Project description:Exposure of macrophages to cytokines and pathogen-associated molecular patterns (PAMPs) can alter their subsequent stimulus responses, in part by epigenetic reprogramming. Our previous studies identified dynamic control of NFκB as a specificity mechanism for inducing hundreds of de novo enhancers in murine macrophages. A second set of hundreds of de novo enhancers are associated with the ISRE DNA binding element of the family of interferon regulatory factors (IRFs). In this project, we have dissected the roles of three endotoxin-responsive IRFs in macrophage de novo enhancer formation. While IRF3 was previously hypothesized to be a chromatin remodeling transcription factor, we found that its genetic requirement for enhancer formation (H3K4me1) is indirect, mediated by its role in type I IFN expression which activates the IRF9-containing ISGF3 transcription factor. However, our analysis shows that ISGF3 is unable to trigger enhancer formation on its own – it must cooperate with IRF1. Timecourse analysis of chromatin accessibility by ATAC-seq reveals that IRF1 plays a major role in the early steps of nucleosome eviction, while its partner ISGF3 then reinforces eviction and H3K4me1 deposition on neighboring nucleosomes. Further studies revealed that IRF1 can also cooperate with the type II IFN-induced GAF transcription factor, generating an additional set of IRF1-GAF-specific enhancers. Finally, global gene expression analysis by RNA-seq reveals that these IRF1-dependent enhancers are associated with potentiated expression of nearby genes in response to secondary immune threat exposure. Together our results reveal unexpected combinatorial coordination of IRF transcription factors in epigenomic reprograming to provide innate immune memory in a manner that is restricted to direct pathogen exposure or type II IFN-associated T-cell immunity, but not secondary innate immune stimulation via type I IFN.

Project description:Exposure of macrophages to cytokines and pathogen-associated molecular patterns (PAMPs) can alter their subsequent stimulus responses, in part by epigenetic reprogramming. Our previous studies identified dynamic control of NFκB as a specificity mechanism for inducing hundreds of de novo enhancers in murine macrophages. A second set of hundreds of de novo enhancers are associated with the ISRE DNA binding element of the family of interferon regulatory factors (IRFs). In this project, we have dissected the roles of three endotoxin-responsive IRFs in macrophage de novo enhancer formation. While IRF3 was previously hypothesized to be a chromatin remodeling transcription factor, we found that its genetic requirement for enhancer formation (H3K4me1) is indirect, mediated by its role in type I IFN expression which activates the IRF9-containing ISGF3 transcription factor. However, our analysis shows that ISGF3 is unable to trigger enhancer formation on its own – it must cooperate with IRF1. Timecourse analysis of chromatin accessibility by ATAC-seq reveals that IRF1 plays a major role in the early steps of nucleosome eviction, while its partner ISGF3 then reinforces eviction and H3K4me1 deposition on neighboring nucleosomes. Further studies revealed that IRF1 can also cooperate with the type II IFN-induced GAF transcription factor, generating an additional set of IRF1-GAF-specific enhancers. Finally, global gene expression analysis by RNA-seq reveals that these IRF1-dependent enhancers are associated with potentiated expression of nearby genes in response to secondary immune threat exposure. Together our results reveal unexpected combinatorial coordination of IRF transcription factors in epigenomic reprograming to provide innate immune memory in a manner that is restricted to direct pathogen exposure or type II IFN-associated T-cell immunity, but not secondary innate immune stimulation via type I IFN.

Project description:Exposure of macrophages to cytokines and pathogen-associated molecular patterns (PAMPs) can alter their subsequent stimulus responses, in part by epigenetic reprogramming. Our previous studies identified dynamic control of NFκB as a specificity mechanism for inducing hundreds of de novo enhancers in murine macrophages. A second set of hundreds of de novo enhancers are associated with the ISRE DNA binding element of the family of interferon regulatory factors (IRFs). In this project, we have dissected the roles of three endotoxin-responsive IRFs in macrophage de novo enhancer formation. While IRF3 was previously hypothesized to be a chromatin remodeling transcription factor, we found that its genetic requirement for enhancer formation (H3K4me1) is indirect, mediated by its role in type I IFN expression which activates the IRF9-containing ISGF3 transcription factor. However, our analysis shows that ISGF3 is unable to trigger enhancer formation on its own – it must cooperate with IRF1. Timecourse analysis of chromatin accessibility by ATAC-seq reveals that IRF1 plays a major role in the early steps of nucleosome eviction, while its partner ISGF3 then reinforces eviction and H3K4me1 deposition on neighboring nucleosomes. Further studies revealed that IRF1 can also cooperate with the type II IFN-induced GAF transcription factor, generating an additional set of IRF1-GAF-specific enhancers. Finally, global gene expression analysis by RNA-seq reveals that these IRF1-dependent enhancers are associated with potentiated expression of nearby genes in response to secondary immune threat exposure. Together our results reveal unexpected combinatorial coordination of IRF transcription factors in epigenomic reprograming to provide innate immune memory in a manner that is restricted to direct pathogen exposure or type II IFN-associated T-cell immunity, but not secondary innate immune stimulation via type I IFN.

Project description:IRF1 cooperates with ISGF3 or GAF to form innate immune de novo enhancers

Project description:IRF1 cooperates with ISGF3 or GAF to form de novo enhancers in murine macrophages

Project description:IRF1 cooperates with ISGF3 or GAF to form de novo enhancers in murine macrophages (ATAC-Seq)

Project description:IRF1 cooperates with ISGF3 or GAF to form de novo enhancers in murine macrophages (ChIP-Seq)

Project description:IRF1 cooperates with ISGF3 or GAF to form de novo enhancers in murine macrophages (RNA-Seq)

Project description:Virus infection induces the production of type I and type II interferons (IFN-I and IFN-II), cytokines that mediate the antiviral response. IFN-I (IFN-a and -b) induces the assembly of ISGF3 (interferon-stimulated gene factor 3), a multimeric transcriptional activation complex comprised of STAT1, STAT2 and IRF9. IFN-II (IFN-g) induces the homodimerization of STAT1 to form the GAF (gamma-activated factor) complex. ISGF3 and GAF bind specifically to distinct regulatory DNA sequences located upstream of IFN-I and II inducible genes, respectively, and activate the expression of distinct set of antiviral genes. The balance between the type I and type II IFN pathways plays a critical role in orchestrating the innate and adaptive immune systems. Here, we show that the phosphorylation of STAT1 by IKKε (IkB-related kinase epsilon) inhibits STAT1 homodimerization, and thus GAF formation, but does not disrupt ISGF3 formation. Therefore, virus and/or IFN-I activation of IKKε suppresses GAF-dependent transcription and promotes ISGF3-dependent transcription. In the absence of IKKε, GAF-dependent transcription is enhanced at the expense of ISGF3-mediated transcription, rendering cells less resistant to infection. We conclude that IKKε plays a critical role in regulating the balance between the IFN-I and IFN-II signaling pathways. ChIP-seq libraries were constructed with an antibody targeting STAT1 from bone marrow macrophages treated with interferon

Project description:Virus infection induces the production of type I and type II interferons (IFN-I and IFN-II), cytokines that mediate the antiviral response. IFN-I (IFN-a and -b) induces the assembly of ISGF3 (interferon-stimulated gene factor 3), a multimeric transcriptional activation complex comprised of STAT1, STAT2 and IRF9. IFN-II (IFN-g) induces the homodimerization of STAT1 to form the GAF (gamma-activated factor) complex. ISGF3 and GAF bind specifically to distinct regulatory DNA sequences located upstream of IFN-I and II inducible genes, respectively, and activate the expression of distinct set of antiviral genes. The balance between the type I and type II IFN pathways plays a critical role in orchestrating the innate and adaptive immune systems. Here, we show that the phosphorylation of STAT1 by IKKε (IkB-related kinase epsilon) inhibits STAT1 homodimerization, and thus GAF formation, but does not disrupt ISGF3 formation. Therefore, virus and/or IFN-I activation of IKKε suppresses GAF-dependent transcription and promotes ISGF3-dependent transcription. In the absence of IKKε, GAF-dependent transcription is enhanced at the expense of ISGF3-mediated transcription, rendering cells less resistant to infection. We conclude that IKKε plays a critical role in regulating the balance between the IFN-I and IFN-II signaling pathways.