A molecular switch from STAT2-IRF9 to ISGF3 underlies interferon-induced gene transcription.
Ekaterini PlatanitisDuygu DemirozAnja SchnellerKatrin FischerChristophe CapelleMarkus HartlThomas GossenreiterMathias MüllerMaria NovatchkovaThomas DeckerPublished in: Nature communications (2019)
Cells maintain the balance between homeostasis and inflammation by adapting and integrating the activity of intracellular signaling cascades, including the JAK-STAT pathway. Our understanding of how a tailored switch from homeostasis to a strong receptor-dependent response is coordinated remains limited. Here, we use an integrated transcriptomic and proteomic approach to analyze transcription-factor binding, gene expression and in vivo proximity-dependent labelling of proteins in living cells under homeostatic and interferon (IFN)-induced conditions. We show that interferons (IFN) switch murine macrophages from resting-state to induced gene expression by alternating subunits of transcription factor ISGF3. Whereas preformed STAT2-IRF9 complexes control basal expression of IFN-induced genes (ISG), both type I IFN and IFN-γ cause promoter binding of a complete ISGF3 complex containing STAT1, STAT2 and IRF9. In contrast to the dogmatic view of ISGF3 formation in the cytoplasm, our results suggest a model wherein the assembly of the ISGF3 complex occurs on DNA.
Keyphrases
- dendritic cells
- gene expression
- transcription factor
- high glucose
- immune response
- diabetic rats
- resting state
- dna methylation
- cell proliferation
- functional connectivity
- living cells
- drug induced
- oxidative stress
- genome wide
- single molecule
- magnetic resonance
- endothelial cells
- magnetic resonance imaging
- binding protein
- computed tomography
- fluorescent probe
- induced apoptosis
- rna seq
- copy number
- reactive oxygen species
- circulating tumor cells