Erin H. Plisch

Signal integration by Akt regulates CD8 T cell effector and memory differentiation.

During a T cell response, the effector CTL pool contains two cellular subsets: short-lived effector cells (SLECs), a majority of which are destined for apoptosis, and the memory precursor effector cells, which differentiate into memory cells. Understanding the mechanisms that govern the differentiation of memory CD8 T cells is of fundamental importance in the development of effective CD8 T cell-based vaccines. The strength and nature of TCR signaling, along with signals delivered by cytokines like IL-2 and IL-12, influence differentiation of SLECs and memory precursor effector cells. A central question is, how are signals emanating from multiple receptors integrated and interpreted to define the fate of effector CTLs? Using genetic and pharmacological tools, we have identified Akt as a signal integrator that links distinct facets of CTL differentiation to the specific signaling pathways of FOXO, mTOR, and Wnt/β-catenin. Sustained Akt activation triggered by convergent extracellular signals evokes a transcription program that enhances effector functions, drives differentiation of terminal effectors, and diminishes the CTLs’ potential to survive and differentiate into memory cells. Whereas sustained Akt activation severely impaired CD8 T cell memory and protective immunity, in vivo inhibition of Akt rescued SLECs from deletion and increased the number of memory CD8 T cells. Thus, the cumulative strength of convergent signals from signaling molecules such as TCR, costimulatory molecules, and cytokine receptors governs the magnitude of Akt activation, which in turn controls the generation of long-lived memory cells. These findings suggest that therapeutic modulation of Akt might be a strategy to augment vaccine-induced immunity.

FoxO1 Controls Effector-to-Memory Transition and Maintenance of Functional CD8 T Cell Memory

During a T cell response, naive CD8 T cells differentiate into effector cells. Subsequently, a subset of effector cells termed memory precursor effector cells further differentiates into functionally mature memory CD8 T cells. The transcriptional network underlying this carefully scripted process is not well understood. In this study, we report that the transcription factor FoxO1 plays an integral role in facilitating effector-to-memory transition and functional maturation of memory CD4 and CD8 T cells. We find that FoxO1 is not required for differentiation of effector cells, but in the absence of FoxO1, memory CD8 T cells displayed features of senescence and progressive attrition in polyfunctionality, which in turn led to impaired recall responses and poor protective immunity. These data suggest that FoxO1 is essential for maintenance of functional CD8 T cell memory and protective immunity. Under competing conditions in bone marrow chimeric mice, FoxO1 deficiency did not perturb clonal expansion or effector differentiation. Instead, FoxO1-deficient memory precursor effector cells failed to survive and form memory CD8 T cells. Mechanistically, FoxO1 deficiency perturbed the memory CD8 T cell transcriptome, characterized by pronounced alterations in the expression of genes that encode transcription factors (including Tcf7), effector molecules, cell cycle regulators, and proteins that regulate fatty acid, purine, and pyramidine metabolism and mitochondrial functions. We propose that FoxO1 is a key regulator that reprograms and steers the differentiation of effector cells to functionally competent memory cells. These findings have provided fundamental insights into the mechanisms that regulate the quality of CD8 T cell memory to intracellular pathogens.

FOXO3 Regulates CD8 T Cell Memory by T Cell-Intrinsic Mechanisms

CD8 T cell responses have three phases: expansion, contraction, and memory. Dynamic alterations in proliferation and apoptotic rates control CD8 T cell numbers at each phase, which in turn dictate the magnitude of CD8 T cell memory. Identification of signaling pathways that control CD8 T cell memory is incomplete. The PI3K/Akt signaling pathway controls cell growth in many cell types by modulating the activity of FOXO transcription factors. But the role of FOXOs in regulating CD8 T cell memory remains unknown. We show that phosphorylation of Akt, FOXO and mTOR in CD8 T cells occurs in a dynamic fashion in vivo during an acute viral infection. To elucidate the potentially dynamic role for FOXO3 in regulating homeostasis of activated CD8 T cells in lymphoid and non-lymphoid organs, we infected global and T cell-specific FOXO3-deficient mice with Lymphocytic Choriomeningitis Virus (LCMV). We found that FOXO3 deficiency induced a marked increase in the expansion of effector CD8 T cells, preferentially in the spleen, by T cell-intrinsic mechanisms. Mechanistically, the enhanced accumulation of proliferating CD8 T cells in FOXO3-deficient mice was not attributed to an augmented rate of cell division, but instead was linked to a reduction in cellular apoptosis. These data suggested that FOXO3 might inhibit accumulation of growth factor-deprived proliferating CD8 T cells by reducing their viability. By virtue of greater accumulation of memory precursor effector cells during expansion, the numbers of memory CD8 T cells were strikingly increased in the spleens of both global and T cell-specific FOXO3-deficient mice. The augmented CD8 T cell memory was durable, and FOXO3 deficiency did not perturb any of the qualitative attributes of memory T cells. In summary, we have identified FOXO3 as a critical regulator of CD8 T cell memory, and therapeutic modulation of FOXO3 might enhance vaccine-induced protective immunity against intracellular pathogens.

Role of PKR and Type I IFNs in Viral Control during Primary and Secondary Infection

Type I interferons (IFNs) are known to mediate viral control, and also promote survival and expansion of virus-specific CD8+ T cells. However, it is unclear whether signaling cascades involved in eliciting these diverse cellular effects are also distinct. One of the best-characterized anti-viral signaling mechanisms of Type I IFNs is mediated by the IFN-inducible dsRNA activated protein kinase, PKR. Here, we have investigated the role of PKR and Type I IFNs in regulating viral clearance and CD8+ T cell response during primary and secondary viral infections. Our studies demonstrate differential requirement for PKR, in viral control versus elicitation of CD8+ T cell responses during primary infection of mice with lymphocytic choriomeningitis virus (LCMV). PKR-deficient mice mounted potent CD8+ T cell responses, but failed to effectively control LCMV. The compromised LCMV control in the absence of PKR was multifactorial, and linked to less effective CD8+ T cell-mediated viral suppression, enhanced viral replication in cells, and lower steady state expression levels of IFN-responsive genes. Moreover, we show that despite normal expansion of memory CD8+ T cells and differentiation into effectors during a secondary response, effective clearance of LCMV but not vaccinia virus required PKR activity in infected cells. In the absence of Type I IFN signaling, secondary effector CD8+ T cells were ineffective in controlling both LCMV and vaccinia virus replication in vivo. These findings provide insight into cellular pathways of Type I IFN actions, and highlight the under-appreciated importance of innate immune mechanisms of viral control during secondary infections, despite the accelerated responses of memory CD8+ T cells. Additionally, the results presented here have furthered our understanding of the immune correlates of anti-viral protective immunity, which have implications in the rational design of vaccines.

Bach2 Regulates Homeostasis of Foxp3 + Regulatory T Cells and Protects against Fatal Lung Disease in Mice

Variants of the Bach2 gene are linked to vitiligo, celiac disease, and type 1 diabetes, but the underlying immunological mechanisms are unknown. In this study, we demonstrate that Bach2 plays crucial roles in maintaining T cell quiescence and governing the differentiation, activation, and survival of Foxp3+ regulatory T (Treg) cells. Bach2-deficient T cells display spontaneous activation and produce elevated levels of Th1/Th2-type cytokines. Without Bach2, Treg cells exhibit diminished Foxp3 expression, depleted numbers, hyperactivation, enhanced proliferation, and profound loss of competitive fitness in vivo. Mechanistically, reduced survival of Bach2-deficient Treg cells was associated with reduced Bcl-2 and Mcl-1 levels and elevated Bim/Bcl-2 ratio. Additionally, Bach2 deficiency induced selective loss of Helios−Foxp3+ Treg cells and a Treg cell transcriptome skewed toward the Th1/Th2 effector program at the expense of the Treg program. In vitro experiments confirmed that Bach2: 1) is indispensable for TCR/TGF-β–induced Foxp3 expression; and 2) mitigates aberrant differentiation of Treg cells by repression of the competing Gata3-driven Th2 effector program. Importantly, perturbations in the differentiation of induced Treg cells was linked to a fatal Th2-type chronic inflammatory lung disease in Bach2-deficient mice. Thus, Bach2 enforces T cell quiescence, promotes the development and survival of Treg lineage, restrains aberrant differentiation of Treg cells, and protects against immune-mediated diseases.

FOXO3 Regulates the CD8 T cell Response to a Chronic Viral Infection

ABSTRACT Chronic infections with viruses such as hepatitis B virus, hepatitis C virus, and HIV constitute a major global public health problem. Studies of chronic viral infections in humans and mice show that persistent antigenic stimulation induces dysregulation of T cell responses; virus-specific T cells either undergo clonal deletion or lose their ability to display the full spectrum of effector functions, a condition termed functional exhaustion. The ability to generate and retain sufficient numbers of functionally competent T cells, therefore, becomes vitally important in controlling chronic viral infections. Our understanding of the mechanisms governing T cell homeostasis during chronic viral infections, however, is poor. The phosphatidylinositol 3-kinase (PI3K)/Akt signaling pathway controls cell fate decisions in many cell types by modulating the activity of downstream effectors, including the FOXO family of transcription factors. We have observed dynamic, in vivo alterations in the phosphorylation levels of three key proteins (Akt, FOXO1/FOXO3 [FOXO1/3], and mammalian target of rapamycin [mTOR]) involved in this signaling cascade and have identified the transcription factor FOXO3 as a negative regulator of the magnitude and effector function of CD8 T cells during chronic lymphocytic choriomeningitis virus (LCMV) infection in mice. We report that ablation of FOXO3 in T cells reduced apoptosis, increased the abundance of polyfunctional virus-specific CD8 T cells, and improved viral control. Thus, FOXO3 is a promising candidate target for immunotherapies of chronic viral infection.

Cbl-b Regulates Antigen-Induced TCR Down-Regulation and IFN-γ Production by Effector CD8 T Cells without Affecting Functional Avidity

The E3 ubiquitin ligase Cbl-b is a negative regulator of TCR signaling that: 1) sets the activation threshold for T cells; 2) is induced in anergic T cells; and 3) protects against autoimmunity. However, the role of Cbl-b in regulating CD8 T cell activation and functions during physiological T cell responses has not been systematically examined. Using the lymphocytic choriomeningitis virus infection model, we show that Cbl-b deficiency did not significantly affect the clonal expansion of virus-specific CD8 T cells. However, Cbl-b deficiency not only increased the steady-state cell surface expression levels of TCR and CD8 but also reduced Ag-induced down-modulation of cell surface TCR expression by effector CD8 T cells. Diminished Ag-stimulated TCR down-modulation and sustained Ag receptor signaling induced by Cbl-b deficiency markedly augmented IFN-γ production, which is known to require substantial TCR occupancy. By contrast, Cbl-b deficiency minimally affected cell-mediated cytotoxicity, which requires limited engagement of TCRs. Surprisingly, despite elevated expression of CD8 and reduced Ag-induced TCR down-modulation, the functional avidity of Cbl-b-deficient effector CD8 T cells was comparable to that of wild-type effectors. Collectively, these data not only show that Cbl-b-imposed constraint on TCR signaling has differential effects on various facets of CD8 T cell response but also suggest that Cbl-b might mitigate tissue injury induced by the overproduction of IFN-γ by CD8 T cells. These findings have implications in the development of therapies to bolster CD8 T cell function during viral infections or suppress T cell-mediated immunopathology.

Regulation of memory CD8 T-cell differentiation by cyclin-dependent kinase inhibitor p27Kip1.

ABSTRACT Induction of potent T-cell memory is the goal of vaccinations, but the molecular mechanisms that regulate the formation of memory CD8 T cells are not well understood. Despite the recognition that controls of cellular proliferation and apoptosis govern the number of memory T cells, the cell cycle regulatory mechanisms that control these key cellular processes in CD8 T cells during an immune response are poorly defined. Here, we have identified the cyclin-dependent kinase inhibitor p27Kip1 as a critical regulator of the CD8 T-cell homeostasis at all phases of the T-cell response to an acute viral infection in mice. By acting as a timer for cell cycle exit, p27Kip1 curtailed the programmed expansion of interleukin-2-producing memory precursors and markedly limited the magnitude and quality of CD8 T-cell memory. In the absence of p27Kip1, CD8 T cells showed superior recall responses shortly after vaccination with recombinant Listeriamonocytogenes. Additionally, we show that p27Kip1 constrains proliferative renewal of memory CD8 T cells, especially of the effector memory subset. These findings provide critical insights into the cell cycle regulation of CD8 T-cell homeostasis and suggest that modulation of p27Kip1 could bolster vaccine-induced T-cell memory and protective immunity.

DNA methylation of E-cadherin is a priming mechanism for prostate development.

In prostate and other epithelial cancers, E-cadherin (CDH1) is downregulated inappropriately by DNA methylation to promote an invasive phenotype. Though cancer frequently involves a reawakening of developmental signaling pathways, whether DNA methylation of Cdh1 occurs during organogenesis has not been determined. Here we show that DNA methylation of Cdh1 mediates outgrowth of developing prostate ducts. During the three-day gestational window leading up to and including prostate ductal initiation, Cdh1 promoter methylation increases and its mRNA and protein abundance decreases in epithelium giving rise to prostatic buds. DNA methylation is required for prostate specification, ductal outgrowth, and branching morphogenesis. All three endpoints are impaired by a DNA methylation inhibitor, which also decreases Cdh1 promoter methylation and increases Cdh1 mRNA and protein abundance. A CDH1 function-blocking antibody restores prostatic identity, bud outgrowth, and potentiates epithelial differentiation in the presence of the DNA methylation inhibitor. This is the first study to mechanistically link acquired changes in DNA methylation to the normal process of prostate organogenesis. We propose a novel mechanism whereby Cdh1 promoter methylation restricts Cdh1 abundance in developing prostate epithelium to create a permissive environment for prostatic bud outgrowth. Thus, DNA methylation primes the prostate primordium to respond to developmental cues mediating outgrowth, differentiation and maturation of the ductal network.

p27 Kip1 Negatively Regulates the Magnitude and Persistence of CD4 T Cell Memory

Much is known about the differentiation of naive T cells into distinct lineages of effector cells, but the molecular mechanisms underlying the generation and maintenance of CD4 T cell memory are poorly characterized. Our studies ascribe a novel role for the cell cycle regulator p27Kip1 as a prominent negative regulator of the establishment and long-term maintenance of Th1 CD4 T cell memory. We demonstrate that p27Kip1 might restrict the differentiation and survival of memory precursors by increasing the T-bet/Bcl-6 ratio in effector CD4 T cells. By promoting apoptosis and contraction of effector CD4 T cells by mechanisms that are at least in part T cell intrinsic, p27Kip1 markedly limits the abundance of memory CD4 T cells. Furthermore, we causally link p27Kip1-dependent apoptosis to the decay of CD4 T cell memory, possibly by repressing the expression of γ-chain receptors and the downstream effector of the Wnt/β-catenin signaling pathway, Tcf-1. We extend these findings by showing that the antagonistic effects of p27Kip1 on CD4 T cell memory require its cyclin-dependent kinase-binding domain. Collectively, these findings provide key insights into the mechanisms underlying the governance of peripheral CD4 T cell homeostasis and identify p27Kip1 as a target to enhance vaccine-induced CD4 T cell memory.