Influenza A, B and C viruses (IAV, IBV, ICV) circulate globally and infect humans, with IAV/IBV causing most severe disease. While CD8 + T-cells confer cross-protection against different IAV strains, CD8 + T-cell responses to IBV/ICV are understudied. We dissected the CD8 + T-cell cross-reactome against influenza viruses and provided the first evidence of CD8 + T-cell cross-reactivity across IAV, IBV and ICV. Using immunopeptidomics, we identified immunodominant CD8 + T-cell epitopes from IBV, protective in mice, and found prominent memory CD8 + T-cells towards both universal and influenza type-specific epitopes in blood and lungs of healthy humans, with lung-derived CD8 + T-cells displaying a tissue-resident phenotype. Importantly, effector CD38 + Ki67 + CD8 + T-cells against novel epitopes were readily detected in IAV-and IBV-infected pediatric and adult patients. Our study introduces a new paradigm, whereby CD8 + T-cells confer unprecedented cross-reactivity across all influenza viruses, a key finding for designing universal vaccines.
Highlights d Single-cell RNA-seq reveals two distinct B cell lineages d An alternative lineage contains CXCR3 + and atypical B cells d Alternative B cells are primed after primary vaccination and respond to boosters d Alternative B cells adopt a more atypical phenotype following repeated antigen exposure
Severe influenza A virus (IAV) infection is associated with immune dysfunction. Here, we show circulating CD8+ T-cell profiles from patients hospitalized with avian H7N9, seasonal IAV, and influenza vaccinees. Patient survival reflects an early, transient prevalence of highly activated CD38+HLA-DR+PD-1+ CD8+ T cells, whereas the prolonged persistence of this set is found in ultimately fatal cases. Single-cell T cell receptor (TCR)-αβ analyses of activated CD38+HLA-DR+CD8+ T cells show similar TCRαβ diversity but differential clonal expansion kinetics in surviving and fatal H7N9 patients. Delayed clonal expansion associated with an early dichotomy at a transcriptome level (as detected by single-cell RNAseq) is found in CD38+HLA-DR+CD8+ T cells from patients who succumbed to the disease, suggesting a divergent differentiation pathway of CD38+HLA-DR+CD8+ T cells from the outset during fatal disease. Our study proposes that effective expansion of cross-reactive influenza-specific TCRαβ clonotypes with appropriate transcriptome signatures is needed for early protection against severe influenza disease.
Background: Interferon-induced transmembrane (IFITM) proteins limit a broad range of RNA viruses. Results: Tyrosine phosphorylation of IFITM2 and IFITM3, and S-palmitoylation of the IFITM proteins, are crucial for antihepatitis C virus (HCV) activity. Conclusion: IFITM2 and IFITM3 are able to limit HCV infection by targeting the late entry stages of the virus. Significance: IFITM proteins inhibit HCV at early and late stages of entry.
The hepatitis C virus (HCV) is a pandemic human pathogen posing a substantial health and economic burden in both developing and developed countries. Controlling the spread of HCV through behavioural prevention strategies has met with limited success and vaccine development remains slow. The development of antiviral therapeutic agents has also been challenging, primarily due to the lack of efficient cell culture and animal models for all HCV genotypes, as well as the large genetic diversity between HCV strains. On the other hand, the use of interferon-α-based treatments in combination with the guanosine analogue, ribavirin, achieved limited success, and widespread use of these therapies has been hampered by prevalent side effects. For more than a decade, the HCV RNA-dependent RNA polymerase (RdRp) has been targeted for antiviral development. Direct acting antivirals (DAA) have been identified which bind to one of at least six RdRp inhibitor-binding sites, and are now becoming a mainstay of highly effective and well tolerated antiviral treatment for HCV infection. Here we review the different classes of RdRp inhibitors and their mode of action against HCV. Furthermore, the mechanism of antiviral resistance to each class is described, including naturally occurring resistance-associated variants (RAVs) in different viral strains and genotypes. Finally, we review the impact of these RAVs on treatment outcomes with the newly developed regimens.
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