Ku proteins interact with activator protein-2 transcription factors and contribute to <it>ERBB2 </it>overexpression in breast cancer cell lines

bcr2450 BCJ Research article Ku proteins interact with activator protein-2 transcription factors and contribute to <it>ERBB2 </it>overexpression in breast cancer cell lines Nolens Grégory gnolens@gmail.com Pignon Jean-Christophe jcpignon@student.ulg.ac.be Koopmansch Benjamin Benjamin.Koopmansch@student.ulg.ac.be Elmoualij Benaïssa b.elmoualij@ulg.ac.be Zorzi Willy willy.zorzi@ulg.ac.be De Pauw Edwin e.depauw@ulg.ac.be Winkler Rosita rwinkler@ulg.ac.be

Laboratory of Molecular Oncology, GIGA Cancer, University of Liège, B34, avenue de l'hopital, Liege, 4000, Belgium

Department of Human Histology-CRPP, University of Liège, B36, avenue de l'hopital, Liege, 4000, Belgium

Laboratory of Mass Spectrometry; CART, GIGA, University of Liège, B6, avenue de la chimie, Liege, 4000, Belgium

Breast Cancer Research 1465-5411 2009 11 6 R83 http://breast-cancer-research.com/content/11/6/R83 19906305 10.1186/bcr2450 26 4 2009 22 5 2009 07 10 2009 11 11 2009 11 11 2009 2009 Nolens et al.; licensee BioMed Central Ltd. This is an open access article distributed under the terms of the Creative Commons Attribution License (http://creativecommons.org/licenses/by/2.0), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly cited.

Abstract

Introduction

Activator protein-2 (AP-2) α and AP-2γ transcription factors contribute to ERBB2 gene overexpression in breast cancer. In order to understand the mechanism by which the ERBB2 gene is overexpressed we searched for novel AP-2 interacting factors that contribute to its activity.

Methods

Ku proteins were identified as AP-2α interacting proteins by glutathione serine transferase (GST)-pull down followed by mass spectrometry. Transfection of the cells with siRNA, expression vectors and reporter vectors as well as chromatin immunoprecipitation (ChIP) assay were used to ascertain the implication of Ku proteins on ERBB2 expression.

Results

Nuclear proteins from BT-474 cells overexpressing AP-2α and AP-2γ were incubated with GST-AP2 or GST coated beads. Among the proteins retained specifically on GST-AP2 coated beads Ku70 and Ku80 proteins were identified by mass spectrometry. The contribution of Ku proteins to ERBB2 gene expression in BT-474 and SKBR3 cell lines was investigated by downregulating Ku proteins through the use of specific siRNAs. Depletion of Ku proteins led to downregulation of ERBB2 mRNA and protein levels. Furthermore, reduction of Ku80 in HCT116 cell line decreased the AP-2α activity on a reporter vector containing an AP-2 binding site linked to the ERBB2 core promoter, and transfection of Ku80 increased the activity of AP-2α on this promoter. Ku siRNAs also inhibited the activity of this reporter vector in BT-474 and SKBR3 cell lines and the activity of the ERBB2 promoter was further reduced by combining Ku siRNAs with AP-2α and AP-2γ siRNAs. ChIP experiments with chromatin extracted from wild type or AP-2α and AP-2γ or Ku70 siRNA transfected BT-474 cells demonstrated Ku70 recruitment to the ERBB2 proximal promoter in association with AP-2α and AP-2γ. Moreover, Ku70 siRNA like AP-2 siRNAs, greatly reduced PolII recruitment to the ERBB2 proximal promoter.

Conclusions

Ku proteins in interaction with AP-2 (α and γ) contribute to increased ERBB2 mRNA and protein levels in breast cancer cells.

Introduction

Breast cancer is the most common cancer in women in Europe 1. Accumulation of different molecular alterations characterizes this complex disease. Five major breast cancer sub-groups have been distinguished according to gene expression signatures 23. One of these subgroups is characterized by ERBB2/Her2 gene amplification and overexpression. This alteration is present in about 20% of breast cancers and was found to be predictive of poor prognosis before the development of ERBB2 targeted drugs 456.

The ERBB2 gene encodes for p185^-erbB2, which is a transmembrane protein with intrinsic tyrosine kinase activity belonging to the EGF receptor (EGFR) family. No growth factor recognizing specifically ERBB2 with high affinity has been identified. Consequently, p185^-erbB2is assumed to be activated by hetero-dimerization with another ligand-activated member of the EGFR family 6.

The high levels of p185^-erbB2measured in breast cancer cells result from gene amplification and increased transcription rates 78. In order to investigate the biology of these specific breast cancers, we chose to study the deregulation of ERBB2 gene expression. Analyses of the ERBB2 promoter have led to the identification of several regulatory sequences through which the gene is overexpressed. AP-2, Ets and YB-1 transcription factor families bind to some of these regulatory regions and have been shown to play a role in ERBB2 overexpression. Ets family transcription factors contribute to ERBB2 overexpression by binding to the proximal promoter 9. YB-1 factors act through binding sites located 815 to 1129 bp upstream the main transcription initiation site 10, whereas AP-2 binding sequences (AP2BS) have been identified in the proximal 111213 and distal 14 regions of the promoter.

The AP-2 transcription factor family contains five members: AP-2α, β, γ, δ and ε. All have a similar 50 kDa apparent molecular mass and are able to form homo- and hetero-dimers. They bind specific DNA sequences, AP2BS, through their conserved helix-span-helix DNA binding domain.

The involvement of AP-2α and AP-2γ factors in ERBB2 overexpression has been described in several breast cancer cell lines 11121315. Besides the ERBB2 gene, AP-2 factors control the expression of several target genes implicated in the control of cell growth, differentiation and carcinogenesis 16.

AP-2 factors control transcription in association with transcriptional cofactors 17. Among them, PC4, PARP 18, CITED-2, CITED-4 and CBP/p300 19, as well as YY1 20, have been shown to interact with and to contribute to AP-2 transcriptional activity. In our own research, we have observed a good correlation between p185^-erbB2, AP-2α and YY1 expression levels in primary breast tumor samples 21. Besides their role in transcription, cofactors are also important for the protection of AP-2 against proteasomal degradation 22.

In order to improve the current understanding of AP-2 (α and γ) activity, we sought here to identify further AP-2α interacting factors contributing to ERBB2 gene overexpression in breast cancer cells. We used a proteomic approach to isolate proteins interacting with this transcription factor in a BT-474 breast cancer cell line. Ku70 and Ku80 were identified by mass spectrometry among the AP-2α interacting proteins.

Ku 70 and Ku80 hetero-dimers are mostly known for their role, in association with DNA-PK, in the repair of DNA double strand breaks. However, it has been shown that Ku70 and Ku80 are involved in transcription regulation either by binding directly to DNA or through interaction with transcription factors 23. Ku factors might also play a role in cancer 24.

We show that siRNAs targeting Ku mRNAs downregulate ERBB2 mRNA and protein levels. The use of reporter vectors containing the ERBB2 proximal promoter demonstrated that Ku70 and Ku80 proteins are involved in ERBB2 transcription regulation. Moreover, we show by ChIP assays that Ku70 protein is recruited to the ERBB2 gene promoter and its absence decreases AP-2α and AP-2γ recruitment. Furthermore, Ku70 recruitment is dependent on the expression of AP-2α and AP-2γ. These results contribute to a better understanding of the mechanism by which AP-2 factors upregulate ERBB2 gene expression in breast cancer cells.

Materials and methods

Cell lines

All the human cell lines (BT-474, ZR-75.1, MDA-MB-231, MCF-7 and SK-BR3, HepG2) were purchased from the American Tissue Culture Collection (Manassas, VA, USA). HCT116 and the derived 70/32 (Ku80+/-) cell lines were gifts from Dr. EA Hendrickson 25. All the cells were cultured in the recommended media supplemented with 10% (v/v) fetal bovine serum, 2 mM glutamine and 100 μg/ml penicillin/streptomycin (Lonza, Basle, Switzerland).

Antibodies

Mouse anti-AP-2α (3B5) 20, rabbit anti-AP-2α (C-18) 20, mouse AP-2γ (6E4/4) 21, goat anti-Ku70 (C-19) 26, goat anti-Ku80 (C-20) 26, mouse anti-Ku80 (B-1) 27, and control mouse, goat and rabbit IgG antibodies were purchased from Santa Cruz Biotechnology (Santa Cruz, CA, USA. Anti RNA Polymerase II (clone CTD4H8) and anti-β-actin (mAbcam 8226) antibodies were obtained from Abcam (Cambridge, UK).

Plasmids and constructs

The pGEX2T-GST-AP2 and -GST vectors were gifts from Dr. Kannan 28. The p86-AP2BS-Luc and p86-AP2BS mut-Luc plasmid reporter vectors (pGL3 basic reporter vector, Promega, Madison, WI, USA) have been previously described by Vernimmen et al 13. The SV40-Luc control vector (pGL3 control vector) was purchased from Promega. The AP-2α and the corresponding control expression vectors 29 have been described previously 20. Ku80 expression vector was a gift from Dr. Chen 30.

GST-pull-down

GST-fusion proteins were expressed and purified according to the procedures provided by Amersham Bioscience (Buckinghamshire, UK). Their purification and the pull-down assay were carried out by using the MagneGST™ Pull-Down System (Promega, Madison, WI, USA). The manipulation (incubation and washing) of the beads was automated by the KingFisher robot (Thermo Fisher Scientific, Waltham, MA, USA). Washing buffer was phosphate buffer saline (PBS)/0,01% Tween. Procedure: 15 μl of MagneGST beads were washed twice with the washing buffer. Beads were incubated with 50 μl of sonicated E. coli (Bl21) transformed with plasmids encoding GST or GST-AP2alpha fusion protein in 250 μl of PBS for 30 min at room temperature (RT). After washing twice with 400 μl of washing buffer, beads bound with GST or GST-AP2 were incubated for 50 minutes with 100 μg (35 μl) of nuclear proteins extracted from BT474 at RT in 180 μl of PBS. After washing the beads three times with 400 μl, the interacting proteins were finally eluted by 8 M urea for 2D gel electrophoresis, or with Laemmli Buffer (2% SDS, 10% glycerol, 5% 2-mercaptoethanol, 0.125 M Tris HCl pH 6.8) for western blotting.

DNase I treatment - GST-AP2 beads incubated with the nuclear protein extracts were washed twice with PBS and suspended in DNase I buffer (40 mM Tris HCl, 10 mM NaCl, 6 mM MgCl2, 1mMCaCl2, pH 7.9). The suspension was incubated with increasing concentrations of DNase I (Roche, Basel, Switzerland) for one hour at 37°C. The suspension was washed three times with PBS, resuspended in Laemmli buffer and the bound proteins were eluted by vortexing during 10 min. Ku70, Ku80 and AP-2 were revealed by western blotting. DNA quantity was estimated by the picoGreen assay (Invitrogen, Carlsbad, CA, USA).

Two-dimensional gel electrophoresis and mass spectrometry

These techniques were performed as described previously 31, except that the proteins were directly loaded onto IPG strips (non linear IPG strip pH 4-10; Amersham, GE Europe (Buckinghamshire, UK). Liquid chromatography was carried out in an UltiMate™ pump/detection module, FAMOS™ micro autosampler, Switchos™ micro switching module (LC Packings, Dionex, Sunnyvale, CA, USA). The mass analysis was carried out in an ion trap Esquire HCT (Bruker Daltonics, Bremen, Germany) mass spectrometer. The database search was performed using a Mascot local server (Matrix Science, London, UK).

Immunoblotting

Proteins were separated on an SDS-PAGE (10%) and transferred to a PVDF membrane (Millipore, Billerica, MA, USA). Primary antibodies were used at a 1:1000 dilution. Secondary antibodies coupled with peroxydase (DAKO, Glostrup, Denmark) at a 1:4000 dilution were detected using the ECL system (Thermo Fisher Scientific).

Immunoprecipitation was carried out using Dynabeads Protein G (Invitrogen), according to the manufacturer's recommended protocol, using acetate sodium buffer for antibodies binding. Anti-AP-2α (C-18), Ku70 (C-19), Ku86 (C-20) antibodies and control antibody were used.

Transient transfection assays of reporter vectors

HCT116, 70/32 (HCT116 Ku80 +/-), BT-474 and SKBR3 cells were transfected using FuGENE HD reagent (Roche Applied Science). The cells (3 × 10⁵) were plated onto 24 mm tissue culture dishes, treated with FuGENE HD/DNA (ratio of 3:1) and incubated for 40 h in complete medium. Cells were then harvested. Lysis and enzymatic activity measures were carried out using the Luciferase Reporter Gene Assay kit (Roche Applied Science). Enzymatic activity was measured in a Wallac Victor™ luminometer (PerkinElmer, Waltham, MA, USA). The data were normalized to total protein content.

Transient siRNA transfection

siRNAs were transfected at a 30 nM final concentration using the Calcium Phosphate precipitation technique 32. Cells were transfected twice at 48 h intervals. As a control, cells were transfected with the negative control siRNA OR-0030-neg05 (Eurogentec, Seraing, Belgium). The AP-2 siRNAs used were as previously described 14. Other siRNAs were: Ku70-1, 5-GUGUGUACAUCAGUAAGAU; Ku70-2, 5-CAGGCAUCUUCCUUGACUU; Ku80-1, 5-GAAGAGGCAUAUUGAAAUA; Ku80-2, 5-CUCCAUUCCUGGUAUAGAA.

Reverse Transcription-Polymerase Chain Reaction (RT-PCR)

Total RNA was extracted after 90 hours of siRNA transfection treatment, using the High Pure RNA Isolation kit (Roche Applied Sciences). RNA quantification was carried out on a Nano Drop 1000 (Thermo Fisher Scientific). Reverse transcription was performed on 1 μg of total extracted RNA. Real time PCR analysis was performed on an ABI Prism 5700 apparatus (Applied Biosystems, Foster City, CA, USA) using the standard protocol. All the results were reported to the β-2-microglobulin mRNA quantity. The primers used were as previously described 21, except for Ku70: 5-AGAAGCAAACCGCCTGTA and 5-CAAGCCTCCTCCAATAAAGC; and Ku80: 5-TGCAGCAAGAGATGATGAGG and 5-GAAAGGCAGCTGCACATACA.

Chromatin Immunoprecipitation (ChIP)

Chromatin Immunoprecipitation was carried out using Dynabeads Protein G (Invitrogen). The previously described protocol 33 was adapted for higher chromatin quantities. On average for each immunoprecipitation reaction, 30 μg of chromatin DNA was precipitated with 4 μg of antibody. Rabbit anti-AP-2α (C-18), goat anti-Ku70 (C-19) and mouse anti-Ku80 (C-20) were used. Immunoprecipitation with pre-immune sera from the same animal species (Ig) or mock immunoprecipitation (NoAb) served as negative controls. Recovered DNA was quantified by real time PCR or by end-point PCR followed by agarose gel electrophoresis and the results were compared to known quantities of chromatin. The gene-specific primer sequences were: -6900 primers: 5-GCAGTAGCAAGCATCGAGTT and 5-TGGATCATCACAAAGGTTTTCA (-6981 bp to -6780 bp); -500-bp ERBB2 primers, 5-GACTGTCTCCTCCCAAATTT and 5-CTTAAACTTTCCTGGGGAGC (fragment -575 to -349 bp); -100-bp ERBB2 primers, 5-GCGAAGAGAGGGAGAAAGTG and 5-GGGGAATCTCAGCTTCACAA; GCK primers, 5-GGTAGAGCAGATCCTGGCAGAG and 5-TGAGCCTTCTGGGGTGGAGCGCA. Dilutions of known quantities of input DNA were used to quantify the PCR products.

Results

Identification of novel AP-2α interacting proteins

Our goal was to identify novel proteins interacting with AP-2, which contribute to the factor's transcriptional activity. Nuclear protein extracts from BT-474 breast cancer cells were incubated with a Glutathione-Serine-Transferase/AP-2α (GST-AP2) hybrid protein, linked to glutathione (GSH) coated magnetic beads. Beads coated with expressed GST alone were used as a negative control. After washes, the proteins bound to GST-AP2 or GST coated beads were eluted and resolved on two-dimensional gel electrophoresis. Two proteins migrating with an apparent molecular mass comprised between 70 and 100 kDa were repeatedly detected among the proteins eluted exclusively from the GST-AP2 coated beads (Figure 1A). The corresponding spots were cut out of the gel, the proteins digested, and the resulting peptides analyzed by LC-MS/MS. The proteins were identified as Ku70 and Ku80 [see Additional data file 1]. Most of the other spots on the 2D-gel recovered from the GST-AP2 pull down, were identified as GST or AP-2α fragments.

Additional data file 1

Mass Spectometry identification of the Ku proteins interacting with AP-2α.

Click here for file

Figure 1

Identification of the Ku proteins interacting with AP-2α

Identification of the Ku proteins interacting with AP-2α. (a) Two-dimensional gel electrophoresis of nuclear proteins eluted from GST AP-2α coated beads or beads coated with GST alone (GST). The gels were silver stained and the proteins retained on GST AP-2α beads were identified by mass spectrometry. Arrows show the location of Ku80 (up) and Ku70 (down). Molecular masses are indicated on the left and the pH scale on the top of the gels. (b) The presence of AP-2α and Ku proteins in the eluted fractions was verified by immunoblotting (IB) and compared to a fraction of the input (IN). (c) Co-immunoprecipitation (IP) of AP-2 and Ku proteins by AP-2, Ku70 and Ku80 antibodies or an Ig control (Ig Ctl). The proteins were revealed by immunoblotting (IB).

The presence of Ku proteins among the proteins eluted from the GST-AP2 beads was confirmed by immunoblotting with Ku specific antibodies (Figure 1B). Moreover, the interaction between AP-2 and Ku proteins was controlled by co-immunoprecipitation, using AP-2, Ku70 and Ku80 specific antibodies (Figure 1C). To verify that the binding of Ku proteins to AP2 is not due to the DNA contaminating the protein extracts 34, the mixture of GST-AP2 beads and nuclear proteins were incubated with increasing concentrations of DNase I. The result, [see Additional data file 2] showed a decrease in bound Ku proteins after treatment with low DNase I concentrations. However, the quantity of recovered Ku proteins remained constant when the enzyme concentration was raised, despite the steady decrease in contaminating DNA. This result indicates that the association of Ku to AP-2 is specific.

Additional file 2

that Ku and AP-2 protein interaction is specific.

Click here for file

Ku70/80 depletion induces downregulation of ERBB2 expression

Figure 2 presents Ku70, Ku80 AP-2α, AP-2γ, and p185^-erbB2protein levels in the cytoplasmic and the nuclear fractions of breast cancer (BT-474, SKBR3, ZR-75.1, MCF-7, MDA-MB-231), colon cancer (HCT-116) and hepatoma (HepG2) cell lines. In most cells, Ku70 and Ku80 proteins were detected in both the nuclear and the cytoplasmic fraction, with the exception of MCF-7 and HepG2 cell lines where Ku80 was exclusively nuclear. In comparison, AP-2α and AP-2γ factors were detected only in the nuclear fraction of BT-474, SKBR3 and ZR-75.1 breast cancer cells that overexpress p185^-erbB2protein.

Figure 2

Ku70 and Ku80 protein levels in cytoplasm and nuclei of cancerous cell lines

Ku70 and Ku80 protein levels in cytoplasm and nuclei of cancerous cell lines. 60 μg of nuclear and cytoplasmic proteins extracted from the cell lines were resolved by 10% PAGE. The Ku80, Ku70, AP-2α, AP-2γ and p185^erbB2proteins were revealed by immunoblotting. The antibodies are indicated on left. Beta-actin (β-actin) protein was used as a loading control.

Next, we studied the consequence of Ku70 and Ku80 downregulation on the ERBB2 expression level. For that purpose, Ku70 and Ku80 were inhibited by the transfection of specific siRNAs in two ERBB2 overexpressing cell lines, BT-474 and SKBR3. In parallel, the cells were transfected with a combination of AP-2α and AP-2γ (AP-2αγ) siRNAs, previously shown to downregulate ERBB2 expression 21. The levels of Ku70, Ku80, AP-2α, AP-2γ and p185^erbB2proteins in BT-474 were assessed by western-immunobloting 96 hours after transfection (Figure 3A). Each siRNA inhibited its own target protein. Moreover, Ku70 and Ku80 siRNAs reduced both Ku70 and Ku80 protein levels, in agreement with published data 3536.

Figure 3

Effect of Ku70/Ku80 and AP-2 downregulation on ERBB2 protein levels in BT-474 cells

Effect of Ku70/Ku80 and AP-2 downregulation on ERBB2 protein levels in BT-474 cells. (a) Immunoblot showing p185^-erbB2, Ku70, Ku80, AP-2α, AP-2γ and beta-actin (β-actin) protein levels in cells transfected with the siRNAs indicated above the photograph. (b) Percent reduction of ERBB2 mRNA levels compared to the Neg siRNA condition in cells transfected with the different siRNAs indicated below the figure. ERBB2 mRNA levels were quantified in triplicate by Real-time RT-PCR, and corrected for beta-2-microglobulin mRNA levels.

The results of similar experiments on SKBR3 cells are presented in Additional data file 3, Figure A. Ku70 and Ku80 siRNAs reduced p185-^erbB2levels less efficiently in SKBR3 than in BT-474 cells. We have to stress that AP-2αγ siRNAs were also less efficient in SKBR3 than in BT-474 cells.

Additional file 3

effect of Ku70/Ku80 and AP-2 deregulation on ERBB2 mRNA and protein expression in SKBR3 cells.

Click here for file

In order to gain a more precise view of the cooperation between Ku and AP-2 proteins on ERBB2 gene transcription, the ERBB2 mRNA level was precisely quantified by real-time RT-PCR in Ku and AP-2αγ siRNA transfected cells. The ERBB2 transcript levels in cells transfected with the siRNAs were compared to the mRNA levels in cells transfected with the Negative (Neg) siRNA [Figure 3B and Figure B in Additional data file 3]. ERBB2 transcript levels were similarly reduced by Ku70 and Ku80 siRNAs in BT474 cells. The AP-2αγ siRNAs were more effective, reducing the ERBB2 transcript level by about 50%. Co-transfection of Ku and AP-2αγ siRNAs did not reduce further the ERBB2 mRNA level in these cells. While the Ku70 siRNA was as effective in SKBR3 as in BT-474 cells, Ku80 and AP-2 αγ siRNAs were much less effective. In contrast with BT-474 cells, in SKBR3 cells a combined effect of Ku70 and AP-2 siRNAs was observed.

Ku70/80 regulate ERBB2 promoter transcriptional activity

To investigate the transcriptional control of ERBB2 gene expression by Ku and AP-2 proteins, we compared the HCT116 cell line and its derived 70/32 cell line, knocked out for one Ku80 allele 25. Ku80 protein level in 70/32 cells was decreased by about 40-60% in comparison with the wild-type HCT116 cells (Figure 4C). The role of the interaction between Ku and AP-2 on ERBB2 gene expression was studied by transfecting in both cell lines a luciferase- reporter vector containing a wild type or a mutant AP-2 binding site (AP2BS) (Figure 4A). The cells were cotransfected with AP-2α and/or Ku80 expression vectors or the corresponding empty vectors. The luciferase activity in the cells transfected with the empty expression vector was considered as equal to one. As previously shown 1320, AP-2α stimulated the activity of the reporter containing the wild type AP2BS (Figure 4B). However, the activation was reduced in 70/32 cells expressing less Ku80. Ku80 expression vector alone had no effect on the promoter activity. However, co-transfection of Ku80 with AP-2α expression vectors induced a significant increase in the promoter activity in both cell lines. Interestingly, transfection of Ku80 restored the activation capacity of AP-2α in 70/32 cell line. Figure 4C presents the AP-2α and Ku80 protein levels in the transfected cells.

Figure 4

Influence of Ku80 on AP-2α transcriptional activity on ERBB2 gene promoter

Influence of Ku80 on AP-2α transcriptional activity on ERBB2 gene promoter. (a) Schematic representation of the reporter vectors used in this study. All the reporter vectors contain 86 bp of the ERBB2 core promoter. The black diamond indicates the CAAT box; the black triangle the TATA box. The sequence of the AP2BS is that of AP-2 binding sites located at -512 bp from the main ERBB2 transcription start site. Mutation of three nucleotides abrogates the binding of the transcription factor to AP2BSmut 25. (b) Variation of luciferase activity in cells transfected with (+) AP-α expression vector alone or with the Ku80 expression vector, in HCT116 and in 70/32 (HCT116 Ku80+/-) cell lines; compared with the activity in the cells transfected with the corresponding empty expression vectors (-). (c) Western blot showing the levels of AP-2α and Ku80 proteins in the cells transfected with the corresponding expression vectors.

To complete this investigation, the reporter vectors activities were measured in BT-474 (Figure 5) and SKBR3 [see Additional data file 4] cells 72 hours after transfection of Ku and AP-2 siRNAs (Figure 5). The Luciferase activity in cells transfected with the negative siRNA was considered as equal to one in each condition. As expected, downregulation of AP-2α and AP-2γ inhibited only the activity of the reporter containing the functional AP2BS (p86-AP2BS-Luc). Ku70 or Ku80 siRNAs also inhibited significantly the activity of this reporter vector. Furthermore, when Ku70 or Ku80 siRNAs were co-transfected with the AP-2αγ siRNAs, the activity of p86-AP2BS-Luc was further reduced. In contrast, AP-2αγ, Ku70 and Ku80 siRNAs did not modify significantly the activity of the vector containing the mutated AP2BS (p86-AP2BS mut-Luc). However, co-transfection of AP-2αγ with Ku70 or Ku80 significantly reduced the activity of the reporter containing the mutant AP2BS.
Additional file 4
that Ku70/80 proteins control ERBB2 promoter activity in SKBR3 cell line.

Click here for file
Figure 5
Ku70/80 proteins control ERBB2 promoter activity in BT-474 cell line

Ku70/80 proteins control ERBB2 promoter activity in BT-474 cell line. Relative luciferase activity in cells transfected with the reporter vectors indicated above the figure, 72 hours after transfection of the siRNAs shown under each bar. The fold induction is the ratio between the luciferase activities in the cells transfected with the siRNA of interest and the activity measured in cells transfected with siRNA Neg. Luciferase activity was normalized to total protein content.

Together, these results suggest that Ku proteins regulate ERBB2 gene expression through the proximal promoter, by an AP-2 dependent mechanism.

Ku70/80 proteins are recruited to the ERBB2 proximal promoter

Next, we investigated Ku binding to ERBB2 gene promoter by chromatin immunoprecipitation (ChIP). Cross-linked chromatin was extracted from BT-474 (Figure 6A) and SKBR3 cells [Supplemental Data, Figure S.4]. We also extracted chromatin from the same cell type transfected with Ku or AP-2αγ siRNAs. Chromatin fragments were immunoprecipitated with antibodies recognizing AP-2α and AP-2γ (AP-2), Ku70, Ku80 and RNA Polymerase II (Pol II). The Pol II antibody was used as a positive control for the recruitment of the transcriptional machinery on the ERBB2 promoter 142037. Three regions of the ERBB2 promoter were amplified (Figure 6B). The -500 bp region contains a high affinity AP2BS 12. The -100 bp region contains the CAAT and TATA boxes and corresponds to the ERBB2 core promoter. The -6900 bp sequence was used as an AP2BS negative control 14. The Ku binding sequence from the Glucokinase (GCK) gene promoter was used as a positive control for Ku proteins binding 37. Experiments were repeated three times and the average quantities of DNA were reported to the "No antibody" (NoAb) condition (Figure 6C).
Figure 6
Ku70 is recruited to the ERBB2 promoter and is necessary for the recruitment of AP-2 and of RNA PolymeraseII

Ku70 is recruited to the ERBB2 promoter and is necessary for the recruitment of AP-2 and of RNA PolymeraseII. (a) Chromatin extracted from BT-474 cells transfected or not with AP-2 (αγ) or Ku70 siRNAs (above) was shared by sonication to fragments of 100-500 bp. Protein expression was verified by immunoblot. (b) Schematic representation of the ERBB2 promoter illustrating the amplified regions. (c) DNA amplified after chromatin immunoprecipitation with AP-2, Ku70 and RNA Polymerase II (Pol II) specific antibodies. ChIP with control antibodies (Ig) are presented on the left of each experimental point (R: rabbit, G: goat and M: mouse). Graphs show the fold enrichment of the target sequence, compared to the no-antibody (NoAb) condition. The error bars were calculated from the results of three independent ChIP experiments. GCK sequence corresponds to a positive control for Ku recruitment. * and **: P-values < 0,05% compared to the No siRNA condition.

In untreated BT-474 cells, Ku70 antibody immunoprecipitated most efficiently the -500 bp DNA sequence of the ERBB2 gene promoter (Figure 6C, black columns). In agreement with previously published data, AP-2 antibody also immunoprecipitated the same region 1420. Interestingly, AP-2 antibodies also immunoprecipitated the GCK sequence. The -500 bp, -100 bp and GCK sequences were efficiently recovered from Pol II specific immunoprecipitations. No DNA was recovered in the ChIP experiments using the C-20 Ku80 specific antibody (data not shown). Although the C-20 antibody has been successfully used in our immunoprecipitation experiments (Figure 1C) and published in ChIP data 26, we did not succeed to immunoprecipitate even the GCK control sequence with this antibody. As the -6900 bp region is devoid of an AP2BS, we consider this signal as background. Compared to BT-474 cells, immunoprecipitation with Ku70 and PolII antibodies of the ERBB2 and GCK promoter regions in SKBR3 was very poor [see Additional data file 5].
Additional file 5
that Ku proteins are necessary for the recruitment of AP-2 on the proximal ERBB2 gene promoter in SKBR3 cell line.

Click here for file

AP-2αγ siRNAs reduced significantly the amount of DNA corresponding to the 500 bp region recovered after immunoprecipitation with the AP-2 antibody. Interestingly, AP-2αγ siRNAs drastically reduced all DNA fragments recovered after ChIP using the Ku70 antibody in the BT-474 cell line. The recruitment of the DNA fragment from the GCK promoter after the Ku70 ChIP was also reduced. These siRNAs completely inhibited Pol II recruitment to the ERBB2 and GCK promoters. In the two cell lines, Ku70 siRNA reduced AP-2 recruitment to the ERBB2 and GCK gene promoters. This siRNA also completely inhibited the recruitment of Ku70 and PolII to the promoters we had investigated in the BT-474 cell line.

The ChIP results suggest that both Ku and AP-2 proteins are recruited on the ERBB2 proximal promoter in BT-474 cells. Moreover, the binding of both factors is necessary for the recruitment of transcription machinery on the ERBB2 gene promoter in BT-474 and SKBR3 cell lines.

Discussion

The aim of this study was to identify novel proteins interacting with and contributing to AP-2 transcription factor activity. Using GST-pull-down coupled with two-dimensional gel electrophoresis and mass spectrometry, Ku70 and Ku80 proteins were identified as AP-2α interactors. AP-2/Ku interaction was confirmed by co-immunoprecipitation. We showed that downregulation of Ku proteins by siRNAs induced a strong reduction in ERBB2 mRNA and protein levels in BT-474 and SKBR3 cells. These siRNAs also inhibited the activity of reporter vectors containing the ERBB2 proximal promoter. ChIP experiments revealed that Ku70 proteins were recruited to the ERBB2 promoter. Interestingly, the inhibition of AP-2α and AP-2γ expression by siRNA strongly reduced Ku70 recruitment to the ERBB2 promoter. Ku70 siRNA reduced by half the recruitment of AP-2 factors to the -500 bp region of the ERBB2 promoter containing a high affinity AP2BS. More importantly, Ku70 siRNA downregulated PolII recruitment to the ERBB2 promoter. These results show that the Ku proteins are involved in ERBB2 gene expression regulation by AP-2 in breast cancer cells.

In addition to their role in the repair of DNA double strand breaks, Ku proteins have been shown to control other important cellular processes such as transcription and apoptosis. Ku proteins modulate transcription by several mechanisms and these properties seem to be gene and cell specific. For example, DNA binding of the Ku70/Ku80 heterodimer is responsible for the downregulation of glycoprotein glycophorin B in non erythroid cells 38. In contrast, Ku binding to apolipoprotein C-IV promoter stimulates the expression of the gene 39. Another study showed that interleukins -13/-4 induced expression of the lipooxygenase-1 gene is mediated by the binding of Ku dimmers to the promoter 40. C-jun expression is also stimulated by Ku80 and possibly by Ku70 binding to gene promoter 41. Ku proteins can also influence transcription by interaction with transcription factors or cofactors. So, Ku binding inhibits ESE1, an Ets family transcription factor, from binding to DNA and thus its transcriptional activity 42. Ku proteins might also be involved in elongation 37 and transcription reinitialization 43.

Ku proteins were also shown to modulate gene expression by binding to PARP-1 and to YY1, which were shown to interact with and influence AP-2 transcription factor activity. Indeed, PARP-1 is necessary to preserve the transcriptional activity of overexpressed AP-2 transcription factors 18. The Ku - PARP interaction has opposing effects on transcription. Ku proteins inhibit the transcriptional activity of β-catenin-TCF4 complex by interfering with PARP-1 binding 44. In contrast, the Ku70/Ku80 dimmer - PARP-1 complex stimulates the expression of the S10019 gene 45. Ku - YY1 interaction inhibits α myosin heavy-chain gene expression in the heart 46, contrary to the consequence of YY1 interaction with AP-2 on ERBB2 gene expression 20.

Conclusions

In summary, the present study contributes to a better understanding of the regulation of ERBB2 gene expression in breast cancer cells, by demonstrating the implication of Ku proteins together with AP-2 transcription factors in the expression of the oncogene. Our results implicate Ku proteins in breast cancer by contributing to ERBB2 gene overexpression and thus the accumulation of excessive amounts of the receptor. Understanding the mechanisms of ERBB2 gene deregulation might help in the development of drugs that target further key elements responsible for this important deregulation. Among these, inhibiting Ku activity might be evaluated as an adjuvant for ERBB2 targeted therapy in breast cancer. However, more work is needed in models resembling the in vivo situation to confirm the implication of Ku proteins in the accumulation of excessive amounts of ERBB2 protein in cancerous cells.

Abbreviations

AP-2: Activator Protein 2; AP2BS: AP-2 binding site; bp: base pairs; ChIP: chromatin immunoprecipitation; EGFR: EGF Receptor; GCK: Glucokinase; GSH: Glutathion; GST: Glutathione Serine Transferase; Luc: Luciferase; MS: Mass Spectrometry; PAGE: Poly-Acrylamide Gel Electrophoresis; PBS: Phosphate Buffer Saline; Pol II: Polymerase II; RT: Room Temperature; siRNA: small interfering RNA.

Competing interests

The authors declare that they have no financial competing interests.

Authors' contributions

GN carried out all the studies and drafted the manuscript. JCP and BK helped in the studies and interpretation of the results. BE, WZ and EDP participated in the study design, revised the manuscript and provided important intellectual support. RW conceived of the study, participated in its design, coordination and interpretation of the results and finalized the manuscript. All authors read and approved the final manuscript.

Acknowledgements

We thank Dr Kannan, Dr Hendrickson and Dr. Chen for their gifts. We thank Dr. Gabriel Mazzucchelli for his help in Mass Spectrometry analyses. This work was supported by grants from Televie (Belgium), Anticancer Centre attached to the University of Liege (Belgium).

GN and JCP are recipients of Televie grants from the FNRS; BK is research fellow of the FNRS; BE and WZ are researchers financially supported by Région Wallonne, contract BA4 grant 114915, contract EPH331030000092-430001, EPH331030000022-130033, Fonds Social Européen contract W2002134, W1000346, contract 14531, iPCRq; EDP is professor at the University of Liege, director of the Mass Spectrometry Laboratory; RW is research director of the FNRS. Support is via FRSM Grant no. 3.4.542.04 and from the Centre anticancéreux at the University of Liège.
Estimates of the cancer incidence and mortality in Europe in 2006 Ferlay J Autier P Boniol M Heanue M Colombet M Boyle P Ann Oncol 2007 18 581 592 10.1093/annonc/mdl498 17287242 Gene expression patterns of breast carcinomas distinguish tumor subclasses with clinical implications Sorlie T Perou CM Tibshirani R Aas T Geisler S Johnsen H Hastie T Eisen MB Rijn van de M Jeffrey SS Thorsen T Quist H Matese JC Brown PO Botstein D Eystein LP Borresen-Dale AL Proc Natl Acad Sci USA 2001 98 10869 10874 58566 11553815 10.1073/pnas.191367098 Gene expression profiles do not consistently predict the clinical treatment response in locally advanced breast cancer Sorlie T Perou CM Fan C Geisler S Aas T Nobel A Anker G Akslen LA Botstein D Borresen-Dale AL Lonning PE Mol Cancer Ther 2006 5 2914 2918 10.1158/1535-7163.MCT-06-0126 17121939 HER2/neu role in breast cancer: from a prognostic foe to a predictive friend Ferretti G Felici A Papaldo P Fabi A Cognetti F Curr Opin Obstet Gynecol 2007 19 56 62 10.1097/GCO.0b013e328012980a 17218853 ERBB receptors and cancer: the complexity of targeted inhibitors Hynes NE Lane HA Nat Rev Cancer 2005 5 341 354 10.1038/nrc1609 15864276 The HER-2/neu Oncogene in Breast Cancer: Prognostic Factor, Predictive Factor, and Target for Therapy Ross JS Fletcher JA Oncologist 1998 3 237 252 10388110 Human breast cancer: correlation of relapse and survival with amplification of the HER-2/neu oncogene Slamon DJ Clark GM Wong SG Levin WJ Ullrich A McGuire WL Science 1987 235 177 182 10.1126/science.3798106 3798106 Expression of the c-erbB2 gene in the BT474 human mammary tumor cell line: measurement of c-erbB2 mRNA half-life Pasleau F Grooteclaes M Gol-Winkler R Oncogene 1993 8 849 854 8096075 Ets regulation of the erbB2 promoter Scott GK Chang CH Erny KM Xu F Fredericks WJ Rauscher FJ III Thor AD Benz CC Oncogene 2000 19 6490 6502 10.1038/sj.onc.1204041 11175365 Disruption of the Y-box binding protein-1 results in suppression of the epidermal growth factor receptor and HER-2 Wu J Lee C Yokom D Jiang H Cheang MC Yorida E Turbin D Berquin IM Mertens PR Iftner T Gilks CB Dunn SE Cancer Res 2006 66 4872 4879 10.1158/0008-5472.CAN-05-3561 16651443 The developmentally regulated transcription factor AP-2 is involved in c-erbB-2 overexpression in human mammary carcinoma Bosher JM Williams T Hurst HC Proc Natl Acad Sci USA 1995 92 744 747 42696 7846046 10.1073/pnas.92.3.744 A new cis element is involved in the HER2 gene overexpression in human breast cancer cells Grooteclaes M Vernimmen D Plaza S Pasleau F Hodzic D Winkler-Gol R Cancer Res 1999 59 2527 2531 10363966 Identification of HTF (HER2 transcription factor) as an AP-2 (activator protein-2) transcription factor and contribution of the HTF binding site to ERBB2 gene overexpression Vernimmen D Begon D Salvador C Gofflot S Grooteclaes M Winkler R Biochem J 2003 370 323 329 1223148 12418962 10.1042/BJ20021238 Distal ERBB2 promoter fragment displays specific transcriptional and nuclear binding activities in ERBB2 overexpressing breast cancer cells Delacroix L Begon D Chatel G Jackers P Winkler R DNA Cell Biol 2005 24 582 594 10.1089/dna.2005.24.582 16153159 A family of AP-2 proteins regulates c-erbB-2 expression in mammary carcinoma Bosher JM Totty NF Hsuan JJ Williams T Hurst HC Oncogene 1996 13 1701 1707 8895516 Activator protein-2 in carcinogenesis with a special reference to breast cancer--a mini review Pellikainen JM Kosma VM Int J Cancer 2007 120 2061 2067 10.1002/ijc.22648 17330235 N-ras oncogene causes AP-2 transcriptional self-interference, which leads to transformation Kannan P Buettner R Chiao PJ Yim SO Sarkiss M Tainsky MA Genes Dev 1994 8 1258 1269 10.1101/gad.8.11.1258 7926729 PolyADP-ribose polymerase is a coactivator for AP-2-mediated transcriptional activation Kannan P Yu Y Wankhade S Tainsky MA Nucleic Acids Res 1999 27 866 874 148259 9889285 10.1093/nar/27.3.866 Human CREB-binding protein/p300-interacting transactivator with ED-rich tail (CITED) 4, a new member of the CITED family, functions as a co-activator for transcription factor AP-2 Braganca J Swingler T Marques FI Jones T Eloranta JJ Hurst HC Shioda T Bhattacharya S J Biol Chem 2002 277 8559 8565 10.1074/jbc.M110850200 11744733 Yin Yang 1 cooperates with activator protein 2 to stimulate ERBB2 gene expression in mammary cancer cells Begon DY Delacroix L Vernimmen D Jackers P Winkler R J Biol Chem 2005 280 24428 24434 10.1074/jbc.M503790200 15870067 The combined immunodetection of AP-2alpha and YY1 transcription factors is associated with ERBB2 gene overexpression in primary breast tumors Allouche A Nolens G Tancredi A Delacroix L Mardaga J Fridman V Winkler R Boniver J Delvenne P Begon DY Breast Cancer Res 2008 10 R9 2374961 18218085 10.1186/bcr1851 Inefficient proteasomal-degradation pathway stabilizes AP-2alpha and activates HER-2/neu gene in breast cancer Li M Wang Y Hung MC Kannan P Int J Cancer 2006 118 802 811 10.1002/ijc.21426 16108032 Ku, a DNA repair protein with multiple cellular functions? Featherstone C Jackson SP Mutat Res 1999 434 3 15 10377944 The biology of Ku and its potential oncogenic role in cancer Gullo C Au M Feng G Teoh G Biochim Biophys Acta 2006 1765 223 234 16480833 Ku86 is essential in human somatic cells Li G Nelsen C Hendrickson EA Proc Natl Acad Sci USA 2002 99 832 837 117391 11792868 Analysis of the DNA replication competence of the xrs-5 mutant cells defective in Ku86 Matheos D Novac O Price GB Zannis-Hadjopoulos M J Cell Sci 2003 116 111 124 10.1242/jcs.00156 12456721 DNA-dependent protein kinase (DNA-PK) phosphorylates nuclear DNA helicase II/RNA helicase A and hnRNP proteins in an RNA-dependent manner Zhang S Schlott B Gorlach M Grosse F Nucleic Acids Res 2004 32 1 10 373260 14704337 10.1093/nar/gkg933 An alternatively spliced mRNA from the AP-2 gene encodes a negative regulator of transcriptional activation by AP-2 Buettner R Kannan P Imhof A Bauer R Yim SO Glockshuber R Van Dyke MW Tainsky MA Mol Cell Biol 1993 13 4174 4185 359967 8321221 Transcriptional activation by Myc is under negative control by the transcription factor AP-2 Gaubatz S Imhof A Dosch R Werner O Mitchell P Buettner R Eilers M EMBO J 1995 14 1508 1519 398238 7729426 ZIC2-dependent transcriptional regulation is mediated by DNA-dependent protein kinase, poly(ADP-ribose) polymerase, and RNA helicase A Ishiguro A Ideta M Mikoshiba K Chen DJ Aruga J J Biol Chem 2007 282 9983 9995 10.1074/jbc.M610821200 17251188 Proteomics in Myzus persicae: effect of aphid host plant switch Francis F Gerkens P Harmel N Mazzucchelli G De Pauw PE Haubruge E Insect Biochem Mol Biol 2006 36 219 227 10.1016/j.ibmb.2006.01.018 16503483 Zoledronic acid up-regulates bone sialoprotein expression in osteoblastic cells through Rho GTPase inhibition Chaplet M Detry C Deroanne C Fisher LW Castronovo V Bellahcene A Biochem J 2004 384 591 598 1134145 15324309 10.1042/BJ20040380 A rapid micro chromatin immunoprecipitation assay (microChIP) Dahl JA Collas P Nat Protoc 2008 3 1032 1045 10.1038/nprot.2008.68 18536650 Protein-protein interaction assays: eliminating false positive interactions Nguyen TN Goodrich JA Nat Methods 2006 3 135 139 2730730 16432524 10.1038/nmeth0206-135 Transient depletion of Ku70 and Xrcc4 by RNAi as a means to manipulate the non-homologous end-joining pathway Bertolini LR Bertolini M Anderson GB Maga EA Madden KR Murray JD J Biotechnol 2007 128 246 257 10.1016/j.jbiotec.2006.10.003 17097754 Ku is a novel transcriptional recycling coactivator of the androgen receptor in prostate cancer cells Mayeur GL Kung WJ Martinez A Izumiya C Chen DJ Kung HJ J Biol Chem 2005 280 10827 10833 10.1074/jbc.M413336200 15640154 Subnuclear localization of Ku protein: functional association with RNA polymerase II elongation sites Mo X Dynan WS Mol Cell Biol 2002 22 8088 8099 134733 12391174 10.1128/MCB.22.22.8088-8099.2002 The E-box of the human glycophorin B promoter is involved in the erythroid-specific expression of the GPB gene Camara-Clayette V Rahuel C Bertrand O Cartron JP Biochem Biophys Res Commun 1999 265 170 176 10.1006/bbrc.1999.1634 10548509 Expression of apolipoprotein C-IV is regulated by Ku antigen/peroxisome proliferator-activated receptor gamma complex and correlates with liver steatosis Kim E Li K Lieu C Tong S Kawai S Fukutomi T Zhou Y Wands J Li J J Hepatol 2008 49 787 798 2644636 18809223 10.1016/j.jhep.2008.06.029 Ku autoantigen (DNA helicase) is required for interleukins-13/-4-induction of 15-lipoxygenase-1 gene expression in human epithelial cells Kelavkar UP Wang S Badr KF Genes Immun 2000 1 237 250 10.1038/sj.gene.6363665 11196700 Purification and identification of positive regulators binding to a novel element in the c-Jun promoter Jiang D Zhou Y Moxley RA Jarrett HW Biochemistry 2008 47 9318 9334 10.1021/bi800285q 18690718 Positive and negative modulation of the transcriptional activity of the ETS factor ESE-1 through interaction with p300, CREB-binding protein, and Ku 70/86 Wang H Fang R Cho JY Libermann TA Oettgen P J Biol Chem 2004 279 25241 25250 10.1074/jbc.M401356200 15075319 Distinct roles for Ku protein in transcriptional reinitiation and DNA repair Woodard RL Lee KJ Huang J Dynan WS J Biol Chem 2001 276 15423 15433 10.1074/jbc.M010752200 11278739 Ku70 and poly(ADP-ribose) polymerase-1 competitively regulate beta-catenin and T-cell factor-4-mediated gene transactivation: possible linkage of DNA damage recognition and Wnt signaling Idogawa M Masutani M Shitashige M Honda K Tokino T Shinomura Y Imai K Hirohashi S Yamada T Cancer Res 2007 67 911 918 10.1158/0008-5472.CAN-06-2360 17283121 Identification of poly(ADP-ribose)polymerase-1 and Ku70/Ku80 as transcriptional regulators of S100A9 gene expression Grote J Konig S Ackermann D Sopalla C Benedyk M Los M Kerkhoff C BMC Mol Biol 2006 7 48 1766928 17187679 10.1186/1471-2199-7-48 The Ku protein complex interacts with YY1, is up-regulated in human heart failure, and represses alpha myosin heavy-chain gene expression Sucharov CC Helmke SM Langer SJ Perryman MB Bristow M Leinwand L Mol Cell Biol 2004 24 8705 8715 516749 15367688 10.1128/MCB.24.19.8705-8715.2004