Project description:The interferon response is a signaling pathway unique to vertebrates that links the innate and adaptive immune responses. Interferons signal through a cascade of factors including the JAK-STAT pathway to induce the transcription of hundreds of interferon stimulated genes (ISGs). Although the main interferon signal transduction pathways and ISGs have been elucidated, translational regulation of ISG transcripts has not been fully investigated. Prior work demonstrated that ribosomal protein RPL28 negatively regulates a subset of ISGs; however, we find that this effect may be due to a reduction in overall ribosome availability. Multi-omics analysis of RNA-seq and LC-MS/MS data reveal proteins that are translationally up-regulated in IFN-β-stimulated cells depleted of ribosome biogeneis factor BOP1, including an enrichment of ISGs. Analysis of codon usage demonstrates a significant reduction in codon optimality for proteins that are translationally up-regulated during BOP1 knockdown and IFN-β stimulation. Using reporter constructs, we demonstrate that codon non-optimal reporters are translated more that codon-optimized reporters in BOP1-depleted IFN-β cells. We propose that ribosome biogenesis regulates translational fine-tuning of integral protein production to ensure optimal interferon responses.

Project description:BRD9 was identified in a genome-wide screen for genes regulating the response to interferon (IFN) in a A549 based reporter cell line. Subsequent experiments determined an involvement of BRD9 in the transcriptional regulation of Interferon-stimulated genes (ISGs) expression following stimulation with IFN-a2. The aim of this proximity-labelling experiments was to gain a more mechanistic understanding of BRD9 recruitment during the IFN signal transduction using A549 cells stably transduced with BRD9-TurboID and mCherry-TurboID fusion proteins. The BRD9 interactome in the absence of IFN- a2 was determined. We found that following IFN-a2 treatment, STAT2 significantly associates with BRD9-TurboID.

Project description:Messenger RNA (mRNA) stability substantially impacts steady-state gene expression levels in a cell. mRNA stability is strongly affected by codon composition in a translation-dependent manner across species, through a mechanism termed codon optimality. We have developed iCodon (www.iCodon.org), an algorithm for customizing mRNA expression through the introduction of synonymous codon substitutions into the coding sequence. iCodon is optimized for four vertebrate transcriptomes: mouse, human, frog, and fish. Users can predict the mRNA stability of any coding sequence based on its codon composition and subsequently generate more stable (optimized) or unstable (deoptimized) variants encoding for the same protein. Further, we show that codon optimality predictions correlate with both mRNA stability using a massive reporter library and expression levels using fluorescent reporters and analysis of endogenous gene expression in zebrafish embryos and/or human cells. Therefore, iCodon will benefit basic biological research, as well as a wide range of applications for biotechnology and biomedicine.

Project description:Interferons (IFNs) are vital weapons in the arsenal of immune mediators produced in response to infection. We showed that Shigella sonnei blocks signaling and interferon-stimulated genes (ISGs) downstream of all families of IFN via secreted effectors of the OspC family. Notably, Ospc1 and OspC3 strongly block the IFN response. This project aims at investigating the cellular signaling pathways that are impacted by OspC1 and OspC3 with or without IFN stimulation and at clarifying whether observed changes in ISGs expression are general or specific to some ISGs.

Project description:SPT6, encoded by the SUPT6H in humans and Supt6 in mice, respectively, is a conserved histone chaperone that interacts with RNA polymerase II and participates in transcription elongation. However, the question of how SPT6 comes into play in transcriptional activation upon signaling, particularly in mammalian cells, has remained elusive. We investigated the contribution of SPT6 to interferon beta (IFNbeta) induced transcription in mouse NIH3T3 cells. IFNbeta triggers rapid and high level transcription of many IFN-stimulated genes (ISGs). We report here that SPT6 is recruited to ISGs after IFN stimulation. This recruitment was dependent on the interaction with the methyltransferase, NSD2. Further, siRNA-based SPT6 knockdown reduced levels of ISG activation. RNA-Seq analysis showed that SPT6 knockdown diminished about 50% of ISGs whose induction levels were higher than those unaffected by SPT6 knockdown. Under the tested conditions, SPT6 knockdown did not measurably change expression of constitutively expressed genes. This report highlights that SPT6 is recruited in a stimulus-dependent manner and elicits a major impact on signal induced transcription.

Project description:HIV is able to outpace the innate immune response, including the response mediated by interferon (IFN), to establish a productive infection. However, monocyte derived macrophages (MDMs) may be protected from HIV infection by treatment with type I IFN before virus exposure. The ability of HIV to modulate the type I IFN-mediated innate immune response when it encounters a cell that has already been exposed to IFN was investigated. To investigate the presence of HIV on an established IFN response, MDMs were subjected to four different conditions: (1) IFN-treated only, (2) IFN-treated followed by HIV infection, (3) HIV infected only, and (4) a mock-treated and mock-infected control. Microarray gene expression analysis was performed on a total of 24 samples derived from the 4 conditions assessed at 3 time points (1, 4 and 8 days following treatment/infection) for both IFN-α2 or -ω. Initially, ISGs were identified as those that were upregulated greater than 2-fold by IFN alone (condition 1) at both Days 4 and 8. Then, the IFN-treated condition was compared to the IFN-treated followed by HIV-infection condition in order to identify those ISGs that were downregulated at least 1.5-fold by the presence of HIV at both days. Assuming that it would be counterproductive for HIV infection by itself to induce the expression of ISGs with putative anti-HIV effects, those ISGs that were upregulated greater than 2-fold in the HIV control were removed. Finally, ISGs that passed these filters and were concordant with both IFN-treatments (IFN-α2 and -ω) were identified and corresponded to the following 8 ISGs: AXL receptor tyrosine kinase (AXL), interferon-alpha inducible protein 27 (IFI27), interferon-induced protein 44 (IFI44), interferon-induced protein 44-like (IFI44L), ISG15, OAS1, OAS3 and XIAP associated factor 1 (XAF1). It should be noted that the IFN-α2 and -ω microarray experiments were performed in different batches but batch effects were not corrected since genes were identified by the filtering approach just described within each batch.

Project description:Human adenoviruses (HAdV) are a large family of DNA viruses generally infecting the airway, the gut, the eye, and the urinary tract. However, certain strains of HAdVs are capable of causing severe infections in the very young, the elderly, the immunocompromised, and sometimes healthy individuals. In particular, species B HAdVs are often associated with more severe disease, involving serotype 7 and 14. Despite the severity of the disease caused by these strains, little is known about the molecular mechanisms underpinning the disease outcomes. Activation of interferon stimulated genes (ISGs) occurs rapidly after interferon (IFN) stimulation and relies on recruitment of the transcription factor complex IFN-stimulated gene factor 3 (ISGF3) to promoters, which happens via the canonical JAK-STAT pathway. Therefore, suppression of IFNs is a key aspect of evading innate immunity by viral pathogens, including HAdVs; and as such, HAdVs have evolved multiple ways by which they suppress activation of ISGs in order to drive viral replication. Our previous work investigated the molecular mechanism of interferon suppression by HAdV-C5. We observed that E1A of HAdV-C5 interacts with the AAA+ DNA helicase RuvBL1/Pontin in order to suppress activation of interferon stimulated genes (ISGs) during infection. We therefore wanted to determine whether RuvBL1 is also a target for the more highly pathogenic HAdV-B7 and B14. As part of this investigation, we examined the broad-range effect of HAdV species C2, B7, and B14 on cells in response to interferon. These results are presented here.

Project description:The type I interferon (IFN-I) response shapes the intracellular environment to supress virus infection. Historically, this remodelling has been linked to the transcriptional induction of interferon stimulated genes (ISGs). However, IFN-I-driven post-translational regulation of proteins already present in the cell remains relatively unexplored. Here, we profiled the activity of cellular RNA-binding proteins (RBPs), which are key players in antiviral immunity. Using RNA interactome capture (RIC), we identified hundreds of RBPs whose association with RNA is regulated by IFN-I (IR-RBPs). Among these IR-RBPs are both known antiviral proteins and novel candidates identified here through a knockdown screen. By modifying RIC to study IR-RBPs' phosphorylation states, we identified several putative instances of IFN-I-driven phospho-regulation of RNA binding. We experimentally confirmed this phospho-driven regulation for MATR3. Altogether, our results reveal a new dimension of the cell’s antiviral programme, in which the cellular RNA-bound proteome is remodelled by IFN-I.

Project description:The healthy intestine mounts immune responses to microbiota to maintain homeostasis, which includes basal production of interferon cytokines. Previous work showed that Type III Interferon (IFN-λ) stimulates localized pockets of interferon-stimulated genes (ISGs) in the adult mouse intestinal epithelium at homeostasis that provide preemptive protection from viral pathogens. Here, we demonstrate that a major source of homeostatic IFN-λ production in the intestine is a population of epithelium-associated plasmacytoid dendritic cells (pDC). These pDC are recruited to the intestine by bacterial microbiota colonization, and pDC depletion or bone marrow reconstitution with IFN-λ-deficient pDC results in reduced homeostatic ISGs in the intestinal epithelium. Notably, intestinal pDC preferentially produce IFN-λ over Type I IFNs whereas splenic pDC produce more Type I IFNs. Comparison of splenic and intestinal pDC reveal tissue-specific changes in gene expression and genomic accessibility, including evidence of response to transforming growth factor beta (TGF-β) in the intestine. Isolated gut pDC produce more IFN-λ that splenic pDC upon stimulation, and pre-treatment of a human pDC cell line with TGF-β results in enhanced production of IFN-λ upon stimulation. This study implicates pDC as important sources of homeostatic IFN-λ in the intestine and defines the role of barrier cytokine TGF-β in regulating IFN types produced by pDC upon stimulation. Reprogramming of recruited pDC by tissue cytokines may have important implications for balancing effective antimicrobial responses with damaging inflammation at barrier tissues.

Project description:The healthy intestine mounts immune responses to microbiota to maintain homeostasis, which includes basal production of interferon cytokines. Previous work showed that Type III Interferon (IFN-λ) stimulates localized pockets of interferon-stimulated genes (ISGs) in the adult mouse intestinal epithelium at homeostasis that provide preemptive protection from viral pathogens. Here, we demonstrate that a major source of homeostatic IFN-λ production in the intestine is a population of epithelium-associated plasmacytoid dendritic cells (pDC). These pDC are recruited to the intestine by bacterial microbiota colonization, and pDC depletion or bone marrow reconstitution with IFN-λ-deficient pDC results in reduced homeostatic ISGs in the intestinal epithelium. Notably, intestinal pDC preferentially produce IFN-λ over Type I IFNs whereas splenic pDC produce more Type I IFNs. Comparison of splenic and intestinal pDC reveal tissue-specific changes in gene expression and genomic accessibility, including evidence of response to transforming growth factor beta (TGF-β) in the intestine. Isolated gut pDC produce more IFN-λ that splenic pDC upon stimulation, and pre-treatment of a human pDC cell line with TGF-β results in enhanced production of IFN-λ upon stimulation. This study implicates pDC as important sources of homeostatic IFN-λ in the intestine and defines the role of barrier cytokine TGF-β in regulating IFN types produced by pDC upon stimulation. Reprogramming of recruited pDC by tissue cytokines may have important implications for balancing effective antimicrobial responses with damaging inflammation at barrier tissues.