Abstract
Activation of nuclear factor κB (NF-κB) by interleukin-1β (IL-1) usually results in an anti-apoptotic activity that is rapidly terminated by a negative feedback loop involving NF-κB dependent resynthesis of its own inhibitor IκBα. However, apoptosis induced by ultraviolet B radiation (UVB) is not attenuated, but significantly enhanced by co-stimulation with IL-1 in human epithelial cells. Under these conditions NF-κB remains constitutively active and turns into a pro-apoptotic factor by selectively repressing anti-apoptotic genes. Two different mechanisms have been separately proposed to explain UV-induced lack of IκBα recurrence: global translational inhibition as well as deactivation of the Ser/Thr phosphatase PP2Ac. Using mathematical modelling, we show that the systems behaviour requires a combination of both mechanisms, and we quantify their contribution in different settings. A mathematical model including both mechanisms is developed and fitted to various experimental data sets. A comparison of the model results and predictions with model variants lacking one of the mechanisms shows that both mechanisms are present in our experimental setting. The model is successfully validated by the prediction of independent data. Weak constitutive IKKβ phosphorylation is shown to be a decisive process in IκBα degradation induced by UVB stimulation alone, but irrelevant for (co-)stimulations with IL-1. In silico knockout experiments show that translational inhibition is predominantly responsible for lack of IκBα recurrence following IL-1+UVB stimulation. In case of UVB stimulation alone, cooperation of both processes causes the observed decrease of IκBα. This shows that the processes leading to activation of transcription factor NF-κB upon stimulation with ultraviolet B radiation with and without interleukin-1 costimulation are more complex than previously thought, involving both a cross talk of UVB induced translational inhibition and PP2Ac deactivation. The importance of each of the mechanisms depends on the specific cellular setting.
Highlights
The transcription factor nuclear factor kB (NF-kB) is of fundamental importance in anti-apoptotic signalling and inflammation, since it is activated by a multitude of stimuli, and causes a wide range of cellular responses
We show that unlike translational inhibition, ultraviolet B radiation (UVB)-induced PP2Ac deactivation is crucial for sustained NF-kB activity in human epithelial cells following IL-1+ UVB stimulation, while both processes are required to induce inhibitor of kBa (IkBa) degradation following UVB irradiation alone
We showed that our minimal model of the NF-kB signalling pathway is completely sufficient to describe NF-kB signalling following various stimulations including different combinations of IL-1, UVB, MG132, and CHX
Summary
The transcription factor nuclear factor kB (NF-kB) is of fundamental importance in anti-apoptotic signalling and inflammation, since it is activated by a multitude of stimuli, and causes a wide range of cellular responses. Constitutive NF-kB activation contributes to the maintenance of a variety of cancers by inducing expression of anti-apoptotic genes [1,2]. Manifold strategies to fight cancer are based on NF-kB inhibition [1,3]. Almost all NF-kB resides in the cytosol and is kept inactive by its binding to the inhibitor of kBa (IkBa). Its catalytic subunit IKKb is phosphorylated at Ser177/ 181 [4] and subsequently phosphorylates the NF-kB inhibitor IkBa at Ser32/36. IkBa becomes polyubiquitinated and is proteasomally degraded, liberating NF-kB
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