Low ambient humidity impairs barrier function and innate resistance against influenza infection.

In the temperate regions, seasonal influenza virus outbreaks correlate closely with decreases in humidity. While low ambient humidity is known to enhance viral transmission, its impact on host response to influenza virus infection and disease outcome remains unclear. Here, we showed that housing Mx1 congenic mice in low relative humidity makes mice more susceptible to severe disease following respiratory challenge with influenza A virus. We find that inhalation of dry air impairs mucociliary clearance, innate antiviral defense, and tissue repair. Moreover, disease exacerbated by low relative humidity was ameliorated in caspase-1/11-deficient Mx1 mice, independent of viral burden. Single-cell RNA sequencing revealed that induction of IFN-stimulated genes in response to viral infection was diminished in multiple cell types in the lung of mice housed in low humidity condition. These results indicate that exposure to dry air impairs host defense against influenza infection, reduces tissue repair, and inflicts caspase-dependent disease pathology.

Topical application of aminoglycoside antibiotics enhances host resistance to viral infections in a microbiota-independent manner.

Antibiotics are widely used to treat infections in humans. However, the impact of antibiotic use on host cells is understudied. Here we identify an antiviral effect of commonly used aminoglycoside antibiotics. We show that topical mucosal application of aminoglycosides prophylactically increased host resistance to a broad range of viral infections including herpes simplex viruses, influenza A virus and Zika virus. Aminoglycoside treatment also reduced viral replication in primary human cells. This antiviral activity was independent of the microbiota, because aminoglycoside treatment protected germ-free mice. Microarray analysis uncovered a marked upregulation of transcripts for interferon-stimulated genes (ISGs) following aminoglycoside application. ISG induction was mediated by Toll-like receptor 3, and required Toll/interleukin-1-receptor-domain-containing adapter-inducing interferon-ß signalling adaptor, and Interferon regulatory factors 3 and 7, transcription factors that promote ISG expression. XCR1+ dendritic cells, which uniquely express Toll-like receptor 3, were recruited to the vaginal mucosa upon aminoglycoside treatment and were required for ISG induction. These results highlight an unexpected ability of aminoglycoside antibiotics to confer broad antiviral resistance in vivo.

Antiviral CD8 T cells induce Zika-virus-associated paralysis in mice.

Zika virus (ZIKV) is an emerging, mosquito-borne RNA virus. The rapid spread of ZIKV within the Americas has unveiled microcephaly 1 and Guillain-Barré syndrome2,3 as ZIKV-associated neurological complications. Recent reports have also indicated other neurological manifestations to be associated with ZIKV, including myelitis 4 , meningoencephalitis 5 and fatal encephalitis 6 . Here, we investigate the neuropathogenesis of ZIKV infection in type I interferon receptor IFNAR knockout (Ifnar1 -/- ) mice, an infection model that exhibits high viral burden within the central nervous system. We show that systemic spread of ZIKV from the site of infection to the brain requires Ifnar1 deficiency in the haematopoietic compartment. However, spread of ZIKV within the central nervous system is supported by Ifnar1-deficient non-haematopoietic cells. Within this context, ZIKV infection of astrocytes results in breakdown of the blood-brain barrier and a large influx of CD8+ effector T cells. We also find that antiviral activity of CD8+ T cells within the brain markedly limits ZIKV infection of neurons, but, as a consequence, instigates ZIKV-associated paralysis. Taken together, our study uncovers mechanisms underlying ZIKV neuropathogenesis within a susceptible mouse model and suggests blood-brain barrier breakdown and T-cell-mediated neuropathology as potential underpinnings of ZIKV-associated neurological complications in humans.

CD301b+ dendritic cells suppress T follicular helper cells and antibody responses to protein antigens.

Strong antibody response is considered a hallmark of a successful vaccine. While dendritic cells (DCs) are important for T follicular helper (Tfh) cell priming, how this process is regulated in vivo is unclear. We show here that the depletion of CD301b+ DCs specifically enhanced the development of Tfh cells, germinal center B cells and antibody responses against protein antigens. Exaggerated antibody responses in mice depleted of CD301b+ DCs occurred in the absence of any adjuvants, and resulting antibodies had broader specificity and higher affinity to the immunogen. CD301b+ DCs express high levels of PD-1 ligands, PD-L1 and PD-L2. Blocking PD-1 or PD-L1 during priming in wild-type mice partially mimicked the phenotype of CD301b+ DC-depleted animals, suggesting their role in Tfh suppression. Transient depletion of CD301b+ DC results in the generation of autoreactive IgG responses. These results revealed a novel regulatory mechanism and a key role of CD301b+ DCs in blocking autoantibody generation.