IFN-lambda 3 directly induces antiviral responses in human B and T cells leading to inhibition of HIV-1 infection of CD4+ T cells

Abstract

Abstract Type III interferons (IFN-lambdas(λ)) are the most recently discovered interferon cytokine family that inhibit viruses by signaling through a unique IFN-λR1/IL-10RB heterodimeric receptor. Until now, IFN-λs were thought to primarily act on anatomical barrier epithelial cells, neutrophils and a subset of dendritic cells, although the majority of studies have been performed in mice. Here, we examine regulation of IFN-λR1 expression and downstream effects of IFN-λ3 stimulation of primary human blood immune cells and compare them to lung or liver epithelial cells. IFN-λ3 directly bound and upregulated IFN-stimulated gene (ISG) expression in freshly purified human B cells and CD8+ T cells, but not monocytes, neutrophils, natural killer cells and CD4+ T cells. Despite similar IFNLR1 transcript levels in B cells and lung epithelial cells, lung epithelial cells bound more IFN-λ3, which resulted in a 50-fold greater ISG induction when compared to B cells. The reduced response of B cells could be explained by the higher expression of the soluble splice variant of IFN-λR1, which inhibited ISG induction when added with IFN-λ3 to peripheral blood mononuclear cells. Human CD4+ T cells gained responsiveness to IFN-λ3 upon T-cell receptor stimulation since activation signals potently, and specifically upregulated membrane-bound IFN-λR1 expression. Importantly, IFN-λ3 treatment of activated CD4+ T cells caused a significant decrease in human immunodeficiency virus-1 (HIV-1) infection. Collectively, our data demonstrate that IFN-λ3 directly interacts with the human adaptive immune system, and thus can promote antiviral immunity at mucosal and peripheral sites, unlike what has been previously shown in published mouse models.