Project description:Interferon ε (IFNε), a unique type I IFN, is thought to protect the host against sexually transmitted infections. Unlike conventional type I IFNs (e.g., IFNα/β), whose expression is undetectable at baseline, IFNε expression is detectable in the epithelium of mucosal tissues, particularly the female reproductive tract (FRT). We found that IFNε expression was not limited to epithelial cells at the FRT. Importantly, in contrast to previous reports, IFNε expression in plasmacytoid dendritic cells and primary cervical epithelial cells was induced by viral infection and by activation of TLR3 or 4 in PBMCs. Induction of IFNε mRNAs was also found in cervicovaginal tissues (CVT) of Zika virus (ZIKV)-infected mice. Mice with IFNε deficiency (Ifnε-/-) did not have impaired induction of interferon-stimulated genes except IFNl, but had altered epithelial and collagen structure in the CVT. Ifnε-/- mice exhibited increased susceptibility to ZIKV infection via an intravaginal route but not via a subcutaneous route, indicating that the protective effect of IFNe was specific to the FRT. Infected Ifnε-/- mice had higher and more sustained viral loads than infected wild-type (WT) mice. Detection of ZIKV infection by single molecule in situ hybridization confirmed that virus spread faster in Ifnε-/- mice than in WT mice. Recombinant murine IFNε protected Ifnar1-/- mice against ZIKV infection when administered through an intravaginal route but not when administered through a subcutaneous route, indicating that the specific role of IFNe at the FRT is independent of IFNAR1 signaling. Our findings indicate that IFNε mediates a novel FRT-specific protective effect on mucosal immunity that limits Zika virus spread.

Project description:The female reproductive tract (FRT) is vulnerable to sexually transmitted infections and therefore a well-tuned immune surveillance system is crucial for maintaining a healthy FRT. However, our understanding of the factors that impact viral infection of the FRT and the host response are not well understood. In this work, we investigate the role of a hormonally regulated type I interferon, IFN epsilon, in control of Zika virus (ZIKV) infection of the FRT. We demonstrate that IFN epsilon has anti-ZIKV properties using a combination of IFN epsilon KO mice, blockade of endogenous IFN epsilon by neutralising Abs and rescue of IFN epsilon KO mice by recombinant IFN epsilon administered directly to the FRT.

Project description:Metagenome of the female upper reproductive tract

Project description:Although Zika virus (ZIKV) can be transmitted sexually and cause congenital birth defects, immune control mechanisms in the female reproductive tract (FRT) are not well characterized. Here we show that treatment of primary human vaginal and cervical epithelial cells with interferon (IFN)-?/? or IFN-? induces host defense transcriptional signatures and inhibits ZIKV infection. We also assess the effects of IFNs on intravaginal infection of the FRT using ovariectomized mice treated with reproductive hormones. We find that mice receiving estradiol are protected against intravaginal ZIKV infection, independently of IFN-?/? or IFN-? signaling. In contrast, mice lacking IFN-? signaling sustain greater FRT infection when progesterone is administered. Exogenous IFN-? treatment confers an antiviral effect when mice receive both estradiol and progesterone, but not progesterone alone. Our results identify a hormonal stage-dependent role for IFN-? in controlling ZIKV infection in the FRT and suggest a path for minimizing sexual transmission of ZIKV in women.

Project description:In order to better understand the female reproductive tract (FRT) we conducted a systematic, comprehensive investigation of the FRT in a tssue-specific manner at three time points relative to mating. By characterizing the transcriptional relationships among discrete FRT tissues across time we advance the understanding of the molecular genetics of FRT functions.

Project description:Bovine reproductive tract sample Metagenome

Project description:Constitutive expression and distinct properties of IFN-epsilon protect the female reproductive tract from Zika virus infection.

Project description:Bovine reproductive tract sample Raw sequence reads

Project description:The female’s reproductive tract is exposed directly to the male’s ejaculate, making it a hotspot for mating-induced responses shortly after mating. In Drosophila melanogaster, changes in the reproductive tract are essential to optimize fertilization. To detect the earliest gene regulatory events that underlie these changes, we measured transcript abundances using RNA-seq and microRNA-seq of reproductive tracts of unmated females and females collected within 10-15 minutes after the end of mating, either to a wildtype male or to a male with defective BMP signaling in secondary cells of the accessory gland, which influences the composition of the male’s ejaculate. We observed transcript abundance changes for genes with roles in tissue morphogenesis, wound healing, the immune response and metabolism. Strikingly, predicted targets of microRNAs that respond to mating are enriched for overlapping functions, suggesting that mating-induced changes are in part regulated by microRNAs. Most of the differentially expressed RNAs are upregulated in response to mating, while most of the differentially expressed microRNAs are downregulated. This pattern suggests a response of activation and de-repression of gene programs that switch the reproductive tract to a “mated” state, rather than a repression of virgin-specific programs. Male genotype did not influence transcript levels, indicating that the earliest transcriptomic responses in the reproductive tract are not dependent on ejaculate components that require BMP signaling in secondary cells. Our results shed light on the molecular changes that accompany very early responses to mating and present candidate genes and microRNAs that can be further examined for their participation in alterations of the reproductive tract microenvironment in response to signals from the male.

Project description:The female’s reproductive tract is exposed directly to the male’s ejaculate, making it a hotspot for mating-induced responses shortly after mating. In Drosophila melanogaster, changes in the reproductive tract are essential to optimize fertilization. To detect the earliest gene regulatory events that underlie these changes, we measured transcript abundances using RNA-seq and microRNA-seq of reproductive tracts of unmated females and females collected within 10-15 minutes after the end of mating, either to a wildtype male or to a male with defective BMP signaling in secondary cells of the accessory gland, which influences the composition of the male’s ejaculate. We observed transcript abundance changes for genes with roles in tissue morphogenesis, wound healing, the immune response and metabolism. Strikingly, predicted targets of microRNAs that respond to mating are enriched for overlapping functions, suggesting that mating-induced changes are in part regulated by microRNAs. Most of the differentially expressed RNAs are upregulated in response to mating, while most of the differentially expressed microRNAs are downregulated. This pattern suggests a response of activation and de-repression of gene programs that switch the reproductive tract to a “mated” state, rather than a repression of virgin-specific programs. Male genotype did not influence transcript levels, indicating that the earliest transcriptomic responses in the reproductive tract are not dependent on ejaculate components that require BMP signaling in secondary cells. Our results shed light on the molecular changes that accompany very early responses to mating and present candidate genes and microRNAs that can be further examined for their participation in alterations of the reproductive tract microenvironment in response to signals from the male.