NF-κB-inducible BCL-3 Expression Is an Autoregulatory Loop Controlling Nuclear p50/NF-κB1 Residence

Muping Lu,Istvan Boldogh,Allan R Brasier,Ying Lu,Tao Hai

doi:10.1074/jbc.m102949200

Muping Lu, Istvan Boldogh + Show 3 more

Open Access

https://doi.org/10.1074/jbc.m102949200

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Abstract

NF-kappa B is a transcription factor whose nuclear residence is controlled by I kappa B family members. In the NF-kappa B-I kappa B autoregulatory loop, activated (nuclear) Rel A.NF-kappa B1 induces the resynthesis of I kappa B alpha recapturing nuclear Rel A back into the cytoplasm within 1 h of stimulation. In contrast, NF-kappa B1 subunits redistribute more slowly into the cytoplasm (from 6 to 12 h). Here we examine the role of inducible cytoplasmic BCL-3 expression in terminating nuclear NF-kappa B1. Although BCL-3 is a nuclear protein in B lymphocytes, surprisingly, BCL-3 is primarily a cytoplasmic protein in HepG2 cells. Cytoplasmic BCL-3 abundance is induced 6-12 h after tumor necrosis factor-alpha stimulation where it complexes with NF-kappa B1 homodimers. Moreover, BCL-3 mRNA and protein expression are induced by NF-kappa B-activating agents. Two observations are interpreted to indicate that bcl-3 is transactivated by NF-kappa B/Rel A: 1) expression of a dominant negative NF-kappa B inhibitor blocks tumor necrosis factor-alpha-induced BCL-3 expression and 2) expression of constitutively active Rel A is sufficient to induce BCL-3 expression. In gene transfer studies, we identify two high affinity NF-kappa B-binding sites, kappa B1 (located at -872 to -861 nucleotides) and kappa B2 (-106 to -96 nucleotides), and although both bind with high affinity to Rel A, only kappa B2 is required for NF-kappa B-dependent induction of the native BCL-3 promoter. Down-regulation of BCL-3 induction results in prolonged, enhanced NF-kappa B1 binding and increased NF-kappa B-dependent transcription. Together, these data suggest the presence of an NF-kappa B-BCL-3 autoregulatory loop important in terminating NF-kappa B1 action and that individual NF-kappa B isoforms are actively terminated through coordinate induction of inhibitory I kappa B molecules to restore cellular homeostasis.

Highlights

Characterized as a nuclear transactivator of the immunoglobulin ␬-light chain enhancer, NF-␬B is known to be a cytokine-inducible transcription factor controlling expression of genetic networks important in inflammation and cellular survival [1,2,3,4]
We previously demonstrated that the complete disappearance of the NF-␬B11⁄7Rel A binding 1 h after stimulation is due to the NF-␬B-I␬B␣ autoregulatory feedback loop, where a rapid resynthesis of I␬B␣ reassociates with Rel A and inactivates it in the cytoplasm where its reassociation can be directly measured by coimmunoprecipitation [5, 15]
Site mutations of the BCL-3 ␬B1 and ␬B2 elements were constructed in the Ϫ916/ϩ37 BCL-3 promoter backbone and transfected into HepG2 cells in the presence of empty vector (GFP) or RelA (EGFP-RelA) expression vector

Summary

Introduction

Characterized as a nuclear transactivator of the immunoglobulin ␬-light chain enhancer (the ␬B enhancer), NF-␬B is known to be a cytokine-inducible transcription factor controlling expression of genetic networks important in inflammation and cellular survival [1,2,3,4]. In the NF-␬B-I␬B␣ feedback loop, nuclear translocated NF-␬B activates transcription of target genes, including I␬B␣ itself, containing multiple NF-␬B-binding sites in its proximal promoter [10, 12, 13]. The first group consists of members translated as mature proteins that contain potent COOH-terminal transcriptional activation domains, such as Rel A and c-Rel, and are targets for inactivation by the prototypical I␬B-␣, -␤, and -⑀ [7, 17,18,19]. The second group consists of members encoded by large precursor proteins that are proteolytically processed into smaller (ϳ50 kDa) DNA-binding subunits with weak transcriptional activation potential, such as p105/NF-␬B1 and p110/NF-. Its function is enigmatic, BCL-3 has been reported to inhibit NF-␬B1 binding in vitro [23], disrupt NF-␬B1 p105-p50 subunit interactions [24], and function as a transcriptional activator by forming ternary complexes with DNA bound NF-␬B2, allowing recruitment of coactivators and histone acetylases [25, 26]

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