Regulation of NF-kappaB2/p100 processing by its nuclear shuttling

TRIM55 promotes noncanonical NF-κB signaling and B cell-mediated immune responses by coordinating p100 ubiquitination and processing

The ubiquitination-dependent processing of NF-κB2 (also known as p100) is a critical step in the activation of the noncanonical NF-κB pathway. We investigated the molecular mechanisms regulating this process and showed that TRIM55 was the E3 ubiquitin ligase that mediated the ubiquitination of p100 and coordinated its processing. TRIM55 deficiency impaired noncanonical NF-κB activation and B cell function. Mice with a B cell-specific Trim55 deficiency exhibited reduced germinal center formation and antibody production. These mice showed less severe symptoms than those of control mice upon the induction of a systemic lupus-like disease, suggesting B cell-intrinsic functions of TRIM55 in humoral immune responses and autoimmunity. Mechanistically, the ubiquitination of p100 mediated by TRIM55 was crucial for p100 processing by VCP, an ATPase that mediates ubiquitin-dependent protein degradation by the proteasome. Furthermore, we found that TRIM55 facilitated the interaction between TRIM21 and VCP as well as TRIM21-mediated K63-ubiquitination of VCP, both of which were indispensable for the formation of the VCP-UFD1-NPL4 complex and p100 processing. Together, our results reveal a mechanism by which TRIM55 fine-tunes p100 processing and regulates B cell-dependent immune responses in vivo, highlighting TRIM55 as a potential therapeutic target for lupus-like disease.

Targeting NF-κB pathway for the therapy of diseases: mechanism and clinical study

NF-κB pathway consists of canonical and non-canonical pathways. The canonical NF-κB is activated by various stimuli, transducing a quick but transient transcriptional activity, to regulate the expression of various proinflammatory genes and also serve as the critical mediator for inflammatory response. Meanwhile, the activation of the non-canonical NF-κB pathway occurs through a handful of TNF receptor superfamily members. Since the activation of this pathway involves protein synthesis, the kinetics of non-canonical NF-κB activation is slow but persistent, in concordance with its biological functions in the development of immune cell and lymphoid organ, immune homeostasis and immune response. The activation of the canonical and non-canonical NF-κB pathway is tightly controlled, highlighting the vital roles of ubiquitination in these pathways. Emerging studies indicate that dysregulated NF-κB activity causes inflammation-related diseases as well as cancers, and NF-κB has been long proposed as the potential target for therapy of diseases. This review attempts to summarize our current knowledge and updates on the mechanisms of NF-κB pathway regulation and the potential therapeutic application of inhibition of NF-κB signaling in cancer and inflammatory diseases.

Preventing abnormal NF-κB activation and autoimmunity by Otub1-mediated p100 stabilization

NF-κB, a family of transcription factors regulating diverse biological processes including immune responses, is activated by canonical and noncanonical pathways based on degradation of IκBα and processing of the IκB-like protein p100, respectively. Although p100 responds to noncanonical NF-κB stimuli for processing, it does not undergo degradation, but rather becomes accumulated, along with canonical NF-κB activation. We show here that the stability of p100 is tightly controlled by a deubiquitinase, Otub1. Otub1 deficiency not only promotes signal-induced p100 processing and noncanonical NF-κB activation but also causes steady-state p100 degradation, leading to aberrant NF-κB activation in the canonical pathway. B-cell-conditional deletion of Otub1 results in B-cell hyperplasia, antibody hyper-production, and lupus-like autoimmunity. Otub1-deficient B cells display aberrantly activated phenotypes and overproduce the cytokine IL-6, contributing to autoimmunity induction. Thus, maintenance of p100 stability by Otub1 serves as an unusual mechanism of NF-κB regulation that prevents autoimmunity.

Signaling via the NFκB system

The nuclear factor kappa B (NFκB) family of transcription factors is a key regulator of immune development, immune responses, inflammation, and cancer. The NFκB signaling system (defined by the interactions between NFκB dimers, IκB regulators, and IKK complexes) is responsive to a number of stimuli, and upon ligand-receptor engagement, distinct cellular outcomes, appropriate to the specific signal received, are set into motion. After almost three decades of study, many signaling mechanisms are well understood, rendering them amenable to mathematical modeling, which can reveal deeper insights about the regulatory design principles. While other reviews have focused on upstream, receptor proximal signaling (Hayden MS, Ghosh S. Signaling to NF-κB. Genes Dev 2004, 18:2195-2224; Verstrepen L, Bekaert T, Chau TL, Tavernier J, Chariot A, Beyaert R. TLR-4, IL-1R and TNF-R signaling to NF-κB: variations on a common theme. Cell Mol Life Sci 2008, 65:2964-2978), and advances through computational modeling (Basak S, Behar M, Hoffmann A. Lessons from mathematically modeling the NF-κB pathway. Immunol Rev 2012, 246:221-238; Williams R, Timmis J, Qwarnstrom E. Computational models of the NF-KB signalling pathway. Computation 2014, 2:131), in this review we aim to summarize the current understanding of the NFκB signaling system itself, the molecular mechanisms, and systems properties that are key to its diverse biological functions, and we discuss remaining questions in the field. WIREs Syst Biol Med 2016, 8:227-241. doi: 10.1002/wsbm.1331 For further resources related to this article, please visit the WIREs website.

Regulation of NF-κB by TNF family cytokines

The NF-κB family of inducible transcription factors is activated in response to a variety of stimuli. Amongst the best-characterized inducers of NF-κB are members of the TNF family of cytokines. Research on NF-κB and TNF have been tightly intertwined for more than 25 years. Perhaps the most compelling examples of the interconnectedness of NF-κB and the TNF have come from analysis of knock-out mice that are unable to activate NF-κB. Such mice die embryonically, however, deletion of TNF or TNFR1 can rescue the lethality thereby illustrating the important role of NF-κB as the key regulator of transcriptional responses to TNF. The physiological connections between NF-κB and TNF cytokines are numerous and best explored in articles focusing on a single TNF family member. Instead, in this review, we explore general mechanisms of TNF cytokine signaling, with a focus on the upstream signaling events leading to activation of the so-called canonical and noncanonical NF-κB pathways by TNFR1 and CD40, respectively.

Identification of a functional nuclear localization signal within the human USP22 protein

Ubiquitin-specific processing enzyme 22 (USP22), a member of the deubiquitinase family, is over-expressed in most human cancers and has been implicated in tumorigenesis. Because it is an enzymatic subunit of the human SAGA transcriptional cofactor, USP22 deubiquitylates histone H2A and H2B in the nucleus, thus participating in gene regulation and cell-cycle progression. However, the mechanisms regulating its nuclear translocation have not yet been elucidated. It was here demonstrated that USP22 is imported into the nucleus through a mechanism mediated by nuclear localization signal (NLS). The bipartite NLS sequence KRELELLKHNPKRRKIT (aa152-168), was identified as the functional NLS for its nuclear localization. Furthermore, a short cluster of basic amino acid residues KRRK within this bipartite NLS plays the primary role in nuclear localization and is evolutionarily conserved in USP22 homologues. In the present study, a functional NLS and the minimal sequences required for the active targeting of USP22 to the nucleus were identified. These findings may provide a molecular basis for the mechanism underlying USP22 nuclear trafficking and function.

The BAFF receptor transduces survival signals by co-opting the B cell receptor signaling pathway

Follicular B cell survival requires signaling from BAFFR, a receptor for BAFF and the B cell antigen receptor (BCR). This “tonic” BCR survival signal is distinct from that induced by antigen binding and may be ligand-independent. We show that inducible inactivation of the Syk tyrosine kinase, a key signal transducer from the BCR following antigen binding, resulted in the death of most follicular B cells because Syk-deficient cells were unable to survive in response to BAFF. Genetic rescue studies demonstrated that Syk transduces BAFFR survival signals via ERK and PI3 kinase. Surprisingly, BAFFR signaling directly induced phosphorylation of both Syk and the BCR-associated Igα signaling subunit, and this Syk phosphorylation required the BCR. We conclude that the BCR and Igα may be required for B cell survival because they function as adaptor proteins in a BAFFR signaling pathway leading to activation of Syk, demonstrating previously unrecognized crosstalk between the two receptors.

Moving to the core: spatiotemporal analysis of Forkhead box O (FOXO) and nuclear factor-κB (NF-κB) nuclear translocation

Nuclear translocation of proteins is an essential aspect of normal cell function, and defects in this process have been detected in many disease-associated conditions. The detection and quantification of nuclear translocation was significantly boosted by the association of robotized microscopy with automated image analysis, a technology designated as high-content screening. Image-based high-content screening and analysis provides the means to systematically observe cellular translocation events in time and space in response to chemical or genetic perturbation at large scale. This approach yields powerful insights into the regulation of complex signaling networks independently of preconceived notions of mechanistic relationships. In this review, we briefly overview the different mechanisms involved in nucleocytoplasmic protein trafficking. In addition, we discuss high-content approaches used to interrogate the mechanistic and spatiotemporal dynamics of cellular signaling events using Forkhead box O (FOXO) proteins and the nuclear factor-κB (NF-κB) as important and clinically relevant examples.

The noncanonical NF-κB pathway

The noncanonical nuclear factor-κB (NF-κB) signaling pathway mediates activation of the p52/RelB NF-κB complex and, thereby, regulates specific immunological processes. This NF-κB pathway relies on the inducible processing of NF-κB2 precursor protein, p100, as opposed to the degradation of IκBα in the canonical NF-κB pathway. A central signaling component of the noncanonical NF-κB pathway is NF-κB-inducing kinase (NIK), which functions together with a downstream kinase, IKKα (inhibitor of NF-κB kinase α), to induce phosphorylation-dependent ubiquitination and processing of p100. Under normal conditions, NIK is targeted for continuous degradation by a tumor necrosis factor (TNF) receptor-associated factor-3 (TRAF3)-dependent E3 ubiquitin ligase. In response to signals mediated by a subset of TNF receptor superfamily members, NIK becomes stabilized as a result of TRAF3 degradation, leading to the activation of noncanonical NF-κB. This review discusses both the historical perspectives and the recent progress in the regulation and biological function of the noncanonical NF-κB pathway.

Nuclear initiated NF-κB signaling: NEMO and ATM take center stage

A large body of literature describes elaborate NF-κB signaling networks induced by inflammatory and immune signals. Decades of research has revealed that transcriptionally functional NF-κB dimers are activated by two major pathways, canonical and non-canonical. Both pathways involve the release of NF-κB dimers from inactive cytoplasmic complexes to cause their nuclear translocation to modulate gene expression programs and biological responses. NF-κB is also responsive to genotoxic agents; however, signal communication networks that are initiated in the nucleus following DNA damage induction are less defined. Evidence in the literature supports the presence of such signaling pathways induced by multiple distinct genotoxic agents, resulting in the activation of cytoplasmic IKK complex. An example is a pathway that involves the DNA damage-responsive kinase ataxia telangiectasia mutated (ATM) and a series of post-translational modifications of NF-κB essential modulator (NEMO) in the nucleus of a genotoxin-exposed cell. Recent evidence also suggests that this nuclear-initiated NF-κB signaling pathway plays significant physiological and pathological roles, particularly in lymphocyte development and human cancer progression. This review will summarize these new developments, while identifying significant unanswered questions and providing new hypotheses that may be addressed in future studies.

Non-canonical NF-κB signaling pathway

The non-canonical NF-κB pathway is an important arm of NF-κB signaling that predominantly targets activation of the p52/RelB NF-κB complex. This pathway depends on the inducible processing of p100, a molecule functioning as both the precursor of p52 and a RelB-specific inhibitor. A central signaling component of the non-canonical pathway is NF-κB-inducing kinase (NIK), which integrates signals from a subset of TNF receptor family members and activates a downstream kinase, IκB kinase-α (IKKα), for triggering p100 phosphorylation and processing. A unique mechanism of NIK regulation is through its fate control: the basal level of NIK is kept low by a TRAF-cIAP destruction complex and signal-induced non-canonical NF-κB signaling involves NIK stabilization. Tight control of the fate of NIK is important, since deregulated NIK accumulation is associated with lymphoid malignancies.

The N-terminal half of the Drosophila Rel/NF-kappaB factor Relish, REL-68, constitutively activates transcription of specific Relish target genes

The Rel/NF-kappaB transcription factor Relish is a major regulator of the antimicrobial response in Drosophila. Upon immune challenge, Relish is cleaved to generate two fragments, the DNA-binding transcription factor REL-68 and the IkappaB-like REL-49. Using transgenic fly strains we show here that overexpression of REL-68 separately from REL-49 is sufficient to activate strong constitutive transcription of the Diptericin gene, but little constitutive or inducible transcription of Attacin and Cecropin, two other Relish target genes. Their transcription may therefore require additional modifications of Relish. However, phosphorylation of the conserved serine residue S431 is not involved in such modifications. This is unlike p65 and Dorsal, which are modulated by phosphorylation at their homologous site. In contrast to other IkappaB proteins, overexpression of REL-49 had no inhibitory effect on Relish-dependent transcription. Instead, we propose that the C-terminal IkappaB-like domain executes a scaffolding and recruiting function for full activation of Relish.

SN52, a novel nuclear factor-kappaB inhibitor, blocks nuclear import of RelB:p52 dimer and sensitizes prostate cancer cells to ionizing radiation

The activation of nuclear factor-kappaB (NF-kappaB) is thought to protect cancer cells against therapy-induced cytotoxicity. RelB, a member of the NF-kappaB family in the alternative pathway, is uniquely expressed at a high level in prostate cancer with high Gleason scores. Here, we show that ionizing radiation (IR) enhances nuclear import of RelB, leading to up-regulation of its target gene, manganese superoxide dismutase (MnSOD), and renders prostate cancer cells resistant to IR. To selectively block RelB nuclear import, we designed a cell-permeable SN52 peptide, a variant of the SN50 peptide that has been shown to block nuclear import of NF-kappaB family members in the classic pathway. Inhibition of IR-induced NF-kappaB activation by SN50 and SN52 was achieved by selectively interrupting the association of p50 and p52 with nuclear import factors importin-alpha1 and importin-beta1. Importantly, SN52 seems to be more efficient for radiosensitization of prostate cancer cells at clinically relevant radiation doses and has less cytotoxicity to normal prostate epithelial cells compared with the toxicity observed with SN50. These results suggest that targeting the alternative pathway is a promising approach to selectively radiosensitize prostate cancers and that SN52 may serve as a prototype biological agent for sensitizing prostate cancers to clinically relevant doses of IR.

The involvement of NF-kappaB p65/p52 in the effects of GDNF on DA neurons in early PD rats

Glial cell line-derived neurotrophic factor (GDNF) can exert neuroprotective effects on the substantia nigra pars compacta (SNc) dopaminergic (DA) neurons that are undergoing degeneration in Parkinson's disease (PD). In an attempt to investigate the molecular signaling mechanisms underlying GDNF protection the DA neurons from degeneration, we established early PD rat models in which the DA neurons in SNc were degenerating. Whether the cytoplasmic NF-kappaB signaling pathway was involved in the protection of GDNF on the degenerating DA neurons was examined in the present study. The results showed that the nuclear NF-kappaB p65 levels in the DA neurons increased when GDNF was injected into SNc of early PD rat models. Immunoprecipitation assays showed that the nuclear NF-kappaB p65/p52 complex levels increased after GDNF administration, while the p65/p50 complex levels decreased. These results indicated that GDNF could activate the NF-kappaB signaling pathway in the degenerating DA neurons. And it was the noncanonical NF-kappaB signaling pathway, which contained the NF-kappaB p65/p52 complex that was involved in the effects of GDNF on DA neurons.

NF-kappaB p52, RelB and c-Rel are transported into the nucleus via a subset of importin alpha molecules

In resting cells NF-kappaB transcription factors are retained in the cytoplasm as latent inactive complexes, until they are activated and rapidly transported into the nucleus. We show that all NF-kappaB proteins are imported into the nucleus via a subset of importin alpha isoforms. Our data indicate that the NF-kappaB components of the classical and alternative pathways have somewhat different specifities to importin alpha molecules. Based on the results from binding experiments of in vitro-translated and Sendai virus infection-induced or TNF-alpha-stimulated endogenous NF-kappaB proteins, it can be predicted that the specifity of NF-kappaB proteins to importin alpha molecules is different and changes upon the composition of the imported dimer. p52 protein binds directly to importin alpha3, alpha4, alpha5 and alpha6 and c-Rel binds to importin alpha5, alpha6 and alpha7 via a previously described monopartite nuclear localization signals (NLSs). Here we show that RelB, instead, has a bipartite arginine/lysine-rich NLS that mediates the binding of RelB to importin alpha5 and alpha6 and subsequent nuclear translocation of the protein. Moreover, we show that the nuclear import of p52/RelB heterodimers is mediated exclusively by the NLS of RelB. In addition, we found that the NLS of p52 mediates the nuclear import of p52/p65 heterodimers.

A novel mutation in the Nfkb2 gene generates an NF-kappa B2 "super repressor"

The noncanonical NF-kappaB pathway regulates the development and function of multiple organs and cell lineages. We have generated mice harboring a novel mutation in Nfkb2 that prevents the processing of the inhibitory precursor, p100, into the active subunit, p52. Mutant mice express a complex phenotype with abnormalities in a variety of tissues, and with a spectrum that is more severe than in mice carrying a targeted deletion of Nfkb2. Signaling through the noncanonical pathway is ablated due to the absence of p52, resulting in disorganized splenic architecture and disrupted B cell development. The inhibitory precursor form of NF-kappaB2 interacts with RelA, preventing activation of RelA dimers in response to both canonical and noncanonical stimuli, which in combination with p52 deficiency, results in defective lymph node formation and bone homeostasis. These findings demonstrate a key role for NF-kappaB2 in the regulation of RelA activation and suggest overlap in the function of NF-kappaB members in canonical and noncanonical pathway signaling.

Endoproteolytic processing of C-terminally truncated NF-kappaB2 precursors at kappaB-containing promoters

The C-terminal, partially truncated forms of the NF-kappaB2/p52 precursor p100, p100DeltaCs, manifest constitutive processing and oncogenic ability, although the responsible mechanisms remain unknown. Here, we report that p100DeltaCs are specifically processed in association with binding to promoter DNA-containing kappaB sites. In the nucleus, p100DeltaCs bind to the kappaB promoter DNA and subsequently recruit the proteasome to form a stable proteasome/p100DeltaC/DNA complex, which mediates the processing of p100DeltaCs. Notably, the processing at the kappaB promoter is initiated by a proteasome-mediated endoproteolytic cleavage at amino acid D(415) of p100DeltaCs, and the processed p52, but not the precursors themselves, is oncogenic by up-regulating a subset of target genes. Our studies demonstrate a different mechanism of p100 processing and also present evidence showing that the proteasome modulates the action of transcription factors at promoter regions through endoproteolysis.

IkappaB kinase epsilon interacts with p52 and promotes transactivation via p65

The members of the NF-kappaB transcription factor family are key regulators of gene expression in the immune response. Different combinations of NF-kappaB subunits not only diverge in timing to induce transcription but also recognize varying sequences of the NF-kappaB-binding site of their target genes. The p52 subunit is generated as a result of processing of NF-kappaB2 p100. Here, we demonstrate that the non-canonical IkappaB kinase epsilon (IKKepsilon) directly interacts with p100. In a transactivation assay, IKKepsilon promoted the ability of p52 to transactivate gene expression. This effect was indirect, requiring p65, which was shown to be part of the IKKepsilon-p52 complex and to be phosphorylated by IKKepsilon. These novel interactions reveal a hitherto unknown function of IKKepsilon in the regulation of the alternative NF-kappaB activation pathway involving p52 and p65.

The alternative NF-kappaB pathway from biochemistry to biology: pitfalls and promises for future drug development

The past two decades have led to a tremendous work on the transcription factor NF-kappaB and its molecular mechanisms of activation. The nuclear translocation of NF-kappaB is controlled by two main pathways: the classical and the alternative NF-kappaB pathways. The classical NF-kappaB pathway activates the IKK complex that controls the inducible degradation of most IkappaB family members that are IkappaBalpha, IkappaBbeta, IkappaBvarepsilon and p105. The alternative NF-kappaB pathway induces p100 processing and p52 generation through the activation of at least two kinases, which are NIK and IKKalpha. Genetic studies have shown that IKKgamma is dispensable for the alternative pathway, which suggests the existence of an alternative IKKalpha-containing complex. It is noteworthy that activation of particular p52 heterodimers like p52/RelB requires solely the alternative pathway while activation of p52/p65 or p52/c-Rel involves a "hybrid pathway". Among others, LTbetaR, BAFF-R, CD40 and RANK have the ability to induce the alternative pathway. The latter plays some roles in biological functions controlled by these receptors, which are the development of secondary lymphoid organs, the proliferation, survival and maturation of B cell, and the osteoclastogenesis. Exacerbated activation of the alternative pathway is potentially associated to a wide range of disorders like rheumatoid arthritis, ulcerative colitis or B cell lymphomas. Therefore, inhibitors of the alternative pathway could be valuable tools for the treatment of inflammatory disorders and cancers.

Two distinct ubiquitin-dependent mechanisms are involved in NF-kappaB p105 proteolysis

Generation of the p50 subunit of NF-kappaB is a rare case in which the ubiquitin system processes a longer precursor, p105, into a shorter active subunit: in the vast majority of cases, the target protein is completely degraded. The mechanisms involved in this process have remained elusive. It appears that a Gly rich region (GRR) in the middle of the molecule serves as a "processing stop signal", though under certain conditions, such as after stimulation, p105 can be completely degraded. Since NF-kappaB plays critical roles in a broad array of basic cellular processes, it is important to dissect the mechanisms that regulate its proteolysis-both destruction and processing. We have previously shown that signal-induced degradation of p105 requires ubiquitination on multiple lysines. Here we describe a novel region, a Processing Inhibitory Domain-PID, that upon its removal, the molecule is processed in high efficiency, which requires ubiquitination on a single, though non-specific, lysine.

Tumor-derived p53 mutants induce NF-kappaB2 gene expression

Overexpression of mutant p53 is a common theme in tumors, suggesting a selective pressure for p53 mutation in cancer development and progression. To determine how mutant p53 expression may lead to survival advantage in human cancer cells, we generated stable cell lines expressing p53 mutants p53-R175H, -R273H, and -D281G by use of p53-null human H1299 (lung carcinoma) cells. Compared to vector-transfected cells, H1299 cells expressing mutant p53 showed a survival advantage when treated with etoposide, a common chemotherapeutic agent; however, cells expressing the transactivation-deficient triple mutant p53-D281G (L22Q/W23S) had significantly lower resistance to etoposide. Gene expression profiling of cells expressing transcriptionally active mutant p53 proteins revealed the striking pattern that all three p53 mutants induced expression of approximately 100 genes involved in cell growth, survival, and adhesion. The gene NF-kappaB2 is a prominent member of this group, whose overexpression in H1299 cells also leads to chemoresistance. Treatment of H1299 cells expressing p53-R175H with small interfering RNA specific for NF-kappaB2 made these cells more sensitive to etoposide. We have also observed activation of the NF-kappaB2 pathway in mutant p53-expressing cells. Thus, one possible pathway through which mutants of p53 may induce loss of drug sensitivity is via the NF-kappaB2 pathway.

Mechanisms of persistent NF-kappaB activation by HTLV-I tax

Human T cell leukemia virus type I (HTLV-I) is the causative agent of a fatal malignancy known as adult T cell leukemia (ATL). The HTLV-I Tax protein is thought to play a significant role in the initiation and pathogenesis of HTLV-I-mediated disease. Tax is a potent oncogene that deregulates cellular gene expression by persistently activating signaling pathways such as NF-kappaB. Tax activation of NF-kappaB is critical for the immortalization and survival of HTLV-I-infected T cells. In this review, we describe recent insights into the mechanisms employed by Tax to activate the canonical and noncanonical NF-kappaB signaling pathways. The adaptor function of Tax appears to be a common and important mechanism for the pathological activation of both NF-kappaB pathways.

High levels of p105 (NFKB1) and p100 (NFKB2) proteins in HPV16-transformed keratinocytes: role of E6 and E7 oncoproteins

We have previously shown that functional components of the NF-kappaB signaling pathway are up-regulated and sequestered in the cytoplasm of human papillomavirus 16 (HPV16)-transformed cell lines leading to a reduced activity of NF-kappaB. In this study, we examined the expression of the NF-kappaB precursors p100 and p105 in keratinocytes transformed or not by HPV16. Western immunoblotting experiments demonstrated high levels of p100 and p105 proteins not only in HPV16+ cervical carcinoma-derived keratinocytes but also in keratinocytes stably transfected by HPV16 E6 or E7 oncogenes. Moreover, p100 and p105 proteins were predominantly cytoplasmic and nuclear in keratinocytes expressing E7 and E6, respectively. A predominantly cytoplasmic localization of E7 protein was also detected in all keratinocytes expressing E7. Our results suggest that HPV16 E6 and E7 proteins modulate the expression and the subcellular localization of p100 and p105 NF-kappaB precursors.

Essential role of IkappaB kinase alpha in the constitutive processing of NF-kappaB2 p100

Processing of NF-kappaB2 precursor protein p100 to generate p52 is tightly controlled, which is important for proper function of NF-kappaB. Accordingly, constitutive processing of p100, caused by the loss of its C-terminal processing inhibitory domain due to nfkappab2 gene rearrangements, is associated with the development of various lymphomas and leukemia. In contrast to the physiological processing of p100 triggered by NF-kappaB-inducing kinase (NIK) and its downstream kinase, IkappaB kinase alpha (IKKalpha), which requires the E3 ligase, beta-transducin repeat-containing protein (beta-TrCP), and occurs only in the cytoplasm, the constitutive processing of p100 is independent of beta-TrCP but rather is regulated by the nuclear shuttling of p100. Here, we show that constitutive processing of p100 also requires IKKalpha, but not IKKbeta (IkappaB kinase beta) or IKKgamma (IkappaB kinase gamma). It seems that NIK is also dispensable for this pathogenic processing of p100. These results demonstrate a general role of IKKalpha in p100 processing under both physiological and pathogenic conditions. Additionally, we find that IKKalpha is not required for the nuclear translocation of p100. Thus, these results also indicate that p100 nuclear translocation is not sufficient for the constitutive processing of p100.

Regulation of NF-κB2 p100 Processing by Its cis-Acting Domain

Processing of NF-kappa B2 precursor protein p100 to generate p52 is tightly regulated. However, this proteolytic event could be actively induced by the NF-kappa B-inducing kinase and the human T-cell leukemia virus-encoded oncoprotein Tax or be constitutively turned on due to the loss of the C-terminal portion of p100. Whereas NF-kappa B-inducing kinase-mediated p100 processing requires beta-transducin repeat-containing protein, constitutive processing of p100 is independent of this protein. On the other hand, Tax-induced processing of p100 appears to be both beta-transducin repeat-containing protein-dependent and -independent. We show here that, besides the C-terminal sequences, multiple functional regions, including the two alpha-helices, dimerization domain, nuclear localization sequence, and glycine-rich region, located in the N terminus of p100, also play important roles in both constitutive and inducible processing, suggesting a common mechanism for p100 processing. We further demonstrate that with the help of the C-terminal death domain and I kappa B kinase alpha-targeting serines, the C-terminal ankyrin-repeat domain of p100 strongly interacts with its N-terminal dimerization domain and nuclear localization sequence, thereby bringing the C- and N-terminal sequences together to form a three-dimensional domain. This presumptive domain is not only responsible for suppression of constitutive processing but also required for inducible processing of p100. Taken together, these studies highlight the mechanism by which the different sequences within p100 work in concert to regulate its processing and shed light on the mechanisms of how p100 processing is tightly and delicately controlled.

Signaling to NF-kappaB

The transcription factor NF-kappaB has been the focus of intense investigation for nearly two decades. Over this period, considerable progress has been made in determining the function and regulation of NF-kappaB, although there are nuances in this important signaling pathway that still remain to be understood. The challenge now is to reconcile the regulatory complexity in this pathway with the complexity of responses in which NF-kappaB family members play important roles. In this review, we provide an overview of established NF-kappaB signaling pathways with focus on the current state of research into the mechanisms that regulate IKK activation and NF-kappaB transcriptional activity.

Functions of NF-kappaB1 and NF-kappaB2 in immune cell biology

Two members of the NF-kappaB (nuclear factor kappaB)/Rel transcription factor family, NF-kappaB1 and NF-kappaB2, are produced as precursor proteins, NF-kappaB1 p105 and NF-kappaB2 p100 respectively. These are proteolytically processed by the proteasome to produce the mature transcription factors NF-kappaB1 p50 and NF-kappaB2 p52. p105 and p100 are known to function additionally as IkappaBs (inhibitors of NF-kappaB), which retain associated NF-kappaB subunits in the cytoplasm of unstimulated cells. The present review focuses on the latest advances in research on the function of NF-kappaB1 and NF-kappaB2 in immune cells. NF-kappaB2 p100 processing has recently been shown to be stimulated by a subset of NF-kappaB inducers, including lymphotoxin-beta, B-cell activating factor and CD40 ligand, via a novel signalling pathway. This promotes the nuclear translocation of p52-containing NF-kappaB dimers, which regulate peripheral lymphoid organogenesis and B-lymphocyte differentiation. Increased p100 processing also contributes to the malignant phenotype of certain T- and B-cell lymphomas. NF-kappaB1 has a distinct function from NF-kappaB2, and is important in controlling lymphocyte and macrophage function in immune and inflammatory responses. In contrast with p100, p105 is constitutively processed to p50. However, after stimulation with agonists, such as tumour necrosis factor-alpha and lipopolysaccharide, p105 is completely degraded by the proteasome. This releases associated p50, which translocates into the nucleus to modulate target gene expression. p105 degradation also liberates the p105-associated MAP kinase (mitogen-activated protein kinase) kinase kinase TPL-2 (tumour progression locus-2), which can then activate the ERK (extracellular-signal-regulated kinase)/MAP kinase cascade. Thus, in addition to its role in NF-kappaB activation, p105 functions as a regulator of MAP kinase signalling.

Tax deregulation of NF-kappaB2 p100 processing involves both beta-TrCP-dependent and -independent mechanisms

Processing of the nf-kappab2 gene product p100 to generate p52 is a tightly regulated event, consistent with the fact that the processing product, p52, is hardly detected in most cell types, including T cells, although the precursor p100 is expressed abundantly in these cells. However, in T cells transformed by the human T-cell leukemia virus type I (HTLV-I), p100 processing is very active, resulting in high level expression of p52. Because overproduction of p52 is associated with lymphoid hyperplasia and transformation, deregulation of p100 processing may be part of the oncogenic mechanism of HTLV-I. We demonstrated previously that HTLV-I Tax oncoprotein is a potent inducer of p100 processing through specific targeting of IKKalpha via IKKgamma to p100 to trigger p100 phosphorylation and ubiquitination. In this study, we further show that Tax-mediated recruitment of IKKalpha to p100 requires serines 866 and 870 of p100, shown to be essential for inducible processing of p100. Upon interaction with p100, activated IKKalpha phosphorylates both N- and C-terminal serines of p100 (serines 99, 108, 115, 123 and 872), serving as a critical step in Tax-induced p100 processing. Using a genetic approach, we find that beta-transducin repeat-containing protein, a component of the SCF ubiquitin ligase complex, previously shown to be required for physiological p100 processing mediated by nuclear factor-kappaB-inducing kinase, is only partially involved in Tax-induced processing of p100. These results indicate that both beta-transducin repeat-containing protein-dependent and -independent mechanisms contribute to Tax-deregulated p100 processing, further suggesting the involvement of different mechanisms in cellular and viral pathways of p100 processing.

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.

Epstein-Barr virus latent infection membrane protein 1 TRAF-binding site induces NIK/IKK alpha-dependent noncanonical NF-kappaB activation

Epstein-Barr virus (EBV) latent infection membrane protein 1 (LMP1)-induced NF-kappaB activation is important for infected cell survival. LMP1 activates NF-kappaB, in part, by engaging tumor necrosis factor (TNF) receptor-associated factors (TRAFs), which also mediate NF-kappaB activation from LTbetaR and CD40. LTbetaR and CD40 activation of p100/NF-kappaB2 is now known to be NIK/IKKalpha-dependent and IKKbeta/IKKgamma independent. In the experiments described here, we found that EBV LMP1 induced p100/NF-kappaB2 processing in human lymphoblasts and HEK293 cells. LMP1-induced p100 processing was NIK/IKKalpha dependent and IKKbeta/IKKgamma independent. Furthermore, the LMP1 TRAF-binding site was required for p100 processing and p52 nuclear localization, whereas the LMP1 death domain-binding site was not. Moreover, the LMP1 TRAF-binding site preferentially caused RelB nuclear accumulation. In murine embryo fibroblasts (MEFs), IKKbeta was essential for LMP1 up-regulation of macrophage inflammatory protein (MIP)-2, TNFalpha, I-TAC, ELC, MIG, and CXCR4 RNAs. Interestingly, in IKKalpha knockout MEFs, LMP1 hyperinduced MIP-2, TNFalpha, and I-TAC expression, consistent with a role for IKKalpha in down-modulating canonical IKKbeta activation or its effects. In contrast, LMP1 failed to up-regulate CXCR4 and MIG RNA in IKKalpha knockout MEFs, indicating a dependence on noncanonical IKKalpha activation. Furthermore, LMP1 up-regulation of MIP-2 RNA in MEFs was both IKKbeta- and IKKgamma-dependent, whereas LMP1 upregulation of MIG and I-TAC RNA was fully IKKgamma independent. Thus, LMP1 induces typical canonical IKKbeta/IKKgamma-dependent, atypical canonical IKKbeta-dependent/IKKgamma-independent, and noncanonical NIK/IKKalpha-dependent NF-kappaB activations; NIK/IKKalpha-dependent NF-kappaB activation is principally mediated by the LMP1 TRAF-binding site.

Nuclear Role of IκB Kinase-γ/NF-κB Essential Modulator (IKKγ/NEMO) in NF-κB-dependent Gene Expression

The I kappa B kinase (IKK) complex, which is composed of the two kinases IKK alpha and IKK beta and the regulatory subunit IKK gamma/nuclear factor-kappa B (NF-kappa B) essential modulator (NEMO), is important in the cytokine-induced activation of the NF-kappa B pathway. In addition to modulation of IKK activity, the NF-kappa B pathway is also regulated by other processes, including the nucleocytoplasmic shuttling of various components of this pathway and the post-translational modification of factors bound to NF-kappa B-dependent promoters. In this study, we explored the role of the nucleocytoplasmic shuttling of components of the IKK complex in the regulation of the NF-kappa B pathway. IKK gamma/NEMO was demonstrated to shuttle between the cytoplasm and the nucleus and to interact with the nuclear coactivator cAMP-responsive element-binding protein-binding protein (CBP). Using both in vitro and in vivo analysis, we demonstrated that IKK gamma/NEMO competed with p65 and IKK alpha for binding to the N terminus of CBP, inhibiting CBP-dependent transcriptional activation. These results indicate that, in addition to the key role of IKK gamma/NEMO in regulating cytokine-induced IKK activity, its ability to shuttle between the cytoplasm and the nucleus and to bind to CBP can lead to transcriptional repression of the NF-kappa B pathway.