Project description:Interleukin (IL)-21 is essential for type 1 diabetes (T1D) development in the NOD mouse model. IL-21-expressing CD4 T cells are present in pancreatic islets where they contribute to disease progression. However, little is known about their phenotype and differentiation states. To fill this gap, we generated a novel IL-21 reporter NOD strain to further characterize IL-21+ CD4 T cells in T1D. IL-21+ CD4 T cells accumulate in pancreatic islets and recognize β-cell antigens. Single-cell RNA sequencing revealed that most CD4 T effector cells in islets actively express IL-21 and they are highly diabetogenic despite expressing multiple inhibitory molecules, including PD-1 and LAG3. Islet IL-21+ CD4 T cells segregate into four phenotypically and transcriptionally distinct differentiation states, less differentiated early effectors, Tfh-like cells, and two Th1 subsets. Trajectory analysis predicts that early effectors differentiate into both Tfh-like and terminal Th1 cells. We further demonstrated that intrinsic IL-27 signaling controls the differentiation of islet IL-21+ CD4 T cells, contributing to their helper function. Collectively, our study reveals the heterogeneity of islet-infiltrating IL-21+ CD4 T cells and indicates that both Tfh-like and Th1 subsets continuously produce IL-21 throughout their differentiation process, highlighting the important sources of IL-21 in T1D pathogenesis.

Project description:T cells infiltrate pancreatic islets during the progression of type 1 diabetes (T1D) but their differentiation states have not been completely defined. We used unbiased single-cell RNA sequencing analyses to gain further insight into the phenotypic complexity of islet-infiltrating T cells in non-obese diabetic (NOD) mice. In the CD4 T cell compartment, we identified naïve, memory, and regulatory T cells, as well as multiple Il21 expressing effector subsets positive for markers indicative of Th1 and Tfh cells. In CD8 T cells, we identified two activated subsets in addition to naïve cells. The two activated islet CD8 T cell subsets respectively resemble the self-renewing progenitor cells and the terminally differentiated/exhausted effectors during chronic lymphocytic choriomeningitis virus infection. We also identified a BATF-driven transcriptional signature promoting the diabetogenic activity of islet-infiltrating β cell autoreactive CD8 T effectors. Our results provide a useful resource for understanding T cell differentiation programs in T1D.

Project description:T cells infiltrate pancreatic islets during the progression of type 1 diabetes (T1D) but their differentiation states have not been completely defined. We used unbiased single-cell RNA sequencing analyses to gain further insight into the phenotypic complexity of islet-infiltrating T cells in non-obese diabetic (NOD) mice. In the CD4 T cell compartment, we identified naïve, memory, and regulatory T cells, as well as multiple Il21 expressing effector subsets positive for markers indicative of Th1 and Tfh cells. In CD8 T cells, we identified two activated subsets in addition to naïve cells. The two activated islet CD8 T cell subsets respectively resemble the self-renewing progenitor cells and the terminally differentiated/exhausted effectors during chronic lymphocytic choriomeningitis virus infection. We also identified a BATF-driven transcriptional signature promoting the diabetogenic activity of islet-infiltrating β cell autoreactive CD8 T effectors. Our results provide a useful resource for understanding T cell differentiation programs in T1D.

Project description:Interferon regulatory factor 4 (IRF4) is an IRF family transcription factor with critical roles in lymphoid development and in regulating the immune response. IRF4 binds DNA weakly owing to a carboxy-terminal auto-inhibitory domain, but cooperative binding with factors such as PU.1 or SPIB in B cells increases binding affinity, allowing IRF4 to regulate genes containing ETS–IRF composite elements (EICEs; 5'-GGAAnnGAAA-3'). Here we show that in mouse CD4+ T cells, where PU.1/SPIB expression is low, and in B cells, where PU.1 is well expressed, IRF4 unexpectedly can cooperate with activator protein-1 (AP1) complexes to bind to AP1–IRF4 composite (5'-TGAnTCA/GAAA-3') motifs that we denote as AP1–IRF composite elements (AICEs). Moreover, BATF–JUN family protein complexes cooperate with IRF4 in binding to AICEs in pre-activated CD4+ T cells stimulated with IL-21 and in TH17 differentiated cells. Importantly, BATF binding was diminished in Irf4-/- T cells and IRF4 binding was diminished in Batf-/- T cells, consistent with functional cooperation between these factors. Moreover, we show that AP1 and IRF complexes cooperatively promote transcription of the Il10 gene, which is expressed in TH17 cells and potently regulated by IL-21. These findings reveal that IRF4 can signal via complexes containing ETS or AP1 motifs depending on the cellular context, thus indicating new approaches for modulating IRF4-dependent transcription. Genome-wide transcription factors mapping and binding of IRF4, BATF, IRF8, STAT3, JUN etc in WT, Irf4-/- and Batf-/- mice in different cell types (B cells, CD4+ T cells and TH17 cells) cultured with or without IL-21 was conducted. RNA-Seq is conducted in mouse B cells, CD4+ T cells, TH1/TH2/TH9/TH17/Treg.

Project description:In type 1 diabetes (T1D) autoreactive CD8 T cells infiltrate pancreatic islets and destroy insulin-producing β cells. Progression to T1D onset is a chronic process, which suggests that the effector activity of β-cell autoreactive CD8 T cells needs to be maintained throughout the course of disease development. The mechanism that sustains diabetogenic CD8 T cell effectors during the course of T1D progression has not been completely defined. Here we used single-cell RNA sequencing to gain further insight into the phenotypic complexity of islet-infiltrating CD8 T cells in NOD mice. We identified two functionally distinct subsets of activated CD8 T cells, CD44highTCF1+CXCR6- and CD44highTCF1-CXCR6+, in islets of prediabetic NOD mice. Compared to CD44highTCF1+CXCR6- CD8 T cells, the CD44highTCF1-CXCR6+ subset expressed higher levels of inhibitory and cytotoxic molecules and was more prone to apoptosis. Adoptive cell transfer experiments revealed that CD44highTCF1+CXCR6- CD8 T cells, through continuous generation of the CD44highTCF1-CXCR6+ subset, were more capable than the latter population to promote insulitis and the development of T1D. We further showed that direct interleukin-27 (IL-27) signaling in CD8 T cells promoted the generation of terminal effectors from the CD44highTCF1+CXCR6- population. These results indicate that islet CD44highTCF1+CXCR6- CD8 T cells are a progenitor-like subset with self-renewing capacity and under an IL-27 controlled mechanism they differentiate into the CD44highTCF1-CXCR6+ terminal effector population. Our study provides new insight into the sustainability of the CD8 T cell response in the pathogenesis of T1D.

Project description:Viral vectors are attractive vaccine platforms that elicit robust innate and adaptive immune responses; however, viral vector vaccine candidates vary greatly in their ability to induce protective immunity. Ad5 vectors elicit robust CD8+ T cell responses but typically characterized by an exhausted phenotype. The mechanisms by which Ad5 vectors induce dysfunctional CD8+ T cells have not been fully elucidated. Here we demonstrate that Ad5 vectors, but not Ad26 vectors, elicit exhausted antigen-specific IL-10+PD1+ CD4+ T cells with a dysfunctional transcriptional profile, and these cells effectively suppress CD8+ T cells responses in vivo. Induction of inhibitory CD4+ T cells by Ad5 vectors was associated with increased IL-27 expression, and IL-27 blockade improved CD4+ T cell polyfunctionality. Together our data highlight a novel role for IL-27 in regulating responses to viral vector vaccines. Splenic CD45.2+ OT-II TCR-Tg CD4 T cells from CD45.1+ B6 mice immunized with Ad5-OVA or Ad26-OVA were purified by FACS on day 10 post-immunization

Project description:In an accompanying paper we found specific localization of diabetogenic T cells only to islets of Langerhans bearing the specific antigen. Instrumental in the specific localization was the presence of intra-islet dendritic cells bearing the β-cell-peptide-MHC complex. Here we report that the entry of diabetogenic CD4 T cells very rapidly triggered inflammatory gene expression changes in islets and vessels by up-regulating chemokines and adhesion molecules. VCAM-1 expression was notable in blood vessels and so was ICAM-1. ICAM-1 was also found on β-cells. These expression changes induced the entry of non-specific T cells that otherwise did not localize to the islets. In contrast to the entry of diabetogenic CD4 T cells, the entrance of non-specific T cells required a chemokine response and VCAM-1 expression by the islets. Interferon-gamma was important for the early gene expression changes in the islets. By microarray analysis we detected up-regulation of a group of interferon-inducible genes as early as 8 hours post T cell transfer. These studies provide a baseline to examine the development of therapeutics that can modulate islet localization of diabetogenic T cells to control this autoimmune disease. 20 total samples

Project description:CD4⁺ T cells are believed to be essential for effective CD8⁺ T cell responses against hepatotropic viruses like hepatitis B virus (HBV). However, the specific locations and the cellular and molecular mechanisms through which CD4⁺ T cells help CD8⁺ T cells remain unclear. In this study, we generated HBV-specific CD4⁺ TCR transgenic mice to demonstrate that effector CD4⁺ T cells can prevent or reverse the dysfunction of CD8⁺ T cells caused by hepatocellular priming. This, in turn, enhances CD8⁺ T cell effector function and suppresses viral replication. Notably, CD4⁺ T cell help to CD8+ T cells occurs directly in the liver, independent of secondary lymphoid organs, and requires local antigen recognition but not epitope linkage. While dendritic cells were found to be dispensable, Kupffer cells (KCs) emerged as the critical cellular platform for this effect. Mechanistically, CD4⁺ T cells engage KCs via CD40-CD40L interactions, leading to the production of IL-12 and IL-27. IL-12 promotes further CD4⁺ T cell expansion, whereas IL-27 serves as the key cytokine that restores CD8⁺ T cell functionality. Furthermore, we show that exogenous IL-27 administration can reverse HBV-specific CD8⁺ T cell dysfunction in mice and in chronically infected patients. These findings reveal a novel mechanism of CD4⁺ T cell help to CD8⁺ T cells that occurs outside secondary lymphoid organs, specifically in the liver, and involves antigen-presenting cells other than conventional dendritic cells, offering new insights for immunotherapeutic strategies against chronic HBV infection.

Project description:CD8+ T cells in chronic viral infections like HIV develop functional defects such as loss of IL-2 secretion and decreased proliferative potential that are collectively termed exhaustion1. Exhausted T cells express increased levels of multiple inhibitory receptors, such as Programmed Death 1 (PD-1). PD-1 inhibition contributes to impaired virus-specific T cell function in chronic infection because antibody-mediated blockade of its ligand, Programmed Death Ligand 1 (PD-L1) is sufficient to improve T cell function and reduce viral replication in animal models. Reversing PD-1 inhibition is therefore an attractive therapeutic target, but the cellular mechanisms by which PD-1 ligation results in T cell inhibition are not fully understood. PD-1 is thought to limit T cell activation by attenuating T cell receptor (TCR) signaling. It is not known whether PD-1 ligation also acts by upregulating genes in exhausted T cells that impair their function. Here, we analyzed gene-expression profiles from HIV-specific CD8+ T cells in patients with HIV and show that PD-1 coordinately upregulates a program of genes in exhausted CD8+ T cells from humans and mice. This program includes upregulation of basic leucine transcription factor, ATF-like (BATF), a transcription factor in the AP-1 family. Enforced expression of BATF was sufficient to impair T cell proliferation and cytokine secretion, while BATF knockdown reduced PD-1 inhibition. Silencing BATF in CD4+ and CD8+ T cells from chronic viremic patients rescued HIV-specific T cell function. Thus inhibitory receptors can cause T cell exhaustion by upregulating genes – such as BATF – that inhibit T cell function. We sorted HIV-specific CD8+ T cells from 18 progressors and 24 controllers, cohorts with a two-log difference in mean viral load

Project description:The transcription factor BATF is required for Th17 and TFH differentiation. Here, we show that BATF also has a fundamental role in regulating effector CD8+ T cell differentiation. BATF-deficient CD8+ T cells show profound defects in effector expansion and undergo proliferative and metabolic catastrophe early after antigen encounter. BATF, together with IRF4 and Jun proteins, binds to and promotes early expression of genes encoding lineage-specific transcription-factors (T-bet and Blimp-1) and cytokine receptors, while paradoxically repressing genes encoding effector molecules (IFNg and granzyme B). Thus, BATF amplifies TCR-dependent transcription factor expression and augments inflammatory signal propagation but restrains effector gene expression. This checkpoint prevents irreversible commitment to an effector fate until a critical threshold of downstream transcriptional activity has been achieved. P14 TCR transgenic CD8+ T cells from wild-type or BATF-/- mice were examined either as naïve cells or after 3 days of in vitro stimulation with antibodies to CD3 and CD28 in the presence of IL-2