The NEDD8 pathway is essential for SCF(beta -TrCP)-mediated ubiquitination and processing of the NF-kappa B precursor p105

The p50 subunit of NF-kappaB is generated by limited processing of the precursor p105. IkappaB kinase-mediated phosphorylation of the C-terminal domain of p105 recruits the SCF(beta-TrCP) ubiquitin ligase, resulting in rapid ubiquitination and subsequent processing/degradation of p105. NEDD8 is known to activate SCF ligases following modification of their cullin component. Here we show that NEDDylation is required for conjugation and processing of p105 by SCF(beta-TrCP) following phosphorylation of the molecule. In a crude extract, a dominant negative E2 enzyme, UBC12, inhibits both conjugation and processing of p105, and inhibition is alleviated by an excess of WT- UBC12. In a reconstituted cell-free system, ubiquitination of p105 was stimulated only in the presence of all three components of the NEDD8 pathway, E1, E2, and NEDD8. A Cul-1 mutant that cannot be NEDDylated could not stimulate ubiquitination and processing of p105. Similar findings were observed also in cells. It should be noted that NEDDylation is required only for the stimulated but not for basal processing of p105. Although the mechanisms that underlie processing of p105 are largely obscure, it is clear that NEDDylation and the coordinated activity of SCF(beta-TrCP) on both p105 and IkappaBalpha serve as an important regulatory mechanism controlling NF-kappaB activity.     

p105.Ikappa Bgamma and prototypical Ikappa Bs use a similar mechanism to bind but a different mechanism to regulate the subcellular localization of NF-kappa B

p105, also known as NF-kappaB1, is an atypical IkappaB molecule with a multi-domain organization distinct from other prototypical IkappaBs, like IkappaBalpha and IkappaBbeta. To understand the mechanism by which p105 binds and inhibits NF-kappaB, we have used both p105 and its C-terminal inhibitory segment known as IkappaBgamma for our study. We show here that one IkappaBgamma molecule binds to NF-kappaB dimers wherein at least one NF-kappaB subunit is p50. We suggest that the obligatory p50 subunit in IkappaBgamma.NF-kappaB complexes is equivalent to the N-terminal p50 segment in all p105.NF-kappaB complexes. The nuclear localization signal (NLS) of the obligatory p50 subunit is masked by IkappaBgamma, whereas the NLS of the nonobligatory NF-kappaB subunit is exposed. Thus, the global binding mode of all IkappaB.NF-kappaB complexes seems to be similar where one obligatory (or specific) NF-kappaB subunit makes intimate contact with IkappaB and the nonobligatory (or nonspecific) subunit is bound primarily through its ability to dimerize. In the case of IkappaBalpha and IkappaBbeta, the specific NF-kappaB subunit in the complex is p65. In contrast to IkappaBalpha.NF-kappaB complexes, where the exposed NLS of the nonspecific subunit imports the complex to the nucleus, p105.NF-kappaB and IkappaBgamma.NF-kappaB complexes are cytoplasmic. We show that the death domain of p105 (also of IkappaBgamma) is essential for the cytoplasmic sequestration of NF-kappaB by p105 and IkappaBgamma. However, the death domain does not mask the exposed NLS of the complex. We also demonstrate that the death domain alone is not sufficient for cytoplasmic retention and instead functions only in conjunction with other parts in the three-dimensional scaffold formed by the association of the ankyrin repeat domain (ARD) and NF-kappaB dimer. We speculate that additional cytoplasmic protein(s) may sequester the entire p105.NF-kappaB complex by binding through the death domain and other segments, including the exposed NLS.     

The 20S proteasome processes NF-kappaB1 p105 into p50 in a translation-independent manner

The NF-kappaB p50 is the N-terminal processed product of the precursor, p105. It has been suggested that p50 is generated not from full-length p105 but cotranslationally from incompletely synthesized molecules by the proteasome. We show that the 20S proteasome endoproteolytically cleaves the fully synthesized p105 and selectively degrades the C-terminus of p105, leading to p50 generation in a ubiquitin-independent manner. As small as 25 residues C-terminus to the site of processing are sufficient to promote processing in vivo. However, any p105 mutant that lacks complete ankyrin repeat domain (ARD) is processed aberrantly, suggesting that native processing must occur from a precursor, which extends beyond the ARD. Remarkably, the mutant p105 that lacks the internal region including the glycine-rich region (GRR) is completely degraded by 20S proteasome in vitro. This suggests that the GRR impedes the complete degradation of the p105 precursor, thus contributing to p50 generation.     

Dual effects of IkappaB kinase beta-mediated phosphorylation on p105 Fate: SCF(beta-TrCP)-dependent degradation and SCF(beta-TrCP)-independent processing

Processing of the p105 NF-kappaB precursor to yield the p50 active subunit is a unique and rare case in which the ubiquitin system is involved in limited processing rather than in complete destruction of its target. The mechanisms involved in this process are largely unknown, although a glycine repeat in the middle of p105 has been identified as a processing stop signal. IkappaB kinase (IKK)beta-mediated phosphorylation at the C-terminal domain with subsequent recruitment of the SCF(beta-TrCP) ubiquitin ligase leads to accelerated processing and degradation of the precursor, yet the roles that the kinase and ligase play in each of these two processes have not been elucidated. Here we demonstrate that IKKbeta has two distinct functions: (i) stimulation of degradation and (ii) stimulation of processing. IKKbeta-induced degradation is dependent on SCF(beta-TrCP), which acts through multiple lysine residues in the IkappaBgamma domain. In contrast, IKKbeta-induced processing of p105 is beta-transduction repeat-containing protein (beta-TrCP) independent, as it is not affected by expression of a dominant-negative beta-TrCP or following its silencing by small inhibitory RNA. Furthermore, removal of all 30 lysine residues from IkappaBgamma results in complete inhibition of IKK-dependent degradation but has no effect on IKK-dependent processing. Yet processing still requires the activity of the ubiquitin system, as it is inhibited by dominant-negative UbcH5a. We suggest that IKKbeta mediates its two distinct effects by affecting, directly and indirectly, two different E3s.     

Shared pathways of IkappaB kinase-induced SCF(betaTrCP)-mediated ubiquitination and degradation for the NF-kappaB precursor p105 and IkappaBalpha

p105 (NFKB1) acts in a dual way as a cytoplasmic IkappaB molecule and as the source of the NF-kappaB p50 subunit upon processing. p105 can form various heterodimers with other NF-kappaB subunits, including its own processing product, p50, and these complexes are signal responsive. Signaling through the IkappaB kinase (IKK) complex invokes p105 degradation and p50 homodimer formation, involving p105 phosphorylation at a C-terminal destruction box. We show here that IKKbeta phosphorylation of p105 is direct and does not require kinases downstream of IKK. p105 contains an IKK docking site located in a death domain, which is separate from the substrate site. The substrate residues were identified as serines 923 and 927, the latter of which was previously assumed to be a threonine. S927 is part of a conserved DSGPsi motif and is functionally most critical. The region containing both serines is homologous to the N-terminal destruction box of IkappaBalpha, -beta, and -epsilon. Upon phosphorylation by IKK, p105 attracts the SCF E3 ubiquitin ligase substrate recognition molecules betaTrCP1 and betaTrCP2, resulting in polyubiquitination and complete degradation by the proteasome. However, processing of p105 is independent of IKK signaling. In line with this and as a physiologically relevant model, lipopolysaccharide (LPS) induced degradation of endogenous p105 and p50 homodimer formation, but not processing in pre-B cells. In mutant pre-B cells lacking IKKgamma, processing was unaffected, but LPS-induced p105 degradation was abolished. Thus, a functional endogenous IKK complex is required for signal-induced p105 degradation but not for processing.     

beta-TrCP binding and processing of NF-kappaB2/p100 involve its phosphorylation at serines 866 and 870

Processing of the NF-kappaB2 precursor protein p100 is a major step in noncanonical NF-kappaB signaling. This signaling step requires the NF-kappaB inducing kinase (NIK) and its downstream kinase, IkappaB kinase alpha (IKKalpha). We show here that p100 undergoes phosphorylation at serines 866, 870, and possibly 872, in cells stimulated with noncanonical NF-kappaB stimuli or transfected with NIK and IKKalpha. Phosphorylation of this serine cluster creates a binding site for beta-TrCP, the receptor subunit of the beta-TrCP(SCF) ubiquitin ligase. Mutation of either serine 866 or serine 870 abolishes the beta-TrCP recruitment and ubiquitination of p100. The functional significance of p100 phosphorylation is further supported by the finding that this molecular event occurs in a NIK- and IKKalpha-dependent manner. Additionally, induction of p100 phosphorylation can be blocked by a protein synthesis inhibitor, suggesting the requirement of de novo protein synthesis. These data suggest that p100 processing involves its phosphorylation at specific terminal serines, which form a binding site for beta-TrCP thereby regulating p100 ubiquitination.     

Defective activation of ERK in macrophages lacking the p50/p105 subunit of NF-kappaB is responsible for elevated expression of IL-12 p40 observed after challenge with Helicobacter hepaticus

Helicobacter hepaticus is an enterohepatic Helicobacter species that induces lower bowel inflammation in susceptible mouse strains, including those lacking the p50/p105 subunit of NF-kappaB. H. hepaticus-induced colitis is associated with elevated levels of IL-12 p40 expression, and p50/p105-deficient macrophages express higher levels of IL-12 p40 than wild-type macrophages after challenge with H. hepaticus. However, the molecular mechanisms by which the p50/p105 subunit of NF-kappaB suppresses IL-12 p40 expression have not yet been elucidated. In this study we have demonstrated that H. hepaticus challenge of macrophages induces ERK activation, and this event plays a critical role in inhibiting the ability of H. hepaticus to induce IL-12 p40. Activation of ERK requires both p50/p105 and the MAPK kinase kinase, Tpl-2. Inhibition of the induction of IL-12 p40 by ERK was independent of c-Rel, a known positive regulator of IL-12 p40. Instead, it was linked to the induction of c-Fos, a known inhibitor of IL-12 p40 expression. These results suggest that H. hepaticus induces ERK activation by a pathway dependent upon Tpl-2 and p105, and that activation of ERK inhibits the expression of IL-12 p40 by inducing c-Fos. Thus, a defect in ERK activation could play a pivotal role in the superinduction of IL-12 p40 observed after challenge of macrophages lacking the p50/p105 subunit of NF-kappaB with H. hepaticus.     

Ceramide triggers an NF-kappaB-dependent survival pathway through calpain

We have shown that C2 ceramide, a cell-permeable analog of this lipid second messenger, triggers an NF-kappaB dependent survival pathway that counteracts cell death. Activation of NF-kappaB and subsequent induction of prosurvival genes relies on calpain activity and is prevented on silencing of the calpain small subunit (Capn4) that is required for the function of ubiquitous calpains. We have demonstrated that p105 (NF-kappaB1) and its proteolytic product p50 can be targets of micro- and milli-calpain in vitro and that a p50 deletion mutant, lacking both the N- and the C-terminal ends, is resistant to calpain-mediated degradation. Capn4 silencing results in stabilization of endogenous p105 and p50 in diverse human cell lines. Furthermore, p105 processing and activation of NF-kappaB survival genes in response to C2 ceramide is impaired in Capn4-/- mouse embryonic fibroblasts defective in calpain activity. Altogether, these data argue for the existence of a ceramide-calpain-NF-kappaB axis with prosurvival functions.     

S9, a 19 S proteasome subunit interacting with ubiquitinated NF-kappaB2/p100

Proteasome-mediated processing of the nfkappab2 gene product p100 is a regulated event that generates the NF-kappaB subunit p52. This event can be induced through p100 phosphorylation by a signaling pathway involving the nuclear factor-kappaB-inducing kinase (NIK). The C-terminal region of p100, which contains its phosphorylation site and a death domain, plays a pivotal role in regulating the processing of p100. To understand the biochemical mechanism of p100 processing, we searched for cellular factors interacting with the C-terminal regulatory region of p100 using the yeast two-hybrid system. This led to the identification of S9, a non-ATPase subunit of the 19 S proteasome with no known functions. Interestingly, the S9/p100 interaction could be induced by NIK but not by a catalytically inactive NIK mutant. This inducible molecular interaction required p100 ubiquitination and was dependent on the intact death domain. We further demonstrated that the death domain is essential for NIK-induced post-translational processing of p100, thus providing a functional link between the S9 binding and the processing of p100. Finally, we provide genetic evidence for the essential role of S9 in the inducible processing of p100.     

Induction of p100 processing by NF-kappaB-inducing kinase involves docking IkappaB kinase alpha (IKKalpha) to p100 and IKKalpha-mediated phosphorylation

The processing of the nfkappab2 gene product p100 to generate p52 is a regulated event, which is important for the instrumental function of NF-kappaB. We previously demonstrated that this tightly controlled event is regulated positively by NF-kappaB-inducing kinase (NIK) and its downstream kinase, IkappaB kinase alpha (IKKalpha). However, the precise mechanisms by which NIK and IKKalpha induce p100 processing remain unclear. Here, we show that, besides activating IKKalpha, NIK also serves as a docking molecule recruiting IKKalpha to p100. This novel function of NIK requires two specific amino acid residues, serine 866 and serine 870, of p100 that are known to be essential for inducible processing of p100. We also show that, after being recruited into p100 complex, activated IKKalpha phosphorylates specific serines located in both N- and C-terminal regions of p100 (serines 99, 108, 115, 123, and 872). The phosphorylation of these specific serines is the prerequisite for ubiquitination and subsequent processing of p100 mediated by the beta-TrCP ubiquitin ligase and 26 S proteasome, respectively. These results highlight the critical but different roles of NIK and IKKalpha in regulating p100 processing and shed light on the mechanisms mediating the tight control of p100 processing. These data also provide the first evidence for explaining why overexpression of IKKalpha or its activation by many other stimuli such as tumor necrosis factor and mitogens fails to induce p100 processing.