NF-κB WebModel
ver 2.1 experimental

Title

A homeostatic model of IkB metabolism to control constitutive activity

Authors

O'Dea, E.L., Barken, D., Peralta, R.Q., Tran K.T., Werner, S.L., Kearns, J.D., Levchenko, A., Hoffmann, A.

Abstract

Cellular signal transduction pathways are usually studied following administration of an external stimulus. However, disease-associated aberrant activity of the pathway is often due to misregulation of the equilibrium state. The transcription factor NF-kappaB is typically described as being held inactive in the cytoplasm by binding its inhibitor, IkappaB, until an external stimulus triggers IkappaB degradation through an IkappaB kinase-dependent degradation pathway. Combining genetic, biochemical, and computational tools, we investigate steady-state regulation of the NF-kappaB signaling module and its impact on stimulus responsiveness. We present newly measured in vivo degradation rate constants for NF-kappaB-bound and -unbound IkappaB proteins that are critical for accurate computational predictions of steady-state IkappaB protein levels and basal NF-kappaB activity. Simulations reveal a homeostatic NF-kappaB signaling module in which differential degradation rates of free and bound pools of IkappaB represent a novel cross-regulation mechanism that imparts functional robustness to the signaling module.

Title

A homeostatic model of IkB metabolism to control constitutive activity

Authors

O'Dea, E.L., Barken, D., Peralta, R.Q., Tran K.T., Werner, S.L., Kearns, J.D., Levchenko, A., Hoffmann, A.

Abstract

Cellular signal transduction pathways are usually studied following administration of an external stimulus. However, disease-associated aberrant activity of the pathway is often due to misregulation of the equilibrium state. The transcription factor NF-kappaB is typically described as being held inactive in the cytoplasm by binding its inhibitor, IkappaB, until an external stimulus triggers IkappaB degradation through an IkappaB kinase-dependent degradation pathway. Combining genetic, biochemical, and computational tools, we investigate steady-state regulation of the NF-kappaB signaling module and its impact on stimulus responsiveness. We present newly measured in vivo degradation rate constants for NF-kappaB-bound and -unbound IkappaB proteins that are critical for accurate computational predictions of steady-state IkappaB protein levels and basal NF-kappaB activity. Simulations reveal a homeostatic NF-kappaB signaling module in which differential degradation rates of free and bound pools of IkappaB represent a novel cross-regulation mechanism that imparts functional robustness to the signaling module.

Title

IkBe provides negative feedback to control NF-kB oscillations, signaling dynamics, and inflammatory gene expression.

Authors

Kearns, J.D., Basak, S., Werner, S.L., Huang, C.S., Hoffmann, A.

Abstract

NF-kappaB signaling is known to be critically regulated by the NF-kappaB-inducible inhibitor protein IkappaBalpha. The resulting negative feedback has been shown to produce a propensity for oscillations in NF-kappaB activity. We report integrated experimental and computational studies that demonstrate that another IkappaB isoform, IkappaBepsilon, also provides negative feedback on NF-kappaB activity, but with distinct functional consequences. Upon stimulation, NF-kappaB-induced transcription of IkappaBepsilon is delayed, relative to that of IkappaBalpha, rendering the two negative feedback loops to be in antiphase. As a result, IkappaBepsilon has a role in dampening IkappaBalpha-mediated oscillations during long-lasting NF-kappaB activity. Furthermore, we demonstrate the requirement of both of these distinct negative feedback regulators for the termination of NF-kappaB activity and NF-kappaB-mediated gene expression in response to transient stimulation. Our findings extend the capabilities of a computational model of IkappaB-NF-kappaB signaling and reveal a novel regulatory module of two antiphase negative feedback loops that allows for the fine-tuning of the dynamics of a mammalian signaling pathway.