Inhibition of NF-κB Activity by Thalidomide through Suppression of IκB Kinase Activity

The sedative and anti-nausea drug thalidomide, which causes birth defects in humans, has been shown to have both anti-inflammatory and anti-oncogenic properties. The anti-inflammatory effect of thalidomide is associated with suppression of cytokine expression and the anti-oncogenic effect with inhibition of angiogenesis. It is presently unclear whether the teratogenic properties of thalidomide are connected in any way to the beneficial, anti-disease characteristics of this drug. The transcription factor NF-κB has been shown to be a key regulator of inflammatory genes such as tumor necrosis factor-α and interleukin-8. Inhibition of NF-κB is associated with reduced inflammation in animal models, such as those for rheumatoid arthritis. We show here that thalidomide can block NF-κB activation through a mechanism that involves the inhibition of activity of the IκB kinase. Consistent with the observed inhibition of NF-κB, thalidomide blocked the cytokine-induced expression of NF-κB-regulated genes such as those encoding interleukin-8, TRAF1, and c-IAP2. These data indicate that the therapeutic potential for thalidomide may be based on its ability to block NF-κB activation through suppression of IκB kinase activity

Chemotherapy-induced muscle wasting: Association with NF-κB and cancer cachexia

A compounding feature of greater than 50% of all cancers is the high incidence of the cachexia syndrome, a complex metabolic disorder characterized by extreme weight loss due mainly to the gross depletion of skeletal muscle tissue. Although studies into the cause of cancer cachexia has spanned over multiple decades, little is known about the effects of various cancer treatments themselves on cachexia. For example, chemotherapy agents induce side effects such as nausea and anorexia, but these symptoms do not fully account for the changes seen with cancer cachexia. In this study we examine the effects of chemotherapeutic compounds, specifically, cisplatin in the colon-26 adenocarcinoma model of cancer cachexia. We find that although cisplatin is able to reduce tumor burden as expected, muscle wasting in mice nevertheless persists. Strikingly, cisplatin alone was seen to regulate muscle atrophy, which was independent of the commonly implicated ubiquitin proteasome system. Finally, we show that cisplatin is able to induce NF-κB activity in both mouse muscles and myotube cultures, suggesting that an additional side effect of cancer treatment is the regulation of muscle wasting that may be mediated through activation of the NF-κB signaling pathway

Iκbα gene transfer is cytotoxic to squamous-cell lung cancer cells and sensitizes them to tumor necrosis factor-α-mediated cell death

Current paradigms in cancer therapy suggest that activation of nuclear factor-κB (NF-κB) by a variety of stimuli, including some cytoreductive agents, may inhibit apoptosis. Thus, inhibiting NF-κB activation may sensitize cells to anticancer therapy, thereby providing a more effective treatment for certain cancers. E-1-deleted adenoviral (Ad) vectors encoding a "superrepressor" form of the NF-κB inhibitor IκBα (AdIκBαSR) or β-galactosidase (AdLacZ) were tested alone and in combination with tumor necrosis factor-α (TNF-α) in lung cancer cells for sensitization of the cells to death. Following transduction with AdIκBαSR, lung cancer cells expressed IκBαSR in a dose-dependent manner. Probing nuclear extracts of lung cancer cells with NF-κB-sequence-specific oligonucleotides indicated that there was a minimal amount of NF-κB in the nucleus at baseline and an expected and dramatic increase in nuclear NF-κB following exposure of cells to TNF-α. Control E-1-deleted AdLacZ did not promote NF-κB activation. Importantly, AdIκBαSR-mediated gene transfer resulted in the complete block of nuclear translocation of NF-κB by specific binding of its p65/relA component with transgenic IκBαSR. At the cellular level, transduction with AdIκBαSR resulted in increased cytotoxicity in lung cancer cells as opposed to transduction with equivalent doses of AdLacZ. In addition, whereas the parental cells were resistant to TNF-α-mediated cytotoxicity, IκBαSR-transduced cells could be sensitized to TNF-α. Consequently, AdIκBαSR transduction followed by exposure to TNF-α uniformly resulted in the death of non-small-cell lung cancer cells. These data suggest that novel approaches incorporating IκBα gene therapy may have a role in the treatment of lung cancer

NF-κB and IκBα are found in the mitochondria. Evidence for regulation of mitochondrial gene expression by NF-κB

The transcription factor NF-κB has been shown to be predominantly cytoplasmically localized in the absence of an inductive signal. Stimulation of cells with inflammatory cytokines such as tumor necrosis factor α or interleukin-1 induces the degradation of IκB, the inhibitor of NF-κB, allowing nuclear accumulation of NF-κB and regulation of specific gene expression. The degradation of IκB is controlled initially by phosphorylation induced by the IκB kinase, which leads to ubiquitination and subsequent proteolysis of the inhibitor by the proteasome. We report here that NF-κB and IκBα (but not IκBβ) are also localized in the mitochondria. Stimulation of cells with tumor necrosis factor α leads to the phosphorylation of mitochondrial IκBα and its subsequent degradation by a nonproteasome-dependent pathway. Interestingly, expression of the mitochondrially encoded cytochrome c oxidase III and cytochrome b mRNAs were reduced by cytokine treatment of cells. Inhibition of activation of mitochondrial NF-κB by expression of the superrepressor form of IκBα inhibited the loss of expression of both cytochrome c oxidase III and cytochrome b mRNA. These data indicate that the NF-κB regulatory pathway exists in mitochondria and that NF-κB can negatively regulate mitochondrial mRNA expression

Regulation of skeletal muscle oxidative phenotype by classical NF-κB signalling.

AbstractBackgroundImpairments in skeletal muscle oxidative phenotype (OXPHEN) have been linked to the development of insulin resistance, metabolic inflexibility and progression of the metabolic syndrome and have been associated with progressive disability in diseases associated with chronic systemic inflammation. We previously showed that the inflammatory cytokine tumour necrosis factor-α (TNF-α) directly impairs muscle OXPHEN but underlying molecular mechanisms remained unknown. Interestingly, the inflammatory signalling pathway classical nuclear factor-κB (NF-κB) is activated in muscle in abovementioned disorders. Therefore, we hypothesised that muscle activation of classical NF-κB signalling is sufficient and required for inflammation-induced impairment of muscle OXPHEN.MethodsMyotubes from mouse and human muscle cell lines were subjected to activation or blockade of the classical NF-κB pathway. In addition, wild-type and MISR (muscle-specific inhibition of classical NF-κB) mice were injected intra-muscularly with TNF-α. Markers and key regulators of muscle OXPHEN were investigated.ResultsClassical NF-κB activation diminished expression of oxidative phosphorylation (OXPHOS) sub-units, slow myosin heavy chain expression, activity of mitochondrial enzymes and potently reduced intra-cellular ATP levels. Accordingly, PGC-1/PPAR/NRF-1/Tfam signalling, the main pathway controlling muscle OXPHEN, was impaired upon classical NF-κB activation which required intact p65 trans-activation domains and depended on de novo gene transcription. Unlike wild-type myotubes, IκBα-SR myotubes (blocked classical NF-κB signalling) were refractory to TNF-α-induced impairments in OXPHEN and its regulation by the PGC-1/PPAR/NRF-1/Tfam cascade. In line with in vitro data, NF-κB blockade in vivo abrogated TNF-α-induced reductions in PGC-1α expression.ConclusionClassical NF-κB activation impairs skeletal muscle OXPHEN

IκBα and p65 Regulate the Cytoplasmic Shuttling of Nuclear Corepressors: Cross-talk between Notch and NFκB Pathways

Notch and NFκB pathways are key regulators of numerous cellular events such as proliferation, differentiation, or apoptosis. In both pathways, association of effector proteins with nuclear corepressors is responsible for their negative regulation. We have previously described that expression of a p65-NFκB mutant that lacks the transactivation domain (p65ΔTA) induces cytoplasmic translocation of N-CoR leading to a positive regulation of different promoters. Now, we show that cytoplasmic sequestration of p65 by IκBα is sufficient to both translocate nuclear corepressors SMRT/N-CoR to the cytoplasm and upregulate transcription of Notch-dependent genes. Moreover, p65 and IκBα are able to directly bind SMRT, and this interaction can be inhibited in a dose-dependent manner by the CREB binding protein (CBP) coactivator and after TNF-α treatment, suggesting that p65 acetylation is modulating this interaction. In agreement with this, TNF-α treatment results in downregulation of the Hes1 gene. Finally, we present evidence on how this mechanism may influence cell differentiation in the 32D myeloid progenitor system