Structural motifs involved in ubiquitin-mediated processing of the NF-kappaB precursor p105: roles of the glycine-rich region and a downstream ubiquitination domain

Functional identification of the pro-apoptotic effector domain in human Sox4

Recent studies provide evidence that Sox4 is involved in regulating apoptosis as well as tumorigenesis of various human cancers; however, its role in the apoptotic machinery is not fully understood. Here we describe that the central domain containing glycine-rich region in Sox4, named CD, is a pivotal pro-apoptotic domain to induce apoptotic cell death. Deletion of the DNA-binding domain or trans-activation domain in Sox4 did not significantly affect pro-apoptotic activity, whereas transient transfection of the high mobility group box or the serine-rich region abrogated the apoptotic activity. Moreover, overexpression of the CD construct (aa 166-342) revealed the apoptotic activity comparable to that of wild-type Sox4, approximately 60% of cell death. Our data suggest that the apoptotic activity of Sox4 can be dissociated from its transcriptional trans-activation and is mediated through its CD.

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.

I?B? is expressed in mast cells

IkappaBgamma (IkappaBgamma) is a 70-kDa protein that is encoded by the C-terminal part of the NF-kappaB p105 gene and acts as an inhibitor of the transcription factor NF-kappaB. Until now, IkappaBgamma expression has only been described in cell-culture models of B-lymphocytes and enterocytes but not in tissues. In a model of radiation-induced pulmonary damage, we found that mast cells accumulating after irradiation are the only cells in the rat lung that are positive for IkappaBgamma. The mast cells were characterised by their metachromatic staining with toluidine blue and by double immunofluorescence labelling with mast-cell tryptase. Western blotting revealed that the lung mast cells expressed the 70-kDa form of IkappaBgamma cytoplasmatically and that no alternative splicing variants were expressed. In addition, we studied 11 cases of systemic mastocytosis, as well as 5 cases of mast-cell hyperplasia. In all cases, the mast cells stained strongly with IkappaBgamma. Rat peritoneal mast cells also contained high levels of IkappaBgamma. Since NF-kappaB is an important regulator of mast-cell functions, IkappaBgamma is likely to play a central role in the maintenance of the mast-cell phenotype and possibly in the modification of mast-cell-dependent immune responses.

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.

An unstructured initiation site is required for efficient proteasome-mediated degradation

The proteasome is the main ATP-dependent protease in eukaryotic cells and controls the concentration of many regulatory proteins in the cytosol and nucleus. Proteins are targeted to the proteasome by the covalent attachment of polyubiquitin chains. The ubiquitin modification serves as the proteasome recognition element but by itself is not sufficient for efficient degradation of folded proteins. We report that proteolysis of tightly folded proteins is accelerated greatly when an unstructured region is attached to the substrate. The unstructured region serves as the initiation site for degradation and is hydrolyzed first, after which the rest of the protein is digested sequentially. These results identify the initiation site as a novel component of the targeting signal, which is required to engage the proteasome unfolding machinery efficiently. The proteasome degrades a substrate by first binding to its ubiquitin modification and then initiating unfolding at an unstructured region.

Nuclear factor-kappaB modulation as a therapeutic approach in hematologic malignancies

Nuclear factor-kappaB (NF-kappaB) is a collective term that refers to a small class of dimeric transcription factors for a number of genes, including growth factors, angiogenesis modulators, cell-adhesion molecules, and antiapoptotic factors. Although most NF-kappaB proteins promote transcription, some act as inactivating or repressive complexes. The most common p50-RelA (p65) dimer known "specifically" as NF-kappaB, is relatively abundant, controls the expression of numerous genes, and exists as an inactive cytoplasmic complex bound to inhibitory proteins of the NF-kappaB inhibitor (IkappaB) family. The inactive NF-kappaB-IkappaB complex is activated by a variety of stimuli, including proinflammatory cytokines, mitogens, growth factors, and stress-inducing agents. The release of NF-kappaB facilitates its translocation to the nucleus, where it promotes cell survival by initiating the transcription of genes encoding stress-response enzymes, cell-adhesion molecules, proinflammatory cytokines, and antiapoptotic proteins. Constitutive activation of NF-kappaB in the nucleus is observed in some hematologic disorders. With the recent approval of bortezomib for patients with advanced multiple myeloma, NF-kappaB modulation is likely to be a therapeutic endeavor of increasing interest in coming years.

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.

TRAIL and NFkappaB signaling--a complex relationship

Tumor necrosis factor (TNF)-related apoptosis-inducing ligand (TRAIL) or Apo2L is a ligand of the TNF family interacting with five different receptors of the TNF receptor superfamily, including two death receptors. It has attracted wide interest as a potential anticancer therapy because some recombinant soluble forms of TRAIL induce cell death predominantly in transformed cells. The nuclear factor-kappaB (NFkappaB)?Rel family of proteins are composed of a group of dimeric transcription factors that have an outstanding role in the regulation of inflammation and immunity. Control of transcription by NFkappaB proteins can be of relevance to the function of TRAIL in three ways. First, induction of antiapoptotic NFkappaB dependent genes critically determines cellular susceptibility toward apoptosis induction by TRAIL-R1, TRAIL-R2, and other death receptors. Each of the multiple of known NFkappaB inducers therefore has the potential to interfere with TRAIL-induced cell death. Second, TRAIL and some of its receptors are inducible by NFkappaB, disclosing the possibility of autoamplifying TRAIL signaling loops. Third, the TRAIL death receptors can activate the NFkappaB pathway. This chapter summarizes basic knowledge regarding the understanding of the NFkappaB pathway and focuses on its multiple roles in TRAIL signaling.

A p105-based inhibitor broadly represses NF-kappa B activities

An IkappaBalpha-based NF-kappaB super repressor (sr) has been used widely for studying genes regulated by NF-kappaB transcription factors. Repression of NF-kappaB by IkappaBalpha(sr) also facilitates tumor necrosis factor alpha-induced apoptosis in the cell. However, IkappaBalpha primarily targets RelA and c-Rel-containing complexes, leaving other NF-kappaB/Rel protein complexes, such as p50 and p52 homodimers, and RelB heterodimers uninhibited. Because these atypical NF-kappaB complexes also contribute to gene regulation and are activated in pathological conditions, broad inhibition of all NF-kappaB species is of significant pharmacological and clinical interests. We have designed, generated, and tested a p105-based NF-kappaB super repressor. We showed that p105(sr), which no longer generates p50 and undergoes signal-induced degradation, effectively inhibits all NF-kappaB activities. In addition, we also demonstrated that p105(sr) significantly enhances tumor necrosis factor alpha-mediated killing of MT1/2 skin papilloma cells where p50 homodimer activity is elevated. Our results suggest that p105(sr) is a broader range and effective NF-kappaB super repressor and can potentially be used in cells where a noncanonical NF-kappaB activity is dominant or multiple NF-kappaB activities are activated.

Inhibition of ubiquitin/proteasome-dependent proteolysis inSaccharomyces cerevisiaeby a Gly-Ala repeat

The glycine-alanine (GA) repeat of the Epstein-Barr virus nuclear antigen-1 inhibits in cis ubiquitin-dependent proteolysis in mammalian cells through a yet unknown mechanism. In the present study we demonstrate that the GA repeat targets an evolutionarily conserved step in proteolysis since it can prevent the degradation of proteasomal substrates in the yeast Saccharomyces cerevisiae. Insertion of yeast codon-optimised recombinant GA (rGA) repeats of different length in green fluorescent protein reporters harbouring N-end rule or ubiquitin fusion degradation signals resulted in efficient stabilisation of these substrates. Protection was also achieved in rpn10delta yeast suggesting that this polyubiquitin binding protein is not required for the rGA effect. The conserved effect of the GA repeat in yeast opens the possibility for the use of genetic screens to unravel its mode of action.

Multifaceted roles of beta-arrestins in the regulation of seven-membrane-spanning receptor trafficking and signalling

Beta-arrestins are cytosolic proteins that bind to activated and phosphorylated G-protein-coupled receptors [7MSRs (seven-membrane-spanning receptors)] and uncouple them from G-protein-mediated second messenger signalling pathways. The binding of beta-arrestins to 7MSRs also leads to new signals via activation of MAPKs (mitogen-activated protein kinases) such as JNK3 (c-Jun N-terminal kinase 3), ERK1/2 (extracellular-signal-regulated kinase 1/2) and p38 MAPKs. By binding to endocytic proteins [clathrin, AP2 (adapter protein 2), NSF (N -ethylmaleimide-sensitive fusion protein) and ARF6 (ADP-ribosylation factor 6)], beta-arrestins also serve as adapters to link the receptors to the cellular trafficking machinery. Agonist-promoted ubiquitination of beta-arrestins is a prerequisite for their role in receptor internalization, as well as a determinant of the differing trafficking patterns of distinct classes of receptors. Recently, beta-arrestins have also been implicated as playing novel roles in cellular chemotaxis and apoptosis. By virtue of their ability to bind, in a stimulus-dependent fashion, to 7MSRs as well as to different classes of cellular proteins, beta-arrestins serve as versatile adapter proteins that regulate the signalling and trafficking of the receptors.

Glycogen synthase kinase-3 beta regulates NF-kappa B1/p105 stability

A number of different kinases have been implicated in NF-kappa B regulation and survival function. Here we investigated the molecular cross-talk between glycogen synthase kinase-3 beta (GSK-3 beta) and the p105 precursor of the NF-kappa B p50 subunit. GSK-3 beta forms an in vivo complex with and specifically phosphorylates NF-kappa B1/p105 at Ser-903 and Ser-907 in vitro. In addition, the p105 phosphorylation level is reduced in fibroblasts lacking GSK-3 beta as compared with wild-type cells. GSK-3 beta has a dual effect on p105: it stabilizes p105 under resting conditions and primes p105 for degradation upon tumor necrosis factor (TNF)-alpha treatment. Indeed, constitutive processing of p105 to p50 occurs at a higher rate in cells lacking GSK-3 beta with respect to wild-type cells and can be reduced upon reintroduction of GSK-3 beta by transfection. Moreover, p105 degradation in response to TNF-alpha is prevented in GSK-3 beta-/- fibroblasts and by a Ser to Ala point mutation on p105 at positions 903 or 907. Interestingly, the increased sensitiveness to TNF-alpha-induced death occurring in GSK-3 beta-/- fibroblasts, which is coupled to a perturbation of p50/105 ratio, can be reproduced by p105 silencing in wild-type fibroblasts.

Stability of the Rel homology domain is critical for generation of NF-kappa B p50 subunit

The NF-kappa B transcription factor p50 and the Rel protein-specific transcription inhibitor p105 are both encoded by the nfkb1 gene. The p50 protein is incorporated within the N-terminal portion of p105 and is a unique product of proteasomal processing. Because proteasome-mediated proteolysis generally results in complete degradation of the substrate, how p50 survives the proteasomal processing remains unknown. Survival of proteasomal processing has also been observed recently for the yeast transcription factors SPT23 and MGA2, but the mechanism is also unclear. Here we show evidence that stability of the Rel homology domain (RHD) within the N-terminal portion of the NF-kappa B 1 protein is required for p50 generation. We demonstrated that proteolysis initiated at an internal location of the NF-kappa B 1 protein, which normally generates p50, degrades the N-terminal portion of the NF-kappa B 1 protein when the RHD is destabilized. Our findings highlight the critical role of the unique structure of the RHD for the survival of p50 during proteosomal processing.

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.

Stabilization signals: a novel regulatory mechanism in the ubiquitin/proteasome system

The turnover of cellular proteins is a highly organized process that involves spatially and temporally regulated degradation by the ubiquitin/proteasome system. It is generally acknowledged that the specificity of the process is determined by constitutive or conditional protein domains, the degradation signals, that target the substrate for proteasomal degradation. In this review, we discuss a new type of regulatory domain: the stabilization signal. A model is proposed according to which protein half-lives are determined by the interplay of counteracting degradation and stabilization signals.

Proteasomal degradation of tau protein

Filamentous inclusions composed of the microtubule-associated protein tau are a defining characteristic of a large number of neurodegenerative diseases. Here we show that tau degradation in stably transfected and non-transfected SH-SY5Y cells is blocked by the irreversible proteasome inhibitor lactacystin. Further, we find that in vitro, natively unfolded tau can be directly processed by the 20S proteasome without a requirement for ubiquitylation, and that a highly reproducible pattern of degradation intermediates is readily detectable during this process. Analysis of these intermediates shows that 20S proteasomal processing of tau is bi-directional, proceeding from both N- and C-termini, and that populations of relatively stable intermediates arise probably because of less efficient digestion of the C-terminal repeat region. Our results are consistent with an in vivo role for the proteasome in tau degradation and support the existence of ubiquitin-independent pathways for the proteasomal degradation of unfolded proteins.

Concurrent translocation of multiple polypeptide chains through the proteasomal degradation channel

The proteasome can actively unfold proteins by sequentially unraveling their substrates from the attachment point of the degradation signal. To investigate the steric constraints imposed on substrate proteins during their degradation by the proteasome, we constructed a model protein in which specific parts of the polypeptide chain were covalently connected through disulfide bridges. The cross-linked model proteins were fully degraded by the proteasome, but two or more cross-links retarded the degradation slightly. These results suggest that the pore of the proteasome allows the concurrent passage of at least three stretches of a polypeptide chain. A degradation channel that can tolerate some steric bulk may reconcile the two opposing needs for degradation that is compartmentalized to avoid aberrant proteolysis yet able to handle a range of substrates of various sizes.

Regulating the 26S proteasome

Despite the fact that the composition of proteasomes purified from different species is almost identical, and the basic components of the proteasome are remarkably conserved among all eukaryotes, there are quite a few additional proteins that show up in certain purifications or in certain screens. There is increasing evidence that the proteasome is in fact a dynamic structure forming multiple interactions with transiently associated subunits and cellular factors that are necessary for functions such as cellular localization, presentation of substrates, substrate-specific interactions, or generation of varied products. Harnessing the eukaryotic proteasome to its defined regulatory roles has been achieved by a number of means: (a) increasing the complexity of the proteasome by gene duplication, and differentiation of members within each gene family (namely the CP and RPT subunits); (b) addition of regulatory particles, complexes, and factors that influence both what enters and what exits the proteasome; and (c) signal-dependent alterations in subunit composition (for example, the CP beta to beta i exchange). It is not be surprising that the proteasome plays diverse roles, and that its specific functions can be fine-tuned depending on biological context or need.

The death domain of NF-kappa B1 p105 is essential for signal-induced p105 proteolysis

Stimulation of cells with tumor necrosis factor alpha (TNFalpha) triggers NF-kappaB1 p105 proteolysis, releasing associated Rel subunits to translocate into the nucleus and modulate target gene expression. Phosphorylation of serine 927 within the p105 PEST region by the IkappaB kinase (IKK) complex is required to promote p105 proteolysis in response to TNFalpha stimulation. In this study, the role of the p105 death domain (DD) in signal-induced p105 proteolysis is investigated. Endogenous p105 is shown to interact with the IKK complex in HeLa cells, and transient transfection experiments in 293 cells indicate that each of the catalytic components of the IKK complex, IKK1 and IKK2, can bind to p105. Interaction of p105 with both IKK1 and IKK2 is substantially reduced by deletion of the p105 DD or introduction of a specific point mutation (L841A) into the p105 DD homologous to the lpr mutation in Fas. Phosphorylation of immunoprecipitated p105 on serine 927 by purified recombinant IKK1 or IKK2 protein in vitro is dramatically reduced in both DD mutants relative to wild type. Furthermore, both of the DD mutations significantly impair the ability of low concentrations of IKK2 to induce p105 serine 927 phosphorylation and proteolysis in transiently transfected 3T3 cells. However, high levels of transiently expressed IKK2 bypass the requirement for the p105 DD to induce p105 serine 927 phosphorylation. Finally, p105 serine 927 phosphorylation by the endogenous IKK complex after TNFalpha stimulation and subsequent p105 proteolysis is blocked in both p105 DD mutants when stably expressed in HeLa cells. Thus, the p105 DD acts as a docking site for IKK, increasing its local concentration in the vicinity of the p105 PEST region and facilitating efficient serine 927 phosphorylation.

The role of p105 protein in NFkappaB activation in ANA-1 murine macrophages following stimulation with titanium particles

Macrophage activation by particulate debris from orthopaedic implants triggers an inflammatory response that ultimately leads to periprosthetic bone resorption and implant failure. TNFalpha has been identified as a critical cytokine involved in the response to debris particles but the mechanisms involved in activation of TNFalpha synthesis are unclear. The current study demonstrates rapid induction or TNFalpha following stimulation with titanium particles in the murine macrophage cell line. ANA-1. Electrophoretic mobility shift assays demonstrated NFkappaB DNA binding activity within 15 min of exposure to titanium particles, and experiments with an NFkappaB luciferase promoter confirmed the induction of NFkappaB mediated transcription by titanium particles. Furthermore, titanium particles induced a 2-fold induction in TNFalpha promoter activity, and mutation of the kappaB2a site, one of the four NFkappaB-binding sites in the TNFalpha promoter, resulted in decreased activation. Since NFtB is a critical regulator of inflammation and is involved in activation of the TNFalpha promoter, additional experiments were performed to determine the mechanism of NFkappaB activation by particles. NFKB activation was found to be dependent upon proteasome activity, since administration of MG 132, a proteasome inhibitor, blocked NFkappaB activation. However, IkappaBalpha is only slightly decreased following Ti treatment, in contrast to marked degradation following stimulation with LPS. Recently, another proteasome-dependent pathway of NFkappaB activation has been described involving degradation of p105. a precursor of p50 that binds to p65. p105 degradation occurred following titanium stimulation. suggesting that this recently described mechanism for NFKB activation is operant in ANA-1 cells following exposure to titanium particles. These findings demonstrate that activation of the NFkappaB signaling pathway is rapidly induced by titanium particles in ANA-1 cells and is associated with p105 degradation. TNFalpha induction appears to be mediated, at least in part, through NFkappaB binding to the kappaB2a site of the TNFalpha promoter.

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.

Emerging roles of ubiquitin in transcription regulation

Ubiquitin is a small protein that was initially found to function as a tag that can be covalently attached to proteins to mark them for destruction by a multisubunit, adenosine 5'-triphosphate-dependent protease called the proteasome. Ubiquitin is now emerging as a key regulator of eukaryotic messenger RNA synthesis, a process that depends on the RNA synthetic enzyme RNA polymerase II and the transcription factors that control its activity. Ubiquitin controls messenger RNA synthesis not only by mechanisms involving ubiquitin-dependent destruction of transcription factors by the proteasome, but also by an intriguing collection of previously unknown and unanticipated mechanisms that appear to be independent of the proteasome.

Taking a bite: proteasomal protein processing

The proteasome is a hollow cylindrical protease that contains active sites concealed within its central cavity. Proteasomes usually completely degrade substrates into small peptides, but in a few cases, degradation can yield biologically active protein fragments. Examples of this are the transcription factors NF-kappa B, Spt23p and Mga2p, which are generated from precursors by proteasomal processing. How distinct protein domains are spared from degradation remains a matter of debate. Here, we discuss several models and suggest a novel mechanism for proteasomal processing.

NFkappaB-dependent signaling pathways

The transcription factor NFkappaB is activated by numerous stimuli. Once NFkappaB is fully activated, it participates in the regulation of various target genes in different cells to exert its biological functions. NFkappaB has often been referred to as a central mediator of the immune response, since a large variety of bacteria and viruses can lead to the activation of NFkappaB, which in turn controls the expression of many inflammatory cytokines, chemokines, immune receptors, and cell surface adhesion molecules. Recent studies have shown that NFkappaB may function more generally as a central regulator of stress responses, since different stressful conditions, including physical stress, oxidative stress, and exposure to certain chemicals, also lead to NFkappaB activation. Furthermore, NFkappaB blocks cell apoptosis in several cell types. Taken together, these findings make it clear that NFkappaB plays an important role in cell proliferation and differentiation. It is the intention of this review to cover the various NFkappaB-dependent signaling pathways, thereby to achieve a better understanding of the mechanisms of NFkappaB activation and the physiological functions of activated NFkappaB.

The ubiquitin-proteasome proteolytic pathway: destruction for the sake of construction

Between the 1960s and 1980s, most life scientists focused their attention on studies of nucleic acids and the translation of the coded information. Protein degradation was a neglected area, considered to be a nonspecific, dead-end process. Although it was known that proteins do turn over, the large extent and high specificity of the process, whereby distinct proteins have half-lives that range from a few minutes to several days, was not appreciated. The discovery of the lysosome by Christian de Duve did not significantly change this view, because it became clear that this organelle is involved mostly in the degradation of extracellular proteins, and their proteases cannot be substrate specific. The discovery of the complex cascade of the ubiquitin pathway revolutionized the field. It is clear now that degradation of cellular proteins is a highly complex, temporally controlled, and tightly regulated process that plays major roles in a variety of basic pathways during cell life and death as well as in health and disease. With the multitude of substrates targeted and the myriad processes involved, it is not surprising that aberrations in the pathway are implicated in the pathogenesis of many diseases, certain malignancies, and neurodegeneration among them. Degradation of a protein via the ubiquitin/proteasome pathway involves two successive steps: 1) conjugation of multiple ubiquitin moieties to the substrate and 2) degradation of the tagged protein by the downstream 26S proteasome complex. Despite intensive research, the unknown still exceeds what we currently know on intracellular protein degradation, and major key questions have remained unsolved. Among these are the modes of specific and timed recognition for the degradation of the many substrates and the mechanisms that underlie aberrations in the system that lead to pathogenesis of diseases.

Regulatory functions of ubiquitination in the immune system

Protein modification via covalent attachment of ubiquitin has emerged as one of the most common regulatory processes in all eukaryotes; it is possibly second only to phosphorylation. In fact, ubiquitination and phosphorylation have much in common: both occur rapidly--often in response to an extracellular signal--and both are quickly reversed by a large set of dedicated enzymes termed deubiquitination enzymes and phosphatases, respectively. In addition, these two protein-modification events often cooperate in mobilizing a particular cellular pathway. Traditionally, ubiquitination has been associated with proteolytic events, mostly in conjunction with the 26S proteosome. Recently, however, ubiquitination has been implicated in other regulatory mechanisms. Some involve proteosome-independent protein degradation, whereas others are entirely proteolysis-independent, ranging from protein kinase activation to translation control. Therefore, it is not surprising that the ever-evolving immune system is an excellent mirror for the multiple roles played by ubiquitination within an organism.

Characterization of an N-terminally truncated cyclin A isoform in mammalian cells

Cyclin A is essential for regulating key transitions in the eukaryotic cell cycle including initiation of DNA replication and mitosis. This paper describes the characterization of a truncated cyclin A isoform (cyclin A(t)) in vitro in cultured mammalian cells and in mouse tissues. The presence of cyclin A(t) in specific cell types correlates with the ability of cell extracts to cleave in vitro translated cyclin A. In CHO-K1 cells, cyclin A processing to cyclin A(t) occurs at the N terminus; it does not involve the 26 S proteasome, nor could it be induced by conditional overexpression of the cyclin-dependent kinase inhibitor p27(Kip1). However, high cell densities lead to increased cyclin A(t) levels. Unlike full-length cyclin A, cyclin A(t) localizes to the cytoplasm, where it binds Cdk2. The data suggest that cyclin A processing occurs in vivo to yield an N-terminally truncated isoform by an unknown mechanism that is regulated by cell density. Differential subcellular localization may provide the first insights into the physiological role of cyclin A(t).

Processing of p105 Is Inhibited by Docking of p50 Active Subunits to the Ankyrin Repeat Domain, and Inhibition Is Alleviated by Signaling via the Carboxyl-terminal Phosphorylation/ Ubiquitin-Ligase Binding Domain

Processing of the p105 precursor to generate the p50 subunit of the nuclear factor kappaB transcription factor is an exceptional case in which the ubiquitin system is involved in limited processing rather than in complete destruction of the target substrate. A Gly-rich region "stop" signal in the middle of the molecule along with a neighboring downstream ubiquitination, and probably an E3 anchoring domain, have been demonstrated to be important for processing. In addition, we have shown that IkappaB kinase-mediated phosphorylation of the C-terminal domain leads to recruitment of the SCF(beta)-TrCP ubiquitin ligase with subsequent accelerated ubiquitination and processing/degradation of the precursor (Orian, A., Gonen, H., Bercovich, B., Fajerman, I., Eytan, E., Israël, A., Mercurio, F., Iwai, K., Schwartz, A. L., and Ciechanover, A. (2000) EMBO J. 19, 2580-2591). Here we show that processing of p105 molecules that contain more then four ankyrin repeats, but lack the C-terminal phosphorylation/ubiquitin ligase binding domain, is strongly inhibited by docked p50 subunits. Inhibition is caused by interference with the function of the proteasome, as conjugation is not affected. Inhibition is alleviated after IkappaB kinase phosphorylation of the C-terminal domain leads to accelerated, beta-TrCP-mediated ubiquitination and processing/degradation of p105. We suggest that under basal conditions, slow generation of p50 probably involves the mid-molecule ubiquitination/E3 recognition motif. Following stimulation, the C-terminal domain is involved in rapid processing/degradation of p105 with release of a large amount of the stored subunits that now become transcriptionally active.

Direct phosphorylation of NF-kappaB1 p105 by the IkappaB kinase complex on serine 927 is essential for signal-induced p105 proteolysis

The p105 precursor protein of NF-kappaB1 acts as an NF-kappaB inhibitory protein, retaining associated Rel subunits in the cytoplasm of unstimulated cells. Tumor necrosis factor alpha (TNFalpha) and interleukin-1alpha (IL-1alpha) stimulate p105 degradation, releasing associated Rel subunits to translocate into the nucleus. By using knockout embryonic fibroblasts, it was first established that the IkappaB kinase (IKK) complex is essential for these pro-inflammatory cytokines to trigger efficiently p105 degradation. The p105 PEST domain contains a motif (Asp-Ser(927)-Gly-Val-Glu-Thr), related to the IKK target sequence in IkappaBalpha, which is conserved between human, mouse, rat, and chicken p105. Analysis of a panel of human p105 mutants in which serine/threonine residues within and adjacent to this motif were individually changed to alanine established that only serine 927 is essential for p105 proteolysis triggered by IKK2 overexpression. This residue is also required for TNFalpha and IL-1alpha to stimulate p105 degradation. By using a specific anti-phosphopeptide antibody, it was confirmed that IKK2 overexpression induces serine 927 phosphorylation of co-transfected p105 and that endogenous p105 is also rapidly phosphorylated on this residue after TNFalpha or IL-1alpha stimulation. In vitro kinase assays with purified proteins demonstrated that both IKK1 and IKK2 can directly phosphorylate p105 on serine 927. Together these experiments indicate that the IKK complex regulates the signal-induced proteolysis of NF-kappaB1 p105 by direct phosphorylation of serine 927 in its PEST domain.

Features of the parkin/ariadne-like ubiquitin ligase, HHARI, that regulate its interaction with the ubiquitin-conjugating enzyme, Ubch7

We recently reported the identification of a RING finger-containing protein, HHARI (human homologue of Drosophila ariadne), which binds to the human ubiquitin-conjugating enzyme UbcH7 in vitro. We now demonstrate that HHARI interacts and co-localizes with UbcH7 in mammalian cells, particularly in the perinuclear region. We have further defined a minimal interaction region of HHARI comprising residues 186-254, identified individual amino acid residues essential for the interaction, and determined that the distance between the RING1 finger and IBR (in between RING fingers) domains is critical to maintaining binding. We have also established that the RING1 finger of HHARI cannot be substituted for by the highly homologous RING finger domains of either of the ubiquitin-protein ligase components c-CBL or Parkin, despite their similarity in structure and their independent capabilities to bind UbcH7. Furthermore, mutation of the RING1 finger domain of HHARI from a RING-HC to a RING-H2 type abolishes interaction with UbcH7. These studies demonstrate that very subtle changes to the domains that regulate recognition between highly conserved components of the ubiquitin pathway can dramatically affect their ability to interact.

Mechanisms of ubiquitin-mediated, limited processing of the NF-kappaB1 precursor protein p105

In most cases, target proteins of the ubiquitin system are completely degraded. In several exceptions, such as the first step in the activation of the transcriptional regulator NF-kappaB, the substrate, the precursor protein p105, is processed in a limited manner to yield the active subunit p50. p50 is derived from the N-terminal domain of p105, whereas the C-terminal domain is degraded. The mechanisms involved in this unique process have remained elusive. We have shown that a Gly-rich region (GRR) at the C-terminal domain of p50 is one important processing signal and that it interferes with processing of the ubiquitinated precursor by the 26S proteasome. Also, amino acid residues 441-454 are important for processing under non-stimulated conditions. Lys 441 and 442 serve as ubiquitination targets, whereas residues 446-454 may serve as a ligase recognition motif. Following IkappaB kinase (IKK)-mediated phosphorylation, the C-terminal domain of p105, residues 918-934, recruits the SCF(beta-TrCP) ubiquitin ligase, and ubiquitination by this complex leads to accelerated processing. The two sites appear to be recognized under different physiological conditions by two different ligases, targeting two distinct recognition motifs. We have shown that ubiquitin conjugation and processing of a series of precursors of p105 that lack the C-terminal IKK phosphorylation/TrCP binding domain, is progressively inhibited with increasing number of ankyrin repeats. Inhibition is due to docking of active NF-kappaB subunits to the ankyrin repeat domain in the C-terminal half of p105 (IkappaBgamma). Inhibition is alleviated by phosphorylation of the C-terminal domain that leads to ubiquitin-mediated degradation of the ankyrin repeat domain and release of the anchored subunits. We propose a model that may explain the requirement for two sites: a) a basal site that may be involved in co-translational processing prior to the synthesis of the ankyrin repeat domain; and b) a signal-induced site that is involved in processing/degradation of the complete molecule following cell activation, with rapid release of stored, transcriptionally active subunits.

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.

Activation of the Drosophila NF-kappaB factor Relish by rapid endoproteolytic cleavage

The Rel/NF-kappaB transcription factor Relish plays a key role in the humoral immune response in Drosophila. We now find that activation of this innate immune response is preceded by rapid proteolytic cleavage of Relish into two parts. An N-terminal fragment, containing the DNA-binding Rel homology domain, translocates to the nucleus where it binds to the promoter of the Cecropin A1 gene and probably to the promoters of other antimicrobial peptide genes. The C-terminal IkappaB-like fragment remains in the cytoplasm. This endoproteolytic cleavage does not involve the proteasome, requires the DREDD caspase, and is different from previously described mechanisms for Rel factor activation.

Cotranslational dimerization of the Rel homology domain of NF-kappaB1 generates p50-p105 heterodimers and is required for effective p50 production

Generation of the NF-kappaB p50 transcription factor is mediated by the proteasome. We found previously that p50 is generated during translation of the NFKB1 gene and that this cotranslational processing allows the production of both p50 and p105 from a single mRNA. We now demonstrate that the Rel homology domain in p50 undergoes cotranslational dimerization and that this interaction is required for efficient production of p50. We further show that this coupling of dimerization and proteasome processing during translation uniquely generates p50-p105 heterodimers. Accordingly, after the primary cotranslational event, additional posttranslational steps regulate p50 homodimer formation and the intracellular ratio of p50 and p105. This cellular strategy places p50 under the control of the p105 inhibitor early in its biogenesis, thereby regulating the pool of p50 homodimers within the cell.

Phosphorylation meets ubiquitination: the control of NF-[kappa]B activity

NF-kappaB (nuclear factor-kappaB) is a collective name for inducible dimeric transcription factors composed of members of the Rel family of DNA-binding proteins that recognize a common sequence motif. NF-kappaB is found in essentially all cell types and is involved in activation of an exceptionally large number of genes in response to infections, inflammation, and other stressful situations requiring rapid reprogramming of gene expression. NF-kappaB is normally sequestered in the cytoplasm of nonstimulated cells and consequently must be translocated into the nucleus to function. The subcellular location of NF-kappaB is controlled by a family of inhibitory proteins, IkappaBs, which bind NF-kappaB and mask its nuclear localization signal, thereby preventing nuclear uptake. Exposure of cells to a variety of extracellular stimuli leads to the rapid phosphorylation, ubiquitination, and ultimately proteolytic degradation of IkappaB, which frees NF-kappaB to translocate to the nucleus where it regulates gene transcription. NF-kappaB activation represents a paradigm for controlling the function of a regulatory protein via ubiquitination-dependent proteolysis, as an integral part of a phosphorylationbased signaling cascade. Recently, considerable progress has been made in understanding the details of the signaling pathways that regulate NF-kappaB activity, particularly those responding to the proinflammatory cytokines tumor necrosis factor-alpha and interleukin-1. The multisubunit IkappaB kinase (IKK) responsible for inducible IkappaB phosphorylation is the point of convergence for most NF-kappaB-activating stimuli. IKK contains two catalytic subunits, IKKalpha and IKKbeta, both of which are able to correctly phosphorylate IkappaB. Gene knockout studies have shed light on the very different physiological functions of IKKalpha and IKKbeta. After phosphorylation, the IKK phosphoacceptor sites on IkappaB serve as an essential part of a specific recognition site for E3RS(IkappaB/beta-TrCP), an SCF-type E3 ubiquitin ligase, thereby explaining how IKK controls IkappaB ubiquitination and degradation. A variety of other signaling events, including phosphorylation of NF-kappaB, hyperphosphorylation of IKK, induction of IkappaB synthesis, and the processing of NF-kappaB precursors, provide additional mechanisms that modulate the level and duration of NF-kappaB activity.

Amino- and carboxy-terminal PEST domains mediate gastrin stabilization of rat L-histidine decarboxylase isoforms

Control of enzymatic function by peptide hormones can occur at a number of different levels and can involve diverse pathways that regulate cleavage, intracellular trafficking, and protein degradation. Gastrin is a peptide hormone that binds to the cholecystokinin B-gastrin receptor and regulates the activity of L-histidine decarboxylase (HDC), the enzyme that produces histamine. Here we show that gastrin can increase the steady-state levels of at least six HDC isoforms without affecting HDC mRNA levels. Pulse-chase experiments indicated that HDC isoforms are rapidly degraded and that gastrin-dependent increases are due to enhanced isoform stability. Deletion analysis identified two PEST domains (PEST1 and PEST2) and an intracellular targeting domain (ER2) which regulate HDC protein expression levels. Experiments with PEST domain fusion proteins demonstrated that PEST1 and PEST2 are strong and portable degradation-promoting elements which are positively regulated by both gastrin stimulation and proteasome inhibition. A chimeric protein containing the PEST domain of ornithine decarboxylase was similarly affected, indicating that gastrin can regulate the stability of other PEST domain-containing proteins and does so independently of antizyme/antizyme inhibitor regulation. At the same time, endoplasmic reticulum localization of a fluorescent chimera containing the ER2 domain of HDC was unaltered by gastrin stimulation. We conclude that gastrin stabilization of HDC isoforms is dependent upon two transferable and sequentially unrelated PEST domains that regulate degradation. These experiments revealed a novel regulatory mechanism by which a peptide hormone such as gastrin can disrupt the degradation function of multiple PEST-domain-containing proteins.

Getting in and out of the proteasome

By far the best understood role of the proteasome is to remove ubiquitin-conjugated proteins from eukaryotric cells by hydrolysing them into small peptides of varying lengths. These include both misfolded/abnormal proteins, as well as 'normal' proteins that need to be rapidly removed for regulatory purposes. However, the proteasome is also present in numerous prokaryotic organisms, while ubiquitin, and the ubiquitin conjugating system, are not. The eukaryotic proteasome has been adapted to degrading proteins in a ubiquitin-dependent fashion by the addition of regulatory factors that assemble in different layers onto the proteolytic core of the proteasome, and by increasing the diversity of the core subunits as well. In addition to hydrolysing ubiquitinated proteins into amino acids, the proteasome can also proteolyse selected non-ubiquitinated proteins, process proteins, and possibly refold misfolded proteins. This review will focus on the different proteasome functions, and how these are used in the multiple regulatory roles the proteasome plays in eukaryotic cells.

SCF(beta)(-TrCP) ubiquitin ligase-mediated processing of NF-kappaB p105 requires phosphorylation of its C-terminus by IkappaB kinase

Processing of the p105 precursor to form the active subunit p50 of the NF-kappaB transcription factor is a unique case in which the ubiquitin system is involved in limited processing rather than in complete destruction of the target substrate. A glycine-rich region along with a downstream acidic domain have been demonstrated to be essential for processing. Here we demonstrate that following IkappaB kinase (IkappaK)-mediated phosphorylation, the C-terminal domain of p105 (residues 918-934) serves as a recognition motif for the SCF(beta)(-TrCP) ubiquitin ligase. Expression of IkappaKbeta dramatically increases processing of wild-type p105, but not of p105-Delta918-934. Dominant-negative beta-TrCP inhibits IkappaK-dependent processing. Furthermore, the ligase and wild-type p105 but not p105-Delta918-934 associate physically following phosphorylation. In vitro, SCF(beta)(-TrCP) specifically conjugates and promotes processing of phosphorylated p105. Importantly, the TrCP recognition motif in p105 is different from that described for IkappaBs, beta-catenin and human immunodeficiency virus type 1 Vpu. Since p105-Delta918-934 is also conjugated and processed, it appears that p105 can be recognized under different physiological conditions by two different ligases, targeting two distinct recognition motifs.

Ubiquitin-mediated proteolysis: biological regulation via destruction

The ubiquitin proteolytic system plays an important role in a broad array of basic cellular processes. Among these are regulation of cell cycle, modulation of the immune and inflammatory responses, control of signal transduction pathways, development and differentiation. These complex processes are controlled via specific degradation of a single or a subset of proteins. Degradation of a protein by the ubiquitin system involves two successive steps, conjugation of multiple moieties of ubiquitin and degradation of the tagged protein by the 26S proteasome. An important question concerns the identity of the mechanisms that underlie the high degree of specificity of the system. Substrate recognition is governed by a large family ubiquitin ligases that recognize the substrates, bind them and catalyze/facilitate their interaction with ubiquitin.

The I kappa B kinase (IKK) and NF-kappa B: key elements of proinflammatory signalling

NF-kappa B is a heterodimeric transcription factor that plays a key role in inflammatory and immune responses. In nonstimulated cells, NF-kappa B dimers are maintained in the cytoplasm through interaction with inhibitory proteins, the I kappa Bs. In response to cell stimulation, mainly by proinflammatory cytokines, a multisubunit protein kinase, the I kappa B kinase (IKK), is rapidly activated and phosphorylates two critical serines in the N-terminal regulatory domain of the I kappa Bs. Phosphorylated I kappa Bs are recognized by a specific E3 ubiquitin ligase complex and undergo polyubiquitination which targets them for rapid degradation by the 26S proteasome. NF-kappa B dimers, which are spared from degradation, translocate to the nucleus to activate gene transcription. There is strong biochemical and genetic evidence that the IKK complex, which consists of two catalytic subunits, IKK alpha and IKK beta, and a regulatory subunit, IKK gamma, is the master regulator of NF-kappa B-mediated innate immune and inflammatory responses. In the absence of IKK gamma, which normally connects IKK to upstream activators, no IKK or NF-kappa B activation can occur. Surprisingly, however, of the two catalytic subunits, only IKK beta is essential for NF-kappa B activation in response to proinflammatory stimuli. The second catalytic subunit, IKK alpha, plays a critical role in developmental processes, in particular formation and differentiation of the epidermis.

Modes of regulation of ubiquitin-mediated protein degradation

The ubiquitin-proteasome pathway is responsible for the major portion of specific cellular protein degradation. Ubiquitin-mediated degradation is involved in physiological regulation of many cellular processes, including cell cycle progression, differentiation, and signal transduction. Here, we review the basic mechanisms of the ubiquitin system and the various ways in which ubiquitin-mediated degradation can be modulated by physiological signals.

Persistent activation of NF-kappaB by the tax transforming protein of HTLV-1: hijacking cellular IkappaB kinases

Biochemical coupling of transcription factor NF-kappaB to antigen and co-stimulatory receptors is required for the temporal control of T-cell proliferation. In contrast to its transitory activation during normal growth-signal transduction, NF-kappaB is constitutively deployed in T-cells transformed by the type 1 human T-cell leukemia virus (HTLV-1). This viral/host interaction is mediated by the HTLV-1-encoded Tax protein, which has potent oncogenic properties. As reviewed here, Tax activates NF-kappaB primarily via a pathway leading to the chronic phosphorylation and degradation of IkappaBalpha, a cytoplasmic inhibitor of NF-kappaB. To access this pathway, Tax associates stably with a cytokine-inducible IkappaB kinase (IKK), which contains both catalytic (IKKalpha and IKKbeta) and noncatalytic (IKKgamma) subunits. Unlike their transiently induced counterparts in cytokine-treated cells, Tax-associated forms of IKKalpha and IKKbeta are persistently activated in HTLV-1-infected T cells. Acquisition of the deregulated IKK phenotype is contingent on the presence of IKKgamma, which functions as a molecular adaptor in the assembly of pathologic Tax/IkappaB kinase complexes. These findings highlight a key mechanistic role for IKK in the Tax/NF-kappaB signaling axis and define new intracellular targets for the therapeutic control of HTLV-1-associated disease.

The NF-kappa B activation pathway: a paradigm in information transfer from membrane to nucleus

Nuclear factor kappa B (NF-kappaB)/Rel proteins are dimeric, sequence-specific transcription factors involved in the activation of an exceptionally large number of genes in response to inflammation, viral and bacterial infections, and other stressful situations requiring rapid reprogramming of gene expression. In unstimulated cells, NF-kappaB is sequestered in an inactive form in the cytoplasm bound to inhibitory IkappaB proteins. Stimulation leads to the rapid phosphorylation, ubiquitinylation, and ultimately proteolytic degradation of IkappaB, which frees NF-kappaB to translocate to the nucleus and activate the transcription of its target genes. The multisubunit IkappaB kinase (IKK) responsible for the inducible phosphorylation of IkappaB appears to be the initial point of convergence for most stimuli that activate NF-kappaB. IKK contains two catalytic subunits, IKKalpha and IKKbeta, both of which phosphorylate IkappaB at sites phosphorylated in vivo. Gene knockout studies indicate that IKKbeta is primarily responsible for the activation of NF-kappaB in response to proinflammatory stimuli, whereas IKKalpha is essential for keratinocyte differentiation. The activity of IKK is regulated by phosphorylation. IKK contains a regulatory subunit, IKKgamma, which is critical for activation of IKK and is postulated to serve as a recognition site for upstream activators. When phosphorylated, the IKK recognition site on IkappaBalpha serves as a specific recognition site for the kappa-TrCP-like component of a Skp1-Cullin-F-box-type E3 ubiquitin-protein ligase. A variety of other signaling events, including phosphorylation of NF-kappaB, phosphorylation of IKK, new synthesis of IkappaBs, and the processing of NF-kappaB precursors provide mechanisms of modulating the amount and duration of NF-kappaB activity.