Abstract
Deciphering complex virus-host interactions is crucial for pandemic preparedness. In this study, we assessed the impact of recently postulated cellular factors ANP32A and ANP32B of influenza A virus (IAV) species specificity on viral pathogenesis in a genetically modified mouse model. Infection of ANP32A−/− and ANP32A+/+ mice with a seasonal H3N2 IAV or a highly pathogenic H5N1 human isolate did not result in any significant differences in virus tropism, innate immune response or disease outcome. However, infection of ANP32B−/− mice with H3N2 or H5N1 IAV revealed significantly reduced virus loads, inflammatory cytokine response and reduced pathogenicity compared to ANP32B+/+ mice. Genome-wide transcriptome analyses in ANP32B+/+ and ANP32B−/− mice further uncovered novel immune-regulatory pathways that correlate with reduced pathogenicity in the absence of ANP32B. These data show that ANP32B but not ANP32A promotes IAV pathogenesis in mice. Moreover, ANP32B might possess a yet unknown immune-modulatory function during IAV infection. Targeting ANP32B or its regulated pathways might therefore pose a new strategy to combat severe influenza.
Highlights
Influenza A virus (IAV) cross-species transmission from animal-to-man poses a continuous risk to global health
ANP32B−/− mice infected with H3N2 influenza presented strongly reduced weight loss and lethality compared to their ANP32B+/+ litter mates (Figures 1G,H)
We provide first evidence regarding the in vivo relevance of these factors by using mice that lack either the ANP32A or ANP32B gene
Summary
Influenza A virus (IAV) cross-species transmission from animal-to-man poses a continuous risk to global health. The influenza pandemic may cause an estimated 80 million deaths worldwide according to a recent report by the World Health Organization (www.who.int). Understanding the molecular basis of interspecies transmission is crucial for pandemic preparedness and for the development of efficient countermeasures and treatments. Interspecies transmission of IAV requires a complex interplay of host adaptive mutations in the viral genome and their dynamic interactions with host cell factors. A major determinant is the heterotrimeric viral polymerase consisting of three subunits: PB1, PB2, and PA (3P). The 3P polymerase together with the viral nucleoprotein (NP) and the viral RNA form the viral genome as viral ribonucleoprotein (vRNP) complexes
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