Abstract
Although type I interferons (IFNs) were first described almost 60 years ago, the ability to monitor and modulate the functional activities of the individual IFN subtypes that comprise this family has been hindered by a lack of reagents. The major type I IFNs, IFN-β and the multiple subtypes of IFN-α, are expressed widely and induce their effects on cells by interacting with a shared heterodimeric receptor (IFNAR). In the mouse, the physiologic actions of IFN-α and IFN-β have been defined using polyclonal anti-type I IFN sera, by targeting IFNAR using monoclonal antibodies or knockout mice, or using Ifnb-/- mice. However, the corresponding analysis of IFN-α has been difficult because of its polygenic nature. Herein, we describe two monoclonal antibodies (mAbs) that differentially neutralize murine IFN-β or multiple subtypes of murine IFN-α. Using these mAbs, we distinguish specific contributions of IFN-β versus IFN-α in restricting viral pathogenesis and identify IFN-α as the key mediator of the antiviral response in mice infected with West Nile virus. This study thus suggests the utility of these new reagents in dissecting the antiviral and immunomodulatory roles of IFN-β versus IFN-α in murine models of infection, immunity, and autoimmunity.
Highlights
The type I interferons (IFNs), first identified by their ability to control viral infection [1, 2], are known to contribute broadly to innate and adaptive immunity [3]
We describe two monoclonal antibodies that differentially neutralize murine IFN-β or multiple subtypes of murine IFN-α. Using these mAbs, we distinguish specific contributions of IFN-β versus IFN-α in restricting viral pathogenesis and identify IFN-α as the key mediator of the antiviral response in mice infected with West Nile virus
Using a mouse model of West Nile virus (WNV) infection, we demonstrate the efficacy of these neutralizing mAbs in vivo and identify distinct roles for IFN-β and IFN-α in controlling WNV pathogenesis
Summary
The type I interferons (IFNs), first identified by their ability to control viral infection [1, 2], are known to contribute broadly to innate and adaptive immunity [3]. The type I IFN family includes IFN-β (encoded by a single gene), multiple IFN-α subtypes (14 genes and 3 pseudogenes), IFN-z (limitin) [4], IFN-ε [5, 6] and IFN-κ [7, 8]. The type I IFNs are encoded by single exon genes (with the exception of IFN-κ, which contains 1 intron) of similar structure, size, and conservation of protein sequence [6, 9, 10] but with divergent regulatory elements [11, 12]. Type I IFNs are induced after microbial products are sensed via pattern-
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