Project description:The cohesin protein complex extrudes chromatin between CTCF binding sites and organizes it into topologically associated domains (TADs), yet the biological implications of this regulatory mechanism are poorly understood. We show that the cohesin subunit Smc3 is required for the postmitotic differentiation and function of antigen-presenting dendritic cells (DCs). In particular, Smc3 deletion impaired antigen cross-presentation and IL-12 secretion by type 1 conventional DCs (cDC1s), thereby crippling antimicrobial and antitumor immune responses. The chromatin profile of DCs was shaped by the interplay of cohesin and the cDC1-specifying transcription factor IRF8. Conversely, optimal expression of IRF8 itself required CTCF/cohesin-binding elements demarcating the Irf8 gene. Cohesin-mediated chromatin remodeling facilitated chromatin priming at activation-inducible genes; accordingly, deletion of CTCF/cohesin-binding sites flanking the Il12b gene reduced basal and activation-induced IL-12 production by cDC1s. Our data reveal an essential role for cohesin-mediated chromatin regulation in the differentiation and function of a key immune cell type.

Project description:The cohesin protein complex extrudes chromatin between CTCF binding sites and organizes it into topologically associated domains (TADs), yet the biological implications of this regulatory mechanism are poorly understood. We show that the cohesin subunit Smc3 is required for the postmitotic differentiation and function of antigen-presenting dendritic cells (DCs). In particular, Smc3 deletion impaired antigen cross-presentation and IL-12 secretion by type 1 conventional DCs (cDC1s), thereby crippling antimicrobial and antitumor immune responses. The chromatin profile of DCs was shaped by the interplay of cohesin and the cDC1-specifying transcription factor IRF8. Conversely, optimal expression of IRF8 itself required CTCF/cohesin-binding elements demarcating the Irf8 gene. Cohesin-mediated chromatin remodeling facilitated chromatin priming at activation-inducible genes; accordingly, deletion of CTCF/cohesin-binding sites flanking the Il12b gene reduced basal and activation-induced IL-12 production by cDC1s. Our data reveal an essential role for cohesin-mediated chromatin regulation in the differentiation and function of a key immune cell type.

Project description:The cohesin protein complex extrudes chromatin between CTCF binding sites and organizes it into topologically associated domains (TADs), yet the biological implications of this regulatory mechanism are poorly understood. We show that the cohesin subunit Smc3 is required for the postmitotic differentiation and function of antigen-presenting dendritic cells (DCs). In particular, Smc3 deletion impaired antigen cross-presentation and IL-12 secretion by type 1 conventional DCs (cDC1s), thereby crippling antimicrobial and antitumor immune responses. The chromatin profile of DCs was shaped by the interplay of cohesin and the cDC1-specifying transcription factor IRF8. Conversely, optimal expression of IRF8 itself required CTCF/cohesin-binding elements demarcating the Irf8 gene. Cohesin-mediated chromatin remodeling facilitated chromatin priming at activation-inducible genes; accordingly, deletion of CTCF/cohesin-binding sites flanking the Il12b gene reduced basal and activation-induced IL-12 production by cDC1s. Our data reveal an essential role for cohesin-mediated chromatin regulation in the differentiation and function of a key immune cell type.

Project description:The cohesin protein complex extrudes chromatin between CTCF binding sites and organizes it into topologically associated domains (TADs), yet the biological implications of this regulatory mechanism are poorly understood. We show that the cohesin subunit Smc3 is required for the postmitotic differentiation and function of antigen-presenting dendritic cells (DCs). In particular, Smc3 deletion impaired antigen cross-presentation and IL-12 secretion by type 1 conventional DCs (cDC1s), thereby crippling antimicrobial and antitumor immune responses. The chromatin profile of DCs was shaped by the interplay of cohesin and the cDC1-specifying transcription factor IRF8. Conversely, optimal expression of IRF8 itself required CTCF/cohesin-binding elements demarcating the Irf8 gene. Cohesin-mediated chromatin remodeling facilitated chromatin priming at activation-inducible genes; accordingly, deletion of CTCF/cohesin-binding sites flanking the Il12b gene reduced basal and activation-induced IL-12 production by cDC1s. Our data reveal an essential role for cohesin-mediated chromatin regulation in the differentiation and function of a key immune cell type.

Project description:The cohesin protein complex extrudes chromatin between CTCF binding sites and organizes it into topologically associated domains (TADs), yet the biological implications of this regulatory mechanism are poorly understood. We show that the cohesin subunit Smc3 is required for the postmitotic differentiation and function of antigen-presenting dendritic cells (DCs). In particular, Smc3 deletion impaired antigen cross-presentation and IL-12 secretion by type 1 conventional DCs (cDC1s), thereby crippling antimicrobial and antitumor immune responses. The chromatin profile of DCs was shaped by the interplay of cohesin and the cDC1-specifying transcription factor IRF8. Conversely, optimal expression of IRF8 itself required CTCF/cohesin-binding elements demarcating the Irf8 gene. Cohesin-mediated chromatin remodeling facilitated chromatin priming at activation-inducible genes; accordingly, deletion of CTCF/cohesin-binding sites flanking the Il12b gene reduced basal and activation-induced IL-12 production by cDC1s. Our data reveal an essential role for cohesin-mediated chromatin regulation in the differentiation and function of a key immune cell type.

Project description:The cohesin protein complex extrudes chromatin between CTCF binding sites and organizes it into topologically associated domains (TADs), yet the biological implications of this regulatory mechanism are poorly understood. We show that the cohesin subunit Smc3 is required for the postmitotic differentiation and function of antigen-presenting dendritic cells (DCs). In particular, Smc3 deletion impaired antigen cross-presentation and IL-12 secretion by type 1 conventional DCs (cDC1s), thereby crippling antimicrobial and antitumor immune responses. The chromatin profile of DCs was shaped by the interplay of cohesin and the cDC1-specifying transcription factor IRF8. Conversely, optimal expression of IRF8 itself required CTCF/cohesin-binding elements demarcating the Irf8 gene. Cohesin-mediated chromatin remodeling facilitated chromatin priming at activation-inducible genes; accordingly, deletion of CTCF/cohesin-binding sites flanking the Il12b gene reduced basal and activation-induced IL-12 production by cDC1s. Our data reveal an essential role for cohesin-mediated chromatin regulation in the differentiation and function of a key immune cell type.

Project description:The cohesin protein complex extrudes chromatin loops between CTCF-bound sites to organize chromosomes into topologically associated domains, yet biological implications of this process remain obscure. We show that cohesin is required for the post-mitotic differentiation and function of antigen-presenting dendritic cells (DCs), particularly for antigen cross-presentation and IL-12 secretion by type 1 conventional DCs (cDC1s) in vivo. The chromatin organization of DCs was shaped by cohesin and the DC-specifying transcription factor IRF8, which controlled chromatin looping and chromosome compartmentalization, respectively. Notably, optimal expression of IRF8 itself required CTCF/cohesin-binding sites demarcating the Irf8 gene. During DC activation, cohesin was required for the induction of a subset of genes with distal enhancers. Accordingly, the deletion of CTCF sites flanking the Il12b gene reduced IL-12 production by cDC1s. Our data reveal an essential role of cohesin-mediated chromatin regulation in cell differentiation and function in vivo, and its bi-directional crosstalk with lineage-specifying transcription factors.

Project description:The cohesin protein complex extrudes chromatin loops between CTCF-bound sites to organize chromosomes into topologically associated domains, yet biological implications of this process remain obscure. We show that cohesin is required for the post-mitotic differentiation and function of antigen-presenting dendritic cells (DCs), particularly for antigen cross-presentation and IL-12 secretion by type 1 conventional DCs (cDC1s) in vivo. The chromatin organization of DCs was shaped by cohesin and the DC-specifying transcription factor IRF8, which controlled chromatin looping and chromosome compartmentalization, respectively. Notably, optimal expression of IRF8 itself required CTCF/cohesin-binding sites demarcating the Irf8 gene. During DC activation, cohesin was required for the induction of a subset of genes with distal enhancers. Accordingly, the deletion of CTCF sites flanking the Il12b gene reduced IL-12 production by cDC1s. Our data reveal an essential role of cohesin-mediated chromatin regulation in cell differentiation and function in vivo, and its bi-directional crosstalk with lineage-specifying transcription factors.

Project description:Inborn defects in DNA repairare associated with complex developmental disorders whose causal mechanisms are poorly understood. Using an in vivo biotinylation tagging approach in mice, we show that the nucleotide excision repair (NER) structure-specific endonuclease ERCC1-XPF complex interacts with the insulator binding protein CTCF, the cohesin subunits SMC1A and SMC3 and with MBD2; the factors co-localize with ATRX at the promoters and control regions (ICRs) of imprinted genes during postnatal hepatic development. Loss of Ercc1or exposure to mitomycin C triggers the localization of CTCF to heterochromatin, the dissociation of the CTCF-cohesin complex and ATRXfrom promoters and ICRs,altered histone marks and the aberrant developmental expression of imprinted genes without altering DNA methylation. We propose that ERCC1-XPF cooperates with CTCF and the cohesinto facilitatet he developmental silencing of imprinted genes and that persistent DNA damage triggers chromatin changes that affect gene expression programs associated with NER disorders.

Project description:Cohesin, which consists of SMC1, SMC3, Rad21 and either SA1 or SA2, topologically embraces the chromatin fibers to hold sister chromatids together and to stabilize chromatin loops. Increasing evidence indicates that these loops are the organizing principle of higher-order chromatin architecture, which in turn is critical for gene expression. To determine how cohesin contributes to the establishment of tissue-specific transcriptional programs, we compared genome-wide cohesin distribution, gene expression and chromatin architecture in cerebral cortex and pancreas from adult mice. More than one third of cohesin binding sites differ between the two tissues and these are enriched at the regulatory regions of tissue-specific genes. Cohesin colocalizes extensively with the CCCTC-binding factor (CTCF). Cohesin/CTCF sites at active enhancers and promoters contain, at least, cohesin-SA1 whereas either cohesin-SA1 or cohesin-SA2 are present at active promoters independently of CTCF. Analyses of chromatin contacts at the Protocadherin gene cluster and the Regenerating islet-derived (Reg) gene cluster, mostly expressed in brain and pancreas respectively, revealed remarkable differences in the architecture of these loci in the two tissues that correlate with the presence of cohesin. Moreover, we found decreased binding of cohesin and reduced transcription of the Reg genes in the pancreas of SA1 heterozygous mice. Given that Reg proteins are involved in the control of inflammation in pancreas, such reduction may contribute to the increased incidence of pancreatic cancer reported in these animals. Examination of the relationship between gene expression, genome wide cohesin distribution and chromatin structure