Main

Nine inherited neurodegenerative disorders with expanded polyglutamine (polyQ) are caused by mutations in different genes, but they likely share the common pathology in which expanded polyQ gains toxic functions.1 The molecular mechanism of neuronal toxicity of polyQ remains enigmatic. Recent findings suggest that the intracellular aggregation of polyQ causes cellular stress responses that trigger neuronal cell death.1 It is hypothesized that polyQ aggregation suppresses neuronal transcriptional activity by sequestering histone acetyltransferases (HAT) from chromosomes and thus polyQ causes neuronal cell death.2, 3, 4

Bax is a proapoptotic member of Bcl-2 family proteins that plays a key role in programmed cell death in neurons.5, 6 Recently, mutant huntingtin with expanded polyQ was shown to activate p53 and increase the expression level of Bax.7 Based on these previous findings, we became interested in examining the role of Bax in polyQ-induced cell death. Recently, we developed a series of cytoprotective membrane-permeable pentapeptides that rescue cells from Bax-mediated cell death. These peptides are named Bax-inhibiting peptides (BIPs) and were designed from the Bax binding domain of Ku70.8, 9, 10 Ku70 is a multifunctional protein playing roles in DNA repair and cell survival.11 Ku70 has been shown to inhibit Bax-mediated cell death by binding Bax in the cytosol.12, 13, 14 The present study demonstrates that BIP can rescue cells from polyQ toxicity, and that polyQ promotes Bax-mediated cell death by inducing Ku70 acetylation that activates Bax.

Results

BIP suppresses Q79C-induced cell death

BIPs consisting of five amino acids (e.g. VPMLK and VPTLK) were used in this study. A mutated peptide (i.e. IPMIK) that does not bind Bax but retains cell permeability was also used in this study as a negative control (NC). For the investigation of polyQ toxicity, we used the C-terminal, truncated fragment of the Machado–Joseph disease 1 (MJD1) gene product, ataxin-3, which includes an expanded polyQ stretch (79 glutamine repeats, Q79C).15, 16 As a negative control, ataxin-3 C-terminus with 22 or 35 glutamine repeats (Q22C and Q35C, respectively) was used.15, 16 BIP readily suppressed Q79C-induced cell death in a neuroblastoma cell line (Neuro-2a) (Figure 1a and b) and in a human embryonic kidney cell line (HEK293T) (Figure 2a). Although these cell lines incorporated BIP very efficiently,9 the primary cultured rat cortical neurons showed very low uptake of BIP. To study whether BIP can suppress polyQ-induced cell death in primary cortical neurons, we utilized the protein transduction domain of the human immunodeficiency virus (HIV) trans-activator (TAT)17 to enhance cell permeability of BIP. PolyQ was expressed by an adenovirus vector.16 We confirmed that TAT-BIP efficiently entered primary cortical neurons (Supplementary Figure 1), and it inhibited polyQ-induced cell death in these cells (Figure 1c). To confirm the role of Bax in polyQ-induced cell death, we employed small interference RNA (siRNA) targeting Bax mRNA (Figure 1d). The siRNA significantly inhibited Q79C-induced cell death (Figure 1e). Furthermore, we examined the cytotoxicity of polyQ in a Bax-deficient cell line, DU145 (human prostate cancer cell line).18 Q79C did not show significant toxicity in DU145 cells, although Q79C induced cell death if Bax expression was restored (Figure 1f). These results suggest that Bax is a key mediator of Q79C-induced cell death.

Figure 1
figure 1

BIP suppresses Q79C-induced cell death. (a and b) Neuro-2a cells in 24-well plates were transfected with pCMX HA-Q22C (0.5 μg), pCMX HA-Q79C (0.5 μg) or pcDNA3 (0.5 μg) in the presence of 200 μM VPTLK (BIP) or negative control peptide (IPMIK; NC). Cell death was analyzed by Trypan blue exclusion (a) or LDH release into the medium (b) at both 24 and 48 h after transfection; ***P<0.001. (c) Primary cortical neurons in 24-well plates were infected with Ad-Q79C or Ad-Q35C at m.o.i. 100 in the presence of 80 μM TAT-VPTLK (TAT-BIP) or negative control peptide (TAT-IPMIK; TAT-NC). Cell death was analyzed by MTT assay at 24, 48, 72 and 96 h after treatment. The relative number of surviving cells was determined in triplicate by estimating the value of unstimulated or uninfected cells as 100%; *P<0.05. (d and e) The Bax siRNA suppresses Q79C toxicity. HEK293T cells in 24-well plates were transfected with pCMX HA-Q79C (0.5 μg) and 100 nM of control siRNA or Bax siRNA. The suppression of endogenous Bax expression by Bax siRNA was confirmed by Western blotting (d). The effect of Bax siRNA on Q79C-induced cell death is shown (e). (f) DU145 cells (Bax-deficient cells) in six-well plates were transfected with pcDNA3 (1 μg), pCMX HA-Q79C (1 μg) or pcDNA3-Bax (0.25 μg), and were cultured in the presence or absence of 200 μM VPMLK (BIP) or negative control peptide (IPMIK; NC). Cell death was analyzed by Trypan blue exclusion at 48 h after transfection

Figure 2
figure 2

BIP suppresses both caspase-dependent and -independent cell death induced by Q79C. (ac) HEK293T (a) or Neuro-2a cells (b and c) in 24-well plates were transfected with pCMX HA-Q22C (0.5 μg) or pCMX HA-Q79C (0.5 μg) in the presence of 200 μM VPMLK (BIP) or 100 μM of caspase inhibitor (z-VAD-fmk). At 48 h after transfection, cell death was determined by Trypan blue exclusion (a and b), and apoptotic events were evaluated by caspase 3 activity (c) *P<0.05 or ***P<0.001. (d and e) Neuro-2a cells in 24-well plates were transfected with pCMX HA-Q22C (0.5 μg) or pCMX HA-Q79C (0.5 μg) in the presence of 200 μM VPMLK (BIP) or 100 μM of caspase inhibitor (z-VAD-fmk). At 48 h after transfection, cell death was determined by double staining with Hoechst (d, upper panel). PI (d, middle panel) and normal light field image (d, lower panel). The percentages of apoptotic cells with nuclear condensation and fragmentation and dead cells detected by PI staining (membrane integrity loss) are presented. Results are shown as mean±S.E. of triplicated samples

BIP suppresses Q79C-induced nuclear fragmentation and cytoplasmic vacuolation

Next, we examined the effect of a pan-caspase inhibitor on Q79C-induced cell death, because Bax activates the caspases resulting in apoptosis.6 Unexpectedly, the pan-caspase inhibitor, z-VAD-fmk, did not show a significant cytoprotective effect against Q79C toxicity when cellular viability was examined by Trypan blue exclusion (Figure 2a and b) and lactate dehydrogenase (LDH) release from the cells into the medium (data not shown). To further determine the role of caspase in Q79C-induced cell death, we examined the increase in caspase activity and the occurrence of nuclear fragmentation. We found that Q79C induced caspase activation (Figure 2c) and nuclear fragmentation (Figure 2d and e), both of which could be attenuated by both inhibitors of Bax (BIP) and of caspases (z-VAD-fmk). Of note, the number of apoptotic cells detected by the presence of nuclear fragmentation (Figure 2d and e) was less than the net number of dead cells detected by staining of Trypan blue (Figure 2b) and propidium iodide (PI) (Figure 2d and e), suggesting that Q79C activates both caspase-dependent and -independent cell death pathways.

PolyQ-induced cell death is associated with an increased number of enlarged vacuoles.19, 20, 21 We also found that Neuro-2a cells with Q79C expression showed marked cytoplasmic vacuolation. BIP suppressed cytoplasmic vacuolation (Figure 3a and b), whereas the caspase inhibitor did not. These results suggest that Q79C-induced vacuolation is Bax-dependent and caspase-independent. Collectively, BIP suppressed both caspase-dependent nuclear fragmentation and caspase-independent cytoplasmic vacuolation elicited by polyQ.

Figure 3
figure 3

BIP suppresses Q79C-induced cytoplasmic vacuolation. Neuro-2a cells were transfected with pCMX HA-Q22C (0.5 μg) or pCMX HA-Q79C (0.5 μg) in the presence of 200 μM VPTLK (BIP) or 100 μM z-VAD-fmk. (a) At 48 h after transfection, the percent of cells with cytoplasmic vacuolation to all living cells were evaluated under optical microscopy ( × 400); (b) ***P<0.001

Q79C expression induces Ku70 acetylation that releases Bax from Ku70

Because BIP is designed from Ku70 which prevents Bax-mediated cell death,8, 9, 10 we examined whether Q79C had any influence on the binding between Ku70 and Bax. Q79C significantly decreased the interaction between Bax and Ku70 (Figure 4a and b). Furthermore, we found that Q79C induced significant acetylation of Ku70 (Figure 4c). To be noted, the acetylation of Ku70 is known to dissociate Bax and Ku70.12 Two lysine (K) residues in Ku70, K539 and K542, are critical acetylation sites that influence Ku70-Bax binding.12 To test whether Ku70 acetylation plays a role for the activation of Bax by polyQ, we generated acetylation-resistant mutants of Ku70 and acetylation-mimicking mutants of Ku70 by substituting K539 and K542 with arginine (R) or glutamine (Q), respectively. Acetylation-resistant Ku70 mutants (K539R and K542R)12 suppressed Q79C-induced cell death more efficiently than wild-type Ku70 (Figure 4d). In contrast, the acetylation-mimicking Ku70 mutants (K539Q and K542Q),12 could not suppress Q79C-induced cell death. The expression of these Ku70 mutants alone did not affect the cell viability. These results support the hypothesis that Q79C expression activates Bax, at least in part, through Ku70 acetylation.

Figure 4
figure 4

Q79C expression induces Ku70 acetylation that releases Bax from Ku70. (a and b) HEK293T cells in 10-cm dishes were transfected with pcDNA3 (10 μg) or pCMX HA-Q79C (10 μg). At 48 h after transfection, cells were harvested and immunoprecipitation was performed using anti-Bax (a) and anti-Ku70 monoclonal antibodies (b). Normal mouse IgG (IgG) was used as a negative control. Western blotting was performed with anti-Ku70 (a) or anti-Bax polyclonal (b) antibody. (c) HEK293T cells in 10-cm dishes were transfected with pcDNA3 (10 μg) or pCMX HA-Q79C (10 μg). After 48 h, cells were harvested and immunoprecipitation was performed using anti-pan-acetyl-lysine monoclonal antibody, and the acetylated Ku70 was detected by Western blotting with anti-Ku70 polyclonal antibody. (d) Neuro-2a cells in 24-well plates were co-transfected with pCMX HA-Q79C/Q22C (0.5 μg) and pcDNA3 (0.1 μg or 0.5 μg), wild-type Ku70 (0.1 μg or 0.5 μg) or Ku70 mutants (0.1 μg or 0.5 μg) bearing K → R (acetylation-resistant mutation) or K → Q substitutions (mutation that mimics acetylation) at positions K539 and K542. Cell death was analyzed by Trypan blue exclusion (d) at 48 h after transfection; ***P<0.001 or *P<0.05

Ku70 and BIP inhibit Bax conformational change induced by polyQ expression

In cells with apoptotic stimuli, Bax is known to change its conformation, and the conformational change can be detected using the 6A7 anti-Bax monoclonal antibody that recognizes the N-terminus of Bax by immunoprecipitation.22, 23 The N-terminus exposure is an early step of Bax activation that occurs in the cytosol, and this conformational change is considered a prerequisite for membrane insertion of Bax at mitochondria and multimerization of Bax.22, 23, 24 We found that Ku70 wild type and acetylation-resistant Ku70 (Ku70(K539R)), but not acetylation-mimicking Ku70 mutant (Ku70(K539Q)), inhibited the conformational change that was induced by polyQ expression (Figure 5a and b). It was also confirmed that BIP treatment significantly blocked Bax conformational change (Figure 5c). These results further support our hypothesis that Ku70 as well as BIP protect cells from polyQ toxicity by inhibiting Bax-mediated cell death.

Figure 5
figure 5

Ku70 and BIP inhibit Bax conformational change induced by polyQ expression. (a and b) Ku70 inhibits conformational change of Bax induced by Q79C. Neuro2a cells in 10-cm dishes were transfected with pcDNA3 (5 μg) or pCMX HA-Q79C (5 μg) together with pCMV-2B-Ku70 (5 μg), K539Q (acetylation-mimicking mutant) (5 μg) or K539R (acetylation-resistant mutant). After 48 h, cells were harvested and immunoprecipitation was performed using 6A7 anti-Bax monoclonal antibody. (c) HEK293T cells in 10-cm dishes were transfected with pcDNA3 (10 μg) or pCMX HA-Q79C (10 μg) in the presence or absence of 200 μM VPMLK (BIP). After 48 h, cells were harvested and immunoprecipitation was performed using 6A7 anti-Bax monoclonal antibody

Q79C binds Ku70 and histone acetyl transferase

Next, we examined how Q79C expression results in the acetylation of Ku70. The cyclic-AMP response element-binding protein (CBP) has been shown to acetylate cytosolic Ku70 in response to apoptotic stimuli.12 Q79C is known to bind CBP in the nucleus.4 We found that this interaction occurs in the cytosol too. We performed co-immunoprecipitation of polyQ and CBP using the cytosolic fraction and found that CBP was co-immunoprecipitated with Q79C, but not with Q22C (Figure 6a). In addition, we found that Ku70 binds both Q79C and Q22C in the cytosolic fraction (Figure 6b). We further confirmed the interaction of Q79C and CBP in the cytosol fraction (Figure 6c). These results suggest that Q79C stimulates Ku70 acetylation by bridging Ku70 and CBP (Figure 6d).

Figure 6
figure 6

Q79C binds Ku70 and CBP. (ac) HEK293T cells were transfected as described in Figure 4a and b, and the cytosolic fraction was used for immunoprecipitation. Immunoprecipitation was performed using anti-HA (a and b) or anti-Ku70 monoclonal antibody (c). Western blotting analyses of HA-tagged polyQ (Q22C and Q79C), CBP and Ku70 are shown. (d) Schematic representation of Bax activation by Ku70 acetylation during Q79C-induced cell death

SIRT1 deacetylase and resveratrol rescue Q79C-induced cell death

The significant role of Ku70 acetylation in Q79C-induced cell death implies the possibility that the stimulation of deacetylases could reduce the polyQ toxicity. First, we examined the effect of the SIRT1 deacetylase, which has been demonstrated to deacetylate Ku70.12 Overexpression of SIRT1 suppressed Q79C-induced cell death in Neuro-2a cells (Figure 7a and b). Small polyphenolic molecules such as resveratrol have been found to increase the affinity of SIRT1 and its target proteins.25 We found that resveratrol markedly suppressed the cell death induced by Q79C in the HEK293T cells and primary cortical neurons (Figure 7c–e). We confirmed that SIRT1expression and resveratrol treatment reduced the acetylation levels of Ku70 that was increased by Q79C expression (Figure 7f).

Figure 7
figure 7

Effects of SIRT1 and resveratrol on Q79C-induced cell death. Neuro-2a cells in 24-well plates were co-transfected with pCMX HA-Q79C or -Q22C (0.5 μg) and pcDNA3 (0.5 μg), or pcDNA3-SIRT1 (0.5 μg). Cell death was analyzed by Trypan blue exclusion (a) or LDH release into the medium (b) at 48 h after transfection; *P<0.05. HEK293T cells in 24-well plates were transfected with pCMX HA-Q79C (0.5 μg) or pCMX HA-Q22C (0.5 μg) in the presence of resveratrol (1 μM). Cell death was assessed by Trypan blue exclusion (c) or LDH release into the medium (d) at 72 h after transfection; **P<0.01 or *P<0.05. (e) Primary cortical neurons in 24-well plates were infected with Ad-Q79C or Ad-Q35C at m.o.i. 100 in the presence of resveratrol (1 μM). Cell death was analyzed by MTT assay at 24, 48, 72 and 96 h after treatment. The relative number of surviving cells was determined in triplicate by estimating the value of unstimulated or uninfected cells as 100%; ***P<0.001 or *P<0.05. (f) HEK293T cells in 10-cm dishes were transfected with pCMX HA-Q79C (5 μg) and pcDNA3-SIRT1 (5 μg), or with pCMX HA-Q79C (5 μg) in the presence of resveratrol (1 μM). After 48 h, cells were harvested and immunoprecipitation was performed using anti-pan-acetyl-lysine monoclonal antibody. The acetylated Ku70 was detected by Western blotting with anti-Ku70 polyclonal antibody

Discussion

We demonstrated that the inhibition of Bax by Ku70 and BIP markedly protected cells from polyQ toxicity. These results indicate that Bax plays a key role in polyQ toxicity. Our data also suggest that polyQ expression activates two different pathways of cell death. One is caspase-dependent cell death associated with nuclear fragmentation, and the other is caspase-independent cell death associated with cytoplasmic vacuolation, both of which were dramatically decreased by BIP. Cytoplasmic vacuolation has been observed in the neurons of patients with polyQ diseases.19, 20, 21 Importantly, Bax is known to induce both caspase-independent and -dependent cell death with cytoplasmic vacuolation when caspase activity is inhibited or absent.26, 27, 28 These previous reports support our hypothesis that Bax is a key mediator of Q79C-induced cell death associated with cytoplasmic vacuolation. Recently, an elevated expression of Bax was reported in the brain of polyQ-transgenic mouse.29, 30 We also observed that the number of pontine nucleus and microglia stained by anti-Bax 6A7-Ab in the brain section of MJD patient was significantly higher than those of normal controls (Supplementary Figure 3). Although this result is consistent with our findings in cell culture system, there are potential limitations of such experiments using human tissue, as the conditions and timing of specimen collection cannot be strictly controlled. Further extensive investigation is needed to determine the role of Bax in MJD pathogenesis in patient brain.

The significant ability of BIP to suppress Q79C-induced cell death suggests the possibility that Q79C expression causes dissociation of Ku70 from Bax. Previously, we reported that apoptotic stimuli decreased cytosolic levels of Ku70, and that this change may be one of the mechanisms for Ku70 dissociation from Bax.31 However, in the case of Q79C expression, the decrease of Ku70 levels was not clear (Figure 4a and c, Ku70 input). The acetylation of Ku70 is known to be another mechanism releasing Bax from Ku70.12 As shown in Figure 4, Q79C induced a significant acetylation of Ku70. We also confirmed that Ku70 mutants mimicking acetylation did not suppress Q79C-induced cell death, whereas acetylation-resistant Ku70 mutants rescued cells from Q79C toxicity more efficiently than Ku70 wild type. These results suggest that Ku70 acetylation is one of the major causes of Bax activation in Q79C-expressing cells.

SIRT1, one of the mammalian silent information regulator 2 (Sir2) homologues, was identified as a cell survival factor that protects cells from DNA damage.32 SIRT1 was shown to have the activity to deacetylate several transcription factors, and through this activity, SIRT1 regulates a wide array of cellular processes for cell defense and survival under various stress conditions (reviewed by Baur and Sinclair25). Recently, resveratrol, an activator of the Sir2 histone deacetylase (HDAC),25 has been reported to rescue polyQ-induced neuronal dysfunction in Caenorhabditis elegans.33 Similarly, in the present study, SIRT1 deacetylase and resveratrol both effectively rescued cultured cells from polyQ toxicity. We confirmed that Ku70 was acetylated by Q79C and that Ku70 was deacetylated by resveratrol and SIRT1. These observations support our hypothesis that Ku70 acetylation plays an important role in Q79C-induced cell death.

It has been hypothesized that polyQ toxicity is caused by decreased histone acetylation, as polyQ sequesters histone acetyl transferase (HAT) (e.g. CBP) from chromosomes.2, 3 The subsequent suppression of histone acetylation decreases cellular transcriptional activities, and these changes are implicated to cause polyQ toxicity. Based on this hypothesis, the maintenance of histone acetylation by HDAC inhibitors, such as trichostatin A (TSA), has been examined for the reduction of polyQ toxicity.3, 34, 35 However, an HDAC inhibitor was recently shown to induce apoptosis in neuroblastoma cells by increasing Ku70 acetylation and promoting Bax-mediated cell death.14 Therefore, it is plausible that HDAC inhibitors have a ‘double-edge’ activity in the context of polyQ toxicity; they attenuate polyQ toxicity by maintaining histone acetylation in the nucleus, but promote Bax-mediated cell death by acetylating Ku70 in the cytosol. In cultured cells, TSA can attenuate Q79C-induced cell death only at the lower doses (3–10 nM), whereas it enhances cell death at the higher doses (more than 20 nM) (Supplementary Figure 2). Actually, the therapeutic effect of an HDAC inhibitor was observed only within a narrow range of lower doses, and the effect changed to be toxic at higher doses in polyQ transgenic mice.35 These results suggest that the use of HDAC inhibitors in polyQ diseases requires careful consideration to avoid causing a lethal degree of Ku70 acetylation. The present study focused on the toxicity of expanded polyQ derived from the causative gene (mutated ataxin3) of MJD. Thus, further study is needed to examine whether our observation can be generally confirmed in other types of toxic polyQ such as that of Huntington's disease and spinocerebellar ataxia type 1 (SCA1).

In conclusion, we propose that Bax is a key mediator of Q79C-induced cell death and that Bax activation is mediated through acetylation of Ku70, which dissociates Bax from Ku70. Our hypothesis is based on the observation in cell culture studies, and further extensive studies using in vivo models are clearly needed. The present study suggests that the inhibition of Bax by BIPs or Ku70 may provide a new strategy to develop therapeutics for MJD.

Materials and Methods

Plasmid constructs and recombinant adenoviruses

The expression plasmids of ataxin-3 were kindly given Dr. Akira Kakizuka. The MJD1 cDNA in the plasmid was a truncated fragment including either 22 (normal, pCMX HA-Q22C) or 79 (expanded, pCMX HA-Q79C) repeats of CAG, and was hemagglutinin (HA)-fused on the N-terminus. The plasmids, pcDNA3-Bax and pCMV 2B-Flag-Ku70 have been described previously.12 pCMV 2B-Flag-Ku70 K539R/K542R/K539Q/K542Q were generated by QuickChange Site-Directed Mutagenesis Kit from Stratagene. SIRT1 expression plasmid was generated by subcloning the coding sequence of SIRT1 cDNA (kindly provided by Dr. Shinichirou Imai) into the pcDNA3 vector (Invitrogen). Recombinant adenoviruses encoding Flag-Q79C and Flag-Q35C were constructed as described previously.36

Cell culture and transfection

HEK293T, Neuro-2a and DU145 cells were cultured in DMEM containing 10% fetal bovine serum. Transfection of plasmids was performed with Lipofectamine Plus reagent (Invitrogen) in accordance with the manufacturer's instructions. For cell death analysis with HEK293T and Neuro-2a cells, transfection efficiency was monitored with co-transfected 50 ng of pEGFP-C2 (Clontech), and confirmed that the efficiency was more than 75% before analysis.

Rat primary cortical neurons

Cortices were dissected from E-18 Sprague-Dawley rats' brains. Rat cortical neurons were plated into poly-D-lysine-coated 24-well plates. Mixed cultures were maintained in neurobasal medium. After 72 h of culture, 10 mM of cytosine arabinoside (Ara-C) was added to stop the proliferation of glial cells. After 72 h of Ara-C-treated, medium was replaced with fresh neurobasal medium.

Cell death assays

Cell death was assessed by Trypan blue exclusion, PI exclusion, LDH relase, Hoechst dye nuclear staining, MTT assay and caspase activity measurement.

For Trypan blue exclusion test, cells were collected and centrifuged for 10 min at 1000 r.p.m. The cell pellet was resuspended in 50 μl of DMEM, to which 50 μl of Trypan blue (0.4%) was added. Dead cells were counted by three independent hemocytometer counts.

LDH release from the cells into the medium was analyzed by the Cytotox 96 nonradioactive cytotoxicity assay (Promega). Cell viability of primary cortical neurons was determined by MTT assay (Chemicon) and LDH release into the medium. Nuclear condensation and membrane integrity loss were monitored by observing cells under a fluorescence microscope after application of 1 μg/ml Hoechst dye 33258 and 4 μg/ml PI. Caspase 3 activities of cells were measured with Caspase 3 Assay Kit (Sigma) in accordance with the manufacturer's instructions. For each experiment, data were obtained from three wells.

Statistical analyses for cell death were performed using the student's t-test and single-factor ANOVA, followed by Fisher's protected least-significant difference post hoc test. The results were confirmed in more than three independent experiments of all cell death analysis and Western blottings.

siRNA preparation

Sense and antisense strands of siRNA oligonucleotides were synthesized, and were then annealed at 95°C for 1 min. The sense sequence of siRNA-Bax is 5′-CCAAGAAGCUGAGCGAGUGdTdT-3′ and the sequence of control siRNA is 5′-GGUCUCGUAGACCGUGCACdTdT-3′.

Immunoprecipitation

For detecting the active form of Bax (Figure 5a–c), transfected HEK293T cells in 10-cm dishes were lysed in 200 μl Chaps buffer (150 mM NaCl, 10 mM HEPES at pH 7.4 and 1.0% Chaps) containing the protease inhibitors (1 : 100 dilution of protease inhibitor Cocktail; Sigma), according to the previously reported methods.22 After pre-clearing 200 μl of the sample with 20 μl protein A-sepharose (CL-4B, 17-0780-01; Amersham Biosciences) at 4°C for 1 h, immunoprecipitation was performed by incubating 200 μl of the lysates with 2 μg of anti-Bax monoclonal antibody (clone 6A7, BD-Pharmingen) at 4°C for 2 h. Immunocomplexes in 200 μl of the lysates were precipitated with 20 μl protein A-sepharose. After extensive washing with buffer, beads were boiled in 40 μl Laemmli buffer, and 20 μl of the eluted proteins were analyzed by Western blotting. Western blotting analysis of pre-immunoprecipitation (input) and immunoprecipitated samples (IP) were performed with an anti-Bax polyclonal antibody (N-20, sc-493; Santa Cruz).

For detecting Bax-Ku70 interactions (Figure 4a and b), transfected HEK293T cells in 10-cm dishes were lysed in 200 μl Chaps buffer containing the protease inhibitors. After pre-clearing 200 μl of the sample with 20 μl protein G-sepharose (4 Fast Flow, 17-0618-01; Amersham Biosciences) at 4°C for 1 h, immunoprecipitation was performed by incubating 200 μl of the lysates with 2 μg of monoclonal anti-Bax antibody (B9, Santa Cruz) or 2 μg of monoclonal anti-Ku70 antibody (A9, Santa Cruz) at 4°C for 2 h. Immunocomplexes in 200 μl of the lysates were precipitated with 20 μL protein G-sepharose. After extensive washing with buffer, beads were boiled in 40 μl Laemmli buffer, and 20 μl of the eluted proteins were analyzed by Western blotting. Mouse IgG was used as negative control. Western blotting analysis of pre-immunoprecipitation (input) and immunoprecipitated samples (α-Bax or α-Ku70) were performed with an anti-Ku70 polyclonal antibody (H-308, sc-9033; Santa Cruz) or an anti-Bax polyclonal antibody (N-20, sc-493; Santa Cruz).

For detecting the acetylated form of Ku70 (Figures 4c and 7f), transfected HEK293T cells in 10-cm dishes were lysed in 200 μl 1% triton in phosphate-buffered saline containing the protease inhibitors and 5 μM TSA (Sigma).12 After pre-clearing 200 μl of the sample with 20 μl protein G-sepharose at 4°C for 1 h, immunoprecipitation was performed by incubating 200 μl of the lysates with 4 μg of anti-pan-acetyl-lysine monoclonal antibody (9681S; Cell Signaling) at 4°C for 2 h. Immunocomplexes in 200 μl of the lysates were precipitated with 20 μl protein G-sepharose. After extensive washing with buffer, beads were boiled in 40 μl Laemmli buffer, and 20 μl of the eluted proteins were analyzed by Western blotting. Mouse IgG was used as negative control. Western blotting analysis of pre-immunoprecipitation (input) and immunoprecipitated samples (α-Ac-K) were performed with an anti-Ku70 polyclonal antibody (H-308, sc-9033; Santa Cruz).

For detecting the interactions of HA-polyQ (Q79C) and CBP or Ku70, Ku70 and CBP (Figure 6a–c), transfected HEK293T cells in 10-cm dishes were homogenized with 350 μl of ice-cold homogenization buffer (250 mM sucrose, 20 mM HEPES at pH 8.0, 10 mM KCl, 1.5 mM MgCl2, 1 mM EDTA, 1 mM EGTA, pH 7.5 and 0.1 mM PMSF) containing the protease inhibitors. The cytosolic fraction was prepared by collecting the supernatant of the centrifuged homogenate samples at 14 000 r.p.m. for 30 min at 4°C. Immunoprecipitation was performed by incubating 300 μl of the lysates with 40 μl of anti-HA antibody-conjugated beads (HA-7, A2095; Sigma) or with 2 μg anti-Ku70 monoclonal antibody (A-9, sc-5309; Santa Cruz) at 4°C for 2 h. Immunocomplexes of anti-Ku70 monoclonal antibody in 200 μl of the lysates were precipitated with 20 μl protein G-sepharose beads (4 Fast Flow, 17-0618-01; Amersham Biosciences). After extensive washing with buffer, beads were boiled in 40 μl Laemmli buffer, and 20 μl of the eluted proteins were analyzed by Western blotting. Western blotting analysis of pre-immunoprecipitation (input) and immunoprecipitated samples (IP) were performed with an anti-HA polyclonal antibody (HA-7, H9658; Sigma), anti-CBP polyclonal antibody (C-20, sc-583; Santa Cruz) or anti-Ku70 polyclonal antibody (H-308, sc-9033; Santa Cruz).