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Protein Kinase Casein Kinase 2 Mediates Inhibitor-B Kinase and Aberrant Nuclear Factor-B Activation by Serum Factor(s) in Head and Neck Squamous Carcinoma Cells

Head and Neck Surgery Branch, National Institute on Deafness and Other Communication Disorders, NIH, Bethesda, Maryland

Requests for reprints: Carter Van Waes, Head and Neck Surgery Branch, Building 10, CRC Room 4-2732, 10 Center Drive, Bethesda, MD 20892. Phone: 301-402-2001; Fax: 301-402-1140; E-mail: vanwaesc{at}nidcd.nih.gov.

	Abstract

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We showed previously that the signal transcription factor nuclear factor-B (NF-B) is aberrantly activated and that inhibition of NF-B induces cell death and inhibits tumorigenesis in head and neck squamous cell carcinomas (HNSCC). Thus, identification of specific kinases underlying the activation of NF-B could provide targets for selective therapy. Inhibitor-B (IB) kinase (IKK) is known to activate NF-B by inducing NH₂-terminal phosphorylation and degradation of its endogenous inhibitor, IB. Casein kinase 2 (CK2) was previously reported to be overexpressed in HNSCC cells and to be a COOH-terminal IKK, but its relationship to NF-B activation in HNSCC cells is unknown. In this study, we examined the contribution of IKK and CK2 in the regulation of NF-B in HNSCC in vitro. NF-B activation was specifically inhibited by kinase-dead mutants of the IKK1 and IKK2 subunits or small interfering RNA targeting the ß subunit of CK2. CK2 and IKK kinase activity, as well as NF-B transcriptional activity, was shown to be serum responsive, indicating that these kinases mediate aberrant activation of NF-B in response to serum factor(s) in vitro. Recombinant CK2 was shown to phosphorylate recombinant IKK2 as well as to promote immunoprecipitated IKK complex from HNSCC to phosphorylate the NH₂-terminal S32/S36 of IB. We conclude that the aberrant NF-B activity in HNSCC cells in response to serum is partially through a novel mechanism involving CK2-mediated activation of IKK2, making these kinases candidates for selective therapy to target the NF-B pathway in HNSCC. (Cancer Res 2006; 66(13): 6722-31)

	Introduction

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The nuclear factor-B (NF-B/Rel) proteins, a family of nuclear transcription factors and their Inhibitors-B (IB), are normally involved in regulating a wide range of intracellular processes, including response to oxidative stress, inflammation, growth factors, injury, and programmed cell death (1). Aberrant NF-B activation has been detected in a variety of cancers, including head and neck squamous cell carcinomas (HNSCC; refs. 1–3). We discovered that NF-B1/RelA (p50/p65) activation is increased with tumor progression in murine SCC and in cell lines and tumor specimens from patients with HNSCC (4–8). Increased nuclear staining of the phosphoactivated form of p65 has recently been shown in the majority of high-grade squamous dysplasias and HNSCC specimens from patients and correlated with decreased survival, supporting the wider importance of NF-B in tumor development and clinical outcome of HNSCC (9). We have also shown that NF-B is an important modulator of the altered pattern of gene expression and malignant phenotype (10), indicating that NF-B activation is an important target for therapy. Specific inhibition of NF-B by overexpression of an IB with S32/S36 phosphorylation site mutations (IBM) restored altered gene expression and inhibited SCC cell proliferation, survival, migration, angiogenesis, tumorigenesis, and radiation resistance in experimental models (7, 10, 11). Bortezomib, an inhibitor of proteasome and IB degradation, had similar effects in preclinical and in a recent phase I clinical study (8, 12). However, the extent of inhibition of the proteasome NF-B and tumor response was limited by the dose of bortezomib achievable without significant side effects (8). Thus, identification of the specific kinases underlying the signal phosphorylation of IB and activation of NF-B could provide more selective targets for therapy in patients with HNSCC.

The eponymous IB kinase (IKK) plays a critical role in activating NF-B-mediated events in cell survival and the immune response (2). The classic IKK complex and pathway is composed of IKK1 (IKK), IKK2 (IKKß), and NF-B essential modulator (NEMO; IKK) subunits. An alternate pathway involving IKK1 has also been described (2). In normal cells, the classic IKK complex plays a critical role in integrating responses to various stimuli, resulting in IKK2-mediated phosphorylation of S32/S36 in the NH₂ terminus of IB and NF-B activation. Casein kinase 2 (CK2) is another stress-activated protein kinase that participates in the transduction of signals that promote cell growth and survival (13) and has been implicated in NF-B activation (14–18). In distinction to IKK2, CK2 has been shown to directly phosphorylate the COOH-terminal PEST domain of IB and has been recently shown to be a COOH-terminal IB kinase responsible for UV light-induced NF-B activation (14–16). CK2 may also promote transactivation by phosphorylation of the RelA subunit of NF-B (17, 18). CK2 is overexpressed and activated in HNSCC cell lines and tumor specimens and associated with poor prognosis (19, 20). Furthermore, antisense RNA targeting CK2 was found to inhibit proliferation of a HNSCC cell line (21), similar to our findings with inhibition of NF-B. These observations suggested a potential relationship and a role for CK2 in upstream signaling and activation of NF-B in HNSCC.

The signals mediating NF-B activation in HNSCC have not been elucidated. CK2, IKK, and NF-B may be activated in response to a variety of cytokines, growth, and serum factors (13, 17, 18, 22–26). In the present study, we examined the contribution of CK2, IKK, and serum to aberrant NF-B activity in HNSCC.

	Materials and Methods

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Cell lines. HNSCC cell lines from the University of Michigan squamous cell carcinoma (UM-SCC) series were obtained from Dr. T.E. Carey (University of Michigan, Ann Arbor, MI) and described previously (27). All UM-SCC cells that are used for this study were maintained in MEM (Invitrogen, Carlsbad, CA) with 10% fetal bovine serum (FBS). Supplemented serum-free medium (SFM) was the same MEM supplemented with nonessential amino acids, insulin-transferrin-selenium-G, vitamin solution, fibronectin (Invitrogen), and trace elements (Biofluids, Camarillo, CA). Human keratinocytes (HEKa) were purchased and maintained in supplemented 154CF medium with 200 mmol/L CaCl₂ (Cascade Biologics, Inc., Portland, OR). All cells were maintained at 37°C in 5% CO₂ atmosphere.

Reagents. Anti-IKK2 and anti-CK2ß antibodies were purchased from BD PharMingen (San Jose, CA). Anti-IB, anti-IKK1, and anti-NEMO antibodies were purchased from Santa Cruz Biotechnology (Santa Cruz, CA). Wild-type (WT) and mutant IB-glutathione S-transferase (GST) fusion proteins and pcDNA3-IKK vectors were kind gifts from Dr. Keith Brown (National Institute of Allergy and Infectious Disease, NIH, Bethesda, MD).

Western blot analysis. Protein (10 µg) of whole-cell lysates was used for each assay with standard immunoblotting procedures. Total proteins that were transferred onto the membrane were stained and quantified for equal loading control and for normalizing the intensities of the detected specific protein bands.

Electrophoretic mobility shift assay. Nuclear extracts were obtained by using a nuclear extract kit (Active Motif, Carlsbad, CA). Nuclear extract (5 µg) was used for electrophoretic mobility shift assay (EMSA) with ³²P-NF-B response element oligonucleotide (sense, 5'-AGTTGAGGGGACTTTCCCAGGC-3'; antisense, 3'-TCAACTCCCCTGAAAGGGTCCG-5'; Promega, Madison, WI). ³²P-OCT-1 was used as a positive control for loading.

NF-B reporter assay. Cells were transfected by jetPEI complexed with control or cis-pNF-B-luc cis-reporter plasmids [PathDetect In vivo Signal Transduction Pathway cis-Reporting Systems NF-B (5x); TGGGGACTTTCCGC; Stratagene, San Diego, CA].¹ After 24 hours, luciferase activities were measured with a dual-luciferase system from Promega (San Luis Obispo, CA) using a vector II spectrophotometer (Perkin-Elmer, Boston, MA). pCIS-CK plasmid was used as a negative control for the pNF-B-luc cis-reporter plasmid, whereas pFC-MEKK plasmid (both obtained from Stratagene) was cotransfected with pNF-B-luc cis-reporter plasmid to serve as a positive control. The firefly luciferase activities of triplicate samples were averaged following normalization by corresponding renilla luciferase activity cotransfected in the same wells. The NF-B luciferase activity is presented as the ratio of NF-B-luc to CK-luc.

CK2 small interfering RNA transfection. Cells were transfected with CK2ß-Stealth-RNAi (sense, 5'-CCAGCAACUUCAAGAGCCCAGUCAA; antisense, 5'-UUGACUGGGCUCUUGAAGUUGACGG), a corresponding scramble stealth RNA interference (RNAi) control (sense, 5'-CCACAACUUGAACGAACCUGGCCAA; antisense 5'-UUGGCCAGGUUCGUUCAAGUUGUGG; both designed by Invitrogen BLOCK-iT RNAi Designer),² or a universal negative control small interfering RNA (siRNA; Ambion, Austin, TX) and LipofectAMINE 2000 (Invitrogen) for 48 hours followed by evaluation assays. Transfection efficiency and cell viability were monitored by FITC-labeled RNA oligo, 4',6-diamidino-2-phenylindole (DAPI), and dead cell dye, respectively (Invitrogen).

mRNA quantification. IB, NF-B2/p100, and CK2ß mRNA levels from the cells were quantified by QuantiGene assay kit with probe sets designed to target each of these mRNAs specifically (Genospectra, Fremont, CA). The results were normalized to corresponding 18S rRNA levels.

IKK kinase assay. Cells were lysed in 25 mmol/L HEPES, 150 mmol/L NaCl, 1% Triton X-100, 10% glycerol, 5 mmol/L EDTA, 2 mmol/L DTT, and protease and phosphatase inhibitor cocktails. IKK was immunoprecipitated from cell lysates by polyclonal anti-NEMO antibody (Santa Cruz Biotechnology). Kinase assay was done in kinase buffer [20 mmol/L HEPES (pH 7.5), 10 mmol/L MgCl₂, 1 mmol/L DTT, 1 mmol/L sodium orthovanadate, 25 mmol/L ß-glycerol phosphate] by incubating IKK complex with either NH₂-terminal 72 amino acid of WT IB (S32/S36)-GST or mutated IB (S32G/S36A)-GST fusion proteins as substrate at 30°C for 30 minutes. The products from the kinase reaction were separated on a 4% to 12% SDS gradient gel and then transferred onto a nitrocellulose membrane. IKK kinase activity was quantified by the intensity of the ³³P-IB-GST band detected by autoradiography and normalized as a ratio to the corresponding quantified protein levels of IB, and IKK2 and IB were detected from immunoblot analysis on the same membrane.

CK2 kinase assay. Cell lysates were prepared as described above for IKK kinase assay. CK2 kinase activity was measured by using a CK2 kinase assay kit with a CK2-specific peptide substrate (Upstate, Charlottesville, VA).³ Total protein (20 µg) of the lysate from each reaction was incubated along with a protein kinase A (PKA) inhibitor and [-³³P]ATP in assay dilution buffer for 10 minutes at 30°C. The phosphorylated substrate is then separated by P81 phosphocellulose paper and quantified by a scintillation counter. Active CK2 enzyme was used as positive control. Spike assay was also used to ensure accuracy.

	Results

Top Abstract Introduction Materials and Methods Results Discussion References

 
Aberrant activation of NF-B in UM-SCC cell lines. We showed previously that NF-B is activated in several human HNSCC cell lines from the UM-SCC series (6, 7). To select representative cell lines for further analysis, we compared NF-B DNA-binding activity in a panel of nine UM-SCC cell lines derived from seven patients and in nonmalignant human keratinocytes (HEKa). Increased NF-B DNA-binding activity was detectable in eight of nine UM-SCC cell lines from six of seven patients relative to HEKa (Fig. 1A ), similar to the frequency of increased NF-B activation observed in HNSCC tumor relative to normal squamous mucosa specimens (9). To determine if variations in DNA binding are reflected by variations in functional activation, NF-B luciferase reporter activity was compared in UM-SCC-1, UM-SCC-6, UM-SCC-9, UM-SCC-11A, and UM-SCC-11B cell lines. Variable NF-B reporter activities were observed in these cells corresponding to their DNA binding activities (Fig. 1B). Thus, UM-SCC cell lines showed aberrant NF-B activation, with a prevalence and variability similar to that reported for HNSCC tumor specimens (8, 9).

View larger version (28K): [in this window] [in a new window]   Figure 1. NK-B is aberrantly activated in UM-SCC cells. A, EMSA for NF-B DNA-binding activity. HEKa and the UM-SCC cell lines were cultured as described in Materials and Methods. Nuclear extract protein (5 µg) from each cell line was used for binding to radiolabeled oligonucleotide containing the NF-B response element. A variable increase in NF-B response element DNA-binding activity was detected in most UM-SCC cells when compared with HEKa cells. Free probe was used as negative control. WT and mutant cold oligonucleotide was incubated with nuclear extracts from UM-SCC-5 as a NF-B response element specific binding control. OCT as a control for nuclear extract integrity and loading. B, NF-B reporter activity from UM-SCC cells. NF-B reporter activity was measured by cotransfecting cells with pNF-B-luc cis-reporter plasmid containing a 5x NF-B enhancer consensus element. NF-B reporter activities represent an average of multiple measurements that were normalized as a percentage of activity of UM-SCC-6 cells. Cell lines include UM-SCC-1, UM-SCC-6, UM-SCC-9, UM-SCC-11A, and UM-SCC-11B. Bottom, transfection conditions were optimized to reach >90% transfection efficiency for each cell line as determined by ß-galactosidase (ß-Gal) gene under control of a constitutive cytomegalovirus promoter. Variable NF-B reporter activities were observed. UM-SCC-6 cells showed significantly high NF-B reporter activity compared with other cell lines (P < 0.01), whereas UM-SCC-9 cells showed significantly low NF-B reporter activity compared with other cells (P < 0.01). C, IB expression and degradation time course from UM-SCC-6 and UM-SCC-9 cells following cycloheximide treatment. Cells were treated with 50 µg/mL cycloheximide for 0.5 to 4 hours. The protein levels of IB were detected by immunoblot analysis and normalized to total protein detected from the membrane. , UM-SCC-6 cells; , UM-SCC-9 cells. Data show that the IB protein level in UM-SCC-6 cells is 1.8-fold of that in UM-SCC-9 cells and that the t1/2 of IB in UM-SCC-6 cells is 1.5 hours, half of that in UM-SCC-9 cells (3 hours). D, comparison of IKK kinase activity between UM-SCC-6 and UM-SCC-9 cells. Cell lysates from UM-SCC-6 and UM-SCC-9 cells were immunoprecipitated by anti-NEMO antibody. IKK kinase activity was measured as incorporated 33P-IB by using an NH2-terminal IB-GST fusion protein as substrate (WT). The result is normalized by total IB, and IKK2 protein levels detected from the same membrane. A mutant S32G/S36A NH2-terminal IB-GST fusion protein was used as negative control (MUT). Data show that IKK kinase activity in UM-SCC-6 cells (SCC-6) is 1-fold higher than that in UM-SCC-9 cells (SCC-9). Below are the detected gel bands and corresponding measurements of the intensities of these bands.

The IKK1 and IKK2 subunits contribute to NF-B activation in UM-SCC cells. The IKK complex has previously been shown to mediate phosphorylation of IB and regulate canonical activation of NF-B by proinflammatory cytokines (13, 28). The role of IKK in aberrant NF-B activation in HNSCC was examined by cotransfection of amino acid–substituted dominant-positive (S176E/S180E, IKK1^EE; S177E/S181E, IKK2^EE), dominant-negative (S176A/S180A, IKK1^AA; S177A/S181A, IKK2^AA), kinase-dead IKK (K44A, IKK1^KA, and IKK2^KA), or WT IKK1 or IKK2 vectors together with cis-pNF-B-luc in UM-SCC-6 cells (28). Figure 2A and B shows that constitutively active IKK1^EE and IKK2^EE induced over a 20-fold increase in NF-B reporter activity compared with that of control cells (P < 0.001). Cotransfection and expression of additional WT IKK1 or IKK2 induced an 1.5-fold (P < 0.05) and 4-fold (P < 0.001) increase of NF-B activity, respectively. Thus, IKK^EE and WT both increased NF-B activity, serving as a positive control for the transfection and responsiveness of the cells. In contrast, the IKK2^KA partially reduced the NF-B reporter activity by 65% (P < 0. 001), whereas IKK1^KA reduced NF-B reporter activity by 50% (P < 0.001). The partial inhibition of NF-B reporter activity observed with either kinase-dead IKK1^KA or IKK2^KA in UM-SCC-6 cells is consistent with the partial 50% to 80% inhibition we have observed in repeated experiments with IKK1^KA or IKK2^KA, IKK1 or IKK2 siRNA, or IKK2 inhibitor PS-1145 in UM-SCC-11A and UM-SCC-11B.⁴ The contribution of both IKK1 and IKK2 to NF-B activation is also supported by their independent roles in processing of p100 to p52 (29) and degradation of IBs (28), both of which were observed after cycloheximide treatment in UM-SCC-6 cells (Fig. 1C; data not shown). In addition, cotransfection of the phosphoacceptor mutants IKK2^AA did not inhibit NF-B activity (P > 0.10) and that of IKK1^AA increased NF-B activity (P < 0.05) in UM-SCC-6 (Fig. 2A and B), suggesting that activation of these IKKs and NF-B may occur via a mechanism other than that previously reported for classic NF-B activation by tumor necrosis factor and interleukin (IL)-1 (28).

View larger version (13K): [in this window] [in a new window]   Figure 2. Effects of IKK mutants on NF-B reporter activity. UM-SCC-6 cells were cotransfected with pNF-B-luc cis-luciferase plasmid and one of the pcDNA3-IKK vectors (IKK1-AA, S176A/S180A; IKK1-EE, S176E/S180E; IKK1-KA, K44A, IKK1-WT, WT; IKK2-AA, S177A/S181A; IKK2-EE, S177E/S181E; IKK2-KA, K44A, IKK2-WT, WT) for 24 hours. pCK is used as a negative control. NF-B activity is normalized to pCK. A, effects of IKK2 on NF-B reporter activity. B, effects of IKK1 on NF-B reporter activity. Both WT (IKK1-WT and IKK2-WT) and dominant positive (IKK1-EE and IKK2-EE) of IKK1 and IKK2 enhanced the NF-B reporter activity (IKK1-WT to untreated control, P < 0.05; IKK1-EE, IKK2-WT, and IKK2-EE to their corresponding untreated control, P < 0.001). Kinase-dead IKK2-KA inhibited 65% of the constitutive NF-B reporter activity (P < 0.001). Dominant-negative signal mutant IKK2-AA showed no inhibitory effect on NF-B activity (P > 0.10). Kinase-dead IKK1-KA inhibited 50% of NF-B activity (P < 0.001). Little inhibitory but enhancing effect was observed from kinase-dead IKK1-AA (P < 0.05).

CK2 contributes to aberrant NF-B activation in UM-SCC cells.

IB

NF-B2

View larger version (23K): [in this window] [in a new window]   Figure 3. CK2 is responsible for the aberrant NF-B activity from UM-SCC cells. A, Apigenin inhibits aberrant NF-B reporter activity from UM-SCC cells. UM-SCC-6, UM-SCC-9, UM-SCC-11A, and UM-SCC-11B cells were exposed to 100 µmol/L apigenin for 2 hours before the DNA transfection for NF-B luciferase reporter assay. The reporter activities from each cell lines were normalized to their corresponding untreated control cells. White column, control (Ctrl); black column, apigenin. Data showed that apigenin inhibited 90% of the NF-B reporter activity from UM-SCC-6 cells (P < 0.005) and 70% of that from UM-SCC-9 cells (P < 0.05). Reduction (90% and 80%) of NF-B reporter activities was also observed from UM-SCC-11A (P < 0.005) and UM-SCC-11B cells (P < 0.05). B and C, CK2ß siRNAs knock down CK2ß mRNA levels in UM-SCC-6 and UM-SCC-9 cells. UM-SCC-6 and UM-SCC-9 cells were transfected with CSNK2B (CK2ß), scrambled, or a universal control siRNAs for 24, 48, and 72 hours. Untreated, no siRNA transfection; Ctrl-Universal, universal negative control siRNA from Ambion; Ctrl-Scramble, stealth scrambled siRNA control for CK2ß siRNA; CSNK2B, siRNA specifically targeting CK2ß mRNA. Data show a time-dependent decrease of CK2ß mRNA levels from both cell lines (UM-SCC-6, P < 10–9; UM-SCC-9 cells P < 10–5). D and E, CK2ß siRNA inhibits the aberrant NF-B activity in UM-SCC cells. Cells were transfected with siRNAs targeting CK2ß subunits as well as control siRNAs for 48 hours before the transfection for NF-B luciferase reporter assay. D, NF-B reporter activities from UM-SCC-6 cells. E, NF-B reporter activities from UM-SCC-9 cells. CK2ß siRNA significantly reduces the NF-B reporter activity (90%) from UM-SCC-6 cells (P < 0.05). Approximately 60% reduction of the NF-B reporter activity was observed from UM-SCC-9 cells, but this change is not statistically significant. F, CK2ß siRNA inhibits expression of endogenous NF-B-inducible genes IB and NF-B2/p100 in UM-SCC cells. mRNA was isolated from cell lysates of untreated UM-SCC-6 cells (white columns) and cells transfected with scramble control siRNA (slashed columns) as well as the siRNAs targeting CK2ß subunits (black columns) after 48 hours. A QuantiGene kit was used for mRNA quantification of IB and NF-B2/p100. Data were normalized to its corresponding 18S rRNA level as detected at the same time. Data show statistically significant decrease of IB (P < 10–6) and NF-B2/p100 (P < 10–7) in CK2ß siRNA-transfected cells compared with the corresponding scramble control.

Aberrant NF-B activation by UM-SCC cells occurs in response to serum.

View larger version (22K): [in this window] [in a new window]   Figure 4. CK2 and IKK mediate NF-B response to serum in UM-SCC cells. A, aberrant NF-B reporter activity is dependent on heat-sensitive components of FBS. UM-SCC-6, UM-SCC-9, UM-SCC-11A, and UM-SCC-11B cells were either cultured in MEM with 10% non-heat-inactivated FBS (black columns; FBS-NHI) or 10% heat-inactivated FBS (cross-hatched columns; FBS-HI), switched to supplemented serum-free MEM (dotted columns; SFM-new), or adapted to SFM (striped columns; SFM-Adp) before the transfection for NF-B reporter activity. The NF-B reporter activity levels were normalized to the level of their corresponding FBS-NHI. ANOVA analysis and Student-Newman-Keuls' analysis comparing each of the treatment groups. A reduction of NF-B reporter activity was observed from the cells that were cultured under both SFM-new and FBS-HI conditions when compared with that of the cells under FBS-NHI conditions. Adaptation to SFM further decreased NF-B reporter activity by 95% in UM-SCC-6, UM-SCC-11A, and UM-SCC-11B cells and 83% in UM-SCC-9 cells (P < 0.01). The level of NF-B reporter activity from SFM-adp is significantly lower than that of both SFM-new and FBS-HI (P < 0.01). No statistically significant difference was detected between SFM-new and FBS-HI. B, comparison of CK2 kinase activity in cells that were cultured in SFM or FBS. Total cell lysates from UM-SCC-6 cells that were cultured either in SFM or FBS were used for the CK2 kinase assay. A recombinant active CK2 was used as positive control. Black columns, CK2 activity from the cells that were cultured in SFM was reduced to 50% of that in FBS (P < 0.001). White columns, Apigenin (100 µmol/L) was applied to separate reactions in parallel to each of the conditions. The cell lysates that were treated with apigenin brought down the corresponding CK2 activity from each of these lysates by 75% of that FBS and 50% of that of SFM (P < 0.05). C, comparison of CK2ß expression level in cells. UM-SCC-6 cells grown in FBS-NHI or SFM-adp and UM-SCC-9 cells grown in FBS-NHI were compared for their CK2ß mRNA levels. CK2ß mRNA expression levels were measured as described in Fig. 3F using QuantiGene kit method. Data show a statistically significant decrease of CK2ß mRNA in both SFM-treated UM-SCC-6 cells and UM-SCC-9 cells compared with FBS control UM-SCC-6 cells (P < 0.01, for SFM; P < 0.001, for UM-SCC-9 cells). D, comparison of IKK kinase activity from the cells that were cultured in SFM or FBS. UM-SCC-6 cells were cultured in SFM or FBS. IKK complexes were immunoprecipitated by an anti-NEMO antibody from 200 µg total protein of whole-cell lysate of each culture. IKK kinase activity was measured with an NH2-terminal 72-amino acid IB-GST fusion protein as substrate and a S32G/S36A mutant of the IB-GST fusion protein as negative control. Quantified total IKK kinase activity was presented as a ratio of incorporated 33P radioactivity of phosphorylated IB-GST quantified by autoradiography to the quantified total IB-GST protein level on the same gel for total IKK kinase activity and further normalized to the total protein levels of IKK2 on the same gel. A 60% reduction of the normalized IKK kinase activity from these cells was observed. A recombinant active IKK2 was used as positive control (data not shown). Below is shown the detected gel bands and corresponding measurements of the intensities of these bands.

IB

Increased IKK activity in response to serum in UM-SCC-6 cells. In Fig. 2, we showed that cotransfection of kinase-dead IKK2^KA inhibited NF-B activity in UM-SCC-6 cells by 65% (Fig. 2A) and that SFM also reduces NF-B activity in these cells (Fig. 4A). We next examined the effect of serum on IKK kinase activity in UM-SCC-6 cells. IKK kinase activity from whole-cell lysate of UM-SCC-6 cells cultured with FBS or SFM was measured as described in Materials and Methods. An 50% decrease of IKK kinase activity was observed from cells that were cultured in SFM when compared with that in FBS in two independent experiments (Fig. 4D; data not shown). The change in IKK kinase activity is consistent with the magnitude of contribution of IKK2 to NF-B activation observed in Fig. 2. Specific phosphorylation of S32/S36 IB, the phosphoacceptor sites for IKK2, was ensured by comparison with a negative control S32G/S36A IB mutant substrate (Fig. 4D). Thus, our data indicate that IKK mediates signal phosphorylation of IB and activation of NF-B in response to serum by UM-SCC-6 cells.

CK2 promotes IKK kinase activity. Because the data above indicate that both CK2 and IKK mediate the response to serum and contribute to NF-B activity in UM-SCC-6 cells, we wondered if CK2 could modulate IKK2-mediated phosphorylation of IB. In this regard, protein sequence analysis revealed 11 putative CK2 phosphorylation consensus motifs in IKK2. Based on prediction algorithms, 6 of these motifs had a score (probability to be phosphorylated by CK2) >0.92 on a 0 to 1 scale (data not shown). This analysis suggested that IKK2 could be a potential substrate of CK2; hence, IKK kinase activity could be regulated by CK2. We examined whether IKK2 is a substrate of CK2 in an in vitro CK2 kinase assay by using rCK2 and recombinant IKK2 (rIKK2; Fig. 5A ). In this assay, we used 0.5 and 5 ng of rCK2 with rIKK2 (200 ng/reaction). Because CK2 can use both ATP and GTP, to ensure the CK2 specificity, we used GTP rather than ATP as a phosphodonor. Our result showed a low level of autophosphorylation by IKK2, which may be caused by the high concentration of rIKK2 used. This was confirmed by comparing GTP with ATP as a phosphodonor, which showed more dramatic autophosphorylation by IKK2 itself (data not shown). On top of this IKK2 autophosphorylation, we detected a rCK2 dose-dependent increase in phosphorylation of rIKK2. In the presence of 0.5 and 5 ng rCK2, an 40% and a 2.2-fold increase of normalized phosphorylated IKK2 was observed when compared with control. Apigenin completely suppressed CK2 phosphorylation of IKK2. The result shown here is an average of two parallel measurements. Thus, these data provide direct evidence that IKK2 is a substrate of CK2.

View larger version (18K): [in this window] [in a new window]   Figure 5. CK2 facilitates IKK kinase activity. A, IKK2 is a substrate of CK2. rIKK2 was incubated with or without (–) 0.5 and 5 ng of rCK2 and 5 ng rCK2 along with 40 µmol/L apigenin in the presence of 33P-GTP followed by SDS-PAGE gel separation, transfer, autoradiography, and immunoblot analysis for detection of phosphorylated IKK2 and protein levels of IKK2 and CK2. CK2 phosphorylation of IKK2 activity is presented as the radiation activity detected by autoradiography and normalized to the protein levels of IKK2 detected from the membrane. Data show CK2 dose-dependent phosphorylation of IKK2 and complete inhibition of this effect by apigenin. B, CK2 promotes IKK kinase activity. Catalytically active rCK2 (0.5 or 5 ng) and 5 ng rCK2 along with 40 µmol/L apigenin, respectively, were incubated with IKK complex that was immunoprecipitated from UM-SCC-6 cell lysate. rCK2 was washed out before IKK kinase assay. A fraction of untreated IKK complex was used as negative control. IKK kinase activity was measured with the same substrate as in Fig. 4D. Quantified total IKK kinase activity was presented as described in Fig. 4D. A 13% and 60% increase of total IKK kinase activities from IKK complex preincubated with 0.5 and 5 ng rCK2, respectively, was observed compared with untreated control. Anpigenin (40 µmol/L) completely inhibits the rCK2-induced IKK kinase activity. Below is shown the detected gel bands and corresponding measurements of the intensities of these bands.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

 
We discovered previously that NF-B is aberrantly activated and promotes tumorigenesis in human HNSCC and murine SCC (4–8, 10). NF-B activation has been broadly shown and associated with progression in intraepithelial premalignant and malignant squamous neoplasms of the head and neck as well as uterine cervix (9, 33). We have shown that expression of an S32A/S36A IB mutant unresponsive to IKK phosphorylation strongly inhibited NF-B activation in HNSCC and murine SCC (7, 10). Tamatani et al. (34) detected increased IKK-mediated phosphorylation of IB and NF-B activation in three HNSCC cell lines relative to that observed in five primary gingival keratinocyte cultures, indicating that IKK and NF-B are aberrantly activated together in HNSCC. Gapany et al. (19) showed that cytosolic CK2 expression and activity are also increased in HNSCC tumor specimens and cell lines. In the present study, we directly examined the hypothesis that CK2 promotes IKK-mediated aberrant activation of NF-B in HNSCC. NF-B activation was specifically inhibited by siRNA targeting the ß subunit of CK2 and kinase-dead mutants of the IKK1 and IKK2 subunits, implicating both the alternative and the classic IKK pathways in NF-B activation. We found that CK2 contributes to the activation of IKK and NF-B in response to serum factor(s). rCK2 was shown to phosphorylate rIKK2 as well as to promote immunoprecipitated IKK complex from HNSCC to phosphorylate the NH₂-terminal S32/S36 of IB. We conclude that the aberrant NF-B activity in HNSCC cells in response to serum is partially through a novel mechanism involving CK2-mediated activation of IKK2, making these kinases candidates for selective therapy to target the NF-B pathway in HNSCC. This is the first study to identify a potential mechanism linking the independent clinical pathologic observations that CK2 is an upstream regulator of IKK and NF-B activation in HNSCC.

Several observations from this and other studies in our laboratory suggested an alternative mechanism of activation and role of IKK in NF-B activation in HNSCC. First, we observed that both IKK1 and IKK2 contribute to NF-B activation. The inhibition of NF-B reporter activity in different UM-SCC cell lines by specific inhibition of either IKK2 with kinase-dead IKK2^KA, IKK2 siRNA, or IKK2 inhibitor PS-1145 or by that of IKK1 with IKK1^KA or IKK1 siRNA along was significant, reproducible, but incomplete. Although IKK2 has been shown to mediate activation of NF-B1/RelA (p50/p65), IKK1 has been reported to promote processing of p100 to p52 (NF-B2), an alternative NF-B activation pathway (29). Consistent with this, we found evidence for higher expression levels of endogenous NF-B-inducible genes IB and NF-B2 (data not shown), increased degradation rate of IBs, and processing of p100 following cycloheximide treatment in UM-SCC-6 cells (data not shown). Furthermore, the IKK2^AA mutant did not inhibit NF-B activation, and the IKK1^AA mutant enhanced activation of NF-B activity. These results suggested that the signaling mediated by these IKK subunits in HNSCC may result from signal(s) and/or mechanism(s) that are distinct from those mediating classic activation of IKK and NF-B (28).

CK2 is a highly conserved pleiotropic and ubiquitous serine and threonine kinase with a wide range of substrates involved in carcinogenesis and tumor progression. More than 300 CK2 substrates have been identified (13, 35), and the majority of which are proteins that are involved in transcription, cell cycle regulation, cell proliferation, cell survival, gene expression, and signal transduction. CK2 phosphorylation has been shown to inhibit apoptosis and favor cell proliferation and oncogenic transformation (13, 36). In this study, we provide evidence that CK2 is a key mediator of overall NF-B activation and functions to enhance IKK kinase phosphorylation of IB. The CK2 inhibitor apigenin or specific siRNA targeting CK2ß was sufficient to inhibit NF-B activity, indicating that the overexpression of CK2 and increased CK2 activity found in prior studies (19, 20) may be responsible for mediating the aberrant activation of NF-B in HNSCC.

CK2 has previously been shown to phosphorylate multiple sites in the COOH-terminal PEST domain of IB, including the response involved in UV light-induced NF-B activation (14, 16). CK2 has also been reported to phosphorylate S529 of the RelA/p65 subunit (17, 18). In addition to these targets, we have found that catalytically active rCK2 can phosphorylate both rIKK2 and rIKK1 (data not shown) in vitro and that incubation of IKK complex with rCK2 resulted in increased IKK2 kinase activity for the phosphorylation of S32/S36 NH₂ terminus of IB, a novel and distinct function from that of CK2 as a known COOH-terminal PEST domain IKK. This finding is also supported by protein sequence analysis of IKK1 and IKK2, which reveals multiple CK2 phosphorylation motifs. Additionally, the decreased IKK kinase activity in UM-SCC-9 and SFM-cultured UM-SCC-6 cells were associated with lower expression levels of CK2ß in these cells, adding another line of evidence that CK2 is an upstream regulator of IKK and NF-B activation.

CK2 has been linked to aberrant NF-B activity in cancer cells derived from human breast, hepatic, and colon carcinomas (30, 37–41). However, the relative contribution of CK2 to NF-B activation seems to vary among different cancers. Compared with CK2 activation of NF-B in other type of cancer cells (30, 37–41), our CK2ß siRNA data indicate a dominant effect of CK2 as a holoenzyme on NF-B activation in UM-SCC cells. On the other hand, our data do not rule out the possibility of direct effects of CK2 on activating the NF-B pathway at other levels, as multiple CK2 phosphorylation motifs have been identified in every member of the NF-B and IB families. Thus, the presence of CK2 target sites in IB and p65 as well as the potential sites in IKK and other NF-B and IB family members could explain why we observed nearly complete inhibition of NF-B activity by blocking CK2 activity. More detailed characterization of the molecular basis of the interaction between CK2 and IKK is needed and may lead to additional specific targets for cancer treatment.

An important finding of the present study is the demonstration that CK2 and IKK mediate the altered activation of NF-B in response to serum factor(s). The increase in CK2 and NF-B activation in the majority of HNSCC specimens relative to normal mucosa (9, 20) indicates that the response of these pathways to serum factor(s) is altered and precedes culture rather than being a mere consequence of serum induction in culture. Indeed, we have shown that the increased NF-B activity in murine SCC cells occurs with tumor progression in vivo and favors tumorigenesis and metastasis in the host environment (5). Consistent with this, the increased nuclear localization of NF-B observed in human squamous dysplasias is associated with higher risk of progression in a recent clinical pathologic study (9).

The factor(s) in serum and/or the host environment that contribute to induction of CK2, IKK, and NF-B remain to be elucidated and may provide additional targets for therapy. Autocrine factors produced by HNSCC (42, 43) or paracrine factors produced by tumor stromal fibroblasts (44) have been shown to enhance activation of NF-B in HNSCC. Several components contained in serum, including cytokines, growth factors, different types of albumins, zinc, copper, and free thiols, have been reported to affect NF-B activity (13, 24–26, 31, 43–49). Because the serum factors contributing to NF-B activation in UM-SCC were heat sensitive, labile protein factors seem the most likely candidates.

We have previously evaluated epidermal growth factor (EGF) and cytokine IL-1 as possible candidates (42, 43) because they are factors that are known to activate NF-B in nonmalignant and malignant cells. Although NF-B was found to be inducible by EGF, C225, the specific antagonist of anti-EGF receptor (EGFR) antibody, inhibited only inducible but not aberrant NF-B activity, making EGFR an unlikely candidate for the aberrant NF-B activation in HNSCC (42). We have previously obtained evidence that the IL-1/IL-1 receptor (IL-1R) pathway may be one of the stimuli contributing to the aberrant activation of NF-B in HNSCC. We found that transient expression of an intracellular form of the IL-1R antagonist could significantly inhibit NF-B reporter activity and cytokine IL-8 gene expression in UM-SCC-9 and UM-SCC-11B cell lines (43). Recently, interruption of the IL-1 signal pathway by expression of siRNA knocking down expression of IL-1R1, or a dominant-negative mutant of the essential Toll receptor linker MyD88, was found to strongly inhibit NF-B activation in five of six UM-SCC lines, including the UM-SCC-6, UM-SCC-9, UM-SCC-11A, and UM-SCC-11B cell lines.⁵

Interestingly, a recent study in malignant keratinocyte lines suggests that the IL-1 pathway and intracellular IL-1R antagonist may play a role in regulating signal degradation of IB and other transcription factors by the COP9 (CSN) signalosome, such as CK2 (50). Such an alternative pathway for activation of NF-B by IL-1 and possibly other factors could explain the enhancement of NF-B reporter activity by IKK1^AA and lack of inhibitory effect we observed with IKK2^AA, both of which are deficient in the phosphoacceptor sites mediating classic activation of NF-B. It would be interesting if this signalosome containing CK2 interacts with the IKK signalosome and other NF-B pathway components. Dissection of the role of CK2 or other intermediate kinases as possible oncogenes mediating aberrant activation of IKK and NF-B in response to exogenous factors in HNSCC may also be important to development of therapy.

In summary, we found that CK2 contributes to the activation of IKK and NF-B in response to serum factor(s), which suggests that CK2 and IKK2 are key candidates for targeting the NF-B pathway in HNSCC. This is the first study to identify a potential mechanism linking the independent clinical pathologic observations that CK2 and NF-B are activated and associated with decreased prognosis in HNSCC. Further clinical and molecular studies are indicated to confirm the role and further elucidate the factor(s) and mechanisms involved in CK2 activation of IKK and NF-B in HNSCC.

	Acknowledgments

 
Grant support: National Institute on Deafness and Other Communication Disorders Intramural Research Project Z01-DC-00016 (C. Van Waes) and Howard Hughes Medical Research Institute-NIH Scholars Program (J. Yeh).

The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked advertisement in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

We thank Keith Brown (National Institute of Allergy and Infectious Disease) and David Gius (National Cancer Institute, Bethesda, MD) for their critical review and comments.

	Footnotes

 
¹ http://www.stratagene.com/manuals/219073.pdf.

² https://rnaidesigner.invitrogen.com/rnaiexpress/Invitrogen.

³ http://www.upstate.com/img/coa/17-132-18642.pdf.

⁴ L. Nottingham and J. Ricker, unpublished observation.

⁵ L. Bagain et al., unpublished observation.

Received 10/19/05. Revised 3/31/06. Accepted 5/ 8/06.

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