Báo cáo khoa học: Etoposide upregulates Bax-enhancing tumour necrosis factor-related apoptosis inducing ligand-mediated apoptosis in the human hepatocellular carcinoma cell line QGY-7703 pdf

Etoposide upregulates Bax-enhancing tumour necrosis factor-related apoptosis inducing ligand-mediated apoptosis in the human hepatocellular carcinoma cell line QGY-7703 Lin Miao, Peng Yi

Etoposide upregulates Bax-enhancing tumour necrosis factor-related apoptosis inducing ligand-mediated apoptosis in the human

hepatocellular carcinoma cell line QGY-7703

Lin Miao, Peng Yi, Yi Wang and Mian Wu

Department of Molecular and Cell Biology, Key Laboratory of Structural Biology, School of Life Sciences,

University of Science and Technology of China, Hefei, Anhui, China

Tumour necrosis factor-related apoptosis-inducing ligand

(TRAIL) has attracted much attention because of its ability

to kill tumour cells In this study, we demonstrated that

treatment of QGY-7703 cells with the combination of

TRAIL and etoposide resulted in synergistic cytotoxic

effects In dissecting the mechanism underlying this

syner-gistic effect, we found that treatment with etoposide alone

resulted in the upregulation of Bax, while the level of

trun-cated Bid (tBid) was unchanged In contrast, while treatment

with TRAIL alone significantly increased the level of tBid,

the expression of Bax remained unaffected The enhanced

apoptosis was accompanied by an increased release of

cytochrome c and second mitochondria-derived activator of

caspase/direct IAP binding protein with low pI (DIABLO)

from mitochondria, leading to the activation of cellular

caspase-8, -9, -3 and -7, as well as poly ADP-ribose polym-erase This enhanced release of cytochrome c and second mitochondria-derived activator of caspase/DIABLO was inhibited by the general caspase inhibitor N-benzyloxycar-bonyl-Val-Ala-Asp-fluoromethylketone The RT–PCR and Western blotting results demonstrated that the levels of both mRNA and protein for death receptor-4, death receptor-5 and decoy receptor-2 remained unchanged in response to etoposide, indicating that the synergistic effect of TRAIL and etoposide is not a result of increasing the expression for TRAIL receptors, but rather is associated with amplification

of the mitochondrial signal pathway

Keywords: p53; Bax; tBid; mitochondrial pathway; death receptor

Chemotherapeutic agents are used widely in the treatment

of different types of cancer Hetapocellular carcinoma, one

of the most common tumours in adults, remains largely

incurable despite intensive multimodality treatment,

inclu-ding surgical eradication, irradiation and chemotherapy

Besides the difficulties of complete surgical removal,

resistance to chemotherapy and irradiation is a major

hindrance for the successful treatment of liver cancers

Defects in signalling pathways leading to the activation of caspases are common in most types of malignancies Accumulating data suggest that two major signal pathways are involved in apoptosis The first is the mitochondrial pathway (intrinsic), usually triggered by DNA damage, and the second is the receptor-mediated pathway (extrinsic), initiated by death receptor activation Resistance to chemotherapeutic agents may be caused by repression of the mitochondrial pathway In order to achieve effective treatment of those drug-resistant tumour cells, new meth-ods, which could bypass the resistance to chemotherapeutic drugs through activation of the death receptor-mediated pathway, need to be developed Tumour necrosis factor-related apoptosis-inducing ligand (TRAIL), a type II membrane protein, is a member of the tumour necrosis factor death-ligand family [1,2] and it selectively induces apoptosis in a number of transformed cells in vitro [1–3] and tumours in vivo, while leaving normal tissues intact [4,5] Four cognate TRAIL death receptors – death receptor (DR)4 [6,7], DR5 [7,8], decoy receptor-1 (DcR-1)/TRID (i.e TRAIL decoy receptor lacking an intracellular domain) [9–11] and DcR-2/TRUNDD (i.e TRAIL decoy receptor containing a truncated death domain) [12–14] – have been identified to date Both DR4 and DR5 contain an intracel-lular
death domain that recruits effector molecules, such as Fas-associated death domain protein (FADD) [15] and death-associated protein 3 (DAP-3) [16] to activate initiator caspase-8 and subsequently the effector caspases leading to apoptosis [6,7] In contrast, DcR-1/TRID and DcR-2/ TRUNDD contain a truncated or a null intracellular death

Correspondence to M Wu, Department of Molecular and Cell

Biology, School of Life Sciences, University of Sciences and

Technology of China, Hefei, Anhui, China, 230027.

Fax: + 86 551 360 6264, Tel.: + 86 551 360 6264,

E-mail: wumian88@yahoo.com

Abbreviations: DcR, decoy receptor; DIABLO, direct IAP binding

protein with low pI; DR, death receptor; FADD, Fas-associated death

domain protein; FITC, fluorescein isothiocyanate; MTT,

3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide; PARP,

poly ADP-ribose polymerase; PI, phosphatidylinositol; Smac, second

mitochondria-derived activator of caspase; tBid, truncated Bid;

TRAIL, tumour necrosis factor-related apoptosis-inducing ligand;

TRID, TRAIL decoy receptor lacking an intracellular domain;

TRUNDD, TRAIL decoy receptor containing a truncated death

domain; zVAD-FMK,

N-benzyloxycarbonyl-Val-Ala-Asp-fluoro-methylketone.

Enzymes: alkaline phosphatase (EC 3.1.3.1).

(Received 13 January 2003, revised 26 March 2003,

accepted 28 April 2003)

domain, respectively, and are unable to transduce the death

signal [6,7]

Mutation in p53 initiates oncogenesis and accounts for

more than 50% of different tumour types [17–19] p53 acts

as a
genome guardian to scrutinize DNA injury in cell cycle

regulation and cell death control by modulating expression

of a number of target genes in response to DNA-damaging

agents, hypoxia or oncogene activation A number of

chemotherapeutic drugs, acting as DNA-damaging agents,

enhance the expression of p53 The downstream target

genes of p53 include p21, Bax, DR4, DR5, DcRs and Bcl-2

Upregulation of p53, resulting in the enhanced expression of

DR4 and/or DR5 in some cancer cell lines, is believed to be

one of the mechanisms by which the susceptibility of the

tumour cells to TRAIL is synergistically increased when

treated with chemotherapeutic agents and TRAIL together

[20,21] However, some research groups have reported that

the upregulation of DR4 and DR5 is not necessarily

p53-dependent [22,23]

Many chemotherapeutic drugs can promote

mitochond-rial membrane permeabilization and release of

caspase-activating factors, in particular cytochrome c and second

mitochondria-derived activator of caspase

(Smac)/DIAB-LO from mitochondria to the cytosol Bax is a

pro-apoptotic factor belonging to the Bcl-2 family and

stimulates mitochondria to release cytochrome c and Smac/

DIABLO Bax, together with its homologue Bak, plays a

vital role in the TRAIL-mediated mitochondrial apoptosis

[24] The Bid protein, a member of the Bcl-2 family, may

stand at the cross-roads of the mitochondria and the death

receptor, as Bid is cleaved by active caspase-8 to form

truncated Bid (tBid), which, in turn, stimulates the

mito-chondria to release cytochrome c [25]

In this study, we examined the apoptotic effects of the

cytokine TRAIL, in the presence and absence of a

chemotherapeutic agent, on hepatocellular carcinoma

QGY-7703 cells to determine whether co-operative killing

could be achieved and, if so, what possible mechanism

might be underlying this effect We found that TRAIL plus

etoposide acts synergistically to kill human liver tumour

cells and this synergistic effect involves the upregulation of

Bax and tBid, but not of DR4 or DR5 The interaction

between Bax and tBid results in the amplification of

mitochondrial release of cytochrome c and Smac/DIABLO,

leading to augmented cell death through enhanced

activa-tion of cellular caspases

Materials and methods

Regents and antibodies

Recombinant human (rh)TRAIL was purchased from

R & D Systems The general caspase inhibitor,

N-benzyl-oxycarbonyl-Val-Ala-Asp-fluoromethylketone

Laboratories Inc Most drugs used in this study, including

etoposide, cisplatin, doxorubincin, 5-fluorouracil,

metho-trexate, cytarabine, cyclophophamide and daunorubicin,

were purchased from Sigma Some other drugs of GCP

(good clinical practice) grade were ordered from a local

pharmaceutical company Antibodies used in this study

were as follows Polyclonal antibodies: anti-caspase-7,

actin, DR4, DR5, DcR-2, Bid, anti-Bax (Santa Cruz Biotech Inc., Santa Cruz, CA, USA), anti-caspase-9 (Immunotech), anti-caspase-3/CPP32 (BD Biosciences) and anti-poly ADP-ribose polymerase (anti-PARP) (Upstate Biotechnology) Monoclonal antibodies (mAbs): anti-cytochrome c (R & D Systems), anti-caspase-8 (BD Biosciences) and anti-Smac/DIABLO (Calbiochem) All the secondary antibodies [goat, mouse, anti-rabbit (H + L)] were purchased from Promega

Cell culture The human hepatocellular carcinoma cell line, QGY-7703, was kindly provided by D Lu (Dept of Neurology, Stanford University, Palo Alto, CA, USA) The cells were maintained in RPMI-1640 containing 10% heat-inactivated bovine serum, 1 mM L-glutamine, 100 UÆml)1penicillin and

100 lgÆml)1 streptomycin (Life Technologies, Inc Grand Island, NY, USA) at 37C under an atmosphere of 5%

CO2in air

Cell death assay The 3-(4,5-dimethylthiazol-2-yl)-2,5-diphenyltetrazolium bromide (MTT) assay was used to determine tumour cell viability Briefly, cells were plated at 1· 104cells per well in 96-well microtitre plates overnight Cells were then treated with 100 lL of fresh medium containing the drug to be tested, cultured for 20 h, then for a further 4 h with 10 lL

of 5 mgÆmL)1 MTT After incubation, the medium was removed and replaced with 100 lL of dimethylsulfoxide and the data were analysed by using an ELX800 Universal Microplate Reader (BIO-TEK Instruments, Inc.) at a wavelength of 570 nm with the reference wavelength set at

630 nm The effect of drug treatment was expressed as a percentage of growth inhibition using untreated cells as the uninhibited control

Assessment of apoptosis by Annexin V staining

An Annexin V–fluorescein isothiocyanate (FITC) Apoptosis Detection kit (Pharmingen, San Diego, CA, USA) was used

in this assay After treatment with the test drugs, cells were harvested and resuspended in binding buffer [0.01MHepes/ NaOH (pH 7.4), 0.14 mM NaCl, 2.5 mM CaCl2] at a concentration of 1· 106cellsÆmL)1 One-hundred micro-litres of this resuspended solution (1· 105cells) was trans-ferred to a 5-mL culture tube After incubation with 5 lL of Annexin V–FITC and 10 lL of phosphatidylinositol (PI) (50 lgÆmL)1) for 15 min at room temperature in the dark, the cells were analysed by flow cytometry in a FACSCalibur usingCELL QUESTsoftware (Becton Dickinson)

Western blot analysis Cells were lysed in 50 lL of lysis buffer [50 mMTris/HCl (pH 7.5), 250 mMNaCl, 5 mMEDTA, 50 mMNaF, 0.5% Nonidet P-40] supplemented with a protease inhibitor cocktail (Roche Molecular Biochemicals, Indianapolis, IN) on ice for 30 min Fifty micrograms of each sample was separated by SDS/PAGE (12% or 15% gel) and transferred to nitrocellulose membrane (Amersham

Pharmacia Biotech) Filters were blocked with NaCl/Tris

(TBS) containing 5% nonfat milk and 0.1% Tween-20 for

1 h at room temperature and then incubated (for a further

1 h) with primary antibodies Blots were then probed with

appropriate alkaline phosphatase-conjugated secondary

antibodies and the proteins visualized by using Western

Blue stabilized substrate for alkaline phosphates (Promega)

RT–PCR

Total cellular RNA was extracted from QGY-7703 cells

using the SV total RNA Isolation kit (Promega) The

yield and purity of the RNA sample were determined by

ultraviolet spectrometry using the DU 640 Nucleic Acid and

Protein Analyser (Beckman Coulter) Two micrograms of

total RNA was reverse transcribed using the TaKaRa One

Step RNA PCR kit (TaKaRa Bio Inc., Shiga, Japan)

according to the manufacturer’s instructions In both RT

and PCR steps, the reaction reagents were prepared as

master mixtures and then aliquotted PCR primers were

designed to amplify the sequence for the intracellular

domain of the TRAIL/Apo2L receptor The housekeeping

gene, b-actin, was amplified as an internal control The

mRNA levels were then normalized to actin mRNA

expression Equal amounts of RT–PCR products, loaded

onto an agarose gel, were quantified by using the Eagel Eye

Jr Still Video System (Stratagene) Differences in mRNA

levels as a result of treatment with etoposide for different

incubation times are represented as relative units over

basal actin mRNA levels The sequences of the primers

used in this study are as follows: DR4 forward,

5¢-CGGAATTCGGAGGGGACCCCAAGTGCAT-3¢;

AGTCTTTACTGTGGAA-3¢; DR5 reverse, 5¢-CGGA

5¢-CGGAATTCCGCGGAAGAAATTCATTTCT-3¢;

DcR2 reverse, 5¢-CGGGATCCTCACAGGCAGGACG

TAGCAG-3¢; Bax forward, 5¢-GCGAATTCCATGG

ACGGGTCCGGGGAG-3¢; Bax reverse, 5¢-CGCTC

5¢-CGGGATCCCCATGGCGATGGACTGTGAGGT-3¢;

Bid reverse, 5¢-CGGAATTCTCAGTCCATCCCATTTC

TGG-3 The primers for b-actin were kindly provided by

Z Tian (Department of Immunology, University of Science

and Technology of China, Hefei, Anhui, China)

Cytochromec release assay

Cell were harvested, as described above, and lysed in

ice-cold lysis buffer (20 mMHepes, pH 7.4, 10 mMKCl, 5 mM

EDTA, 2 mMMgCl2, with 2 mMdithiothreitol and

prote-ase inhibitor cocktail added before use) for 15 min on ice

Cell lysates were centrifuged at 16 000 g for 2 min and the

supernatants mixed with 2· Laemmli buffer and resolved

by SDS–PAGE (15% gel) Released cytochrome c and

Smac/DIABLO were subjected to analysis by Western blot

Statistical analysis

All determinations were made in triplicate, and the results

were expressed as the mean value ± SD Statistical

signi-ficance was determined by the Student’s t-test A P-value

of < 0.05 was considered significant Calculations of synergistic cytotoxicity were determined by isobolographic analysis, as described by Berenbaum [26] The isobolo-graphic analysis can detect whether the dose-dependent effects of two compounds in a mixture are more or less effective than the expected effects based on tests of the compounds individually Simply put, the point representing the dose combination lying on, below, or above the straight line represents additive, synergistic, or antagonistic effects, respectively

Results and discussion Effect of TRAIL on the liver carcinoma cells QGY-7703

To investigate the apoptotic function of TRAIL containing the extracellular domain (amino acids 114–281) of the human liver cancer cell line, QGY-7703 [27], we treated the cells with increasing concentrations of TRAIL and then analysed cell viability by using the MTT assay After incubation with TRAIL at a concentration of 10 ngÆmL)1 for 30 h, QGY-7703 cells were found to show morpho-logical changes, from a spindle-like to a rounded shape, a characteristic feature of apoptosis (Fig 1A,c) As controls, untreated cells (Fig 1A,a) and cells treated with medium (Fig 1A,b) remained healthy and viable Although TRAIL can induce the apoptosis of QGY-7703 cells, we found that the cells were relatively insensitive to TRAIL In the dose– response experiment (Fig 1B), even though the QGY-7703 cells were treated with TRAIL at a high concentration of

100 ngÆmL)1for 24 h, only 23% cell death was detected To further verify whether the TRAIL-induced cell death represents apoptosis, we utilized the AnnexinV–FITC staining method to quantify the apoptotic cell numbers by flow cytometry, which relies on the property of cells to lose membrane asymmetry in the early phase of apoptosis As shown in Fig 1C,a, only 1.4% of untreated QGY-7730 cells were Annexin-V positive and PI negative (early apoptotic cells) In contrast, approximately 7% of TRAIL (10 ngÆmL)1)-treated QGY-7730 cells were Annexin-V posi-tive and PI negaposi-tive (Fig 1C,c) Approximately 6% of untreated cells were double-positive for Annexin-V and PI (Fig 1C,a) We noted that the percentage of these Annexin-V- and PI-positive cells remained similar after treatment with TRAIL (Fig 1C,c; 7.3%), etoposide (Fig 1C,b; 6.2%), or both (Fig 1C,d; 5%), indicating that those double-positive cells may represent either late-stage apop-totic cells or necrosis cells, which are independent of apoptotic induction

Etoposide, in conjunction with TRAIL, results

in synergistic effects in inducing apoptosis The resistance of tumours to conventional chemothera-peutic drugs, and the potential toxicity of conventional chemotherapeutic drugs to patients, is a major problem in the treatment of malignant liver tumours Despite its potent cytotoxic effect on malignant cells, TRAIL causes little, if any, damage to normal adult tissues [28] To examine whether treatment with the combination of TRAIL and chemotherapeutic drugs was able to trigger enhanced

Fig 1 The effects of tumour necrosis factor-related apoptosis-inducing ligand (TRAIL)on human liver cancer cells QGY-7703 (A) QGY-7703 cells treated with TRAIL (10 ngÆmL)1) for 30 h and the morphological changes associated with apoptosis were photographed under an inverted light microscope In contrast to the untreated cells (a) and those treated with medium only (b), viability loss was noted at 30 h in cells treated with TRAIL (c) (B) Cytotoxicity of TRAIL (1–100 ngÆmL)1) on QGY-7703 cells was determined by the MTT assay (C) Flow cytometry analysis of TRAIL-induced apoptosis QGY-7703 cells treated with medium (a), 8 lgÆmL)1etoposide (b), 10 ngÆmL)1TRAIL (c), or 10 ngÆmL)1TRAIL plus

8 lgÆmL)1etoposide in the presence (e) or absence (d) of 100 l M N-benzyloxycarbonyl-Val-Ala-Asp-fluoromethylketone (zVAD-FMK) for 12 h were stained with fluorescein isothiocyanate (FITC) conjugated to Annexin V and phosphatidylinositol (PI) Ten-thousand events were analysed The percentage of apoptotic cells is indicated in the respective boxes.

apoptotic induction in the hepatocellular carcinoma cells,

QGY-7703, we treated these cells with eight different agents,

at increasing concentrations, with and without TRAIL,

then analysed apoptosis using the MTT cell death assay and

plotted the results of the cytotoxic effect The inhibition rate

was calculated as follows:

Inhibition rate¼ ½1  ðabsorbance of drug-treated cells/

absorbance of control cells)]100

Of the eight drugs tested, etoposide was found to be able to

enhance the TRAIL-induced apoptosis in QGY-7703 cells

(Fig 2A) and was found, by isobolographic analysis, to act

synergistically (Fig 2B) The remaining seven

chemothera-peutic agents (cisplatin, doxorubincin, 5-fluorouracil,

methotrexate, cytarabine, daunorubicin and

cyclophospha-nide) did not show any synergistic effect when applied together with TRAIL (data not shown) As shown in Fig 2A, only about 25% cell death was detected as a result

of treatment with etoposide alone at a very high concen-tration (64 lgÆmL)1) The QGY-7703 cells were relatively resistant to etoposide As shown in Fig 1C,b, treatment of QGY-7703 cells with etoposide (8 lgÆmL)1) alone for 12 h caused the induction of early apoptosis in 4.8% of cells, which is only a slightly increase compared to cells treated with medium However, when QGY-7703 cells were treated with a combination of TRAIL and etoposide, a significant potentiation of cytotoxicity was achieved For example, when combined with TRAIL at a very low concentration of

1 ngÆmL)1, 8 lgÆmL)1etoposide was sufficient to induce the same cytotoxicity induced by 64 lgÆmL)1 etoposide As shown in Fig 1C,d, the percentage of early apoptotic cells induced by TRAIL (10 ngÆmL)1) plus etoposide (8 lgÆmL)1) for 12 h was significantly increased, from 1.4

to 31% This effect, however, can be prevented by the general caspase inhibitor, zVAD-FMK (Fig 1C,e) In the presence of zVAD-FMK, the percentage of early apoptotic cells was reduced to 0.59%, indicating complete abrogation

of the synergistic effects resulting from co-treatment with TRAIL and etoposide It is also worthy of note that the top three cell death curves, shown in Fig 2A become indistin-guishable when the TRAIL concentration used was

> 10 ngÆmL)1; this saturation phenomenon could be explained by the fact that TRAIL-induced apoptosis involves ligand/receptor (TRAIL/DR4 or TRAIL/DR5) interaction Myen et al and Maccon et al demonstrated that cisplatin and etoposide dramatically augment TRAIL-induced apoptosis in both LNCap and PC3 prostate cancer cells [29] and malignant breast cells [30] Taken together, our results may have provided some clinical significance in the killing of tumour cells, as combined treatment will help to achieve more effective therapy with less toxicity by using a lower dose of chemotherapeutic drugs

The synergistic effect of augmented apoptosis

is involved in the upregulation of Bax and tBid, but not of DR4 or DR5

Etoposide is a DNA-damaging agent that affects chromo-somal DNA [31] It is well known that the transcription factor, p53, is essential for the apoptosis caused by DNA damage [32] We therefore studied the expression level of p53 in hepatocellular carcinoma cells, in response to etoposide or TRAIL As shown in Fig 3A, treatment with etoposide resulted in a time-dependent accumulation of p53,

as expected Treatment with TRAIL alone did not stimulate the production of endogenous p53, which is consistent with the results reported by Ashkenazi & Rieger, who claimed that TRAIL-induced apoptosis is p53-independent [14,33] Tumour-suppressor p53 modulates apoptosis through regulating its target genes involved in apoptosis We performed RT–PCR analysis to determine which genes regulated by p53 could account for the synergistic effect of etoposide and TRAIL The QGY-7703 cells were first treated with etoposide (8 lgÆmL) for the indicated times, and the subsequent RT–PCR results are shown in Fig 3B The quantitative results from RT–PCR are shown in Fig 3C It is interesting to note that only Bax mRNA

Fig 2 The synergistic cytotoxicity of tumour necrosis factor-related

apoptosis-inducing ligand (TRAIL)and etoposide on QGY-7703 cells.

(A) The cytotoxicity of TRAIL (1–100 ngÆmL)1) and etoposide (8, 16,

32, 64 lgÆmL)1), coincubated with QGY-7703 cells for 24 h, was

measured by an MTT assay All determinations were made in

tripli-cate, and the results are expressed as the mean value ± SD The data

shown are representative of three independent experiments Bars, SD.

(B) Synergistic cytotoxicity of TRAIL and etoposide was assessed by

isobolographic analysis.

was significantly increased at the 12-h time-point and

reached a peak at 18 h, whereas mRNA levels for DR4,

DR5, DcR-2 and Bid remained essentially unchanged at all

time-points tested We further examined (by Western

blotting) the protein expression of DR4, DR5, DcR-2 and

Bax in QGY-7703 cells treated with and without etoposide

As shown in Fig 3D, while no changes in the protein level

for DR4, DR5 or DcR-2 were observed, the expression of

Bax was found to be increased These Western blot results

are in good accordance with those of RT–PCR (Fig 3B)

DR4, DR5 and DcR-2 are receptors for TRAIL and their

genes are downstream targets of p53 [34–37] The

upregu-lation of TRAIL death receptors, especially DR5, by p53

was thought to be the bridge linking chemotherapeutic

agents to the death receptor-elicited apoptotic pathway,

contributing to the synergistic effect of TRAIL and

chemotherapeutic agents [38,39] In this study, the mRNA

for DR4 and DR5 appeared not to be regulated by p53, indicating that there exists another mechanism underlying the synergistic effect Liu et al reported that TRAIL and chemotherapy (such as doxorubicin) can significantly increase the apoptosis of Mesothelioma cell lines, which is

a highly chemoresistant tumour, but showed no change in DR5 when treated with chemotherapy [40]

Bax belongs to the Bcl-2 protein family and promotes apoptosis through increasing the release of cytochrome c from mitochondria Recently, Joanna et al reported that Bid can be regulated directly by p53 and contributes to chemosensitivity [41] Our data demonstrated that Bax, not Bid, was upregulated upon treatment with etoposide To examine whether TRAIL was also able to upregulate Bax, RT–PCR was performed and the result is shown in Fig 4A

No effects on the expression of Bax were observed in

QGY-7703 cells treated with TRAIL Shi et al recently reported

Fig 3 Etoposide induces the accumulation of p53 and upregulates the mRNA level for Bax, but not for death receptor (DR)4, DR5, decoy receptor-2 (DcR-2)or Bid (A) Cells were treated with tumour necrosis factor-related apoptosis-inducing ligand (TRAIL) (10 ngÆmL)1) or etoposide (8 lgÆmL)1) for 0, 8, 16 and 24 h, and 50 lg of cell lysate was then used to detect the protein level of p53 (B) Total RNA was extracted from

QGY-7703 cells treated with etoposide (8 lgÆmL)1) for the indicated time-periods Two micrograms of total RNA of each sample was used in RT–PCR to evaluate the level of mRNA for DcR-2, DR4, DR5, Bax and Bid The housekeeping gene, b-actin, was used as internal control for ensuring that an equal amount of template was used PCR was performed under the following conditions: 25 cycles (DR4 and DR5) or 30 cycles (DcR-2, Bax, Bid)

of denaturation at 94 C for 30 s, annealing at 56 C or 59 C (for Bax and Bid) for 30 s, and extension at 72 C for 90 s The expected sizes of RT– PCR amplification fragments are indicated at the right of the panel The mRNA levels were quantified by densitometry and normalized to basal b-actin mRNA expression and the results are shown in (C) *, statistically significant result (P < 0.05) (D) Cells were treated with or without etoposide (8 lgÆmL)1) for 16 h and the cell lysates were then used to detect the protein level of DR4, DR5, DcR-2 and Bax Actin was used as the loading control.

that p53 was able to upregulate DR4 and DR5, but not Bax,

in the human lung cancer cells cotreated with TRAIL and

CD437 [38] Similarly, Kirsten also reported that the

DNA-damaging agent, N-methyl-N¢-nitro-N-nitrosoguanidine

(MNNG), did not affect the expression of Bax [42],

implying that upregulation of Bax upon p53 activation

may be cell-type dependent Recent studies indicated that

cross-talk might exist between the two pathways by the Bid

protein, a pro-apoptotic protein of the Bcl-2 family The

BH3 domain of tBid (a cleaved form of Bid) is required to

trigger Bax to release cytochrome c from mitochondria

[43,44]; therefore, tBid is believed to be the linkage protein

between the death receptor pathway and the mitochondrial

pathway Kim and co-workers have demonstrated that

TRAIL-induced translocation of Bax, subsequent to the

cleavage of Bid, is vital in the TRAIL-induced

mitochond-rial pathway [45] We therefore examined (by Western blotting) the protein level of tBid in QGY-7703 cells treated with TRAIL or etoposide As shown in Fig 4B, the level of tBid was markedly increased with the incubation time when cells were treated with TRAIL alone, whereas treatment with etoposide alone did not affect the protein level of tBid

We also examined the expression of tBid and Bax by combined treatment of TRAIL and etoposide; these results are shown in Fig 4C The protein levels of both tBid and Bax increased with the incubation time, and these results are

in agreement with the results shown in Figs 3D and 4B Taken together, our results show that the increased level of active tBid resulting from treatment with TRAIL may link the death receptor pathway to the mitochondrial pathway

by interaction with upregulated Bax

Enhanced release of cytochromec and Smac/DIABLO

by combined treatment with TRAIL and etoposide

It is well established that mitochondria play a vital role in apoptosis and induce cell death by releasing cytochrome c [46,47] and Smac/DIABLO Our results also implied that the mitochondrial pathway is critical for contributing to the synergistic effect of TRAIL and etoposide in

QGY-7703 cells To test whether mitochondria are involved in the co-operative effect of TRAIL and etoposide, we treated QGY-7703 cells with and without etoposide (8 lgÆmL)1) in the presence or absence of TRAIL (10 ngÆmL)1) for 16 h to determine the release of cytochrome c and Smac/DIABLO As expected, little, if any, cytochrome c and Smac/DIABLO were detected in the cytoplasm when treated with TRAIL alone (Fig 5A),

as there was no increase in the expression of Bax Treatment with etoposide alone (Fig 5A) effected some release of cytochrome c and Smac/DIABLO Further-more, both cytochrome c and Smac/DIABLO showed

a marked release from the mitochondria by combined treatment with TRAIL and etoposide (Fig 5A) Similarly

to cytochrome c and Smac/DIABLO, the expression of Bax was also notably increased by cotreatment with TRAIL and etoposide compared with that of TRAIL or etoposide alone (Fig 5A) Smac/DIABLO promotes the activation of caspases, such as procaspase-9 and caspase-3,

by binding to the inhibitor of apoptosis proteins and thus disrupts linkage of the caspase–inhibitor of apoptosis proteins complex during apoptosis [48–50] Recently, Deng et al reported that TRAIL-induced apoptosis requires Bax-dependent mitochondrial release of Smac/ DIABLO [51] They have shown that the release of Smac/ DIABLO is required to remove the inhibitory effect of X-linked inhibitor of apoptosis protein (XIAP) and allow apoptosis to proceed, and thus mediates the contribution

of the mitochondrial pathway to death receptor-mediated apoptosis To our knowledge, ours is the first report to demonstrate that combined treatment of TRAIL and etoposide results in an enhanced release of

Smac/DIAB-LO in the hepatocellular carcinoma cell system zVAD-FMK is the general caspase inhibitor and used to prevent caspase-dependent apoptosis We demonstrated that zVAD-FMK is able to prevent the early apoptosis induced

by TRAIL plus etoposide (Fig 1C,e) To investigate whether the release of cytochrome c and Smac/DIABLO,

Fig 4 Activation of Bid in response to tumour necrosis factor-related

apoptosis-inducing ligand (TRAIL), but not to etoposide (A) Total

RNA was extracted from QGY-7703 cells treated with TRAIL

(10 ngÆmL)1) for the indicated time-periods and then RT–PCR was

performed to evaluate the levels of mRNA for Bax The housekeeping

gene, b-actin, was used as an internal control for ensuring that an equal

amount of template was used (B) and (C) QGY-7703 cells were

exposed to TRAIL (10 ngÆmL)1) alone, etoposide (8 lgÆmL)1) alone,

or TRAIL and etoposide together, for the indicated time-periods and

the cell lysates were subject to Western blot analysis for detection of

truncated Bid (tBid) or Bax.

or the expression of Bax, could also be inhibited by

zVAD-FMK, QGY-7703 cells were exposed to TRAIL

plus etoposide in the presence or absence of zVAD-FMK

Whole-cell protein lysates or cytosolic protein fractions

were subject to Western blot analysis As shown in

Fig 5B, the release of cytochrome c and Smac/DIABLO

were significantly decreased in the presence of

zVAD-FMK However, the decrease of Bax in the presence of

zVAD-FMK was not as marked as that of cytochrome c

and Smac/DIABLO when compared with Bax expression

in the absence of zVAD-FMK The exact mechanism underlying this discrepancy remains unclear Nevertheless, our results are similar to those reported by Adrain et al [52] They have proposed a model for explaining how the caspase inhibitor, zVAD-FMK, could inhibit the release

of cytochrome c and Smac/DIABLO from mitochondria They claimed that release of Smac/DIABLO and cyto-chrome c requires downstream caspase activation Based

on this model, the results shown in Fig 5B are plausible,

as zVAD-FMK reduced the release of cytochrome c and Smac/DIABLO by inhibiting the downstream caspase activation Bax is upstream of cytochrome c and Smac/ DIABLO, therefore zVAD-FMK had little effect on its expression These results also confirmed that mitochondria might play a key role in contributing to the synergistic effect of TRAIL and etoposide in QGY-7703 cells

Involvement of caspase activation in the enhancement

of TRAIL-induced apoptosis by etoposide Caspases play key roles in apoptosis triggered by various pro-apoptotic signals To identify which caspase is involved in the process of apoptosis of QGY-7703 cells, and whether the activation of caspase is enhanced during the combined treatment with TRAIL and etoposide,

Fig 6 The enhanced cleavage of caspases by combined treatment with tumour necrosis factor-related apoptosis-inducing ligand (TRAIL)and etoposide Total cellular lysates were extracted from QGY-7703 cells treated with etoposide (8 lgÆmL)1), with or without TRAIL (10 ngÆmL)1), for 24 h Western blot analysis was performed to assess the processing of caspase-7, -9, -3, -8 and poly ADP-ribose polymerase (PARP) Human actin was used as the loading control +, treated; –, untreated.

Fig 5 Increased mitochondrial release of cytochrome c and second

mitochondria-derived activator of caspase (Smac)/DIABLO during the

synergistic induction of apoptosis by tumour necrosis factor-related

apoptosis-inducing ligand (TRAIL)and etoposide (A) Cell lysates were

isolated from QGY-7703 cells treated with etoposide (8 lgÆmL)1), with

or without TRAIL (10 ngÆmL)1), for 16 h and assessed for Bax

expression (cell lysate) and the contents of released cytochrome c and

Smac/DIABLO (cytosolic fractions) by immunoblot analysis using

respective antibodies Actin was used as the loading control (B)

QGY-7703 cells were exposed to the combination of etoposide (8 lgÆmL)1)

and TRAIL (10 ngÆmL)1), with or without the caspase inhibitor

N-benzyloxycarbonyl-Val-Ala-Asp-fluoromethylketone (zVAD-FMK)

(100 l M ), for 16 h and both the cell lysate and the cytosolic fractions

were subject to Western blot analysis for detection of the expression of

Bax (cell lysate) and the release of cytochrome c and Smac/DIABLO

(cytosolic fractions) Actin was used as the loading control +, treated;

–, untreated.

(10 ngÆmL)1) or etoposide (8 lgÆmL)1), or the

combina-tion of both, for 24 h (Fig 6) Etoposide alone and

TRAIL alone slightly activated the initiators caspase-8

and -9, but their activation was much more enhanced

when cells were cotreated with TRAIL plus etoposide

Similar results were also obtained for effector caspases,

caspase-3 and -7, as seen in Fig 6 The activation of

caspase-3 and -7 was further confirmed by the accelerated

cleavage of PARP, a direct downstream substrate of

caspase-3 and -7 As shown in Fig 6, cotreatment with

TRAIL plus etoposide resulted in an enhanced cleavage

of PARP compared to that obtained by treatment with

either TRAIL or etoposide alone We noted that

treat-ment with etoposide alone also resulted in some cleavage

of procaspase-8; this observation has been documented

previously [53,54], where it was concluded that caspase-8

can be processed by anticancer drugs, independently of

death receptors In general, activation of the caspase

cascade requires both initiator caspases such as caspase-8

and -9, and effector caspases, such as caspase-3 and -7

[55] The death ligands and the chemotherapeutic agents

are two distinct classes of signals used to induce apoptosis

and activate the caspase cascade Caspase-8 is known as

the initiator caspase in the death receptor signal pathway,

while caspase-9 is associated more with the mitochondrial

pathway, which is activated by many chemotherapeutic

drugs [56] Caspase-3 and -7 are the major effector

caspases and act downstream of caspase-8 and -9 Our

results have demonstrated that cotreatment with TRAIL

and etoposide activated both the caspase-8- and

-9-mediated apoptotic pathway, resulting in augmentation of

the apoptotic death effect Shi and co-workers have also

reported similar results in human lung cancer cells treated

with TRAIL and CD437 [38] Taken together, we propose

a hypothetical model to illustrate the possible mechanism

by which TRAIL and etoposide synergistically augment apoptosis in QGY-7703 cells, and the detailed descriptions are outlined in Fig 7

Acknowledgements

This research was supported by the Key Project Fund (KSCX2-2-01-004), a special grant (to M W.) from the Chinese Academy of Sciences, grants from the National Natural Science Foundation of China (30121001 and 90208027) and a 973 grant (2002CB713700) from the Ministry of Science and Technology of China.

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