Tài liệu Báo cáo khoa học: Upregulation of DR5 by proteasome inhibitors potently sensitizes glioma cells to TRAIL-induced apoptosis doc

Here we investigated the sensitivity of a panel of glioma cell lines U87, U251, U343, U373, MZ-54, and MZ-18 to apoptosis induced by the death receptor ligand tumor necrosis factor-relat

sensitizes glioma cells to TRAIL-induced apoptosis

Holger Hetschko1, Valerie Voss1, Volker Seifert1, Jochen H M Prehn2 and Donat Ko¨gel1

1 Department of Neurosurgery, Centre for Neurology and Neurosurgery, Johann Wolfgang Goethe University Clinics, Frankfurt ⁄ Main, Germany

2 Department of Physiology and Medical Physics, Royal College of Surgeons in Ireland, Dublin, Ireland

Gliomas are the most common and malignant primary

brain tumors in humans Glioblastoma multiforme is

the highest-grade as well as the most aggressive and

frequent glioma [1] Because gliomas are characterized

by a diffuse infiltrative growth into the surrounding

brain tissue, complete surgical resection of glioblas-toma multiforme tumors is virtually impossible [2] In addition, high-grade gliomas exhibit only limited sensi-tivity to ensuing multimodal treatment with radio-therapy and chemoradio-therapy [2], which in large part is

Keywords

apoptosis; astrocytoma; death receptor;

proteasome; stress kinase

Correspondence

D Ko¨gel, Experimental Neurosurgery,

Johann Wolfgang Goethe University Clinics,

Theodor-Stern-Kai 7, Neuroscience Centre,

D-60590 Frankfurt am Main, Germany

Fax: +49 69 6301 5575

Tel: +49 69 6301 6940

E-mail: koegel@em.uni-frankfurt.de

(Received 28 January 2008, revised 19

February 2008, accepted 21 February 2008)

doi:10.1111/j.1742-4658.2008.06351.x

This study was undertaken to explore the potential of new therapeutic approaches designed to reactivate cell death pathways in apoptosis-refrac-tory gliomas and to characterize the underlying molecular mechanisms of this reactivation Here we investigated the sensitivity of a panel of glioma cell lines (U87, U251, U343, U373, MZ-54, and MZ-18) to apoptosis induced by the death receptor ligand tumor necrosis factor-related apopto-sis-inducing ligand (TRAIL), TRAIL in combination with gamma irradia-tion, and TRAIL in combination with proteasome inhibitors (MG132 and epoxomicin) Analysis of these six glioma cell lines revealed drastic differ-ences in their sensitivity to these treatments, with two of the six cell lines revealing no significant induction of cell death in response to TRAIL alone Interestingly, the proteasome inhibitors MG132 and epoxomicin were capable of potentiating TRAIL-induced apoptosis in TRAIL-sensitive U87 and U251 cells and of reactivating apoptosis in TRAIL-resistant U343 and U373 cells In contrast, gamma irradiation had no synergistic effects with TRAIL in the two TRAIL-resistant cell lines RNA interference against death receptor 5 (DR5) revealed that reactivation of TRAIL-induced apoptosis by proteasome inhibitors depended on enhanced tran-scription and surface expression of DR5 Transient knockdown of the transcription factor GADD153⁄ C ⁄ EBP homologous protein and applica-tion of the synthetic c-Jun N-terminal kinase inhibitor SP600125 indicated that enhanced DR5 expression occurred independently of GADD153⁄

C⁄ EBP homologous protein, but required activation of the c-Jun N-termi-nal kinase⁄ c-Jun signaling pathway Novel therapeutic approaches using TRAIL or agonistic TRAIL receptor antibodies in combination with pro-teasome inhibitors may represent a promising approach to reactivate apop-tosis in therapy-resistant high-grade gliomas

Abbreviations

Ac-DEVD-AMC, acetyl-DEVD-7-amido-4-methylcoumarin; CHOP, C⁄ EBP homologous protein; DR4, death receptor 4; DR5, death receptor 5; FACS, fluorescence-activated cell sorting; GAPDH, glyceraldehyde-3-phosphate dehydrogenase; JNK, c-Jun N-terminal kinase; NF-jB, nuclear factor kappa B; PI, proteasome inhibitor; siRNA, small interfering RNA; TRAIL, tumor necrosis factor-related apoptosis-inducing ligand.

caused by inherent and potent apoptosis resistance [3].

Clearly, overcoming this resistance by approaches

designed to reactivate apoptosis in malignant glioma

has important implications for the development of

novel glioma therapies

Tumor necrosis factor-related apoptosis-inducing

ligand (TRAIL), a member of the tumor necrosis factor

superfamily, has been shown to be a promising

candi-date for novel anticancer therapies [4] Interestingly,

TRAIL is capable of inducing apoptosis in a wide

range of tumor cells, but not in normal tissue This

tumor-selective cytotoxicity has been shown for glioma

cells in comparison to non-transformed astrocytes

in vitro [5,6] The physiological function of TRAIL

remains unclear, although studies suggest that TRAIL

plays a key role in tumor surveillance by the immune

system [7] TRAIL induces apoptosis by binding to

its agonistic cognate cell surface receptors death

receptor 4 (DR4)⁄ TRAIL R1 and death receptor 5

(DR5)⁄ TRAIL R2, and this then leads to recruitment

of the adaptor protein Fas-associated death domain

and the initiator caspases 8 and

procaspase-10, and formation of a membrane-bound multiprotein

complex called death-inducing signaling complex [4]

Death-inducing signaling complex formation then

leads to autoproteolytic cleavage of procaspase-8 and

procaspase-10, and subsequent downstream

activa-tion of the extrinsic and intrinsic pathways of apoptosis

[4]

Despite the considerable interest raised by the

poten-tial of TRAIL in novel anticancer therapies,

accumu-lating evidence suggests that TRAIL alone may not be

sufficient to efficiently activate apoptosis in many types

of cancers, inluding gliomas [8] Hence, much effort

has been made to establish new modalities for

com-bined treatments with TRAIL and other antineoplastic

agents or apoptosis inducers to improve the potency of

TRAIL-based therapeutic approaches

Proteasome inhibitors (PIs) represent a highly

prom-ising novel class of anticancer agents [9] PIs are

already in clinical use, as bortezomib (PS-341⁄

Velcade) has been approved for the treatment of

multi-ple myeloma [10] Recent evidence suggests that PIs

also might be efficient agents for the treatment of solid

tumors, such as lung and prostate cancer [11,12]

This study reveals that TRAIL-induced apoptosis

can be efficiently reactivated in TRAIL-resistant

malig-nant glioma cell lines by combined treatment with PIs

Furthermore, we show that reactivation of

TRAIL-induced apoptosis by proteasome inhibition induces

the c-Jun N-terminal kinase (JKN)⁄ c-Jun stress

signal-ing pathway and requires enhanced JNK⁄

c-Jun-depen-dent surface expression of DR5

Results

Synergistic effects of combined treatment with TRAIL and gamma irradiation

To analyze the sensitivity of high-grade gliomas to cell death induced by the death ligand TRAIL, we employed a panel of six grade III–IV glioma cell lines (U87, U251, U343, U373, MZ-18, and MZ-54) In an initial experiment, the cells were treated for 48 h at a final concentration of 250 ng TRAILÆmL)1 (Fig 1A) Surprisingly, only two of six cell lines (U87 and U251) significantly responded to TRAIL treatment as measured by annexin-V–FLUOS⁄ propidium iodide staining and flow cytometry (Fig 1A) Prolonged incu-bation for up to 96 h also did not induce detectable cell death in the four TRAIL-resistant cell lines (data not shown)

As gamma irradiation is an existing component of current glioma therapies, and as activation of TRAIL receptors and DNA damage were shown to have syner-gistic death-inducing effects in other types of cancer [13], we investigated whether similar effects could also

be observed in glioma cells Cell lines U87, U343 and U373 were subjected to gamma irradiation with single doses of 10 Gy and 20 Gy respectively Twenty-four hours postirradiation, the cultures were treated with

250 ngÆmL)1TRAIL for an additional 24 h, after which cell death was measured by fluorescence-activated cell sorting (FACS) analysis (Fig 1B) In comparison to the controls, a dose of 10 Gy had no effect on cell viability, either alone or in combination with TRAIL (data not shown) The higher dose of 20 Gy induced significant cell death in all three cell lines after 48 h ( 20–30%), and was capable of potentiating TRAIL-induced cell death in the TRAIL-sensitive cell line U87 However, in U343 and U373 cells, there was no significant synergis-tic effect of TRAIL and gamma irradiation, indicating that the activation of DNA damage-induced signaling pathways was not sufficient to reactivate TRAIL sensi-tivity in the TRAIL-resistant cell lines (Fig 1B) It is of note that this lack of apoptosis reactivation was inde-pendent of the p53 status of these cells, as U343 cells, but not U373 cells, have been shown to express func-tional p53 [14,15]

PIs potently reactivate TRAIL-induced apoptosis

in glioma cells Next, we investigated the synergistic effects of TRAIL and PIs in our glioma cell lines For that purpose, we employed two different PIs in combination with TRAIL: MG132, a potent reversible inhibitor targeting

the 26S complex of the proteasome [16], and

epoxomi-cin, a highly specific and irreversible inhibitor of

several hydrolyzing activities of the proteasome [17],

at concentrations of 2.5 lm and 50 nm respectively

(Fig 2) Whereas treatment with MG132 alone had a

moderate cytotoxic effect in three cell lines (U87,

U373, and MZ-54), treatment with epoxomicin

signifi-cantly induced cell death in only two of six cell lines

(U373 and MZ-54) (Fig 2) Interestingly, both PIs

potently enhanced TRAIL-induced apoptosis in the

two TRAIL-sensitive cell lines (U87 and U251), and

were able to reactivate apoptosis in four

TRAIL-resis-tant cell lines (U343, U373, MZ-54, and MZ-18) It is

of note that all six investigated cell lines were

previ-ously shown to express DR5, whereas DR4 expression

was undetectable in U251, U373 and MZ-54 cells [18]

Furthermore, reactivation of TRAIL-induced cell

death did not depend on functional p53, as it was also

observed in mutant p53 expressing U373 cells

PIs potently induce expression of DR5

in glioma cells

To elucidate the underlying molecular mechanisms of

the observed synergistic effects of PIs, we focused on

the transcriptional activation of pro-apoptotic genes after proteasome inhibition with MG132 and epoxo-micin Samples of cells exposed to gamma irradiation served as a control for p53-dependent gene activation Although we found markedly enhanced DR5 trans-criptional activation after proteasome inhibition and gamma irradiation in all four cell lines investigated (Fig 3A), there was no evidence for activation of DR4 by any stimulus However the stress-activated pro-apoptotic transcription factors C⁄ EBP homolo-gous protein (CHOP) and c-Jun were transcriptionally activated after proteasome inhibition in all four cell lines, whereas induction of CHOP and c-Jun was less prominent or even absent after gamma irradiation (Fig 3A)

Western blot analysis confirmed that DR4 protein levels were not elevated after proteasome inhibition or gamma irradiation (Fig 3B) Although we found a strong elevation of DR5 protein levels after protea-some inhibition, we could detect only moderately enhanced protein levels after gamma irradiation Simi-larly, the amount of CHOP protein was markedly increased by proteasome inhibition in all three cell lines, but in only one cell line (U87) after gamma irradiation

B A

Fig 1 Synergistic effects of combined treatment with TRAIL and gamma irradiation (A) TRAIL resistance is commonly observed in glioma cell lines U87, U251, U343, U373, MZ-54 and MZ-18 cells were treated with 250 ngÆmL)1TRAIL for 48 h Cells were stained with annexin-V–FLUOS⁄ propidium iodide, and cell death was measured with flow cytometry Data are means ± SEM from four independent cultures.

*P < 0.05 as compared to untreated control (B) TRAIL-sensitive cells (U87) and TRAIL-resistant cells (U343, U373) were subjected to gamma irradiation (20 Gy) and subsequently were treated with 250 ngÆmL)1TRAIL or were left untreated for an additional 24 h Cells were irradiated once in an Elekta SL75 ⁄ 5 linear accelerator (6 MeV) Apoptosis was quantified with annexin-V–FLUOS ⁄ propidium iodide staining and flow cytometry Data are means ± SEM from four independent cultures *P < 0.05 as compared to untreated control.#P < 0.05 as com-pared to treatment of the same cell line with gamma irradiation alone Similar results were obtained in three separate experiments.

Upregulation of DR5 by PIs contributes to the

reactivation of TRAIL-induced cell death

in glioma cells

Although the PIs prominently upregulated DR5

(Fig 3), it was not clear whether this elevated

expres-sion was responsible for the dramatic reactivation of

TRAIL-induced apoptosis observed in malignant

gli-oma cells To address this question, we knocked down

expression of DR5 by small interfering RNA (siRNA)

duplexes targeted against DR5 mRNA and studied the

effect on caspase activation after treatment of the cells

with TRAIL, MG132, and TRAIL in combination

with MG132 In initial experiments, U343 cells were

transfected with DR5 siRNA, treated with or without

2.5 lm MG132, and subjected to western blot analysis

(Fig 4A) Transfection with siRNA against DR5

resulted in a robust reduction of DR5 activation after

MG132 treatment as compared to MG132-treated

con-trol cells transfected with a nontargeting scrambled

siRNA (Fig 4A) In contrast, transfection with the siRNAs had no major effect on expression levels of DR4 To determine whether the changes in the amount

of DR5 protein in the protein lysates were also reflected by the levels of DR5 surface expression, we performed a flow cytometric analysis, which indeed confirmed enhanced DR5 surface expression after treatment of the cells with MG132 In analogy to the western blot data, DR5 surface expression was not completely abolished in DR5 siRNA-transfected cells treated with MG132, but was reduced to basal surface expression levels of scrambled siRNA-transfected con-trol cells (Fig 4B) Under the experimental conditions chosen, TRAIL alone caused only weak induction of caspase-3-like activity in the TRAIL-sensitive cell lines U87 and U251 (Fig 4C) Nevertheless, we observed a clear trend towards an apoptosis-inhibitory effect of the DR5 knockdown, indicating that basal expression

of DR5 is required for the TRAIL sensitivity in these cells Apoptosis induced by TRAIL in combination

Fig 2 Reactivation of TRAIL-induced apop-tosis after combined treatment with TRAIL and PIs TRAIL-sensitive cells (U87 and U251) and TRAIL-resistant cells (U343, U373, MZ-54, and MZ-18) were treated with

250 ngÆmL)1TRAIL and the PIs MG132 (2.5 l M ) and epoxomicin (50 n M ) or vehicle (dimethylsulfoxide) for 16 h Apoptosis was quantified with annexin-V–FLUOS ⁄ propidium iodide staining and flow cytometry Data are means ± SEM from four independent cul-tures *P < 0.05 as compared to dimethyl-sulfoxide-treated control.#P < 0.05 as compared to treatment of the same cell line with the respective PI alone Similar results were obtained in three separate experi-ments.

with MG132 was potently attenuated in

TRAIL-resis-tant U343 cells, TRAIL-sensitive U251 cells and

TRAIL-sensitive U87 cells after knockdown of DR5 in

comparison to the respective controls (Fig 4C) These

results suggest that enhanced surface expression of

DR5 plays a critical role in the reactivation of

TRAIL-induced apoptosis after proteasome inhibition

in glioma cells

CHOP is not involved in DR5 upregulation by PIs

and cell death induced by proteasome inhibition

plus TRAIL

It was recently reported that CHOP, an endoplasmic

reticulum stress-inducible member of the CCAAT⁄

enhancer-binding protein family, can act as an

upstream activator of DR5 in certain types of cancer

cells [19,20] In line with our previous findings [21],

we found CHOP to be strongly activated after

pro-teasome inhibition (Fig 3), and were therefore

inter-ested in whether CHOP was also involved in DR5

upregulation by PIs in glioma cells To determine

this, U343 cells were transfected with siRNA duplexes

targeted against CHOP or with nontargeting

scram-bled siRNA, and then treated with MG132 (Fig 5A)

Western blot analysis revealed that although CHOP

expression was knocked down significantly in the

CHOP siRNA-transfected cells as compared to the scrambled siRNA-transfected control cells, the activa-tion of DR5 after MG132 treatment was not affected

by the knockdown (Fig 5A) Furthermore, the knockdown of CHOP did not result in a significant attenuation of apoptosis induced by TRAIL plus MG132 in CHOP siRNA-transfected cells as com-pared to scrambled siRNA-transfected control cells (Fig 5B)

Inhibition of the JNK/c-Jun pathway abrogates PI-mediated DR5 upregulation and cell death Our data so far had suggested that PIs potently induced the expression of DR5 in glioma cells in a CHOP-independent manner Although the tumor sup-pressor p53 has also been implicated in regulation of DR5 expression [22], the p53-deficient cell line U373 showed a similiar increase in DR5 upregulation as the wild-type p53-expressing cell lines U87 and U343 after treatment with PIs in this study (Fig 3A,B), indicating that p53 was not responsible for the observed DR5 induction As a third potential upstream regulator of DR5, we next focused on the JNK⁄ c-Jun stress signal-ing pathway It is well established that PIs such as MG132 are capable of inducing the JNK⁄ c-Jun path-way [23] To address the issue of whether activation of

B

A

Fig 3 PIs enhance expression of DR5 (A)

DR5, CHOP and c-Jun are transcriptionally

induced after proteasome inhibition Cells

were either treated with 2.5 l M MG132,

50 n M epoxomicin or vehicle

(dimethylsulf-oxide) for 16 h or subjected to gamma

irradi-ation (20 Gy) and subsequently lysed 24 h

after exposure Expression of DR4 (28

cycles), DR5 (25 cycles), CHOP (28 cycles)

and GAPDH (25 cycles) was determined by

semiquantitative RT-PCR For detection of

c-Jun expression, RT-PCR with GAPDH

serving as an internal control (in the same

PCR reaction) was performed (30 cycles for

c-Jun and 30 cycles for GAPDH) Similar

results were obtained in at least three

sepa-rate experiments (B) Western blot analysis

of DR4, DR5 and CHOP expression levels.

Forty micrograms of protein were loaded

onto each lane, with a-tubulin serving as a

loading control Similar results were

obtained in two separate experiments.

JNKs and c-Jun contributes to PI-dependent DR5

upregulation in human glioma cells, we investigated

the effect of MG132 on DR5 upregulation in the

pres-ence of the JNK-specific inhibitor SP600125 by

wes-tern blot analysis At concentrations of 10–30 lm,

SP600125 abrogated the MG132-induced increase in

phosphorylated c-Jun levels significantly (Fig 6A) We

also observed that in combination with MG132,

SP600125 effectively blocked MG132-induced DR5

expression in a dose-dependent manner in U251 cells,

and this was subsequently confirmed for the highest

concentration used (30 lm) in U343 cells (Fig 6B)

There was no detectable effect of SP600125 on

MG132-triggered induction of CHOP, suggesting that

the AP-1 site in the CHOP promoter [24] is not required for enhanced CHOP expression after protea-some inhibition, and lending further support to the notion that the observed DR5 upregulation occured in

a CHOP-independent manner To analyze the rele-vance of JNK⁄ c-Jun-dependent DR5 upregulation in cell death triggered by TRAIL in combination with MG132, we again performed caspase assays Blocking the JNK⁄ c-Jun signaling pathway before treatment of the cells with MG132 led to a significant decrease of caspase-3-like activity induced by TRAIL plus MG132

in both TRAIL-sensitive and TRAIL-resistant glioma cells (Fig 6C) These results strongly suggest a promi-nent role of the JNK⁄ c-Jun signaling pathway in

C

Fig 4 RNA interference against DR5 effi-ciently protects cells from TRAIL-induced apoptosis after proteasome inhibition Twenty-four hours after transfection with scrambled control siRNA or DR5 siRNA, TRAIL-resistant U343 cells were treated with 2.5 l M MG132 or dimethylsulfoxide for

16 h (A) Analysis of DR5 and DR4 expres-sion levels by western blotting a-Tubulin served as a loading control Similar results were obtained in two separate experiments (B) Analysis of cell surface expression of DR5 after RNA interference against DR5 (DR5) or treatment with control siRNA (scr), subsequent treatment with 2.5 l M MG132

or dimethylsulfoxide (16 h), and staining with a specific goat anti-DR5 IgG Unspecific goat IgG served as isotype control The experiment was repeated twice with similiar results (C) Knockdown of DR5 inhibits apoptosis after treatment with TRAIL and MG132 Following transfection with DR5 siRNA (DR5) and control siRNA (scr), cells were treated with dimethylsulfoxide (con-trol), 2.5 l M MG132, TRAIL (250 ngÆmL)1)

or TRAIL in combination with MG-132 for an additional 16 h, after which the cells were harvested and whole cell lysates were moni-tored for caspase-3-like activity by measur-ing cleavage of the fluorogenic substrate Ac-DEVD-AMC (10 l M ) Data are means ± SEM from four to eight indepen-dent cultures *P < 0.05 as compared to dimethylsulfoxide-treated control Similar results were obtained in two separate experiments.

upregulation of DR5 and resensitization to apoptosis

after proteasome inhibition

Discussion

The high resistance of malignant gliomas to the

cur-rently used radiation therapy and chemotherapy

proto-cols is a persistent obstacle to the improvement of the

outcome in glioma patients Hence, a much effort has

been made in recent years to obtain more data on the

molecular mechanisms underlying gliomagenesis and

therapy resistance of gliomas, with the aim of

develop-ing more efficient and target-specific therapies

The death receptor ligand TRAIL and agonistic

TRAIL-R antibodies are being considered as novel

and promising therapeutic agents for the treatment of hematological malignancies and solid tumors, includ-ing gliomas Despite the described tumor-selective pro-apoptotic properties of TRAIL, many cancer cells are innately resistant to TRAIL In line with previous studies [6,25], all 18 glioma cell lines investigated in this study exhibited expression of DR5, but four of six cell lines showed no significant response to TRAIL

In order to identify synergistic treatments to modu-late TRAIL sensitivity and to reactivate apoptosis in glioma cells, we compared the effects of already exist-ing treatment modalities (gamma irradiation) with PIs (MG132 and epoxomicin), a new class of chemothera-peutic drugs with tremendous therachemothera-peutic potential [9] The correct functioning of the ubiquitin–proteasome pathway is essential for the degradation of the major-ity of intracellular proteins and is implicated in many cellular processes, including regulation of apoptosis Both epoxomicin and MG132 were able to potently enhance apoptosis in the TRAIL-sensitive cell lines Both PIs increased apoptosis  5–6-fold in the TRAIL-sensitive cell lines U87 and U251, and even at subtoxic levels they were able to reactivate apoptosis

in both TRAIL-resistant cell lines (U343 and U373)

It is widely accepted that PIs can act on mutiple cellu-lar targets implicated in regulation of apoptosis [20,21,26,27] However, despite abundant evidence for the therapeutic potential of PIs in a variety of malig-nancies, the relevant signaling pathways leading to apoptosis triggered by proteasome inhibition seem to vary substantially between different types of cancer In some types of cancer, such as prostate cancer and leu-kemia, upregulation of DR5 seems to play a critical role in the potentiating effects of PIs on TRAIL-induced cell death [20,28,29] Our data clearly indicate that treatment with PIs potently elevated DR5 expres-sion at the mRNA and protein levels in glioma cells, whereas gamma irradiation induced only a moderate increase in DR5 protein levels, even in the wild-type p53-expressing cell lines U87 and U343 Enhanced pro-tein levels and surface expression of DR5 after PI treatment might be caused by a cumulative effect of transcriptional induction and decreased degradation of DR5 protein, thus providing an explanation for the high efficiency of PIs in reactivation of TRAIL-depen-dent cell death observed in this study, and also for the reduced potency of gamma irradiation in elevating DR5 protein levels

To assess the importance of DR5 in PI-triggered reactivation of TRAIL-dependent apoptosis, we per-formed transient RNA interference against DR5 expression Indeed, the knockdown of PI-triggered DR5 induction had a very potent effect on DR5

A

B

Fig 5 DR5 protein levels are not affected by RNA interference

against CHOP (A) Four hours after transfection with CHOP siRNA

(CHOP) and scrambled control siRNA (scrambled), TRAIL-resistant

U343 cells were treated with 2.5 l M MG132 or dimethylsulfoxide

for 16 h CHOP and DR5 expression levels were analyzed by

wes-tern blotting a-Tubulin served as a loading control (B) Knockdown

of CHOP expression has no effect on TRAIL-induced apoptosis

after proteasome inhibition U343 cells were treated as described

in (A), and caspase-3-like activity was measured by Ac-DEVD-AMC

cleavage Data are means ± SEM from four to eight independent

cultures *P < 0.05 as compared to dimethylsulfoxide-treated

con-trol Similar results were obtained in two separate experiments.

surface expression levels and apoptosis induced by

TRAIL in combination with MG132 in U343 and

U251 cells These data suggest that, in contrast to

other cancer types, such as hepatocellular carcinoma

[30], transcriptional upregulation of DR5 plays a

piv-otal role in potentiation and reactivation of

TRAIL-induced apoptosis in glioma cells

We then addressed the question of which upstream

signaling pathways might lead to enhanced DR5

sur-face expression after PI treatment, and in line with

previous observations in other types of cancer cells

[21], we demonstrated that the pro-apoptotic

transcrip-tion factor CHOP was potently activated on the

tran-scriptional level by PIs in glioma cells Although

CHOP has been previously described as a putative

upstream regulator of DR5 in different types of cancer

cells [19,20], we did not observe any significant

CHOP-dependent effects on DR5 expression and cell death,

indicating that CHOP is not required for DR5

induc-tion triggered by PIs in glioma cells

Two other apoptosis-regulating transcription fac-tors whose activity is known to be modulated by PIs are p53 and nuclear factor kappa B (NF-jB) Although the majority of reports suggest that PIs induce a p53-dependent form of apoptosis in most cancer cell types, such as leukemia cells [27], as well

as melanoma, colon cancer and myeloma cells [21,26,31], PIs have been shown to induce p53-inde-pendent apoptosis in glioma cells [32,33] In line with these observations, enhanced DR5 expression did not depend on the p53 status (wild-type or mutated) in the three glioma cell lines investigated in this study

As IjBa, the endogenous inhibitor of the transcrip-tion factor NF-jB, is continuously degraded via the proteasome pathway, PIs act as indirect inhibitors of the antiapoptotic transcription factor NF-jB [34] However, we have previously shown that treatment of neuroblastoma and colon cancer cells with epoxomicin

is not associated with noticeable transcriptional

A

C

B

Fig 6 The JNK ⁄ c-Jun signaling pathway contributes to DR5 induction and apoptosis induced by TRAIL plus PIs in glioma cells (A) Inhibition

of JNK ⁄ c-Jun signaling downmodulates DR5 induction in a dose-dependent manner U251 cells were pretreated with the indicated concen-trations of the JNK inhibitor SP600125 or vehicle (dimethylsulfoxide) for 2 h and treated with 2.5 l M MG132 or dimethylsulfoxide for an addi-tional 16 h Whole cell lysates were analyzed by western blotting for levels of phosphorylated c-Jun and DR5 a-Tubulin served as a loading control (B) SP600125 downmodulates PI-triggered DR5 induction in U343 cells U343 cells were pretreated with 30 l M SP600125 or di-methylsulfoxide for 2 h, and subsequently treated with 2.5 l M MG132 for an additional 16 h in the presence or absence of 30 l M

SP600125 Protein levels of phosphorylated c-Jun, DR5 and CHOP were analyzed by western blotting a-Tubulin served as a loading control (C) SP600125 inhibits apoptosis induced by TRAIL plus MG132 in three different glioma cell lines U87, U251 and U343 cells were treated

as described in (B) Caspase-3-like activity was measured by Ac-DEVD-AMC cleavage Data are means ± SEM from four to eight indepen-dent cultures *P < 0.05 as compared to dimethylsulfoxide-treated control Similar results were obtained in three separate experiments.

changes of antiapoptotic NF-jB target genes such as

Bcl-2, Bcl-xL, and the inhibitors of apoptosis (IAPs)

[21] In addition, it was recently reported that most

glioblastoma cell lines exhibit only low constitutive

NF-jB activity, and inhibition of NF-jB did not

sig-nificantly influence apoptosis induced by DNA

dam-age, TRAIL and PIs in glioma cells in this study [35]

Although inactivation of NF-jB has been suggested to

play a major role in the antitumorigenic effect of the

PI bortezomib (Velcade⁄ PS-341) in multiple myeloma

[36] and melanoma cells [26], inhibition of NF-kB is

not required to sensitize hepatocellular carcinoma cells

and lymphoma cells to apoptosis [37,38], again

empha-sizing the cancer type-specific effects of PIs

As PIs are also known to trigger the stress-induced

JNK⁄ c-Jun pathway [23,33], we finally asked the

question of whether this pathway might be involved

in the observed DR5 induction triggered by PIs

RT-PCR analysis revealed a potent upregulation of

c-Jun at the transcriptional level, suggesting upstream

activation of JNKs, phosphorylation of c-Jun and

enhanced c-Jun expression by an autoregulatory

feed-forward mechanism [39] Indeed, application of the

synthetic JNK inhibitor SP600125 significantly

reduced levels of phosphorylated c-Jun in a

dose-dependent manner after PI treatment in glioma

cells, whereas it had no discernible effect on CHOP

induction Inhibition of the JNK⁄ c-Jun pathway with

SP600125 also significantly downmodulated

PI-induced DR5 induction and cell death triggered by

TRAIL in combination with MG132

In conclusion, our data emphasize the importance of

the JNK⁄ c-Jun signaling cascade in transcriptional

induction of DR5 and resensitization to

TRAIL-induced apoptosis in malignant glioma cells, and

sug-gest that new target-specific therapeutic approaches

employing PIs in combination with TRAIL may

repre-sent a highly promising strategy to reactivate apoptosis

in therapy-resistant high-grade astrocytomas

Experimental procedures

Materials

The caspase substrate

acetyl-DEVD-7-amido-4-methyl-coumarin (Ac-DEVD-AMC) was purchased from Bachem

(Heidelberg, Germany) MG132 and epoxomicin were

pur-chased from Sigma-Aldrich (Deisenhofen, Germany) JNK

inhibitor II (SP600125) was from Merck Biosciences

(Darmstadt, Germany) Recombinant human TRAIL was

from PeproTech Inc (Rocky Hill, NJ, USA) All other

chemicals were of analytic grade purity and were from

Sigma-Aldrich (Deisenhofen, Germany)

Cell lines and culture

Human glioma cell lines U87, U251, U343, and U373, as well as the newly established glioma cell lines, were main-tained in DMEM with 10% heat-inactivated fetal bovine serum, 100 UÆmL)1 penicillin, and 100 mgÆmL)1 strepto-mycin Human glioma cell lines MZ-18 and MZ-54 were established from a primary glioblastoma and a recurrent grade IV tumor, respectively To isolate glioma cells, tumor specimens were homogenized, suspended in NaCl⁄ Pi and centrifuged at 400 g Pellets were resuspended in 10 mL of medium, and plated into Petri dishes Cultivation was per-formed under standard conditions at 37C and a humidi-fied 5% CO2 atmosphere When confluent monolayers had been obtained, tumor-derived cells were trypsinized and replated in new Petri dishes for serial passaging All newly established cell lines were analyzed for glial fibrillary acidic protein expression by immunostaining with a monoclonal glial fibrillary acidic protein IgG (R&D Systems, Wiesbaden, Germany) Isotypic primary antibody (Serotec, Du¨sseldorf, Germany) was used as control

RT-PCR

Extraction of total cellular RNA, reverse transcription and PCR were performed as previously described [40] Primer sequences were as follows: CHOP-sense, 5¢-GGT CCT GTC TTC AGA TGA AAA TG-3¢; CHOP-antisense, 5¢-CCT GGT GCA GAT TCA CCA TTC-3¢; c-Jun-sense, 5¢-TGA CTG CAA AGA TGG AAA CG-3¢; c-Jun-antisense,

5¢-AGA GAG AAG TCC CTG CAC CA-3¢; DR4-antisense,

DR5-anti-sense, 5¢-TAC GGC TGC AAC TGT GAC TC-3¢; glyceral-dehyde-3-phosphate dehydrogenase (GAPDH)-sense; 5¢-CCT GAC CTG CCG TCT AGA AA-3¢; GAPDH-anti-sense, 5¢-TTA CTC CTT GGA GGC CAT GT-3¢

SDS/PAGE and western blotting

SDS⁄ PAGE and western blotting were performed as described elsewhere [40] The resulting blots were probed with rabbit polyclonal anti-DR5 serum (Imgenex, San Diego,

CA, USA) diluted 1 : 200, rabbit polyclonal anti-DR4 serum (ProSci, Poway, CA, USA) diluted 1 : 500, rabbit polyclonal anti-phospho-c-Jun serum (Cell Signaling Technology, Danvers, MA, USA) diluted 1 : 800, mouse monoclonal anti-CHOP IgG diluted 1 : 200, or mouse monoclonal anti-a-tubulin IgG (clone DM 1A; Sigma), diluted 1 : 5000

Determination of caspase-3-like protease activity

DEVDase (caspase-3-like) activity was determined as previ-ously described [40]

Flow cytometry

For cell death analysis, cells were stained with

annexin-V–FLUOS⁄ propidium iodide (Roche Applied Science,

Mannheim, Germany), following the manufacturer’s

instructions For analysis of DR5 surface expression, cells

were stained with goat polyclonal anti-DR5 IgG (Axxora,

Gru¨nberg, Germany) and a goat IgG isotype control

(SouthernBiotech, Birmingham, AL, USA), respectively,

according to the manufacturer’s instructions In all cases, a

minimum of 104events per sample were acquired Flow

cytometric analyses were performed on a FACScan (BD

Biosciences; Heidelberg, Germany) followed by analysis

using cellquest and winmdi software

Gene silencing using siRNA

The following annealed double-stranded siRNAs from

Dharmacon (Chicago, IL, USA) were used: CHOP

siGe-nome duplexes D-004819-01-0005 and D-004819-02-0005;

and DR5 siGenome duplexes D-004448-01-0005 and

D-004448-03-0005 Scrambled siRNA siCONTROL from

Dharmacon was used as a negative, nonsilencing control

Cells were transfected with 100 nm siRNAs using

siM-PORTER (Biomol, Hamburg, Germany) as described by

the manufacturer

Statistics

Data are given as means ± SEM For statistical

compari-son, a t-test or one-way ANOVA followed by a Tukey test

were employed using spss software (SPSS GmbH Software,

Munich, Germany) P-values smaller than 0.05 were

consid-ered to be statistically significant

Acknowledgements

The authors would like to thank Dr Sigrid Horn and

Monika Herr, Department of Neurosurgery, Mainz

University Clinics, for cell lines MZ-18 and MZ-54, Dr

Klaus Eberlein and Jussi Moog, Department of

Radia-tion Therapy and RadiaRadia-tion Oncology, Frankfurt

University Clinics, for help with the gamma irradiation

experiments, and Hildegard Schweers for excellent

technical assistance This study was supported by

the Wilhelm Sander Stiftung (grant 2005.067.1) to

D Ko¨gel and by Science Foundation Ireland to

J H M Prehn

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