Namir Shaabani 1 , Vincent F Vartabedian 2 , Nhan Nguyen 2 , Nadine Honke 3 , Zhe Huang 2 , John R Teijaro 4 Show Affiliations »
Abstract
BACKGROUND/AIMS: During an immune response, type I interferon (IFN-I) signaling induces a wide range of changes, including those which are required to overcome viral infection and those which suppress cytotoxic T cells to avoid immunopathology. During certain bacterial infections, IFN-I signaling exerts largely detrimental effects. Although the IFN-I family of proteins all share one common receptor, biologic responses to signaling vary depending on IFN-I subtype. Here, we asked if one IFN-I subtype dominates the pro-bacterial effect of IFN-I signaling and found that control of Listeria monocytogenes (L.m.) infection is more strongly suppressed by IFN-β than IFN-α. METHODS: To study this, we measured bacterial titers in IFNAR-/-, IFN-β‑/‑, Stat2-/-, Usp18fl/fl and Usp18fl/fl x CD11c-Cre mice models in addition to IFN-I blocking antibodies. Moreover, we measured interferon stimulated genes in bone marrow derived dendritic cells after treatment with IFN-α4 and IFN-β. RESULTS: Specifically, we show that genetic deletion of IFN-β or antibody-mediated IFN-β neutralization was sufficient to reduce bacterial titers to levels similar to those observed in mice that completely lack IFN-I signaling (IFNAR-/- mice). However, IFN-α blockade failed to significantly reduce L.m. titers, suggesting that IFN-β is the dominant IFN-I subtype responsible for the pro-bacterial effect of IFN-I. Mechanistically, when focusing on IFN-I signals to dendritic cells, we found that IFN-β induces ISGs more robustly than IFN-α, including USP18, the protein we previously identified as driving the pro-bacterial effects of IFN-I. Further, we found that this induction was STAT1/STAT2 heterodimer- or STAT2/STAT2 homodimer-dependent, as STAT2-deficient mice were more resistant to L.m. infection. CONCLUSION: In conclusion, IFN-Β is the principal member of the IFN-I family responsible for driving the pro-bacterial effect of IFN-I. © Copyright by the Author(s). Published by Cell Physiol Biochem Press.
BACKGROUND/AIMS: During an immune response, type I interferon (IFN-I) signaling induces a wide range of changes, including those which are required to overcome viral infection and those which suppress cytotoxic T cells to avoid immunopathology. During certain bacterial infections , IFN-I signaling exerts largely detrimental effects. Although the IFN-I family of proteins all share one common receptor, biologic responses to signaling vary depending on IFN-I subtype. Here, we asked if one IFN-I subtype dominates the pro-bacterial effect of IFN-I signaling and found that control of Listeria monocytogenes (L.m .) infection is more strongly suppressed by IFN-β than IFN-α. METHODS: To study this, we measured bacterial titers in IFNAR -/-, IFN-β‑/‑, Stat2 -/-, Usp18fl/fl and Usp18fl/fl x CD11c -Cre mice models in addition to IFN-I blocking antibodies. Moreover, we measured interferon stimulated genes in bone marrow derived dendritic cells after treatment with IFN-α4 and IFN-β. RESULTS: Specifically, we show that genetic deletion of IFN-β or antibody-mediated IFN-β neutralization was sufficient to reduce bacterial titers to levels similar to those observed in mice that completely lack IFN-I signaling (IFNAR -/- mice ). However, IFN-α blockade failed to significantly reduce L.m . titers, suggesting that IFN-β is the dominant IFN-I subtype responsible for the pro-bacterial effect of IFN-I. Mechanistically, when focusing on IFN-I signals to dendritic cells, we found that IFN-β induces ISGs more robustly than IFN-α, including USP18 , the protein we previously identified as driving the pro-bacterial effects of IFN-I. Further, we found that this induction was STAT1 /STAT2 heterodimer- or STAT2 /STAT2 homodimer-dependent, as STAT2 -deficient mice were more resistant to L.m . infection . CONCLUSION: In conclusion, IFN-Β is the principal member of the IFN-I family responsible for driving the pro-bacterial effect of IFN-I. © Copyright by the Author(s). Published by Cell Physiol Biochem Press.
Entities: Disease
Gene
Species
Keywords:
DCs; Interferon; Usp18; Listeria monocytogenes
Year: 2021
PMID: 33984198 DOI: 10.33594/000000370
Source DB: PubMed Journal: Cell Physiol Biochem ISSN: 1015-8987