Defining intracellular signaling pathways that dictate a universal antiviral response to conserved viral architectures in TLR2/6-dependent manner.

Abstract

Abstract Previously we found that conserved viral architecture, namely the repeating protein subunit pattern (RPSP) of virus capsids is recognized by the cell-surface receptor TLR2/6. This RPSP is common to most, if not all virus capsids (vc) potentially serving as a conserved mechanism of extracellular recognition for viral pathogen-associated molecular patterns (PAMPs). TLR2/6-dependent recognition of vcRPSP induced an antiviral state that resulted in recruitment of immune cells and induction of type I IFN which we found to be required for reduced susceptibility to subsequent bacterial infections (BSI) in murine model of respiratory S. aureus infections. The improved BSI clearance after RPSP recognition was also seen in vcRPSP-treated PBMC-derived human macrophages, indicating the RPSP response is likely similar in humans. TLR2 is unique in that it recognizes an array of PAMPs, signals from the cell surface or endosome (proinflammatory or type I IFN response, respectively), and interacts with co-receptors, including CD14. Indeed, using bone marrow macrophages (BMMs) deficient in CD14, we found that CD14 was required for improved BSI clearance post-vcRPSP recognition. Interestingly, while blocking endosome maturation and acidification did not reduce RPSP-dependent improved clearance of BSI, using knockout BMMs we also found that MyD88, a canonical cell surface TLR signaling molecule, but also TRAM that is associated with endosomal signaling, were both required for improved BSI clearance post-vcRPSP recognition. This indicates that CD14, and the TLR signaling adaptors, MyD88 and TRAM play a role in the recognition and response to RPSP for a TLR2/6-vcRPSP mediated antiviral response but that endosome is not involved in the response.