The ubiquitin‐editing enzyme A20 requires RNF11 to downregulate NF‐κB signalling

The RING domain protein RNF11 is overexpressed in breast cancers and promotes tumour growth factor‐beta (TGF‐β) signalling. RNF11 has been proposed to regulate TGF‐β signalling by interacting with HECT‐ and SCF‐type E3 ligases; however, the role of RNF11 in other signalling pathways is poorly understood. Here, we demonstrate a novel function of RNF11 as a negative regulator of NF‐κB and jun N‐terminal kinase (JNK) signalling pathways. Knockdown of RNF11 with siRNA resulted in persistent tumour necrosis factor (TNF)‐ and lipopolysaccharide (LPS)‐mediated NF‐κB and JNK signalling. RNF11 interacted with the NF‐κB inhibitor A20 and its regulatory protein TAX1BP1 in a stimulus‐dependent manner. RNF11 negatively regulated RIP1 and TRAF6 ubiquitination upon stimulation with TNF and LPS, respectively. Furthermore, RNF11 was required for A20 to interact with and inactivate RIP1 to inhibit TNF‐mediated NF‐κB activation. Our studies reveal that RNF11, together with TAX1BP1 and Itch, is an essential component of an A20 ubiquitin‐editing protein complex that ensures transient activation of inflammatory signalling pathways.     

MALT1 is a potential therapeutic target in glioblastoma and plays a crucial role in EGFR‐induced NF‐κB activation

Glioblastoma multiforme (GBM) is the most common malignant tumour in the adult brain and hard to treat. Nuclear factor κB (NF‐κB) signalling has a crucial role in the tumorigenesis of GBM. EGFR signalling is an important driver of NF‐κB activation in GBM; however, the correlation between EGFR and the NF‐κB pathway remains unclear. In this study, we investigated the role of mucosa‐associated lymphoma antigen 1 (MALT1) in glioma progression and evaluated the anti‐tumour activity and effectiveness of MI‐2, a MALT1 inhibitor in a pre‐clinical GBM model. We identified a paracaspase MALT1 that is involved in EGFR‐induced NF‐kB activation in GBM. MALT1 deficiency or inhibition significantly affected the proliferation, survival, migration and invasion of GBM cells both in vitro and in vivo. Moreover, MALT1 inhibition caused G1 cell cycle arrest by regulating multiple cell cycle–associated proteins. Mechanistically, MALTI inhibition blocks the degradation of IκBα and prevents the nuclear accumulation of the NF‐κB p65 subunit in GBM cells. This study found that MALT1, a key signal transduction cascade, can mediate EGFR‐induced NF‐kB activation in GBM and may be potentially used as a novel therapeutic target for GBM.     

Cell entry of bovine ephemeral fever virus requires activation of Src‐JNK‐AP1 and PI3K‐Akt‐NF‐κB pathways as well as Cox‐2‐mediated PGE2/EP receptor signalling to enhance clathrin‐mediated virus endocytosis

Although we have previously demonstrated that cell entry of bovine ephemeral fever virus (BEFV) follows a clathrin‐mediated and dynamin 2‐dependent endocytosis pathway, the cellular mechanism mediating virus entry remains unknown. Here, we report that BEFV triggers simultaneously Src‐JNK‐AP1 and PI3K‐Akt‐NF‐κB signalling pathways in the stage of virus binding to induce clathrin and dynamin 2 expressions, while vesicular stomatitis virus only activates Src‐JNK signalling to enhance its entry. Activation of these pathways by ultraviolet‐inactivated BEFV suggests a role for virus binding but not viral internalization and gene expression. By blocking these signalling pathways with specific inhibitors, BEFV‐induced expressions of clathrin and dynamin 2 were significantly diminished. By labelling BEFV with 3,3′‐dilinoleyloxacarbocyanine perchlorate to track viral entry, we found that virus entry was hindered by both Src and Akt inhibitors, suggesting that these signalling pathways are crucial for efficient virus entry. In addition, BEFV also triggers Cox‐2‐catalysed prostaglandin E₂ (PGE₂) synthesis and induces expressions of G‐protein‐coupled E‐prostanoid (EP) receptors 2 and 4, leading to amplify signal cascades of Src‐JNK‐AP1 and PI3K‐Akt‐NF‐κB, which elevates both clathrin and dynamin 2 expressions. Furthermore, pretreatment of cells with adenylate cyclase (cAMP) inhibitor SQ22536 reduced BEFV‐induced Src phosphorylation as well as clathrin and dynamin 2 expressions. Our findings reveal for the first time that BEFV activates the Cox‐2‐mediated PGE₂/EP receptor signalling pathways, further enhancing Src‐JNK‐AP1 in a cAMP‐dependent manner and PI3K‐Akt‐NF‐κB in a cAMP‐independent manner. Accordingly, BEFV stimulates PGE₂/EP receptor signalling amplifying Src‐JNK‐AP1 and PI3K‐Akt‐NF‐κB pathways in an autocrine or paracrine fashion to enhance virus entry.     

Essential involvement of cross‐talk between IFN‐γ and TNF‐α in CXCL10 production in human THP‐1 monocytes

Interferon (IFN)‐γ‐induced protein 10 (IP‐10/CXCL10), a CXC chemokine, has been documented in several inflammatory and autoimmune disorders including atopic dermatitis and bronchial asthma. Although CXCL10 could be induced by IFN‐γ depending on cell type, the mechanisms regulating CXCL10 production following treatment with combination of IFN‐γ and TNF‐α have not been adequately elucidated in human monocytes. In this study, we showed that TNF‐α had more potential than IFN‐γ to induce CXCL10 production in THP‐1 monocytes. Furthermore, IFN‐γ synergistically enhanced the production of CXCL10 in parallel with the activation of NF‐κB in TNF‐α‐stimulated THP‐1 cells. Blockage of STAT1 or NF‐κB suppressed CXCL10 production. JAKs inhibitors suppressed IFN‐γ plus TNF‐α‐induced production of CXCL10 in parallel with activation of STAT1 and NF‐κB, while ERK inhibitor suppressed production of CXCL10 as well as activation of NF‐κB, but not that of STAT1. IFN‐γ‐induced phosphorylation of JAK1 and JAK2, whereas TNF‐α induced phosphorylation of ERK1/2. Interestingly, IFN‐γ alone had no effect on phosphorylation and degradation of IκB‐α, whereas it significantly promoted TNF‐α‐induced phosphorylation and degradation of IκB‐α. These results suggest that TNF‐α induces CXCL10 production by activating NF‐κB through ERK and that IFN‐γ induces CXCL10 production by increasing the activation of STAT1 through JAKs pathways. Of note, TNF‐α‐induced NF‐κB may be the primary pathway contributing to CXCL10 production in THP‐1 cells. IFN‐γ potentiates TNF‐α‐induced CXCL10 production in THP‐1 cells by increasing the activation of STAT1 and NF‐κB through JAK1 and JAK2. J. Cell. Physiol. 220: 690–697, 2009. © 2009 Wiley‐Liss, Inc.     

OTUB1 modulates c‐IAP1 stability to regulate signalling pathways

The cellular inhibitor of apoptosis (c‐IAP) proteins are E3 ubiquitin ligases that are critical regulators of tumour necrosis factor (TNF) receptor (TNFR)‐mediated signalling. Through their E3 ligase activity c‐IAP proteins promote ubiquitination of receptor‐interaction protein 1 (RIP1), NF‐κB‐inducing kinase (NIK) and themselves, and regulate the assembly of TNFR signalling complexes. Consequently, in the absence of c‐IAP proteins, TNFR‐mediated activation of NF‐κB and MAPK pathways and the induction of gene expression are severely reduced. Here, we describe the identification of OTUB1 as a c‐IAP‐associated deubiquitinating enzyme that regulates c‐IAP1 stability. OTUB1 disassembles K48‐linked polyubiquitin chains from c‐IAP1 in vitro and in vivo within the TWEAK receptor‐signalling complex. Downregulation of OTUB1 promotes TWEAK‐ and IAP antagonist‐stimulated caspase activation and cell death, and enhances c‐IAP1 degradation. Furthermore, knockdown of OTUB1 reduces TWEAK‐induced activation of canonical NF‐κB and MAPK signalling pathways and modulates TWEAK‐induced gene expression. Finally, suppression of OTUB1 expression in zebrafish destabilizes c‐IAP (Birc2) protein levels and disrupts fish vasculature. These results suggest that OTUB1 regulates NF‐κB and MAPK signalling pathways and TNF‐dependent cell death by modulating c‐IAP1 stability.     

Advanced glycation end products‐related modulation of cathepsin L and NF‐κB signalling effectors in retinal pigment epithelium lead to augmented response to TNFα

The retinal pigment epithelium (RPE) plays a central role in neuroretinal homoeostasis throughout life. Altered proteolysis and inflammatory processes involving RPE contribute to the pathophysiology of age‐related macular degeneration (AMD), but the link between these remains elusive. We report for the first time the effect of advanced glycation end products (AGE)—known to accumulate on the ageing RPE's underlying Bruch's membrane in situ—on both key lysosomal cathepsins and NF‐κB signalling in RPE. Cathepsin L activity and NF‐κB effector levels decreased significantly following 2‐week AGE exposure. Chemical cathepsin L inhibition also decreased total p65 protein levels, indicating that AGE‐related change of NF‐κB effectors in RPE cells may be modulated by cathepsin L. However, upon TNFα stimulation, AGE‐exposed cells had significantly higher ratio of phospho‐p65(Ser536)/total p65 compared to non‐AGEd controls, with an even higher fold increase than in the presence of cathepsin L inhibition alone. Increased proportion of active p65 indicates an AGE‐related activation of NF‐κB signalling in a higher proportion of cells and/or an enhanced response to TNFα. Thus, NF‐κB signalling modulation in the AGEd environment, partially regulated via cathepsin L, is employed by RPE cells as a protective (para‐inflammatory) mechanism but renders them more responsive to pro‐inflammatory stimuli.     

TRAF Family Member-associated NF-κB Activator (TANK) Inhibits Genotoxic Nuclear Factor κB Activation by Facilitating Deubiquitinase USP10-dependent Deubiquitination of TRAF6 Ligase

DNA damage-induced NF-κB activation plays a critical role in regulating cellular response to genotoxic stress. However, the molecular mechanisms controlling the magnitude and duration of this genotoxic NF-κB signaling cascade are poorly understood. We recently demonstrated that genotoxic NF-κB activation is regulated by reversible ubiquitination of several essential mediators involved in this signaling pathway. Here we show that TRAF family member-associated NF-κB activator (TANK) negatively regulates NF-κB activation by DNA damage via inhibiting ubiquitination of TRAF6. Despite the lack of a deubiquitination enzyme domain, TANK has been shown to negatively regulate the ubiquitination of TRAF proteins. We found TANK formed a complex with MCPIP1 (also known as ZC3H12A) and a deubiquitinase, USP10, which was essential for the USP10-dependent deubiquitination of TRAF6 and the resolution of genotoxic NF-κB activation upon DNA damage. Clustered regularly interspaced short palindromic repeats (CRISPR)/Cas9-mediated deletion of TANK in human cells significantly enhanced NF-κB activation by genotoxic treatment, resulting in enhanced cell survival and increased inflammatory cytokine production. Furthermore, we found that the TANK-MCPIP1-USP10 complex also decreased TRAF6 ubiquitination in cells treated with IL-1β or LPS. In accordance, depletion of USP10 enhanced NF-κB activation induced by IL-1β or LPS. Collectively, our data demonstrate that TANK serves as an important negative regulator of NF-κB signaling cascades induced by genotoxic stress and IL-1R/Toll-like receptor stimulation in a manner dependent on MCPIP1/USP10-mediated TRAF6 deubiquitination.     

RTP801 Regulates Maneb‐ and Mancozeb‐Induced Cytotoxicity via NF‐κB

Environmental factors have been implicated in the pathogenesis of neurodegenerative diseases. Maneb (MB) and mancozeb (MZ) have been extensively used as pesticides. Exposure to MB lowers the threshold for dopaminergic damage triggered by 1‐methyl‐4‐phenyl‐1,2,3,6‐tetrahydropyridine. MB and MZ potentiate 1‐methyl‐4‐phenylpyridium (MPP⁺)‐induced cytotoxicity in rat pheochromocytoma (PC12) cells partially via nuclear factor kappa B (NF‐κB) activation. RTP801 dramatically increased by oxidative stresses and DNA damage is the possible mechanism of neurotoxins‐induced cell death in many studies. This study demonstrated that MB and MZ induced DNA damage as seen in comet assay. The expressions of RTP801 protein and mRNA were elevated after MB and MZ exposures. By knocking down RTP801 using shRNA, we demonstrated that NF‐κB activation by MB and MZ was regulated by RTP801 and cell death triggered by MB and MZ was associated with RTP801 elevation. This revealed that the toxic mechanisms of dithiocarbamates are via the cross talk between RTP801 and NF‐κB.     

KiSS1 suppresses TNFα‐induced breast cancer cell invasion via an inhibition of RhoA‐Mediated NF‐κB activation

Tumor necrosis factor‐alpha (TNFα) induces cancer development and metastasis, which is prominently achieved by nuclear factor‐kappa B (NF‐κB) activation. TNFα‐induced NF‐κB activation enhances cellular mechanisms including proliferation, migration, and invasion. KiSS1, a key regulator of puberty, was initially discovered as a tumor metastasis suppressor. The expression of KiSS1 was lost or down‐regulated in different metastatic tumors. However, it is unclear whether KiSS1 regulates TNFα‐induced NF‐κB activation and further tumor cell migration. In this study, we demonstrate that KiSS1 suppresses the migration of breast cancer cells by inhibiting TNFα‐induced NF‐κB pathway and RhoA activation. Both KiSS1 overexpression and KP10 (kisspeptin‐10) stimulation inhibited TNFα‐induced NF‐κB activity, suppressed TNFα‐induced cell migration and cell attachment to fibronectin in breast cancer cells while KP10 has little effect on cancer cell proliferation. Furthermore, KP10 inhibited TNFα‐induced cell migration and RhoA GTPase activation. Therefore, our data demonstrate that KiSS1 inhibits TNFα‐induced NF‐κB activation via downregulation of RhoA activation and suppression of breast cancer cell migration and invasion. J. Cell. Biochem. 107: 1139–1149, 2009. © 2009 Wiley‐Liss, Inc.     

Silencing of ATP2B1‐AS1 contributes to protection against myocardial infarction in mouse via blocking NFKBIA‐mediated NF‐κB signalling pathway

Myocardial infarction (MI) is an acute coronary syndrome that refers to tissue infarction of the myocardium. This study aimed to investigate the effect of long intergenic non‐protein‐coding RNA (lincRNA) ATPase plasma membrane Ca²⁺ transporting 1 antisense RNA 1 (ATP2B1‐AS1) against MI by targeting nuclear factor‐kappa‐B inhibitor alpha (NFKBIA) and mediating the nuclear factor‐kappa‐B (NF‐κB) signalling pathway. An MI mouse model was established and idenepsied by cardiac function evaluation. It was determined that ATP2B1‐AS1 was highly expressed, while NFKBIA was poorly expressed and NF‐κB signalling pathway was activated in MI mice. Cardiomyocytes were extracted from mice and introduced with a series of mouse ATP2B1‐AS1 vector, NFKBIA vector, siRNA‐mouse ATP2B1‐AS1 and siRNA‐NFKBIA. The expression of NF‐κBp50, NF‐κBp65 and IKKβ was determined to idenepsy whether ATP2B1‐AS1 and NFKBIA affect the NF‐κB signalling pathway, the results of which suggested that ATP2B1‐AS1 down‐regulated the expression of NFKBIA and activated the NF‐κB signalling pathway in MI mice. Based on the data from assessment of cell viability, cell cycle, apoptosis and levels of inflammatory cytokines, either silencing of mouse ATP2B1‐AS1 or overexpression of NFKBIA was suggested to result in reduced cardiomyocyte apoptosis and expression of inflammatory cytokines, as well as enhanced cardiomyocyte viability. Our study provided evidence that mouse ATP2B1‐AS1 silencing may have the potency to protect against MI in mice through inhibiting cardiomyocyte apoptosis and inflammation, highlighting a great promise as a novel therapeutic target for MI.     

LIGHT/IFN‐γ triggers β cells apoptosis via NF‐κB/Bcl2‐dependent mitochondrial pathway

LIGHT recruits and activates naive T cells in the islets at the onset of diabetes. IFN‐γ secreted by activated T lymphocytes is involved in beta cell apoptosis. However, whether LIGHT sensitizes IFNγ‐induced beta cells destruction remains unclear. In this study, we used the murine beta cell line MIN6 and primary islet cells as models for investigating the underlying cellular mechanisms involved in LIGHT/IFNγ – induced pancreatic beta cell destruction. LIGHT and IFN‐γ synergistically reduced MIN6 and primary islet cells viability; decreased cell viability was due to apoptosis, as demonstrated by a significant increase in Annexin V⁺ cell percentage, detected by flow cytometry. In addition to marked increases in cytochrome c release and NF‐κB activation, the combination of LIGHT and IFN‐γ caused an obvious decrease in expression of the anti‐apoptotic proteins Bcl‐2 and Bcl‐xL, but an increase in expression of the pro‐apoptotic proteins Bak and Bax in MIN6 cells. Accordingly, LIGHT deficiency led to a decrease in NF‐κB activation and Bak expression, and peri‐insulitis in non‐obese diabetes mice. Inhibition of NF‐κB activation with the specific NF‐κB inhibitor, PDTC (pyrrolidine dithiocarbamate), reversed Bcl‐xL down‐regulation and Bax up‐regulation, and led to a significant increase in LIGHT‐ and IFN‐γ‐treated cell viability. Moreover, cleaved caspase‐9, ‐3, and PARP (poly (ADP‐ribose) polymerase) were observed after LIGHT and IFN‐γ treatment. Pretreatment with caspase inhibitors remarkably attenuated LIGHT‐ and IFNγ‐induced cell apoptosis. Taken together, our results indicate that LIGHT signalling pathway combined with IFN‐γ induces beta cells apoptosis via an NF‐κB/Bcl2‐dependent mitochondrial pathway.     

Central role of PAFR signalling in ExoU‐induced NF‐κB activation

ExoU is an important virulence factor in acute Pseudomonas aeruginosa infections. Here, we unveiled the mechanisms of ExoU‐driven NF‐κB activation by using human airway cells and mice infected with P. aeruginosa strains. Several approaches showed that PAFR was crucially implicated in the activation of the canonical NF‐κB pathway. Confocal microscopy of lungs from infected mice revealed that PAFR‐dependent NF‐κB activation occurred mainly in respiratory epithelial cells, and reduced p65 nuclear translocation was detected in mice PAFR?/? or treated with the PAFR antagonist WEB 2086. Several evidences showed that ExoU‐induced NF‐κB activation regulated PAFR expression. First, ExoU increased p65 occupation of PAFR promoter, as assessed by ChIP. Second, luciferase assays in cultures transfected with different plasmid constructs revealed that ExoU promoted p65 binding to the three κB sites in PAFR promoter. Third, treatment of cell cultures with the NF‐κB inhibitor Bay 11–7082, or transfection with IκBα negative‐dominant, significantly decreased PAFR mRNA. Finally, reduction in PAFR expression was observed in mice treated with Bay 11–7082 or WEB 2086 prior to infection. Together, our data demonstrate that ExoU activates NF‐κB by PAFR signalling, which in turns enhances PAFR expression, highlighting an important mechanism of amplification of response to this P. aeruginosa toxin.