Project description:Regulatory T (Treg) cells play crucial roles in suppressing deleterious immune response. Here, we investigate how mechanistically Treg cells are induced and stabilized via transcriptional regulation of Treg lineage–specifying factor Foxp3. Acetylation of histone tails in the Foxp3 locus is induced during Treg cell development and required in cis for the initiation of Foxp3 transcription. Upon induction, histone acetylation signal largely acts in trans to sustain Foxp3 transcription via multiple factors. Subsequently, Tet-mediated DNA demethylation of Foxp3 cis-regulatory elements particularly enhancer CNS2 increases chromatin accessibility and protein binding, drastically stabilizing Foxp3 transcription, although histone acetylation still regulates global gene expression. These processes transform stochastic Treg cell induction into a stable cell fate, with the former sensitive and latter resistant to genetic and environmental perturbations. Thus, our study reveals distinct roles of histone acetylation in Foxp3 induction and maintenance, reflecting sequential mechanical switches governing Treg cell lineage specification.

Project description:Regulatory T (Treg) cells play crucial roles in suppressing deleterious immune response. Here, we investigate how mechanistically Treg cells are induced and stabilized via transcriptional regulation of Treg lineage–specifying factor Foxp3. Acetylation of histone tails in the Foxp3 locus is induced during Treg cell development and required in cis for the initiation of Foxp3 transcription. Upon induction, histone acetylation signal largely acts in trans to sustain Foxp3 transcription via multiple factors. Subsequently, Tet-mediated DNA demethylation of Foxp3 cis-regulatory elements particularly enhancer CNS2 increases chromatin accessibility and protein binding, drastically stabilizing Foxp3 transcription, although histone acetylation still regulates global gene expression. These processes transform stochastic Treg cell induction into a stable cell fate, with the former sensitive and latter resistant to genetic and environmental perturbations. Thus, our study reveals distinct roles of histone acetylation in Foxp3 induction and maintenance, reflecting sequential mechanical switches governing Treg cell lineage specification.

Project description:Regulatory T (Treg) cells play crucial roles in suppressing deleterious immune response. Here, we investigate how mechanistically Treg cells are induced and stabilized via transcriptional regulation of Treg lineage–specifying factor Foxp3. Acetylation of histone tails in the Foxp3 locus is induced during Treg cell development and required in cis for the initiation of Foxp3 transcription. Upon induction, histone acetylation signal largely acts in trans to sustain Foxp3 transcription via multiple factors. Subsequently, Tet-mediated DNA demethylation of Foxp3 cis-regulatory elements particularly enhancer CNS2 increases chromatin accessibility and protein binding, drastically stabilizing Foxp3 transcription, although histone acetylation still regulates global gene expression. These processes transform stochastic Treg cell induction into a stable cell fate, with the former sensitive and latter resistant to genetic and environmental perturbations. Thus, our study reveals distinct roles of histone acetylation in Foxp3 induction and maintenance, reflecting sequential mechanical switches governing Treg cell lineage specification.

Project description:Regulatory T (Treg) cells play an indispensable role in immune homeostasis. The development and function of Tregs are dependent on transcriptional factor Foxp3, but how constant expression of Foxp3 is maintained in Tregs is not clear. Here we show that ablation of the conserved non-coding DNA sequence 2 (CNS2) at the Foxp3 locus in mice led to spontaneous lymphoproliferative disease and exacerbation of experimental autoimmune encephalomyelitis (EAE). CNS2 is required for activated Treg cells to maintain elevated Foxp3 expression, which is critical for their suppressor function and lineage stability. Mechanistically, upon TCR stimulation, NFAT binds to both CNS2 and Foxp3 promoter and mediates the interaction between CNS2 and Foxp3 promoter. Our findings demonstrated an essential role for CNS2 in maintaining the stability and function of activated Treg cells and identified NFAT as a key mediator of its function. Gene expression was profiled in T regulatory cells (Treg) in WT and CNS2 knockout mice. CNS2 knockout mice lack a conserved non-coding DNA sequence 2 (CNS2) at the Foxp3 locus. Treg cells were further sorted into Foxp3-high and Foxp3-low populations based on the expression level of Foxp3. mRNA was profiled using RNA-Seq (unstranded, polyA+, SE100) in replicate for each condition

Project description:Regulatory T (Treg) cells play an indispensable role in immune homeostasis. The development and function of Tregs are dependent on transcriptional factor Foxp3, but how constant expression of Foxp3 is maintained in Tregs is not clear. Here we show that ablation of the conserved non-coding DNA sequence 2 (CNS2) at the Foxp3 locus in mice led to spontaneous lymphoproliferative disease and exacerbation of experimental autoimmune encephalomyelitis (EAE). CNS2 is required for activated Treg cells to maintain elevated Foxp3 expression, which is critical for their suppressor function and lineage stability. Mechanistically, upon TCR stimulation, NFAT binds to both CNS2 and Foxp3 promoter and mediates the interaction between CNS2 and Foxp3 promoter. Our findings demonstrated an essential role for CNS2 in maintaining the stability and function of activated Treg cells and identified NFAT as a key mediator of its function.

Project description:CD4+ regulatory T cells (Tregs) are key mediators of immunological tolerance and promising effector cells for immuno-suppressive adoptive cellular therapy to fight autoimmunity and chronic inflammation. Their functional stability is critical for their clinical utility and has been correlated to the demethylated state of the TSDR/CNS2 enhancer element in the Treg lineage transcription factor FOXP3. However, proof for a causal contribution of the TSDR de-methylation to FOXP3 stability and Treg induction is so far lacking. We here established a powerful transient-transfection CRISPR-Cas9-based epigenetic-editing method for the selective de-methylation of the TSDR within the endogenous chromatin environment of a living cell. The induced de-methylated state was stable over weeks in clonal T cell proliferation cultures even after expression of the editing complex had ceased. Epigenetic editing of the TSDR resulted in FOXP3 expression, even in its physiological isoform distribution, proving a causal role for the de-methylated TSDR in FOXP3 regulation. However, successful FOXP3 induction was not associated with a switch towards a functional Treg phenotype, in contrast to what has been reported from FOXP3 overexpression approaches. Thus, TSDR de-methylation is required, but not sufficient for a stable Treg phenotype induction. Therefore, targeted demethylation of the TSDR may be a critical addition to published in vitro Treg induction protocols which so far lack FOXP3 stability.

Project description:Treg cells bearing a diverse antigen receptor repertoire suppress pathogenic T cells and maintain immune homeostasis during their long lifespan. How their robust function is determined genetically remains elusive. Here, we investigate the regulatory space of the cis-regulatory elements of Treg lineage–specifying factor Foxp3. Foxp3 enhancers are known as distinct readers for environmental cues in promoting Treg cell induction or lineage stability. However, their single deficiencies cause mild, if any, immune dysregulation, leaving the key transcriptional mechanisms determining Foxp3 expression and thereby Treg suppressive capacity uncertain. We examined the collective activities of Foxp3 enhancers and found that they coordinate to maximize Treg cell induction, Foxp3 expression level, or lineage stability through distinct modes and that ablation of synergistic enhancers led to lethal autoimmunity in young mice. Thus, the induction and maintenance of a diverse, stable Treg cell repertoire rely on combinatorial Foxp3 enhancers, suggesting broad, stage-specific, synergistic activities of cell-intrinsic factors and -extrinsic cues in determining Treg suppressive capacity.

Project description:Treg cells bearing a diverse antigen receptor repertoire suppress pathogenic T cells and maintain immune homeostasis during their long lifespan. How their robust function is determined genetically remains elusive. Here, we investigate the regulatory space of the cis-regulatory elements of Treg lineage–specifying factor Foxp3. Foxp3 enhancers are known as distinct readers for environmental cues in promoting Treg cell induction or lineage stability. However, their single deficiencies cause mild, if any, immune dysregulation, leaving the key transcriptional mechanisms determining Foxp3 expression and thereby Treg suppressive capacity uncertain. We examined the collective activities of Foxp3 enhancers and found that they coordinate to maximize Treg cell induction, Foxp3 expression level, or lineage stability through distinct modes and that ablation of synergistic enhancers led to lethal autoimmunity in young mice. Thus, the induction and maintenance of a diverse, stable Treg cell repertoire rely on combinatorial Foxp3 enhancers, suggesting broad, stage-specific, synergistic activities of cell-intrinsic factors and -extrinsic cues in determining Treg suppressive capacity.

Project description:Treg cells bearing a diverse antigen receptor repertoire suppress pathogenic T cells and maintain immune homeostasis during their long lifespan. How their robust function is determined genetically remains elusive. Here, we investigate the regulatory space of the cis-regulatory elements of Treg lineage–specifying factor Foxp3. Foxp3 enhancers are known as distinct readers for environmental cues in promoting Treg cell induction or lineage stability. However, their single deficiencies cause mild, if any, immune dysregulation, leaving the key transcriptional mechanisms determining Foxp3 expression and thereby Treg suppressive capacity uncertain. We examined the collective activities of Foxp3 enhancers and found that they coordinate to maximize Treg cell induction, Foxp3 expression level, or lineage stability through distinct modes and that ablation of synergistic enhancers led to lethal autoimmunity in young mice. Thus, the induction and maintenance of a diverse, stable Treg cell repertoire rely on combinatorial Foxp3 enhancers, suggesting broad, stage-specific, synergistic activities of cell-intrinsic factors and -extrinsic cues in determining Treg suppressive capacity.

Project description:Treg cells bearing a diverse antigen receptor repertoire suppress pathogenic T cells and maintain immune homeostasis during their long lifespan. How their robust function is determined genetically remains elusive. Here, we investigate the regulatory space of the cis-regulatory elements of Treg lineage–specifying factor Foxp3. Foxp3 enhancers are known as distinct readers for environmental cues in promoting Treg cell induction or lineage stability. However, their single deficiencies cause mild, if any, immune dysregulation, leaving the key transcriptional mechanisms determining Foxp3 expression and thereby Treg suppressive capacity uncertain. We examined the collective activities of Foxp3 enhancers and found that they coordinate to maximize Treg cell induction, Foxp3 expression level, or lineage stability through distinct modes and that ablation of synergistic enhancers led to lethal autoimmunity in young mice. Thus, the induction and maintenance of a diverse, stable Treg cell repertoire rely on combinatorial Foxp3 enhancers, suggesting broad, stage-specific, synergistic activities of cell-intrinsic factors and -extrinsic cues in determining Treg suppressive capacity.