Counter-Regulation of Human Cd4+ T Helper 2 Lymphocyte Development and Stability by Type I Interferon
Huber, Jonathan Philip
MetadataShow full item record
Innate cytokines shape the differentiation of CD4+ T cells from naïve precursors into multiple functional subsets in order carry out effective adaptive immune responses to diverse immunological stimuli. Interleukin-12 controls the development of T helper 1 (Th1) cells, which fight infection by intracellular pathogens such as bacteria and viruses. Helminth parasites and allergens induce the production of IL-4, which drives differentiation to Th2. The IL-12 and IL-4 signaling pathways also counter-regulate each other, though this balance favors Th2 as IL-4 signaling overrides the effects of IL-12. In addition, IL-4 induces expression of the GATA3 transcription factor that stabilizes the Th2 phenotype through auto-regulatory maintenance of its own expression. A role for type I interferon (IFN-a/b), a major antiviral cytokine, has been described more recently in Th1 cells, but the potential role of IFN-a/b in counter-regulating Th2 development is poorly understood. My work reveals that IFN-a/b blocks IL-4-induced Th2 differentiation of human CD4+ T cells by inhibiting expression of GATA3. The loss of GATA3 in developing Th2 cells leads to reduced secretion of the Th2 cytokines, IL-4, IL-5, and IL-13, and reduced expression of chemoattractant receptor expressed in Th2 cells (CRTh2). IFN-a/b also suppresses GATA3 in committed Th2 cells, leading to a loss of the Th2 phenotype. GATA3 transcription utilizes two distinct first exons, exon 1A and 1B, which are controlled by separate promoters, but IL-4 signaling in Th2 cells leads to preferential utilization of the upstream exon 1A transcript. IFN-a specifically blocks expression of the 1A but not 1B transcript, indicating a specific regulation of Th2 cells. Furthermore, IFN-a appears to induce epigenetic silencing of an upstream conserved non-coding sequence I, which may be required for optimal exon 1A transcription in Th2 cells. This work reveals an unexpected role for IFN-a in selectively inhibiting Th2 but not Th1 differentiation, which may be important for ensuring appropriate development of antiviral immunity. In addition, the ability of IFN-a to suppress both developing Th2 cells and previously committed Th2 cells suggests that IFN-a may be useful as a novel therapeutic for atopic diseases.