TAK1 and IKK2, novel mediators of SCF-induced signaling and potential targets for c-Kit-driven diseases

Sebastian Drube,Anne Dudeck,Christiane Göpfert,Thomas Kamradt,Tobias Löhn,Florian R Greten,Karin Hartmann,Franziska Weber,Julia Ruth,Michaela A Diamanti,Norman Häfner,Oliver H Krämer,Romy Loschinski,Franziska Boelke,Dagmar Schütz,Ralf Stumm,Mandy Rothe

doi:10.18632/oncotarget.5008

Sebastian Drube, Anne Dudeck + Show 15 more

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https://doi.org/10.18632/oncotarget.5008

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NF-κB activation depends on the IKK complex consisting of the catalytically active IKK1 and 2 subunits and the scaffold protein NEMO. Hitherto, IKK2 activation has always been associated with IκBα degradation, NF-κB activation, and cytokine production. In contrast, we found that in SCF-stimulated primary bone marrow-derived mast cells (BMMCs), IKK2 is alternatively activated. Mechanistically, activated TAK1 mediates the association between c-Kit and IKK2 and therefore facilitates the Lyn-dependent IKK2 activation which suffices to mediate mitogenic signaling but, surprisingly, does not result in NF-κB activation. Moreover, the c-Kit-mediated and Lyn-dependent IKK2 activation is targeted by MyD88-dependent pathways leading to enhanced IKK2 activation and therefore to potentiated effector functions. In neoplastic cells, expressing constitutively active c-Kit mutants, activated TAK1 and IKKs do also not induce NF-κB activation but mediate uncontrolled proliferation, resistance to apoptosis and enables IL-33 to mediate c-Kit-dependent signaling. Together, we identified the formation of the c-Kit-Lyn-TAK1 signalosome which mediates IKK2 activation. Unexpectedly, this IKK activation is uncoupled from the NF-κB-machinery but is critical to modulate functional cell responses in primary-, and mediates uncontrolled proliferation and survival of tumor-mast cells. Therefore, targeting TAK1 and IKKs might be a novel approach to treat c-Kit-driven diseases.

Highlights

The IKK complex consists of IKK1/2 and NEMO
Aiming to investigate the SCF-induced signaling in bone marrow-derived mast cells (BMMCs) we unexpectedly found that SCF induces IKK2 activation which was blocked by the c-Kit inhibitor imatinib (Figure 1A)
Compared to the results obtained with ikk2Δ BMMCs, these data show that IKK-inhibitor VII treatment or the reduced IKK2 expression affected the same SCF-induced signaling pathways

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Introduction

The IKK complex consists of IKK1/2 and NEMO. IKK1 and 2 are the catalytically active components whereas NEMO is the regulatory scaffold protein of the IKK complex [1,2,3]. Stimulation of receptors of the TLR/IL-1 (TIR) - or TNFR superfamily results in a polyubiquitinylation-dependent phosphorylation of the serine (S) residue motive, S177/S181 of IKK2. This motive is located in the activation loop of IKK2 [4, 5] and is pivotal for IKK2 activation [5]. Recent publications suggests that receptor tyrosine kinases (RTKs) activate NF-κB via the IKK complex [8, 9]

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