Project description:Six distinct NFκB signaling codons convey discrete information to distinguish stimuli and enable appropriate macrophage responses

Project description:The epigenome defines the cell type, but also possesses plasticity to tune gene expression in the context of extracellular cues. This tuning is evident in immune sentinel cells such as macrophages, which respond to pathogens and cytokines with phenotypic shifts driven by epigenomic reprogramming. Recent studies indicate that this reprogramming arises from the activity of transcription factors including nuclear factor kappa-light-chain-enhancer of activated B cells (NFκB). NFκB binds not only to available enhancers but may also produce de novo enhancers in previously silent areas of the genome. Here, we show that NFκB reprograms the macrophage epigenome in a stimulus-specific manner, in response only to a subset of pathogen-derived stimuli. The basis for these surprising differences lies in the stimulus-specific temporal dynamics of NFκB activity. In response to different stimuli, NFκB enters the nucleus with variable speed, amplitude, and duration, and may oscillate between the nucleus and cytoplasm. These dynamical features combine to specify the identity and dose of a given stimulus. We demonstrate through live cell imaging, mathematical modeling, and genetic perturbations that NFκB promotes open chromatin and formation of de novo enhancers most strongly when its dynamics are non-oscillatory. These de novo enhancers result in the activation of additional response genes. We propose a mechanistic paradigm in which the temporal dynamics of transcription factors are a key determinant of their capacity to control epigenomic reprogramming, thus enabling the formation of stimulus-specific memory in innate immune sentinel cells.

Project description:NFκB dynamics determine the stimulus-specificity of epigenomic reprogramming in macrophages

Project description:The NFκB family of transcription factors is a major regulator of the innate immune responses, and its dysregulation has been linked to several inflammatory diseases. In this study we focused on bone marrow derived macrophages from the recently described p65-DsRed/IκBα-eGFP transgenic strain, in which a human copy of RelA (p65) was introduced into the mouse genome. Confocal imaging analysis showed that the human RelA is expressed these cells and can translocate to the nucleus upon Toll-like receptor 4 activation (TLR4). RNA sequencing analysis of polysaccharide-stimulated macrophage cultures, revealed that the extra copy of human RelA impacts on gene transcription, affecting both NFκB and non-NFκB target genes, including immediate-early and late response NFκB target genes, such as Fos and Cxcl10, respectively. In validation experiments on NFB targets we observed reduced mRNA levels, but similar expression kinetic profile of the transgenic cells compared to the wild type. Enrichment pathway analysis based on the differentially regulated genes revealed that interferon and cytokine signaling, are affected downstream TLR4. These immune response pathways were also affected when the macrophages were treated with tumor necrosis factor. The impact of genetic manipulation on cell-specific functions is particularly important and highlights the need of understanding the molecular basis on which complicated in vitro and in vivo experiments will be designed on.

Project description:Immune sentinel macrophages initiate responses to pathogens via hundreds of immune response genes. Each immune threat demands a tailored response, suggesting that the capacity for stimulus-specific gene expression is a key functional hallmark of healthy macrophages. To quantify this property, termed Response Specificity, we developed a single-cell experimental workflow and analytical approaches based on information theory and machine learning. We found that Response Specificity of macrophages is driven by combinations of specific immune genes that show low cell-to-cell heterogeneity and are targets of separate signaling pathways. The Response Specificity Profile, a systematic comparison of multiple stimulus response distributions, was distinctly altered by polarizing cytokines and enabled an assessment of the functional state of macrophages. Indeed, the Response Specificity Profile of peritoneal macrophages from old and obese mice showed characteristic differences, suggesting that Response Specificity may be a basis for measuring the functional state of innate immune cells.

Project description:Immune sentinel macrophages initiate responses to pathogens via hundreds of immune response genes. Each immune threat demands a tailored response, suggesting that the capacity for stimulus-specific gene expression is a key functional hallmark of healthy macrophages. To quantify this property, termed Response Specificity, we developed a single-cell experimental workflow and analytical approaches based on information theory and machine learning. We found that Response Specificity of macrophages is driven by combinations of specific immune genes that show low cell-to-cell heterogeneity and are targets of separate signaling pathways. The Response Specificity Profile, a systematic comparison of multiple stimulus response distributions, was distinctly altered by polarizing cytokines and enabled an assessment of the functional state of macrophages. Indeed, the Response Specificity Profile of peritoneal macrophages from old and obese mice showed characteristic differences, suggesting that Response Specificity may be a basis for measuring the functional state of innate immune cells.

Project description:Ultimately, the genotype of a cell and its interaction with the environment determine the cell’s biochemical state. While the cell’s response to a single stimulus has been studied extensively, a conceptual framework to model the effect of multiple environmental stimuli applied concurrently is not as well developed. In this study, we developed the concepts of environmental interactions and epistasis to explain the responses of the S. cerevisiae proteome to simultaneous environmental stimuli. We hypothesize that, as an abstraction, environmental stimuli can be treated as analogous to genetic elements. This would allow modeling of the effects of multiple stimuli using the concepts and tools developed for studying gene interactions. Mirroring gene interactions, our results show that environmental interactions play a critical role in determining the state of the proteome. We show that individual and complex environmental stimuli behave similarly to genetic elements in regulating the cellular responses to stimuli, including the phenomena of dominance and suppression. Interestingly, we observed that the effect of a stimulus on a protein is dominant over other stimuli if the response to the stimulus involves the protein. Using publicly available transcriptomic data, we find that environmental interactions and epistasis regulate transcriptomic responses as well.

Project description:Gonadotrophin-releasing hormone (GnRH) significantly inhibits proliferation of a proportion of cancer cell lines by activating GnRH receptor-G protein signaling. Therefore, manipulation of GnRH receptor signaling may have an under-utilized role in treating certain breast and ovarian cancers. However, the precise signaling pathways necessary for the effect and the features of cellular responses remain poorly defined. We used transcriptomic and proteomic profiling approaches to characterize the effects of GnRH receptor activation in sensitive cells (HEK293-GnRHR, SCL60) in in vitro and in vivo settings, compared to unresponsive HEK293. Analyses of gene expression demonstrated a dynamic SCL60 response to the GnRH super-agonist Triptorelin. Early and mid-phase changes (0.5-1.0 h) comprised mainly transcription factors. Later changes (8-24 h) included a GnRH target gene, CGA, and up or down-regulation of transcripts encoding signaling and cell division machinery. Pathway analysis exposed identified altered mitogen-activated protein kinase and cell cycle pathways, consistent with occurrence of G2/M arrest and apoptosis. NFκB pathway gene transcripts were differentially expressed between control and Triptorelin-treated SCL60 cultures. Reverse phase protein and phospho-proteomic array analyses profiled responses in cultured cells and SCL60 xenografts in vivo during Triptorelin anti-proliferation. Increased phosphorylated NFκB (p65) occurred in SCL60 in vitro, and p-NFκB and IκBε were higher in treated xenografts than controls after 4 days Triptorelin. NFκB inhibition enhanced the anti-proliferative effect of Triptorelin in SCL60 cultures. This study reveals details of pathways interacting with intense GnRH receptor signaling, identifies potential anti-proliferative target genes and implicates the NFκB survival pathway as a node for enhancing GnRH agonist-induced anti-proliferation. 55 samples: 35 SCL60 (15 Control, 20 Treated), 20 HEK293 (12 Control, 8 Treated). Samples collected after 0, 0.5, 1, 2, 8 or 24h after treatment with Triptorelin (100nM) or vehicle control (20% Propylene Glycol solution). SCL60 cells are HEK293 cells stably transfected with a high level of functional rat GnRHR.

Project description:Granulomas are immune cell aggregates formed in response to persistent inflammatory stimuli. Granuloma macrophage subsets are diverse and carry varying copy numbers of their genomic information. The molecular programs that control the differentiation of such macrophage populations in response to a chronic stimulus, though critical for disease outcome, have not been defined. In this study, we performed scRNA-Seq experiments to gain insights into the transcriptional regulation of polyploid macrophage differentiation in response to chronically persistent inflammatory stimuli.

Project description:Suppressor of cytokine signaling-1 (SOCS1) exerts control over inflammation by targeting p65 NFκB for degradation in addition to its canonical role regulating cytokine signaling. We report here that SOCS1 does not operate on all p65 targets equally, instead localizing to a select subset of pro-inflammatory genes. Promoter-specific interactions of SOCS1 and p65 determine the subset of genes activated by NFκB during systemic inflammation, with profound consequences for cytokine responses, immune cell mobilization, and tissue injury. Nitric oxide synthase-1 (NOS1)-derived NO is required and sufficient for displacement of SOCS1 from chromatin, permitting full transcriptional activation of these genes. Single cell transcriptomic analysis of NOS1-deficient animals led to the detection of a regulatory macrophage subset, which exerts potent suppression on inflammatory cytokine responses and tissue remodeling. These results provide the first example of a redox-sensitive, gene-specific mechanism for converting macrophages from cells that regulate inflammation to cells licensed to promote aggressive and potentially injurious inflammation.