DNA binding and I kappa B inhibition of the cloned p65 subunit of NF-kappa B, a rel-related polypeptide

The sequence and biochemical properties of the product of the cloned cDNA for the p65 subunit of nuclear factor kappa B (NF-kappa B) have been determined. The cDNA has an open reading frame of 549 amino acids capable of encoding a 60 kd protein. NF-kappa B p65 contains an amino-terminal region of 320 amino acids with extensive similarity to the oncogene c-rel and lesser similarity to NF-kappa B p50. In vitro translated p65 forms a DNA-binding complex with NF-kappa B p50, and the binding of this complex can be specifically inhibited by purified I kappa B. Progressive carboxy-terminal deletions of p65 show that, contrary to previous assumptions, p65 does include a DNA-binding domain that in vivo might become activated only through hetero-oligomerization with p50. DNA binding by truncated p65 is inhibited by I kappa B, thus mapping the I kappa B interaction domain to the rel-homologous region and suggesting that I kappa B exerts its inhibitory effect upon NF-kappa B primarily through interaction with p65.     

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.     

Tumor necrosis factor and interleukin-1 lead to phosphorylation and loss of I kappa B alpha: a mechanism for NF-kappa B activation.

Nuclear factor kappa B (NF-kappa B) is a critical regulator of several genes which are involved in immune and inflammation responses. NF-kappa B, consisting of a 50-kDa protein (p50) and a 65-kDa protein (p65), is bound to a cytoplasmic retention protein called I kappa B. Stimulation of cells with a variety of inducers, including cytokines such as tumor necrosis factor and interleukin-1, leads to the activation and the translocation of p50/65 NF-kappa B into the nucleus. However, the in vivo mechanism of the activation process remains unknown. Here, we provide the first evidence that the in vivo mechanism of NF-kappa B activation is through the phosphorylation and subsequent loss of its inhibitor, I kappa B alpha. We also show that both I kappa B alpha loss and NF-kappa B activation are inhibited in the presence of antioxidants, demonstrating that the loss of I kappa B alpha is a prerequisite for NF-kappa B activation. Finally, we demonstrate that I kappa B alpha is rapidly resynthesized after loss, indicating that an autoregulatory mechanism is involved in the regulation of NF-kappa B function. We propose a mechanism for the activation of NF-kappa B through the modification and loss of I kappa B alpha, thereby establishing its role as a mediator of NF-kappa B activation.     

Activation of NF-kappa B in vivo is regulated by multiple phosphorylations.

The activation of nuclear factor kappa B (NF-kappa B) in intact cells is mechanistically not well understood. Therefore we investigated the modifications imposed on NF-kappa B/I kappa B components following stimulation and show that the final step of NF-kappa B induction in vivo involves phosphorylation of several members of the NF-kappa B/I kappa B protein families. In HeLa cells as well as in B cells, TNF-alpha rapidly induced nuclear translocation primarily of p50-p65, but not of c-rel. Both NF-kappa B precursors and I kappa B alpha became strongly phosphorylated with the same kinetics. In addition to the inducible phosphorylation after stimulation, B lymphocytes containing constitutive nuclear NF-kappa B revealed constitutively phosphorylated p65 and I kappa B alpha. Phosphorylation was accompanied by induced processing of the precursors p100 and p105 and by degradation of I kappa B alpha. As an in vitro model we show that phosphorylation of p105 impedes its ability to interact with NF-kappa B, as has been shown before for I kappa B alpha. Surprisingly, even p65, but not c-rel, was phosphorylated after induction in vivo, suggesting that TNF-alpha selectively activates only specific NF-kappa B heteromers and that modifications regulate not only I kappa B molecules but also NF-kappa B molecules. In fact, cellular NF-kappa B activity was phosphorylation-dependent and the DNA binding activity of p65-containing NF-kappa B was enhanced by phosphorylation in vitro. Furthermore, we found that the induction by hydrogen peroxide of NF-kappa B translocation to the nucleus, which is assumed to be triggered by reactive oxygen intermediates, also coincided with incorporation of phosphate into the same subunits that were modified after stimulation by TNF-alpha. Thus, phosphorylation appears to be a general mechanism for activation of NF-kappa B in vivo.     

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.     

Differential phosphorylation of the signal-responsive domain of I kappa B alpha and I kappa B beta by I kappa B kinases

NF-kappa B activity is regulated by its association with the inhibitory I kappa B proteins, among which I kappa B alpha and I kappa B beta are the most abundant. I kappa B proteins are widely expressed in different cells and tissues and bind to similar combinations of NF-kappa B proteins. The degradation of I kappa B proteins allows nuclear translocation of NF-kappa B and hence plays a critical role in NF-kappa B activation. Previous studies have demonstrated that, although both I kappa B proteins are phosphorylated by the same I kappa B kinase (IKK) complex, and their ubiquitination and degradation following phosphorylation are carried out by the same ubiquitination/degradation machinery, their kinetics of degradation are quite different. To better understand the underlying mechanism of the differences in degradation kinetics, we have carried out a systematic, comparative analysis of the ability of the IKK catalytic subunits to phosphorylate I kappa B alpha and I kappa B beta. We found that, whereas IKK alpha is a weak kinase for the N-terminal serines of both I kappa B isoforms, IKK beta is an efficient kinase for those residues in I kappa B alpha. However, IKK beta phosphorylates the N-terminal serines of I kappa B beta far less efficiently, thereby providing an explanation for the slower rate of degradation observed for I kappa B beta. Mutational analysis indicated that the regions around the two N-terminal serines collectively influence the relative phosphorylation efficiency, and no individual residue is critical. These findings provide the first systematic analysis of the ability of I kappa B alpha and I kappa B beta to serve as substrates for IKKs and help provide a possible explanation for the differential degradation kinetics of I kappa B alpha and I kappa B beta.     

A novel complex between the p65 subunit of NF-kappa B and c-Rel binds to a DNA element involved in the phorbol ester induction of the human urokinase gene.

The NF-kappa B subunits, p50 and p65, have extensive sequence homology with the c-rel proto-oncogene and the Drosophila morphogen dorsal. It has recently been shown that in vitro translated c-Rel can bind to DNA and form a complex with p50. However, the conditions for DNA binding of c-Rel in vivo and its DNA sequence specificity have not been established. Here we report the identification a novel heterodimeric complex that binds to a kappa B-like, phorbol ester (TPA) responsive DNA sequence, 5'-GGGAAAGTAC-3', in the 5' flanking region of the human urokinase (uPA) gene. This sequence was shown to bind two protein complexes, LC and UC. LC was indistinguishable from NF-kappa B as it reacted with antibodies recognizing the p50 subunit of NF-kappa B, and was shown by UV crosslinking to contain the p50 and p65 subunits of NF-kappa B. UC, on the other hand, strongly reacted with anti-v-Rel, but not with the anti-p50 antibodies, and was shown by crosslinking to contain 75 kDa and 85 kDa protein-DNA adducts. The 75 kDa and the 85 kDa adducts could be immunoprecipitated only by anti-p65 and anti-c-Rel antibodies, respectively, showing that c-Rel formed a heterodimer with p65. Both protein complexes were present in inactive forms in HeLa cell cytosol, and their nuclear translocation was induced by TPA. DNA binding of UC and LC could, furthermore, be inhibited by I kappa B-alpha.(ABSTRACT TRUNCATED AT 250 WORDS)