Identification of a novel enhancer essential for Satb1 expression in TH2 cells and activated ILC2s.

The genome organizer, special AT-rich binding protein-1 (SATB1), functions to globally regulate gene networks during primary T cell development and plays a pivotal role in lineage specification in CD4+ helper-, CD8+ cytotoxic-, and FOXP3+ regulatory-T cell subsets. However, it remains unclear how Satb1 gene expression is controlled, particularly in effector T cell function. Here, by using a novel reporter mouse strain expressing SATB1-Venus and genome editing, we have identified a cis-regulatory enhancer, essential for maintaining Satb1 expression specifically in TH2 cells. This enhancer is occupied by STAT6 and interacts with Satb1 promoters through chromatin looping in TH2 cells. Reduction of Satb1 expression, by the lack of this enhancer, resulted in elevated IL-5 expression in TH2 cells. In addition, we found that Satb1 is induced in activated group 2 innate lymphoid cells (ILC2s) through this enhancer. Collectively, these results provide novel insights into how Satb1 expression is regulated in TH2 cells and ILC2s during type 2 immune responses.

The Majority of the Serine/Threonine Phosphorylation Sites in Bcl11b Protein Are Dispensable for the Differentiation of T Cells.

Posttranslational modification, such as phosphorylation, is an important biological event that modulates and diversifies protein function. Bcl11b protein is a zinc-finger transcription factor that plays a crucial role in early T cell development and the segregation of T cell subsets. Bcl11b possesses at least 25 serine/threonine (S/T) residues that can be phosphorylated upon TCR stimulation. To understand the physiological relevance of the phosphorylation on Bcl11b protein, we replaced S/T residues with alanine (A) by targeting murine Bcl11b gene in embryonic stem cells. By combinational targeting of exons 2 and 4 in the Bcl11b gene, we generated a mouse strain, Bcl11b-phosphorylation site mutation mice, in which 23 S/T residues were replaced with A residues. Such extensive manipulation left only five putative phosphorylated residues, two of which were specific for mutant protein, and resulted in reduced amounts of Bcl11b protein. However, primary T cell development in the thymus, as well as the maintenance of peripheral T cells, remained intact even after loss of major physiological phosphorylation. In addition, in vitro differentiation of CD4+ naive T cells into effector Th cell subsets-Th1, Th2, Th17, and regulatory T-was comparable between wild-type and Bcl11b-phosphorylation site mutation mice. These findings indicate that the physiological phosphorylation on major 23 S/T residues in Bcl11b is dispensable for Bcl11b functions in early T cell development and effector Th cell differentiation.

Constitutive CD8 expression drives innate CD8+ T-cell differentiation via induction of iNKT2 cells.

Temporal down-regulation of the CD8 co-receptor after receiving positive-selection signals has been proposed to serve as an important determinant to segregate helper versus cytotoxic lineages by generating differences in the duration of TCR signaling between MHC-I and MHC-II selected thymocytes. By contrast, little is known about whether CD8 also modulates TCR signaling engaged by the non-classical MHC-I-like molecule, CD1d, during development of invariant natural killer T (iNKT) cells. Here, we show that constitutive transgenic CD8 expression resulted in enhanced differentiation of innate memory-like CD8+ thymocytes in both a cell-intrinsic and cell-extrinsic manner, the latter being accomplished by an increase in the IL-4-producing iNKT2 subset. Skewed iNKT2 differentiation requires cysteine residues in the intracellular domain of CD8α that are essential for transmitting cellular signaling. Collectively, these findings shed a new light on the relevance of CD8 down-regulation in shaping the balance of iNKT-cell subsets by modulating TCR signaling.

Differential Requirement of Cd8 Enhancers E8I and E8VI in Cytotoxic Lineage T Cells and in Intestinal Intraepithelial Lymphocytes.

CD8 expression in T lymphocytes is tightly regulated by the activity of at least six Cd8 enhancers (E8I-E8VI), however their complex developmental stage-, subset-, and lineage-specific interplays are incompletely understood. Here we analyzed ATAC-seq data on the Immunological Genome Project database and identified a similar developmental regulation of chromatin accessibility of a subregion of E8I, designated E8I-core, and of E8VI. Loss of E8I-core led to a similar reduction in CD8 expression in naïve CD8+ T cells and in IELs as observed in E8I-/- mice, demonstrating that we identified the core enhancer region of E8I. While E8VI-/- mice displayed a mild reduction in CD8 expression levels on CD8SP thymocytes and peripheral CD8+ T cells, CD8 levels were further reduced upon combined deletion of E8I-core and E8VI. Moreover, activated E8I-core-/-E8VI-/- CD8+ T cells lost CD8 expression to a greater degree than E8I-core-/- and E8VI-/- CD8+ T cells, suggesting that the combined activity of both enhancers is required for establishment and maintenance of CD8 expression before and after TCR activation. Finally, we observed a severe reduction of CD4 CTLs among the TCRß+CD4+ IEL population in E8I-core-/- but not E8VI-/- mice. Such a reduction was not observed in Cd8a-/- mice, indicating that E8I-core controls the generation of CD4 CTLs independently of its role in Cd8a gene regulation. Further, the combined deletion of E8I-core and E8VI restored CD4 CTL subsets, suggesting an antagonistic function of E8VI in the generation of CD4 CTLs. Together, our study demonstrates a complex utilization and interplay of E8I-core and E8VI in regulating CD8 expression in cytotoxic lineage T cells and in IELs. Moreover, we revealed a novel E8I-mediated regulatory mechanism controlling the generation of intestinal CD4 CTLs.

Runx-dependent and silencer-independent repression of a maturation enhancer in the Cd4 gene.

An intronic silencer, S4, in the Cd4 gene has been shown to be responsible for the helper-lineage-specific expression of CD4; S4 requires Runx complex binding to exert its silencer function against the enhancer-mediated Cd4 activation by modulating the epigenetic state of the Cd4 gene. Here we identify a late-acting maturation enhancer. Bcl11b plays essential roles for activation of both the early-acting proximal enhancer and maturation enhancer of Cd4. Notably, Runx complexes suppress these enhancers by distinct mechanisms. Whereas repression of the proximal enhancer depends on the S4 silencer, the maturation enhancer is repressed by Runx in the absence of S4. Moreover, ThPOK, known to antagonize S4-mediated Cd4 repression, assists Runx complexes to restrain maturation enhancer activation. Distinct modes of S4 silencer action upon distinct enhancers thus unravel a pathway that restricts CD4 expression to helper-lineage cells by silencer-independent and Runx-dependent repression of maturation enhancer activity in cytotoxic-lineage cells.

Data on the TGFß response of CD4+ T cells in the absence of Eed.

The data presented here are related to the research article entitled "Loss of Eed leads to lineage instability and increased CD8 expression of mouse CD4+ T cells upon TGFß signaling" [1]. The cited research article investigates the molecular mechanism of CD8α upregulation observed in Eed-deficient (∆Eed) CD4+ T cells upon activation in the presence of TGFß. This data report describes the effect of retinoic acid (RA) and/or anti-interferon-gamma (IFNγ) antibody supplementation on up-regulation of CD8α and Foxp3 in ∆Eed CD4+ T cells, the effect of dose or timing of TGFß treatment on CD4+ T cell identity of ∆Eed, adding further information regarding the conditions that induces CD8α, and mRNA expression changes of genes encoding polycomb repressive complex 2 (PRC2) subunits by TGFß treatment.

Requirement for intron structures in activating the Cd8a locus.

During differentiation of CD4+CD8+ double-positive (DP) thymocytes into the CD4-CD8+ single-positive (CD8SP) thymocytes committed to the cytotoxic T cell lineage, Cd8a transcription is temporally terminated after positive selection and is subsequently reinitiated, a process known as coreceptor reversal. Despite the identification of a transcriptional enhancer in the Cd8a gene that directs reporter transgene expression specifically in CD8SP thymocytes, the molecular mechanisms controlling reactivation of the Cd8a gene are not fully understood. Here, we show that, after positive selection, hCD2 reporter expression from the Cd8a locus, which was generated by insertion of hCD2 cDNA into the first exon of the Cd8a gene, requires the incorporation of intron sequences into the hCD2 transcript. The presence of polyadenylation signals after hCD2 cDNA inhibited hCD2 expression in mature CD8+ T cells, whereas hCD2 expression in DP thymocytes recapitulated the Cd8a expression. Incorporation of the endogenous short intron structure and heterologous intron structure of the Cd4 locus restored hCD2 expression in mature CD8+ T cells in a variegated manner. Interestingly, stage-specific DNA demethylation was impaired in Cd8a reporter alleles that failed to express hCD2 in CD8+ T cells, and intron sequences lacking RNA splicing signals still restored hCD2 expression. These observations indicate that "intron-mediated enhancement" is involved in a stage-specific reactivation of the Cd8a locus harboring hCD2 cDNA. However, the Cd8a gene was transcribed in mature CD8+ T cells, albeit at a lower level, from a mutant Cd8a locus lacking intron structures, suggesting that protein-coding sequences in transcripts affect sensitivity to intron-mediated enhancement.

Loss of Eed leads to lineage instability and increased CD8 expression of mouse CD4+ T cells upon TGFß signaling.

Tri-methylation of lysine 27 on histone H3 (H3K27me3) is a repressive epigenetic modification catalyzed by polycomb repressive complex 2 (PRC2) that is required for proper cell fate determination as well as cellular function. Numerous studies have been performed to elucidate the role of PRC2 in T-cell differentiation and function; however, its role in the regulation of T-helper (Th) subset differentiation and identity has not been fully explored. Here, we report that Eed, an essential subunit of PRC2, is crucial to maintain the identity of CD4+ T cells under TGFß-induced regulatory T cell (Treg)-polarizing conditions. Mouse CD4+ T cells lacking Eed exhibited unstable CD4 expression upon TCR stimulation in vitro. Helper lineage instability was further augmented by Treg-polarizing conditions, leading to the immense up-regulation of CD8α as well as other molecules, resembling CD4+ CD8αα+ intraepithelial lymphocyte (DP-IEL) differentiation. Genetic studies suggested that the altered balance between transcription factors T-bet, Runx3, and Th-POK underlies the induction of the DP-IEL-like phenotype in Eed-deficient CD4+ cells. Furthermore, comparison to Th1- and Th17-polarizing conditions indicated that cooperation between Smad3 and the T-bet-Runx3 axis facilitated by the loss of H3K27me3 is crucial for phenotype induction. Collectively, our results provide insight into the molecular mechanism that maintains and regulates the proper cellular response upon TGFß signaling in CD4+ T cells.

Cbfß2 controls differentiation of and confers homing capacity to prethymic progenitors.

Multipotent hematopoietic progenitors must acquire thymus-homing capacity to initiate T lymphocyte development. Despite its importance, the transcriptional program underlying this process remains elusive. Cbfß forms transcription factor complexes with Runx proteins, and here we show that Cbfß2, encoded by an RNA splice variant of the Cbfb gene, is essential for extrathymic differentiation of T cell progenitors. Furthermore, Cbfß2 endows extrathymic progenitors with thymus-homing capacity by inducing expression of the principal thymus-homing receptor, Ccr9. This occurs via direct binding of Cbfß2 to cell type-specific enhancers, as is observed in Rorγt induction during differentiation of lymphoid tissue inducer cells by activation of an intronic enhancer. As in mice, an alternative splicing event in zebrafish generates a Cbfß2-specific mRNA, important for ccr9 expression. Thus, despite phylogenetically and ontogenetically variable sites of origin of T cell progenitors, their robust thymus-homing capacity is ensured by an evolutionarily conserved mechanism emerging from functional diversification of Runx transcription factor complexes by acquisition of a novel splice variant.

Unique N-terminal sequences in two Runx1 isoforms are dispensable for Runx1 function.

BACKGROUND: The Runt-related transcription factors (Runx) are a family of evolutionarily conserved transcriptional regulators that play multiple roles in the developmental control of various cell types. Among the three mammalian Runx proteins, Runx1 is essential for definitive hematopoiesis and its dysfunction leads to human leukemogenesis. There are two promoters, distal (P1) and proximal (P2), in the Runx1 gene, which produce two Runx1 isoforms with distinct N-terminal amino acid sequences, P1-Runx1 and P2-Runx1. However, it remains unclear whether P2-Runx specific N-terminal sequence have any specific function for Runx1 protein. RESULTS: To address the function of the P2-Runx1 isoform, we established novel mutant mouse models in which the translational initiation AUG (+1) codon for P2-Runx1 isoform was modulated. We found that a truncated P2-Runx1 isoform is translated from a downstream non-canonical AUG codon. Importantly, the truncated P2-Runx1 isoform is sufficient to support primary hematopoiesis, even in the absence of the P1-Runx1 isoform. Furthermore, the truncated P2-Runx1 isoform was able to restore defect in basophil development caused by loss of the P1-Runx1 isoform. The truncated P2-Runx1 isoform was more stable than the canonical P2-Runx1 isoform. CONCLUSIONS: Our results demonstrate that the N-terminal sequences specific for P2-Runx1 are dispensable for Runx1 function, and likely serve as a de-stabilization module to regulate Runx1 production.

Priming of lineage-specifying genes by Bcl11b is required for lineage choice in post-selection thymocytes.

T-lineage committed precursor thymocytes are screened by a fate-determination process mediated via T cell receptor (TCR) signals for differentiation into distinct lineages. However, it remains unclear whether any antecedent event is required to couple TCR signals with the transcriptional program governing lineage decisions. Here we show that Bcl11b, known as a T-lineage commitment factor, is essential for proper expression of ThPOK and Runx3, central regulators for the CD4-helper/CD8-cytotoxic lineage choice. Loss of Bcl11b results in random expression of these factors and, thereby, lineage scrambling that is disconnected from TCR restriction by MHC. Initial Thpok repression by Bcl11b prior to the pre-selection stage is independent of a known silencer for Thpok, and requires the last zinc-finger motif in Bcl11b protein, which by contrast is dispensable for T-lineage commitment. Collectively, our findings shed new light on the function of Bcl11b in priming lineage-specifying genes to integrate TCR signals into subsequent transcriptional regulatory mechanisms.CD4 and CD8 T cells develop in the thymus with their transcription programs controlled by ThPOK and Runx3, respectively. Here the authors show that a pre-commitment event modulated by the transcription factor, Bcl11b, is required for the proper expression of ThPOK and Runx3 and correct CD4/CD8 lineage commitment.

Cbfß2 deficiency preserves Langerhans cell precursors by lack of selective TGFß receptor signaling.

The mouse Langerhans cell (LC) network is established through the differentiation of embryonic LC precursors. BMP7 and TGFß1 initiate cellular signaling that is essential for inducing LC differentiation and preserving LCs in a quiescent state, respectively. Here we show that loss of Cbfß2, one of two RNA splice variants of the Cbfb gene, results in long-term persistence of embryonic LC precursors after their developmental arrest at the transition into the EpCAM+ stage. This phenotype is caused by selective loss of BMP7-mediated signaling essential for LC differentiation, whereas TGFßR signaling is intact, maintaining cells in a quiescent state. Transgenic Cbfß2 expression at the neonatal stage, but not at the adult stage, restored differentiation from Cbfß2-deficient LC precursors. Loss of developmental potential in skin-residential precursor cells was accompanied by diminished BMP7-BMPR1A signaling. Collectively, our results reveal an essential requirement for the Cbfß2 variant in LC differentiation and provide novel insight into how the establishment and homeostasis of the LC network is regulated.

Essential Roles of SATB1 in Specifying T Lymphocyte Subsets.

T cell receptor (TCR) signaling by MHC class I and II induces thymocytes to acquire cytotoxic and helper fates via the induction of Runx3 and ThPOK transcription factors, respectively. The mechanisms by which TCR signaling is translated into transcriptional programs for each cell fate remain elusive. Here, we show that, in post-selection thymocytes, a genome organizer, SATB1, activates genes for lineage-specifying factors, including ThPOK, Runx3, CD4, CD8, and Treg factor Foxp3, via regulating enhancers in these genes in a locus-specific manner. Indeed, SATB1-deficient thymocytes are partially re-directed into inappropriate T lineages after both MHC class I- and II-mediated selection, and they fail to generate NKT and Treg subsets. Despite its essential role in activating enhancers for the gene encoding ThPOK in TCR-signaled thymocytes, SATB1 becomes dispensable for maintaining ThPOK in CD4+ T cells. Collectively, our findings demonstrate that SATB1 shapes the primary T cell pool by directing lineage-specific transcriptional programs in the thymus.

Distinct requirement of Runx complexes for TCRß enhancer activation at distinct developmental stages.

A TCRß enhancer, known as the Eß enhancer, plays a critical role in V(D)J recombination and transcription of the Tcrb gene. However, the coordinated action of trans-acting factors in the activation of Eß during T cell development remains uncharacterized. Here, we characterized the roles of Runx complexes in the regulation of the Eß function. A single mutation at one of the two Runx binding motifs within the Eß severely impaired Tcrb activation at the initiation phase in immature thymocytes. However, TCRß expression level in mature thymocytes that developed under such a single Runx site mutation was similar to that of the control. In contrast, mutations at two Runx motifs eliminated Eß activity, demonstrating that Runx complex binding is essential to initiate Eß activation. In cells expressing Tcrb harboring rearranged V(D)J structure, Runx complexes are dispensable to maintain TCRß expression, whereas Eß itself is continuously required for TCRß expression. These findings imply that Runx complexes are essential for Eß activation at the initiation phase, but are not necessary for maintaining Eß activity at later developmental stages. Collectively, our results indicate that the requirements of trans-acting factor for Eß activity are differentially regulated, depending on the developmental stage and cellular activation status.

Epigenetic Thpok silencing limits the time window to choose CD4(+) helper-lineage fate in the thymus.

CD4(+) helper and CD8(+) cytotoxic T cells differentiate from common precursors in the thymus after T-cell receptor (TCR)-mediated selection. Commitment to the helper lineage depends on persistent TCR signals and expression of the ThPOK transcription factor, whereas a ThPOK cis-regulatory element, ThPOK silencer, represses Thpok gene expression during commitment to the cytotoxic lineage. Here, we show that silencer-mediated alterations of chromatin structures in cytotoxic-lineage thymocytes establish a repressive state that is epigenetically inherited in peripheral CD8(+) T cells even after removal of the silencer. When silencer activity is enhanced in helper-lineage cells, by increasing its copy number, a similar heritable Thpok silencing occurs. Epigenetic locking of the Thpok locus may therefore be an independent event from commitment to the cytotoxic lineage. These findings imply that long-lasting TCR signals are needed to establish stable Thpok expression activity to commit to helper T-cell fate and that full commitment to the helper lineage requires persistent reversal of silencer activity during a particular time window.

Transcriptional reprogramming of mature CD4⁺ helper T cells generates distinct MHC class II-restricted cytotoxic T lymphocytes.

TCRαß thymocytes differentiate into either CD8αß(+) cytotoxic T lymphocytes or CD4(+) helper T cells. This functional dichotomy is controlled by key transcription factors, including the helper T cell master regulator ThPOK, which suppresses the cytolytic program in major histocompatibility complex (MHC) class II-restricted CD4(+) thymocytes. ThPOK continues to repress genes of the CD8 lineage in mature CD4(+) T cells, even as they differentiate into effector helper T cell subsets. Here we found that the helper T cell fate was not fixed and that mature, antigen-stimulated CD4(+) T cells terminated expression of the gene encoding ThPOK and reactivated genes of the CD8 lineage. This unexpected plasticity resulted in the post-thymic termination of the helper T cell program and the functional differentiation of distinct MHC class II-restricted CD4(+) cytotoxic T lymphocytes.

Cutting edge: fine-tuning of Thpok gene activation by an enhancer in close proximity to its own silencer.

Differentiation of MHC class II-selected thymocytes toward the CD4(+) helper lineage depends on function of the transcription factor ThPOK, whose expression is repressed in CD8(+) cytotoxic lineage cells by a transcriptional silencer activity within the distal regulatory element (DRE) in the Thpok gene. Interestingly, the DRE also functions as a transcriptional enhancer. However, how the DRE exerts such dual functionality remains obscure. In this study, we dissected the DRE and identified DNA sequences specifically responsible for enhancer activity, and designated this as the thymic enhancer. Removal of the thymic enhancer from the murine Thpok locus resulted in inefficient ThPOK induction, thereby inducing a redirection toward alternative CD8(+) cytotoxic lineage in a proportion of MHC class II-selected cells, even when they express monoclonal MHC class II-restricted transgenic TCR. Thus, regulation of contiguous but separable sequences with opposite function in the DRE plays an important role in precise coupling of TCR signaling with the selection process of two opposite lineages.

Nonredundant roles for Runx1 alternative promoters reflect their activity at discrete stages of developmental hematopoiesis.

The transcription factor Runx1 is a pivotal regulator of definitive hematopoiesis in mouse ontogeny. Vertebrate Runx1 is transcribed from 2 promoters, the distal P1 and proximal P2, which provide a paradigm of the complex transcriptional and translational control of Runx1 function. However, very little is known about the biologic relevance of alternative Runx1 promoter usage in definitive hematopoietic cell emergence. Here we report that both promoters are active at the very onset of definitive hematopoiesis, with a skewing toward the P2. Moreover, functional and morphologic analysis of a novel P1-null and an attenuated P2 mouse model revealed that although both promoters play important nonredundant roles in the emergence of definitive hematopoietic cells, the proximal P2 was most critically required for this. The nature of the observed phenotypes is indicative of a differential contribution of the P1 and P2 promoters to the control of overall Runx1 levels, where and when this is most critically required. In addition, the dynamic expression of P1-Runx1 and P2-Runx1 points at a requirement for Runx1 early in development, when the P2 is still the prevalent promoter in the emerging hemogenic endothelium and/or first committed hematopoietic cells.

Cascading suppression of transcriptional silencers by ThPOK seals helper T cell fate.

CD4 and the transcription factor ThPOK are essential for the differentiation of major histocompatibility complex class II-restricted thymocytes into the helper T cell lineage; their genes (Cd4 and Zbtb7b (called 'ThPOK' here)) are repressed by transcriptional silencer elements in cytotoxic T cells. The molecular mechanisms regulating expression of these genes during helper T cell lineage differentiation remain unknown. Here we showed that inefficient upregulation of ThPOK, induced by removal of the proximal enhancer from the ThPOK locus, resulted in the transdifferentiation of helper lineage-specified cells into the cytotoxic T cell lineage. Furthermore, direct antagonism by ThPOK of the Cd4 and ThPOK silencers generated two regulatory loops that initially inhibited Cd4 downregulation and later stabilized ThPOK expression. Our results show how an initial lineage-specification signal can be amplified and stabilized during the lineage-commitment process.

Phosphorylation of Runx1 at Ser249, Ser266, and Ser276 is dispensable for bone marrow hematopoiesis and thymocyte differentiation.

Runx1, one of three mammalian runt-domain transcription factor family proteins, is essential for definitive hematopoiesis. Based on transfection assays, phosphorylation of Runx1 at the three serine residues, Ser249, Ser266, and Ser276, was thought to be important for trans-activation activity of Runx1. By using "knock-in" gene targeting, we generated mouse strains expressing mutant Runx1 protein that harbored a combined serine-to-alanine substitution at either of two residues, Ser249/Ser266 or Ser249/Ser276. Either mutation resulted in a lack of major phosphorylated form of Runx1. However, while loss of definitive hematopoiesis and impaired thymocyte differentiation was observed following the loss of Runx1, these phenotypes were rescued in those mice lacking the major phosphorylated form of Runx1. These results not only challenge the predicted regulation of Runx1 activity by phosphorylation at these serine residues, but also reaffirm the effectiveness of "knock-in" mutagenesis as a powerful tool for addressing the physiological relevance of post-translation modifications.