Project description:IFN-g primes macrophages for enhanced inflammatory activation by TLRs and microbial killing, but little is known about the regulation of cell metabolism or mRNA translation during priming. We found that IFN-g regulates macrophage metabolism and translation in an integrated manner by targeting mTORC1 and MNK pathways that converge on the selective regulator of translation initiation eIF4E. Physiological downregulation of the central metabolic regulator mTORC1 by IFN-g was associated with autophagy and translational suppression of repressors of inflammation such as HES1. Genome-wide ribosome profiling in TLR2-stimulated macrophages revealed that IFN-g selectively modulates the macrophage translatome to promote inflammation, further reprogram metabolic pathways, and modulate protein synthesis. These results add IFN-g-mediated metabolic reprogramming and translational regulation as key components of classical inflammatory macrophage activation. RPF and RNAseq libraries were generated from mock or IFN-g-primed human macrophages. Cells were stimulated with Pam3Cys and harvested at 4 hours. Libraries were generated using protocol modified from Illumina Truseq technology.

Project description:We sequenced microRNAs from bone marrow derived macrophages derived from the control (WT) and RBP-J conditional knockout mice (RBP-J KO; Rbpjf/f; LysM Cre). Examination of differential microRNA expression levels induced by TNF as well as regulated by RBP-J in bone marrow derived macrophages.

Project description:IFN-g primes macrophages for enhanced inflammatory activation by TLRs and microbial killing, but little is known about the regulation of cell metabolism or mRNA translation during priming. We found that IFN-g regulates macrophage metabolism and translation in an integrated manner by targeting mTORC1 and MNK pathways that converge on the selective regulator of translation initiation eIF4E. Physiological downregulation of the central metabolic regulator mTORC1 by IFN-g was associated with autophagy and translational suppression of repressors of inflammation such as HES1. Genome-wide ribosome profiling in TLR2-stimulated macrophages revealed that IFN-g selectively modulates the macrophage translatome to promote inflammation, further reprogram metabolic pathways, and modulate protein synthesis. These results add IFN-g-mediated metabolic reprogramming and translational regulation as key components of classical inflammatory macrophage activation.

Project description:IFN-g primes macrophages for enhanced inflammatory activation by TLRs and microbial killing, but little is known about the regulation of cell metabolism or mRNA translation during priming. We found that IFN-g regulates macrophage metabolism and translation in an integrated manner by targeting mTORC1 and MNK pathways that converge on the selective regulator of translation initiation eIF4E. Physiological downregulation of the central metabolic regulator mTORC1 by IFN-g was associated with autophagy and translational suppression of repressors of inflammation such as HES1. Genome-wide ribosome profiling in TLR2-stimulated macrophages revealed that IFN-g selectively modulates the macrophage translatome to promote inflammation, further reprogram metabolic pathways, and modulate protein synthesis. These results add IFN-g-mediated metabolic reprogramming and translational regulation as key components of classical inflammatory macrophage activation.

Project description:Purpose: The goal of this study is to explore the role of miRNAs in dairy cow response to E. coli and S. aureus, mastitis causing pathogens, is not well understood. Results: The global expression of miRNAs in bovine mammary epithelial cells (MAC-T cells) challenged with heat-inactivated Staphylococcus aureus (S. aureus) or Escherichia coli (E. coli) bacteria (treatments: 6, 12, 24 and 48 hr) and without challenge (control: 0, 6, 12, 24 and 48 hr) was profiled using next-generation-sequencing. A total of 231 known bovine miRNAs were identified with more than 10 counts per million (CPM) in at least one of 13 libraries and 5 miRNAs including bta-miR-21-5p, miR-27b, miR-22-3p, miR-184 and let-7f represented more than 50% of the total reads of known bovine miRNAs. One hundred and fifty novel miRNAs were identified and half of them belong to the bta-miR-2284 family. Seventeen miRNAs were significantly (P<0.05) differentially regulated by the presence of pathogens. E. coli initiated an earlier regulation of miRNAs (6 miRNAs differentially regulated within the first 6 hrs post challenge as compared to one for S. aureus) while S. aureus presented a delayed response. Five differentially expressed miRNAs (Bta-miR184, miR-24-3p, miR-148, miR-486 and bta-let-7a-5p) were unique to E. coli while four (bta-miR-2339, miR-499, miR-23a and miR-99b) were unique to S. aureus. In addition, our study revealed a temporal differential regulation of five miRNAs (bta-miR-193a-3p, miR-423-5p, miR-30b-5p, miR-29c and miR-un116) in unchallenged cells. Target gene predictions of pathogen differentially expressed miRNAs indicate a significant enrichment in gene ontology functional categories in development/cellular processes, biological regulation as well as cell growth and death. Furthermore, target genes were significantly enriched in several KEGG (Kyoto encyclopedia of genes and genomes) pathways of the immune system, signal transduction, cellular process, nervous system, development and pathways in human diseases, especially cancer. Conclusion: Using next-generation sequencing, our study identified 150 novel bovine miRNAs and revealed a pathogen directed differential regulation of miRNAs in MAC-T cells with roles in immunity and development. E. coli elicited an earlier differential regulation of miRNAs as opposed to a delayed regulation by S. aureus. Furthermore, target gene prediction showed significant enrichments for functions in different biological and cellular processes as well as KEGG pathways in immunity, development and human diseases. Our study provides a further confirmation of the involvement of mammary epithelia cells in contributing to the immune response to infecting pathogens and suggests the potential of miRNAs to serve as biomarkers for diagnosis of mastitis and development of control measures. Bovine mammary epithelial cells (MAC-T cells) challenged with heat-inactivated Staphylococcus aureus (S. aureus) or Escherichia coli (E. coli) bacteria (treatments: 6, 12, 24 and 48 hr) and without challenge (control: 0, 6, 12, 24 and 48 hr) was profiled using next-generation-sequencing, no replicates, using illumina HiScanSQ platform.

Project description:Gene expression analysis of primary CSF1-deprived bone marrow-derived macrophages (BMDM) of Tsc2fl/fl LysM+/+ and TSC2fl/fl LysM+/cre mice Maintenance of tissue homeostasis requires a tight control of the in situ-proliferative capacity of tissue-resident macrophages. Here we show that specific deletion of Tsc2 in myeloid cells breaks quiescence and strongly induces macrophage proliferation and hypertrophy leading to granuloma formation in vivo in an mTORC1-dependent manner. Intriguingly, the growth factor CSF1 induces expression of cyclin-dependent kinase 4 (CDK4) via TSC2-mTORC1 to stimulate cell proliferation, while simultaneously NF-κB signaling and apoptosis are inhibited. Tsc2-deficient macrophages show constitutive CDK4 expression and enhanced M2-like polarization that is supported by a metabolic reprogramming towards increased glycolysis and mitochondrial metabolism. Strikingly, mTORC1 activation and macrophage proliferation are identified as a hallmark of the human granulomatous disease sarcoidosis and correlate with a clinically progressive disease outcome. In conclusion, TSC2-mTORC1 integrates macrophage quiescence, polarization, and metabolism to prevent granulomatous disease. Fundamentally, we show that the macrophage cell cycle is controlled by a growth factor-induced expression of CDK4.

Project description:IFN-g Regulates mTORC1, Cellular Metabolism and mRNA Translation to Potentiate Inflammatory Macrophage Activation

Project description:Macrophage activation is associated with profound transcriptional reprogramming. Although much progress has been made in the understanding of macrophage activation, polarization and function, the transcriptional programs regulating these processes remain poorly characterized. We stimulated human macrophages with diverse activation signals, acquiring a dataset of 299 macrophage transcriptomes. Analysis of this dataset revealed a spectrum of macrophage activation states extending the current M1 versus M2-polarization model. Network analyses identified central transcriptional regulators associated with all macrophage activation complemented by regulators related to stimulus-specific programs. Applying these transcriptional programs to human alveolar macrophages from smokers and patients with chronic obstructive pulmonary disease (COPD) revealed an unexpected loss of inflammatory signatures in COPD patients. Finally, by integrating murine data from the ImmGen project we propose a refined, activation-independent core signature for human and murine macrophages. This resource serves as a framework for future research into regulation of macrophage activation in health and disease. Since transcriptional programs are further modulated on several levels including miRNAs we assessed the global spectrum of miRNA expression by miRNA-Seq in macrophages stimulated with IFNM-NM-3, IL4 or with the combination of TNFM-NM-1, PGE2 and P3C

Project description:Activation of immune cells is accompanied by a metabolic reconfiguration of their cellular energy metabolism including shifts in glycolysis and mitochondrial respiration that critically regulate functional effector responses. However, while current mass spectrometry strategies identify overall or flux-dependent metabolite profiles of cells or tissues, they fail to comprehensively identify the checkpoint nodes and enzymes that are responsible for different metabolic outputs. Here, we demonstrate that a data-driven inverse modelling approach from mass spectrometry metabolomics data can be used to identify a causal biochemical node that influence overall metabolic profiles and reactions. In our study we applied this strategy to TSC2/mTORC1-dependent macrophage polarization. Using multiomics metabolomics, proteomics and transcriptomics analysis as well as enzymatic activity measurements we demonstrate that TSC2, a negative regulator of mTORC1 signaling, critically influences the cellular metabolism of macrophages by regulating the enzyme phosphoglycerate dehydrogenase (PHGDH), a rate-limiting enzyme that diverts carbon from glycolysis for de novo serine/glycine biosynthesis. This is the first evidence that the metabolic kinase mTORC1 positively regulates PHGDH activity in macrophages. Importantly, PHGDH itself is a central regulator of macrophage polarization. Anti-inflammatory (M2) macrophages have high PHGDH activity that is required for the expression of typical anti-inflammatory molecules. Inhibition of PHGDH activity suppressed marker genes in IL-4 stimulated M2 macrophages. This identifies PHGDH as a metabolic signature of M2 macrophages. The presented concept of data-driven inverse modelling and multiomics analysis allows for the systematic integration of genome-scale metabolic reconstruction, prediction and analysis of causal biochemical regulation.

Project description:We have used small RNA sequencing to measure the expression of all miRNAs present in the kidneys during the development of folic acid-induced kidney injury and fibrosis. From this miRNA expression profile, we identified miRNAs associated with different stages and aspects of kidney damage. BALB/c mice were injected with 250mg/kg of folic acid and kidneys were collected at 0, 1, 2, 3, 7, 14, and 28 days. Total RNA was prepared for sequencing using the Illumina TruSeq Small RNA Sample Preparation Kit, and analyzed on an Illumina HiSeq 2000.