p100/IκBδ sequesters and inhibits NF-κB through kappaBsome formation.

Degradation of I kappaB (κB) inhibitors is critical to activation of dimeric transcription factors of the NF-κB family. There are two types of IκB inhibitors: the prototypical IκBs (IκBα, IκBß, and IκBε), which form low-molecular-weight (MW) IκB:NF-κB complexes that are highly stable, and the precursor IκBs (p105/IκBγ and p100/IκBδ), which form high-MW assemblies, thereby suppressing the activity of nearly half the cellular NF-κB [Savinova OV, Hoffmann A, Ghosh G (2009) Mol Cell 34(5):591-602]. The identity of these larger assemblies and their distinct roles in NF-κB inhibition are unknown. Using the X-ray crystal structure of the C-terminal domain of p100/IκBδ and functional analysis of structure-guided mutants, we show that p100/IκBδ forms high-MW (IκBδ)4:(NF-κB)4 complexes, referred to as kappaBsomes. These IκBδ-centric "kappaBsomes" are distinct from the 2:2 complexes formed by IκBγ. The stability of the IκBδ tetramer is enhanced upon association with NF-κB, and hence the high-MW assembly is essential for NF-κB inhibition. Furthermore, weakening of the IκBδ tetramer impairs both its association with NF-κB subunits and stimulus-dependent processing into p52. The unique ability of p100/IκBδ to stably interact with all NF-κB subunits by forming kappaBsomes demonstrates its importance in sequestering NF-κB subunits and releasing them as dictated by specific stimuli for developmental programs.

A structural basis for IκB kinase 2 activation via oligomerization-dependent trans auto-phosphorylation.

Activation of the IκB kinase (IKK) is central to NF-κB signaling. However, the precise activation mechanism by which catalytic IKK subunits gain the ability to induce NF-κB transcriptional activity is not well understood. Here we report a 4 Å x-ray crystal structure of human IKK2 (hIKK2) in its catalytically active conformation. The hIKK2 domain architecture closely resembles that of Xenopus IKK2 (xIKK2). However, whereas inactivated xIKK2 displays a closed dimeric structure, hIKK2 dimers adopt open conformations that permit higher order oligomerization within the crystal. Reversible oligomerization of hIKK2 dimers is observed in solution. Mutagenesis confirms that two of the surfaces that mediate oligomerization within the crystal are also critical for the process of hIKK2 activation in cells. We propose that IKK2 dimers transiently associate with one another through these interaction surfaces to promote trans auto-phosphorylation as part of their mechanism of activation. This structure-based model supports recently published structural data that implicate strand exchange as part of a mechanism for IKK2 activation via trans auto-phosphorylation. Moreover, oligomerization through the interfaces identified in this study and subsequent trans auto-phosphorylation account for the rapid amplification of IKK2 phosphorylation observed even in the absence of any upstream kinase.

NF-κB regulation: lessons from structures.

The signaling module that specifies nuclear factor-κΒ (NF-κB) activation is a three-component system: NF-κB, inhibitor of NF-κΒ (IκΒ), and IκΒ kinase complex (IKK). IKK receives upstream signals from the surface or inside the cell and converts itself into a catalytically active form, leading to the destruction of IκB in the inhibited IκB:NF-κB complex, leaving active NF-κB free to regulate target genes. Hidden within this simple module are family members that all can undergo various modifications resulting in expansion of functional spectrum. Three-dimensional structures representing all three components are now available. These structures have allowed us to interpret cellular observations in molecular terms and at the same time helped us to bring forward new concepts focused towards understanding the specificity in the NF-κB activation pathway.

NF-kappaB p52:RelB heterodimer recognizes two classes of kappaB sites with two distinct modes.

The X-ray structure of the nuclear factor-kappaB (NF-kappaB) p52:RelB:kappaB DNA complex reveals a new recognition feature not previously seen in other NF-kappaB:kappaB DNA complexes. Arg 125 of RelB is in contact with an additional DNA base pair. Surprisingly, the p52:RelB R125A mutant heterodimer shows defects both in DNA binding and in transcriptional activity only to a subclass of kappaB sites. We found that the Arg 125-sensitive kappaB sites contain more contiguous and centrally located A:T base pairs than do the insensitive sites. A protein-induced kink observed in this complex, which used an AT-rich kappaB site, might allow the DNA contact by Arg 125; such a kink might not be possible in complexes with non-AT-rich kappaB sites. Furthermore, we show that the p52:RelB heterodimer binds to a broader spectrum of kappaB sites when compared with the p50:RelA heterodimer. We suggest that the p52:RelB heterodimer is more adaptable to complement sequence and structural variations in kappaB sites when compared with other NF-kappaB dimers.

Crystal structure of a free kappaB DNA: insights into DNA recognition by transcription factor NF-kappaB.

The dimeric NF-kappaB transcription factors regulate gene expression by recognizing specific DNA sequences located within the promoters of target genes. The DNA sequences, referred to as kappaB DNA, are divided into two broad classes. Class I kappaB DNA binds optimally to p50 and p52 NF-kappaB subunits, while class II kappaB DNAs are recognized specifically by the NF-kappaB subunits c-Rel and p65. We determined the X-ray crystal structure of a class II kappaB DNA sequence at 1.60 A resolution. This structure provides a detailed picture of kappaB DNA hydration, counter ion binding, and conformation in the absence of NF-kappaB binding partner. X-ray structures of both class I and class II kappaB DNA bound to NF-kappaB dimers were determined previously. Additionally, the NMR solution structure of a class I kappaB DNA is known. Comparison of the protein-bound and unbound kappaB DNA structures reveals that the free form of both classes approximates ideal B-form DNA more closely. Local geometries about specific DNA bases differ significantly upon binding to NF-kappaB. This is particularly evident at the 5'-GG/CC base-pairs; a signature of NF-kappaB specific DNA binding sequences. Differential phosphate group conformations, minor groove widths, buckle, twist, and tilt angles are observed between bound and unbound kappaB DNA. We observe that the presence of an extra G:C base-pair, 5'- to the GGA sequence in class I kappaB DNA, alters the geometry of the two internal G:C base-pairs within the GGGA tetranucleotide, which explains, at least in part, the structural basis for distinct NF-kappaB dimer recruitment by the two different classes of kappaB DNA. Together, these observations suggest that NF-kappaB dimers recognize specific structural features of kappaB DNA in order to make sequence-specific complexes.

The NF-κB subunit RelB controls p100 processing by competing with the kinases NIK and IKK1 for binding to p100.

The heterodimer formed by the nuclear factor κB (NF-κB) subunits p52 and RelB is the product of noncanonical signaling in which the key event is the proteolytic processing of p100 to generate p52. The kinases NF-κB-inducing kinase (NIK) and inhibitor of κB kinase 1 (IKK1; also known as IKKα) are activated during noncanonical signaling and play essential roles in p100 processing. In resting cells, RelB remains associated with unprocessed p100 as a transcriptionally inert p100:RelB complex, which is part of a larger assembly with other NF-κB factors known as the "kappaBsome." We investigated how these two different RelB-containing complexes with opposing effects on target gene transcription are formed. We found that RelB controls the extent of both p100 processing and kappaBsome formation during noncanonical signaling. Within an apparently "transitional" complex that contains RelB, NIK, IKK1, and p100, RelB and the NIK:IKK1 complex competed with each other for binding to a region of p100. A fraction of p100 in the transitional complex was refractory to processing, which resulted in the formation of the kappaBsome. However, another fraction of p100 protein underwent NIK:IKK1-mediated phosphorylation and processing while remaining bound to RelB, thus forming the p52:RelB heterodimer. Our results suggest that changes in the relative concentrations of RelB, NIK:IKK1, and p100 during noncanonical signaling modulate this transitional complex and are critical for maintaining the fine balance between the processing and protection of p100.

Stabilization of RelB requires multidomain interactions with p100/p52.

The NF-kappaB family member RelB has many properties not shared by other family members such as restricted subunit association and lack of regulation by the classical IkappaB proteins. We show that the protein level of RelB is significantly reduced in the absence of p100 and reduced even more when both p100 and p105 are absent. RelB stabilizes itself by directly interacting with p100, p105, and their processed products. However, RelB forms complexes with its partners using different interaction modes. Although the C-terminal ankyrin repeat domain of p105 is not involved in the RelB-p105 complex formation, all domains and flexible regions of each protein are engaged in the RelB-p100 complex. In several respects the RelB-p52 and RelB-p100 complexes are unique in the NF-kappaB family. The N-terminal domain of p100/p52 interacts with RelB but not RelA. The transcriptional activation domain of RelB, but not RelA, directly interacts with the processing region of p100. These unique protein-protein contacts explain why RelB prefers p52 as its dimeric partner for transcriptional activity and is retained in the cytoplasm as an inhibited complex by p100. This association-mediated stabilization of RelB implies a possible role for RelB in the processing of p100 into p52.