Project description:The ability of the transcription factor NF-kappaB to upregulate anti-apoptotic proteins has been linked to the chemoresistance of solid tumors to standard chemotherapy. In contrast, recent studies have proposed that, in response to doxorubicin, NF-kappaB can be pro-apoptotic through repression of anti-apoptotic target genes. However, there is little evidence analyzing the outcome of NF-kappaB inhibition on the cytotoxicity of doxorubicin in studies describing pro-apoptotic NF-kappaB activity. In this study, we further characterize the activation of NF-kappaB in response to doxorubicin and evaluate its role in chemotherapy-induced cell death in sarcoma cells where NF-kappaB is reported to be pro-apoptotic. Doxorubicin treatment in U2OS cells induced canonical NF-kappaB activity as evidenced by increased nuclear accumulation of phosphorylated p65 at serine 536 and increased DNA-binding activity. Co-treatment with a small molecule IKKbeta inhibitor, Compound A, abrogated this response. RT-PCR evaluation of anti-apoptotic gene expression revealed that doxorubicin-induced transcription of cIAP2 was inhibited by Compound A, while doxorubicin-induced repression of other anti-apoptotic genes was unaffected by Compound A or siRNA to p65. Furthermore, the combination of doxorubicin and canonical NF-kappaB inhibition with Compound A or siRNA to p65 resulted in decreased cell viability measured by trypan blue staining and MTS assay and increased apoptosis measured by cleaved poly (ADP-ribose) polymerase and cleaved caspase 3 when compared to doxorubicin alone. Our results demonstrate that doxorubicin-induced canonical NF-kappaB activity associated with phosphorylated p65 is anti-apoptotic in its function and that doxorubicin-induced repression of anti-apoptotic genes occurs independent of p65. Therefore, combination therapies incorporating NF-kappaB inhibitors together with standard chemotherapies remains a viable method to improve the clinical outcomes in patients with advanced stage malignancies.

Project description:Specific therapies are not available for inflammatory muscle diseases. We and others have shown that the pro-inflammatory NF-kappaB pathway is highly activated in these conditions. Since NF-kappaB is an important therapeutic target, we decided to utilize an in vitro screening assay to identify potential inhibitors that block TNF-alpha induced NF-kappaB activation in a C2C12 muscle line stably expressing an NF-kappaB luciferase reporter gene. Upon evaluation of multiple anti-inflammatory agents in undifferentiated myoblasts as well as differentiated myotubes , we found different levels of inhibition depending on the state of differentiation. Interestingly, we found that some drugs that are known to inhibit NF-kappaB in immune cells were not effective in muscle cells. Drug toxicity was assessed for using an MTT cell viability assay, and the validity of the luciferase assay was verified by immunostaining for NF-kappaB nuclear translocation in myoblasts. In conclusion, we have determined the optimal assay conditions for detecting potentially valuable NF-kappaB inhibitors for the first time in a muscle cell line that may have significant therapeutic potential for inflammatory muscle diseases.

Project description:Proteasome inhibition has become synonymous with inhibition of NF-kappaB activity. However, hyperactive NF-kappaB responses often accompany physiological conditions marked by proteasomal defects, i.e. advancing age, geriatric diseases, and bortezomib resistance. These paradoxical NF-kappaB responses are likely to be impervious to proteasomal defects because they stem from atypical NF-kappaB signaling induced by upstream mechanisms which are proteasome-independent. While this atypical pathway does not require proteasome for NF-kappaB nuclear translocation, a role for proteasome in regulating nuclear NF-kappaB remains unexplored. We now demonstrate that proteasome stringently controls transcription of inflammatory mediators regulated by this atypical NF-kappaB pathway. Proteolytic activity of the proteasome mediates the removal of the NF-kappaB subunit, p65/RelA, from inflammatory genes, thereby terminating atypical NF-kappaB-dependent transcriptional responses. For the first time, we demonstrate that both 19S and 20S components of the 26S proteasome complex are recruited to an inflammatory gene promoter; additionally, the 19S and 20S complexes appear to play distinct roles in the negative regulation of NF-kappaB-dependent transcription. By demonstrating that proteasome regulates the termination of atypical NF-kappaB-dependent transcriptional responses, these studies clearly indicate a novel, regulatory role for proteasome in atypical NF-kappaB signaling. Moreover, these results signal a potential interplay between lowered proteasomal function and increased inflammation and may explain why inflammation accompanies physiological conditions under which proteasomal function is compromised, such as during advancing age or following bortezomib treatment. Given this role for proteasome in inflammation resolution, restoration of proteasome function may constitute a novel mechanism for intervening in chronic inflammatory diseases.

Project description:Background & aimsThe pro-inflammatory functions of NF-kappaB must be tightly regulated to prevent inappropriate tissue damage and remodelling caused by activated inflammatory and wound-healing cells. The p50 subunit of NF-kappaB is emerging as an important repressor of immune and inflammatory responses, but by mechanisms that are poorly defined. This study aims to delineate p50 target genes in activated hepatic stellate cells and to outline mechanisms utilised in their repression.MethodsHepatic stellate cells were isolated from nfkb1(p50)-deficient or Wt mice and gene expression compared using microarray. Target genes were verified by qRT-PCR and p50-mediated HDAC-1 recruitment to the target genes demonstrated using chromatin immunoprecipitation.ResultsWe identify p50 as transcriptional repressor of multiple pro-inflammatory genes including Ccl2, Cxcl10, Gm-csf, and Mmp-13. These genes are over-expressed in nfkb1(p50)-deficient mice suffering from chronic hepatitis and in fibrogenic/inflammatory hepatic stellate cells isolated from nfkb1(-/-) liver. We identify Mmp-13 as a bona-fide target gene for p50 and demonstrate that p50 is required for recruitment of the transcriptional repressor histone deacetylase (HDAC)-1 to kappaB sites in the Mmp-13 promoter. Chromatin immunoprecipitations identified binding of HDAC-1 to specific regulatory regions of the Ccl2, Cxcl10, Gm-csf genes that contain predicted kappaB binding motifs. Recruitment of HDAC-1 to these genes was not observed in nfkb1(-/-) cells suggesting a requirement for p50 in a manner similar to that described for Mmp-13.ConclusionsRecruitment of HDAC-1 to inflammatory genes provides a widespread mechanism to explain the immunosuppressive properties of p50.

Project description:BackgroundSilicosis is a complex lung disease for which no successful treatment is available and therefore lung transplantation is a potential alternative. Tumor necrosis factor alpha (TNFalpha) plays a central role in the pathogenesis of silicosis. TNFalpha signaling is mediated by the transcription factor, Nuclear Factor (NF)-kappaB, which regulates genes controlling several physiological processes including the innate immune responses, cell death, and inflammation. Therefore, inhibition of NF-kappaB activation represents a potential therapeutic strategy for silicosis.Methods/findingsIn the present work we evaluated the lung transplant database (May 1986-July 2007) at the University of Pittsburgh to study the efficacy of lung transplantation in patients with silicosis (n = 11). We contrasted the overall survival and rate of graft rejection in these patients to that of patients with idiopathic pulmonary fibrosis (IPF, n = 79) that was selected as a control group because survival benefit of lung transplantation has been identified for these patients. At the time of lung transplantation, we found the lungs of silica-exposed subjects to contain multiple foci of inflammatory cells and silicotic nodules with proximal TNFalpha expressing macrophage and NF-kappaB activation in epithelial cells. Patients with silicosis had poor survival (median survival 2.4 yr; confidence interval (CI): 0.16-7.88 yr) compared to IPF patients (5.3 yr; CI: 2.8-15 yr; p = 0.07), and experienced early rejection of their lung grafts (0.9 yr; CI: 0.22-0.9 yr) following lung transplantation (2.4 yr; CI:1.5-3.6 yr; p<0.05). Using a mouse experimental model in which the endotracheal instillation of silica reproduces the silica-induced lung injury observed in humans we found that systemic inhibition of NF-kappaB activation with a pharmacologic inhibitor (BAY 11-7085) of IkappaB alpha phosphorylation decreased silica-induced inflammation and collagen deposition. In contrast, transgenic mice expressing a dominant negative IkappaB alpha mutant protein under the control of epithelial cell specific promoters demonstrate enhanced apoptosis and collagen deposition in their lungs in response to silica.ConclusionsAlthough limited by its size, our data support that patients with silicosis appear to have poor outcome following lung transplantation. Experimental data indicate that while the systemic inhibition of NF-kappaB protects from silica-induced lung injury, epithelial cell specific NF-kappaB inhibition appears to aggravate the outcome of experimental silicosis.

Project description:One mechanism leading to neurodegeneration during Alzheimer's disease (AD) is amyloid beta peptide (Abeta) neurotoxicity. Abeta elicits in cultured central nervous system neurons a biphasic response: a low-dose neurotrophic response and a high-dose neurotoxic response. Previously we reported that NF-kappaB is activated by low doses of Abeta only. Here we show that NF-kappaB activation leads to neuroprotection. In primary neurons we found that a pretreatment with 0.1 microM Abeta-(1-40) protects against neuronal death induced with 10 microM Abeta-(1-40). As a known neuroprotective agent we next analyzed the effect of tumor necrosis factor alpha (TNF-alpha). Maximal activation of NF-kappaB was found with 2 ng/ml TNF-alpha. Pretreatment with TNF-alpha protected cerebellar granule cells from cell death induced by 10 microM Abeta-(1-40). This protection is described by an inverted U-shaped dose response and is maximal with a NF-kappaB-activating dose. The molecular specificity of this protective effect was analyzed by specific blockade of NF-kappaB activation. Overexpression of a transdominant negative IkappaB-alpha blocks NF-kappaB activation and potentiates Abeta-mediated neuronal apoptosis. Our findings show that activation of NF-kappaB is the underlying mechanism of the neuroprotective effect of low-dose Abeta and TNF-alpha. In accordance with these in vitro data we find that nuclear NF-kappaB immunoreactivity around various plaque stages of AD patients is reduced in comparison to age-matched controls. Taken together these data suggest that pharmacological NF-kappaB activation may be a useful approach in the treatment of AD and related neurodegenerative disorders.

Project description:BACKGROUND:Chronic inflammation is a well-known corollary of the aging process and is believed to significantly contribute to morbidity and mortality of many age-associated chronic diseases. However, the mechanisms that cause age-associated inflammatory changes are not well understood. Particularly, the contribution of cell stress responses to age-associated inflammation in 'non-inflammatory' cells remains poorly defined. The present cross-sectional study focused on differences in molecular signatures indicative of inflammatory states associated with biological aging of human fibroblasts from donors aged 22 to 92 years. RESULTS:Gene expression profiling revealed elevated steady-state transcript levels consistent with a chronic inflammatory state in fibroblast cell-strains obtained from older donors. We also observed enhanced NF-kappaB DNA binding activity in a subset of strains, and the NF-kappaB profile correlated with mRNA expression levels characteristic of inflammatory processes, which include transcripts coding for cytokines, chemokines, components of the complement cascade and MHC molecules. This intrinsic low-grade inflammatory state, as it relates to aging, occurs in cultured cells irrespective of the presence of other cell types or the in vivo context. CONCLUSION:Our results are consistent with the view that constitutive activation of inflammatory pathways is a phenomenon prevalent in aged fibroblasts. It is possibly part of a cellular survival process in response to compromised mitochondrial function. Importantly, the inflammatory gene expression signature described here is cell autonomous, i.e. occurs in the absence of prototypical immune or pro-inflammatory cells, growth factors, or other inflammatory mediators.

Project description:In the central nervous system (CNS) the transcription factor NF-kappaB is a key regulator of inflammation and secondary injury processes. Following trauma or disease, the expression of NF-kappaB-dependent genes is activated, leading to both protective and detrimental effects on CNS recovery. Here we show that transgenic inactivation of astroglial NF-kappaB in mice (GFAP-IkappaBalpha-dn mice) resulted in dramatic reduction of disease severity and improvement in functional recovery following EAE. This coincided with a higher presence of leukocytes in the cord and brain of transgenic mice at the chronic phase of the disease, when the functional recovery over WT mice was the most significant. We observed that expression of proinflammatory genes in both spinal cord and cerebellum was delayed and reduced, while the loss of neuronal-specific molecules essential for synaptic transmission was limited compared to WT mice. Furthermore, death of retinal ganglion cells in affected retinas was almost abolished, suggesting the activation of neuroprotective mechanisms. Our data indicate that inhibiting NF-kappaB in astrocytes results in neuroprotective effects following EAE, directly implicating astrocytes in the pathophysiology of this disease. Keywords: time course, EAE, transgenic mice, astrocytes, inflammation, cytokines, chemokines

Project description:The transcription factor NF-kappaB (p50/p65) binds either a kappaB DNA element or its inhibitor protein, IkappaBalpha, but these two binding events are mutually exclusive. The reason for this exclusivity is not obvious from the available crystal structure data. The C-terminal PEST-like sequence of IkappaBalpha appears to be involved in the process, but it is located in both of the published X-ray structures of the IkappaBalpha/NF-kappaB complex at a significant distance away from the DNA contact loop in the NF-kappaB DNA-binding domain. We have used nuclear magnetic resonance spectroscopy and differential isotopic labeling to probe the interactions between the p50/p65 NF-kappaB heterodimer and IkappaBalpha in solution. Our measurements are able to resolve a local structural discrepancy between the two crystal structures, and we confirm that the primary interaction of the IkappaBalpha PEST domain is with the DNA-binding domain of the p65 subunit. Mutagenesis of key arginine residues in the DNA contact sequence results in the loss of specific interaction of the PEST sequence with the p65 subdomain. We conclude that the local structure of the IkappaBalpha/NF-kappaB complex in the region of the PEST sequence is consistent with a direct interaction of this acidic sequence with the basic DNA contact sequence in p65, thus reducing the affinity of NF-kappaB for DNA by a competitive mechanism that is still to be elucidated fully.

Project description:The complex host-pathogen interplay involves the recognition of the pathogen by the host's innate immune system and countermeasures taken by the pathogen. Detection of invading bacteria by the host leads to rapid activation of the transcription factor NF-kappaB, followed by inflammation and eradication of the intruders. In response, some pathogens, including enteropathogenic Escherichia coli (EPEC), acquired means of blocking NF-kappaB activation. We show that inhibition of NF-kappaB activation by EPEC involves the injection of NleE into the host cell. Importantly, we show that NleE inhibits NF-kappaB activation by preventing activation of IKKbeta and consequently the degradation of the NF-kappaB inhibitor, IkappaB. This NleE activity is enhanced by, but is not dependent on, a second injected effector, NleB. In conclusion, this study describes two effectors, NleB and NleE, with no similarity to other known proteins, used by pathogens to manipulate NF-kappaB signaling pathways.