Project description:Inflammation-induced osteoblast death undermines bone homeostasis and can aggravate bone-destructive diseases, yet how pro-survival BMP signaling intersects with inflammatory TNF–NF-κB signaling remains poorly defined. Here we show that BMP4 protects mouse osteoblasts from TNF-α–triggered apoptosis and cytotoxic death and that this cytoprotection requires both Smad4 and NF-κB p65. Integrative epigenomic profiling (ChIP-seq/ATAC-seq/RNA-seq) reveals extensive Smad4–p65 co-occupancy and identifies Samd9l as a prominent TNF-α–inducible gene that is selectively repressed by BMP4. Two Smad4/p65-bound distal elements physically contact the Samd9l promoter, exhibit TNF-responsive enhancer activity, and are required for Samd9l induction, as demonstrated by 4C-seq and CRISPR/dCas9-based chromatin closing/opening. Functionally, Samd9l depletion attenuates TNF-α–driven caspase activation and cytotoxicity in osteoblasts and enhances BMP2-driven ectopic bone formation in vivo. Cross-species mapping suggests that the two mouse regulatory elements converge into a single promoter-proximal composite element at the human SAMD9L locus, supporting a conserved inflammatory control node. Together, these findings define a BMP4–Smad4 mechanism that reshapes NF-κB enhancer outputs to limit osteoblast death and nominate the SAMD9L regulatory circuit as a therapeutic entry point for inflammatory bone loss.

Project description:Inflammation-induced osteoblast death undermines bone homeostasis and can aggravate bone-destructive diseases, yet how pro-survival BMP signaling intersects with inflammatory TNF–NF-κB signaling remains poorly defined. Here we show that BMP4 protects mouse osteoblasts from TNF-α–triggered apoptosis and cytotoxic death and that this cytoprotection requires both Smad4 and NF-κB p65. Integrative epigenomic profiling (ChIP-seq/ATAC-seq/RNA-seq) reveals extensive Smad4–p65 co-occupancy and identifies Samd9l as a prominent TNF-α–inducible gene that is selectively repressed by BMP4. Two Smad4/p65-bound distal elements physically contact the Samd9l promoter, exhibit TNF-responsive enhancer activity, and are required for Samd9l induction, as demonstrated by 4C-seq and CRISPR/dCas9-based chromatin closing/opening. Functionally, Samd9l depletion attenuates TNF-α–driven caspase activation and cytotoxicity in osteoblasts and enhances BMP2-driven ectopic bone formation in vivo. Cross-species mapping suggests that the two mouse regulatory elements converge into a single promoter-proximal composite element at the human SAMD9L locus, supporting a conserved inflammatory control node. Together, these findings define a BMP4–Smad4 mechanism that reshapes NF-κB enhancer outputs to limit osteoblast death and nominate the SAMD9L regulatory circuit as a therapeutic entry point for inflammatory bone loss.

Project description:Inflammation-induced osteoblast death undermines bone homeostasis and can aggravate bone-destructive diseases, yet how pro-survival BMP signaling intersects with inflammatory TNF–NF-κB signaling remains poorly defined. Here we show that BMP4 protects mouse osteoblasts from TNF-α–triggered apoptosis and cytotoxic death and that this cytoprotection requires both Smad4 and NF-κB p65. Integrative epigenomic profiling (ChIP-seq/ATAC-seq/RNA-seq) reveals extensive Smad4–p65 co-occupancy and identifies Samd9l as a prominent TNF-α–inducible gene that is selectively repressed by BMP4. Two Smad4/p65-bound distal elements physically contact the Samd9l promoter, exhibit TNF-responsive enhancer activity, and are required for Samd9l induction, as demonstrated by 4C-seq and CRISPR/dCas9-based chromatin closing/opening. Functionally, Samd9l depletion attenuates TNF-α–driven caspase activation and cytotoxicity in osteoblasts and enhances BMP2-driven ectopic bone formation in vivo. Cross-species mapping suggests that the two mouse regulatory elements converge into a single promoter-proximal composite element at the human SAMD9L locus, supporting a conserved inflammatory control node. Together, these findings define a BMP4–Smad4 mechanism that reshapes NF-κB enhancer outputs to limit osteoblast death and nominate the SAMD9L regulatory circuit as a therapeutic entry point for inflammatory bone loss.

Project description:Increasing evidence shows that many transcription factors execute important biologic functions independent from their DNA-binding capacity. The NF-κB p65 (RELA) subunit is a central regulator of innate immunity. Here, we investigated the relative functional contribution of p65 DNA-binding and dimerization in p65-deficient human and murine cells reconstituted with single amino acid mutants preventing either DNA-binding (p65 E/I) or dimerization (p65 FL/DD). DNA-binding of p65 was required for RelB-dependent stabilization of the NF-κB p100 protein. The antiapoptotic function of p65 and expression of the majority of TNF-α–induced genes were dependent on p65’s ability to bind DNA and to dimerize. Chromatin immunoprecipitation with massively parallel DNA sequencing experiments revealed that impaired DNA-binding and dimerization strongly diminish the chromatin association of p65. However, there were also p65-independent TNF-α–inducible genes and a subgroup of p65 binding sites still allowed some residual chromatin association of the mutants. These sites were enriched in activator protein 1 (AP-1) binding motifs and showed increased chromatin accessibility and basal transcription. This suggests a mechanism of assisted p65 chromatin association that can be in part facilitated by chromatin priming and cooperativity with other transcription factors such as AP-1.

Project description:DOT1L-catalyzed H3K79 methylation is a hallmark of actively transcribed genes and has been extensively studied in developmental and disease contexts. While DOT1L inhibition has emerged as a promising therapeutic strategy in cancer, its role in pro-atherogenic endothelial inflammation remains unclear. To investigate this, we utilized an in vivo partial carotid artery ligation model and observed increased DOT1L expression and H3K79me3 level. Consistently, in vitro studies employing a 3D-printed human coronary artery model and TNF-α stimulation corroborated these results, showing elevated DOT1L expression and H3K79me3 deposition, while levels of H3K79me and me2 remained unchanged. Further analyses identified key DotCom complex components, AF10 and AF9 (upregulated) and AF17 (downregulated), as contributors to the enhanced H3K79me3 landscape. CUT&RUN sequencing showed prominent H3K79me3 enrichment at the RELA (NF-κB p65) promoter, corresponding with increased NF-κB p65 expression and activation. Notably, inhibition/knockdown of the methyltransferase DOT1L or overexpression of the demethylase FBXL10 significantly reduced H3K79me3 levels, thereby suppressing NF-κB p65 expression and attenuating endothelial inflammation, independent of canonical NF-κB p65 activation. These findings establish DOT1L-mediated H3K79me3 as a crucial epigenetic regulator of endothelial inflammation, highlighting a potential therapeutic avenue for mitigating NF-κB p65-driven pro-atherogenic endothelial dysfunction.

Project description:Deletion of the NF-κB subunit p65/RelA in the hematopoietic compartment results in gene expression changes in lineage-Flk2-c-kit+Sca-1+ cells from mouse bone marrow. We analyzed lineage-Flk2-c-kit+Sca-1+ cells from the bone marrow of p65 wild-type or knockout mice using the Affymetrix Mouse Exon 1.0 ST platform. Array data was processed by Affymetrix Exon Array Computational Tool. No technical replicates were performed.

Project description:Unraveling the complexity of transcriptional programs coded by different cell types has been one of the central goals of cell biology. Using genome-wide location analysis, we examined how two different cell types generate different responses to the NF-kappaB signaling pathway. We showed that, after tumor necrosis factor-alpha (TNF-alpha) treatment, NF-kappaB p65 subunit binds to distinct genome locations and subsequently induces different subsets of genes in human monocytic THP-1 cells versus HeLa cells . Interestingly, the differential p65 binding in two cell types correlates with pre-existing cell-type specific enhancers prior to TNF-alpha stimulation, marked by histone modifications. We also found that two transcription factors, PU.1 and C/EBPalpha, appear to synergistically mediate enhancer creation and affect NF-kappaB target selection in THP-1 cells. In HeLa cells, co-expression of PU.1 and C/EBPalpha conferred TNF-alpha responsiveness to a subset of THP-1 specific NF-kappaB target genes. These results suggest that the diversity of transcriptional programs in mammalian cells arises, at least in part, from pre-existing enhancers that are established by cell specific transcription factors. We used Affymetrix microarray (GPL570) to obtain gene expression data for THP1 and HeLa cells before and after TNF-alpha treatment.

Project description:Given the intimate link between inflammation and dysregulated cell proliferation in cancer we investigated cytokine-triggered gene expression in different cell cycle stages. High density microarray analysis revealed that G1 release primes and cooperates with the cytokine-driven gene response. This effect is transmitted through CDK6 which shares the ability to regulate expression of inflammatory genes with its functional homologue CDK4. CDK6 contributes to the regulation of inflammatory gene expression by physical and functional cooperation with the NF-κB subunit p65 in the nucleus. ChIPSeq experiments showed a tight co-recruitment of CDK6 and p65 to enhancers and promoters of many transcriptionally active NF-κB target genes. While CDK6 recruitment to distinct chromatin regions of inflammatory target genes had no effect on histone modifications, it was essential for proper loading of NF-κB p65 to its cognate binding sites and for the function of p65 coactivators such as TRIP6. Furthermore, cytokine-inducible nuclear translocation and chromatin association of CDK6 depends on the kinase activity of TAK1 and p38. These results have widespread biological implications, as aberrant CDK6 expression or activation that is frequently observed in human tumors cooperates with NF-κB to shape the cytokine- and chemokine-repertoire in chronic inflammation and cancer. Four sets of experiments were performed in total (Exp1-4). Within each of these sets biological duplicates (Rep1-2) were included and analyzed. HeLa control cells or cells with established shRNA-mediated knockdown of CDK4 or CDK6 were analyzed. Cells were subjected to cell cycle arrest or were released from the arrested state for 6h. Cells were treated for 30 minutes with Interleukin-1-alpha at the arrested state or after release or were left untreated.

Project description:Specialized pro-resolving mediators (SPMs) are multifunctional lipid mediators that participate in the resolution of inflammation. We have recently described that oral epithelial cells (OECs) express receptors of the SPM resolvin RvD1n-3 DPA and that cultured OECs respond to the RvD1n-3 DPA addition by intracellular calcium release, nuclear receptor translocation and transcription of genes coding for antimicrobial peptides. The aim of the present study was to assess the functional outcome of RvD1n-3 DPA–signaling in OECs. under inflammatory conditions. To this end, we performed transcriptomic analyses of TNF-α-stimulated cells that were subsequently treated with RvD1n-3 DPA and found significant downregulation of pro-inflammatory nuclear factor kappa B (NF-κB) target genes. Further bioinformatics analyses also showed that RvD1n-3 DPA inhibited expression of several genes involved in the NF-κB activation pathway. Immunofluorescence examination revealed that addition of RvD1n-3 DPA to OECs reversed TNF-α-induced nuclear translocation of NF-κB p65. Co-treatment of the cells with the exportin 1 inhibitor leptomycin B indicated that RvD1n-3 DPA increases nuclear export of p65. Unlike earlier cell cultural studies where SPMs are added before or together with the inflammatory stimulus, the present observations suggest that SPMs also have the potential to be used as a therapeutic aid when inflammation is established.

Project description:Medicinal plants have shown great promise as a source of novel drug compounds for the treatment of inflammatory disorders. In our search for new entities with anti-inflammatory potential, the extracts of the whole plant of Saussurea heteromalla (family-Asteraceae), collected from Himalayas, were evaluated in the high throughput screen for TNF-α and IL-6 inhibitors. The plant has been found as a new source of chlorojanerin, a guaianolide type of sesquiterpene lactone. This is the first report on the potent anti-inflammatory activity of the compound. Chlorojanerin was shown to be significantly effective in inhibiting TNF-α and IL-6 production in LPS induced THP-1 cells (TNF-α, IC50 = 3µM and IL-6, IC50 = 0.8µM). The compound also blocked TNF-α and IL-6 production from LPS induced human monocytes and synovial cells from RA patients. Chlorojanerin also inhibited the binding of NF-κB in a GFP reporter assay system. Transcriptional profiling of the LPS stimulated THP-1 cells revealed that chlorojanerin exerted its anti-inflammatory effect by inhibiting the expression of genes involved in activating the transcription factor – NF-κB. Real time analysis of these genes validated the effect of chlorojanerin on the classical downstream targets of NF-κB. Thus, this study clearly delineated 8 targets specific for the effect of chlorojanerin on NF-κB induced signaling at the mRNA level. This work is a step towards the isolation and characterization of lead anti-inflammatory agents from the extract of Saussurea heteromalla, which can be developed into better therapeutic molecules targeted towards some specific inflammatory diseases. Single dye labelling with Cy3 for all treatment RNA samples. Treatments included unstimulated, LPS stimulated, Chlorjanerin treatment and dexamethasone treatment.