Author: Shepardson, Kelly M.; Schwarz, Benjamin; Larson, Kyle; Morton, Rachelle V.; Avera, John; McCoy, Kimberly; Caffrey, Alayna; Harmsen, Ann; Douglas, Trevor; Rynda-Apple, Agnieszka
Title: Induction of Antiviral Immune Response through Recognition of the Repeating Subunit Pattern of Viral Capsids Is Toll-Like Receptor 2 Dependent Cord-id: u8kmlcaw Document date: 2017_11_14
ID: u8kmlcaw
Snippet: Although viruses and viral capsids induce rapid immune responses, little is known about viral pathogen-associated molecular patterns (PAMPs) that are exhibited on their surface. Here, we demonstrate that the repeating protein subunit pattern common to most virus capsids is a molecular pattern that induces a Toll-like-receptor-2 (TLR2)-dependent antiviral immune response. This early antiviral immune response regulates the clearance of subsequent bacterial superinfections, which are a primary caus
Document: Although viruses and viral capsids induce rapid immune responses, little is known about viral pathogen-associated molecular patterns (PAMPs) that are exhibited on their surface. Here, we demonstrate that the repeating protein subunit pattern common to most virus capsids is a molecular pattern that induces a Toll-like-receptor-2 (TLR2)-dependent antiviral immune response. This early antiviral immune response regulates the clearance of subsequent bacterial superinfections, which are a primary cause of morbidities associated with influenza virus infections. Utilizing this altered susceptibility to subsequent bacterial challenge as an outcome, we determined that multiple unrelated, empty, and replication-deficient capsids initiated early TLR2-dependent immune responses, similar to intact influenza virus or murine pneumovirus. These TLR2-mediated responses driven by the capsid were not dependent upon the capsid’s shape, size, origin, or amino acid sequence. However, they were dependent upon the multisubunit arrangement of the capsid proteins, because unlike intact capsids, individual capsid subunits did not enhance bacterial clearance. Further, we demonstrated that even a linear microfilament protein built from repeating protein subunits (F-actin), but not its monomer (G-actin), induced similar kinetics of subsequent bacterial clearance as did virus capsid. However, although capsids and F-actin induced similar bacterial clearance, in macrophages they required distinct TLR2 heterodimers for this response (TLR2/6 or TLR2/1, respectively) and different phagocyte populations were involved in the execution of these responses in vivo. Our results demonstrate that TLR2 responds to invading viral particles that are composed of repeating protein subunits, indicating that this common architecture of virus capsids is a previously unrecognized molecular pattern.
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