NF-kappaB activation and IkappaB alpha dynamism involved in iNOS and chemokine induction in astroglial cells

This review will discuss the recent literature on the molecular mechanism of NF-kappaB activation, with special focus on IkappaB alpha dynamism involved in iNOS- and chemokine-induction in glial cells. NF-kappaB, a heterotrimer composed of p50, p65 (Rel A) and IkappaB alpha, has been shown to be activated by elimination of the regulatory subunit IkappaB alpha from the heterotrimer. The elimination of IkappaB alpha (formation of active NF-kappaB, p50-p65) is due to phosplorylation of serines 32 and 36 of IkappaB alpha, followed by polyubiquitination and 26S proteasomal degradation of IkappaB alpha. Experiments using stable clones of rat C6 glioma cells transfected with dominant negative IkappaB alpha (serines 32 and 36 replaced by alanine) suggest that NF-kappaB activation (phosphorylation of IkappaB alpha) is involved in LPS/IFNgamma- or IL-1beta/IFNgamma-induced iNOS expression. Furthermore, the time courses of phosphorylation, ubiquitination of IkappaB alpha and proteasome activity after IL-1beta treatment also suggest that 26S proteasomal degradation of IkappaB alpha is more crucial for chemokine expression in glial cells.     

The carboxyl-terminal region of IkappaB kinase gamma (IKKgamma) is required for full IKK activation

IkappaB kinase gamma (IKKgamma) (also known as NEMO, Fip-3, and IKKAP-1) is the essential regulatory component of the IKK complex; it is required for NF-kappaB activation by various stimuli, including tumor necrosis factor alpha (TNF-alpha), interleukin 1 (IL-1), phorbol esters, lipopolysaccharides, and double-stranded RNA. IKKgamma is encoded by an X-linked gene, deficiencies in which may result in two human genetic disorders, incontinentia pigmenti (IP) and hypohidrotic ectodermal dysplasia with severe immunodeficiency. Subsequent to the linkage of IKKgamma deficiency to IP, we biochemically characterized the effects of a mutation occurring in an IP-affected family on IKK activity and NF-kappaB signaling. This particular mutation results in premature termination, such that the variant IKKgamma protein lacks its putative C-terminal Zn finger and, due to decreased mRNA stability, is underexpressed. Correspondingly, IKK and NF-kappaB activation by TNF-alpha and, to a lesser extent, IL-1 are reduced. Mutagenesis of the C-terminal region of IKKgamma was performed in an attempt to define the role of the putative Zn finger and other potential functional motifs in this region. The mutants were expressed in IKKgamma-deficient murine embryonic fibroblasts (MEFs) at levels comparable to those of endogenous IKKgamma in wild-type MEFs and were able to associate with IKKalpha and IKKbeta. Substitution of two leucines within a C-terminal leucine zipper motif markedly reduced IKK activation by TNF-alpha and IL-1. Another point mutation resulting in a cysteine-to-serine substitution within the putative Zn finger motif affected IKK activation by TNF-alpha but not by IL-1. These results may explain why cells that express these or similar mutant alleles are sensitive to TNF-alpha-induced apoptosis despite being able to activate NF-kappaB in response to other stimuli.     

NF-kappaB activation by double-stranded-RNA-activated protein kinase (PKR) is mediated through NF-kappaB-inducing kinase and IkappaB kinase

The interferon (IFN)-inducible double-stranded-RNA (dsRNA)-activated serine-threonine protein kinase (PKR) is a major mediator of the antiviral and antiproliferative activities of IFNs. PKR has been implicated in different stress-induced signaling pathways including dsRNA signaling to nuclear factor kappa B (NF-kappaB). The mechanism by which PKR mediates activation of NF-kappaB is unknown. Here we show that in response to poly(rI). poly(rC) (pIC), PKR activates IkappaB kinase (IKK), leading to the degradation of the inhibitors IkappaBalpha and IkappaBbeta and the concomitant release of NF-kappaB. The results of kinetic studies revealed that pIC induced a slow and prolonged activation of IKK, which was preceded by PKR activation. In PKR null cell lines, pIC failed to stimulate IKK activity compared to cells from an isogenic background wild type for PKR in accord with the inability of PKR null cells to induce NF-kappaB in response to pIC. Moreover, PKR was required to establish a sustained response to tumor necrosis factor alpha (TNF-alpha) and to potentiate activation of NF-kappaB by cotreatment with TNF-alpha and IFN-gamma. By coimmunoprecipitation, PKR was shown to be physically associated with the IKK complex. Transient expression of a dominant negative mutant of IKKbeta or the NF-kappaB-inducing kinase (NIK) inhibited pIC-induced gene expression from an NF-kappaB-dependent reporter construct. Taken together, these results demonstrate that PKR-dependent dsRNA induction of NF-kappaB is mediated by NIK and IKK activation.     

NF-kappaB is required for UV-induced JNK activation via induction of PKCdelta

Ultraviolet (UV) exerts its biological activities by activating downstream effectors, including NF-kappaB, JNK, and caspases. Activation of JNK is required for UV-induced apoptosis. It is unknown whether any crosstalk occurs between NF-kappaB and JNK in response to UV and, if so, how it affects UV killing. Here we report that NF-kappaB promotes UV-induced JNK activation, thereby contributing to UV-induced apoptosis. UV-induced JNK activation is impaired in RelA/NF-kappaB null murine embryonic fibroblasts. In resting cells, the preexisting nuclear RelA has already been recruited to PKCdelta promoter and is essential for its expression. UV-induced rapid and robust activation of JNK requires PKCdelta, which augments JNK phosphorylation-activation by its upstream kinases. The RelA/NF-kappaB-PKCdelta-JNK pathway is critical for UV-induced apoptosis, as it induces the immediate expression of the proapoptotic Fas ligand. Thus, our results demonstrate that RelA/NF-kappaB via PKCdelta positively regulates UV-induced JNK activation and provide a mechanism by which NF-kappaB promotes UV-induced apoptosis.     

Caspase-mediated activation and induction of apoptosis by the mammalian Ste20-like kinase Mst1.

Mst1 is a ubiquitously expressed serine-threonine kinase, homologous to the budding yeast Ste20, whose physiological regulation and cellular function are unknown. In this paper we show that Mst1 is specifically cleaved by a caspase 3-like activity during apoptosis induced by either cross-linking CD95/Fas or by staurosporine treatment. CD95/Fas-induced cleavage of Mst1 was blocked by the cysteine protease inhibitor ZVAD-fmk, the more selective caspase inhibitor DEVD-CHO and by the viral serpin CrmA. Caspase-mediated cleavage of Mst1 removes the C-terminal regulatory domain and correlates with an increase in Mst1 activity in vivo, consistent with caspase-mediated cleavage activating Mst1. Overexpression of either wild-type Mst1 or a truncated mutant induces morphological changes characteristic of apoptosis. Furthermore, exogenously expressed Mst1 is cleaved, indicating that Mst1 can activate caspases that result in its cleavage. Kinase-dead Mst1 did not induce morphological alterations and was not cleaved upon overexpression, indicating that Mst1 must be catalytically active in order to mediate these effects. Mst1 activates MKK6, p38 MAPK, MKK7 and SAPK in co-transfection assays, suggesting that Mst1 may activate these pathways. Our findings suggest the existence of a positive feedback loop involving Mst1, and possibly the SAPK and p38 MAPK pathways, which serves to amplify the apoptotic response.     

Essential role of IkappaB kinase alpha in thymic organogenesis required for the establishment of self-tolerance

IkappaB kinase (IKK) alpha exhibits diverse biological activities through protein kinase-dependent and -independent functions, the former mediated predominantly through a noncanonical NF-kappaB activation pathway. The in vivo function of IKKalpha, however, still remains elusive. Because a natural strain of mice with mutant NF-kappaB-inducing kinase (NIK) manifests autoimmunity as a result of disorganized thymic structure with abnormal expression of Rel proteins in the thymic stroma, we speculated that the NIK-IKKalpha axis might constitute an essential step in the thymic organogenesis that is required for the establishment of self-tolerance. An autoimmune disease phenotype was induced in athymic nude mice by grafting embryonic thymus from IKKalpha-deficient mice. The thymic microenvironment that caused autoimmunity in an IKKalpha-dependent manner was associated with defective processing of NF-kappaB2, resulting in the impaired development of thymic epithelial cells. Thus, our results demonstrate a novel function for IKKalpha in thymic organogenesis for the establishment of central tolerance that depends on its protein kinase activity in cooperation with NIK.     

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.     

Hepatitis C virus core protein suppresses NF-kappaB activation and cyclooxygenase-2 expression by direct interaction with IkappaB kinase beta

In addition to hepatocytes, hepatitis C virus (HCV) infects immune cells, including macrophages. However, little is known concerning the impact of HCV infection on cellular functions of these immune effector cells. Lipopolysaccharide (LPS) activates IkappaB kinase (IKK) signalsome and NF-kappaB, which leads to the expression of cyclooxygenase-2 (COX-2), which catalyzes production of prostaglandins, potent effectors on inflammation and possibly hepatitis. Here, we examined whether expression of HCV core interferes with IKK signalsome activity and COX-2 expression in activated macrophages. In reporter assays, HCV core inhibited NF-kappaB activation in RAW 264.7 and MH-S murine macrophage cell lines treated with bacterial LPS. HCV core inhibited IKK signalsome and IKKbeta kinase activities induced by tumor necrosis factor alpha in HeLa cells and coexpressed IKKgamma in 293 cells, respectively. HCV core was coprecipitated with IKappaKappabeta and prevented nuclear translocation of IKKbeta. NF-kappaB activation by either LPS or overexpression of IKKbeta was sufficient to induce robust expression of COX-2, which was markedly suppressed by ectopic expression of HCV core. Together, these data indicate that HCV core suppresses IKK signalsome activity, which blunts COX-2 expression in macrophages. Additional studies are necessary to determine whether interrupted COX-2 expression by HCV core contributes to HCV pathogenesis.