Abstract
Over the past four years, the field of the innate immune response has been highly influenced by the discovery of the IκB kinase (IKK)-related kinases, TANK Binding Kinase 1 (TBK1) and IKKi, which regulate the activity of interferon regulatory factor (IRF)-3/IRF-7 and NF-κB transcription factors. More recently, additional essential components of the signaling pathways that activate these IKK homologues have been discovered. These include the RNA helicases RIGi and MDA5, and the downstream mitochondrial effector known as CARDIF/MAVS/VISA/IPS-1. In addition to their essential functions in controlling the innate immune response, recent studies have highlighted a role of these kinases in cell proliferation and oncogenesis. The canonical IKKs are well recognized to be a bridge linking chronic inflammation to cancer. New findings now suggest that the IKK-related kinases TBK1 and IKKi also participate in signaling pathways that impact on cell transformation and tumor progression. This review will therefore summarize and discuss the role of TBK1 and IKKi in cellular transformation and oncogenesis by focusing on their regulation and substrate specificity.
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Introduction
The molecular links between chronic inflammation and cancer have only recently begun to emerge, despite the fact that Rudolf Virchow proposed such an association more than 100 years ago 1, 2. Following exposure to pathogen-associated molecular patterns (PAMPs), the innate immune response and the inflammation reaction that follows rely on evolutionarily conserved receptors termed pattern-recognition receptors (PRRs). Some of these receptors are located at the plasma membrane and include molecules such as the Toll-like receptors (TLR 1, 2, 4, 5, and 6) and scavenger receptors (CD36 and SR-A). Others occur in acidic endosomes (TLR 3, 7, 8, and 9), and still others can be found in the cytoplasm [PKR, the RIG-I-like helicases (RLHs) (RIGi and MDA5), the DNA-dependent activator of interferon (IFN) regulatory factors (IRFs) (DAI), and the nucleotide-binding oligomerization domain (NOD) receptors] 3, 4. Engagement of these receptors signals the activation of several transcription factors that are inactive in resting cells. One of the most important signaling cascades triggered by these receptors is the IκB kinase (IKK)α/β-NF-κB pathway leading to the induction of several key molecules involved in the clearance of incoming pathogens. Notably, several of these key molecules, such as TNF-α, IL-6, or vascular endothelial growth factor (VEGF), are implicated in cell survival, cell proliferation and angiogenesis signaling pathways and, therefore, can influence cancer development 5, 6, 7. Elegant gene targeting studies using mice with tissue-specific ablation of the IKKβ gene in epithelial cells, bone-marrow-derived macrophages, and hepatocytes demonstrated a complex role of the IKKβ-NF-κB pathway in a variety of cancer models that are dependent on or independent of chronic inflammation 8, 9. Moreover, study of IKKαAA knock-in mice, which express a catalytically inactive kinase mutant, revealed an important role for IKKα in metastatogenesis 10. These important findings have recently been extensively reviewed 2, 5, 11, 12 and will not be discussed further here. This review focuses on recent data suggesting that additional players that control the innate immune system may be involved in cancer development.
The IKK-related kinases, partners in NF-κB signaling
The importance of the IKK complex in the regulation of NF-κB has fueled intensive research efforts by several groups leading to the discovery of the IKK-related kinases (for good reviews, see 13, 14). Using degenerate primers containing sequences common to IKKα and IKKβ, a portion of NF-κB-activating kinase (NAK) was amplified by PCR 15. This NAK, also called TANK Binding Kinase 1 (TBK1), was shown to act as an IKK-activating kinase responsible for NF-κB activation in response to growth factors that stimulate PKCɛ. TBK1 was originally identified in a yeast two-hybrid screening using TANK as the bait 16. At almost exactly the same time, another IKK-related kinase was also characterized and named IKKɛ/IKKi. Peters and colleagues 17 found IKKɛ in a database search for proteins similar to IKKα and IKKβ, whereas Akira's group 18 isolated IKKi in a subtractive hybridization screen of a cDNA library from lipopolysaccharide (LPS)-stimulated mouse macrophages. In contrast to IKKα, IKKβ, and TBK1, which are constitutively expressed in virtually all cell types, IKKi is predominantly expressed in specific tissues such as the pancreas, thymus, spleen, and peripheral blood leukocytes 18. It is also expressed at very low level in specific cell lines 19, 20, 21. Importantly, IKKi mRNA can be induced in response to exposure to LPS, viral infection, or a number of NF-κB-inducing cytokines 18, 20, 22, 23. TBK1 and IKKi display 61% sequence identity, and overexpression of both kinases induces NF-κB activation 16, 17, 18. However, in contrast to IKKβ, the enzymes TBK1 and IKKi phosphorylate only one (Serine 36) of the two phosphoacceptor sites present in IκBα 15, 17, 18. Why only one phosphorylation event occurs in the IκBα phosphodegron motif -DSGXXS- is unclear. Overexpression of IKKi is known to effectively drive IκBα degradation 24, 25, indicating that phosphorylation of Serine 36 may facilitate the phosphorylation of the protein on Serine 32, leading to its degradation. TANK phosphorylation by IKKi could also induce the release of TRAF2 followed by the subsequent activation of the IKK complex 26 (see Table 1).
Mouse embryonic fibroblasts (MEFs) deficient for IKKi or TBK1 show normal IκBα degradation and NF-κB DNA-binding activity in response to classical NF-κB inducers including TNFα, IL-1β and LPS 22, 27. However, the induction of well-characterized NF-κB target genes such as IL6, MCP1, COX2, and ICAM1 was abrogated in MEFs lacking either IKKi or TBK1. Phosphorylation of the p65/RelA subunit of NF-κB was proposed to explain the observed defects in the transactivation of specific NF-κB target genes 27. It is worth noting that phosphorylation of p65/RelA at Serine 536 by IKKβ and IKKα was shown to be an essential modification required in the second phase of NF-κB activation. This plays a key role in determining both the strength and duration of the NF-κB-mediated transcriptional response 28, 29. Interestingly, both IKKi and TBK1 also target p65/RelA at Serine 536, a process clearly involved in the induction of NF-κB-regulated genes 30, 31. In stimulated T cells, IKKi was shown to enhance the activity of p65 following its phosphorylation at Serine 468 32. Animal models also revealed functional similarities between IKKβ and the IKK-related kinases. Notably, TBK1-deficient mice were phenotypically similar to NEMO/IKKγ-, IKKβ-, and p65-deficient mice, where embryonic lethality was observed at E14.5 due to liver degeneration and apoptosis 27. Clearly, the IKK-related kinases are major molecular players in the modulation of inflammatory responses through their action on effectors of the NF-κB pathway.
The IKK-related kinases, key players in the induction of type I IFN
The field of the innate immune system was changed by the remarkable discovery that TBK1 and IKKi function as virus-activated kinases necessary for the establishment of an antiviral state 33, 34. Both kinases phosphorylate the transcription factors IRF-3 and IRF-7 at key C-terminal residues 35, 36, 37, 38, 39. IRF-3 and IRF-7 are important players in the induction of type I IFN following viral infection 3, 21, 40. Whereas IRF-7 can be induced at the transcriptional level, IRF-3 is found latent in the cytoplasm. Upon phosphorylation of the C-terminal region by TBK1 or IKKi, IRF-3 and IRF-7 heterodimerize and translocate into the nucleus, where they induce several proinflammatory and antiviral genes such as type I IFN (see 3 for a good review). Another IRF family member, IRF-5, is also involved in type I IFN induction 41 and can also be phosphorylated by TBK1 or IKKi 42, 43, 44. However, how IRF-5 participates in the transcriptional regulation of type I IFN genes is not yet completely understood.
Since the discovery of TBK1 and IKKi, detailed characterization of the signaling pathways involved in the activation of NF-κB and IRF-3 in response to pathogen infection has led to the identification of several positive scaffolding effectors regulating the phosphotransferase activities of TBK1 and IKKi. These effectors include FADD 45, TRADD 46, TRAF3 47, 48, TANK 26, 49, 50, 51, NAP1 30, 52, HSP90 53, and SINTBAD 54. In addition, intracellular RNA sensors such as RIG-I 55 and MDA-5 56, which signal through the mitochondrial antiviral signaling adaptor MAVS (also known as Cardif, VISA, and IPS-1) 57, 58, 59, 60, have been found to activate the IKK-related kinases in response to infection by RNA viruses. Cytosolic DNA sensors were also recently described. DAI, also known as DLM-1/ZBP1, is a DNA sensor that assembles with TBK1 and IRF-3 upon dsDNA treatment 61, whereas NALP3 and ASC recognize cytosolic microbial and host DNA to induce an innate immune response independent of IRFs 62. At the level of transcriptional regulation, GRIP1 was recently identified as a new cofactor of the IRF-3 dimers 63. Negative regulators including the SHP-2 phosphatase 64, SIKE 65, A20 66, LGP-2 67, NLXR1 68, and CYLD 69 were also added to the complex puzzle. Some of these important findings have been extensively reviewed elsewhere 3, 13, 70, 71, 72 and will not be discussed further here. More recently, the IKK-related kinases have been implicated in oncogenesis 24, 25, 73. The following discussion will describe the potential oncogenic roles of the IKK-related kinases and their different substrates (Table 1).
The IKK-related kinases in oncogenesis
In addition to the proposed roles of the IKK-related kinases in controlling NF-κB and the IRF transcription factors, recent findings point towards a role for TBK1 and IKKi in Ras-induced oncogenic transformation (Figure 1). TBK1 was identified as a RalB effector in the Ras-like (Ral)-guanine nucleotide exchange factor (GEF) pathway that is required for Ras-induced transformation. On the other hand, a functional screen identified IKKi as a kinase that acts downstream of the phosphatidylinositol 3-kinase (PI3K)-AKT pathway and cooperates with activated MEK to promote cellular transformation.
TBK1 and RalB signaling
The Ral GTPases RalA and RalB are two close relatives of the founding members of the Ras GTPase superfamily. The Ral proteins are involved in a variety of regulatory systems known to participate in oncogenic signaling cascades. Indeed, modulation of Ral GTPase activity influences the activation of Src, JNK, and p38 kinases; induction of phospholipase D activity; and the activation of NF-κB, Stat3, and transcription factors of the Forkhead family 74. Moreover, Ral GEF-induced Ral activation was recently found to be necessary and sufficient for Ras transformation of a variety of human cell types 75, 76, 77. Ral GTPases also control secretory events through the exocyst. The exocyst is a multisubunit complex whose core elements include Sec3, Sec5, Sec6, Sec8, Sec10, Sec15, Exo70, and Exo84. It is involved in the intricate secretory vesicle sorting and delivery events required to establish and support functionally and architecturally discrete plasma membrane domains 74. Sec5 and Exo84 are both direct effectors of Ral.
While studying the contribution of Ral GTPase effector proteins to Ral function in normal and tumorigenic epithelial cells, Chien and colleagues 73 observed that RNAi-mediated depletion of Sec5 induces apoptosis of a variety of tumor cell lines. To understand the molecular basis of this effect, they immunoisolated the exocyst complex from epithelial cells and identified TBK1 as a co-precipitating protein. They further showed that RalB activation promotes TBK1/Sec5 assembly and that TBK1 can phosphorylate Sec5 in vitro (see Figure 2A and Table 1). Silencing of TBK1 expression by RNAi was found to mimic depletion of RalB or Sec5 and induce tumor cell apoptosis. On the other hand, non-tumorigenic epithelial cells do not depend on TBK1 for survival 73. The selective dependence of transformed cells on TBK1 was also reflected in the enzyme's phosphotransferase activity, which was higher in transformed cells than in non-tumorigenic epithelial cells. Furthermore, studies using TBK1−/− fibroblasts revealed that TBK1 expression was required for cells to tolerate transforming levels of oncogenic K-RasG12V. This study also established that RalB and Sec5 were required for activation of the host defense pathway. Whereas Ras activity was suppressed in non-transformed epithelial cells in response to TLR3 signaling stimulated by poly (I:C) treatment, Ral GTPases were activated and this activation correlated with the phosphorylation of IRF-3. Moreover, siRNA-mediated depletion of Sec5 severely impaired not only the nuclear accumulation of IRF-3, but also the induction of ISG56 and IFNβ following Sendai virus (SeV) infection or poly (I:C) treatment. In summary, the RalB/TBK1 pathway is required for the survival of Ras-transformed cells and to activate the innate immune response in non-tumorigenic cells (Figure 3).
Another recent study also provides evidence for a role of TBK1 in tumorigenesis. Using a genome-wide phenotypic screen based on the overexpression of 250 000 cDNAs in HEK 293 cells combined with the transfer of culture supernatants onto HUVEC cells, Korherr and colleagues 78 identified TBK1 and TRIF as new regulators of vascularization. Overexpression of TRIF and TBK1 in HEK 293 cells resulted in the secretion of a complex mixture containing endothelial growth factors such as IL-8 and RANTES, as well as the anti-proliferative cytokine IFNβ. The secreted mixture showed significant proangiogenic properties on endothelial cells. In addition to HEK 293 cells, the authors analyzed the proliferative response of endothelial cells to supernatants isolated from MCF-7, PC-3, and KB-3-1 cancer cells transiently transfected with the TBK1 gene. They confirmed that the autocrine effect produced by TBK1 overexpression is observed in various cancer cell lines. Interestingly, these cancer cell lines already show increased activity of TBK1 (see above). Their study also showed some unexpected findings: TBK1 was up-regulated under hypoxic conditions, as well as in solid breast and colon tumors. This is the first report demonstrating modulation of TBK1 at the protein level.
Breast cancer and the NF-κB pathway: is IKKi the missing link?
Inflammatory breast cancer (IBC) is the most aggressive form of locally advanced breast cancer with a high metastatic potential. At the molecular level, microarray and qPCR analysis have revealed an 'NF-κB signature' in IBC 79, 80. Interestingly, the first piece of evidence implicating IKKi in tumor development was in breast cancer. IKKi was found to be constitutively expressed in two-thirds of the human breast cancer tissues analyzed, as well as in several human breast cancer cell lines 25. Casein kinase 2 (CK2) was proposed to be involved in the increased expression of IKKi. Most importantly, the NF-κB pathway is thought to contribute to the uncontrolled cellular proliferation of IKKi-expressing cells, since overexpression of an inactive mutant of IKKi reduces the expression of the cyclin D1 gene targeted by NF-κB (Figure 2B). It also reduces the ability of breast cancer cells to grow in soft agar and to form invasive colonies in Matrigel.
Mutation of the Ras proteins or hyperactivation of downstream effector pathways, principally the mitogen-activated protein kinase (MAPK) and PI3K pathways, occurs in several epithelial cancers including breast cancers (81 and Figure 1). An elegant functional genomic approach was used to identify protein kinases that have the potential to replace activated Akt and cooperate with a constitutively active MAPK pathway to drive tumorigenesis of immortalized human embryonic kidney epithelial cells 24. In this study, IKKi was identified among four kinases with the transforming potential (Figure 2B). Interestingly, the authors found copy-number amplification of the 1q32 region, which includes the IKBKE locus, in 16.3% of breast cancer cell lines and in several primary human breast cancer specimens. No somatic mutation was found in the IKBKE gene, and no association was observed between the IKBKE copy-number gain and the estrogen receptor or Her2/neu status. IKBKE amplification correlated with overexpression of IKKi in several breast cancer cell lines such as MCF-7 and ZR-75–1. Silencing experiments with shRNAs confirmed that IKKi is required for the proliferation and survival of ZR-75-1 cells. Interestingly, knocking down the expression levels of both IKKi and TBK1 was required to diminish the viability of MCF-7 cells. This observation also supports a role for TBK1 in oncogenesis as discussed above.
At the molecular level, the overexpression of IKKi observed in breast cancer cell lines resulted in increased expression of two NF-κB-regulated genes, MMP9 and BCL2, both of which were down-regulated when IKBKE expression was suppressed. Moreover, immunohistochemical studies in patient-derived breast cancer tissue samples revealed nuclear staining for c-Rel, a recently described substrate of IKKi (Table 1). This protein had previously been reported to accumulate in the nuclei of breast cancer cells 82 and to contribute to tumorigenesis of the mammary gland in an MMTV-LTR-c-Rel transgenic mouse model 83. IKKi modulates c-Rel activity through direct phosphorylation of the transactivation domain 84. However, even though nuclear accumulation of c-Rel was observed in HEK 293T cells, IKKi-induced phosphorylation was insufficient to significantly induce its transactivation potential. Thus, additional signaling cascades are likely to be required for full activation of c-Rel.
In addition to c-Rel and RelB 25, RelA/p65 was observed to accumulate in the nuclei in primary human breast tumor specimens 82. Furthermore, in many cancer cell lines, expression levels of IKKi correlate with p65 phosphorylation at Serine 536 85. However, Serine 536 is targeted by many other kinases, including IKKα/β, TBK1, and RSK1 31, 86, 87. Finally, IKKi also interacts with NF-κB2/p100 and p52 following TNFα stimulation 88. Gel filtration experiments suggest that IKKi and p52 are components of a 600-kDa complex. This interaction, in a ternary complex with p65/RelA, promotes transcription of p52-dependent genes. Although the kinase activity of IKKi is essential for this process, p52 does not seem to be a direct target, again suggesting that p65/RelA may be the preferred substrate of the kinase.
Are other substrates of IKK-related kinases involved in tumorigenesis?
It is intriguing that while the activity of IKK-related kinases is linked to cancer cell survival (see above), these kinases act on transcription factors with tumor suppressor properties, namely IRF-3, -5, and -7 (Table 1 and Figure 3). Activated by TBK1 or IKKi following viral or bacterial infections, these transcription factors ultimately lead to pathogen clearance. This occurs through the induction of type I IFN and of several IFN-stimulated genes (ISGs) involved in cellular processes of host defense. These processes include shutdown of protein translation, cell cycle withdrawal, apoptosis, and hematopoietic cell regulation such as dendritic cell (DC) activation. Notably, type I IFN signaling induces p53 accumulation 89. Thus, at first glance, one can argue that the IKK-related kinases may also counteract tumor development through their effect on type I IFN synthesis. However, several cancers exhibit specific mutations in components of the IFN signaling pathway 90 and are therefore resistant to the growth-inhibitory effect of type I IFN. Since these cytokines are known to act by paracrine and autocrine mechanisms, transformed cells that rely on the IKK-related kinases for survival and proliferation are likely to be unresponsive to type I IFN, thus shifting the equilibrium toward tumor progression (Figure 3). On the other hand, IRF-3 is known to possess tumor suppressor activities that are unrelated to the protein's effect on type I IFN synthesis, but are directly linked to its effect on apoptosis. Studies have revealed that IRF-3 can transactivate a large number of genes, such as ISG56, TRAIL, and NOXA, which are known to lead to abrogation of protein synthesis or to induce apoptosis in a p53-independent manner 91, 92, 93, 94, 95. IRF-3 also activates transcription of the gene encoding promyelocytic leukemia protein (PML), leading to p53-dependent growth inhibition of cancer cells 96, 97.
The role of IRF-7 in oncogenesis is still unclear. According to Zhang and colleagues, IRF-7 itself has oncogenic potential, as evidenced by its ability to induce tumor formation in nude mice and to cause anchorage-independent growth in NIH 3T3 cells 98. These authors suggested that IRF-7 may cooperate with the viral oncoprotein LMP-1 in EBV-immortalized B cells or CNS lymphoma cells in order to achieve cellular transformation. Conversely, a recent study pointed out the antitumor effector functions of IRF-7. Adenoviral transduction of an active form of IRF-7 into macrophages was found to up-regulate genes such as TRAIL, IL15, IL12p35, ISG56, and CD80 and also down-regulate transcription of proangiogenic/metastatic genes such as VEGF and MMP2. Thus, IRF-7 increases the antitumor properties of primary macrophages while reducing their protumorigenic effects 99.
IRF-5 is also a candidate tumor suppressor gene that mediates cell cycle arrest and apoptosis (reviewed in 3). In primary hematological malignancies such as acute lymphoblastic leukemia, chronic lymphocytic leukemia, and acute myeloid leukemia, IRF-5 expression is frequently down-regulated or absent 100. Overexpression of IRF-5 reduces colony formation of A549 lung cancer cells and HCT116 colorectal cancer cells 101, and inhibits growth of BJAB tumor cells in vivo 100.
STAT1, a novel substrate of IKKi
As key players in the IFN pathway, the signal transducers and activators of transcription (STAT) proteins contribute to the induction of numerous genes important for establishing a formidable barrier against viral infection. Recently, Tenoever and colleagues 102 established a molecular link between IKKi and the formation of the IFN-stimulated gene factor 3 complex (ISGF3), composed of the STAT1-STAT2 heterodimer and IRF-9. They showed that IKKi phosphorylates STAT1 following treatment with IFNβ. In vitro kinase assays combined with mass spectrometry identified Serine 708 as the phosphorylated residue. This post-translational modification allows formation of a more stable STAT1-STAT2 heterodimer, which is likely to be essential for binding the ISRE sequence located in a subset of genes involved in antiviral immunity. Thus, IKKi may be involved in defining ISGF3 binding specificity.
The STAT proteins have also been extensively studied for their role in oncogenesis. For instance, constitutive activation of STAT1, STAT3, and STAT5 has been observed in different human primary tumors and cell lines derived from breast cancer, multiple myeloma, head and neck cancer, leukemia, lymphoma, and lung cancer 103, 104. However, unlike the clear involvement of STAT3 and STAT5 in oncogenesis, the role of STAT1 remains obscure and controversial. While STAT3 and STAT5 are clearly recognized as oncogenic transcription factors, the STAT1 pathway has been predominantly associated with the inhibition of cell proliferation and tumor suppression 104, 105. On one hand, STAT1 can promote tumor cell death through transcriptional regulation of genes encoding proteins such as death receptors and ligands, caspases, iNOS, Bcl-xL, and p21Cip1 (for good reviews see 103, 106, 107). On the other hand, according to the recent findings of Yarilina and colleagues 108, STAT1 in myeloid cells could enhance tumor progression by accelerating inflammation during the early stages of inflammation-associated tumorigenesis. Indeed, TNFα, a well-known protumorigenic cytokine 6, can stimulate macrophages to produce low levels of IFNβ, which can in turn activate JAK-STAT signaling. Once activated, JAK-STAT signaling acts in synergy with other TNF-induced signals to maintain the expression of inflammatory cytokines. It also leads to increased expression of IKKi, IRF-7, and STAT1. Thus, STAT1 activation could play opposing roles in cancer development (Figure 3). As mentioned above, IKKi expression is also increased in breast tumors and may therefore play a role in the constitutive activation of STAT1 seen in breast tumor-derived cell lines 103, 104.
The roles of the IKK-related kinases in oncolytic-based viral therapy
Tumor cells show deficient type I IFN signaling, a trait that can be exploited for oncolytic-based viral therapy 90. For instance, VSV has been shown to exhibit powerful antitumor effects against metastatic breast adenocarcinoma 109, 110, 111. The Ras-dependent MAPK pathway seems to be responsible for this down-regulation of IFN-induced antiviral response 112. In this context, one can argue that increased levels of IKKi in breast cancer cells may promote the virus infection-mediated apoptosis. Indeed, VSV-mediated apoptosis was shown to be dependent on IRF-5, which, in turn, is likely to be phosphorylated and activated by the IKK-related kinases following VSV infection 41, 42, 43, 44, 113. It has also been reported that reovirus, another oncolytic virus, takes advantage of the Ras-dependent RalGEF pathway for its replication 114. Knowing that reovirus activation of IRF-3 enhances cellular apoptosis 115, it is tempting to speculate that the RalB-induced TBK1 activity in transformed cells may prove useful for developing anti-cancer therapies.
Conclusion
There is now compelling evidence that the transcription factor NF-κB plays a key role in cancer development and progression. Thus, the recent suggestion that the IKK-related kinases TBK1 and IKKi also regulate the proliferation and survival of cancer cells was not totally unexpected. However, these new findings will increase our understanding of the complex relationship between innate immune effectors and the signaling events that drive tumor formation. Some of the future questions that should be high on the priority list of investigators analyzing the role of these kinases in tumor development are the following. How is the kinase activity of TBK1 increased in cancer-derived cell lines in the absence of any apparent increase in expression level? Is this related to distinct scaffold proteins that facilitate assembly of TBK1 and IKKi subcomplexes 116 or could it be more related to the decrease in the expression of the tumor suppressor CYLD 69? What is the molecular basis of IKKi overexpression in breast tumors in the absence of amplification of the IKBKE locus, and is this related to increased NF-κB signaling? Are IRF-3 and IRF-7 activated in transformed cells that rely on TBK1 or IKKi for their proliferation and survival? If yes, then what is the role of the proapoptotic functions of these transcription factors that are unrelated to the proteins' effect on type I IFN synthesis? Since IKKi acts downstream of AKT in cancer-derived cell lines, is IKKi a direct substrate of AKT? Is TBK1 also subjected to this precise regulation? Are there other substrates for these kinases that could explain their effect on cellular proliferation? TBK1 and IKKi are new effectors implicated in tumor progression and may therefore represent new opportunities for drug development. Notably, the availability of compounds like SU6668, which targets TBK1 and other kinases, may help dissect the role of IKK-related kinases in cancer 117.
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Acknowledgements
We apologize to all colleagues whose papers could not be cited owing to space limitations. This work was supported by funding from the Canadian Institutes of Health Research (CIHR) to MJS (MOP-84571). MJS is the recipient of a R&D/CIHR Health Research Foundation Career Awards in Health Sciences. SM is the recipient of a Canada Research Chair in Cellular Signaling. JFC is the recipient of a studentship from the Fonds de la Recherche en Santé du Québec (FRSQ).
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Clément, JF., Meloche, S. & Servant, M. The IKK-related kinases: from innate immunity to oncogenesis. Cell Res 18, 889–899 (2008). https://doi.org/10.1038/cr.2008.273
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