T helper type 1 (T(H)1) cell development involves interferon-gamma (IFN-gamma) signaling through signal transducer and activator of transcription 1 (STAT1) and interleukin-12 (IL-12) signaling through STAT4 activation. We examined here T-bet regulation and evaluated the actions of T-bet in STAT1- and STAT4-dependent T(H)1 development processes. We found that T-bet expression during T cell activation was strongly dependent on IFN-gamma signaling and STAT1 activation, but was independent of STAT4. Ectopic T-bet expression strongly increased IFN-gamma production in T(H)2 cells activated by PMA-ionomycin, but weakly increased IFN-gamma production in T(H)2 cells stimulated by IL-12 IL-18 or OVA peptide antigen-presenting cell stimulation. In contrast, IL-12 IL-18 induced IFN-gamma production remained STAT4-dependent despite ectopic T-bet expression. Ectopic T-bet expression selectively induced expression of IL-12Rbeta2, but not IL-18Ralpha, in wild-type and STAT1(-/-) T(H)2 cells, but did not extinguish expression of GATA-3 and T(H)2 cytokines. Finally, ectopic T-bet did not directly induce expression of endogenous T- bet independently of IFN-gamma or STAT1. Thus, T-bet is induced by IFN-gamma and STAT1 signaling during T cell activation. In addition, T-bet mediates STAT1-dependent processes of T(H)1 development, including the induction of IL-12Rbeta2.
SlllnmaryInterleukin 12 initiates the differentiation of naive CD4 + T ceils to T helper type 1 (Thl) cells critical for resistance to intracellular pathogens such as Leishmania major. To explore the basis of IL-12 action, we analyzed induction of nuclear factors in Thl cells. IL-12 selectively induced nuclear DNA-binding complexes that contained Star3 and Stat4, recently cloned members of the family of signal transducers and activators of transcription (STATs). While Stat3 participates in signaling for several other cytokines, Stat4 was not previously known to participate in the signaling pathway for any natural ligand. The selective activation of Stat4 provides a basis for unique actions of IL-12 on Thl development. Thus, this study presents the first identification of the early events in IL-12 signaling in T cells and of ligand activation of Stat4.
Developmental-commitment to Th1 or Th2 responses critically influences host susceptibility to particular pathogens. We describe a novel mechanism governing stable commitment to Th2 differentiation. Naive T cells develop strongly polarized Th1 and Th2 profiles by 7 days after activation. However, commitment of these developing cells differs substantially. Although IL-4 reverses early Th1 differentiation, IL-12 cannot reverse early Th2 differentiation. Th1 reversibility results from maintenance of IL-4 signal transduction, whereas Th2 commitment results from rapid loss of IL-12 signaling. The IL-12 signaling defect in Th2 cells results in failure to phosphorylate Jak2, Stat3, and Stat4. Since Th2 cells express the mRNA for the cloned murine IL-12 receptor beta subunit, the signaling defect may involve expression or function of unidentified receptor components. The rapid extinction of IL-12 signaling in Th2 cells provides a demonstration of a mechanism for the stable commitment to a T helper phenotype.
Epstein–Barr virus (EBV) latent infection membrane protein 1 (LMP1)-induced NF-κB activation is important for infected cell survival. LMP1 activates NF-κB, in part, by engaging tumor necrosis factor (TNF) receptor-associated factors (TRAFs), which also mediate NF-κB activation from LTβR and CD40. LTβR and CD40 activation of p100/NF-κB2 is now known to be NIK/IKKα-dependent and IKKβ/IKKγ independent. In the experiments described here, we found that EBV LMP1 induced p100/NF-κB2 processing in human lymphoblasts and HEK293 cells. LMP1-induced p100 processing was NIK/IKKα dependent and IKKβ/IKKγ independent. Furthermore, the LMP1 TRAF-binding site was required for p100 processing and p52 nuclear localization, whereas the LMP1 death domain-binding site was not. Moreover, the LMP1 TRAF-binding site preferentially caused RelB nuclear accumulation. In murine embryo fibroblasts (MEFs), IKKβ was essential for LMP1 up-regulation of macrophage inflammatory protein (MIP)-2, TNFα, I-TAC, ELC, MIG, and CXCR4 RNAs. Interestingly, in IKKα knockout MEFs, LMP1 hyperinduced MIP-2, TNFα, and I-TAC expression, consistent with a role for IKKα in down-modulating canonical IKKβ activation or its effects. In contrast, LMP1 failed to up-regulate CXCR4 and MIG RNA in IKKα knockout MEFs, indicating a dependence on noncanonical IKKα activation. Furthermore, LMP1 up-regulation of MIP-2 RNA in MEFs was both IKKβ- and IKKγ-dependent, whereas LMP1 upregulation of MIG and I-TAC RNA was fully IKKγ independent. Thus, LMP1 induces typical canonical IKKβ/IKKγ-dependent, atypical canonical IKKβ-dependent/IKKγ-independent, and noncanonical NIK/IKKα-dependent NF-κB activations; NIK/IKKα-dependent NF-κB activation is principally mediated by the LMP1 TRAF-binding site.
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