Báo cáo Y học: Double-stranded RNA-activated protein kinase interacts with apoptosis signal-regulating kinase 1 Implications for apoptosis signaling pathways docx

Double-stranded RNA-activated protein kinase interacts withapoptosis signal-regulating kinase 1 Implications for apoptosis signaling pathways Takenori Takizawa1, Chizuru Tatematsu1and Yo

Double-stranded RNA-activated protein kinase interacts with

apoptosis signal-regulating kinase 1

Implications for apoptosis signaling pathways

Takenori Takizawa1, Chizuru Tatematsu1and Yoshinobu Nakanishi2

1 Department of Biochemistry, Institute for Developmental Research, Aichi Human Service Center, Kasugai, Aichi, Japan;

2

Graduate school of Medical Science, Kanazawa University, Kanazawa, Ishikawa, Japan

Double-stranded RNA-activated protein kinase (PKR), a

serine/threonine kinase, is activated in virus-infected cells

and acts as an antiviral machinery of type I interferons

PKR controls several stress response pathways induced by

double-stranded RNA, tumor necrosis factor-a or

lipo-polysaccharide, which result in the activation of

stress-acti-vated protein kinase/c-Jun NH2-terminal kinase and p38 of

the mitogen-activated protein kinase family Here we

showed a novel interaction between PKR and apoptosis

signal-regulating kinase 1 (ASK1), one of the members of

the mitogen-activated protein kinase kinase kinase family,

which is activated in response to a variety of

apoptosis-inducing stimuli PKR and ASK1 showed predominant

cytoplasmic localization in COS-1 cells transfected with both cDNAs, and coimmunoprecipitated from the cell extracts A dominant negative mutant of PKR (PKR-KR) inhibited both the apoptosis and p38 activation induced by ASK1 in vivo Consistently, PKR-KR inhibited the auto-phosphorylation of ASK1 in vitro, and exposure to poly(I)– poly(C) increased the phosphorylation of ASK1 in vivo These results indicate the existence of a link between PKR and ASK1, which modifies downstream MAPK

Keywords: ASK1; apoptosis; MAPK; PKR; signal trans-duction

The interferon-inducible, double-stranded RNA

(dsRNA)-activated protein kinase (PKR) is a serine/threonine kinase

ubiquitously expressed in mammalian cells [1,2] PKR is

activated by a variety of dsRNA molecules generated

during viral infection [3] Upon its activation, PKR

autophosphorylates and then phosphorylates eukaryotic

translational initiation factor 2 (eIF-2a) [4], thereby

inhi-biting cell growth or viral replication [5,6] Thus PKR

mediates the antiviral and antiproliferative actions of type I

interferons [6] On the other hand, catalytically inactive

mutants of PKR transform NIH-3T3 cells [7,8], while

overexpression of wild-type PKR induces apoptosis of

HeLa cells [9,10] PKR appears to up-regulate expression of

the apoptotic receptor Fas induced by viral infection [11,12]

Moreover, mouse embryonic fibroblasts deleted of the PKR

gene have been shown to resist apoptosis in response to

dsRNA, tumor necrosis factor-a (TNF-a) or

lipopolysac-charide (LPS) [13] PKR has been shown to play some role

in the activation of p38 mitogen activated protein kinases (MAPKs) and the stress-activated protein kinase (SAPK)/ c-Jun amino-terminal kinases (JNKs) that are strongly activated in response to TNF-a, dsRNA or LPS [13] However, the precise pathway linking PKR and the MAPK family remains to be elucidated

Apoptosis signal-regulating kinase 1 (ASK1) is a MAPK kinase kinase (MAPKKK) that acts upstreamof JNK and p38 MAPKs [14,15] ASK1 phosphorylates SEK1/MKK4

or MKK3/MKK6, one of the members of the MAPK kinase family, which in turn activates JNK or p38 MAPK, respectively [15] A wide variety of stress-related stimuli activate ASK1, including serumwithdrawal, TNF-a, react-ive oxygen species, microtubule-interfering agents, genoto-xic stress, and possibly Fas ligand [16] Overexpression of the wild type or constitutively active formof ASK1 induces cell death through signals involving the mitochondrial cell death pathway [17] ASK1 binds proteins associated with death receptors as TNF-receptor-associated proteins (TRAFs) or Daxx, which also results in MAPK activation [18,19] In the present study, we show that PKR interacts with ASK1 and modifies the ASK1 signaling pathway both

in vivoand in vitro These results suggest that PKR acts as a signal transducer by interacting with MAPKKKs, which then modifies the downstream MAPK cascade

M A T E R I A L S A N D M E T H O D S

Plasmids and DNA transfection Human PKR cDNA was kindly provided by A Hovanes-sian (Institut Pasteur, France) A mutant PKR cDNA

Correspondence to T Takizawa, Department of Biochemistry,

Institute for Developmental Research, Aichi Human

Service Center, Kasugai, Aichi 480-0392, Japan.

Fax: + 81 568 88 0829, Tel.: + 81 568 88 0829,

E-mail: takizawa@inst-hsc.pref.aichi.jp

Abbreviations: ASK1, apoptosis signal-regulating kinase 1; dsRNA,

double-stranded RNA; eIF-2a, eukaryotic translational initiation

factor 2a; EGFP, enhanced green fluorescence protein; FITC,

fluorescein isothiocyanate; LPS, lipopolysaccharide; MAPK,

mitogen activated protein kinase; PKR, double-stranded

RNA-acti-vated protein kinase; RITC, tetaramethyl rhodamine isothiocyanate;

DMEM, Dulbecco’s modified Eagle’s medium.

(Received 29 June 2002, revised 4 September 2002,

accepted 22 October 2002)

carrying a point mutation of K to R at position 296

(PKR-KR) was constructed as described [20] cDNAs for

human ASK1 and dominant negative mutant of ASK1

carrying a point mutation of K to M at position 709

(ASK-KM) were kindly provided by H Ichijo (Laboratory of Cell

Signaling, Tokyo Medical and Dental University) The

plasmid encoding PKR or PKR-KR fused to enhanced

green fluorescent protein (EGFP) (Clontech Laboratories,

Inc., Palo Alto, CA, USA) was described previously [21]

Human embryonic kidney 293 (HEK293), COS-1 and

NIH-3T3 cells were cultured in Dulbecco’s modified Eagle’s

medium (DMEM) supplemented with 10% fetal bovine

serum, and maintained under 5% CO2at 37C Cells were

transfected with 2 lg of plasmid DNA using 6 lL of

Lipofectamine-plus and 4 lL of Lipofectamine

(Gib-coBRL) according to the manufacturer’s instructions To

establish permanent transfectants, HEK293 cells were

diluted about 10-fold and replated in medium containing

750 lgÆmL)1of G418 two days after transfection, and then

drug-resistant colonies were isolated For microscopic

observation, cells were seeded on a cover glass and DNAs

were transfected as described above For in vivo labeling of

ASK1 or PKR, cells were washed with phosphate-free

DMEM, and then incubated in phosphate-free DMEM in

the presence of [32P]-orthophosphate (400 lCiÆmL)1) (ICN

Biomedicals, CA, USA) for the indicated period as

described in the figure legend The phosphorylation reaction

was resolved by SDS/PAGE and visualized by

autoradio-graphy Autoradiogramwas scanned and densitometric

analysis was performed with Kodak DIGITAL SCIENCE 1D

software (Eastman Kodak)

Indirect immunofluorescence

The day after transfection, cells were fixed with 4%

paraformaldehyde containing 0.2% Triton X-100 in

NaCl/Pi for 30 min and washed with NaCl/Pi

Subse-quently, cells were incubated with anti-HA mAb (12CA5,

Boehringer Mannheim, Germany) or anti-PKR polyclonal

antibody (N-18, Santa Cruz, CA, USA) at a dilution of 200

or 100, respectively, for 60 min Cells were then stained with

anti-(mouse IgG) conjugated with fluorescein

isothiocya-nate (FITC) (MBL, Nagoya, Japan) or anti-(rabbit IgG)

conjugated with tetaramethyl rhodamine isothiocyanate

(RITC) (Jackson Immunoresearch Laboratory, West

Grove, PA, USA) at a dilution of 200 for 60 min, and

observed under a fluorescence microscope at a

magnifica-tion of 270 (Olympus BX-60, Tokyo, Japan) For the

expression of EGFP, cells were fixed with 4%

paraformal-dehyde, and observed under a fluorescence microscope as

described above

In vitro kinase assay

Cell extracts were prepared with PKR buffer I (20 mMTris/

HCl pH 7.6, 50 mM KCl, 400 mM NaCl, 1 mM EDTA,

5 mM 2-mercaptoethanol, 1% Triton X-100, 0.2 mM

phe-nylmethane sulfonyl fluoride, 100 UÆmL)1 aprotinin, and

20% glycerol) and cleared by centrifugation Then ASK1 in

the cell extract was precipitated by incubation with anti-HA

mAb (5 lL) for 1 h at 4C followed by 50 lL of a 1 : 1

slurry of protein–G Sepharose 4FF (Pharmacia,

Piscata-way, NJ, USA) The immune complex on the beads was

washed four times with PKR buffer I and then once with PKR buffer III (20 mM Tris/HCl pH 7.6, 80 mM KCl,

5 mMb-mercaptoethanol, 2 mMMgCl2, 2 mMMnCl2, and 20% glycerol) The beads were then resuspended in PKR buffer III containing 2 lM [c-32P]ATP (5 lCi) (ICN Biomedicals) in the presence or absence of poly(I)–poly(C)

at the concentration indicated in the legends for 15 min at

30C The phosphorylation reaction was resolved by SDS/ PAGE and visualized by autoradiography PKR activity was measured as described [11]

Immunoprecipitation and Immunoblot analyses Cell extracts were prepared with PKR buffer I and incubated with anti-PKR mAb (2 lL) or anti-HA antibody (5 lL) for 1 h at 4C followed by 50 lL of a 1 : 1 slurry of protein-G Sepharose 4FF for another 1 h at 4C The immune complex on the beads was washed four times with PKR buffer I The beads were then boiled in Laemmli’s sample buffer [22] and resolved by SDS/PAGE Proteins were transferred onto nitrocellulose filters (Bio-Rad Labor-atory, Hercules, CA, USA) and were incubated with polyclonal PKR Ig or HA Ig followed by anti-(rabbit IgG) or anti-(mouse IgG) conjugated with peroxidase Signals were visualized using an enhanced chemiluminescence (ECL) detection system (Amersham, Boston, MA, USA) Protein was measured by Bradford reagent (Bio-Rad Laboratory)

R E S U L T S

PKR interacts with ASK1

To investigate whether PKR and ASK1 interact with each other, the localization of PKR and ASK1 was first examined by indirect immunofluorescence As the wild type

of PKR is hardly expressed at all by transfection due to translational inhibition [23], we used the kinase negative mutant of PKR (PKR-KR), which shows the same localization pattern as the wild type as previously reported [24] The signal for PKR-KR was predominantly localized

in the cytoplasm, whereas that for ASK1 distributed diffusely with relatively intense staining at the periphery of the cells (Fig 1A, a and b) When PKR-KR and ASK1 were cotransfected into COS-1, both proteins showed predominant cytoplasmic localization (Fig 1A, c and d), indicating colocalization of PKR and ASK1

We next used a coimmunoprecipitation assay to define the interaction between PKR and ASK1 They were transfected into COS-1 cells, and immunoprecipitated with antibody against either PKR or ASK1 When the immune-complexes were precipitated with anti-PKR Ig and analyzed

by Western blotting with anti-HA Ig, the signal of ASK1 was detected only in the cell extracts transfected with both cDNAs (lane 2 in Fig 1B) PKR-KR was also coimmuno-precipitated with anti-HA Ig (lane 4 in Fig 1B) Expression

of these proteins was verified by Western blotting (Fig 1B, right panel) To examine whether endogenous PKR is coimmunoprecipitated with ASK1, we established two HEK 293 cells permanently expressing ASK1 (ASK-4 and ASK-8 cells) and control cells containing empty plasmid (pcDNA) The expressions of ASK1 and endogenous PKR

in these cells were confirmed by Western blotting (Fig 1C,

right panel) ASK1 or endogenous PKR was

immunopre-cipitated with anti-PKR or anti-HA Ig, respectively

(Fig 1C, left panel) All these results indicate that PKR

directly interacts with ASK1 Alternatively, the interaction

might be bridged by RNA However, as all these

coimmu-noprecipitation assays were conducted in the presence of

high salt (0.45M), and immunecomplexes were resistant to

RNase treatment (data not shown), direct protein–protein

interaction seems to be likely

Dominant negative mutant of PKR inhibits

ASK1 activity

To explore the potential influence of PKR on ASK1 in vivo,

the effect of PKR-KR on the ASK1-induced apoptosis was

investigated We used constructs of PKR fused with EGFP

to directly visualize cell morphology We have shown that

EGFP-PKR induced apoptosis without poly(I)–poly(C),

whereas EGFP-PKR-KR inhibited Fas-induced apoptosis

[21] NIH-3T3 cells were transfected with ASK1 and either

pEGFP-PKR-KR or pEGFP Serumwas removed from

the medium 24 h after transfection, and the cells were

incubated for another 24 h The cells were then fixed and

ASK1 was stained with anti-HA Ig followed by RITC-labeled secondary antibody ASK1 and EGFP-expressing cells exhibited a round shrunken morphology indicating an induction of apoptosis (Fig 2B, arrow heads in upper panel), whereas the cells expressing both ASK1 and pEGFP-PKR-KR exhibited a flat spread shape (Fig 2B, arrow heads in lower panel) EGFP-expressing cells without ASK1 expression were a flat shape as well (Fig 2B, upper panel) The expression of these proteins was verified by Western blotting (Fig 2A) The number of cells exhibiting a shrunken morphology was counted in several fields and summarized (Fig 2C) Transfection of ASK1 and subse-quent serumdeprivation caused about 60% of cells to die, whereas cotransfection of pEGFP-PKR-KR suppressed the cell death to almost the control level (Fig 2C) Transfection

of either empty vector or PKR-KR alone did not cause significant cell death

As PKR-KR inhibited the ASK1-induced apoptosis, it seems reasonable to speculate that PKR-KR inhibited ASK1 signaling As ASK1 has been shown to activate stress-activated MAPKs, the effect of PKR-KR on the activation of p38 by ASK1 was examined COS-1 cells were transfected with ASK1 and/or PKR-KR, and p38 activation was examined by Western blotting using antibody against the phosphorylated formof p38 (Fig 3) ASK1 increased p38 phosphorylation 24 h after transfection (lane 6 in Fig 3) (an average of 5.4-fold increase in the intensity fromthree independent experi-ments compared with that of pcDNA at 24 h), whereas cotransfection of PKR-KR inhibited its increase to about 60% level of ASK1 (lane 8 in Fig 3) (an average of 3.4-fold increase)

Fig 1 PKR interacts with ASK1 (A) Cytoplasmic localization of ASK1 with PKR COS-1 cells were transfected with

pcDNA-PKR-KR (a), pcDNA-ASK1-HA (b), or both (c and d) Cells were fixed

18 h after transfection and then incubated with anti-PKR Ig (a) or anti-HA Ig (b) followed by FITC-labeled anti-rabbit or anti-mouse immunoglobulin, respectively For double staining of PKR-KR (c) and ASK1 (d), cells were incubated with both antibodies, followed by RITC-labeled and FITC-labeled secondary antibodies Cells were observed under a fluorescent microscope at a magnification of 270 (B) PKR and ASK1 were coimmunoprecipitated COS-1 cells (approxi-mately 4 · 10 5

cells) were transfected with the plasmid DNAs indi-cated above the lanes, and lysed in a lysis buffer 48 h after transfection Lysates (200 lg of total protein) were incubated with anti-PKR (lanes

1 and 2) or anti-HA (lanes 3 and 4) antibody, followed by protein G–Sepharose Immunecomplexes were then analyzed by Western blotting with anti-HA (lanes 1 and 2) or anti-PKR (lanes 3 and 4) Ig Expression of ASK1 and PKR-KR in a total lysate (100 lg of total protein) was examined by Western blotting using anti-HA (ASK1) or anti-PKR Ig (PKR) (right panel) Signals were visualized by ECL Ig denotes immunoglobulin (C) ASK1 and endogenous PKR were coimmunoprecipitated HEK293 cell lines permanently transfected with pcDNA (pcDNA) or ASK1 (ASK-4, ASK-8) were established Approximately 2 · 10 7 celles were lysed in a lysis buffer, and ASK1 or PKR in a lysate (12 mg of total protein) was immunoprecipitated with anti-HA or anti-PKR Ig (immppt) as described in (B), and Immune-complexes were analyzed by Western blotting with HA or anti-PKR Ig (WB) Expression of ASK1 or endogenous anti-PKR in a total lysate (100 lg of total protein) was examined by Western blotting (right panel) Signals were visualized by ECL.

Dominant negative mutant of PKR inhibits

ASK1 activityin vitro

The above results suggested that PKR modifies ASK1

activity We therefore examined by means of an in vitro

kinase assay whether PKR directly affects ASK1 activity

ASK1 was immunoprecipitated with anti-HA Ig from the extract of HEK293 cells permanently expressing ASK1, and

an autophosphorylation reaction was induced in the presence or absence of poly(I)–poly(C) Poly(I)–poly(C), however, did not affect ASK1 activity at all (Fig 4A) This might be due to the amount of PKR coimmunoprecipitated, which was so small that its effect could not be detected Therefore, PKR-KR was further transfected into ASK-8 cells and ASK1 activity was examined An increase in the intensity of the PKR signal was observed in PKR-KR-transfected cells by Western blotting (lanes 2 and 4 in

Fig 2 Effect of dominant negative mutant of PKR (PKR-KR) on ASK1-induced apoptosis (A) Western blotting of PKR-KR or ASK1 NIH-3T3 cells were transfected with empty vector of pEGFP (GFP), pEGFP-PKR-KR (PKR-KR), pEGFP and ASK1 (ASK + GFP) or pEGFP-PKR-KR and ASK1 (ASK + PKR-KR) as indicated above the lanes Cell lysates were prepared 48 h after transfection and then examined by Western blotting using anti-GFP, anti-PKR, or anti-HA

Ig Signals were visualized by ECL (B) Effect of PKR-KR on the ASK1-induced apoptosis NIH-3T3 cells were transfected with 1.5 lg

of pcDNA-ASK1-HA with either 0.5 lg of pEGFP or

pEGFP-PKR-KR Serumwas removed fromthe medium24 h after transfection, and the cells were incubated for another 24 h They were then fixed with 4% PFA and stained with anti-HA Ig followed by anti-(mouse IgG) conjugated with RITC Arrowheads indicate the cells expressing ASK1 and either EGFP or PKR-KR fusion protein (C) Rounded and shrunken cells were counted as apoptotic The percentages of apop-totic cells are shown as an average of three independent experiments

± S.D.

Fig 3 Effect of dominant negative mutant of PKR (PKR-KR) on activation of p38 induced by ASK1 COS-1 cells (approximately 4 · 10 5

cells) were transfected with the plasmid DNAs described above the lanes, and cells were harvested 12 h or 24 h after transfection Cell lysates (100 lg of total protein) were resolved by SDS/PAGE Expression of the phosphorylated formof p38, total p38, ASK1 and PKR was examined by Western blotting using P), anti-(p38-total), anti-HA, and anti-PKR Ig, respectively Signals were visualized

by ECL The representative data of three independent experiments with similar results were shown.

Fig 4B), while the amount of ASK1 in ASK-8 cells did not

change (lanes 3 and 4 in Fig 4B) Transfection of PKR-KR

revealed a 35% decrease (an average fromthree

independ-ent experimindepend-ents) in the autophosphorylation activity of

ASK1 (lanes 7 and 8 in Fig 4B), suggesting that PKR

affects the activity

Effect of PKR on the activity of ASK1in vivo

To examine in vivo the effect of PKR on ASK1 activity,

HEK293 cells permanently transfected with wild type or

dominant negative mutant of ASK1 were exposed to

either poly(I)–poly(C) or H2O2 in the presence of [32P]

orthophosphate, and cell lysates were prepared ASK1 was

immunoprecipitated with anti-HA Ig Immunecomplex

was then resolved by SDS/PAGE, and phosphorylation

reaction was visualized by autoradiography Exposure to

H2O2 markedly increased the intensity of ASK1 about 2.7-fold (an average of two independent experiments) compared with that without H2O2 (AR in Fig 5B), indicating H2O2 activates ASK1 as described [25] Expo-sure to poly(I)–poly(C) also increased the signal for ASK1 about 2.1-fold (an average of two independent experi-ments) compared with that without poly(I)–poly(C) (AR

in Fig 5A), suggesting that PKR could activate ASK1 The amount of ASK1 in the immunecomplexes was not changed by these exposures, which was verified by Western blotting (WBs in Fig 5A and B) On the other hand exposure to poly(I)–poly(C) did not markedly

Fig 5 Effect of poly(I)–poly(C) on ASK1 activity in vivo (A) HEK293 cells (approximately 4 · 10 5

cells) permanently transfected with empty vector (pcDNA), wild type (ASK-8) or dominant negative mutant of ASK1 (ASK-KM-2) were incubated with or without poly(I)–poly(C) (polyI–C) (100 lgÆmL)1) in the presence of [32P]-orthophosphate (400 lCiÆmL)1) for 2 h and harvested ASK1 was immunoprecipitated with anti-HA mAb, and resolved by SDS/PAGE Phosphorylation reactions were visualized by autoradiography (AR) Expression of ASK1, ASK-KM was verified by Western blotting (WB) (B) Cells were incubated with or without H 2 O 2 (1 m M ) in the presence of [ 32 P]-orthophosphate for 1 h and harvested Phosphorylation reactions (AR) and expression of ASK1, ASK-KM (WB) were examined as described in (A) The representative data of two independent experi-ments with similar results were shown.

Fig 4 Effect of PKR-KR on ASK1 activity in vitro (A) ASK1 activity

in ASK1-expressing HEK293 cells (ASK-4, ASK-8) Cells were lysed

in a lysis buffer, and ASK1 in a lysate (400 lg of total protein) was

immunoprecipitated with anti-HA monoclonal Ig followed by protein

G-sepharose Protein G-sepharose was then suspended in PKR III

buffer with [c- 32 P]ATP in the absence or presence of poly(I)–poly(C)

(polyI–C) (1.0 lgÆmL)1) for 15 min at 30 C Reactions were resolved

by SDS/PAGE and visualized by autoradiography (B) Effect of

PKR-KR on ASK1 activity Control (pcDNA) or ASK-8 cells were

trans-fected with PKR-KR (+) or empty vector (–), and cell lysates were

prepared 48 h after transfection Expression of ASK1 and PKR-KR

was verified by Western blotting (lanes 1–4) ASK1 activity in the

absence or presence of PKR-KR was examined as described in (A) and

visualized by autoradiography (lanes 5–8) The representative data of

three independent experiments with similar results were shown.

increase the phosphorylation state of ASK-KM, a kinase

negative mutant of ASK1 [15,19] This may indicate that

PKR does not directly phosphorylate ASK1 but rather

supports autophosphorylation activity of ASK1 All these

results suggest that PKR could activate ASK1, although it

remains possible that poly(I)–poly(C) directly activates

ASK1 However, the latter might be unlikely, as poly(I)–

poly(C) did not activate ASK1 in vitro (Fig 4A)

D I S C U S S I O N

Besides having the antiviral activity of type I interferons,

PKR has been shown to transduce signals such as dsRNA,

LPS, platelet-derived growth factor, Fas, and TNF-a

[13,26,27] As most of these signals are capable of inducing

apoptosis, PKR seems to transduce apoptotic signals,

especially receptor-mediated stimuli As these stimuli also

have been shown to activate protein kinases of the MAPK

family [28], cross talk between PKR and the MAPK cascade

has been proposed However, the pathway linking PKR and

the MAPK family remains to be clarified

In the present study, we showed that PKR colocalized

and was coimmunoprecipitated with ASK1 when

cotrans-fected into COS-1 cells The interaction of PKR with

ASK1 does not require kinase activity of PKR, as a

kinase negative mutant as well as endogenous PKR were

coimmunoprecipitated with ASK1 This seems to be

consistent with recent reports that the interaction of

PKR with IjB kinase b or the signal transducer and

activator of transcription1 does not require kinase activity

of PKR [29,30] However, PKR-KR decreased the

autophosphorylation activity of ASK1 in vitro, and

inhibited both the activation of p38 MAPK and apoptosis

induced by ASK1 in vivo Moreover, exposure to poly(I)–

poly(C) increased ASK1 phosphorylation All these results

indicate that PKR dose not play only a structural role but

rather modulates a signaling pathway of ASK1 Therefore

the binding of PKR to ASK1 might cause a

conforma-tional change in ASK1 for activation, of which is

dependent on PKR activity, or an additional factor(s)

might be requited to activate ASK1

It has been shown that the activation p38 by poly(I)–

poly(C) or LPS treatment was abrogated in PKR-null

fibroblasts, while generally acting stimuli such as osmotic

shock or H2O2 did not require PKR to activate MAPKs

[13] By contrast, a variety of stimuli such as TNF-a,

IL-1, Fas, ceramide, H2O2, osmotic shock, heat shock,

anticancer drugs, protein synthesis inhibitors and so on

activate ASK1 [16] Thus, PKR seems to be a specific

transducer of inflammatory stimuli, while ASK1 is a

general transducer Our results indicate that the signaling

pathway directed fromPKR to ASK1 may define the

roles of these kinases Determining the binding site(s) in

the PKR and ASK1 molecules will help to confirm this

speculation

A C K N O W L E D G E M E N T S

We are grateful to Dr Ara Hovanessian for providing the anti-PKR

mAb and PKR cDNA, and Dr Hidenori Ichijo for ASK1 and

ASK-KM cDNAs This work was supported in part by a grant-in-aid for

scientific research fromthe Ministry of Education, Science, Sports, and

Culture, Japan.

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