Project description:The Epidermal Growth Factor Receptor (EGFR)/ligand system is centrally involved in multiple homeostatic functions of the epithelia. Epithelial cells are the primary targets of humanized antibodies and small molecule inhibitors against this system, whereby the constellation of skin-specific side effects of these drugs stems from a profound disturbance of keratinocyte biology. So far, the molecular mechanisms underlying these toxic events have been investigated only broadly. Here we show that keratinocyte response to anti-EGFR drugs comprises the development of a type 1 interferon (IFN) molecular signature including enhanced expression of IFN-kappa. Mechanistically, nuclear accumulation of IRF1 precedes this signature as well as the enhanced expression of a chemokine cluster we previously identified as a relevant pro-inflammatory component of EGFR inhibition. In fact, either silencing of IRF1 transcript expression, or antibody-mediated blockade of type 1 IFN receptor function and consequent abrogation of STAT1 activation, leads to impairment of this gene transcription profile. High levels of IRF1 and IFN-kappa can be clearly observed in the early skin lesions of patients treated with cetuximab. Type 1 IFN signaling could be crucially implicated in the triggering of the inflammatory mechanisms active in the skin of patients under treatment with anti-EGFR drugs.

Project description:Radiation and chemotherapy represent standard-of-care cancer treatments, however most treated patients eventually experience tumor recurrence, treatment failure and metastatic dissemination with fatal consequences. To elucidate molecular mechanisms of resistance to radio- and chemo-therapy, we exposed human cancer cell lines (HeLa, MCF-7, and DU145) to clinically relevant doses of 5-azacytidine or ionizing radiation and compared the transcript profiles of all surviving cell subpopulations including non-adherent fraction. Stress-mobilized non-adherent cell fractions differed from other survivors in deregulation of hundreds of genes including those involved in interferon response. Exposure of cancer cells to interferon-gamma but not interferon-beta resulted in development of a heterogeneous non-adherent fraction comprising, besides apoptotic/necrotic cells, also live cells featuring active Notch signaling and expressing stem cell markers. Interferon-gamma-mediated loss of adhesion and anoikis-resistance required active Erk pathway interlinked with interferon signaling by IRF1, as chemical inhibition of MEK or siRNA-mediated knockdown of Erk1/2 and IRF1 prevented mobilization of the surviving non-adherent population. Noteworthy, among the top scoring genes upregulated in surviving non-adherent tumor cells induced by 5-azacytidine or irradiation was a skin-specific protein suprabasin (SBSN), a recently identified oncoprotein. SBSN expression required the activity of the MEK/Erk pathway, and siRNA-mediated knockdown of SBSN resulted in suppression of the non-adherent fraction in irradiated, interferon-gamma- and 5-azacytidine-treated cells, respectively. Consistently, ectopic expression of SBSN isoforms enhanced the non-adherent phenotype, suggesting functional participation of SBSN in genotoxic stress-induced phenotypic plasticity and stress resistance. The stress-induced expression of skin protein(s) in a subset of cancer cells indicates partial induction of a keratinocyte-like expression program. Overall, we propose that IFN and Erk signaling drive the heterogeneous response of cancer cells to genotoxic therapies and expression of keratinocyte-specific genes as key players in mobilization and survival of cancer stem-like cells, with implications for cancer evolution and therapy resistance.

Project description:Inborn errors of human IFN-γ immunity underlie mycobacterial diseases, whereas inborn errors of IFN-a/b immunity underlie viral diseases. Both types of IFNs induce the transcription factor IRF1. We describe two unrelated children with inherited complete IRF1 deficiency and early-onset, multiple, life-threatening diseases caused by weakly virulent mycobacteria. These children have no history of severe viral disease, despite exposure to many viruses, including SARS-CoV-2, which is life-threatening in individuals with impaired IFN-a/b immunity. The IRF1-dependent cellular responses to IFN-γ are, both quantitatively and qualitatively, much greater than those to IFN-a/b in vitro. Monocyte- and iPSC-derived macrophages from the two patients show no upregulation of at least 20% of the target genes normally induced by IFN-γ. By contrast, cell-intrinsic IFN-a/b immunity to diverse viruses, including SARS-CoV-2, is intact. Human IRF1 is, thus, largely redundant for antiviral IFN-a/b immunity. By contrast, human IRF1 is essential for IFN-γ immunity to mycobacteria in myeloid cells.

Project description:Type I interferon (IFN) is the first line of defense against virus infection. By using both in vivo and in vitro influenza infection models, we found that type I IFN-κ, limited the replication of influenza viruses by stimulating a IFNAR-MAPK-cFos-CHD6 axis. Similarly, Zika virus (ZIKV) was also highly sensitive to IFN-κ-mediated suppression. With an IAV infected mouse model, we found that IFN-κ was the earliest responding type I interferon among all known members in mice after H9N2 infection, a low-pathogenic Avian Influenza, whereas this early induction did not occur upon highly pathogenic H7N9 infection. IFN-κ can efficiently contain both low- and high-pathogenic influenza replication in cultured human lung cells, and CHD6 was the major effector responsive molecule for IFN-κ, but not for IFN-α/β. Furthermore, we discovered that both IFNAR1 and IFNAR2 subunits of type I interferon receptor and their downstream axis of p38-cFos are engaged in IFN-κ signaling cascade to acti vate CHD6, which didn`t require STAT1 activity. In addition, we showed that the pre-treatment with IFN-κ before IAV challenge protected mice from high mortality. Altogether, our study identified an IFN-κ-specific pathway that suppressed influenza A virus in vitro and in vivo. Thus, IFN-κ may have potential as a new prevention and treatment agents against emerging viruses

Project description:Type I interferon (IFN) is the first line of defense against virus infection. By using both in vivo and in vitro influenza infection models, we found that type I IFN-κ, limited the replication of influenza viruses by stimulating a IFNAR-MAPK-cFos-CHD6 axis. Similarly, Zika virus (ZIKV) was also highly sensitive to IFN-κ-mediated suppression. With an IAV infected mouse model, we found that IFN-κ was the earliest responding type I interferon among all known members in mice after H9N2 infection, a low-pathogenic Avian Influenza, whereas this early induction did not occur upon highly pathogenic H7N9 infection. IFN-κ can efficiently contain both low- and high-pathogenic influenza replication in cultured human lung cells, and CHD6 was the major effector responsive molecule for IFN-κ, but not for IFN-α/β. Furthermore, we discovered that both IFNAR1 and IFNAR2 subunits of type I interferon receptor and their downstream axis of p38-cFos are engaged in IFN-κ signaling cascade to acti vate CHD6, which didn`t require STAT1 activity. In addition, we showed that the pre-treatment with IFN-κ before IAV challenge protected mice from high mortality. Altogether, our study identified an IFN-κ-specific pathway that suppressed influenza A virus in vitro and in vivo. Thus, IFN-κ may have potential as a new prevention and treatment agents against emerging viruses

Project description:It has long been known that excessive mitotic activity due to H-Ras can block keratinocyte differentiation and cause skin cancer. It is not clear, however, whether there are any innate surveillants that ensure keratinocytes undergoing terminal differentiation, preventing the disease. IKKα induces keratinocyte terminal differentiation and its reduction promotes skin tumor development. However, its nature function in skin cancer is unknown. Here we found that mice with IKKα deletion in keratinocytes or in hair follicle keratinocytes developed a thickened epidermis and spontaneous squamous cell-like carcinomas. Inactivation of epidermal growth factor receptor (EGFR) or reintroduction of IKKα inhibited excessive mitosis, induced terminal differentiation, and prevented skin cancer through an EGFR-driven autocrine loop in mice. Thus, IKKα serves as an innate surveillant. Experiment Overall Design: The differences in gene expression profiles of CHUK deleted mouse keratinocytes compared to wild type mouse keratinocytes were analyzed using two dual-channel agilent microarrays in duplicates.

Project description:Using doxycycline-inducible IFN-kappa expression in CIN612-9E cells, which maintain extrachromosomally replicating HPV31 genomes, we demonstrate that IFN-kappa inhibits the growth of these cells and reduces viral transcription and replication. Interestingly, the initiation of viral early transcription was already inhibited 4-6h after IFN-kappa expression. This was also observed with recombinant IFN-beta suggesting a common mechanism of IFNs. RNA-seq analysis identified 1367 IFN-kappa regulated genes of which 221 were modulated >2-fold. The majority of those (71%) matched known ISGs confirming that IFN-kappa acts as a bona fide type I IFN in hr-HPV-positive keratinocytes. RNAi and co-transfection experiments indicate that the inhibition of viral transcription is mainly due to the induction of Sp100 proteins by IFN-kappa. CIN612-9E/pInd-IFN-kappa were induced for 4h with 1µg/ml doxycyclin or not. Three biological replicates were analyzed.

Project description:It has long been known that excessive mitotic activity due to H-Ras can block keratinocyte differentiation and cause skin cancer. It is not clear, however, whether there are any innate surveillants that ensure keratinocytes undergoing terminal differentiation, preventing the disease. IKKα induces keratinocyte terminal differentiation and its reduction promotes skin tumor development. However, its nature function in skin cancer is unknown. Here we found that mice with IKKα deletion in keratinocytes or in hair follicle keratinocytes developed a thickened epidermis and spontaneous squamous cell-like carcinomas. Inactivation of epidermal growth factor receptor (EGFR) or reintroduction of IKKα inhibited excessive mitosis, induced terminal differentiation, and prevented skin cancer through an EGFR-driven autocrine loop in mice. Thus, IKKα serves as an innate surveillant.

Project description:The autoimmune disease lupus erythematosus (lupus) is characterized in part by photosensitivity, where patients can develop inflammatory skin lesions with even ambient ultraviolet radiation (UVR) exposure. Evidence points to a role for type I interferon (IFN-I) in photosensitivity, but mechanistic understanding remains limited. We have shown that photosensitivity in lupus models is at least in part attributable to Langerhans cell (LC) dysfunction. Healthy LCs limit photosensitivity via a disintegrin and metalloprotease 17 (ADAM17), a sheddase that normally limits UVR-induced skin inflammation by releasing soluble epidermal growth factor receptor (EGFR) ligands to support keratinocyte survival. On the other hand, LCs from lesional and even non-lesional lupus model skin show reduced ADAM17 activity and mRNA expression. Non-lesional human lupus skin also showed evidence of LC dysfunction, and, here, we asked how the lupus skin environment contributes to this dysfunction. We show that non-lesional skin in human CLE and multiple photosensitive lupus models share gene expression patterns consistent with a high IFN environment and LC dysfunction. IFN-I inhibits murine and human LC ADAM17 activity, and anti-IFNAR1 in lupus models restores LC ADAM17 function and reduces photosensitivity in EGFR and LC ADAM17-dependent manners. Reactive oxygen species (ROS) are a mediator of ADAM17 activity, and we show that lupus models have reduced UVR-induced LC ROS generation that is restored by anti-IFNAR1. Our findings suggest shared pathogenic mechanisms of photosensitivity in human and murine lupus skin and a model whereby the IFN-I-rich microenvironment in non-lesional lupus skin inhibits UVR-induced ADAM17 activity, predisposing to photosensitivity. Our data also suggest that the beneficial effects of the recently FDA-approved anifrolumab (anti-IFNAR1) on human lupus skin could act in part by restoring LC function.

Project description:The autoimmune disease lupus erythematosus (lupus) is characterized in part by photosensitivity, where patients can develop inflammatory skin lesions with even ambient ultraviolet radiation (UVR) exposure. Evidence points to a role for type I interferon (IFN-I) in photosensitivity, but mechanistic understanding remains limited. We have shown that photosensitivity in lupus models is at least in part attributable to Langerhans cell (LC) dysfunction. Healthy LCs limit photosensitivity via a disintegrin and metalloprotease 17 (ADAM17), a sheddase that normally limits UVR-induced skin inflammation by releasing soluble epidermal growth factor receptor (EGFR) ligands to support keratinocyte survival. On the other hand, LCs from lesional and even non-lesional lupus model skin show reduced ADAM17 activity and mRNA expression. Non-lesional human lupus skin also showed evidence of LC dysfunction, and, here, we asked how the lupus skin environment contributes to this dysfunction. We show that non-lesional skin in human CLE and multiple photosensitive lupus models share gene expression patterns consistent with a high IFN environment and LC dysfunction. IFN-I inhibits murine and human LC ADAM17 activity, and anti-IFNAR1 in lupus models restores LC ADAM17 function and reduces photosensitivity in EGFR and LC ADAM17-dependent manners. Reactive oxygen species (ROS) are a mediator of ADAM17 activity, and we show that lupus models have reduced UVR-induced LC ROS generation that is restored by anti-IFNAR1. Our findings suggest shared pathogenic mechanisms of photosensitivity in human and murine lupus skin and a model whereby the IFN-I-rich microenvironment in non-lesional lupus skin inhibits UVR-induced ADAM17 activity, predisposing to photosensitivity. Our data also suggest that the beneficial effects of the recently FDA-approved anifrolumab (anti-IFNAR1) on human lupus skin could act in part by restoring LC function.