key: cord-0001816-aghh3orn authors: Harris, Tarsha L.; McGargill, Maureen A. title: Drak2 Does Not Regulate TGF-β Signaling in T Cells date: 2015-05-07 journal: PLoS One DOI: 10.1371/journal.pone.0123650 sha: 1b02698e082376846f59c99c449161a7a7eb737f doc_id: 1816 cord_uid: aghh3orn Drak2 is a serine/threonine kinase expressed highest in T cells and B cells. Drak2(-/-) mice are resistant to autoimmunity in mouse models of type 1 diabetes and multiple sclerosis. Resistance to these diseases occurs, in part, because Drak2 is required for the survival of autoreactive T cells that induce disease. However, the molecular mechanisms by which Drak2 affects T cell survival and autoimmunity are not known. A recent report demonstrated that Drak2 negatively regulated transforming growth factor-β (TGF-β) signaling in tumor cell lines. Thus, increased TGF-β signaling in the absence of Drak2 may contribute to the resistance to autoimmunity in Drak2(-/-) mice. Therefore, we examined if Drak2 functioned as a negative regulator of TGF-β signaling in T cells, and whether the enhanced susceptibility to death of Drak2(-/-) T cells was due to augmented TGF-β signaling. Using several in vitro assays to test TGF-β signaling and T cell function, we found that activation of Smad2 and Smad3, which are downstream of the TGF-β receptor, was similar between wildtype and Drak2(-/-) T cells. Furthermore, TGF-β-mediated effects on naïve T cell proliferation, activated CD8(+) T cell survival, and regulatory T cell induction was similar between wildtype and Drak2(-/-) T cells. Finally, the increased susceptibility to death in the absence of Drak2 was not due to enhanced TGF-β signaling. Together, these data suggest that Drak2 does not function as a negative regulator of TGF-β signaling in primary T cells stimulated in vitro. It is important to investigate and discern potential molecular mechanisms by which Drak2 functions in order to better understand the etiology of autoimmune diseases, as well as to validate the use of Drak2 as a target for therapeutic treatment of these diseases. T cells play crucial roles in tumor surveillance and protection against invading pathogens. However, if not properly regulated, T cells can attack normal healthy cells of the body. This defective response may lead to tissue destruction and devastating autoimmune diseases such as type 1 diabetes and multiple sclerosis. Treatments to modify the progression of autoimmune diseases often include immunosuppressant medications that lead to enhanced susceptibility to infections and tumors. Inhibition of Drak2, a serine-threonine kinase, may be an alternative approach to inhibit autoreactive T cells without acting as an immunosuppressant. Drak2 -/mice are resistant to autoimmune disease in mouse models of type 1 diabetes and multiple sclerosis [1, 2] . In both of these disease models, the accumulation of autoreactive T cells in the target organ is significantly reduced in the absence of Drak2. The reduced accumulation of autoreactive T cells is due to an increased susceptibility to death of the Drak2 -/-T cells [2, 3] . Interestingly, despite this increased sensitivity to death in the T cells, the Drak2 -/mice effectively eliminate infectious pathogens and retain the ability to combat tumors as well as wildtype mice [2, [4] [5] [6] [7] . Thus, Drak2 is an ideal protein to target in order to treat autoimmune disorders without compromising immunity to pathogens and tumors. However, the substrates and downstream effects of Drak2 signaling that contribute to autoimmunity require further elucidation to validate its potential as a therapeutic target and to further understand how these autoimmune diseases develop. Drak2 has been shown to interact with several proteins in in vitro recombinant assays and in cell lines. These proteins include myosin light chain [8] , calcineurin homologous protein [9] , Protein kinase D [10] , p70S6 kinase [11] , and TGF-β receptor I (TGF-βRI) [12] . However, most of these interactions have not been confirmed in T cells and therefore, it is not clear which of these interactions may affect autoimmune disease. As TGF-β is a critical suppressor of autoimmunity, the interaction of Drak2 and the TGF-βRI is an intriguing possibility to explain how Drak2 contributes to autoimmunity. TGF-β is a pleiotropic cytokine that elicits numerous effects on various cell types [13] . In T cells specifically, TGF-β inhibits proliferation of naïve T cells, induces development of regulatory T cells, and enhances apoptosis of activated T cells. A recent study proposed that Drak2 functions as a negative regulator of TGF-β signaling by inhibiting the phosphorylation and recruitment of Smad2 and Smad3 to the TGF-βRI in cell lines [12] . Thus, the absence of Drak2 in T cells may render these cells more susceptible to TGF-β signaling, which could prevent autoimmunity. However, it has not been tested if Drak2 functions as a negative regulator of TGF-β in T cells, and consequently, whether Drak2 -/-T cells are more sensitive to TGF-β signaling. Therefore, we investigated whether Drak2 functions as a negative regulator of TGF-β signaling in T cells, and further if the enhanced susceptibility to apoptosis in Drak2 -/-T cells was due to augmented TGF-β signaling. We found that TGF-β signaling via Smad2 and Smad3 was not enhanced in the absence of Drak2 in T cells, and that Drak2 -/-T cells did not exhibit enhanced responses to TGF-β signaling during in vitro assays. These data suggest that Drak2 does not function as an inhibitor of TGF-β signaling in T cells. Moreover, in the absence of TGF-β signaling, Drak2 -/-T cells remained more susceptible to apoptosis, suggesting that the increase in cell death observed in vitro, was not due to enhanced TGF-β-mediated signals. These data provide insight into the role of Drak2 in autoimmune diseases by showing that Drak2 may not suppress TGF-β signaling in T cells, and therefore may contribute to autoimmune disease via other molecular pathways. Mice B6.Drak2 -/mice were previously described and backcrossed 19 generations to C57BL/6 [1] . OT-II mice were obtained from Kristin Hogquist, TGF-βDNRII mice were obtained from Hongbo Chi, C57BL/6, CD451/1, and OT-I mice were purchased from Jackson Laboratories. Mice were held under specific pathogen-free conditions at St. Jude Children's Research Hospital. All studies were reviewed and approved by the St. Jude Animal Ethics Committee under protocol number 486-100303-05/14. St. Jude is AAALAC accredited and complies with all federal, state, and local laws. T cells were purified from the spleen and lymph nodes of mice by FACS sorting with antibodies specific for CD4, CD8, CD25, CD44, and CD62L (eBioscience). Naïve T cells were CD25 -CD44 lo or CD25 -CD44 lo CD62L hi . Cell sorting was performed using the iCyt Reflection or SY3200 Cell Sorters (Sony Biotechnology). Magnetic separation of CD4 + T cells T cells were purified from the lymph nodes of mice by negative selection with biotin-conjugated antibodies specific for B220, CD8, CD11b, DX5, and MHC class II (eBioscience), followed by separation with streptavidin-conjugated magnetic beads (Miltenyi Biotech). Single cell suspensions from in vitro cultures were stained with antibodies specific for CD4, CD8, CD25, CD45.1, and CD45.2 (eBioscience and BioLegend). Cells were analyzed on a FACSCalibur or LSRFortessa (BD Biosciences,). Cell death and viability was determined utilizing Annexin V (BD Biosciences) or Fixable Viability Dye (eBioscience), according to manufacturer's instructions. Analysis was performed with FlowJo software (TreeStar, Inc.). To detect Foxp3 + cells, suspensions were stained with antibodies specific for CD4, CD8, and CD25. Cells were then fixed and permeabilized with the Foxp3/Transcription Factor Staining Buffer Set according to manufacturer's instructions (eBioscience) and stained with anti-Foxp3 antibody (eBioscience). For analysis of phosphorylated Smad2/3, cells were stained with antibodies specific for CD4 and CD8, then fixed with 1X BD Phosflow Lyse/Fix Buffer and permeabilized with BD Phosflow Perm Buffer III according to manufacturer's instructions (BD Biosciences) and stained with anti-pSmad2/3 antibody (BD Biosciences). Tissue culture-treated plates were incubated for one hour with 30μg/ml goat anti-hamster IgG in PBS (Vector Laboratories, Burlingame, CA), then washed and incubated for one hour with 1μg/ml or 2μg/ml anti-CD3 (eBioscience). Plates were washed before addition of cells and 1μg/ ml anti-CD28 (eBioscience). Naïve OT-I CD8 + T cells were sorted and labeled with 5,6-carboxyfluorescein diacetate succinimidyl ester (CFSE) (Molecular probes) at 0.4 μM in pre-warmed PBS (0.1% FCS) for 10 minutes at 37°C, then washed twice with RP10 advanced media (RPMI advanced media, 10% FCS, Hepes, Pen-Strep, L-glutamine, BME, gentamicin). Cells were stimulated in vitro for two days with 100pM OVA 257 peptide-pulsed, CD45.1 splenocytes that were irradiated at 3000 rads. Alternatively, 2 x 10 6 FACS-sorted, naïve OT-I CD8 + T cells were stimulated with 4.5 x 10 6 200 nM OVA 257 peptide-pulsed, CD45.1 splenocytes at 37°C for two days in RP10 advanced media. The cells were harvested, washed, and replated with naïve splenocytes in the presence of 5ng/ml TGF-β (R&D Systems) with or without 20 ng/ml recombinant mouse IL- Naïve OT-II CD4 + T cells were sorted, CFSE labeled, and stimulated in vitro for three days in the presence or absence of 10-fold TGF-β titrations with 10μM OVA 323 peptide-pulsed, irradiated splenocytes. After three days, the cells were harvested and analyzed by flow cytometry. Naïve CD4 + T cells were purified and stimulated with plate-bound anti-CD3 and soluble anti-CD28 for 72 hours with 20ng/ml IL-2 and increasing amounts of TGF-β. Cells were analyzed for Foxp3 expression. Wildtype and Drak2 -/-CD4 + cells were negatively selected with Miltenyi beads and stimulated with 1μg/ml anti-CD3 coated on poly L-lysine-coated coverglass slides and 1μg/ml soluble anti-CD28 for 24 hours. TGF-β was added to some samples for the final 20 minutes. Cells were fixed with 4% methanol-free formaldehyde, permeabilized in 0.1% Triton-X in PBS, washed with PBS, blocked with 1% BSA, and incubated with anti-Smad2 antibody (Cell Signaling) overnight. Cells were stained with Alexa Fluor 647 goat anti-Rabbit, Alexa Fluor 488 Phalloidin, and DAPI (Invitrogen Life Technologies). Images were collected utilizing a Nikon C1Si laser scanning confocal microscope. Spleen and lymph nodes were harvested from wildtype and Drak2 -/mice. Whole splenocytes and FACS-sorted naïve CD4 + and CD8 + T cells were stimulated for two hours with platebound anti-CD3 and anti-CD28 with or without 2 ng/ml TGF-β for one additional hour. Cells were harvested and frozen at -80°C. Frozen cell pellets were lysed (50mM Tris, 150mM NaCl, 1% Triton X-100, 0.5% sodium deoxycholate, 2mM EDTA, 10% glycerol with phosphatase and protease inhibitors (Calbiochem). Protein concentration was determined using a BCA Protein Assay (Thermo Scientific). Equal amounts of protein were denatured in sample buffer (10% SDS, 20% Glycerol, 0.2M Tris HCl, 0.05% Bromophenol Blue), separated by SDS-PAGE, and transferred to PVDF membranes for immunoblot analysis. Given that recent experiments in cell lines suggested that Drak2 negatively regulates TGF-β signaling [12] , and enhanced TGF-β signaling in T cells could contribute to the resistance to autoimmune disease, we tested whether Drak2 functions as a negative regulator of TGF-β signaling in T cells. TGF-β receptor engagement results in the phosphorylation of the Smad2/Smad3 signaling complex, which then translocates from the cytoplasm into the nucleus to facilitate TGF-β-mediated transcription. To determine if Smad2 translocation into the nucleus was increased in the absence of Drak2, we activated CD4 + T cells with anti-CD3 and anti-CD28 antibodies for 24 hours, and then utilized confocal fluorescent microscopy to analyze Smad2 localization following addition of TGF-β. As expected, Smad2 translocation into the nucleus was not observed in stimulated T cells without exogenous TGF-β (Fig 1) . The addition of TGF-β during the final 20 minutes of culture elicited Smad2 translocation into the nuclear region of both wildtype and Drak2 -/-T cells (Fig 1) . Importantly, there were no differences in Smad2 translocation between wildtype and Drak2 -/-T cells in response to exogenous TGF-β. We also examined phosphorylation of Smad2 by western blot in lysates from purified CD4 + T cells, CD8 + T cells, or whole splenocytes. In all cell types, Smad2 was phosphorylated in response to TGF-β treatment; however, the extent of phosphorylation was not increased in Drak2 -/cells compared to wildtype cells (Fig 2a) . Finally, to determine if Drak2 -/cells are hypersensitive to lower concentrations of TGF-β, we analyzed the phosphorylation of the Smad2/ Smad3 complex by flow cytometry in response to decreasing amounts of TGF-β. Again, even at the lower doses of TGF-β, the phosphorylation of Smad2/3 was similar in wildtype and Drak2 -/cells (Fig 2b) . Together, these data show that Drak2 -/-T cells do not exhibit enhanced TGF-β signaling via Smad2 or Smad2/3 complex phosphorylation compared to wildtype T cells, suggesting that Drak2 does not function as a negative regulator of TGF-β signaling in primary T cells activated in vitro. Many of the downstream mechanisms utilized by TGF-β to regulate T cells remain unclear. Although we did not observe enhanced TGF-β signaling in Drak2 -/-T cells via Smad proteins, it was possible that Drak2 regulated the pathway through alternative mechanisms. Therefore, we explored the effects of TGF-β on several T cell functions in vitro. TGF-β suppresses T cell receptor-induced proliferation of naïve T cells in vitro [14] . Thus, we examined if naïve Drak2 -/-T cells were more sensitive to TGF-β-mediated inhibition of proliferation than naive wildtype T cells. Naïve OT-II and OT-II.Drak2 -/-CD4 + T cells were stimulated with OVA 323pulsed splenocytes in the presence or absence of TGF-β, and analyzed for proliferation. The number of live, divided CD4 + T cells decreased in response to TGF-β (Fig 3a) . However, the effect of TGF-β inhibition was comparable between OT-II and OT-II.Drak2 -/-T cells. We also tested the effect of TGF-β on proliferation of naïve CD8 + T cells, by stimulating OT-I and OT-I.Drak2 -/-T cells with OVA 257 -pulsed splenocytes in the presence of TGF-β. Similar to CD4 + T cells, the number of live, divided CD8 + T cells decreased in response to TGF-β, and the amount of suppression was similar between OT-I and OT-I.Drak2 -/-T cells (Fig 3b) , again suggesting that TGF-β signaling was not enhanced in the absence of Drak2. TGF-β can abrogate survival signals provided by IL-15, but not those elicited by IL-2 and IL-7 in expanding CD8 + T cells [15] . To determine if TGF-β function in response to opposing cytokines is altered in the absence of Drak2, we explored the antagonistic effects of TGF-β on cell recovery and survival of activated CD8 + cells. OT-I and OT-I.Drak2 -/cells were stimulated with OVA 257 -pulsed splenocytes for two days. Cells were then washed and cultured with exogenous IL-2, IL-7, or IL-15 with or without TGF-β for an additional four days. The addition of TGF-β decreased the number of live CD8 + T cells compared to culture in media alone (Fig 4a) . Adding IL-2, IL-7, and IL-15 enhanced the recovery of live CD8 + T cells compared to culture in media alone. The addition of TGF-β masked the increased recovery in response to IL-15, but not IL-2 and IL-7. Decreased cell recovery in response to TGF-β compared to culture in media alone correlated with an increase in the proportion of Annexin V + apoptotic cells (Fig 4b) . The addition of TGF-β abrogated the survival effects of IL-15, but did not alter the anti-apoptotic effects of IL-2 and IL-7. However, the ability of TGF-β to oppose the effects of IL-15, but not IL-2 and IL-7 was comparable between OT-I and OT-I.Drak2 -/-T cells, suggesting that these TGF-β-mediated effects are not enhanced in the absence of Drak2. These data further indicate that TGF-β signaling and function is not increased in Drak2 -/-T cells compared to wildtype T cells following in vitro stimulation. Another function of TGF-β is the induction of peripheral regulatory T cells [16] . As regulatory T cells are critical to prevent autoimmune diseases, we explored if there were alterations in TGF-β-mediated differentiation of induced regulatory T cells. Naïve wildtype and Drak2 -/-CD4 + T cells were purified and stimulated in vitro with anti-CD3, anti-CD28, and IL-2, with increasing amounts of TGF-β (Fig 5) . The addition of TGF-β increased Foxp3 expression, indicative of regulatory T cell induction. However, we did not observe an enhanced induction in the A) CD4 + CD25 -CD44 lo naïve cells were purified from wildtype and Drak2-/-mice and stimulated with 1μg/ml anti-CD3 and 1μg/ml anti-CD28 with 20ng/ml IL-2 alone or plus 10-fold TGF-β titrations for 3 days. The A) percent and B) number of Foxp3 + cells of electronically gated CD4 + cells is shown. There was no significant difference in the response of the wildtype and Drak2-/-cells according to the Mann-Whitney U-test. percent (Fig 5a) or number (Fig 5b) of Foxp3 + CD4 + cells in the absence of Drak2. These data also suggest that TGF-β functions similarly in wildtype and Drak2 -/-T cells that were activated in vitro. Therefore, Drak2 may not act as a negative regulator of TGF-β signaling in T cells. We previously showed that Drak2 -/-T cells exhibit enhanced susceptibility to death in vivo, which promotes resistance to type 1 diabetes and multiple sclerosis [2] . In addition, we found that following in vitro stimulation with anti-CD3 and anti-CD28, a greater proportion of Drak2 -/-T cells were apoptotic compared to wildtype T cells (Fig 6a and 6b , left portion of Drak2 and TGF-β Signaling in T Cells graph). Although we did not observe differences in TGF-β signaling in the absence of Drak2, there may be alternative TGF-β-mediated effects on T cell survival. Thus, we sought to determine if the survival defect in Drak2 -/-T cells compared to wildtype T cells was due to enhanced TGF-β signaling. To test this, we compared T cell survival between wildtype and Drak2 -/-T cells that exhibit impaired TGF-β signaling due to expression of a dominant-negative TGF-β receptor II (DNRII) transgene. The DNRII transgene is a kinase-dead mutant that blocks signaling through the endogenous TGF-β receptor by competing for TGF-β binding [17] . Naïve CD4 + and CD8 + T cells were sorted from wildtype, Drak2 -/-, DNRII, and DNRII.Drak2 -/mice. The purified T cells were stimulated in vitro with anti-CD3 and anti-CD28. We found that even with the severe reduction in TGF-β signaling, there was an increase in the proportion of nonviable DNRII.Drak2 -/-CD4 + (Fig 6a, right portion of graph) and CD8 + (Fig 6b, right portion of graph) T cells compared to DNRII CD4 + and CD8 + T cells. These data show that the enhanced death in the Drak2 -/-T cells following in vitro stimulation is not due to increased TGFβ signaling, and suggest that alternative signaling pathways play a role. Drak2 contributes to organ-specific autoimmune disease and is an ideal protein to target to treat these diseases without causing generalized immune suppression. Therefore, it is pertinent to understand the molecular and cellular mechanisms by which Drak2 functions in order to further comprehend the etiology of autoimmune disease. In addition, insight into the function of Drak2 is critical to validate it as a therapeutic target. TGF-β is a multifunctional cytokine that controls many aspects of T cell behavior and elicits protective effects in several autoimmune diseases [13] . It has been suggested that Drak2 functions as a negative regulator of TGF-β signaling [12] . As TGF-β can inhibit proliferation, survival, and differentiation of T cells, enhanced TGF-β signaling in Drak2 -/-T cells could contribute to the resistance to autoimmune disease in the Drak2 -/mice via one or more of these mechanisms. However, our data suggest that in primary T cells stimulated in vitro, Drak2 does not function as a negative regulator of this pathway. Smad2/3 signaling after TGF-β stimulation was not enhanced in Drak2 -/-T cells compared to wildtype T cells. Importantly, the impact of TGF-β on T cell behavior was not enhanced in the absence of Drak2 as evidenced by equal inhibition of naïve T cell proliferation, comparable effects on activated CD8 + T cell accumulation and survival, and similar induction of regulatory T cells in wildtype and Drak2 -/-T cells. The previous studies that suggested Drak2 negatively regulates TGF-β signaling were performed in tumor cell lines [12] . It is possible that Drak2 inhibits TGF-β in certain tumor cells, but not in primary T cells. Mutations that lead to tumorigenesis could facilitate a role for Drak2 regulation in TGF-β signaling. Thus, as reported in certain tumors, Drak2 may function to negatively regulate TGF-β signaling and promote tumorigenesis [12] . However, this is contrary to other reports that describe Drak2 as a tumor suppressor [18] [19] [20] . Therefore, the role of Drak2 in different types of tumors is also controversial and needs to be studied further. Interestingly, we have shown that Drak2 -/mice respond similarly to wildtype mice in various in vivo tumor models, again suggesting that the role of Drak2 in cell lines may not mimic its role under physiological conditions [7] . Furthermore, it is important to investigate the molecular mechanisms of Drak2 in primary T cells, as these are the cells relevant to the induction or resistance to autoimmunity. The importance of Drak2 specifically in T cells during autoimmunity was highlighted in our previous studies, which demonstrated that the resistance to disease in the mouse model of multiple sclerosis was due to Drak2-deficiency in T cells [2] . In addition, we found that the resistance to type 1 diabetes was also due to the absence of Drak2 in T cells (TLH and MAM manuscript submitted). Another possible explanation for the discrepancy between our results in primary T cells and the previous data in tumor cell lines is that during development, the Drak2 -/-T cells may have compensated for the loss of Drak2 through modifications of alternate pathways involved in TGF-β regulation. For example, increased levels of Smad7, a negative regulator of TGF-β signaling [21] , could mask alterations in TGF-β signaling in the absence of Drak2. Therefore, Drak2 -/-T cells may exhibit altered signaling pathways that function differently compared to physiological conditions in wildtype T cells, which warrants further investigation. Nevertheless, our data presented here indicate that TGF-β signaling is not enhanced in Drak2 -/-T cells following in vitro stimulation. Consequently, Drak2 may not function as a negative regulator of TGF-β signaling in T cells, which are critical for the induction of autoimmunity. Therefore, further investigation of the potential molecular mechanisms by which Drak2 functions during autoimmune disease is required to gain insight into the etiology of these diseases. A deficiency in Drak2 results in a T cell hypersensitivity and an unexpected resistance to autoimmunity Drak2 regulates the survival of activated T cells and is required for organ-specific autoimmune disease Enhanced T cell apoptosis within Drak2-deficient mice promotes resistance to autoimmunity Drak2 contributes to West Nile virus entry into the brain and lethal encephalitis Anti-viral effector T cell responses and trafficking are not dependent upon DRAK2 signaling following viral infection of the central nervous system DRAK2 regulates memory T cell responses following murine coronavirus infection Drak2 is not required for tumor surveillance and suppression novel serine/threonine kinases related to death-associated protein kinase that trigger apoptosis A serine/threonine kinase which causes apoptosis-like cell death interacts with a calcineurin B-like protein capable of binding Na Protein kinase D orchestrates the activation of DRAK2 in response to TCR-induced Ca2+ influx and mitochondrial reactive oxygen generation Drak2 is upstream of p70S6 kinase: its implication in cytokineinduced islet apoptosis, diabetes, and islet transplantation DRAK2 participates in a negative feedback loop to control TGF-β/Smads signaling by binding to type I TGF-βreceptor TGFbeta signalling in control of T-cell-mediated self-reactivity Distinct effects of TGF-beta 1 on CD4+ and CD8+ T cell survival, division, and IL-2 production: a role for T cell intrinsic Smad3 Opposing effects of TGF-beta and IL-15 cytokines control the number of short-lived effector CD8+ T cells TGF-β: guardian of T cell function Abrogation of TGFbeta signaling in T cells leads to spontaneous T cell differentiation and autoimmune disease Regulation of the apoptosis-inducing kinase DRAK2 by cyclooxygenase-2 in colorectal cancer The MYB oncogene can suppress apoptosis in acute myeloid leukemia cells by transcriptional repression of DRAK2 expression Nuclear localization of the serine/threonine kinase DRAK2 is involved in UV-induced apoptosis Negative regulation of TGF-βreceptor/Smad signal transduction The authors would like to thank the St. Jude Cell and Tissue Imaging Core, the St. Jude Animal Resource Center, Benjamin A. Edwards, and Ashley Castellaw for excellent technical assistance.