PI3K/Akt promotes feedforward mTORC2 activation through IKKα

The ser-thr Akt plays a critical role in the regulation of cell survival, cell growth and proliferation, as well as energy metabolism and is dysregulated in many cancers. The regulation of Akt activity depends on the phosphorylation at two sites: (i) Thr308 in the activation loop by phosphoinositide-dependent kinase-1 (PDK1) and (ii) Ser473 hydrophobic motif at the carboxyl terminus by a second activity termed PDK2, which is the mTORC2 complex composed of mTOR, rictor, and Sin1. Previously we demonstrated that IKKα, a component of the IKK complex that controls NF-κB activation, participates in the Akt-dependent regulation of mTORC1. Here we have explored a potential involvement of IKKα in controlling Akt activity and whether this may involve mTORC2. The experiments show that IKKα associates with mTORC2 in several cancer cells in a manner dependent on PI3K/Akt activity and that IKKα positively promotes Akt phosphorylation at Ser473 and at Thr308. Moreover, IKKα enhances mTORC2 kinase activity directed to Akt on Ser473 and Akt-mediated phosphorylation of FOXO3a and GSK3β, but not other Akt-associated targets such as TSC2 and PRAS40, indicating the existence of multiple mechanisms of Akt activation in cells. In addition, loss of IKKα suppresses growth factor-induced Akt activation associated with mTORC1 inhibition. These results indicate that IKKα serves as a feedforward regulator of mTORC2 and that IKKα could serve as a key therapeutic target to block mTORC2 and Akt activation in some cancers

IKKα and IKKβ Each Function to Regulate NF-κB Activation in the TNF-Induced/Canonical Pathway

Activation of the transcription factor NF-kappaB by cytokines is rapid, mediated through the activation of the IKK complex with subsequent phosphorylation and degradation of the inhibitory IkappaB proteins. The IKK complex is comprised of two catalytic subunits, IKKalpha and IKKbeta, and a regulatory protein known as NEMO. Using cells from mice that are genetically deficient in IKKbeta or IKKalpha, or using a kinase inactive mutant of IKKbeta, it has been proposed that IKKbeta is critical for TNF-induced IkappaB phosphorylation/degradation through the canonical pathway while IKKalpha has been shown to be involved in the non-canonical pathway for NF-kappaB activation. These conclusions have led to a focus on development of IKKbeta inhibitors for potential use in inflammatory disorders and cancer.Analysis of NF-kappaB activation in response to TNF in MEFs reveals that IKKbeta is essential for efficient phosphorylation and subsequent degradation of IkappaB alpha, yet IKKalpha contributes to the NF-kappaB activation response in these cells as measured via DNA binding assays. In HeLa cells, both IKKalpha and IKKbeta contribute to IkappaB alpha phosphorylation and NF-kappaB activation. A kinase inactive mutant of IKKbeta, which has been used as evidence for the critical importance of IKKbeta in TNF-induced signaling, blocks activation of NF-kappaB induced by IKKalpha, even in cells that are deficient in IKKbeta.These results demonstrate the importance of IKKalpha in canonical NF-kappaB activation, downstream of cytokine treatment of cells. The experiments suggest that IKKalpha will be a therapeutic target in inflammatory disorders

Cytosolic DNA Promotes Signal Transducer and Activator of Transcription 3 (STAT3) Phosphorylation by TANK-binding Kinase 1 (TBK1) to Restrain STAT3 Activity

Cytosolic DNA can elicit beneficial as well as undesirable immune responses. For example, viral or microbial DNA triggers cell-intrinsic immune responses to defend against infections, whereas aberrant cytosolic accumulation of self-DNA results in pathological conditions, such as autoimmunity. Given the importance of these DNA-provoked responses, a better understanding of their molecular mechanisms is needed. Cytosolic DNA engages stimulator of interferon genes (STING) to activate TANK-binding kinase 1 (TBK1), which subsequently phosphorylates the transcription factor interferon regulatory factor 3 (IRF3) to promote interferon expression. Recent studies have reported that additional transcription factors, including nuclear factor κB (NF-κB) and signal transducer and activator of transcription 6 (STAT6), are also activated by cytosolic DNA, suggesting that cytosolic DNA-induced gene expression is orchestrated by multiple factors. Here we show that cytosolic DNA activates STAT3, another member of the STAT family, via an autocrine mechanism involving interferon β (IFNβ) and IL-6. Additionally, we observed a novel cytosolic DNA-induced phosphorylation at serine 754 in the transactivation domain of STAT3. Upon cytosolic DNA stimulation, Ser 754 is directly phosphorylated by TBK1 in a STING-dependent manner. Moreover, Ser 754 phosphorylation inhibits cytosolic DNA-induced STAT3 transcriptional activity and selectively reduces STAT3 target genes that are up-regulated in response to cytosolic DNA. Taken together, our results suggest that cytosolic DNA-induced STAT3 activation via IFNβ and IL-6 is restrained by Ser 754 phosphorylation of STAT3. Our findings reveal a new signaling axis downstream of the cytosolic DNA pathway and suggest potential interactions between innate immune responses and STAT3-driven oncogenic pathways

IKK-i/IKKϵ Controls Constitutive, Cancer Cell-associated NF-κB Activity via Regulation of Ser-536 p65/RelA Phosphorylation

Nuclear factor kappaB (NF-kappaB) has been studied extensively as an inducible transcriptional regulator of the immune and inflammatory response. NF-kappaB activation downstream of lipopolysaccharide or cytokine stimulation is controlled by the IkappaB kinase complex, which contains IKKalpha and IKKbeta. Significantly, the constitutive activity of NF-kappaB has been implicated as an important aspect of many cancer cells, but mechanisms associated with this activity are poorly understood. An inducible kinase, IKK-i/IKKepsilon, related to the catalytic forms of the IkappaB kinase, has been studied as an anti-viral, innate immune regulator through its ability to control the activity of the transcription factors IRF-3 and IRF-7. Here, we demonstrate that IKK-i/IKKepsilon is expressed in a number of cancer cells and is involved in regulating NF-kappaB activity through its ability to control basal/constitutive, but not cytokine-induced, p65/RelA phosphorylation at Ser-536, a modification proposed to contribute to the transactivation function of NF-kappaB. Knockdown of IKK-i/IKKepsilon or expression of a S536A mutant form of p65 suppresses HeLa cell proliferation. The data indicate a role for IKK-i/IKKepsilon in controlling proliferation of certain cancer cells through regulation of constitutive NF-kappaB activity

Maintenance of Constitutive I B Kinase Activity by Glycogen Synthase Kinase-3 / in Pancreatic Cancer

Constitutive NF-κB activation is among the many deregulated signaling pathways that are proposed to drive pancreatic cancer cell growth and survival. Recent reports suggest that glycogen synthase kinase-3β (GSK-3β) plays a key role in maintaining basal NF-κB target gene expression and cell survival in pancreatic cancer cell lines. However, the mechanism by which GSK-3β facilitates constitutive NF-κB signaling in pancreatic cancer remains unclear. In this report, we analyze the contributions of both GSK-3 isoforms (GSK-3α, GSK-3β) in regulating NF-κB activation and cell proliferation in pancreatic cancer cell lines (Panc-1 and MiaPaCa-2). We demonstrate that GSK-3 isoforms are differentially required to maintain basal NF-κB DNA binding activity, transcriptional activity, and cell proliferation in Panc-1 and MiaPaCa-2 cells. Our data also indicate that IKK subunits are not equally required to regulate pancreatic cancer-associated NF-κB activity and cell growth. Importantly, we provide the first evidence that GSK-3 maintains constitutive NF-κB signaling in pancreatic cancer by regulating IKK activity. These data provide new insight into GSK-3-dependent NF-κB regulation, and further establishes GSK-3 and IKK as potential therapeutic targets for pancreatic cancer

Requirement of the NF- B Subunit p65/RelA for K-Ras-Induced Lung Tumorigenesis

K-Ras-induced lung cancer is a very common disease, for which there are currently no effective therapies. Because therapy directly targeting the activity of oncogenic Ras has been unsuccessful, a different approach for novel therapy design is to identify critical Ras downstream oncogenic targets. Given that oncogenic Ras proteins activate the transcription factor NF-κB, and the importance of NF-κB in oncogenesis, we hypothesized that NF-κB would be an important K-Ras target in lung cancer. To address this hypothesis, we generated an NF-κB-EGFP reporter mouse model of K-Ras-induced lung cancer and determined that K-Ras activates NF-κB in lung tumors in situ. Furthermore, a mouse model was generated where activation of oncogenic K-Ras in lung cells was coupled with inactivation of the NF-κB subunit p65/RelA. In this model, deletion of p65/RelA reduces the number of K-Ras-induced lung tumors both in the presence and absence of the tumor suppressor p53. Lung tumors with loss of p65/RelA have higher numbers of apoptotic cells, reduced spread and lower grade. Using lung cell lines expressing oncogenic K-Ras, we show that NF-κB is activated in these cells in a K-Ras-dependent manner and that NF-κB activation by K-Ras requires IKKβ kinase activity. Taken together, these results demonstrate the importance of the NF-κB subunit p65/RelA in K-Ras induced lung transformation and identify IKKβ as a potential therapeutic target for K-Ras-induced lung cancer

IκB Kinase α and p65/RelA Contribute to Optimal Epidermal Growth Factor-induced c- fos Gene Expression Independent of IκBα Degradation

Mitogenic activation of expression of immediate-early genes, such as c-fos, is controlled through signal-induced phosphorylation of constitutively bound transcription factors that is correlated with a nucleosomal response that involves inducible chromatin modifications, such as histone phosphorylation and acetylation. Here we have explored a potential role for the transcription factor NF-kappaB and its associated signaling components in mediating induction of c-fos gene expression downstream of epidermal growth factor (EGF)-dependent signaling. Here we show that EGF treatment of quiescent fibroblast does not induce the classical pathway of NF-kappaB activation through IkappaB kinase (IKK)-directed IkappaBalpha phosphorylation. Interestingly, efficient induction of c-fos transcription requires IKKalpha, one of the subunits of the IkappaB kinase complex. The NF-kappaB subunit, p65/RelA, is found constitutively associated with the c-fos promoter, and knock-out of this transcription factor significantly reduces c-fos gene expression. Importantly, EGF induces the recruitment of IKKalpha to the c-fos promoter to regulate promoter-specific histone H3 Ser(10) phosphorylation in a manner that is independent of p65/RelA. Collectively, our data demonstrate that IKKalpha and p65/RelA contribute significantly to EGF-induced c-fos gene expression in a manner independent of the classical, IkappaBalpha degradation, p65/RelA nuclear accumulation response pathway

Addressing Reported Pro-Apoptotic Functions of NF-κB: Targeted Inhibition of Canonical NF-κB Enhances the Apoptotic Effects of Doxorubicin

The ability of the transcription factor NF-κB 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-κB can be pro-apoptotic through repression of anti-apoptotic target genes. However, there is little evidence analyzing the outcome of NF-κB inhibition on the cytotoxicity of doxorubicin in studies describing pro-apoptotic NF-κB activity. In this study, we further characterize the activation of NF-κB in response to doxorubicin and evaluate its role in chemotherapy-induced cell death in sarcoma cells where NF-κB is reported to be pro-apoptotic. Doxorubicin treatment in U2OS cells induced canonical NF-κB activity as evidenced by increased nuclear accumulation of phosphorylated p65 at serine 536 and increased DNA–binding activity. Co-treatment with a small molecule IKKβ 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-κB 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-κB 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-κB inhibitors together with standard chemotherapies remains a viable method to improve the clinical outcomes in patients with advanced stage malignancies

Observing Single Cell NF-κB Dynamics under Stimulant Concentration Gradient

Study of cell signaling often requires examination of the cellular dynamics under variation in the stimulant concentration. Such variation has typically been conducted by dispensing cell populations in a number of chambers or wells containing discrete concentrations. Such practice adds to the complexity associated with experimental or device design and requires substantial labor for implementation. Furthermore, there is also potential risk of missing important results due to the often arbitrary selection of discrete concentration values for testing. In this letter, we study NF-κB activation and translocation at the single cell level using a microfluidic device that generates continuously varying concentration gradient. We use only three device settings to cover stimulant (interleukin-1β) concentrations of four orders of magnitude (0.001-10 ng/ml). Such device allows us to study temporal dynamics of NF-κB in single cells under different stimulant concentrations by real-time imaging. Interestingly, our results reveal that while the percent of cells with NF-κB translocation decreases with lower stimulant concentration in the range of 0.1-0.001 ng/ml, the response time of such translocation remains constant, reflected by the single cell data