Report

Protein Kinase C-θ Mediates Negative Feedback on Regulatory T Cell Function

See allHide authors and affiliations

Science  16 Apr 2010:
Vol. 328, Issue 5976, pp. 372-376
DOI: 10.1126/science.1186068

This article has a correction. Please see:

Abstract

T cell receptor (TCR)–dependent regulatory T cell (Treg) activity controls effector T cell (Teff) function and is inhibited by the inflammatory cytokine tumor necrosis factor–α (TNF-α). Protein kinase C-θ (PKC-θ) recruitment to the immunological synapse is required for full Teff activation. In contrast, PKC-θ was sequestered away from the Treg immunological synapse. Furthermore, PKC-θ blockade enhanced Treg function, demonstrating PKC-θ inhibits Treg-mediated suppression. Inhibition of PKC-θ protected Treg from inactivation by TNF-α, restored activity of defective Treg from rheumatoid arthritis patients, and enhanced protection of mice from inflammatory colitis. Treg freed of PKC-θ–mediated inhibition can function in the presence of inflammatory cytokines and thus have therapeutic potential in control of inflammatory diseases.

CD4+ CD25+ regulatory T cells (Treg) suppress the function of CD4+ and CD8+ effector T cells (Teff) through a T cell receptor (TCR) engagement and cell contact–dependent mechanism (13). Inflammatory signals delivered by cytokines like tumor necrosis factor–α (TNF-α) decrease Treg activity (4, 5), perhaps as a mechanism to reduce interference by Treg cells in immune responses to pathogens. In rheumatoid arthritis, Treg cells circulate in normal numbers, but they have decreased activity ex vivo (5, 6). Besides the negative signals initiated by TNF-α, Treg also receive inhibitory signals via the TCR. Akt activation by the TCR can reduce Treg function and thus appears to be tightly regulated (7). This suggests TCR signaling in Treg can negatively feed back to inhibit Treg-mediated suppression. Moreover, TCR signaling leads to formation of the immunological synapse within seconds of T cell activation. Thus, the differences in TCR signaling in Treg may emerge at the level of the immunological synapse (IS), a structured interface between T cells and antigen-presenting cells (APCs) where TCR signalosomes are assembled (8). Whereas Treg can form stable contacts with APCs with functional consequences both in vitro and in vivo (911), signaling events in the Treg IS have not been investigated.

To study signaling in the human Treg IS, we developed a model system on supported planar bilayers containing the mobile fluorescently labeled intercellular adhesion molecule–1 (ICAM-1) and antigen surrogate anti-CD3 (the signaling subunit of the TCR) antibodies and CD4+ CD25+ Teff or CD4+ CD25+ Treg freshly isolated from peripheral blood (fig. S1, A to C). Teff and Treg both formed IS, defined by a symmetric pattern consisting of a central cluster of anti-CD3 surrounded by a ring of ICAM-1 (12, 13) (Fig. 1A). Treg ISs were more stable than Teff ISs (fig. S2, A and B), which displayed symmetry breaking within 20 min as previously described (14). Ex vivo expanded, human umbilical cord blood Treg (15) displayed similar behavior to adult peripheral blood Treg (fig. S2, C to E). We measured recruitment of TCR proximal signaling molecules to IS by staining with phospho-Src kinase activation loop and Zap70 kinase interdomain A tyrosine 319 antibodies and imaging with total internal reflection fluorescence microscopy (TIRFM) (16). Signals were quantified on the basis of unbiased measurement of IS proximal fluorescence intensity. Teff IS displayed significantly higher amounts of phospho-Src than Treg (fig. S3A); however, we observed a similar intensity of phosphorylation of the downstream kinase Zap70 (fig. S3B). We next explored the protein kinase C-θ (PKC-θ) pathway, which is downstream of Src family kinases (17) and mediates IS breaking (14), because Zap70 phosphorylation appeared normal in Treg.

Fig. 1

Human Treg form altered ISs. Human Teff and Treg were introduced into bilayers containing anti-CD3 (5 μg/ml) and ICAM-1 at 250 molecules/mm2 (A to D); fixed at 6 min; and permeabilized, stained, and imaged by TIRFM [(A), (B), (D), and (E)] or by confocal microscopy (C). (A) Localization of ICAM-1 (red) and anti-CD3 (green) in the IS. (B and D) Staining and average fluorescence intensity of PKC-θ (B) and Carma-1 (D). (C) Distribution of endogenous PKC-θ in cells. Histogram shows average of (bottom planes “proximal”/upper planes “distal”) ratio of anti-PKCθ intensity per cell. The images show representative images. (E and F) PKC-θ staining (E) and average fluorescence intensity (F) in Teff or Treg on bilayers containing only anti-CD3 (left) or ICAM-1 (right). Data are representative of three [(A) to (D)] or five [(E) and (F)] different experiments. P values were calculated by Mann-Whitney test.

PKC-θ recruitment to the IS leads to recruitment of Carma-1, a MAGUK (membrane-associated guanylate kinase) protein, which enables the assembly of a Carma-1-Bcl10-Malt1 complex necessary for transcription factor NF-κB activation and subsequent Teff activation (18). We quantified PKC-θ and Carma-1 recruitment in ISs on planar bilayers by TIRFM. Teff ISs recruited PKC-θ in a broad pattern overlapping with early TCR signaling, as previously reported (14) (Fig. 1B). Treg displayed sixfold lower PKC-θ recruitment to IS than that of Teff, and this recruitment was focused in a limited area defined by a small number of bright puncta (Fig. 1B). The same difference in the ability to recruit PKC-θ was found with ex vivo expanded, human umbilical cord blood Treg and expanded CD4+ CD25 Teff cells (fig. S4). CD28 co-stimulation plays an important role in PKC-θ recruitment to IS (13, 17). Thus, we compared the ability of Treg and Teff to recruit PKC-θ in the presence of a CD28 ligand, CD80, in the bilayer. The co-stimulatory signal increased the amounts of PKC-θ recruited to ISs in both Treg and Teff (fig. S5). Even in the presence of CD80 in the bilayer, the Treg still have significantly less PKC-θ recruited to the IS than Teff (P < 0.001). Interestingly, total PKC-θ expression was even higher in Treg compared with Teff (fig. S6). Moreover, the confocal imaging revealed that PKC-θ was sequestered away from the Treg IS, whereas PKC-θ in Teff accessed the IS and formed cytoplasmic puncta (Fig. 1C and fig. S7). Treg IS also displayed significantly less Carma-1 recruitment than Teff IS (Fig. 1D). Thus, recruitment of PKC-θ and its downstream target to the IS are reduced in Treg.

We further dissected the TCR and LFA-1 integrin-dependent components of PKC-θ recruitment by using bilayers containing either anti-CD3 or ICAM-1, respectively. TCR engagement in Teff was necessary and sufficient for increased PKC-θ recruitment on the basis of a twofold increase in PKC-θ fluorescence intensity on anti-CD3–only bilayers compared with fluorescence on ICAM-1–alone bilayers (Fig. 1, E and F). TCR engagement alone in Treg recruited 11-fold less PKC-θ than in Teff, whereas LFA-1 engagement alone recruited 3.5-fold more PKC-θ than in Teff (Fig. 1, E and F). Thus, TCR triggering in Treg actually down-regulates PKC-θ recruitment to the IS by 7.7-fold compared with basal recruitment by LFA-1 engagement alone (Fig. 1F).

We hypothesized that PKC-θ activation may be part of a negative feedback loop controlling Treg function because TCR signals are essential for Treg function but suppress PKC-θ recruitment. We investigated whether inhibition of PKC-θ with compound 20 (C20) (19) may affect the suppressive function of human CD4+ CD25+ Treg cells. Teff function was measured as cytokine secretion and cell proliferation. C20 treatment of only the Treg cells significantly up-regulated their suppressive ability, even in the presence of CD28-mediated costimulation, but did not induce suppressive activity in treated Teff (Fig. 2, A and B, and fig. S8A). Consistent with imaging data showing that co-stimulation up-regulates the recruitment of PKC-θ to ISs in Treg (fig. S5), untreated Treg demonstrated reduced ability to suppress Teff function in the presence of CD28 antibodies [40% and 25%, respectively (fig. S8A)], and this difference was abrogated by treatment with C20. Inhibition of PKC-θ seemed to increase Treg suppressive function in general, without preference for specific helper T cell type (fig. S8B). C20 also significantly increased Treg function in an APC-dependent assay (fig. S8C).

Fig. 2

PKC-θ inhibition up-regulates the suppressive function of Treg in vitro. Average of four different experiments are shown for all graphs. P values were calculated by t test. (A and B) Treg and Teff were treated with PKC-θ inhibitor C20 at 0.001 to 1 μM for 30 min and washed three times. Treated cells were then mixed with CD4+ CD25 T (Teff) cells at a 1:9 ratio and plated on immobilized monoclonal antibody (mAb) against CD3 (anti-CD3). Error bars indicate standard deviation. (A) The supernatants were analyzed for IFN-γ after 24 hours by enzyme-linked immunosorbent assay (ELISA). (B) Cell proliferation was determined after 96 hours by Alamar Blue (left), or Treg cells were treated with 1 μM C20 for 30 min, washed, mixed with Teff and proliferation was assayed by carboxyfluorescein diacetate succinimidyl ester (CFSE) (right). (C) Treg were treated with 1 μM of C20 for 30 min, washed, and stimulated by anti-CD3, and p65/p50 specific binding to NF-κB consensus sequence was determined by ELISA. O.D., optical density. (D) Treg cells were treated with 1 μM of NF-κB and IκB kinase (IKK) inhibitors and mixed with Teff, and IFN-γ secretion was analyzed as in (A) after 48 hours. DMSO, dimethyl sulfoxide. (E) Treg were treated with 1 μM of C20, mixed with Teff, and cultured on anti-CD3 with or without neutralizing antibodies against TGF-β RII (20 μg/ml). IFN-γ secretion was analyzed as in (A) after 48 hours. (F) Treg were transfected with siRNA targeting PKC-θ or with control siRNA and plated on anti-CD3. After 48 hours, PKC-θ expression was measured by Western blot analysis (top). siRNA-transfected Treg were mixed with CD4+ CD25 T (Teff) cells at 1:9 ratio and plated on immobilized anti-CD3 mAb. The supernatants were analyzed for IFN-γ after 48 hours.

It has been reported that the CD4+ CD25high Treg cells are the most potent suppressors in vitro (20); we therefore sorted CD4+ T cells according to their CD25 expression (fig. S1D), pretreated the sorted Treg with C20, and cocultured the CD4+ CD25int or CD4+ CD25high T cells with target CD4+ CD25 T cells. Although the CD4+ CD25high T cells manifested a greater suppressive activity, pretreatment with C20 significantly enhanced their suppression of interferon-γ (IFN-γ) secretion (fig. S8D). Lastly, the effect of C20 on Treg function was time-dependent; we observed the peak of suppressive function after 30 min of treatment (fig. S8E).

TCR-induced DNA binding of NF-κB p65 and p50 subunits, which indicates NF-κB activation, and the ability to proliferate were greatly reduced by C20 in both Treg and Teff (Fig. 2C and fig. S9). To test whether activation of NF-κB was a critical PKC-θ target in control of Treg activity, we inhibited NF-κB activation by using two different types of inhibitors, and both significantly increased Treg activity (Fig. 2D). Moreover, treatment of Treg with analogs of C20 with different median inhibitory concentration (IC50) values demonstrated that, of the analogs tested, only PKC-θ inhibitors with IC50 ≤ 1 nM significantly up-regulated Treg suppressive function (fig. S10). Lastly, neutralizing antibodies against transforming growth factor–β (TGF-β) receptor II completely blocked the suppressive function of Treg induced by inhibition of PKC-θ either in APC-free or in presence of APC in the coculture (Fig. 2E and fig. S8C), suggesting the possible involvement of TGF-β presented by Treg as a suppressive mechanism. To confirm the conclusion that inhibition of PKC-θ up-regulates the suppressive activity of human Treg, we specifically silenced PKC-θ gene expression by using RNA interference (21). The specific PKC-θ small interfering RNA (siRNA) reduced PKC-θ expression by 80% (Fig. 2F). Moreover, silencing of PKC-θ significantly increased Treg-mediated suppression of IFN-γ secretion by Teff (Fig. 2F). PKC-θ silencing in Teff resulted in the expected down-regulation of IFN-γ secretion and cell proliferation (fig. S11). We concluded that PKC-θ activity induced by TCR signaling mediates a negative feedback loop that reduces the activity of human CD4+ CD25high Treg to suppress cytokine secretion and proliferation of Teff in vitro.

Rheumatoid arthritis (RA) is a chronic autoimmune disorder that results in the destruction of joint architecture (22). Recent studies in RA patients demonstrated that the function of CD4+ CD25high Treg is impaired (5, 6). We used Treg purified from peripheral blood of 25 RA patients with different severities of disease (fig. S12) and found, despite anergic state and comparable Treg numbers to healthy donors (fig. S13A), that RA Treg demonstrated significantly reduced suppression of IFN-γ from autologous CD4+ CD25 Teff (fig. S13B). The loss of function was due to defective intrinsic function of Treg from RA patients and not due to increased resistance of Teff (fig. S13C), consistent with previously published results (5). Treatment with C20 significantly increased the suppressive function of Treg purified from all 25 RA patients (Fig. 3A) to levels comparable to those of healthy donor-derived Treg (30 to 50% inhibition at a Treg/Teff of 1:3, fig. S13B). Moreover, the defective Treg function in RA patients was inversely correlated with the disease active score (DAS score), and the shift in IFN-γ secretion was similar across the disease score spectrum (Fig. 3B). Thus, inhibition of PKC-θ boosts the suppressive function of Treg isolated from RA patients independent of the severity of disease.

Fig. 3

Inhibition of PKC-θ rescues and protects Treg function. (A and B) Freshly purified Treg from healthy donors and RA patients were treated or not with PKC-θ inhibitor C20 for 30 min at 1 μM, washed three times, mixed with CD4+CD25 T cells at ratio 1:3, and plated on immobilized anti-CD3. The supernatants were analyzed for IFN-γ after 24 to 48 hours by ELISA. (C to E) Treg cells from healthy donors were treated with PKC-θ inhibitor C20 [(C) and (E)] or with PKC-θ siRNA (D) as described above and cocultured with CD4+ CD25 T cells with or without TNF-α (50 ng/ml). IFN-γ secretion was determined after 48 hours by ELISA [(C) and (D)], and proliferation was determined after 96 hours (E). Error bars indicate standard deviation. (F) Untreated or TNF-α–treated (50 ng/ml, for 24 hours) Treg were introduced to bilayers with anti-CD3 and ICAM-1, fixed, and imaged by confocal microscopy. Representative images are shown with ICAM-1 (blue), anti-CD3 (red), and PKC-θ (green). Plots show the distribution of endogenous PKC-θ in cells. Each bar shows average of (bottom planes “synapse proximal”/upper planes “synapse distal”) ratio of anti-PKCθ intensity per cell. Data points from three independent experiments are included in the analysis.

Treatment of Treg cells with TNF-α inhibits their activity and down-regulates expression of the Treg master regulator transcription factor Foxp3 (5). We investigated the possibility that elimination of the PKC-θ–mediated negative feedback on Treg function may render Treg resistant to inhibition by TNF-α. As expected, in the presence of TNF-α, Treg displayed significantly reduced inhibition of IFN-γ secretion and proliferation in Teff, and this effect was largely reversed by C20 or PKC-θ–specific siRNA (Fig. 3, C to E, and fig. S14A). Moreover, C20 prevented TNF-α–induced down-regulation of Foxp3 in Treg (fig. S14B). Strikingly, TNF-α treatment induced increased PKC-θ recruitment to IS in Treg by decreasing sequestration at the distal pole (Fig. 3F), consistent with the idea that TCR-activated PKC-θ mediates negative feedback on Treg function that is further enhanced by TNF-α.

Lastly, we determined the ability of C20 to increase Treg function in vivo by using a colitis model in TCRα−/− β−/− mice induced by transfer of the CD4+ CD25 CD45RBhigh Teff cells (23, 24). Treatment of murine Treg with C20 up-regulated their suppressive function in vitro (fig. S15, A and B). Moreover, C20-treated CD4+ CD25+ Treg cells provided significant protection from colitis, as demonstrated by normal weight gain and normal histology of the distal colon in seven of eight mice (Fig. 4, A to C). C20 treatment increased the number of Treg recovered from mesenteric lymph nodes and the spleen (fig. S15C). This protection was significantly greater than that afforded by Treg left untreated (Fig. 4, A to C). Treatment of CD4+ CD25 Teff with C20 before transfer with untreated Teff did not protect mice from colitis (fig. S16). Thus, PKC-θ inhibition significantly increased the suppressive effect of Treg in vivo.

Fig. 4

Treatment with PKC-θ inhibitor up-regulates Treg function in vivo. Colitis was induced in C57BL/10.PL TCRα−/− β−/− mice (31). Disease progression was monitored by (A) body weight loss, (B) colitis score, and (C) histology. Numbers in parentheses indicate number of mice. Combined data of three independent experiments are presented. P values were calculated by t test. PBS, phosphate-buffered saline.

Treg function is crucial to prevent autoimmunity in mice and humans. Although Treg numbers in patients suffering from autoimmune diseases are similar to healthy controls, Treg function is defective, probably caused by negative regulation of Treg by the inflammatory milieu (20). In the present study, we demonstrate that PKC-θ is sequestered in the distal pole of Treg cells in a manner that reduces its recruitment to the IS. Moreover, inhibition of PKC-θ protects both mouse and human Treg against negative effects of TNF-α, which appears to act in Treg by unleashing PKC-θ from the distal pole. In Teff, PKC-θ is part of a strong positive circuit with free access to TCR signalosomes in the IS, NF-κB activation, increased expression of IL-2, proliferation, and survival (17, 25, 26). PKC-θ is not sequestered in the distal pole of Teff, although the negative regulators like Csk binding protein are (27). In contrast, we noted that Treg display increased IS stability, consistent with decreased PKC-θ activity in the IS and attenuated NF-κB activation. The proposed role of NF-κB in inhibition of Treg function is consistent with the system-wide role of this family of transcription factors in promoting inflammation (28). IS stabilization may enhance Treg function on the basis of recent evidence for an important role of IS in Treg effects mediated through dendritic cells (1, 29).

In conclusion, formation of IS induces altered signaling pathways in Treg, which is characterized by reduced recruitment of Src kinases, PKC-θ, and Carma-1 to the IS. Moreover, in Treg, PKC-θ acts as a proinflammatory mediator, and this effect is enhanced by TNF-α. Indeed, Treg treated with C20 displayed enhanced ability to prevent autoimmune colitis and to restore function of Treg from RA patients. Thus, targeting the PKC-θ–mediated negative feedback loop enhances the activity of Treg and makes them resistant to cytokines associated with the inflammatory milieu found in some autoimmune diseases. Thus, inhibition of PKC-θ in Treg may be a valuable component in Treg adoptive immunotherapy to treat autoimmunity and graft versus host disease (30).

Supporting Online Material

www.sciencemag.org/cgi/content/full/science.1186068/DC1

Materials and Methods

Figs. S1 to S16

References

References and Notes

  1. Materials and methods are available as supporting material on Science Online.
  2. This work was funded by NIH through the NIH Roadmap for Medical Research PN2 EY016586 and R01 AI43542 to M.L.D.; a Leukemia and Lymphoma Translational Research grant 6098-09 to B.B. S.K. was supported by the Osaka University Immunology Frontier Research Center. B. Blazer is an ad hoc advisor to Becton Dickinson. Becton Dickinson has purchased licensing rights for the use of Treg cells to prevent alloresponses and autoimmunity. An MTA agreement is required for use of compound 20. M.D. and A.Z.-Z. have applied for patents for the use of compound 20 and RNA interference against PKCθ in adoptive immunotherapy (patent application nos. 61173237 and 61286871).
View Abstract

Navigate This Article