Fig. 2F). Overall, these findings indicate that agg Ig-INS induces tolerance of diabetogenic T cells most likely through IL-10 from APCs and/or Treg cells.
Agg Ig-INS delays diabetes in young NOD mice through IL-10-producing Treg cells
Agg Ig-INS was then tested for protection of young NOD mice against diabetes. Accordingly, animals were given agg Ig-INS at the preinsulitis stage (weeks 4, 5, and 6 of age), and the mice were monitored for blood glucose weekly up to week 26. As shown in Fig. 3A, agg Ig-INS delayed diabetes in all mice, except one up to week 20. Such delay remained significant by week 26, at which point only 30% of the mice had high blood glucose levels, while 80% of the untreated mice became diabetic. It is worth noting that agg Ig-HEL displayed a significant delay of diabetes up to week 16. Because Ig-HEL is made of the same Ig backbone (IgG2b isotype) as Ig-INS and upon aggregation cross-links FcR on the presenting cells and induces IL-10 production by APCs, such a delay is most likely due to IL-10 bystander suppression. In fact, we have previously observed similar bystander suppression unrelated to Ag specificity with Ig-myelin chimeras (11, 12, 13). In contrast, sol Ig-INS, which does not induce IL-10 by APCs, was not as effective as agg Ig-INS in delaying the onset of diabetes (Fig. 3B). Although no animals were hyperglycemic by week 16 of age and some delay persisted until week 20, most of the mice became diabetic by week 26. Sol Ig-HEL did not display any significant delay of diabetes onset, indicating that the effect observed with Ig-INS is Ag specific. The role of IL-10 against diabetes at this young age became evident when agg Ig-INS was unable to delay the onset of diabetes in NOD mice deficient for IL-10 (Fig. 3C). Indeed, the incidence of diabetes was similar in agg Ig-INS-treated and untreated IL-10–/– NOD mice, but significantly higher than in the treated wild-type mice. Interestingly, when depleting anti-CD25 Ab accompanied the treatment, delay of disease did not occur (Fig. 3D). Indeed, the incidence of diabetes increased from 20 to 50% at weeks 20 and 30 to 70% at week 26 in animals treated with agg Ig-INS + rat IgG vs agg Ig-INS + anti-CD25 Ab. These results indicate that agg Ig-INS, which sustains IL-10 production from both APCs and Treg cells, down-regulates diabetogenic T cells and effectively protects young mice against diabetes.
FIGURE 3. Expansion of CD4+CD25+ IL-10-producing T cells is required for effective suppression of diabetes in young NOD mice. Female NOD mice (10 per group) were given an i.p. injection of a saline solution containing 300 μg of either agg (A) or sol Ig-INS or Ig-HEL (B) at weeks 4, 5, and 6 of age, and then monitored for blood glucose levels weekly up to 26 wk of age. A group of mice that did not receive any injection (Nil) was included for control purposes. C, Groups (10 mice per group) of female wild-type (WT) and IL-10–/– NOD mice were given agg Ig-INS according to the same treatment regimen and monitored for blood glucose levels. A group of IL-10–/– mice that did not receive any treatment with agg Ig-INS was included for control purposes. D, Groups (10 mice per group) of mice were given agg Ig-INS according to the same treatment regimen, except that each injection was accompanied by 1 mg of anti-CD25 Ab or rat IgG control. A group of mice given anti-CD25 Ab without agg Ig-INS was included to serve as control. a, p < 0.05 compared with untreated mice; b, p < 0.05 compared with IL-10–/–/agg Ig-INS-treated mice; c, p < 0.05 compared with untreated mice.
Endogenous IL-10 opposes protection against diabetes upon treatment of IAA-positive mice with agg Ig-INS
Recently, it has been shown that IAA can be used as a marker for insulitis (26) and prediction of type 1 diabetes in young NOD mice (27). Similarly, among 58 female NOD mice that seroconverted to IAA production at the age of 8–11 wk, 84% had become diabetic by 30 wk of age, suggesting that our assay for detection of autoantibody is reliable and supports the notion that IAA can predict both diabetes (27) and most certainly insulitis (26). This offers a reference point to evaluate agg Ig-INS for reversal of diabetes at an early stage of the disease. Accordingly, NOD mice were given agg Ig-INS upon IAA seroconversion, as indicated, and monitored for blood glucose levels up to week 26 of age. Surprisingly, no significant delay of disease was observed, and the incidence of diabetes was similar in the mice treated with agg Ig-INS and Ig-HEL (Fig. 4A). The sol Ig-INS though showed some delay on week 20 relative to untreated or sol Ig-HEL-treated mice (Fig. 4B). Moreover, when a continuous treatment regimen was applied, a significant delay of the disease was observed with the sol, but not the agg form of Ig-INS (Fig. 4, C and D). Indeed, only 20% of sol Ig-INS-treated mice developed diabetes by week 20, and such a delay remained significant as only an additional 10% of mice became diabetic by 26 wk of age (Fig. 4D). The delay is Ag specific, as Ig-HEL had no significant delay or protection against diabetes at any time point and Ig-HEL-treated animals had a similar pattern of disease as the untreated mice. The disease pattern observed in agg Ig-INS-treated groups was also comparable to those seen with untreated or Ig-HEL-treated mice (Fig. 4C). Histological analysis at week 26 indicated that the mice treated continuously with sol Ig-INS and remaining free of diabetes had islet infiltration, but to a lesser extent than mice given sol Ig-HEL (Fig. 4E). The lack of efficacy of agg Ig-INS against diabetes was not due to irreversibility of the disease, but most likely to endogenous IL-10 induced by agg Ig-INS. This statement is supported by the observation that IAA-positive IL-10–/– mice reverse their diabetes upon treatment with agg Ig-INS, while the untreated mice do not (Fig. 4F). Indeed, the incidence of diabetes in these mice was 30% at week 26 of age, while the untreated animals had 70% incidence like wild-type NOD mice treated with agg Ig-INS. Overall, these results indicate that agg Ig-INS is not effective against diabetes upon IAA seroconversion most likely due to an undefined regulatory function of IL-10.
FIGURE 4. Treatment of diabetes in IAA-seropositive mice is much more effective when the regimen is devoid of IL-10. Mice (10 per group) that tested positive for IAA between the age of 8 and 11 wk were given an i.p. injection of 300 μg of agg (A) or sol (B) Ig-INS () or Ig-HEL () on the week of seroconversion, as well as 7 and 14 days later. Other groups of mice were given a weekly injection of agg (C) or sol (D) Ig-INS () or Ig-HEL () up to week 12. Subsequently, these mice received another 300 μg of Ig chimera every 2 wk until the age of 24 wk. This regimen is referred to as continuous treatment regimen. All mice were monitored for blood glucose from weeks 12 to 26 of age. An untreated group of mice () was included in all experiments for comparison purposes. E, Shows an H&E staining of islet sections and the percentage of noninfiltrated islets in the IAA-positive mice treated continuously with sol Ig-INS or Ig-HEL. The histological analyses illustrated in E were performed on nondiabetic mice at week 26 of age. F, Groups of IAA-positive IL-10–/– female NOD mice were subject to a continuous treatment regimen with agg Ig-INS (IL-10–/–/Agg Ig-INS), and their incidence of diabetes is compared with untreated IL-10–/– (IL-10–/–/Untreated) as well as wild-type NOD female mice treated with agg Ig-INS (WT/Agg Ig-INS). a, p < 0.05 compared with untreated mice; b, p < 0.05 compared with WT/agg Ig-INS-treated mice.
Agg Ig-INS stimulates rather than tolerizes islet-resident T cells
IL-10 has been ineffective against diabetes when expressed locally in cells (5). Similarly, mobilization of IL-10 by agg Ig-INS is also ineffective against the disease after IAA seroconversion, a stage in which diabetogenic T cells would have migrated to the islets. One possible interpretation of these observations is that islet T cells are resistant to the modulatory function of IL-10. To test this premise, splenic (peripheral) and islet cells from diabetes-free 12-wk-old naive NOD mice were stimulated with agg Ig-INS and their IFN- responses were measured. Fig. 5 shows that agg Ig-INS reduced IFN- responses by the splenic cells, while the sol form of Ig-INS as well as free INS peptide did not (Fig. 5A). Addition of IL-10, however, reduced the response of the cells against free INS and sol Ig-INS to levels similar to those observed with agg Ig-INS. In contrast, agg Ig-INS stimulated significant IFN- responses by islet cells, while the sol form and free peptide did not (Fig. 5B). Interestingly, exogenous IL-10 boosts free INS and sol Ig-INS to support significant IFN- responses by the otherwise unresponsive islet cells. Neutralization of IL-10 with an anti-IL-10 Ab during stimulation with agg Ig-INS inhibits the IFN- responses by islet cells, while isotype-matched control Ab did not (Fig. 5C). Because islet infiltration includes CD8 among other T cells (28), the INS peptide contains a CD8 epitope (29, 30), and IL-10 has been shown to stimulate CD8 T cells (31), the IFN- responses obtained with islet cells could be due to cross-presentation of agg Ig-INS to CD8 T cells. Therefore, bulk islet cells were fractionated into CD4 and CD8 T cells, and stimulation with agg Ig-INS was reassayed. The results in Fig. 5D indicate that the postulate is incorrect, and CD4, but not the CD8 T cells were able to produce IFN- upon stimulation with agg Ig-INS. Furthermore, neutralization of IL-10 with an anti-IL-10 Ab inhibits IFN- responses by the CD4 T cells. These data indicate that islet and peripheral INS-specific CD4 T cells display differential susceptibility to IL-10.
FIGURE 5. Islet INS-specific T cells develop IFN- responses upon stimulation with Ag in the presence of IL-10, while splenic T cells undergo down-regulation. Whole splenic (A) and islet (B) cells from 12-wk-old NOD female mice were stimulated with 18 μM INS, 1 μM agg, or sol Ig-INS in the absence or presence of 1 ng of rIL-10, as indicated, and their IFN- responses were measured. C, The stimulation of islet cells was conducted in the presence of 40 μg of anti-IL-10 Ab or isotype control rat IgG. D, Purified islet CD4 and CD8 T cells were incubated with BSA-APCs and 1 μM agg or sol Ig-INS with or without 40 μg/ml anti-IL-10 Ab. In all experiments, the incubation lasted 48 h, and cytokine measurement was done by ELISA using 100 μl of culture supernatant. Each bar represents the mean ± SD of triplicates after deduction of background levels obtained from cultures without Ag stimulation. These background levels were 3- to 8-fold lower than sol Ig-INS for the spleen (A) or agg Ig-INS for the islets cells (B–D). *, p < 0.05 compared with sol Ig-INS; **, p < 0.01 compared with sol Ig-INS.
Agg Ig-INS down-regulates CTLA-4 expression on islet T cells through endogenous IL-10
Upon migration to the islets, T cells would be exposed to Ag and undergo activation. Hypothetically, these cells would up-regulate CTLA-4 to deliver negative signals and control such activation (32, 33). IL-10 may down-regulate CTLA-4 to interfere with its inhibitory function and sustain activation of islet-resident T cells. Indeed, Fig. 6 shows that in the spleen of unmanipulated 12-wk-old mice, only 2.5% of CD4 T cells express surface CTLA-4 (Fig. 6A), while in the islets CTLA-4 expression was seen on 11% of the resident CD4 T cells (Fig. 6B). Interestingly, stimulation of the islet CD4 T cells with agg Ig-INS in the presence of anti-CTLA-4 Ab inhibited stimulation of IFN- production, while isotype control Ab did not (Fig. 6C). Moreover, anti-CTLA-4 Ab did not confer stimulatory function to sol Ig-INS, indicating that signaling through, rather than blockade of, CTLA-4 is the operative mechanism in this setting.
FIGURE 6. IL-10 reverses up-regulation of CTLA-4 expression upon treatment with agg Ig-INS. A and B, Splenic and islet CD4 T cells were purified by positive selection on anti-CD4 Ab-coated Miltenyi microbeads and stained with anti-CD4-FITC and PE-conjugated anti-CTLA-4 Ab or isotype control hamster IgG. The cells were gated on CD4 and analyzed for binding of anti-CTLA-4 or isotype control hamster IgG. The marker, M1, represents the cells positive for CTLA-4. C, Purified islet CD4 T cells were incubated with BSA-APCs and 1 μM agg or sol Ig-INS with or without 100 μg/ml anti-CTLA-4 Ab, then IFN- was measured by ELISA. The 4F10 Ab used here triggers rather than blocks the CTLA-4-inhibitory pathway. Each bar represents the mean ± SD of triplicates. D, The islet CD4 T cells were incubated with BSA-APCs and a 1 μM mixture of either agg or sol Ig-INS + Ig-GAD2 (1/1) in the presence or absence of 1 ng of rIL-10. The cells were then stained with anti-CD4-FITC and anti-CTLA-4- PE and analyzed as in A and B. For investigation of in vivo down-regulation of CTLA-4 by agg Ig-INS, IAA-positive NOD female mice were untreated (E), given a three-injection regimen (as in Fig. 4A) of agg Ig-INS alone (F), agg Ig-INS accompanied by anti-IL-10 Ab (500 μg/injection), (G) or sol Ig-INS (H). Seven days later, the splenic CD4 T cells were purified and stained with anti-CD4 and anti-CTLA-4, as above.
To test whether IL-10 interferes with expression of CTLA-4, islet CD4 T cells were stimulated with a mix (Ig-INS and Ig-GAD2) of Ig chimeras, and CTLA-4 expression was assessed. The addition of Ig-GAD2 together with Ig-INS in this assay is to maximize the number of specific CD4 T cells for analysis of CTLA-4 expression upon stimulation with Ag. Strikingly, the results depicted in Fig. 6D show that stimulation of islet T cells with agg chimeras significantly reduced the expression of CTLA-4. However, such a reduction did not occur with sol chimeras, but addition of IL-10 to the culture supported CTLA-4 down-regulation by the sol chimeras. In vivo, CTLA-4 expression on islet T cells was reduced from 8.3% in untreated mice to 3.1% in agg Ig-INS-treated animals (Fig. 6, E and F). In fact, when tested for IFN- production, these cells showed higher levels of cytokine than untreated animals (248 pg/ml ± 46 vs 128 pg/ml ± 27). Moreover, coadministration of anti-IL-10 Ab with agg Ig-INS restored CTLA-4 expression, and the number of islet cells with significant surface CTLA-4 was similar to that observed in mice recipient of sol Ig-INS, which does not induce IL-10 production by APCs (Fig. 6, G and H). These results indicate that IL-10 produced by the APCs and/or Treg cells down-regulates CTLA-4 expression on islet-resident T cells.
Discussion
IL-10, an anti-Th1 cytokine and growth factor for Treg cells, prompted high expectations for modulation of autoreactive T cells and suppression of autoimmunity (14, 15, 17, 34, 35). Success has been achieved in a number of autoimmunity models, but IL-10 has shown variable results in type 1 diabetes (5, 6, 7, 8, 9). In this study, an approach for controlled mobilization of IL-10 was developed and used both in young insulitis-free and older IAA-positive mice to determine how the cytokine regulates diabetogenic CD4 T cells within and peripheral to the islets. It is shown that Ig-INS, an Ig expressing the diabetogenic INS peptide, can, upon aggregation, cross-link FcRs and trigger the production of IL-10 by APCs (Fig. 1). In vitro, agg Ig-INS suppressed IFN- responses of INS-specific T cells, and such modulation was dependent upon IL-10 (Fig. 2). In vivo, young mice exposed to agg Ig-INS developed IL-10-producing Treg cells (Fig. 1), reduced their proliferative and IFN- responses (Fig. 2), and delayed their diabetes (Fig. 3). This protection against the disease was also IL-10 dependent as NOD mice deficient for the IL-10 gene were unable to delay their disease upon treatment with agg Ig-INS (Fig. 3). Moreover, depletion of IL-10-producing Treg cells abrogated agg Ig-INS-mediated protection against diabetes (Fig. 3). These observations suggest that endogenous IL-10, whether from APCs or Ag-expanded Treg cells, contributes significantly to the down-regulation of peripheral T cells in these young mice and sustains protection against the disease. IL-10 exercises anti-Th1 function through down-regulation of the expression of costimulatory molecules (31, 36). Our own investigation indicates that agg Ig-INS does not up-regulate B7 or CD40 on APCs (data not shown), which agrees with our previous reports showing that agg Ig-myelin chimeras made of the same Ig backbone as Ig-INS modulate T cells through lack of costimulation (11, 12). Thus, the mechanism we propose for protection against diabetes in the young mice suggests that IL-10 from the APCs and/or Treg cells most likely interferes with costimulation (see Fig. 7, left panel). This does not, however, exclude the possibility that Treg cells may be exercising additional suppressive function (37, 38) or that IL-10 may be directly affecting the diabetogenic T cells (39).
FIGURE 7. Proposed model for IL-10 regulation of peripheral and islet-resident diabetogenic T cells.
In contrast, this IL-10-driven protection against diabetes was not effective in older animals positive for IAA. Indeed, when agg Ig-INS was administered upon IAA seroconversion, protection was not achieved, despite the fact that the disease remains reversible and the sol form of Ig-INS delayed diabetes effectively (Fig. 4). Given the fact that in young animals most of the diabetogenic T cells remain peripheral to the islets, while in older mice a significant number of these cells would have become islet resident, we suspected that peripheral and islet-resident T cells display differential susceptibility to regulation by IL-10. This hypothesis proved correct, and splenic INS-specific T cells down-regulated IFN- production upon stimulation with agg Ig-INS, while islet T cells responded to such stimulation and produced significant amounts of IFN- (Fig. 5). However, sol Ig-INS, which does not induce IL-10 production by APCs, displayed opposite effects and stimulated IFN- responses by the splenic, but not islet
T cells. IL-10 has previously been shown to stimulate CD8 T cells (31). Given the fact that INS encompasses a CTL epitope (29, 30), we thought that agg Ig-INS is cross-presented on MHC class I through the exogenous pathway and stimulates CD8 T cells that would be frequent in the islets during insulitis (40). Our prediction, however, proved incorrect, and upon separation of islet CD4 and CD8 T cells and stimulation with agg Ig-INS only the CD4 T cells responded and produced IFN- (Fig. 5D). Overall, these observations indicate that IL-10 is stimulatory for islet-resident diabetogenic CD4 T cells, but down-regulatory for the same cells when the encounter occurs peripheral to the islets.
Upon migration to the islets, T cells are presumably exposed to Ag and most likely undergo activation. CTLA-4 expression arises on activated T cells, providing a means to control excessive responses (32, 33). Thus, it is possible that upon IAA seroconversion, the islet-resident T cells up-regulate CTLA-4 expression. Upon treatment with agg Ig-INS, it may be that IL-10 interferes with CTLA-4-inhibitory function and stimulates T cell responses rather than tolerance. This postulate proved correct, and islet, but not splenic T cells from the same animal displayed up-regulated expression of surface CTLA-4 (Fig. 6, A and B). Interestingly, addition of anti-CTLA-4 Ab during incubation with agg Ig-INS restored the inhibitory function of CTLA-4 and the T cells were not able to produce IFN- (Fig. 6C). Moreover, stimulation of islet T cells with agg Ig chimeras reduced the surface expression of CTLA-4, while stimulation with sol chimeras did not, unless supplemented with exogenous IL-10 (Fig. 6D). In vivo, treatment of IAA-positive mice with agg Ig-INS down-regulated CTLA-4 expression on islet T cells (Fig. 6, E and F). However, neutralization of IL-10 during administration of agg Ig-INS restored CTLA-4 expression (Fig. 6G). Thus, IL-10 sustains stimulation of previously activated islet-resident T cells by down-regulation of CTLA-4 expression and interference with its inhibitory function. In fact, administration of anti-CTLA-4 upon IAA seroconversion completely abrogated the onset of diabetes (data not shown). Therefore, interruption of CTLA-4-inhibitory function by IL-10 promotes activation rather than tolerance. The median panel of Fig. 7 proposes that IL-10 down-regulates both costimulatory molecules and CTLA-4, resulting in loss of inhibitory control of diabetogenic T cells. This will ultimately sustain stimulation, as previously activated lymphocytes do not require costimulation (41, 42). The fact that sol Ig-INS, not inducing IL-10, was able to delay disease at this stage bodes well with the findings. The right panel of Fig. 7 proposes that sol Ig-INS does not sustain activation of the cells because the APC at this inflammatory site express costimulatory molecules that should engage CTLA-4, which is not down-regulated by the sol Ig-INS (Fig. 6H). The end result then is inhibition of T cell activation and delay of diabetes.
Overall, agg Ig-INS tolerizes T cells in the periphery and limits input into the islets, thus effectively suppressing the disease when given at a young age before insulitis. Upon IAA seroconversion, agg Ig-INS will exercise down-regulation of peripheral T cells, limiting the seeding of islets by naive T cells, but will compensate for the shortage by stimulating and sustaining vigorous activation of islet-resident cells that have migrated before the treatment or have escaped peripheral tolerance. Sol Ig-INS is less effective in tolerizing peripheral T cells due to the lack of IL-10. However, upon IAA seroconversion, sol Ig-INS will compensate for the moderate tolerance in the periphery by not sustaining activation of islet-resident T cells. This mechanism will require continual treatment and show reduced infiltration. This model agrees with the report showing that anti-CTLA-4 Ab delays passive diabetes induced by transfer of activated pathogenic T cells (43). The findings are also in good standing with observations indicating that local expression of IL-10 exacerbates the disease (5, 7) and delivery of IL-10 at an older age is not effective against diabetes (9). Thus, the model reconciles the variable functions associated with IL-10 (6). The notion that encounter of the T cells with IL-10 before migration to the islets has a different outcome from encounters that happen within the islets is also supported by studies demonstrating that delivery of IL-10 at a young age (before insulitis) delays diabetes, while it is ineffective against disease in older animals with progressive insulitis (9).
Another point we emphasize is that this interplay between IL-10 and CTLA-4 may contribute to the development of spontaneous diabetes. Treg cells develop in the normal T cell repertoire and are presumed to sustain peripheral tolerance (37, 38). An initial exposure of cell-associated self Ags would activate diabetogenic T cells, but could also expand Treg cells to control pathogenicity (44). However, if those Treg cells produce IL-10, an interplay with CTLA-4 would be put into motion and their function would be rather counterproductive, resulting in sustained T cell activation and exacerbation of diabetes. This possibility, however, remains to be investigated. Recently, we found that decline of membrane-bound TGF can also nullify the suppressive function of Tregs, leading to development of diabetes (45).
Acknowledgments
We thank Kevin Legge for advice on the construction of the Ig chimeras, Katherine Benwell for technical assistance, George Eisenbarth for advice on detection of IAA, and Dale Wegmann for advice on generation of T cell lines. We also thank Barbara Olack and Jeremy Goodman for their assistance with the islet isolation protocol.
Footnotes
The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked advertisement in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
1 This work was supported by start up funds from the University of Missouri School of Medicine. S.J.S. was supported by a fellowship from the University of Missouri Arts and Sciences Undergraduate Research Mentor Program and a scholarship from the University of Missouri Life Sciences Undergraduate Research Opportunity Program. J.J.B. was supported by the predoctoral training grant (T32 GM08396-13) from National Institute of General Medical Sciences.
2 Current address: University of Virginia, Beirne B. Carter Center for Immunology Research, MR4 Building, Charlottesville, VA 22908-1386.
3 Address correspondence and reprint requests to Dr. Habib Zaghouani, University of Missouri School of Medicine, Department of Molecular Microbiology and Immunology, M616 Medical Sciences Building, Columbia, MO 65212. E-mail address: zaghouanih@health.missouri.edu
4 Abbreviations used in this paper: IDDM, insulin-dependent diabetes mellitus; agg, aggregated; DC, dendritic cell; Foxp3, forkhead/winged helix transcription factor gene; GAD, glutamic acid decarboxylase; HEL, hen egg lysozyme; IAA, insulin autoantibody; INS, insulin -chain; sol, soluble; Treg, T regulatory.
Received for publication June 10, 2004. Accepted for publication October 28, 2004.
References
Castano, L., G. S. Eisenbarth. 1990. Type-1 diabetes: a chronic autoimmune disease of human, mouse, and rat. Annu. Rev. Immunol. 8:647.
Tisch, R., H. O. McDevitt. 1996. Insulin dependent diabetes mellitus. Cell 85:291.
Delovitch, T., B. Singh. 1997. The nonobese diabetic mouse as a model of autoimmune diabetes: immune dysregulation gets the NOD. Immunity 7:727.
André, I., A. Gonzalez, B. Wang, J. Katz, C. Benoist, D. Mathis. 1996. Checkpoints in the progression of autoimmune disease: lessons from diabetes models. Proc. Natl. Acad. Sci. USA 93:2260.
Wogensen, L., M.-S. Lee, N. Sarvetnick. 1994. Production of interleukin 10 by islet cells accelerates immune-mediated destruction of cells in nonobese diabetic mice. J. Exp. Med. 179:1379.
Balasa, B., N. Sarvetnick. 1996. The paradoxical effects of interleukin 10 in the immunoregulation of autoimmune diabetes. J. Autoimmun. 9:283.
Balasa, B., A. La Cava, K. Van Gunst, L. Mocnik, D. Balakrishna, N. Nguen, L. Tucker, N. Sarvetnick. 2000. A mechanism for IL-10-mediated diabetes in the nonobese diabetic (NOD) mouse: ICAM-1 deficiency blocks accelerated diabetes. J. Immunol. 165:7330.
Phillips, J. M., N. M. Parish, M. Drage, A. Cooke. 2001. Cutting edge: interactions through the IL-10 receptor regulate autoimmune diabetes. J. Immunol. 167:6087
Yang, Z., M. Chen, R. Wu, L. B. Fialkow, J. S. Bromber, M. McDuffie, A. Naji, J. Nadler. 2002. Suppression of autoimmune diabetes by viral IL-10 gene transfer. J. Immunol. 168:6479.
Legge, K. L., B. Min, N. T. Potter, H. Zaghouani. 1997. Presentation of a T cell receptor antagonist peptide by immunoglobulins ablates activation of T cells by a synthetic peptide or proteins requiring endocytic processing. J. Exp. Med. 185:1043.
Legge, K. L., B. Min, J. J. Bell, J. C. Caprio, L. Li, R. K. Gregg, H. Zaghouani. 2000. Coupling of peripheral tolerance to endogenous interleukin 10 promotes effective modulation of myelin-activated T cells and ameliorates experimental allergic encephalomyelitis. J. Exp. Med. 191:2039.
Legge, K. L., J. J. Bell, L. Li, R. K. Gregg, J. C. Caprio, H. Zaghouani. 2001. Multi-modal antigen specific therapy for autoimmunity. Int. Rev. Immunol. 20:593.
Legge, K. L., R. K. Gregg, R. Maldonado-Lopez, L. Li, J. C. Caprio, M. Moser, H. Zaghouani. 2002. On the role of dendritic cells in peripheral T cell tolerance and modulation of autoimmunity. J. Exp. Med. 196:217.
Groux, H., A. O’Garra, M. Bigler, M. Rouleau, J. de Vries, M.-G. Roncarolo. 1997. Generation of a novel regulatory CD4+ T-cell population, which inhibits antigen-specific T-cell responses. Nature 389:737.
Asseman, C., S. Mauze, M. W. Leach, R. L. Coffman, F. Powrie. 1999. An essential role for IL-10 in the function of Treg cells that inhibit intestinal inflammation. J. Exp. Med. 190:995.
Barrat, F. J., D. J. Cua, A. Boonstra, D. F. Richards, C. Crain, H. F. Savelkoul, R. de Waal-Malefyt, R. L. Coffman, C. M. Hawrylowicz, A. O’Garra. 2002. In vitro generation of interleukin 10-producing regulatory CD4+ T cells is induced by immunosuppressive drugs and inhibited by T helper (Th1)- and Th2-inducing cytokines. J. Exp. Med. 195:603.
Sundstedt, A., E. J. O’Neill, K. S. Nicolson, D. C. Wraith. 2003. Role for IL-10 in suppression mediated by peptide-induced Treg cells in vivo. J. Immunol. 170:1240.
Daniel, D., D. R. Wegmann. 1996. Protection of nonobese diabetic mice from diabetes by intranasal or subcutaneous administration of insulin peptide B (9-23). Proc. Natl. Acad. Sci. USA 93:956
Heath, V. L., P. Hutchings, D. J. Fowell, A. Cooke, D. Mason. 1999. Peptides derived from murine insulin are diabetogenic in both rats and mice, but the disease-inducing epitopes are different: evidence against a common environmental cross-reactivity in the pathogenicity of diabetes. Diabetes 48:2157.
Serreze, D. V., H. D. Chapman, C. M Post, E. A. Johnson, W. L. Suarez-Pinzon, A. Rabinovitch. 2001. Th1 to Th2 cytokine shifts in nonobese diabetic mice: sometimes an outcome, rather than the cause of diabetes resistance elicited by immunostimulation. J. Immunol. 166:1352.
Chao, C.-C., H.-K. Sytwu, E. L. Chen, J. Toma, H. O. McDevitt. 1999. The role of MHC class II molecules in susceptibility to type 1 diabetes: identification of peptide epitopes and characterization of the T cell repertoire. Proc. Natl. Acad. Sci. USA 96:9299.
Latek, R. R., A. Suri, S. J. Petzold, C. A. Nelson, O. Kanagawa, E. R. Unanue, D. H. Fremont. 2000. Structural basis of peptide binding and presentation by the diabetes-associated MHC class II molecule of NOD mice. Immunity 12:699.
Faveeuw, C., M. C. Gagnerault, F. Lepault. 1995. Isolation of leukocytes infiltrating the islets of Langerhans of diabetes-prone mice for flow cytometric analysis. J. Immunol. Methods 187:163.
Fontenot, J. D., M. A. Gavin, A. Y. Rudensky. 2003. Foxp3 programs the development and function of CD4+CD25+Treg cells. Nat. Immunol. 4:330.
Li, L., H.-H. Lee, J. J. Bell, R. K. Gregg, J. S. Ellis, A. Gessner, H. Zaghouani. 2004. IL-4 utilizes an alternative receptor to drive apoptosis of Th1 cells and skews neonatal immunity towards Th2. Immunity 20:429.
Robles, D. T., G. S. Eisenbarth, N. J. M. Dailey, L. B. Peterson, L. Wicker. 2003. Insulin autoantibodies are associated with islet inflammation but not always related to diabetes progression in NOD congenic mice. Diabetes 52:882
Yu, L., D. T. Robles, N. Abiru, P. Kaur, M. Rewers, K. Kelemen, G. S. Eisenbarth. 2000. Early expression of antiinsulin autoantibodies of humans and the NOD mouse: evidence for early determination of subsequent diabetes. Proc. Natl. Acad. Sci. USA 97:1701.
Ablamunits, V., D. Elias, I. R. Cohen. 1999. The pathogenicity of islet-infiltrating lymphocytes in the non-obese diabetic (NOD) mouse. Clin. Exp. Immunol. 115:260
Anderson, B., B.-J. Park, J. Verdaguer, A. Abrani, P. Santamaria. 1999. Prevalent CD8+ T cell response against one peptide/MHC complex in autoimmune diabetes. Proc. Natl. Acad. Sci. USA 96:9311.
Wong, F. S., A. K. Moustakas, L. Wen, G. K. Papadopoulos, C. A. Janeway, Jr. 2002. Analysis of structure and function relationships of an autoantigenic peptide of insulin bound to H-2K(d) that stimulates CD8 T cells in insulin-dependent diabetes mellitus. Proc. Natl. Acad. Sci. USA 99:5551.
Moore, K. W., R. de Waal Malefyt, R. L. Coffman, A. O’Garra. 2001. Interleukin-10 and the interleukin-10 receptor. Annu. Rev. Immunol. 19:683.
Chambers, C. A., M. S. Kuhns, J. G. Egen, J. P. Allison. 2001. CTLA-4-mediated inhibition in regulation of T cell responses: mechanisms and manipulation in tumor immunotherapy. Annu. Rev. Immunol. 19:565.
Salomon, B., J. A. Bluestone. 2001. Complexities of CD28/B7: CTLA-4 costimulatory pathways in autoimmunity and transplantation. Annu. Rev. Immunol. 19:225.
Zheng, X., A. Steele, W. Hancock, A. C. Stevens, P. W. Nickerson, P. Roy-Chaudhury, Y. Tian, T. B. Strom. 1997. A noncytolytic IL-10/Fc fusion protein prevents diabetes, blocks autoimmunity, and promotes suppressor phenomena in NOD mice. J. Immunol. 158:4507.
Moritani, M., K. Yoshimoto, S. Ii, M. Kondo, H. Iwahana, T. Yamaoka, T. Sano, N. Nakano, H. Kikutani, M. Itakura. 1996. Prevention of adoptively transferred diabetes in nonobese diabetic mice with IL-10-transduced islet-specific Th1 lymphocytes. J. Clin. Invest. 98:1851.
Ding, L., P. S. Linsley, L.-Y. Huang, R. N. Germain, E. M. Shevach. 1993. IL-10 inhibits macrophage costimulatory activity by selectively inhibiting the up-regulation of B7 expression. J. Immunol. 151:1224.
Sakaguchi, S.. 2000. Treg cells: key controller of immunologic self tolerance. Cell 101:455.
Shevach, E. M.. 2000. Treg cell in autoimmunity. Annu. Rev. Immunol. 18:423.
Joss, A., M. Akdis, A. Faith, K. Blaser, C. A. Akdis. 2000. IL-10 directly acts on T cells by specifically altering the CD28 co-stimulation pathway. Eur. J. Immunol. 30:1683.
Wegmann, D. R., M. Norbury-Glaser, D. Daniel. 1994. Insulin-specific(Randal K. Greg2, J. Jerem)
IL-10, a powerful anti-Th1 cytokine, has shown paradoxical effects against diabetes. The mechanism underlying such variable function remains largely undefined. An approach for controlled mobilization of endogenous IL-10 was applied to the NOD mouse and indicated that IL-10 encounter with diabetogenic T cells within the islets sustains activation, while encounter occurring peripheral to the islets induces tolerance. Insulin -chain (INS) 9-23 peptide was expressed on an Ig, and the aggregated (agg) form of the resulting Ig-INS triggered IL-10 production by APCs, and expanded IL-10-producing T regulatory cells. Consequently, agg Ig-INS delayed diabetes effectively in young NOD mice whose pathogenic T cells remain peripheral to the islets. However, agg Ig-INS was unable to suppress the disease in 10-wk-old insulitis-positive animals whose diabetogenic T cells have populated the islets. This is not due to irreversibility of the disease because soluble Ig-INS did delay diabetes in these older mice. Evidence is provided indicating that upon migration to the islet, T cells were activated and up-regulated CTLA-4 expression. IL-10, however, reverses such up-regulation, abolishing CTLA-4-inhibitory functions and sustaining activation of the islet T lymphocytes. Therefore, IL-10 supports T cell tolerance in the periphery, but its interplay with CTLA-4 sustains activation within the islets. As a result, IL-10 displays opposite functions against diabetes in young vs older insulitis-positive mice.
Introduction
Type 1 or insulin-dependent diabetes mellitus (IDDM)4 is regarded as an immune-mediated disease in which the cells of the pancreatic islets of Langerhans are destroyed as a consequence of inflammatory reactions triggered by activation of T cells specific for cell-associated Ags (1, 2). The NOD mouse develops spontaneous diabetes that shares many of the features associated with human IDDM, providing a well-characterized animal model for this complex autoimmune disease (3). In the NOD mouse model, like in human IDDM, self-reactive Th1 cells play a major role in the initial stages of the disease (4). IL-10, a powerful anti-Th1 cytokine, has in recent years shown variable effects against type 1 diabetes (5, 6, 7, 8, 9). The mode of delivery of the cytokine (5, 6, 7) as well as the age of the animals (8, 9) are believed to be contributing factors to the erratic behavior of IL-10. The question then is how IL-10 in the blood affects diabetes differently from IL-10 expressed in the islet. Also, how does IL-10 suppress diabetes in young animals whose diabetogenic T cells remain peripheral to the islets, but display no effectiveness in older animals whose diabetogenic T cells are spread both in the periphery and the islets? One potential response to these questions is that peripheral and islet-resident diabetogenic T cells display differential susceptibility to regulation by IL-10. The studies presented in this work devised a unique strategy for mobilizing and targeting endogenous IL-10 to diabetogenic T cells and attempted to explore this postulate.
We have previously shown that expression of myelin peptides on Ig facilitates internalization through FcR and increases peptide presentation to T cells (10). In addition, aggregation of the Ig-myelin chimera, which cross-links FcR, induced IL-10 production by APCs and sustained effective suppression of experimental allergic encephalomyelitis (11, 12, 13). Recently, IL-10 has been shown to serve as a growth factor for T regulatory (Treg) cells (14, 15). In fact, in vitro (16) as well as in vivo (17) regimens using IL-10 successfully induced Treg cells that produce IL-10 and support tolerance against pathogenic T cells.
In this study, the I-Ag7-restricted insulin -chain (INS) 9-23 peptide (18, 19) was genetically engineered into the V region of an Ig molecule, and the resulting Ig-INS was aggregated (agg) and tested for induction of IL-10-producing Treg cells and suppression of diabetes. Both young NOD mice that have not progressed to insulitis and older animals positive for insulin autoantibody (IAA), which is indicative of insulitis, were included in the studies. The results indicate that agg Ig-INS induced IL-10 production by APCs and sustained the development of IL-10-producing Treg cells in vivo. Moreover, when given to 4-wk-old NOD mice, agg Ig-INS suppressed diabetogenic T cells and protected the mice against diabetes. This effect is most likely due to down-regulation by IL-10 from APCs and/or Treg cells because: 1) soluble (sol) Ig-INS, not inducing IL-10, was less effective against the disease; 2) agg Ig-INS was unable to protect young IL-10-deficient mice from diabetes; and 3) depletion of Treg cells at young age also hinders agg Ig-INS-mediated delay of the disease. Surprisingly, however, agg Ig-INS was unable to delay diabetes in IAA-positive mice despite the fact that the disease remained reversible as the sol form of Ig-INS was able to reverse it. Evidence is provided indicating that T cells up-regulate CTLA-4 upon migration to the islets and agg Ig-INS reversed such expression both in vitro and in vivo through APC and/or Treg cell-derived IL-10. The end result is sustained activation of the diabetogenic T cells. Given the fact that IAA-positive IL-10–/– mice were able to reverse their diabetes upon treatment with agg Ig-INS, it is suggested that down-regulation of CTLA-4 by IL-10 nullifies its inhibitory functions and sustains T cell activation and lack of protection against diabetes.
Materials and Methods
Mice
NOD (H-2g7) and NOD.scid mice were purchased from The Jackson Laboratory, and IL-10-deficient (IL-10–/–) NOD mice were previously described (20). The experimental procedures performed on these animals were conducted according to the guidelines of the institutional animal care and use committee.
Assessment of diabetes
Mice are bled from the tail vein weekly, and the blood samples are used to assess glucose content using test strips and an Accu-Chek Advantage monitoring system (Roche Diagnostics). A mouse is considered diabetic when the blood glucose is above 300 mg/dl for 2 consecutive wk.
Antigens
Peptides. All peptides used in this study were purchased from Metabion and purified by HPLC to >90% purity. INS peptide encompasses the diabetogenic INS 9-23 amino acid sequence (SHLVEALYLVCGERG). Glutamic acid decarboxylase 2 (GAD2) peptide corresponds to aa residues 206–220 (TYEIAPVFVLLEYVT) of GAD65 (21). Hen egg lysozyme (HEL) peptide encompasses a nondiabetogenic epitope corresponding to aa residues 11–25 (AMKRHGLDNYRGYSL) of HEL (22). INS, GAD2, and HEL peptides are presented to T cells in association with I-Ag7 MHC class II molecules.
Ig chimeras. Ig-INS, Ig-GAD2, and Ig-HEL express INS, GAD2, and HEL peptide, respectively. Insertion of INS, GAD2, and HEL nucleotide sequences into the CDR3 of the H chain V region of the 91A3 IgG2b, Ig was conducted as described (10). Large-scale cultures of transfectoma cells were conducted in DMEM medium containing 10% iron-enriched calf serum (BioWhittaker). Purification of the chimeras was conducted on separate columns of rat anti-mouse -chain mAb coupled to CNBr-activated 4B Sepharose (Amersham Biosciences). Aggregation of the Ig chimeras was conducted by precipitation with 50% saturated (NH4)2SO4, as described (11).
T cell lines
T cell lines specific for INS, GAD2, and HEL peptides were generated by immunizing NOD mice s.c. with 100 μg of peptide in CFA and in vitro peptide stimulation, followed by resting, as described (11). These lines are of Th1-type T cells and produce IFN-, but not IL-4 or IL-10 upon stimulation with the corresponding peptide or sol Ig chimera (data not shown).
Isolation of T cells
CD4 and CD8 T lymphocytes were isolated from splenic or islet cells by positive selection on Miltenyi (Miltenyi Biotec) microbeads, according to the manufacturer’s instructions. Isolation of islet CD4 and CD8 T cells was performed, as described (23). Isolation of splenic CD4+CD25+ T cells was conducted by negative selection of CD4 T cells, followed by positive selection by anti-CD25 Ab coupled to microbeads, according to Miltenyi’s instructions.
Isolation of APCs
Splenic dendritic cells (DC) were purified, according to a standard collagenase/differential adherence method (13). Briefly, the spleen was disrupted in a collagenase solution, and isolated DC floated on a dense BSA gradient. Subsequently, the cells were allowed to adhere to petri dishes for 90 min at 37°C, washed, and incubated overnight. The DC were then harvested and further purified on anti-CD11c-coupled microbeads, according to Miltenyi’s instructions. Partial purification of splenic APCs was conducted by floating the cells on a dense BSA gradient as for the DC, and the cells were washed in plain culture medium and used in presentation assays. These APCs are designated BSA-APCs.
Flow cytometry analyses
For staining of CD4+CD25+ T cells, purified splenic CD4 T cells (1 x 106 cell/ml) were incubated with anti-CD4-FITC and anti-CD25-APC or isotype control rat IgG1 APC for 30 min at 4°C and washed with buffer. The cells were then fixed with 2% formaldehyde for 20 min at 25°C and then analyzed. Events (30–50 x 103) were collected on a FACSVantage flow cytometer (BD Biosciences) and analyzed using CellQuest software 3.3 (BD Biosciences). Staining for CTLA-4 was conducted, as follows: purified islet and splenic CD4 T cells (1 x 106 cells/ml) were incubated with anti-CTLA-4-PE or isotype control hamster IgG1 for 2 h at 37°C, followed by anti-CD4-FITC for 30 min at 4°C. The cells were then washed, fixed with 2% formaldehyde, and analyzed on a FACSVantage flow cytometer, as above.
Proliferation assays
For T cell line proliferation assay, irradiated (3000 rad) NOD female splenocytes (5 x 105 cells/50 μl/well) were incubated with graded amounts of either Ig-INS or Ig-HEL (100 μl/well), and 1 h later INS-specific T cells (5 x 104 cells/well/50 μl) were added. After 72 h, 1 μCi of [3H]thymidine was added per well, and the culture was continued for an additional 14.5 h. The cells were then harvested on a Trilux 1450 Microbeta Wallac Harvester, and incorporated [3H]thymidine was counted using the Microbeta 270.004 software (EG & G Wallac).
For evaluation of T cell responses in vivo, purified splenic CD4 T cells (2.5 x 105 cell/well) isolated from 16-wk-old untreated or agg Ig-INS-treated mice were stimulated with irradiated (3000 rad) BSA-APCs (5 x 105 cells/well) and 30 μg/ml peptide, and proliferation was measured, as above.
For proliferation of Treg cells, purified CD4+CD25+ and CD4+CD25– T cells (2 x 105 cells/well) were incubated for 72 h with 18 μM INS or HEL and irradiated (3000 rad) BSA-APCs (4 x 105 cells/well), and proliferation was assessed
T cell cytokine assays
All cytokine analyses were done by ELISA using anti-cytokine Abs from BD Pharmingen, as described (13).
Analysis of the effect of APC’s IL-10 on IFN- production was done as follows: the T cell line (0.2 x 105 cells/well) was incubated with purified NOD splenic DC (5 x 104 cells/well) and Ig chimeras for 24 h, and IFN- as well as IL-10 were measured by ELISA. In some experiments, blockade of IL-10 was performed by supplementing the culture with 40 μg/ml anti-IL-10 Ab JES5-2A5. The isotype control used 40 μg/ml rat IgG.
For evaluation of cytokine T cell responses in vivo, purified splenic CD4 T cells (2.5 x 105 cell/well) isolated from 16-wk-old untreated or agg Ig-INS-treated mice were stimulated with irradiated (3000 rad) BSA-APC (5 x 105 cells/well), and 30 μg/ml peptide and IFN- as well as IL-10 were measured by ELISA after 48-h incubation.
For assessment of IL-10 production by Treg cells, purified CD4+CD25+ and CD4+CD25– T cells (2 x 105 cells/well) were incubated for 48 h with 10 μg/ml plate-bound anti-CD3 Ab (2C11), and the cytokine was measured by ELISA.
For evaluation of IFN- production by islet-resident T cells, bulk islet cells (5 x 105 cells/well) were stimulated with 18 μM INS peptide or 1 μM Ig chimeras for 48 h, and IFN- was measured by ELISA. In the case of purified islet lymphocytes, the CD4 or CD8 T cells (2 x 105 cells/well) were incubated with irradiated BSA-APCs (5 x 105 cells/well) and 1 μM Ig chimeras. IFN- was measured 48 h later by ELISA.
RT-PCR for Foxp3 expression
Total RNA was extracted from cells using TRIzol reagent and used to determine relative mRNA levels of forkhead/winged helix transcription factor gene (Foxp3). Reverse transcription and DNA amplification were performed using 300 ng of total RNA, 100 ng of Foxp3 and -actin primers (24), and the QuantiTect SYBR Green RT-PCR kit from Qiagen, as described (25).
Adoptive transfer
CD4+CD25+ and CD4+CD25– T cells were purified from the spleen of 6-wk-old agg Ig-INS-treated mice, and 5 x 105 cells were cotransferred i.v. with 10 x 106 diabetic splenocytes into NOD.scid mice (4–8 wk of age). The animals were monitored for blood glucose levels weekly.
Depletion of Treg cells
For depletion of CD25+ T cells in vivo, NOD mice were given 1 mg/mouse anti-CD25 mAb (PC61) alone or concurrently with agg Ig-INS injection. Rat IgG (1 mg/mouse) was used as a control.
Detection of IAA
The following was conducted by ELISA: microtiter plates were coated with 50 μl of sodium bicarbonate solution (pH 9.6) containing 10 μg/ml porcine insulin (Sigma-Aldrich) for 16 h at 4°C. The plates were then washed three times with PBS-0.05% Tween 20 and saturated with 2.5% casein (in 0.3 M NaCl, pH 7) for 2 h. Serum samples (1/200 dilutions) were then added for 16 h at 4°C, followed by biotin-conjugated rat anti-mouse mAb (100 μl at 1 μg/ml). The plates were then incubated with avidin peroxidase (2.5 mg/ml) for 30 min at 25°C, and the assay was revealed by addition of ABTS substrate. The samples were read at 405 nm on a Spectramax 190. A sample is considered IAA positive when the OD405 is >0.2. This cutoff line of 0.2 was chosen because serum samples from 10 SJL mice, which are nonprone to diabetes development and presumably do not produce insulin-specific autoantibodies, never exceeded 0.05 OD405 (4-fold less than cutoff).
Statistical analysis
The 2 test was used for data analysis among experimental and control groups. Cytokine levels were compared using Student’s t test for unpaired samples.
Results
Agg Ig-INS triggers IL-10 production by APCs and supports the development of Treg cells
Recent studies have revealed that delivery of myelin peptides on Igs enhances presentation to T cells (12). Moreover, aggregation of Ig-myelin chimeras induced IL-10 production by APCs and sustained effective down-regulation of myelin-reactive T cells (11, 13). Because IL-10 can serve as a growth factor for Treg cells (14), delivery of self peptides on IL-10-inducing agg Igs could support the development of Treg cells and sustain additive tolerogenic functions that should be effective against complex autoimmunity such as type 1 diabetes. To test this premise, the I-Ag7-restricted diabetogenic INS peptide was expressed on an Ig and the resulting Ig-INS chimera was tested for presentation to INS-specific T cells, triggering of IL-10 production by APCs, and induction of Treg cells. Fig. 1A shows that Ig-INS, but not the control Ig-HEL, induced significant proliferation of INS-specific T cells. These results indicate that Ig-INS was taken up by the APCs and processed, and an INS peptide was generated and presented to T cells. Also, agg, but not sol Ig-INS induced IL-10 production by DC (Fig. 1B). As IL-10 can serve as a growth factor for Treg cells (14, 15), treatment with agg Ig-INS may support the development of Treg cells in vivo. Fig. 1, C and D, shows that agg Ig-INS increased CD4+CD25+ T cells from 4.4% in untreated to 7.1% in agg Ig-INS-treated nondiabetic NOD mice. Moreover, these CD4+CD25+ T cells had increased Foxp3 mRNA expression relative to their CD4+CD25– counterparts (Fig. 1E), but displayed reduced proliferation upon stimulation with INS peptide (Fig. 1F). CD4+CD25+ T cells from untreated mice also had 4-fold higher Foxp3 expression (data not shown). Interestingly, stimulation with anti-CD3 Ab induced increased IL-10 production by the expanded relative to the natural CD4+CD25+ T cells or the CD4+CD25– counterparts (Fig. 1G). The lack of increased IL-10 production by the natural CD4+CD25+ T cells may be related to lower frequency of IL-10-producing cells among this heterogeneous population, while treatment with agg Ig-INS specifically expands IL-10-producing T cells. Finally, upon transfer to NOD.scid mice, the CD4+CD25+, but not CD4+CD25– T cells conferred protection against passive diabetes mediated by diabetogenic splenocytes (Fig. 1H). Thus, these CD4+CD25+ T cells represent Tregs rather than activated CD4+ T cells because they have higher Foxp3 expression relative to their CD4+CD25– counterparts as did CD4+CD25+ T cells from untreated mice, were not proliferative upon stimulation with INS peptide, and suppressed diabetes upon transfer into NOD.scid mice along with pathogenic splenocytes. Overall, these results indicate that agg Ig-INS supports the development of IL-10-producing Treg cells endowed with suppressive functions.
FIGURE 1. Agg Ig-INS expands IL-10-producing Treg cells. A, Presentation of Ig-INS and the control Ig-HEL to INS-specific T cells by irradiated splenic NOD APCs was assessed by [3H]thymidine incorporation. B, The ability of agg and sol Ig-INS to induce IL-10 production by DC was measured by incubating 100 x 103 purified DC and measuring the cytokine 24 h later by ELISA. Each point represents the mean of triplicate wells. Detection of splenic CD4+CD25+ T cells from 16-wk-old NOD mice untreated (C) or treated (D) with agg Ig-INS at weeks 4, 5, and 6 of age was assessed by flow cytometry. Foxp3 mRNA expression (E) and proliferation (F) of CD4+CD25+ T cells in comparison with their CD4+CD25– counterparts were analyzed by real-time PCR and [3H]thymidine incorporation, respectively. For proliferation, both INS and the control HEL peptides were presented on irradiated NOD splenocytes. Each bar represents the mean ± SD of triplicates. G, Illustrates production of IL-10 by agg Ig-INS-expanded and natural (Nil) CD4+CD25+ T cells in comparison with their CD4+CD25– counterparts upon stimulation with plate-bound anti-CD3 Ab, as measured by ELISA. The bars represent the mean ± SD of triplicates. H, Agg Ig-INS-expanded splenic CD4+CD25+ and CD4+CD25– T cells were coinjected with diabetic splenocytes into NOD.scid mice, and blood glucose levels were monitored weekly. A recipient group injected with diabetic splenocytes only (No transfer) was included as a control. Shown is the percentage of mice free of diabetes.
Agg Ig-INS suppresses T cell responses
IL-10 produced by the DC upon presentation of agg Ig-INS displays down-regulatory functions on the activation of specific T cells engaged to the DC through INS peptide. Indeed, when an INS-specific Th1 cell line was incubated with DC and agg Ig-INS, the secretion of IFN- by the T cell line decreased as production of IL-10 by the DC increased (Fig. 2A). Such down-regulation of IFN- did not occur with sol Ig-INS, which did not induce IL-10 secretion by the DC (Fig. 2B). Neutralization of IL-10 during stimulation with agg Ig-INS restores IFN- production by the T cells (Fig. 2C).
FIGURE 2. Agg Ig-INS down-regulates INS-specific T cells both in vitro and in vivo. Down-regulation of INS-specific Th1 cell line in vitro by agg (A) or sol Ig-INS (B) was assessed by measurement of IFN- using ELISA. IL-10 production by the presenting DC was also measured in the same culture well by ELISA. C, The effect of DC’s IL-10 on IFN- secretion by the Th1 cell line was assessed by stimulation with graded amounts of agg Ig-INS in the presence of 40 μg of anti-IL-10 Ab or rat IgG control. Each bar represents the mean ± SD of triplicates. D–F, Mice were untreated (Nil) or given 300 μg of agg Ig-INS (Agg Ig-INS) at weeks 4, 5, and 6 of age, and their responses were analyzed on week 16. The analysis used purified splenic CD4 T cells that were stimulated with INS or HEL peptide presented on BSA-APCs. Splenic cells from untreated diabetic (Nil/dia) mice were included for comparison purposes. The proliferative responses (D) were measured by [3H]thymidine incorporation, while IFN- (E) and IL-10 (F) production were assessed by ELISA.
In vivo, when NOD mice were given agg Ig-INS at a young age and then tested for T cell responses at a later time point, there was effective suppression of proliferation and IFN- production (Fig. 2, D and E). Untreated mice, whether diabetic or not, developed significant proliferation and IFN- production upon stimulation with INS, but not HEL peptide. Interestingly, agg Ig-INS-treated, but not untreated mice developed IL-10 responses upon stimulation with INS, but not HEL peptide (Fig. 2F). Overall, these findings indicate that agg Ig-INS induces tolerance of diabetogenic T cells most likely through IL-10 from APCs and/or Treg cells.
Agg Ig-INS delays diabetes in young NOD mice through IL-10-producing Treg cells
Agg Ig-INS was then tested for protection of young NOD mice against diabetes. Accordingly, animals were given agg Ig-INS at the preinsulitis stage (weeks 4, 5, and 6 of age), and the mice were monitored for blood glucose weekly up to week 26. As shown in Fig. 3A, agg Ig-INS delayed diabetes in all mice, except one up to week 20. Such delay remained significant by week 26, at which point only 30% of the mice had high blood glucose levels, while 80% of the untreated mice became diabetic. It is worth noting that agg Ig-HEL displayed a significant delay of diabetes up to week 16. Because Ig-HEL is made of the same Ig backbone (IgG2b isotype) as Ig-INS and upon aggregation cross-links FcR on the presenting cells and induces IL-10 production by APCs, such a delay is most likely due to IL-10 bystander suppression. In fact, we have previously observed similar bystander suppression unrelated to Ag specificity with Ig-myelin chimeras (11, 12, 13). In contrast, sol Ig-INS, which does not induce IL-10 by APCs, was not as effective as agg Ig-INS in delaying the onset of diabetes (Fig. 3B). Although no animals were hyperglycemic by week 16 of age and some delay persisted until week 20, most of the mice became diabetic by week 26. Sol Ig-HEL did not display any significant delay of diabetes onset, indicating that the effect observed with Ig-INS is Ag specific. The role of IL-10 against diabetes at this young age became evident when agg Ig-INS was unable to delay the onset of diabetes in NOD mice deficient for IL-10 (Fig. 3C). Indeed, the incidence of diabetes was similar in agg Ig-INS-treated and untreated IL-10–/– NOD mice, but significantly higher than in the treated wild-type mice. Interestingly, when depleting anti-CD25 Ab accompanied the treatment, delay of disease did not occur (Fig. 3D). Indeed, the incidence of diabetes increased from 20 to 50% at weeks 20 and 30 to 70% at week 26 in animals treated with agg Ig-INS + rat IgG vs agg Ig-INS + anti-CD25 Ab. These results indicate that agg Ig-INS, which sustains IL-10 production from both APCs and Treg cells, down-regulates diabetogenic T cells and effectively protects young mice against diabetes.
FIGURE 3. Expansion of CD4+CD25+ IL-10-producing T cells is required for effective suppression of diabetes in young NOD mice. Female NOD mice (10 per group) were given an i.p. injection of a saline solution containing 300 μg of either agg (A) or sol Ig-INS or Ig-HEL (B) at weeks 4, 5, and 6 of age, and then monitored for blood glucose levels weekly up to 26 wk of age. A group of mice that did not receive any injection (Nil) was included for control purposes. C, Groups (10 mice per group) of female wild-type (WT) and IL-10–/– NOD mice were given agg Ig-INS according to the same treatment regimen and monitored for blood glucose levels. A group of IL-10–/– mice that did not receive any treatment with agg Ig-INS was included for control purposes. D, Groups (10 mice per group) of mice were given agg Ig-INS according to the same treatment regimen, except that each injection was accompanied by 1 mg of anti-CD25 Ab or rat IgG control. A group of mice given anti-CD25 Ab without agg Ig-INS was included to serve as control. a, p < 0.05 compared with untreated mice; b, p < 0.05 compared with IL-10–/–/agg Ig-INS-treated mice; c, p < 0.05 compared with untreated mice.
Endogenous IL-10 opposes protection against diabetes upon treatment of IAA-positive mice with agg Ig-INS
Recently, it has been shown that IAA can be used as a marker for insulitis (26) and prediction of type 1 diabetes in young NOD mice (27). Similarly, among 58 female NOD mice that seroconverted to IAA production at the age of 8–11 wk, 84% had become diabetic by 30 wk of age, suggesting that our assay for detection of autoantibody is reliable and supports the notion that IAA can predict both diabetes (27) and most certainly insulitis (26). This offers a reference point to evaluate agg Ig-INS for reversal of diabetes at an early stage of the disease. Accordingly, NOD mice were given agg Ig-INS upon IAA seroconversion, as indicated, and monitored for blood glucose levels up to week 26 of age. Surprisingly, no significant delay of disease was observed, and the incidence of diabetes was similar in the mice treated with agg Ig-INS and Ig-HEL (Fig. 4A). The sol Ig-INS though showed some delay on week 20 relative to untreated or sol Ig-HEL-treated mice (Fig. 4B). Moreover, when a continuous treatment regimen was applied, a significant delay of the disease was observed with the sol, but not the agg form of Ig-INS (Fig. 4, C and D). Indeed, only 20% of sol Ig-INS-treated mice developed diabetes by week 20, and such a delay remained significant as only an additional 10% of mice became diabetic by 26 wk of age (Fig. 4D). The delay is Ag specific, as Ig-HEL had no significant delay or protection against diabetes at any time point and Ig-HEL-treated animals had a similar pattern of disease as the untreated mice. The disease pattern observed in agg Ig-INS-treated groups was also comparable to those seen with untreated or Ig-HEL-treated mice (Fig. 4C). Histological analysis at week 26 indicated that the mice treated continuously with sol Ig-INS and remaining free of diabetes had islet infiltration, but to a lesser extent than mice given sol Ig-HEL (Fig. 4E). The lack of efficacy of agg Ig-INS against diabetes was not due to irreversibility of the disease, but most likely to endogenous IL-10 induced by agg Ig-INS. This statement is supported by the observation that IAA-positive IL-10–/– mice reverse their diabetes upon treatment with agg Ig-INS, while the untreated mice do not (Fig. 4F). Indeed, the incidence of diabetes in these mice was 30% at week 26 of age, while the untreated animals had 70% incidence like wild-type NOD mice treated with agg Ig-INS. Overall, these results indicate that agg Ig-INS is not effective against diabetes upon IAA seroconversion most likely due to an undefined regulatory function of IL-10.
FIGURE 4. Treatment of diabetes in IAA-seropositive mice is much more effective when the regimen is devoid of IL-10. Mice (10 per group) that tested positive for IAA between the age of 8 and 11 wk were given an i.p. injection of 300 μg of agg (A) or sol (B) Ig-INS () or Ig-HEL () on the week of seroconversion, as well as 7 and 14 days later. Other groups of mice were given a weekly injection of agg (C) or sol (D) Ig-INS () or Ig-HEL () up to week 12. Subsequently, these mice received another 300 μg of Ig chimera every 2 wk until the age of 24 wk. This regimen is referred to as continuous treatment regimen. All mice were monitored for blood glucose from weeks 12 to 26 of age. An untreated group of mice () was included in all experiments for comparison purposes. E, Shows an H&E staining of islet sections and the percentage of noninfiltrated islets in the IAA-positive mice treated continuously with sol Ig-INS or Ig-HEL. The histological analyses illustrated in E were performed on nondiabetic mice at week 26 of age. F, Groups of IAA-positive IL-10–/– female NOD mice were subject to a continuous treatment regimen with agg Ig-INS (IL-10–/–/Agg Ig-INS), and their incidence of diabetes is compared with untreated IL-10–/– (IL-10–/–/Untreated) as well as wild-type NOD female mice treated with agg Ig-INS (WT/Agg Ig-INS). a, p < 0.05 compared with untreated mice; b, p < 0.05 compared with WT/agg Ig-INS-treated mice.
Agg Ig-INS stimulates rather than tolerizes islet-resident T cells
IL-10 has been ineffective against diabetes when expressed locally in cells (5). Similarly, mobilization of IL-10 by agg Ig-INS is also ineffective against the disease after IAA seroconversion, a stage in which diabetogenic T cells would have migrated to the islets. One possible interpretation of these observations is that islet T cells are resistant to the modulatory function of IL-10. To test this premise, splenic (peripheral) and islet cells from diabetes-free 12-wk-old naive NOD mice were stimulated with agg Ig-INS and their IFN- responses were measured. Fig. 5 shows that agg Ig-INS reduced IFN- responses by the splenic cells, while the sol form of Ig-INS as well as free INS peptide did not (Fig. 5A). Addition of IL-10, however, reduced the response of the cells against free INS and sol Ig-INS to levels similar to those observed with agg Ig-INS. In contrast, agg Ig-INS stimulated significant IFN- responses by islet cells, while the sol form and free peptide did not (Fig. 5B). Interestingly, exogenous IL-10 boosts free INS and sol Ig-INS to support significant IFN- responses by the otherwise unresponsive islet cells. Neutralization of IL-10 with an anti-IL-10 Ab during stimulation with agg Ig-INS inhibits the IFN- responses by islet cells, while isotype-matched control Ab did not (Fig. 5C). Because islet infiltration includes CD8 among other T cells (28), the INS peptide contains a CD8 epitope (29, 30), and IL-10 has been shown to stimulate CD8 T cells (31), the IFN- responses obtained with islet cells could be due to cross-presentation of agg Ig-INS to CD8 T cells. Therefore, bulk islet cells were fractionated into CD4 and CD8 T cells, and stimulation with agg Ig-INS was reassayed. The results in Fig. 5D indicate that the postulate is incorrect, and CD4, but not the CD8 T cells were able to produce IFN- upon stimulation with agg Ig-INS. Furthermore, neutralization of IL-10 with an anti-IL-10 Ab inhibits IFN- responses by the CD4 T cells. These data indicate that islet and peripheral INS-specific CD4 T cells display differential susceptibility to IL-10.
FIGURE 5. Islet INS-specific T cells develop IFN- responses upon stimulation with Ag in the presence of IL-10, while splenic T cells undergo down-regulation. Whole splenic (A) and islet (B) cells from 12-wk-old NOD female mice were stimulated with 18 μM INS, 1 μM agg, or sol Ig-INS in the absence or presence of 1 ng of rIL-10, as indicated, and their IFN- responses were measured. C, The stimulation of islet cells was conducted in the presence of 40 μg of anti-IL-10 Ab or isotype control rat IgG. D, Purified islet CD4 and CD8 T cells were incubated with BSA-APCs and 1 μM agg or sol Ig-INS with or without 40 μg/ml anti-IL-10 Ab. In all experiments, the incubation lasted 48 h, and cytokine measurement was done by ELISA using 100 μl of culture supernatant. Each bar represents the mean ± SD of triplicates after deduction of background levels obtained from cultures without Ag stimulation. These background levels were 3- to 8-fold lower than sol Ig-INS for the spleen (A) or agg Ig-INS for the islets cells (B–D). *, p < 0.05 compared with sol Ig-INS; **, p < 0.01 compared with sol Ig-INS.
Agg Ig-INS down-regulates CTLA-4 expression on islet T cells through endogenous IL-10
Upon migration to the islets, T cells would be exposed to Ag and undergo activation. Hypothetically, these cells would up-regulate CTLA-4 to deliver negative signals and control such activation (32, 33). IL-10 may down-regulate CTLA-4 to interfere with its inhibitory function and sustain activation of islet-resident T cells. Indeed, Fig. 6 shows that in the spleen of unmanipulated 12-wk-old mice, only 2.5% of CD4 T cells express surface CTLA-4 (Fig. 6A), while in the islets CTLA-4 expression was seen on 11% of the resident CD4 T cells (Fig. 6B). Interestingly, stimulation of the islet CD4 T cells with agg Ig-INS in the presence of anti-CTLA-4 Ab inhibited stimulation of IFN- production, while isotype control Ab did not (Fig. 6C). Moreover, anti-CTLA-4 Ab did not confer stimulatory function to sol Ig-INS, indicating that signaling through, rather than blockade of, CTLA-4 is the operative mechanism in this setting.
FIGURE 6. IL-10 reverses up-regulation of CTLA-4 expression upon treatment with agg Ig-INS. A and B, Splenic and islet CD4 T cells were purified by positive selection on anti-CD4 Ab-coated Miltenyi microbeads and stained with anti-CD4-FITC and PE-conjugated anti-CTLA-4 Ab or isotype control hamster IgG. The cells were gated on CD4 and analyzed for binding of anti-CTLA-4 or isotype control hamster IgG. The marker, M1, represents the cells positive for CTLA-4. C, Purified islet CD4 T cells were incubated with BSA-APCs and 1 μM agg or sol Ig-INS with or without 100 μg/ml anti-CTLA-4 Ab, then IFN- was measured by ELISA. The 4F10 Ab used here triggers rather than blocks the CTLA-4-inhibitory pathway. Each bar represents the mean ± SD of triplicates. D, The islet CD4 T cells were incubated with BSA-APCs and a 1 μM mixture of either agg or sol Ig-INS + Ig-GAD2 (1/1) in the presence or absence of 1 ng of rIL-10. The cells were then stained with anti-CD4-FITC and anti-CTLA-4- PE and analyzed as in A and B. For investigation of in vivo down-regulation of CTLA-4 by agg Ig-INS, IAA-positive NOD female mice were untreated (E), given a three-injection regimen (as in Fig. 4A) of agg Ig-INS alone (F), agg Ig-INS accompanied by anti-IL-10 Ab (500 μg/injection), (G) or sol Ig-INS (H). Seven days later, the splenic CD4 T cells were purified and stained with anti-CD4 and anti-CTLA-4, as above.
To test whether IL-10 interferes with expression of CTLA-4, islet CD4 T cells were stimulated with a mix (Ig-INS and Ig-GAD2) of Ig chimeras, and CTLA-4 expression was assessed. The addition of Ig-GAD2 together with Ig-INS in this assay is to maximize the number of specific CD4 T cells for analysis of CTLA-4 expression upon stimulation with Ag. Strikingly, the results depicted in Fig. 6D show that stimulation of islet T cells with agg chimeras significantly reduced the expression of CTLA-4. However, such a reduction did not occur with sol chimeras, but addition of IL-10 to the culture supported CTLA-4 down-regulation by the sol chimeras. In vivo, CTLA-4 expression on islet T cells was reduced from 8.3% in untreated mice to 3.1% in agg Ig-INS-treated animals (Fig. 6, E and F). In fact, when tested for IFN- production, these cells showed higher levels of cytokine than untreated animals (248 pg/ml ± 46 vs 128 pg/ml ± 27). Moreover, coadministration of anti-IL-10 Ab with agg Ig-INS restored CTLA-4 expression, and the number of islet cells with significant surface CTLA-4 was similar to that observed in mice recipient of sol Ig-INS, which does not induce IL-10 production by APCs (Fig. 6, G and H). These results indicate that IL-10 produced by the APCs and/or Treg cells down-regulates CTLA-4 expression on islet-resident T cells.
Discussion
IL-10, an anti-Th1 cytokine and growth factor for Treg cells, prompted high expectations for modulation of autoreactive T cells and suppression of autoimmunity (14, 15, 17, 34, 35). Success has been achieved in a number of autoimmunity models, but IL-10 has shown variable results in type 1 diabetes (5, 6, 7, 8, 9). In this study, an approach for controlled mobilization of IL-10 was developed and used both in young insulitis-free and older IAA-positive mice to determine how the cytokine regulates diabetogenic CD4 T cells within and peripheral to the islets. It is shown that Ig-INS, an Ig expressing the diabetogenic INS peptide, can, upon aggregation, cross-link FcRs and trigger the production of IL-10 by APCs (Fig. 1). In vitro, agg Ig-INS suppressed IFN- responses of INS-specific T cells, and such modulation was dependent upon IL-10 (Fig. 2). In vivo, young mice exposed to agg Ig-INS developed IL-10-producing Treg cells (Fig. 1), reduced their proliferative and IFN- responses (Fig. 2), and delayed their diabetes (Fig. 3). This protection against the disease was also IL-10 dependent as NOD mice deficient for the IL-10 gene were unable to delay their disease upon treatment with agg Ig-INS (Fig. 3). Moreover, depletion of IL-10-producing Treg cells abrogated agg Ig-INS-mediated protection against diabetes (Fig. 3). These observations suggest that endogenous IL-10, whether from APCs or Ag-expanded Treg cells, contributes significantly to the down-regulation of peripheral T cells in these young mice and sustains protection against the disease. IL-10 exercises anti-Th1 function through down-regulation of the expression of costimulatory molecules (31, 36). Our own investigation indicates that agg Ig-INS does not up-regulate B7 or CD40 on APCs (data not shown), which agrees with our previous reports showing that agg Ig-myelin chimeras made of the same Ig backbone as Ig-INS modulate T cells through lack of costimulation (11, 12). Thus, the mechanism we propose for protection against diabetes in the young mice suggests that IL-10 from the APCs and/or Treg cells most likely interferes with costimulation (see Fig. 7, left panel). This does not, however, exclude the possibility that Treg cells may be exercising additional suppressive function (37, 38) or that IL-10 may be directly affecting the diabetogenic T cells (39).
FIGURE 7. Proposed model for IL-10 regulation of peripheral and islet-resident diabetogenic T cells.
In contrast, this IL-10-driven protection against diabetes was not effective in older animals positive for IAA. Indeed, when agg Ig-INS was administered upon IAA seroconversion, protection was not achieved, despite the fact that the disease remains reversible and the sol form of Ig-INS delayed diabetes effectively (Fig. 4). Given the fact that in young animals most of the diabetogenic T cells remain peripheral to the islets, while in older mice a significant number of these cells would have become islet resident, we suspected that peripheral and islet-resident T cells display differential susceptibility to regulation by IL-10. This hypothesis proved correct, and splenic INS-specific T cells down-regulated IFN- production upon stimulation with agg Ig-INS, while islet T cells responded to such stimulation and produced significant amounts of IFN- (Fig. 5). However, sol Ig-INS, which does not induce IL-10 production by APCs, displayed opposite effects and stimulated IFN- responses by the splenic, but not islet
T cells. IL-10 has previously been shown to stimulate CD8 T cells (31). Given the fact that INS encompasses a CTL epitope (29, 30), we thought that agg Ig-INS is cross-presented on MHC class I through the exogenous pathway and stimulates CD8 T cells that would be frequent in the islets during insulitis (40). Our prediction, however, proved incorrect, and upon separation of islet CD4 and CD8 T cells and stimulation with agg Ig-INS only the CD4 T cells responded and produced IFN- (Fig. 5D). Overall, these observations indicate that IL-10 is stimulatory for islet-resident diabetogenic CD4 T cells, but down-regulatory for the same cells when the encounter occurs peripheral to the islets.
Upon migration to the islets, T cells are presumably exposed to Ag and most likely undergo activation. CTLA-4 expression arises on activated T cells, providing a means to control excessive responses (32, 33). Thus, it is possible that upon IAA seroconversion, the islet-resident T cells up-regulate CTLA-4 expression. Upon treatment with agg Ig-INS, it may be that IL-10 interferes with CTLA-4-inhibitory function and stimulates T cell responses rather than tolerance. This postulate proved correct, and islet, but not splenic T cells from the same animal displayed up-regulated expression of surface CTLA-4 (Fig. 6, A and B). Interestingly, addition of anti-CTLA-4 Ab during incubation with agg Ig-INS restored the inhibitory function of CTLA-4 and the T cells were not able to produce IFN- (Fig. 6C). Moreover, stimulation of islet T cells with agg Ig chimeras reduced the surface expression of CTLA-4, while stimulation with sol chimeras did not, unless supplemented with exogenous IL-10 (Fig. 6D). In vivo, treatment of IAA-positive mice with agg Ig-INS down-regulated CTLA-4 expression on islet T cells (Fig. 6, E and F). However, neutralization of IL-10 during administration of agg Ig-INS restored CTLA-4 expression (Fig. 6G). Thus, IL-10 sustains stimulation of previously activated islet-resident T cells by down-regulation of CTLA-4 expression and interference with its inhibitory function. In fact, administration of anti-CTLA-4 upon IAA seroconversion completely abrogated the onset of diabetes (data not shown). Therefore, interruption of CTLA-4-inhibitory function by IL-10 promotes activation rather than tolerance. The median panel of Fig. 7 proposes that IL-10 down-regulates both costimulatory molecules and CTLA-4, resulting in loss of inhibitory control of diabetogenic T cells. This will ultimately sustain stimulation, as previously activated lymphocytes do not require costimulation (41, 42). The fact that sol Ig-INS, not inducing IL-10, was able to delay disease at this stage bodes well with the findings. The right panel of Fig. 7 proposes that sol Ig-INS does not sustain activation of the cells because the APC at this inflammatory site express costimulatory molecules that should engage CTLA-4, which is not down-regulated by the sol Ig-INS (Fig. 6H). The end result then is inhibition of T cell activation and delay of diabetes.
Overall, agg Ig-INS tolerizes T cells in the periphery and limits input into the islets, thus effectively suppressing the disease when given at a young age before insulitis. Upon IAA seroconversion, agg Ig-INS will exercise down-regulation of peripheral T cells, limiting the seeding of islets by naive T cells, but will compensate for the shortage by stimulating and sustaining vigorous activation of islet-resident cells that have migrated before the treatment or have escaped peripheral tolerance. Sol Ig-INS is less effective in tolerizing peripheral T cells due to the lack of IL-10. However, upon IAA seroconversion, sol Ig-INS will compensate for the moderate tolerance in the periphery by not sustaining activation of islet-resident T cells. This mechanism will require continual treatment and show reduced infiltration. This model agrees with the report showing that anti-CTLA-4 Ab delays passive diabetes induced by transfer of activated pathogenic T cells (43). The findings are also in good standing with observations indicating that local expression of IL-10 exacerbates the disease (5, 7) and delivery of IL-10 at an older age is not effective against diabetes (9). Thus, the model reconciles the variable functions associated with IL-10 (6). The notion that encounter of the T cells with IL-10 before migration to the islets has a different outcome from encounters that happen within the islets is also supported by studies demonstrating that delivery of IL-10 at a young age (before insulitis) delays diabetes, while it is ineffective against disease in older animals with progressive insulitis (9).
Another point we emphasize is that this interplay between IL-10 and CTLA-4 may contribute to the development of spontaneous diabetes. Treg cells develop in the normal T cell repertoire and are presumed to sustain peripheral tolerance (37, 38). An initial exposure of cell-associated self Ags would activate diabetogenic T cells, but could also expand Treg cells to control pathogenicity (44). However, if those Treg cells produce IL-10, an interplay with CTLA-4 would be put into motion and their function would be rather counterproductive, resulting in sustained T cell activation and exacerbation of diabetes. This possibility, however, remains to be investigated. Recently, we found that decline of membrane-bound TGF can also nullify the suppressive function of Tregs, leading to development of diabetes (45).
Acknowledgments
We thank Kevin Legge for advice on the construction of the Ig chimeras, Katherine Benwell for technical assistance, George Eisenbarth for advice on detection of IAA, and Dale Wegmann for advice on generation of T cell lines. We also thank Barbara Olack and Jeremy Goodman for their assistance with the islet isolation protocol.
Footnotes
The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked advertisement in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.
1 This work was supported by start up funds from the University of Missouri School of Medicine. S.J.S. was supported by a fellowship from the University of Missouri Arts and Sciences Undergraduate Research Mentor Program and a scholarship from the University of Missouri Life Sciences Undergraduate Research Opportunity Program. J.J.B. was supported by the predoctoral training grant (T32 GM08396-13) from National Institute of General Medical Sciences.
2 Current address: University of Virginia, Beirne B. Carter Center for Immunology Research, MR4 Building, Charlottesville, VA 22908-1386.
3 Address correspondence and reprint requests to Dr. Habib Zaghouani, University of Missouri School of Medicine, Department of Molecular Microbiology and Immunology, M616 Medical Sciences Building, Columbia, MO 65212. E-mail address: zaghouanih@health.missouri.edu
4 Abbreviations used in this paper: IDDM, insulin-dependent diabetes mellitus; agg, aggregated; DC, dendritic cell; Foxp3, forkhead/winged helix transcription factor gene; GAD, glutamic acid decarboxylase; HEL, hen egg lysozyme; IAA, insulin autoantibody; INS, insulin -chain; sol, soluble; Treg, T regulatory.
Received for publication June 10, 2004. Accepted for publication October 28, 2004.
References
Castano, L., G. S. Eisenbarth. 1990. Type-1 diabetes: a chronic autoimmune disease of human, mouse, and rat. Annu. Rev. Immunol. 8:647.
Tisch, R., H. O. McDevitt. 1996. Insulin dependent diabetes mellitus. Cell 85:291.
Delovitch, T., B. Singh. 1997. The nonobese diabetic mouse as a model of autoimmune diabetes: immune dysregulation gets the NOD. Immunity 7:727.
André, I., A. Gonzalez, B. Wang, J. Katz, C. Benoist, D. Mathis. 1996. Checkpoints in the progression of autoimmune disease: lessons from diabetes models. Proc. Natl. Acad. Sci. USA 93:2260.
Wogensen, L., M.-S. Lee, N. Sarvetnick. 1994. Production of interleukin 10 by islet cells accelerates immune-mediated destruction of cells in nonobese diabetic mice. J. Exp. Med. 179:1379.
Balasa, B., N. Sarvetnick. 1996. The paradoxical effects of interleukin 10 in the immunoregulation of autoimmune diabetes. J. Autoimmun. 9:283.
Balasa, B., A. La Cava, K. Van Gunst, L. Mocnik, D. Balakrishna, N. Nguen, L. Tucker, N. Sarvetnick. 2000. A mechanism for IL-10-mediated diabetes in the nonobese diabetic (NOD) mouse: ICAM-1 deficiency blocks accelerated diabetes. J. Immunol. 165:7330.
Phillips, J. M., N. M. Parish, M. Drage, A. Cooke. 2001. Cutting edge: interactions through the IL-10 receptor regulate autoimmune diabetes. J. Immunol. 167:6087
Yang, Z., M. Chen, R. Wu, L. B. Fialkow, J. S. Bromber, M. McDuffie, A. Naji, J. Nadler. 2002. Suppression of autoimmune diabetes by viral IL-10 gene transfer. J. Immunol. 168:6479.
Legge, K. L., B. Min, N. T. Potter, H. Zaghouani. 1997. Presentation of a T cell receptor antagonist peptide by immunoglobulins ablates activation of T cells by a synthetic peptide or proteins requiring endocytic processing. J. Exp. Med. 185:1043.
Legge, K. L., B. Min, J. J. Bell, J. C. Caprio, L. Li, R. K. Gregg, H. Zaghouani. 2000. Coupling of peripheral tolerance to endogenous interleukin 10 promotes effective modulation of myelin-activated T cells and ameliorates experimental allergic encephalomyelitis. J. Exp. Med. 191:2039.
Legge, K. L., J. J. Bell, L. Li, R. K. Gregg, J. C. Caprio, H. Zaghouani. 2001. Multi-modal antigen specific therapy for autoimmunity. Int. Rev. Immunol. 20:593.
Legge, K. L., R. K. Gregg, R. Maldonado-Lopez, L. Li, J. C. Caprio, M. Moser, H. Zaghouani. 2002. On the role of dendritic cells in peripheral T cell tolerance and modulation of autoimmunity. J. Exp. Med. 196:217.
Groux, H., A. O’Garra, M. Bigler, M. Rouleau, J. de Vries, M.-G. Roncarolo. 1997. Generation of a novel regulatory CD4+ T-cell population, which inhibits antigen-specific T-cell responses. Nature 389:737.
Asseman, C., S. Mauze, M. W. Leach, R. L. Coffman, F. Powrie. 1999. An essential role for IL-10 in the function of Treg cells that inhibit intestinal inflammation. J. Exp. Med. 190:995.
Barrat, F. J., D. J. Cua, A. Boonstra, D. F. Richards, C. Crain, H. F. Savelkoul, R. de Waal-Malefyt, R. L. Coffman, C. M. Hawrylowicz, A. O’Garra. 2002. In vitro generation of interleukin 10-producing regulatory CD4+ T cells is induced by immunosuppressive drugs and inhibited by T helper (Th1)- and Th2-inducing cytokines. J. Exp. Med. 195:603.
Sundstedt, A., E. J. O’Neill, K. S. Nicolson, D. C. Wraith. 2003. Role for IL-10 in suppression mediated by peptide-induced Treg cells in vivo. J. Immunol. 170:1240.
Daniel, D., D. R. Wegmann. 1996. Protection of nonobese diabetic mice from diabetes by intranasal or subcutaneous administration of insulin peptide B (9-23). Proc. Natl. Acad. Sci. USA 93:956
Heath, V. L., P. Hutchings, D. J. Fowell, A. Cooke, D. Mason. 1999. Peptides derived from murine insulin are diabetogenic in both rats and mice, but the disease-inducing epitopes are different: evidence against a common environmental cross-reactivity in the pathogenicity of diabetes. Diabetes 48:2157.
Serreze, D. V., H. D. Chapman, C. M Post, E. A. Johnson, W. L. Suarez-Pinzon, A. Rabinovitch. 2001. Th1 to Th2 cytokine shifts in nonobese diabetic mice: sometimes an outcome, rather than the cause of diabetes resistance elicited by immunostimulation. J. Immunol. 166:1352.
Chao, C.-C., H.-K. Sytwu, E. L. Chen, J. Toma, H. O. McDevitt. 1999. The role of MHC class II molecules in susceptibility to type 1 diabetes: identification of peptide epitopes and characterization of the T cell repertoire. Proc. Natl. Acad. Sci. USA 96:9299.
Latek, R. R., A. Suri, S. J. Petzold, C. A. Nelson, O. Kanagawa, E. R. Unanue, D. H. Fremont. 2000. Structural basis of peptide binding and presentation by the diabetes-associated MHC class II molecule of NOD mice. Immunity 12:699.
Faveeuw, C., M. C. Gagnerault, F. Lepault. 1995. Isolation of leukocytes infiltrating the islets of Langerhans of diabetes-prone mice for flow cytometric analysis. J. Immunol. Methods 187:163.
Fontenot, J. D., M. A. Gavin, A. Y. Rudensky. 2003. Foxp3 programs the development and function of CD4+CD25+Treg cells. Nat. Immunol. 4:330.
Li, L., H.-H. Lee, J. J. Bell, R. K. Gregg, J. S. Ellis, A. Gessner, H. Zaghouani. 2004. IL-4 utilizes an alternative receptor to drive apoptosis of Th1 cells and skews neonatal immunity towards Th2. Immunity 20:429.
Robles, D. T., G. S. Eisenbarth, N. J. M. Dailey, L. B. Peterson, L. Wicker. 2003. Insulin autoantibodies are associated with islet inflammation but not always related to diabetes progression in NOD congenic mice. Diabetes 52:882
Yu, L., D. T. Robles, N. Abiru, P. Kaur, M. Rewers, K. Kelemen, G. S. Eisenbarth. 2000. Early expression of antiinsulin autoantibodies of humans and the NOD mouse: evidence for early determination of subsequent diabetes. Proc. Natl. Acad. Sci. USA 97:1701.
Ablamunits, V., D. Elias, I. R. Cohen. 1999. The pathogenicity of islet-infiltrating lymphocytes in the non-obese diabetic (NOD) mouse. Clin. Exp. Immunol. 115:260
Anderson, B., B.-J. Park, J. Verdaguer, A. Abrani, P. Santamaria. 1999. Prevalent CD8+ T cell response against one peptide/MHC complex in autoimmune diabetes. Proc. Natl. Acad. Sci. USA 96:9311.
Wong, F. S., A. K. Moustakas, L. Wen, G. K. Papadopoulos, C. A. Janeway, Jr. 2002. Analysis of structure and function relationships of an autoantigenic peptide of insulin bound to H-2K(d) that stimulates CD8 T cells in insulin-dependent diabetes mellitus. Proc. Natl. Acad. Sci. USA 99:5551.
Moore, K. W., R. de Waal Malefyt, R. L. Coffman, A. O’Garra. 2001. Interleukin-10 and the interleukin-10 receptor. Annu. Rev. Immunol. 19:683.
Chambers, C. A., M. S. Kuhns, J. G. Egen, J. P. Allison. 2001. CTLA-4-mediated inhibition in regulation of T cell responses: mechanisms and manipulation in tumor immunotherapy. Annu. Rev. Immunol. 19:565.
Salomon, B., J. A. Bluestone. 2001. Complexities of CD28/B7: CTLA-4 costimulatory pathways in autoimmunity and transplantation. Annu. Rev. Immunol. 19:225.
Zheng, X., A. Steele, W. Hancock, A. C. Stevens, P. W. Nickerson, P. Roy-Chaudhury, Y. Tian, T. B. Strom. 1997. A noncytolytic IL-10/Fc fusion protein prevents diabetes, blocks autoimmunity, and promotes suppressor phenomena in NOD mice. J. Immunol. 158:4507.
Moritani, M., K. Yoshimoto, S. Ii, M. Kondo, H. Iwahana, T. Yamaoka, T. Sano, N. Nakano, H. Kikutani, M. Itakura. 1996. Prevention of adoptively transferred diabetes in nonobese diabetic mice with IL-10-transduced islet-specific Th1 lymphocytes. J. Clin. Invest. 98:1851.
Ding, L., P. S. Linsley, L.-Y. Huang, R. N. Germain, E. M. Shevach. 1993. IL-10 inhibits macrophage costimulatory activity by selectively inhibiting the up-regulation of B7 expression. J. Immunol. 151:1224.
Sakaguchi, S.. 2000. Treg cells: key controller of immunologic self tolerance. Cell 101:455.
Shevach, E. M.. 2000. Treg cell in autoimmunity. Annu. Rev. Immunol. 18:423.
Joss, A., M. Akdis, A. Faith, K. Blaser, C. A. Akdis. 2000. IL-10 directly acts on T cells by specifically altering the CD28 co-stimulation pathway. Eur. J. Immunol. 30:1683.
Wegmann, D. R., M. Norbury-Glaser, D. Daniel. 1994. Insulin-specific(Randal K. Greg2, J. Jerem)