Characterization of the nuclear import and export functions of Ikappa B(epsilon)

Control over the nuclear localization of nuclear factor kappaB/Rel proteins is accomplished in large part through association with members of the inhibitor of kappaB (IkappaB) protein family. For example, the well studied IkappaBalpha protein actively shuttles between the nucleus and the cytoplasm and both inhibits nuclear import and mediates nuclear export of NF-kappaB/Rel proteins. In contrast, the IkappaBbeta protein can inhibit nuclear import of NF-kappaB/Rel proteins but does not remove NF-kappaB/Rel proteins from the nucleus. To further understand how the IkappaB proteins control the nuclear-cytoplasmic distribution of NF-kappaB/Rel proteins, we have characterized the nuclear import and nuclear export functions of IkappaBepsilon. Our results indicate that the IkappaBepsilon protein, like the IkappaBalpha protein, actively shuttles between the nucleus and the cytoplasm. Similar to IkappaBalpha, nuclear import of IkappaBepsilon is mediated by its ankyrin repeat domain and is not blocked by the dominant-negative RanQ69L protein. However, the nuclear import function of the IkappaBepsilon ankyrin repeat domain is markedly less efficient than that of IkappaBalpha, with the result that nuclear shuttling of IkappaBepsilon between the nucleus and the cytoplasm is significantly slower than IkappaBalpha. Nuclear export of IkappaBepsilon is mediated by a short leucine-rich nuclear export sequence (NES)-like sequence ((343)VLLPFDDLKI(352)), located between amino acids 343 and 352. This NES-like sequence is required for RanGTP-dependent binding of IkappaBepsilon to CRM1. Nuclear accumulation of IkappaB(epsilon) is increased by either leptomycin B treatment or alanine substitutions within the IkappaBepsilon-derived NES. A functional NES is required for both efficient cytoplasmic retention and post-induction control of c-Rel by IkappaBepsilon, consistent with the notion that IkappaBepsilon-mediated nuclear export contributes to control over the nucleocytoplasmic distribution of NF-kappaB/Rel proteins.     

Reductions in I kappa B epsilon and changes in NF-kappa B activity during B lymphocyte differentiation

The levels and stability of IkappaBepsilon have been examined in unstimulated and stimulated splenic B cells and compared with that of IkappaBalpha and IkappaBbeta. Primary murine splenic B cells but not T cells were found to contain high levels of IkappaBepsilon protein, equivalent to levels of the abundant IkappaBalpha. Most agents that activate IkappaBalpha and IkappaBbeta degradation do not induce rapid degradation of IkappaBepsilon. Interestingly, however, the levels of IkappaBepsilon, but not of IkappaBalpha or IkappaBbeta, are dramatically reduced upon the stimulation of B cells both in vivo and in vitro. Since IkappaBepsilon exhibits substrate specificity for NF-kappaB Rel homodimers, this suggested the possibility that changes in NF-kappaB-responsive genes might also occur during this transition. Consistent with this hypothesis, we found that a NF-kappaB reporter construct sensitive to p65/RelA homodimers is activated at the time that IkappaBepsilon levels decline following B cell stimulation. In IgG(+) B cell lines, which contain low levels of IkappaBepsilon, this same reporter construct was inactive, suggesting that the increases in Rel homodimer activity that accompany B cell stimulation are transient. However, there are differences in the level of expression of NF-kappaB-responsive genes in these IgG(+) B cell lines compared with their IgM(+) counterparts. From these data, we conclude that there are transient changes in NF-kappaB activity due to reductions in IkappaBepsilon, which might contribute to long-term, persistent changes that accompany B cell differentiation. We propose an important role for IkappaBepsilon in the differential regulation of nuclear NF-kappaB activity in stimulated B cells.     

Ikappakappa mediates NF-kappaB activation in human immunodeficiency virus-infected cells

Human monocytes and macrophages are persistent reservoirs of human immunodeficiency virus (HIV) type-1. Persistent HIV infection of these cells results in increased levels of NF-kappaB in the nucleus secondary to increased IkappaBalpha, IkappaBbeta, and IkappaBepsilon degradation, a mechanism postulated to regulate viral persistence. To characterize the molecular mechanisms regulating HIV-mediated degradation of IkappaB, we have sought to identify the regulatory domains of IkappaBalpha targeted by HIV infection. Using monocytic cells stably expressing different transdominant molecules of IkappaBalpha, we determined that persistent HIV infection of these cells targets the NH2 but not the COOH terminus of IkappaBalpha. Further analysis demonstrated that phosphorylation at S32 and S36 is necessary for HIV-dependent IkappaBalpha degradation and NF-kappaB activation. Of the putative N-terminal IkappaBalpha kinases, we demonstrated that the Ikappakappa complex, but not p90(rsk), is activated by HIV infection and mediates HIV-dependent NF-kappaB activation. Analysis of viral replication in cells that constitutively express IkappaBalpha negative transdominant molecules demonstrated a lack of correlation between virus-induced NF-kappaB (p65/p50) nuclear translocation and degree of viral persistence in human monocytes.     

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.     

RelA/p65 regulation of IkappaBbeta

IkappaB inhibitor proteins are the primary regulators of NF-kappaB. In contrast to the defined regulatory interplay between NF-kappaB and IkappaBalpha, much less is known regarding the regulation of IkappaBbeta by NF-kappaB. Here, we describe in detail the regulation of IkappaBbeta by RelA/p65. Using p65(-/-) fibroblasts, we show that IkappaBbeta is profoundly reduced in these cells, but not in other NF-kappaB subunit knockouts. This regulation prevails during embryonic and postnatal development in a tissue-specific manner. Significantly, in both p65(-/-) cells and tissues, IkappaBalpha is also reduced, but not nearly to the same extent as IkappaBbeta, thus highlighting the degree to which IkappaBbeta is dependent on p65. This dependence is based on the ability of p65 to stabilize IkappaBbeta protein from the 26S proteasome, a process mediated in large part through the p65 carboxyl terminus. Furthermore, IkappaBbeta was found to exist in both a basally phosphorylated and a hyperphosphorylated form. While the hyperphosphorylated form is less abundant, it is also more stable and less dependent on p65 and its carboxyl domain. Finally, we show that in p65(-/-) fibroblasts, expression of a proteolysis-resistant form of IkappaBbeta, but not IkappaBalpha, causes a severe growth defect associated with apoptosis. Based on these findings, we propose that tight control of IkappaBbeta protein by p65 is necessary for the maintenance of cellular homeostasis.     

X-ray crystal structure of an IkappaBbeta x NF-kappaB p65 homodimer complex

We report the crystal structure of a murine IkappaBbeta x NF-kappaB p65 homodimer complex. Crystallographic models were determined for two triclinic crystalline systems and refined against data at 2.5 and 2.1 A. The overall complex structure is similar to that of the IkappaBalpha.NF-kappaB p50/p65 heterodimer complex. One NF-kappaB p65 subunit nuclear localization signal clearly contacts IkappaBbeta, whereas a homologous segment from the second subunit of the homodimer is mostly solvent-exposed. The unique 47-amino acid insertion between ankyrin repeats three and four of IkappaBbeta is mostly disordered in the structure. Primary sequence analysis and differences in the mode of binding at the IkappaBbeta sixth ankyrin repeat and NF-kappaB p65 homodimer suggest a model for nuclear IkappaBbeta.NF-kappaB.DNA ternary complex formation. These unique structural features of IkappaBbeta may contribute to its ability to mediate persistent NF-kappaB activation.     

IkappaBbeta, but not IkappaBalpha, functions as a classical cytoplasmic inhibitor of NF-kappaB dimers by masking both NF-kappaB nuclear localization sequences in resting cells

NF-kappaB dimers, inhibitor IkappaB proteins, and NF-kappaB.IkappaB complexes exhibit distinct patterns in partitioning between nuclear and cytoplasmic cellular compartments. IkappaB-dependent modulation of NF-kappaB subcellular localization represents one of the more poorly understood processes in the NF-kappaB signaling pathway. In this study, we have combined in vitro biochemical and cell-based methods to elucidate differences in NF-kappaB regulation exhibited by the inhibitors IkappaBbeta and IkappaBalpha. We show that although both IkappaBalpha and IkappaBbeta bind to NF-kappaB with similar global architecture and stability, significant differences exist that contribute to their unique functional roles. IkappaBbeta derives its high affinity toward NF-kappaB dimers by binding to both NF-kappaB subunit nuclear localization signals. In contrast, IkappaBalpha contacts only one NF-kappaB NLS and employs its carboxyl-terminal proline, glutamic acid, serine, and threonine-rich region for high affinity NF-kappaB binding. We show that the presence of one free NLS in the NF-kappaB.IkappaBalpha complex renders it a dynamic nucleocytoplasmic complex, whereas NF-kappaB.IkappaBbeta complexes are localized to the cytoplasm of resting cells.     

Common pathway for the ubiquitination of IkappaBalpha, IkappaBbeta, and IkappaBepsilon mediated by the F-box protein FWD1.

FWD1 (the mouse homolog of Drosophila Slimb and Xenopus betaTrCP, a member of the F-box- and WD40 repeat-containing family of proteins, and a component of the SCF ubiquitin ligase complex) was recently shown to interact with IkappaBalpha and thereby to promote its ubiquitination and degradation. This protein has now been shown also to bind to IkappaBbeta and IkappaBepsilon as well as to induce their ubiquitination and proteolysis. FWD1 was shown to recognize the conserved DSGPsiXS motif (where Psi represents the hydrophobic residue) present in the NH(2)-terminal regions of these three IkappaB proteins only when the component serine residues are phosphorylated. However, in contrast to IkappaBalpha and IkappaBbeta, the recognition site in IkappaBepsilon for FWD1 is not restricted to the DSGPsiXS motif; FWD1 also interacts with other sites in the NH(2)-terminal region of IkappaBepsilon. Substitution of the critical serine residues in the NH(2)-terminal regions of IkappaBalpha, IkappaBbeta, and IkappaBepsilon with alanines also markedly reduced the extent of FWD1-mediated ubiquitination of these proteins and increased their stability. These data indicate that the three IkappaB proteins, despite their substantial structural and functional differences, all undergo ubiquitination mediated by the SCF(FWD1) complex. FWD1 may thus play an important role in NF-kappaB signal transduction through regulation of the stability of multiple IkappaB proteins.     

Induced fit, folding, and recognition of the NF-kappaB-nuclear localization signals by IkappaBalpha and IkappaBbeta

Protein structure prediction codes based on the associative memory Hamiltonian were used to probe the binding modes between the nuclear localization signal (NLS) polypeptide of NF-kappaB and the inhibitors IkappaBalpha and IkappaBbeta. Experimentally, it is known that the NLS polypeptide is unstructured in the NF-kappaB complex with DNA but it forms an extended helical structure with the NLS (residues 301-304) between the two helices in the NF-kappaB/IkappaBalpha complex. The simulations included the NF-kappaB(p65) and (p50) NLS polypeptides and various mutants alone and in the presence of IkappaBalpha and IkappaBbeta. The simulations predict that the NLS polypeptide by itself binds tightly to IkappaBalpha and IkappaBbeta. In the NF-kappaB (p50/p65) heterodimer, the p50 NLS is predicted to remain free to bind to importin alpha. In the interaction with IkappaBalpha, both p65 NLSs are predicted to be bound. In IkappaBbeta, the NLS polypeptide binds to two binding sites, as seen in the crystal structure, with one site heavily favored for stable binding.     

Postrepression Activation of NF-κB Requires the Amino-Terminal Nuclear Export Signal Specific to IκBα

One of the most prominent NF-kappaB target genes in mammalian cells is the gene encoding one of its inhibitor proteins, IkappaBalpha. The increased synthesis of IkappaBalpha leads to postinduction repression of nuclear NF-kappaB activity. However, it is unknown why IkappaBalpha, among multiple IkappaB family members, is involved in this process and what significance this feedback regulation has beyond terminating NF-kappaB activity. Herein, we report an important IkappaBalpha-specific function dictated by its amino-terminal nuclear export sequence (N-NES). The IkappaBalpha N-NES is necessary for the postinduction export of nuclear NF-kappaB, which is a critical event in reestablishing a permissive condition for NF-kappaB to be rapidly reactivated. We show that although IkappaBalpha and another IkappaB member, IkappaBbeta, can enter the nucleus and repress NF-kappaB DNA-binding activity during the postinduction phase, only IkappaBalpha allows the efficient export of nuclear NF-kappaB. Moreover, swapping the N-terminal region of IkappaBbeta for the corresponding IkappaBalpha sequence is sufficient for the IkappaB chimera protein to export NF-kappaB similarly to IkappaBalpha during the postinduction state. Our findings provide a mechanistic explanation of why IkappaBalpha but not other IkappaB members is crucial for postrepression activation of NF-kappaB. We propose that this IkappaBalpha-specific function is important for certain physiological and pathological conditions where NF-kappaB needs to be rapidly reactivated.     

Role of specific CD8+ T cells in the severity of a fulminant zoonotic viral hemorrhagic fever, hantavirus pulmonary syndrome

Infection with lesion-derived Leishmania mexicana amastigotes inhibited LPS-induced IL-12 production by mouse bone marrow-derived macrophages. This effect was associated with expression of cysteine peptidase B (CPB) because amastigotes of CPB deletion mutants had limited ability to inhibit IL-12 production, whereas preincubation of cells with a CPB inhibitor, cathepsin inhibitor IV, was able to suppress the effect of wild-type amastigotes. Infection with wild-type amastigotes resulted in a time-dependent proteolytic degradation of IkappaBalpha and IkappaBbeta and the related protein NF-kappaB. This effect did not occur with amastigotes of CPB deletion mutants or wild-type promastigotes, which do not express detectable CPB. NF-kappaB DNA binding was also inhibited by amastigote infection, although nuclear translocation of cleaved fragments of p65 NF-kappaB was still observed. Cysteine peptidase inhibitors prevented IkappaBalpha, IkappaBbeta, and NF-kappaB degradation induced by amastigotes, and recombinant CPB2.8, an amastigote-specific isoenzyme of CPB, was shown to degrade GST-IkappaBalpha in vitro. LPS-mediated IkappaBalpha and IkappaBbeta degradation was not affected by these inhibitors, confirming that the site of degradation of IkappaBalpha, IkappaBbeta, and NF-kappaB by the amastigotes was not receptor-driven, proteosomal-mediated cleavage. Infection of bone marrow macrophages with amastigotes resulted in cleavage of JNK and ERK, but not p38 MAPK, whereas preincubation with a cysteine peptidase inhibitor prevented degradation of these proteins, but did not result in enhanced protein kinase activation. Collectively, our results suggest that the amastigote-specific cysteine peptidases of L. mexicana are central to the ability of the parasite to modulate signaling via NF-kappaB and consequently inhibit IL-12 production.