Novel splice variants of human IKKε negatively regulate IKKε-induced IRF3 and NF-kB activation.

The inhibitor of κB kinase ε (IKKε) is pivotal for an efficient innate immune response to viral infections and has been recognized as breast cancer oncogene. The antiviral function of IKKε involves activation of the transcription factors IFN regulatory factor 3 (IRF3) and NF-κB, thus inducing the expression of type I IFN. Here, we have identified two novel splice variants of human IKKε, designated IKKε-sv1 and IKKε-sv2, respectively. Interestingly, RT-PCR revealed quantitatively different isoform expression in PBMC from different individuals. Moreover, we found cell type- and stimulus-specific protein expression of the various splice variants. Overexpression of full-length wt IKKε (IKKε-wt) leads to the activation of NF-κB- as well as IRF3-driven luciferase reporter genes. Although none of the splice variants activates IRF3, IKKε-sv1 still activates NF-κB, whereas IKKε-sv2 is also defective in NF-κB activation. Both splice variants form dimers with IKKε-wt and inhibit IKKε-wt-induced IRF3 signaling including the antiviral activity in a dominant-negative manner. The lack of IRF3 activation is likely caused by the failure of the splice variants to interact with the adapter proteins TANK, NAP1, and/or SINTBAD. Taken together, our data suggest alternative splicing as a novel regulatory mechanism suitable to shift the balance between different functions of IKKε.

IFN-γ and IL-12 synergize to convert in vivo generated Th17 into Th1/Th17 cells.

Th1 and Th17 cells are distinct lineages of effector/memory cells, imprinted for re-expression of IFN-γ and IL-17, by upregulated expression of T-bet and retinoic acid-related orphan receptor γt (RORγt), respectively. Apparently, Th1 and Th17 cells share tasks in the control of inflammatory immune responses. Th cells coexpressing IFN-γ and IL-17 have been observed in vivo, but it remained elusive, how these cells had been generated and whether they represent a distinct lineage of Th differentiation. It has been shown that ex vivo isolated Th1 and Th17 cells are not interconvertable by TGF-ß/IL-6 and IL-12, respectively. Here, we show that ex vivo isolated Th17 cells can be converted into Th1/Th17 cells by combined IFN-γ and IL-12 signaling. IFN-γ is required to upregulate expression of the IL-12Rß2 chain, and IL-12 for Th1 polarization. These Th1/Th17 cells stably coexpress RORγt and T-bet at the single-cell level. Our results suggest a molecular pathway for the generation of Th1/Th17 cells in vivo, which combine the pro-inflammatory potential of Th1 and Th17 cells.

Persistence of effector memory Th1 cells is regulated by Hopx.

Th1 cells are prominent in inflamed tissue, survive conventional immunosuppression, and are believed to play a pivotal role in driving chronic inflammation. Here, we identify homeobox only protein (Hopx) as a critical and selective regulator of the survival of Th1 effector/memory cells, both in vitro and in vivo. Expression of Hopx is induced by T-bet and increases upon repeated antigenic restimulation of Th1 cells. Accordingly, the expression of Hopx is low in peripheral, naïve Th cells, but highly up-regulated in terminally differentiated effector/memory Th1 cells of healthy human donors. In murine Th1 cells, Hopx regulates the expression of genes involved in regulation of apoptosis and survival and makes them refractory to Fas-induced apoptosis. In vivo, adoptively transferred Hopx-deficient murine Th1 cells do not persist. Consequently, they cannot induce chronic inflammation in murine models of transfer-induced colitis and arthritis, demonstrating a key role of Hopx for Th1-mediated immunopathology.

Interaction with XIAP prevents full caspase-3/-7 activation in proliferating human T lymphocytes.

Caspases are essential mediators of cytokine release and apoptosis. Additionally, caspase activity is required for the proliferation of naive T lymphocytes. It remained unclear how proliferating cells are able to cope with the pro-apoptotic activity especially of effector caspases-3 and -7. Possible reasons might include limited subcellular localization of active caspases or inhibition by endogenous caspase inhibitors. Here, we compared the activation of various caspases in proliferating human T cells with that in apoptotic cells. We show that cleaved caspases-3/-7 appear to be widely distributed in apoptotic cells while they are largely confined to the cytoplasm in proliferating cells. Additionally, in proliferating T cells caspase-3 remains incompletely cleaved, while in apoptotic cells fully mature caspase-3 is generated. We provide evidence that during T cell proliferation the intracellular caspase inhibitor X-linked inhibitor-of-apoptosis protein (XIAP) interacts with caspases-3/-7, thereby blocking their full activation, substrate cleavage, and cell death. The lack of substrate cleavage might also lead to the observed limited subcellular distribution of caspases-3/-7. After induction of apoptosis, second mitochondria-derived activator of caspases/direct inhibitor of apoptosis-binding protein with low isoelectric point (Smac/DIABLO) is released from mitochondria, resulting in the abrogation of the inhibitory effect of XIAP, full activation of caspases-3/-7, and apoptosis.