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Erschienen in: BMC Cancer 1/2014

Open Access 01.12.2014 | Research article

BIMELis a key effector molecule in oxidative stress-mediated apoptosis in acute myeloid leukemia cells when combined with arsenic trioxide and buthionine sulfoximine

verfasst von: Yukie Tanaka, Takayuki Komatsu, Hiroko Shigemi, Takahiro Yamauchi, Yutaka Fujii

Erschienen in: BMC Cancer | Ausgabe 1/2014

Abstracts

Background

Arsenic trioxide (ATO) is reported to be an effective therapeutic agent in acute promyelocytic leukemia (APL) through inducing apoptotic cell death. Buthionine sulfoximine (BSO), an oxidative stress pathway modulator, is suggested as a potential combination therapy for ATO-insensitive leukemia. However, the precise mechanism of BSO-mediated augmentation of ATO-induced apoptosis is not fully understood. In this study we compared the difference in cell death of HL60 leukemia cells treated with ATO/BSO and ATO alone, and investigated the detailed molecular mechanism of BSO-mediated augmentation of ATO-induced cell death.

Methods

HL60 APL cells were used for the study. The activation and expression of a series of signal molecules were analyzed with immunoprecipitation and immunoblotting. Apoptotic cell death was detected with caspases and poly (ADP-ribose) polymerase activation. Generation of intracellular reactive oxygen species (ROS) was determined using a redox-sensitive dye. Mitochondrial outer membrane permeabilization was observed with a confocal microscopy using NIR dye and cytochrome c release was determined with immunoblotting. Small interfering (si) RNA was used for inhibition of gene expression.

Results

HL60 cells became more susceptible to ATO in the presence of BSO. ATO/BSO-induced mitochondrial injury was accompanied by reduced mitochondrial outer membrane permeabilization, cytochrome c release and caspase activation. ATO/BSO-induced mitochondrial injury was inhibited by antioxidants. Addition of BSO induced phosphorylation of the pro-apoptotic BCL2 protein, BIMEL, and anti-apoptotic BCL2 protein, MCL1, in treated cells. Phosphorylated BIMEL was dissociated from MCL1 and interacted with BAX, followed by conformational change of BAX. Furthermore, the knockdown of BIMEL with small interfering RNA inhibited the augmentation of ATO-induced apoptosis by BSO.

Conclusions

The enhancing effect of BSO on ATO-induced cell death was characterized at the molecular level for clinical use. Addition of BSO induced mitochondrial injury-mediated apoptosis via the phosphorylation of BIMEL and MCL1, resulting in their dissociation and increased the interaction between BIMEL and BAX.
Hinweise

Electronic supplementary material

The online version of this article (doi:10.​1186/​1471-2407-14-27) contains supplementary material, which is available to authorized users.

Competing interests

All of authors have no conflicts of interest to disclose.

Authors’ contributions

Participated in research design: K, T. Conducted experiments: T, S, K. Contributed new reagents or analytic tools: T, S. Performed data analysis: K, T, Y. Wrote or contributed to the writing of the manuscript: K, T, Y, S, F. All authors read and approved the final manuscript.
Abkürzungen
ATO
Arsenic trioxide
BSO
Buthionine sulfoximine
ATO/BSO
A combined treatment of ATO and BSO
ROS
Reactive oxygen species
APL
Acute promyelocytic leukemia
AML
Acute myeloid leukemia
BIMEL
BCL2-interacting mediator of cell death-extra long protein
MCL1
Myeloid cell leukemia-1 protein
BAX
BCL2-assocated X protein
BAK
BCL2-antagonist/killer protein
BAD
BCL2-associated death promoter protein
BID
BH3-interacting domain death agonist
tBID
Truncated BID
BCL2
B cell lymphoma 2 protein
BCLxL
BCL2-like X protein
JNK
c-JUN N-terminal kinase
ERK1/2
Extracellular signal-regulated kinase 1/2
ASK1
Apoptosis signal-regulating kinase 1.

Background

Arsenic trioxide (ATO) has been reported to be an effective therapeutic agent in both newly diagnosed and relapsed patients with acute promyelocytic leukemia (APL) [1, 2]. This success has prompted an interest in understanding the molecular mechanisms of action underlying the clinical effectiveness of ATO. ATO is reported to induce apoptosis in leukemic promyelocytes [3, 4]. ATO-induced apoptosis appears to be dependent on the intracellular redox homeostasis. In particular, the effectiveness of ATO in inducing to apoptosis is associated with an increased generation of intracellular reactive oxygen species (ROS) [5, 6]. However, the antitumor effect of ATO is limited in other types of leukemia and solid tumor cells, since these cancer cell types have low susceptibility to ATO [7, 8]. Previous studies suggest that the ineffectiveness of ATO in ATO-resistant tumors may be due to low ROS levels, preventing the triggering of effective apoptosis [5, 9, 10]. These early studies thus provide a rationale for utilizing ATO in combination with oxidative pathway modulators to extend the use of ATO for treating non-APL malignacies. Buthionine sulfoximine (BSO), which is known to effectively deplete cellular glutathione [11], is used to augment ATO-induced apoptosis [1214]. However, the precise mechanism of BSO-mediated augmentation of ATO-induced apoptosis remains unclear. In particular, the molecular events in mitochondria involved in increased apoptotic susceptibility are unknown. In this study we investigated the detailed molecular mechanism of mitochondrial injury-mediated cell death by treating HL60 with ATO/BSO, compared with that with ATO alone. We report that the dissociation of BIMEL and MCL1 and the subsequent interaction of BIMEL and BAX play a critical role in BSO-mediated augmentation of ATO-induced apoptosis.

Methods

Reagents

ATO, BSO, n-acetylcysteine (NAC), dithiothreitol (DTT), SP600125, U0126, PD035901 and SB203580 were purchased from Sigma Chemical (St. Louis, MO, USA). The following antibodies were obtained from Cell Signaling Technology (Beverly, MA, USA): antibodies to the cleaved form of caspase 3 (C-cas3), caspase 9 (C-cas9), poly (ADP-ribose) polymerase (C-PARP); antibodies to normal and phosphorylated forms of MCL1 (MCL1, P-MCL1 at Ser159/Thr163), BCL2 (BCL2, P-BCL2 at Ser70), BIM (BIM, P-BIM at Ser69), JNK (JNK, P-JNK at Thr183/Tyr185), c-JUN (c-JUN, P-c-JUN at Ser63), p38 (p38, P-p38 at Thr180/Tyr182) and ERK1/2 (ERK1/2, P-ERK1/2 at Thr202/Tyr204); antibodies to actin, BAD, BID and BOK. Antibodies to BAK, ASK, and normal and phosphorylated forms of BCLxL (BCLxL, P-BCLxL at Ser62) were obtained from Abcam (Cambridge, MA, USA). Antibodies to mouse and human phosphorylated forms of ASK1 (P-ASK1 at Thr845 or at Thr838) [15] was provided by Dr. H. Ichijo, the University of Tokyo.

Cell culture

The HL60 cell line, which was derived from peripheral blood cells of a 36-year old Caucasian female with APL, was obtained from ATCC (Manassas, VA, USA). Cells were maintained in RPMI-1640 medium supplemented with 10% heat inactivated fetal bovine serum.

Cell viability

Cell viability was determined using a cell proliferation kit (XTT) (Roche Applied Sciences, Rotkreuz, Switzerland) as described elsewhere [16]. The half-maximal inhibitory concentration (IC50) was calculated using Graphpad PRISM software (GraphPad, San Diego, CA, USA). The nontoxic concentrations of various reagents were confirmed by the XTT test.

Identification of apoptotic cell death

Apoptotic cells were identified using a cell death detection kit (Roche Applied Sciences) using mouse monoclonal antibodies against fragmented DNA and histones according to the manufacturer’s instructions.

Determination of intracellular ROS level

The generation of intracellular ROS was determined using a redox-sensitive dye 5-(and-6)-chloromethyl-2′,7′-dichlorodihydrofluorescein diacetate probe (CM-H2DCFDA) (Molecular probes, Eugene, Oregon, USA) according to the manufacturer’s instructions.

Determination of mitochondrial outer membrane permeability (MOMP)

Cells were incubated with NIR dye supplied in a NIR mitochondrial membrane potential assay kit (Abcam) and 1 μM Hoechst 33342 dye for 30 min at 37˚C. Stained cells were subjected to confocal microscopy (Leica TCS SP II, Wetzlar, Germany). The fluorescence ratio of the two dyes was determined for quantitative analysis of MOMP. The Leica confocal software, a MetaMorph ver.7.8 (Molecular Devices) was used for the analysis.

Determination of cytochrome crelease

The release of cytochrome c was determined using an ApoAlert cell fractionation kit (Clontech, Mountain View, USA). The cells were processed according to the manufacturer’s instructions and the concentration of released cytochrome c in the cytosolic fractions was determined by immunoblotting with anti-cytochrome c antibody.

Immunoprecipitation and immunoblotting analysis

Cells were lysed in CHAPS buffer (10 mM Hepes, pH7.5, 150 mM NaCl, 2% CHAPS) or RIPA buffer (50 mM Tris–HCl, pH 8.0, 150 mM NaCl, 0.5% sodium deoxycholate, 0.1% sodium dodecyl sulfate, 1.0% NP-40) containing protease inhibitor cocktail (Nacalai Tesque, Kyoto, Japan) and phosphatase inhibitor cocktail I (Wako Pure Chemical, Osaka, Japan). Protein lysates (500 μg of protein) in CHAPS buffer were subjected to immunoprecipitation using an antibody to BAX 6A7 (BD Biosciences, San Jose, CA, USA), BAK Ab1 (Abcam), BIM (Cell Signaling Technology) or MCL1 (BD Pharmingen). The immunoprecipitates or whole cell lysates (10 μg of protein) were analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis on 7.5-15% gels and electroblotted onto nitrocellulose membranes (BIO-RAD, Hercules, CA, USA). Immunoblots were treated with primary and secondary antibodies and then analyzed using an ECL-Advance Western blotting kit (GE Healthcare, Little Chalfont, England). In several experiments, band intensities were quantified using a LAS4000 imaging system (GE Healthcare).

Transfection with small interfering (si) RNA

HL60 cells (1 × 106 cells) were transfected with two distinct siRNA (BIM#1 and BIM#2) specifically designed against human BIMEL, or with a control non-silencing siRNA (Silencer Select; Life Technologies, Carlsbad, CA, USA) using hemagglutinating virus supplied in a Japan-envelope vector kit (GenomONE-Si; Ishihara Sangyo, Osaka, Japan), according to the manufacturer’s instructions. The cells were used for ATO/BSO treatment 48 h after transfection with siRNA.

Statistical analysis

Experimental values are represented as the mean ± standard deviation in triplicate. The experiments were carried out at least 3 times. The significance of difference between experimental and control groups was determined by the Student’s t-test. A value of p < 0.05 was considered statistically significant.

Results

BSO augments ATO-induced cell death via intracellular ROS generation

The effect of BSO on ATO-induced cell death using HL60 cells was examined by determining cell viability (Figure 1A). BSO significantly augmented ATO-induced cell death. Approximately 80% of HL60 cells died when exposed to ATO in the presence of BSO, whereas ATO alone killed approximately 30% of the cells (p < 0.01, ATO alone or ATO/BSO vs. none). Since ATO-induced cell death is associated with generation of intracellular ROS [5, 6], the effect of the antioxidants, NAC and DTT, on ATO/BSO-induced cell death was examined (Figure 1A). Antioxidants prevented ATO/BSO-induced cell death, suggesting that ROS play an important role in BSO-mediated augmentation of ATO-induced cell death. To confirm the ROS generation directly in ATO/BSO-treated cells, intracellular ROS generation was determined using a fluorescent probe, CM-H2DCFDA dye (Figure 1B). ATO/BSO treatment markedly increased the ROS generation, although ATO alone treatment did it only slightly.

BSO augments ATO-induced cell death via ROS-mediated mitochondrial injury

In the preceding section, BSO augmented ATO-induced cell death via intracellular ROS generation. To clarify involvement of ROS-mediated mitochondrial injury in BSO-mediated augmentation, the effect of BSO on the release of cytochrome c, a marker of mitochondrial injury, in ATO-treated cells was examined by immunoblotting. BSO significantly augmented ATO-induced cytochrome c release whereas ATO alone induced slight release of cytochrome c (Figure 2A). The cytochrome c release was abolished by antioxidants (Figure 2A). Further, BSO markedly augmented the activation of caspase 9, which is triggered by released cytochrome c and is involved in an early stage of mitochondrial apoptosis. On the other hand, the caspase 9 activation was hardly detected in ATO alone treatment. To confirm BSO-mediated mitochondrial injury, the effect of ATO/BSO treatment on MOMP was examined with a confocal microscope. Addition of BSO significantly reduced NIR stain in ATO-treated cells whereas ATO did it only minimally (Figure 2B). Thus, BSO was suggested to augment ATO-induced cell death via mitochondrial injury characterized by cytochrome c release, caspase 9 activation and MOMP reduction.

BSO induces conformational change in BAX, but not in BAK

Since the two proapoptotic BCL2 effector proteins, BAX and BAK, play central roles in oxidative stress-mediated mitochondrial apoptosis [17, 18], the effect of BSO addition on the conformational change of BAX and BAK in ATO-treated cells was examined by immunoprecipitation and immunoblotting. Immunoblotting analysis with anti-whole BAX antibody demonstrated no significant difference in total BAX expression between ATO/BSO and ATO alone treatment. However, an antibody which defines conformationally changed BAX immunoprecipitated much more BAX in ATO/BSO-treated cells than ATO alone-treated cells (Figure 3, upper panel). An anti-whole BAX antibody immunoprecipitated a lower level of BAX from the supernatant fraction of ATO/BSO-treated cells. Therefore, BSO was suggested to trigger conformational change of BAX in ATO/BSO treatment. In addition, the conformational change of BAX in ATO/BSO-treated cells was prevented by DTT as an antioxidant (Figure 3, upper panel).
Immunoprecipitation analysis using an antibody to whole BAK or conformationally changed BAK demonstrated no presence of conformationally changed BAK in either ATO/BSO or ATO alone treatment (Figure 3, lower panel).

BSO induces phosphorylation of BIMELand MCL1 in mitochondria

A possibility was raised that the conformational change of BAX might be critical for BSO-mediated mitochondrial injury. Therefore, we examined the expression and activation of a series of BCL2-family proteins, which affect the conformational change of BAX [19, 20]. First, the expression of BIMEL, a proapoptotic protein in the BCL2 family, was analyzed by immunoblotting. Normal HL60 cells expressed a readily detectable level of the two major BIM isoforms, BIMEL and BIML whereas they expressed a low level of the smallest isoform, BIMS (Figure 4A upper panel). BIMEL (23 kDa) underwent an electrophoretic mobility shift (24–26 kDa) following ATO/BSO treatment whereas the smaller isoform, BIML did not. BSO addition caused a high level of S69-phosphorylated BIMEL (Figure 4A). The enhanced BIMEL phosphorylation was abolished by NAC or DTT as antioxidants (Figure 4A). In contrast, neither mobility shift nor phosphorylation of BIMEL was induced by ATO alone. There was no significant difference in the expression of the other pro-apoptotic proteins of the BCL2 family, BAD and BID between ATO/BSO and ATO treatment (Figure 4B).
Second, the effect of BSO addition on the expression and activation of MCL1, an anti-apoptotic protein of the BCL2 family, was examined. BSO addition augmented the expression and phosphorylation of MCL1 at Ser159 and/or Thr163, whereas ATO alone did it only minimally (Figure 4C). The BSO-mediated augmentation of MCL1 expression and phosphorylation was abolished by antioxidants. Similar augmentation was seen in phosphorylation of BCLXL (Figure 4C). In addition, there was no significant difference in the BCL2 expression in ATO/BSO treatment in the presence or absence of antioxidants (Figure 4C).

BSO induces the dissociation of phosphorylated BIMELfrom MCL1

Since MCL1 is a preferred binding partner for BIM [21], and BIM phosphorylation is known to influence the binding to prosurvival BCL2-family proteins, especially MCL1 [22, 23], the phosphorylation of BIMEL and/or MCL1 disrupting the complex formation between BIMEL and MCL1 was examined using immunoprecipitation and immunoblotting. The MCL1-BIMEL complex was detected in untreated control cells (Figure 5A, MCL1 lane 5). BSO augmented the phosphorylation of BIMEL (Figure 5A, P-BIMEL lane 2) and the expression of MCL1 (Figure 5A, MCL1 lane 2), but reduced the level of MCL1 that co-precipitated with BIMEL (Figure 5A, MCL1 lane 6). The reduced interaction between BIMEL and MCL1 was also confirmed using an MCL1-specific antibody (Figure 5A, BIMEL lane 14). Furthermore, the interaction between MCL1 and phosphorylated BIMEL was low (Figure 5A, P-BIMEL lane 14). In contrast, ATO alone did not induce the phosphorylation of BIMEL (Figure 5A, P-BIMEL lane 3) but rather slightly reduced the amount of MCL1 that co-precipitated with BIMEL (Figure 5A, MCL1 lane 7).

BSO induces the interaction of phosphorylated BIMELwith BAX

Since BIM promotes apoptosis through binding directly to BAX and inducing conformational changes [24, 25], the interaction between BIMEL dissociated from MCL1 and BAX in ATO/BSO treatment was examined using immunoprecipitation. As shown in Figure 5A, BSO reduced the amount of non-phosphorylated (basal) BIMEL and increased the amount of BIMEL slower migrating forms (phosphorylated BIMEL) in cell lysate (Figure 5B, left panel). The BIMEL slower migrating form was detected in immunoprecipitates of BAX in ATO/BSO-treated cells but few in ATO alone-treated cells (Figure 5B, right panel). To confirm the interaction between BAX and phosphorylated BIMEL, BAX immunoprecipitates were analyzed by immunoblotting with an anti-phosphorylated BIMEL antibody (Figure 5B, right panel). Phosphorylated BIMEL was detected in BAX immunoprecipitates but not in ATO-treated cells. BSO was suggested to augment the interaction between phosphorylated BIMEL and BAX.

Silencing of BIMELwith si RNA abolishes ATO/BSO-induced cell death

To confirm the importance of BIMEL in BSO-mediated augmentation of ATO-induced cell death, the effect of gene silencing of BIMEL on ATO/BSO-induced cell death was examined (Figure 6). Transfection of HL60 cells with BIMEL-specific siRNA significantly decreased the expression level of BIMEL whereas the negative control siRNA had no effect. BIMEL-specific siRNA but not control siRNA inhibited the cleavage of caspase 3 and PARP, markers of apoptosis, in ATO/BSO-treated cells, suggesting the critical role of BIMEL in ATO/BSO-induced apoptosis.

BSO triggers phosphorylation of MCL1 and BIMELvia activation of JNK

To determine which mitogen-activated protein kinases (MAPKs) trigger phosphorylation of BIMEL and MCL1 in response to ATO/BSO, the effect of BSO addition on ATO-induced activation of JNK, ERK1/2 and p38 was examined. As shown in Figure 7A, BSO augmented phosphorylation of JNK, ERK1/2 and p38 in ATO-treated cells. The phosphorylation of these proteins was largely abolished by the presence of antioxidants. Furthermore, the effect of a series of pharmacological inhibitors against MAPKs on BSO-induced phosphorylation of BIMEL and MCL1 was examined (Figure 7B). SP600125, a JNK inhibitor, inhibited phosphorylation of MCL1 and BIMEL (Figure 7B, left panel) whereas a p38 inhibitor (SB203580) augmented phosphorylation of BIMEL and MCL1 compared to the untreated control (Figure 7B, right panel). An ERK1/2 inhibitor (U0126) did not affect the phosphorylation of BIMEL and MCL1 (Figure 7B, middle panel). The phosphorylation of BIMEL and MCL1 corresponded to the activation of caspase 3 and PARP (Figure 7B, upper panel). Further, the effect of a MEK1/2 inhibitor, PD035901, in combination with SP600125 or U0126 was examined (Figure 7B, lower panel). A combination of PD035901 and SP600125 completely blocked BSO-induced phosphorylation of BIMEL present as slower migrating forms. A combination of PD035901 and U0126 did not affect BIMEL S69 phosphorylation but blocked slower migrating forms. The phosphorylation of BIMEL corresponded to the activation of PARP.

BSO triggers activation of ASK1 and JNK and induces phosphorylation of BIMELand MCL1

ASK1 is activated by ATO through ROS accumulation [26] and induces activation of JNK and p38 [27]. To confirm the involvement of ASK1 in BSO-mediated augmentation of ATO-induced cell death, the effect of BSO addition on the activation of ASK1 in ATO-treated cells was examined. Thr838 of ASK1 was markedly phosphorylated by BSO addition whereas no obvious phosphorylation was observed upon ATO alone (Figure 8A). The phosphorylation was inhibited by antioxidants (Figure 8A). Furthermore, the effect of an ASK1 inhibitor, NQDI1 [28], on the phosphorylation of JNK, MCL1 and BIMEL was examined (Figure 8B). NQDI1 inhibited BSO-mediated phosphorylation of JNK, MCL1 and BIMEL and the cleavage of caspase 3 and PARP (Figure 8B). BSO was suggested to activate ASK1 and induce the activation of MCL1, BIMEL, caspase 3 and PARP.

Discussion

In the present study, we have demonstrated that BSO augments ATO-induced cell death in HL60 cells and that the augmentation is responsible for ROS-mediated mitochondrial apoptosis. The detailed molecular mechanism of BSO-mediated mitochondrial injury was studied by comparing ATO cell death in the presence or absence of BSO. We here report that BSO augments intracellular ROS production in mitochondria and induces a series of molecular events, such as conformational change of BAX, phosphorylation and dissociation of BIMEL and MCL1, and interaction of BIMEL and BAX.
Previously several groups showed that BSO decreased the levels of glutathione and enhanced ATO-induced apoptosis [29, 30]. Chen et al. reported that ATO/BSO induced apoptosis in ATO-sensitive and insensitive leukemia cells through activation of JNK, which up-regulated death receptor (DR) 5 and the caspase 8 pathway [30]. However, they did not report the accumulation of ROS in ATO/BSO-induced apoptosis, nor the associated molecular events occurring in mitochondria. We have demonstrated that ATO/BSO induces the dissociation of BIMEL from MCL1, and that its interaction with BAX plays a critical role in ATO/BSO-induced apoptosis via conformational changes in BAX. Our results demonstrate that BSO causes ROS-mediated mitochondrial injury, accompanied by cytochrome c release and reduced MOMP. This is the first report showing the involvement of ROS-mediated mitochondrial injury in BSO-mediated augmentation of ATO-induced apoptosis. Moreover, we show the pivotal role played by the pro-apoptotic molecule, BIMEL, in ATO/BSO-induced apoptosis, and confirm it by the finding that knockdown of BIMEL abolishes ATO/BSO-induced apoptosis. The remarkable behavior of pro-apoptotic BIMEL in mitochondria provides new insights into the molecular mechanism of ATO/BSO-induced apoptosis. Pro-apototic effects are reported to be associated with BIML activation [31]. However, we could not confirm the activation of BIML in this study. Rather, the role of BIMEL might be more important than that of BIML, although we do not exclude the involvement of BIML in ATO/BSO-induced apoptosis.
BSO induces phosphorylation of BIMEL and MCL1 in ATO-treated cells. Phosphorylated BIMEL is dissociated from MCL1 and interacts with BAX. The complex formation between phosphorylated BIMEL and BAX triggers a conformational change in BAX, leading to the dysfunction of MOMP and the release of cytochrome c. Finally, ATO/BSO-treated cells undergo apoptosis via activation of cytochrome c-mediated caspase 9, caspase 3 and PARP. The putative molecular events occurring in mitochondria for BSO-mediated augmentation of ATO-induced apoptosis are summarized in Figure 9. There are several reports on the phosphorylation and dissociation of BIM and MCL1 [23, 32, 33]. The withdrawal of serum survival factors is reported to induce the phosphorylation of BIM at Ser65 (Ser69 in human) and dissociation from MCL1 and BCLxL [32]. In normal B cells treated with anti-IgM antibody, the phosphorylation of BIM at Ser69 has been reported to play a regulatory role in the release of MCL1 [33]. However, these studies reported that the dissociation of phosphorylated BIM from MCL1 is related to survival response, whereas our results demonstrate that the dissociation of BIMEL from MCL1 leads to cell death in ATO/BSO-treated cells. The crucial role of BIMEL phosphorylation in apoptosis has been reported previously for cell death induced by trophic factor deprivation [34] and diallyl trisulfide [35], although the dissociation of BIMEL and MCL1 was not observed. There remained a possibility that phosphatase inhibition might be involved in the phosphorylation of a series of signal molecules.
The critical role of ASK1 in apoptosis induction has been reported [3638]. We have found that BSO triggers activation of ASK1 in ATO-treated cells. The involvement of ASK1 activation in ATO/BSO-induced apoptosis is confirmed by using pharmacological inhibitors, although it must be confirmed by more specific technique. Yan et al. [26] reported that ASK1 is activated by ATO through ROS accumulation, and that it negatively regulates apoptosis in leukemia cells without activating JNK and p38. In contrast, our results clearly show that ASK1 activated by BSO causes the activation of JNK and p38. The difference between the two studies might be due to excessive ROS generation in response to ATO/BSO. ASK1 is a member of the MAPK kinase kinase family and activates JNK and p38 MAPKs in response to an array of stresses such as oxidative stress, endoplasmic reticulum stress and calcium influx [27]. It is reasonable that BSO activates ASK1 via oxidative stress and then activates JNK and p38. Inhibition of p38 with a pharmacological inhibitor induces the activation of caspase 3 and PARP in ATO/BSO-induced apoptosis, suggesting negative feedback of p38 against ATO/BSO-induced apoptosis. The precise role of ASK1 and MAPKs in ATO/BSO-mediated apoptosis must await further characterization.

Conclusions

ATO/BSO combined treatment induces ROS-mediated mitochondrial apoptosis in HL60 cells. ATO/BSO-induced mitochondrial apoptosis is caused by successive BIMEL alterations consisting of phosphorylation, dissociation from MCL1, and interaction with BAX. The enhancing effect of BSO on ATO-induced apoptosis was characterized at the molecular level for clinical use.

Acknowledgements

We thank Dr. H. Ichijo for kindly providing anti-phopho-ASK1 antibody. We thank Dr. M. Urasaki for excellent technical advice. Ms. T. Sugino provided outstanding technical assistance.
Role of the funding source
This work was supported in part by a Grant-in-Aid for Scientific Research from the Ministry of Education, Science, Sports and Culture of Japan (23590147, 2011).
Open Access This article is published under license to BioMed Central Ltd. This is an Open Access article is distributed under the terms of the Creative Commons Attribution License ( https://​creativecommons.​org/​licenses/​by/​2.​0 ), which permits unrestricted use, distribution, and reproduction in any medium, provided the original work is properly credited. The Creative Commons Public Domain Dedication waiver ( https://​creativecommons.​org/​publicdomain/​zero/​1.​0/​ ) applies to the data made available in this article, unless otherwise stated.

Competing interests

All of authors have no conflicts of interest to disclose.

Authors’ contributions

Participated in research design: K, T. Conducted experiments: T, S, K. Contributed new reagents or analytic tools: T, S. Performed data analysis: K, T, Y. Wrote or contributed to the writing of the manuscript: K, T, Y, S, F. All authors read and approved the final manuscript.
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Metadaten
Titel
BIMELis a key effector molecule in oxidative stress-mediated apoptosis in acute myeloid leukemia cells when combined with arsenic trioxide and buthionine sulfoximine
verfasst von
Yukie Tanaka
Takayuki Komatsu
Hiroko Shigemi
Takahiro Yamauchi
Yutaka Fujii
Publikationsdatum
01.12.2014
Verlag
BioMed Central
Erschienen in
BMC Cancer / Ausgabe 1/2014
Elektronische ISSN: 1471-2407
DOI
https://doi.org/10.1186/1471-2407-14-27

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