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Transmissible spongiform encephalopathies (TSEs) or prion diseases are a group of infectious neurodegenerative diseases that are associated with misfolding of the cellular form of the cellular prion protein (PrPC) into a disease associated conformer (PrPSc). No therapy for prion diseases is available at present. So far, anti-PrPC vaccination is hampered by immunological tolerance of the mammalian immune system to endogenous PrPC. The aim of this thesis was to set up a new vaccination strategy based on virus-like particles (VLP) to induce anti-PrPC antibody responses in PrPC-competent mice. In a first step it was assessed whether VLP have the capacity to induce antibody responses that are protective against conventional pathogens. For this purpose, VLP displaying the vesicular stomatitis virus-gylcoprotein (VLP-VSV) were generated and tested for their immunogenicity. Similarly to live vesicular stomatitis virus (VSV), replication deficient VLP-VSV induced T help-independent VSV neutralizing IgM responses that switched to the IgG subclass in a T help-dependent manner. Furthermore, type I IFN receptor (IFNAR) triggering only marginally affected VLP-VSV induced neutralizing IgM responses, whereas it was critically required to promote the IgG switch. The analysis of conditional knockout mice with a lymphocyte-specific IFNAR deletion revealed that IFNAR triggering of lymphocytes did not play a crucial role, neither upon VLP-VSV nor VSV immunization. Collectively, these data verified the high immunogenicity of VLP. Therefore, in a next step VLP were generated displaying the C-terminal half of PrP (residues 121-231aa) fused to the platelet derived growth factor receptor (PDGFR) transmembrane region (VLP-PrPD111) for anti-PrPC immunization. On the surface of such retroparticles, PrPC was expressed at high levels as determined by electron microscopy. VLP-PrPD111 immunization of Prnp-deficient (Prnp0/0) mice resulted in antibody response specifically binding the cellular form of PrPC. Upon intravenous injection of wild-type mice, high PrPC-specific IgM responses were induced, whereas the T cell-dependent switch from the IgM to the IgG subclass was less pronounced. As a consequence, anti-PrPC titers were rather short-lived. The impaired subclass switch was probably related with host T cell tolerance to endogenous PrPC. Attempts to increase anti-PrPC IgG responses in wild-type mice via administration of VLP-PrPD111 emulsified in various different adjuvants failed. Nevertheless, in single individuals low IgG antibodies were induced after immunization of VLP-PrPD111 emulsified in CFA. To circumvent T cell tolerance in wild-type mice, a multitude of different immunization strategies was tested, including priming and boosting protocols with different types of VLP or VLP expressing PrPC together with foreign T helper epitopes. Overall, those efforts did not improve anti-PrPC IgG responses in wild-type mice. Interestingly, anti-PrPC antibodies induced in Prnp0/0 mice reduced PrPSc levels in prion infected cell cultures, whereas serum of vaccinated wild-type mice did not. To assess the protective capacity of VLP-PrPD111 induced immune responses, vaccinated wild-type mice were infected with scrapie (RML 5.0). Unfortunately, vaccinated mice did not show a significant delay in the onset of scrapie. In a last part of the thesis it was studied whether in the absence of T cell help activated “memory” B cells were able to produce anti-PrPC specific antibodies. To address this question, PrPC-specific memory B cells were sorted from vaccinated Prnp0/0 mice and adoptively transferred into wild-type recipient mice. Upon VLP-PrPD111 challenge, no PrPC-specific IgG titers were induced in the recipients. Nevertheless, several VLP-PrPD111 challenged recipient mice were protected against scrapie infection. In conclusion, VLP were characterized as highly immunogenic vaccines that were used to elucidate various questions concerning adaptive immune response and basic mechanisms of PrPC-specific tolerance vs. immunity. Remarkably, VLP-PrPD111 was able to induce native PrPC-specific antibodies in wild-type mice but major difficulties associated with PrPC-specific tolerance made efficacious scrapie vaccination impossible. New vaccination approaches are being tested to overcome these limitations.
A small percentage (1-5%) of the blood lymphocytes expresses alternative T-cell antigen receptor that uses g and d TCR rearranging genes. A subset of them expresses the Vg9Vd2 TCR. Those cells respond to self-nonpeptide and foreign antigens presented by unknown antigen-presenting molecules. Vg9Vd2 T cells also express Toll-like receptors and natural killer receptors that allow them to respond to other nonpeptide microbial components or to alterations in the expression of stress cell surface ligands such as NKG2D ligands. Vg9Vd2 T cells frequently are regulated by the expression of activating and/or inhibitory NKRs (iNKRs) that can fine-tune their activation threshold and the activating NKG2D receptor is one of the most studied until now. NKG2D, a C-type lectin receptor directed against MICA/MICB and UL16-binding protein (ULBP) molecules, have been reported a powerful co-stimulus for Ag-mediated activation of CD8 and Vg9Vd2 T cells. Indeed, NKG2D is recruited within the Vg9Vd2 TCR immunological synapse and enhances recognition by Vg9Vd2 T cells of Mycobacteria-infected DCs and various MICA/MICB or ULBP hemopoietic and non-hemopoietic tumors. The level of NKG2D is upregulated by inflammatory cytokines (e.g. IL-15), and NKG2D ligands are induced after a physical or genotoxic stress and/or along infection by intracellular pathogens. Therefore, NKG2D is a key stress sensor that strongly enhances recognition of altered or infected self by human gd T cells. Recent progress in the field supports the idea that gd T cells fulfill a role in the innate and adaptative immune response in different way of the conventional ab T cells. We demonstrated direct activation of Vg9Vd2 T cells by NKG2D ligation through the association with DAP10 adapter molecules and independently of TCR-Ag recognition, similar to the NKG2D-mediated activation of NK cells. Culture of peripherical blood mononuclear cells with immobilized NKG2D mAb or NKG2D ligand MICA induces up-regulation of CD69 and CD25 in NK and Vg9Vd2 T cells but not in CD8 T cells. Additionally, the ligation of NKG2D induces in Vg9Vd2 T cells the up-regulation of molecules typical for antigenpresenting cells, such as co-stimulator molecules (CD86) antigen presenting molecules (CD1a, HLA-DR), adhesion molecules (CD54), and activation molecules (CD69). Furthermore, NKG2D ligation in Vg9Vd2 T cells induces the production of cytokines such as TNF-a and chemokines such as, MIP-1a, but cannot induce the production of cytokines such as IL-6 or IFN-g and chemokines such as RANTES, MCP-1 and GM-CSF. In addition, NKG2D triggers the activation of the cytolytic machinery as efficient as CD3 stimulation as shown by measurement of the release of granules with esterase activity (BLT assay), perforin and the up-regulation of CD107a on the surface of Vg9Vd2 T cells. This NKG2D dependent cytolysis has been confirmed using purified Vg9Vd2 T cells, which kill MICA-transduced RMA cells but not the control cells. The TCR independence and NKG2D dependence of this killing is supported by mAb inhibition experiment. Finally, DAP 10, which mediates NKG2D signaling of human NK cells, is found in resting and activated Vg9Vd2 T cells. Moreover, data of intracellular signaling studies suggest an important role of Scr kinases in the NKG2D mediated killing and involvement of DAP-10-PI3K and PLCg 1 pathways as mayor proteins implicated in target cell lysis, and shows remarkable difference with the TCR signaling. The identification of these similarities in NKG2D function between NK and Vg9Vd2 T cells may be of interest for development of new strategies for Vg9Vd2 T cell-based immunotherapy in certain types of cancer and help to understand Vg9Vd2 T cell function in general.
The steroid hormones corticosterone/cortisol and aldosterone are synthesized and secreted by the adrenal gland in response to stress or an altered salt-water balance. This is controlled by a negative feedback mechanism referred to as the HPA axis and the RAAS. Actions of these steroid hormones are mediated by the glucocorticoid receptor (GR) and the mineralocorticoid receptor (MR), which reside in the cytoplasm in a complex with heat-shock proteins. Both, the GR and the MR belong to the nuclear receptor superfamily and share a common protein structure consisting of three separate domains. However, they have different affinities for various ligands, their actions depend on hormone concentration, they are modulated by pre-receptor mechanisms such as the 11β-HSD2 and they are differently distributed in several tissues. Aldosterone acts via the MR in epithelial and in non-epithelial cells and regulates sodium-water homeostasis, cardiovascular function, neuronal excitability and adipocyte differentiation. So far the analysis of gene inactivation in vivo was limited to mice, but disease models in rats sometimes more closely reflect the situation encountered in humans. Since embryonic stem cells and thus gene targeting in rats is not available, we generated MR knock-down transgenic rats by lentiviral delivery of a shRNA. The F1 progeny of the founder rats showed a wide range of reduced MR mRNA and protein levels in kidney and hippocampus, the two major sites of MR expression. In contrast, expression of the highly homologous GR was unaltered, indicating specificity of gene inactivation. The two MR target genes, Sgk1 and ENaC, were up-regulated while the mRNA levels of other genes such as IK1 and SCD2 was reduced. Similar to the knock-out mice and human patients, the knock-down rats displayed typical signs of pseudohypoaldosteronism type I such as increased serum levels of aldosterone and renin as well as growth retardation. Importantly, we found a linear relationship between MR mRNA expression in kidney, serum aldosterone levels and body weight. Thus, our MR knock-down rats are amongst the first examples of RNAi in vivo and confirm that this technique allows to accomplish graded levels of gene inactivation that mimick human genetic diseases. Secondly, we investigated the role of the GR and the MR for the immunomodulatory activities of glucocorticoids (GCs) in peritoneal macrophages. GCs are involved in the modulation of macrophage function and thereby control the host’s immune responses to pathogens. Therefore, GCs are widely used for the treatment of inflammation and autoimmune diseases. However, concerning these GC activities neither the role of hormone concentration nor the differential contribution of the GR and the MR are known. At first we confirmed that both receptors but not 11β-HSD2 are expressed in peritoneal macrophages. Next, we showed that low levels of corticosterone enhance NO production as well as mRNA expression of pro-inflammatory cytokines, chemokines and enzymes required for mediator synthesis. In contrast, at high corticosterone concentrations macrophage function was strongly repressed. Importantly, inactivation of the GR by lentiviral delivery of siRNAs abrogated both the immunostimulatory and the immunosuppressive GC actions whereas inactivation of the MR had no effect. Furthermore, removal of endogenous GCs by adrenalectomy in vivo induced a pre-activated state in macrophages that could be modulated by corticosterone. We conclude that GCs exert distinct effects on macrophage function dependent on their concentration, and that they act through the GR despite concomitant expression of the MR. In summary, our results confirm that lentiviral delivery of shRNAs is an efficient means to down-regulation gene expression in primary cells and transgenic rats and thereby allows to perform functional studies on gene function that were previously limited to mice.
Effects of desialyation on TCR-cross-linking and antigen sensitivity of CD8 positive T lymphocytes
(2005)
The featured experiments focus on changes in T cell membrane glycosylation as a possible means of controlling TCR cross-linking. Taking the long known fact that activated T cells show decreased levels of surface sialic acid as a starting point, differences in ligand binding and cellular reaction upon in vitro stimulation were investigated in naïve, activated and enzymatically desialyated CD8+, 2C TCR transgenic mouse lymphocytes. To detect differences in ligand binding lymphocytes were incubated with various concentrations of fluorescently labeled, soluble MHC/Ig fusion proteins until equilibrium was reached. Without previous washing, cells were analyzed by flow cytometry, determined MCF values were normalized to the plateau and fit to a mathematical model of equilibrium binding of divalent ligands to monomorphic receptors (Perelson 1984). Parameters derived from the model fit of binding data show, that neuraminidase treatment of T cells was sufficient to mimic a partially activated phenotype, showing enhanced TCR cross-linking. Enhanced TCR cross-linking was found to be dependent on the presence of CD8, as neuraminidase treatment of DN cells lead to decreased cross-linking. To elucidate the physiological relevance of desialyation induced increases in TCR cross-linking early tyrosine phosphorylation events and proliferative response upon in vitro stimulation of T cells were investigated. Both were found enhanced in neuraminidase treated cells, as compared to native cells. In conclusion the featured experiments suggest a role of surface sialic acid in controlling TCR cross-linking on naïve and activated T cells.
Visualization of type I immunity using bicistronic IFN-gamma reporter mice in vitro and in vivo
(2006)
IFN-γ is the signature cytokine of Th1 and CD8+ effector cells generated in type I immune responses against pathogens, such as Influenza virus, Sendai virus and the intracellular protozoan parasite Toxoplasma gondii. Understanding the regulation of IFN-γ is critical for the manipulation of immune responses, prevention of immunopathology and for vaccine design. In the present thesis, IFN-γ expression by CD4+ and CD8+ T cells was characterized in detail and the requirement of IFN-γ receptor mediated functions for IFN-γ expression was assessed. Bicistronic IFN-γ-eYFP reporter mice, which allow direct identification and isolation of live IFN-γ expressing cells, were used to visualize IFN-γ expression in vitro and in vivo after infection with the afore mentioned pathogens. Expression of the IFN-γ-eYFP reporter by CD4+ and CD8+ T cells was broadly heterogeneous in vitro and in vivo after infection. Increased expression of the reporter correlated positively with the abundance of IFN-γ transcripts and IFN-γ protein production upon stimulation. eYFP reporter brightness reflected the potential for IFN-γ production, but actual secretion was largely dependent on antigenic stimulation. Increased expression of the reporter also correlated with enhanced secretion of additional proinflammatory cytokines and chemokines and cell surface expression of markers that indicate recent activation. Highly eYFP fluorescent cells were generally more differentiated and their anatomical distribution was restricted to certain tissues. The anatomical restriction depended on the pathogen. IFN-γ expressing CD4+ and CD8+ T cells were generated in IFN-γ receptor deficient reporter mice after infection with Sendai virus or Toxoplasma gondii. However, in the absence of IFN-γ receptor mediated functions, the frequency and brightness of the eYFP reporter expression was altered. Dual BM chimeric mice, reconstituted with wild-type and IFN-γ receptor deficient reporter BM, revealed a T cell-intrinsic requirement for the IFN-γ receptor for optimal IFN-γ expression. Reporter fluorescence intensities were regulated independently of IFN-γ receptor mediated functions. Finally, we propose a model for IFN-γ expression by CD4+ and CD8+ T cells. 2. SUMMARY 10 In summary, the expression of IFN-γ is differentially regulated in CD4+ and CD8+ T cells and after viral or protozoan infections. Additionally, the role of IFN-γ receptor mediated functions for the expression of IFN-γ was determined.
Glucocorticoids (GCs) are small lipophilic compounds that mediate a plethora of biological effects by binding to the intracellular glucocorticoid receptor (GR) which, in turn, translocates to the nucleus and directly or indirectly regulates gene transcription. GCs remain the cornerstone in the treatment for a number of hematological malignancies, including leukemia, lymphoma and myeloma. Extensive literature suggests that the efficacy of GCs stems from their ability to mediate apoptosis. Despite the enormous strides made in our understanding of regulated cell death, the exact mechanism by which GCs cause apoptosis is still unknown. The data obtained so far provide strong evidence that gene transactivation by the GR underlies the initiation phase of GC-induced thymocyte apoptosis. Furthermore, the multicatalytic proteasome, several members of the Bcl-2 family, changes in calcium flux as well as caspases have been identified as important players in the execution phase of GC-mediated cell death. However, the exact sequence of events in this process still remains elusive. A major problem of the current discussion arises from the fact that different cell types, such as thymocytes, peripheral T cells and lymphoma cells are compared without acknowledging their different characteristics and gene expression profiles. Although it is generally assumed that GCs induce apoptosis via a conserved mechanism, this is not supported by any data. In other words, it is possible that thymocytes, peripheral T cells and lymphoma cells may undergo cell death along different pathways. We therefore wondered whether a unique signal transduction pathway is engaged by GCs to initiate and execute cell death in all types of T lymphocytes or whether distinct pathways exist. Therefore, we compared the role of the proteasome, various caspases, the lysosomal compartment and other factors in GC-induced apoptosis of murine thymocytes and peripheral T cells as well as T-ALL lymphoma cells. Our findings show that the initiation phase of GC-induced apoptosis is similar irrespective of the differentiation state of the cell. Apoptosis in both thymocytes and peripheral T cells is mediated by the GR and depends on gene transcription. In contrast, the execution phase significantly differs between thymocyte and peripheral T cells in its requirement for a number of signal transduction components. Whilst in thymocytes, the proteasome, caspases 3, 8 and 9 as well as cathepsin B play an important role in GC-induced apoptosis, these factors are dispensable for the induction of cell death in peripheral T cells. In contrast, changes in the expression and intracellular location of Bcl-2 family members do not appear to contribute to GC-induced apoptosis in either cell type. Importantly, our observation that GC treatment of thymocytes leads to an activation of the lysosomal protease cathepsin B and that this is an essential step in the induction of cell death by GCs, is the first indication that a lysosomal amplification loop is involved in this process. Analysis of GC-induced apoptosis in several T-ALL cell lines further indicates that the signaling pathway induced by GCs in thymocytes but not in peripheral T cells is shared by all lymphoma cell-types analyzed. Given the therapeutic importance of high-dose GC-therapy for the treatment of hematological malignancies, this finding could potentially form a basis for new anti-cancer strategies in the future, which specifically target tumor cells whilst leaving peripheral T cells of patients untouched.
Regulation of B lymphocyte terminal differentiation and death by the transcription factor Blimp-1
(2005)
B lymphocyte induced maturation protein-1 (Blimp-1) and X-box-binding protein-1 (XBP-1) are indispensible transcription factors required for B lymphocyte terminal differentiation into Ig secreting plasma cells. Occurrence of an unfolded protein response (UPR) and XBP-1 splicing, due to elevated Ig levels, are critical events during plasma cell generation. However, the upstream molecule sufficient to trigger these events remain elusive. Because ectopic expression of Blimp-1 in B cells is sufficient to generate plasma cells, it is plausible that Blimp-1 might be the upstream molecule, sufficient for the induction of UPR and XBP-1 splicing. The results from the current study indicate that ectopic expression of Blimp-1 or its N-terminal domain, in B cells, is sufficient to induce XBP-1 splicing, UPR and Ig (immunoglobulin) secretion. Further more Blimp-1 is able to directly repress the antiapoptotic gene A1, by binding to specific DNA elements in A1 promoter. This repression of A1 by Blimp-1 seems to be an important prerequisite for Plasma cell differentiation because ectopic expression of A1 in primary B cells resulted in reduced immunoglobulin secretion.
In this project two novel murine autoimmune models were to be established in an attempt to further investigate the nervous system disorders of Multiple Sclerosis and Guillain Barré Syndrome. Previous experimental autoimmune encephalomyelitis (EAE) and experimental autoimmune neuritis (EAN) models have demonstrated that T cells play a major role in these diseases. Which roles CD4 and CD8 T cells specifically have in the initiation, propagation and termination of an autoimmune nervous system disorder remains controversial. To this end two transgenic mice specifically expressing the neo-antigen (Ag) ovalbumin (OVA) in either the central nervous system (CNS) or peripheral nervous system (PNS) were to be generated. The myelin basic protein (MBP) is a major component of the myelin sheath both within the CNS and the PNS. Therefore the MBP promoter was employed for its distinct regulatory elements to facilitate exclusive CNS or PNS OVA expression. The adoptive transfer of OVA specific MHCI restricted (OT-I) and MHCII restricted (OT-II) TCR Tg T cells extended the OVA Tg mouse model by allowing potentially encephalitogenic T cells to be tracked in vivo. Specificity for the target Ag should enable the dynamic role of antigen specific T cells in neuroinflammatory diseases to be revealed in more detail.
Protein kinase B (PKB), a serine threonine kinase, is highly involved in the regulation of cellular proliferation and survival. To characterize PKB’s function in lymphocyte development and activation, transgenic (tg) mice that express a membrane targeted constitutively active form of PKBa (myr PKB) in T and B cells were analysed. Thymocytes from myr PKB tg mice showed enhanced proliferation after T cell receptor (TCR) engagement compared to wild type (wt) mice. Astonishingly, myr PKB tg thymocytes were capable to proliferate in response to PMA only and were also less sensitive to inhibition by the calcineurin inhibitors CsA or FK506, which indicates the proliferative response of myr PKB tg T cells is relatively independent of calcium mobilisation and calcineurin activity. In addition, when TCR signalling was inhibited by the MEKinase inhibitor PD98059 or the Srckinase inhibitor PP1 myr PKB tg thymocytes again were more resistant to inhibition. Western blot analysis revealed myr PKB enhances activation of the kinases Lck, Raf and Erk after TCR/CD3 stimulation. Thus, myr PKB renders proliferative responses of thymocytes more sensitive to TCR signals by positive regulation of the Lck-Raf-MEK-Erk signalling pathway. Studies on the cellular location of the tg protein showed myr PKB is located in membrane socalled “lipid rafts”. Furthermore, we found that after TCR/CD3 ligation endogenous cytoplasmic PKB moves into “lipid rafts”, which highlights PKB as a crucial mediator of TCR proximal signalling events. Analysing three different TCR tg model systems for positive and negative selection of immature precursors in the thymus, we found myr PKB promotes positive selection of CD4+ but not CD8+ T cells. This most likely results from PKB’s positive cross-talk on Lck-Raf-Erk signalling, which is known to influence thymocyte selection and CD4/CD8-lineage choice. Furthermore, myr PKB enhances phosphorylation of glycogen synthase kinase 3 (GSK3), a negative regulator of the transcription factor NFAT (nuclear factor of activated T cells) and T cell activation, and of the adapter protein c-Cbl. Concerning negative selection, myr PKB enhanced (OT1 mice), reduced (HY mice) or had no influence (OT2 mice) on negative selection. Thus, myr PKB’s effect on negative selection strongly depends on the model system analysed and this most likely results from differences in TCR affinity/avidity and TCR specificity for MHC. 106 Peripheral CD4+ T cells from myr PKB tg mice showed enhanced production of both Th1 and Th2 cytokines. Furthermore, after TCR/CD3 stimulation in the presence of TGF-b1, wt CD4+ T cells showed a drastic inhibition of proliferation, whereas myr PKB tg CD4+ T cells proliferated even better, i.e. they were resistant to the inhibitory TGF-b1 signals. Expression of myr PKB in B cells leads to reduced Ca2+ flux and proliferation after BCR stimulation, but activation of Lyn, SLP-65, c-Cbl and GSK-3 were enhanced. When we analysed B cell subsets in myr PKB tg mice, a decrease in immature and mature B cells became obvious, whereas cell numbers for marginal zone (MZ) B cells were normal. In aged myr PKB tg mice we detected a very strong reduction of pro/pre and immature B cell populations in the bone marrow, indicating PKB is very important for maintenance of B cell development. Furthermore, myr PKB also lead to a strong reduction of peritoneal B-1 cells. However, expression of NFATc1, which is required for B-1 cell development, was comparable between wt and myr PKB tg B-1 cells. To analyse the effect of myr PKB on immunoglobulin production, mice were immunized with thymus dependent (TD) and independent (TI) antigens. In both cases, B cell responses were strongly elevated in myr PKB tg mice. Finally, RT-PCR analyses of in vitro expanded B cells revealed increased Blimp-1 and Notch3 expression in myr PKB tg B cells, which might be primary candidates involved in their enhanced effector function. In summary, this study clearly shows an important cross-talk between PKB and various critical signalling molecules downstream of the TCR and BCR. Thereby active PKB modulates and regulates the thresholds for thymocyte selection and T cell activation as well as for B cell development and function.
To analyze the role of protein kinase B(PKB)on developmental and functional aspects of T cells, we have generated transgenic mouse lines expressing a constitutively active form of PKB (myrPKB) in early stages of T cell development.Peripheral CD4+ T cells from PKB tg mice are hyperreactive, more efficient in producing th1 and th2 cytokines and show faster and CD28 co-stimulation independent cell cycle progression.Interestingly PKB tg T cells are resistant to CsA treatment in proliferation and cytokine production.Further analysis show PKB tg CD4+ T cells have a drastically reduced nuclear translocation of NFAT proteins and this is due to a direct interaction between PKB and NFAT. To study whether the negative regulatiopn of NFATs by PKB affects T cell development, we analyzed double tg mice expressing both, a constitutively active version of calcineurin (dCam) and myrPKB. dCam tg mice have a severe block in thymocyte development at the DN3 stage.But in the dCam/PKB double tg mice this developmental block is significantly rescued.This rescue of thymocyte development by PKB is due to the expression of RAG1 and subsequent TCRb chain expression. CsA treatment of neonatal thymic lobes from dCam mice restores normal thymocyte development, indicating involvement of NFATs in the severe block in dCam thymocyte development.Confocal studies clearly established that compared to dCam DN cells there is a significant reduction in the nuclear levels of NFATc1 and NFATc3 in dCam/PKB cells.Downregulation of nuclear NFAT levels by myrPKB thus seems to be an essential parameter in dCam cells to proceed with normal differentiation. In summary, the data from PKB tg peripheral CD4+ T cells and dCam/PKB double tg thymocytes clearly establish PKB as an important modulator of T cell development and function and PKB as a novel negative regulator of NFAT activation.