The NF-kappa B precursor p105 and the proto-oncogene product Bcl-3 are I kappa B molecules and control nuclear translocation of NF-kappa B.

We have examined the interaction of the NF-kappa B precursor p105 with NF-kappa B subunits. Similar to an I kappa B molecule, p105 associates in the cytoplasm with p50 or p65. Through this assembly, p105 efficiently blocks nuclear transfer of either subunit. Moreover, the p105 protein inhibits DNA binding of dimeric NF-kappa B subunits in a similar, but not identical, manner to its isolated C-terminal domain, which contains an ankyrin-like repeat domain (ARD). The proto-oncogene product Bcl-3 also controls nuclear translocation of p50, but not of p65. Hence, p50 can be retained in the cytoplasm via at least three distinct interactions: through direct interactions either with its own precursor, with Bcl-3 or indirectly through I kappa B alpha or -beta when attached to p65. We discuss a function of p105 as a cytoplasmic assembly unit for homo- and heteromeric NF-kappa B complexes and of Bcl-3 as an I kappa B with novel subunit specificity.     

Inhibition of I kappa B-alpha phosphorylation and degradation and subsequent NF-kappa B activation by glutathione peroxidase overexpression

We report here that both kappa B-dependent transactivation of a reporter gene and NF-kappa B activation in response to tumor necrosis factor (TNF alpha) or H2O2 treatments are deficient in human T47D cell transfectants that overexpress seleno-glutathione peroxidase (GSHPx). These cells feature low reactive oxygen species (ROS) levels and decreased intracellular ROS burst in response to TNF alpha treatment. Decreased ROS levels and NF-kappa B activation were likely to result from GSHPx increment since these phenomena were no longer observed when GSHPx activity was reduced by selenium depletion. The cellular contents of the two NF-kappa B subunits (p65 and p50) and of the inhibitory subunit I kappa B-alpha were unaffected by GSHPx overexpression, suggesting that increased GSHPx activity interfered with the activation, but not the synthesis or stability, of Nf-kappa B. Nuclear translocation of NF-kappa B as well as I kappa B-alpha degradation were inhabited in GSHPx-overexpressing cells exposed to oxidative stress. Moreover, in control T47D cells exposed to TNF alpha, a time correlation was observed between elevated ROS levels and I kappa B- alpha degradation. We also show that, in growing T47D cells, GSHPx overexpression altered the isoform composition of I kappa B-alpha, leading to the accumulation of the more basic isoform of this protein. GSHPx overexpression also abolished the TNF alpha-mediated transient accumulation of the acidic and highly phosphorylated I kappa B-alpha isoform. These results suggest that intracellular ROS are key elements that regulate the phosphorylation of I kappa B-alpha, a phenomenon that precedes and controls the degradation of this protein, and then NF- kappa B activation.     

Mechanism of I kappa B alpha binding to NF-kappa B dimers

X-ray crystal structures of the NF-kappa B.I kappa B alpha complex revealed an extensive and complex protein-protein interface involving independent structural elements present in both I kappa B alpha and NF-kappa B. In this study, we employ a gel electrophoretic mobility shift assay to assess and quantitate the relative contributions of the observed interactions toward overall complex binding affinity. I kappa B alpha preferentially binds to the p50/p65 heterodimer and p65 homodimer, with binding to p50 homodimer being significantly weaker. Our results indicate that the nuclear localization sequence and the region C-terminal to it of the NF-kappa B p65 subunit is a major contributor to NF-kappa B. I kappa B alpha complex formation. Additionally, there are no contacts between the corresponding nuclear localization signal tetrapeptide of p50 and I kappa B alpha. A second set of interactions involving the acidic C-terminal/PEST-like region of I kappa B alpha and the NF-kappa B p65 subunit N-terminal domain also contributes binding energy toward formation of the complex. This interaction is highly dynamic and nonspecific in nature, as shown by oxidative cysteine cross-linking. Phosphorylation of the C-terminal/PEST-like region by casein kinase II further enhances binding.     

Common structural constituents confer I kappa B activity to NF-kappa B p105 and I kappa B/MAD-3.

The vertebrate NF-kappa B/c-rel inhibitors MAD-3/I kappa B alpha, I kappa B gamma/pdI and bcl-3 all share a conserved ankyrin repeat domain (ARD) consisting of six complete repeats, a short acidic motif and/or an incomplete seventh repeat. We present here a detailed analysis of the domain in p105/pdI and MAD-3/I kappa B involved in inhibition of DNA binding and in protein interaction with rel factors. We demonstrate that in both cases an acidic region and six ankyrin-like repeats are sufficient and required for protein interaction with the rel factors. However, for p105/pdI to achieve the high affinity needed to suppress DNA binding, an incomplete seventh repeat is required in addition. Both pdI and MAD-3 associate with rel proteins by forming heterotrimeric complexes, as shown by native gel analysis and by cross-linking. Furthermore, we demonstrate that deletion of only three amino acids in the first repeat converts the subunit specificity of the p105 ARD into that of MAD-3/I kappa B. We conclude that functionally the ARD in these molecules has a modular structure, with different subregions determining the specificity for the NF-kappa B subunits p50 and p65.     

NF-kappa B regulation by I kappa B kinase-2 in rheumatoid arthritis synoviocytes

IkappaB kinase-1 and IkappaB kinase-2 (IKK1 and IKK2; also called IKKalpha and IKKbeta, respectively) are part of the signal complex that regulates NF-kappaB activity in many cell types, including fibroblast-like synoviocytes (FLS). We determined which of these two kinases is responsible for cytokine-induced NF-kappaB activation in synoviocytes and assessed the functional consequences of IKK1 or IKK2 overexpression and inhibition. FLS were infected with adenovirus constructs encoding either wild-type (wt) IKK1 or IKK2, the dominant negative (dn) mutant of both kinases, or a control construct encoding green fluorescence protein. Analysis of the NF-kappaB pathway revealed that cytokine-induced IKK activation, IkappaB degradation, and NF-kappaB activation was prevented in cells expressing the IKK2 dn mutant, whereas baseline NF-kappaB activity was increased by IKK2 wt. In addition, synthesis of IL-6 and IL-8, as well as expression of ICAM-1 and collagenase, was only increased by IKK2 wt, and their cytokine-induced production was abrogated by IKK2 dn mutant. However, the IKK1 dn mutant did not inhibit cytokine-mediated activation of NF-kappaB or any of the functional assays. These data indicate that IKK2 is the key convergence pathway for cytokine-induced NF-kappaB activation. Furthermore, IKK2 regulates adhesion molecule, matrix metalloproteinase, and cytokine production in FLS.     

Reductions in I kappa B epsilon and changes in NF-kappa B activity during B lymphocyte differentiation

The levels and stability of IkappaBepsilon have been examined in unstimulated and stimulated splenic B cells and compared with that of IkappaBalpha and IkappaBbeta. Primary murine splenic B cells but not T cells were found to contain high levels of IkappaBepsilon protein, equivalent to levels of the abundant IkappaBalpha. Most agents that activate IkappaBalpha and IkappaBbeta degradation do not induce rapid degradation of IkappaBepsilon. Interestingly, however, the levels of IkappaBepsilon, but not of IkappaBalpha or IkappaBbeta, are dramatically reduced upon the stimulation of B cells both in vivo and in vitro. Since IkappaBepsilon exhibits substrate specificity for NF-kappaB Rel homodimers, this suggested the possibility that changes in NF-kappaB-responsive genes might also occur during this transition. Consistent with this hypothesis, we found that a NF-kappaB reporter construct sensitive to p65/RelA homodimers is activated at the time that IkappaBepsilon levels decline following B cell stimulation. In IgG(+) B cell lines, which contain low levels of IkappaBepsilon, this same reporter construct was inactive, suggesting that the increases in Rel homodimer activity that accompany B cell stimulation are transient. However, there are differences in the level of expression of NF-kappaB-responsive genes in these IgG(+) B cell lines compared with their IgM(+) counterparts. From these data, we conclude that there are transient changes in NF-kappaB activity due to reductions in IkappaBepsilon, which might contribute to long-term, persistent changes that accompany B cell differentiation. We propose an important role for IkappaBepsilon in the differential regulation of nuclear NF-kappaB activity in stimulated B cells.