Nrf2 Is a Direct PERK Substrate and Effector of PERK-Dependent Cell Survival

Activation of PERK following the accumulation of unfolded proteinsin the endoplasmic reticulum (ER) promotes translation inhibitionand cell cycle arrest. PERK function is essential for cell survivalfollowing exposure of cells to ER stress, but the mechanismswhereby PERK signaling promotes cell survival are not thoroughlyunderstood. We have identified the Nrf2 transcription factoras a novel PERK substrate. In unstressed cells, Nrf2 is maintainedin the cytoplasm via association with Keap1. PERK-dependentphosphorylation triggers dissociation of Nrf2/Keap1 complexesand inhibits reassociation of Nrf2/Keap1 complexes in vitro.Activation of PERK via agents that trigger the unfolded proteinresponse is both necessary and sufficient for dissociation ofcytoplasmic Nrf2/Keap1 and subsequent Nrf2 nuclear import. Finally,we demonstrate that cells harboring a targeted deletion of Nrf2exhibit increased cell death relative to wild-type counterpartsfollowing exposure to ER stress. Our data demonstrate that Nrf2is a critical effector of PERK-mediated cell survival.

INTRODUCTION

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Introduction

Mammalian cells possess a signaling network that senses endoplasmicreticulum (ER) stress and determines cell fate following exposureto stress. The ER signaling network consists of three relatedtransmembrane protein kinases, Ire1 ${alpha}$ , Ire1ß, and PERK(31). Ire1 ${alpha}$ and Ire1ß are composed of a luminal domainthat senses stress, a single membrane-spanning domain, and acytosolic tail that contains both a serine/threonine kinasedomain and an RNase domain (40). Ire1-dependent signals induceexpression of ER chaperones (40) and CHOP (42), a transcriptionfactor that may participate in the apoptotic program. Activationof PERK, which lacks an RNase domain, following ER stress promotesphosphorylation of the translation initiation factor eukaryoticinitiation factor 2 ${alpha}$ (eIF2 ${alpha}$ ), thereby attenuating translationinitiation (15, 22). PERK is one of at least four eIF2 ${alpha}$ proteinkinases that include the heme-regulated kinase (HRI), the interferon-inducible,RNA-dependent protein kinase (PKR), and GCN2 (3, 39). Amongthese, only PERK function is required for the cellular responseto ER stress (22).

Activation of PERK via ER stress initiates cell cycle arrestvia inhibition of cyclin D1 translation (5). PERK-dependentsignaling is also critical for cell survival following the initiationof an ER stress response. Targeted deletion of PERK dramaticallyreduces survival of embryonic stem cells following exposureto ER stress-inducing agents (21). Mice that contain inactivatedPERK exhibit severe defects in the exocrine pancreas due toa high rate of secretory cell apoptosis (20, 44). While themechanism that underlies PERK-dependent cell cycle arrest isestablished, the nature of PERK-dependent cell survival is unresolved.

A majority of PERK's biological activities have been attributedto its function as an eIF2 ${alpha}$ kinase. However, the possibilitythat PERK targets additional downstream substrates that functionas cellular effectors has not been addressed. In order to identifynovel PERK substrates, we performed a yeast two-hybrid screenwith the PERK catalytic domain. We describe the identificationof the Cap 'n' Collar transcription factor Nrf2 as a PERK substrate.In unstressed cells, Nrf2 is maintained in latent cytoplasmiccomplexes via association with the cytoskeletal anchor, Keap1.Previous work revealed that oxidative stress triggers dissociationof this complex via an uncharacterized mechanism, thereby allowingNrf2 nuclear import, where it promotes expression of its downstreamtarget genes (30). We demonstrate that PERK-dependent phosphorylationis both necessary and sufficient to trigger dissociation ofNrf2/Keap1 complexes and thereby promote Nrf2 nuclear import.Furthermore, Nrf2 nuclear translocation is independent of eIF2 ${alpha}$ phosphorylation. Finally, targeted deletion of Nrf2 reducescell survival following ER stress. Collectively, these datasupport a model wherein Nrf2 functions as an effector of PERKcell survival signaling.

MATERIALS AND METHODS

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Materials and Methods

Tissue culture conditions. Cells were maintained in Dulbecco's modified Eagle's medium(DMEM) supplemented with 10% fetal calf serum (FCS), antibiotics,nonessential amino acids, and glutamine (Mediatech, Inc.). Wild-typeand Nrf2^-/- mouse embryonic fibroblasts (MEFs) were immortalizedvia a standard 3T9 protocol (41). Transfections were performedwith Lipofectamine Plus reagent (Life Technologies, Inc.).

Plasmids. ${Delta}$ NPERK was generated from murine PERK cDNA using PCR (primers5'-CCCGGGTCTAGAGAGCGCGCCACCCCGGCCCGG-3' and 5'-GGGCCCGAATTCTCAGGAGAAGGAGCTTGACTT-3'). ${Delta}$ NPERKK618A was generated through site-directed PCR mutagenesis(primers 5'-CAATTACGCTATCGCGAGGATCCGGCT-3' and 5'-AGCCGGATCCTCGCGATAGCGTAATTG-3'[mutated residues are underlined]). ${Delta}$ NPERK and ${Delta}$ NPERKK618A weresubcloned into pGEX4T1 and pAS2 (Amersham) vectors using EcoRIsites. Murine Nrf1 and MafG were cloned from a mouse cDNA library(Nrf1, 5'-TCTAGAATGGAAATGCAGGCTATG-3' and 5'-CAGCTGGTATTTGGACAGCAG-3';MafG, 5'-GTCCCCCGGGTTATGACGAC-3' and 5'-GAATTCGTGTCCCTATGACCGAGCATC-3').Cloned cDNAs were ligated into the pcDNA3 vector (Invitrogen)using EcoRI sites. Myc-Keap1 and His-Keap1 were generated fromKeap1 cDNA and cloned into pcDNA3 or pET15b vectors. HA-Nrf2and GST-Nrf2 were generated from Nrf2 cDNA and cloned into thepCI and pGEX5T2 vectors. The antioxidant response element (ARE)reporter plasmid was generated by cloning four ARE motifs (36)upstream of the TATA sequence in pGL2 (Promega). The mutantARE reporter contains a minimal initiator sequence upstreamof the TATA sequence in pGL2. PERK ${Delta}$ C and myc-PERK plasmids andviruses were described previously (5).

Yeast two-hybrid screen. ${Delta}$ NPERK(K618A) was cloned into the pAS2(TRP) vector using EcoRIsites, resulting in GAL4- ${Delta}$ NPERK(K618A). Saccharomyces cerevisiaestrain AH109 was transformed with GAL4- ${Delta}$ NPERK(K618A) and pACT(LEU)plasmids containing cDNAs from MEFs. Double transformants wereselected for their ability to grow on medium lacking tryptophan,leucine, and histidine and supplemented with 50 mM 3-amino-1,2,4-triazole.Transformants were further selected for their ability to drivelacZ expression in a GAL4- ${Delta}$ NPERKK618A-dependent manner. cDNAsfrom positive transformants were recovered and sequenced.

EMSA. A consensus ARE oligomer (primers 5'-CTACGATTTCTGCTTAGTCATTGTCTTCC-3'and 5'-GGAAGACAATGACTAAGCACAATCGTAG-3') was end labeled with[ ${gamma}$ -³²P]ATP and incubated with 10 µg of cell extract (lysedin 50 mM Tris, 250 mM NaCl, 5 mM EDTA, 0.1% Triton, and 4 mMdithiothreitol [DTT]) for 30 min at room temperature in a reactionmixture containing 20 mM HEPES (pH 8.0), 1 mM EDTA, 20 mM KCl,4 mM MgCl₂, 4% glycerol, 2 µg of poly(dI-dC), and 5 mMDTT. Where indicated, proteins were first preincubated for 1h at 4°C in the presence of antibodies. To achieve maximumresolution of in vivo-derived protein-DNA adducts, native gelswere run at low voltage for 4 h with the free probe routinelyrunning off the gel. For in vitro reactions, recombinant Nrf2(0.5 µg) and in vitro-transcribed and -translated MafG(Promega) were combined in electrophoretic mobility shift assay(EMSA) reaction mixtures as described above.

Immunofluorescence. Cells proliferating on glass coverslips were transfected andtreated as indicated. Cells were fixed in 3% paraformaldehydeand permeabilized in 0.1% Triton in phosphate-buffered saline(PBS). The hemagglutinin (HA) epitope was detected with eitherthe 12CA5 or the 3F10 monoclonal antibody. The myc epitope wasdetected with either the 9E10 or the Jac6 monoclonal antibody.Calreticulin was detected using a polyclonal anticalreticulinantibody (Stressgen). Cells were stained with either fluoresceinisothiocyanate (FITC)-conjugated or biotinylated immunoglobulinG and Texas Red-streptavidin (Vector). DNA was detected withHoechst 33258 dye (Sigma). Cells were visualized using a Nikonmicroscope fitted with appropriate filters or a Bio-Rad confocalimaging system.

Reporter assays. NIH 3T3 cells transfected with the indicated plasmids were leftuntreated or treated with 5 µg of tunicamycin/ml or 100µM tert-butylhydroquinone (tBHQ) for the indicated intervals.Luciferase assays were carried out according to the manufacturer'sinstructions (Dual Luciferase Reporter assay system; Promega)with a luminometer (PE Applied Biosystems). Firefly luciferaseactivity was normalized against Renilla luciferase activityfrom the same lysates.

Cellular fractionation, immunoblotting, and Northern blot analysis. Wild-type, PERK^-/-, and eIF2 ${alpha}$ (S51A) MEFs were treated with 5µg of tunicamycin/ml for the indicated time intervals.Nuclei were collected in buffer A (10 mM HEPES [pH 8.0], 10mM KCl, 1.5 mM MgCl₂, 0.1 mM EDTA, 0.1 mM EGTA, 0.1% IGEPAL)and buffer C (420 mM NaCl, 1.5 mM MgCl₂, 1.0 mM EDTA, 1.0 mMEGTA, 20% glycerol) and stored in buffer D (20 mM HEPES [pH8.0], 50 mM KCl, 0.2 mM EDTA, 0.2 mM EGTA, 20% glycerol). Allbuffers were supplemented with 0.1 mM phenylmethylsulfonyl fluoride,1 µg of aprotinin/ml, 1 µg of leupeptin/ml, 1 µgof pepstatin/ml, and 25 mM ß-glycerol phosphate. Proteinswere resolved by sodium dodecyl sulfate-polyacrylamide gel electrophoresis(SDS-PAGE), transferred to nitrocellulose membranes (Osmonics),and blotted with an anti-Nrf2 polyclonal antibody (Santa Cruz).For detection of eIF2 ${alpha}$ , cells were lysed in EBC buffer, proteinswere resolved by SDS-PAGE and transferred to a nitrocellulosemembrane (Osmonics), and total and phosphorylated eIF2 ${alpha}$ was detectedby immunoblotting (Cell Signaling). RNA was extracted usingTRIzol reagent (Life Technologies, Inc.). RNA immobilized onnylon membranes (Osmonics) was hybridized with ³²P-labeled probesspecific for either luciferase, ${gamma}$ -glutamylcysteine synthetaseligase (GCLC), or ${gamma}$ -actin (5). Signals were detected by phosphorimaging.

Protein kinase assays, metabolic labeling, and immunoprecipitation. Affinity-purified recombinant GST- ${Delta}$ NPERK was used as the kinase,and equivalent amounts of affinity-purified GST-Nrf2, glutathioneS-transferase (GST), and His-eIF2 ${alpha}$ were used as substrates inthe in vitro kinase assays. ${Delta}$ NPERK was preincubated with kinasebuffer (50 mM HEPES [pH 8.0], 10 mM MgCl₂, 2.5 mM EGTA, 20 µMATP) at 30°C for 1 h prior to addition of substrates inorder to reduce incorporation of radioactive phosphate intoPERK itself due to its propensity to autophosphorylate (22).Kinase reactions were initiated following addition of substratesby the addition of 10 µCi of [ ${gamma}$ -³²P]ATP and placement at30°C for 30 min. Reactions were terminated by the additionof sample buffer containing SDS and incubation at 100°Cfor 3 min. Proteins were resolved by SDS-PAGE and visualizedby autoradiography. To obtain PERK produced in mammalian cells,NIH 3T3 cells infected with retrovirus encoding PERK were lysedin radioimmunoprecipitation assay buffer (150 mM NaCl, 10 mMsodium phosphate, 2 mM EDTA, 1% NP-40, 0.1% SDS, 1% deoxycholicacid,) and immunoprecipitated with anti-PERK antiserum. Proteinswere mixed with the indicated recombinant substrates in kinasereactions as described above. For metabolic labeling, NIH 3T3cells were cultured for 1 h in phosphate-free DMEM supplementedwith 0.1% dialyzed FCS and then labeled with 1 mCi of [³²P]orthophosphate(ICN) and in the presence of 5 µg of tunicamycin/ml. Cellswere lysed in NP-40 lysis buffer (50 mM Tris [pH 7.5], 150 mMNaCl, 1% NP-40, 0.5% deoxycholic acid). HA-Nrf2 was precipitatedfrom cell lysates with the 12CA5 antibody and visualized byautoradiography.

In vitro binding assays. Nrf2, in vitro transcribed and translated (Promega) in the presenceof [³⁵S]methionine (ICN), was mixed with purified His-Keap1or His-eIF2 ${alpha}$ immobilized on Talon beads in binding buffer (20mM Tris, 150 mM NaCl, 0.5% IGEPAL) for 2 h at 4°C. Afterwashes with buffer, Nrf2-containing complexes were incubatedwith ${Delta}$ NPERK or ${Delta}$ NPERKK618A in the absence or presence of 500 µMATP at 30°C for the indicated intervals in kinase bufferlacking EGTA.

Annexin V staining and clonogenic survival assays. Cells proliferating on glass coverslips were left untreatedor were treated with 5 µg of tunicamycin/ml, 4 µMstaurosporine, or tumor necrosis factor alpha (TNF- ${alpha}$ ; 5 ng/ml)plus cycloheximide (10 µg/ml) for the indicated intervals.Cells were then washed with PBS and stained with a FITC-conjugatedannexin V antibody and propidium iodide (Pharmingen) and examinedby fluorescence and light microscopy. Annexin V-positive cellsare expressed as the percentage of total cells. For colony outgrowth,cells were plated at 2 x 10⁴/60-mm dish, and 24 h later cellswere left untreated or treated with 1 µg of tunicamycin/mlfor 8 h. Following treatment, cells were washed with PBS, refedwith complete medium, and allowed to grow for 7 days.

RESULTS

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Results

Activation of the Nrf2 transcription factor and Nrf2 target genes by the UPR. To identify novel PERK substrates, we performed a yeast two-hybridscreen with the catalytic domain of murine PERK. Sequence analysisof these clones revealed three overlapping cDNAs predicted toencode the C-terminal 219 amino acids of the Nrf1 transcriptionfactor. Nrf1 belongs to the Cap 'n' Collar family of transcriptionfactors (9), which includes NF-E2 (1) and Nrf2 (34). Nrf1 and-2 are homologous within their C-terminal DNA-binding domains,but they are divergent at their N-terminal transactivation domains(25). We confirmed that PERK could bind directly to both Nrf1and Nrf2 in an in vitro binding assay (data not shown). To determinethe likely PERK target, we evaluated the capacity of the unfoldedprotein response (UPR)-inducing agent, tunicamycin (Fig. 1A),an inhibitor of N-linked glycosylation, or phorbol myristateacetate (PMA) (100 nM), a phorbol ester, to induce Nrf1 or Nrf2DNA-binding activity. Extracts prepared from cells left untreatedor treated for the indicated intervals were evaluated by EMSAreactions using a ³²P-labeled oligonucleotide containing a singleARE (36). Increased DNA-binding activity was detected in extractsfrom both PMA- and tunicamycin-treated cells by 30 min (Fig.1A, lanes 3 and 4 and lanes 5 and 6, respectively). Similarresults were observed upon thapsigargin treatment (data notshown), which induces ER stress via perturbations in calciumhomeostasis. To identify the Nrf family member that bound toDNA, extracts were preincubated with antibodies specific forindividual Nrf proteins. An antibody specific for Nrf2, butnot for Nrf1, abolished the formation of the shifted complex(compare lanes 8 and 9), indicating that Nrf2, but not Nrf1,is a required component of the tunicamycin-induced DNA-bindingcomplex. Neither Nrf1 nor Nrf2 bound to an oligonucleotide containinga mutant ARE (negative data not shown).

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FIG. 1. Nrf2, and not Nrf1, is activated by ER stress. (A) Whole-cell extracts prepared from NIH 3T3 cells treated with PMA (lanes 3 and 4) or tunicamycin (tun) (1 µg/ml) (lanes 5 and 6) were mixed with a radiolabeled oligonucleotide containing a consensus ARE in an EMSA reaction. In lanes 7 to 9, tunicamycin-treated (60 min) whole-cell extracts were exposed to antibodies against Nrf1 (lane 9) or Nrf2 (lane 8) in the EMSA reactions. (B) NIH 3T3 cells were cotransfected with plasmids encoding the 4xARE reporter or a reporter lacking an ARE (mut) along with the cytomegalovirus-Renilla control (internal normalization control) with or without PERK ${Delta}$ C. Cells were treated with 5 µg of tunicamycin/ml or 100 µM tBHQ for the indicated time intervals (in hours), harvested, and assayed for luciferase and Renilla activities. Luciferase activity is shown as the ratio of reporter activity to Renilla luciferase activity; activity in untreated cells was set as 1. Error bars represent the standard deviation from three independent experiments. (C) NIH 3T3 cells were transfected with the 4xARE reporter and treated with tunicamycin (5 µg/ml) for the indicated intervals. RNA was extracted, and expression of luciferase was assessed by Northern blot analysis. (D) Wild-type (lanes 1 to 4) and Nrf2^-/- (lanes 5 to 8) fibroblasts were treated with thapsigargin (1 µM) for the indicated intervals. RNA was extracted, and expression of GCLC and ${gamma}$ -actin was determined by Northern blot analysis.

To evaluate whether tunicamycin elevates Nrf2-dependent geneexpression, NIH 3T3 cells were cotransfected with a fireflyluciferase plasmid containing four ARE sequences (4xARE) anda cytomegalovirus-directed Renilla luciferase plasmid as aninternal control. Treatment with tunicamycin resulted in a reproducibleinduction of luciferase activity (Fig. 1B, panel 2). Treatmentwith tBHQ, a known inducer of Nrf2 activity (28), also increasedARE-dependent gene expression (Fig. 1B, panel 6). Neither tunicamycinnor tBHQ elicited expression of a luciferase reporter whichlacked the ARE motifs (Fig. 1B, panel 3, and data not shown).To confirm these results, we directly assessed luciferase geneexpression by Northern blotting. Increased luciferase mRNA wasevident by 30 min of tunicamycin treatment (Fig. 1C). We noteda decrease in luciferase message by 120 min. This decrease likelyreflects the relative instability of the luciferase messagecompounded by the transient nature of Nrf2 activation followingER stress (see Fig. 3 and 4, below).

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FIG. 3. The UPR triggers PERK-dependent Nrf2 nuclear translocation. (A and B) NIH 3T3 cells proliferating on glass coverslips were cotransfected with plasmids encoding HA-Nrf2 and myc-Keap1. Transfected cells were treated with 5 µg of tunicamycin/ml for the indicated periods of time and fixed, and proteins were visualized by confocal microscopy with antibodies specific for the HA epitope, the myc epitope, and calreticulin. (C) Graphical representation of data in panels A and B. Error bars represent the standard deviations from three independent experiments. (D) NIH 3T3 cells cotransfected with plasmids encoding HA-Nrf2 and myc-Keap1 were pretreated with 5 mM NAC and then treated as described for panels A and B. Error bars represent the standard deviations from three independent experiments. (E) Nuclear extracts prepared from NIH 3T3 cells treated with 5 µg of tunicamycin/ml for the indicated periods of time were resolved by SDS-PAGE, transferred to a nitrocellulose membrane, and probed with an antibody specific for Nrf2.

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FIG. 4. PERK activity is necessary and sufficient for Nrf2 nuclear translocation. (A) NIH 3T3 cells proliferating on glass coverslips were cotransfected with plasmids encoding HA-Nrf2, Myc-Keap1 (panels a to c), or HA-Nrf2, myc-Keap1 and myc-PERK (panels d to f). Twenty-four hours posttransfection, cells were fixed and proteins were detected by indirect immunofluorescence with an antibody specific for the HA epitope. DNA was stained with Hoechst dye. (B) Graphical representation of data in panel A. Error bars represent standard deviations from three independent experiments. (C) Wild-type (PERK^+/+) or PERK^-/- murine fibroblasts proliferating on glass coverslips were cotransfected with plasmids encoding HA-Nrf2 and myc-Keap1 and treated with 5 µg of tunicamycin/ml for the indicated time intervals. Proteins were detected with antibodies specific for the HA and myc epitopes and visualized by confocal microscopy. (D) Graphical representation of data presented in panel C. Solid bars represent wild-type cells, and hatched bars represent PERK^-/- cells. Error bars represent the standard deviations from three independent experiments.

To determine if UPR-dependent induction of the ARE reporterrequired PERK activity, we measured expression of the ARE reporterin NIH 3T3 cells cotransfected with a dominant-negative PERK(PERK ${Delta}$ C) (5). While the cotransfection of PERK ${Delta}$ C did not influencebasal luciferase gene expression (Fig. 1B, bar 4), cotransfectionof PERK ${Delta}$ C eliminated tunicamycin-dependent induction of 4xARE-luciferase(bar 5).

We next assessed the capacity of ER stress-inducing agents toinduce expression of an endogenous Nrf2 target gene. For thisexperiment, we utilized fibroblasts prepared from either wild-typeor Nrf2-null mouse embryos. Wild-type and Nrf2^-/- MEFs werechallenged with thapsigargin, total RNA was collected, and expressionof the Nrf2 target gene, GCLC (7), was assessed. Thapsigargintreatment resulted in a rapid increase in GCLC mRNA in wild-type(Fig. 1D, lanes 1 to 4) but not in Nrf2^-/- (lanes 5 to 8) MEFs.Induction of GCLC was also noted in MEFs containing a homozygousknock-in of a nonphosphorylatable allele of eIF2 ${alpha}$ , eIF2 ${alpha}$ (S51A)(data not shown) (37). These data demonstrate that inductionof the UPR triggers the activation of Nrf2 and Nrf2-dependentgene expression and suggest that PERK function is essentialfor Nrf2 activation.

Nrf2 is a PERK substrate. To evaluate the possibility that Nrf2 is a PERK substrate, weproduced an N-terminally truncated PERK kinase, ${Delta}$ NPERK. ${Delta}$ NPERKpurified from bacteria was mixed with equivalent amounts ofGST, His-eIF2 ${alpha}$ , or GST-Nrf2 (Fig. 2A, lanes 4 to 6) in the presenceof [ ${gamma}$ -³²P]ATP. PERK phosphorylated His-eIF2 ${alpha}$ and GST-Nrf2 (Fig.2A, lanes 2 and 3) but not GST (lane 1). We also assessed whetherPERK expressed in mammalian cells could phosphorylate Nrf2.PERK was precipitated from cell lysates prepared from NIH 3T3cells transduced with a retrovirus encoding PERK (38); overexpressionof PERK results in its activation via enforced oligomerizationin the absence of cell stress (4, 22). PERK precipitates phosphorylatedboth GST-Nrf2 and His-eIF2 ${alpha}$ , but not GST (Fig. 2B). As a specificitycontrol, we also evaluated the ability of Ire1ß precipitatedfrom infected NIH 3T3 cells to phosphorylate GST-Nrf2 or GST.In contrast to PERK, Ire1ß failed to phosphorylateeither GST or Nrf2 (Fig. 2B, lanes 1 and 2). Expression of bothPERK and Ire1 was confirmed in parallel by immunoblotting (datanot shown). This control illustrates two important points. First,Nrf2 is not a general substrate of all the known ER proteinkinases, and second, our precipitates do not contain significantquantities of contaminating protein kinases that nonspecificallyphosphorylate Nrf2. These data demonstrate that Nrf2 is a directPERK substrate.

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FIG. 2. Phosphorylation of Nrf2 by PERK and during the UPR. (A) Recombinant GST (lane 1), GST-Nrf2 (lane 3), or His-eIF2 ${alpha}$ (lane 2) was mixed with the catalytic domain of PERK along with [ ${gamma}$ -³²P]ATP and incubated at 30° for 30 min. Phosphorylated proteins were resolved on denaturing polyacrylamide gels and visualized by autoradiography. Lanes 4, 5, and 6 show Coomassie brilliant blue staining of GST, His-eIF2 ${alpha}$ , and GST-Nrf2, respectively. (B) Lysates prepared from NIH 3T3 cells infected with PERK or Ire1ß were precipitated with an antibody against PERK or a C-terminal myc epitope, respectively. The precipitated protein was mixed with recombinant His-eIF2 ${alpha}$ , GST, or GST-Nrf2 along with [ ${gamma}$ -³²P]ATP. Phosphorylated proteins were resolved on denaturing gels and visualized by autoradiography. (C) NIH 3T3 cells cotransfected with HA-Nrf2 and myc-Keap1 were treated with 5 µg of tunicamycin/ml and [³²P]orthophosphate for the indicated times. Lysates were precipitated with the 12CA5 antibody; complexes were resolved by SDS-PAGE and visualized by autoradiography. (D) Lysates prepared from NIH 3T3 cells were treated with 5 µg of tunicamycin/ml and resolved by SDS-PAGE, and membranes were probed with antibodies specific for total and phosphorylated eIF2 ${alpha}$ .

We next determined if Nrf2 is phosphorylated in vivo followinginduction of an ER stress response. NIH 3T3 cells cotransfectedwith plasmids encoding Nrf2 engineered to express an amino-terminalHA epitope tag (HA-Nrf2) and Keap1 were cultured in medium containing[³²P]orthophosphate and subsequently challenged with tunicamycinfor the indicated intervals (Fig. 2C). Lysates were preparedand subjected to precipitation with the 12CA5 monoclonal antibody.Nrf2 phosphorylation was evident by 10 min of tunicamycin treatment(lane 3) and reached peak levels by 30 min (lane 5), indicatingthat Nrf2 is rapidly phosphorylated in response to ER stressconditions. Similar results were observed in cells challengedwith tBHQ (data not shown) (28). No phosphorylation was detectedin mock-transfected cells (lane 7) or in control precipitates(lane 1). Additionally, Nrf2 phosphorylation was eliminatedin cells that had been transfected with a plasmid encoding PERK ${Delta}$ C(negative data not shown), implicating PERK as the Nrf2 kinasein intact cells. The rapid phosphorylation of Nrf2 led us tocompare the kinetics of Nrf2 phosphorylation with that of eIF2 ${alpha}$ ,a known in vivo substrate of PERK. NIH 3T3 cells were treatedwith tunicamycin for the indicated intervals, and eIF2 ${alpha}$ phosphorylationwas assessed by immunoblotting using an eIF2 ${alpha}$ phospho-specificantibody. Increased eIF2 ${alpha}$ phosphorylation was detectable by 10to 20 min (Fig. 2D, lanes 2 and 3) and was maximal at 60 min(lane 4). These data demonstrate that Nrf2 is phosphorylatedduring an ER stress response in a PERK-dependent fashion, withkinetics that are temporally similar to that of the other knownPERK substrate, eIF2 ${alpha}$ .

ER stress triggers PERK-dependent Nrf2 nuclear import. Under homeostatic conditions, Nrf2 is maintained in inactivecytoplasmic complexes by Keap1 (30). Dissociation of Nrf2/Keap1complexes and subsequent Nrf2 nuclear import can be achievedby treatment of cells with electrophiles such as tBHQ (28).While the mechanism underlying activation of Nrf2 remains unclear,models invoking oxidation of redox-sensitive cysteines withinKeap1 (13, 14, 24) or phosphorylation of Nrf2 (28, 43, 45) havebeen proposed. Given the capacity of ER stress to induce bothNrf2 DNA-binding activity and Nrf2-dependent gene expression,we reasoned that ER stress must also induce Nrf2 nuclear translocation.To assess regulated nuclear entry of Nrf2, NIH 3T3 cells werecotransfected with plasmids encoding HA-Nrf2 and Keap1 engineeredwith an N-terminal myc epitope (myc-Keap1). Cells expressingHA-Nrf2 and myc-Keap1 were left untreated or treated with tunicamycinfor various intervals, and Nrf2 localization was visualizedusing epitope-specific antibodies followed by confocal microscopy.In the absence of stimulus, Nrf2 was cytoplasmic (Fig. 3A, panela, B, panel a, and C); by 30 min of tunicamycin treatment, HA-Nrf2was primarily nuclear (Fig. 3A, panel d, B, panel d, and C).In contrast, myc-Keap1 remained cytoplasmic at all intervals(Fig. 3A, panels b, e, h, and k). While nuclear Nrf2 stainingremained evident at 2 h (Fig. 3A, panel g, B, panel g, and C),by 6 h Nrf2 increasingly relocalized to the cytoplasm (Fig.3A, panel j, B, panel j, and C). Similar results were observedfollowing treatment with other known inducers of ER stress,including thapsigargin (data not shown). Transient nuclear accumulationof endogenous Nrf2 was also observed following ER stress asdetermined by subcellular fractionation (Fig. 3E). Loss of endogenousNrf2 nuclear localization was evident by 2 h, suggesting thatoverexpression may result in some attenuation of Nrf2 downregulation.

Because the UPR is known to elicit oxidative stress (18, 31),a known inducer of Nrf2 nuclear translocation, we assessed whethertunicamycin-dependent activation of Nrf2 was directed by a burstof reactive oxygen species (ROS) generated as a consequenceof ER stress. NIH 3T3 cells transfected with plasmids encodingboth HA-Nrf2 and myc-Keap1 were pretreated with the ROS scavengerN-acetylcysteine (5 mM) prior to treatment with tunicamycin.While this dose was sufficient to reduce levels of tunicamycin-inducedoxidative stress by over 80%, as measured by dichlorodihydrofluoresceindiacetate fluorescence (data not shown), tunicamycin still inducedthe nuclear accumulation of Nrf2 (Fig. 3D). These results suggestthat Nrf2 nuclear transport is unlikely to result from the generationof ROS following ER stress.

The capacity of ER stress to induce Nrf2 nuclear import is consistentwith the notion that a subset of cytoplasmic Nrf2 complexesmust be in the proximity of the ER. We thus determined whetherHA-Nrf2 colocalized with calreticulin, an ER resident protein,in either untreated or tunicamycin-treated cells. As anticipated,in unstimulated cells HA-Nrf2 colocalized with endogenous, ER-localizedcalreticulin (Fig. 3B, panel c); however, treatment of cellswith tunicamycin resulted in HA-Nrf2 nuclear import and a lossof HA-Nrf2-calreticulin colocalization (Fig. 3B, panels f andi). In addition, myc-Keap1 colocalized with calreticulin inthe absence or presence of ER stress (data not shown).

The above data suggest that ER stress triggers Nrf2-Keap1 dissociationand Nrf2 nuclear import, but they do not address whether PERKactivity is required for this action. To assess the role ofPERK in Nrf2 nuclear import, we cotransfected NIH 3T3 cellswith plasmids encoding HA-Nrf2 and Keap1 with or without PERK.Cexpression of wild-type PERK efficiently promoted Nrf2 nuclearlocalization in the absence of a stress-inducing agent (Fig.4A, panel d, and B), demonstrating that PERK activity is sufficientfor Nrf2 nuclear import. To assess whether PERK is requiredfor Nrf2 nuclear import following ER stress, we examined Nrf2localization in fibroblasts derived from PERK null embryos (PERK^-/-).PERK^-/- fibroblasts or fibroblasts derived from wild-type littermates(PERK^+/+) were cotransfected with plasmids encoding HA-Nrf2and myc-Keap1. In PERK^-/- cells, Nrf2 remained cytoplasmic inthe absence or presence of tunicamycin (Fig. 4C, panels a',d', and g', and D), where it colocalized with Keap1 (Fig. 4C,panels c', f', and i'). In contrast, in wild-type cells thatexpress endogenous PERK, tunicamycin triggered Nrf2 nuclearlocalization (Fig. 4C, compare panels a and d).

To determine whether Nrf2 nuclear translocation was an indirectconsequence of PERK-dependent eIF2 ${alpha}$ phosphorylation, we assessedNrf2 localization in MEFs containing a homozygous knock-in ofa nonphosphorylatable eIF2 ${alpha}$ allele, eIF2 ${alpha}$ (S51A) (37). Fibroblastsderived from either wild-type or eIF2 ${alpha}$ (S51A) embryos were transfectedwith vectors encoding HA-Nrf2 or myc-Keap1. Treatment of bothwild-type and eIF2 ${alpha}$ (S51A) cells resulted in Nrf2 nuclear accumulation(Fig. 5A and B).

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FIG. 5. Nrf2 nuclear translocation occurs independently of eIF2 ${alpha}$ phosphorylation. (A and B) Wild-type fibroblasts (B) or eIF2 ${alpha}$ (S51A) fibroblasts (A) were cotransfected with plasmids encoding HA-Nrf2 and myc-Keap1 and treated with 5 µg of tunicamycin/ml for the indicated time intervals. HA-Nrf2 was detected with the 12CA5 monoclonal antibody and visualized by confocal microscopy. (C) Nuclear extracts were prepared from wild-type (WT), eIF2 ${alpha}$ (S51A), or PERK^-/- MEFs treated with 5 µg of tunicamycin/ml for the indicated intervals, resolved by SDS-PAGE, transferred to a nitrocellulose membrane, and probed with an antibody specific for Nrf2.

We also assessed ER stress-dependent nuclear accumulation ofendogenous Nrf2. Nuclear extracts were prepared from wild-type,PERK^-/-, and eIF2 ${alpha}$ (S51A) MEFs treated with tunicamycin for theindicated intervals and assessed for the presence of Nrf2 viaWestern blotting. Following tunicamycin treatment, Nrf2 translocatedto the nucleus in both wild-type and eIF2 ${alpha}$ (S51A) MEFs; however,no accumulation of Nrf2 was observed in PERK^-/- MEFs (Fig. 5C).Efficacy of the fractionation was confirmed by immunoblottingfor ß-tubulin (cytosolic) and CREB (nuclear) (datanot shown). These data strongly support a model wherein nuclearaccumulation of Nrf2 following ER stress is a direct consequenceof PERK activation. We did note that the rate of Nrf2 nuclearaccumulation was more gradual in the eIF2 ${alpha}$ (S51A) MEFs. The reasonfor this is unclear, given that we detected similar kineticsof nuclear Nrf2 entry by immunofluorescence. The important pointis that Nrf2 nuclear entry occurs in a PERK-dependent and eIF2 ${alpha}$ -independentfashion.

Phosphorylation of Nrf2 promotes its dissociation from Keap1. The capacity of tunicamycin to induce PERK-dependent Nrf2 nuclearaccumulation, while Keap1 remains cytoplasmic, suggests thatPERK phosphorylation triggers Nrf2/Keap1 dissociation. To directlyassay complex dissociation, Nrf2 was in vitro transcribed andtranslated in the presence of [³⁵S]methionine and mixed withrecombinant His-Keap1 that was immobilized on nickel affinityresin. Nrf2 efficiently bound Keap1 (Fig. 6A, lane 3) but notthe negative control, His-eIF2 ${alpha}$ (lane 2). After binding and extensivewashing, the Nrf2/Keap1 complexes were divided equally intoaliquots and incubated in the absence of ${Delta}$ NPERK (Fig. 6B, lane3), with ${Delta}$ NPERK but without ATP (lanes 5 and 7), with ${Delta}$ NPERK andunlabeled ATP (500 µM) (lanes 6 and 8), or with the catalyticallyinactive ${Delta}$ NPERK K618A (22) but with ATP (500 µM) (lane4) for the indicated times at 30°C. Nrf2/Keap1 complexeswere then washed extensively, and the presence of Keap1-associatedNrf2 was determined by SDS-PAGE and visualized by autoradiography.Phosphorylation of Nrf2/Keap1 complexes by PERK led to a time-dependentdecrease in Keap1-associated Nrf2 (compare lanes 3 and 6). By30 min in the presence of the PERK catalytic domain, Nrf2/Keap1binding was equal to that of the negative control (compare lanes2 and 8); however, incubation of Nrf2/Keap1 complexes with PERK(K618A)for 30 min had no effect on Nrf2/Keap1 association (comparelanes 3 and 4). The inability of PERK(K618A) to dissociate Nrf2/Keap1complexes illustrates two important points. First, PERK catalyticactivity is essential for Nrf2/Keap1 dissociation rather thansimple physical association, as both wild-type PERK and PERK(K618A)can associate with Nrf2 (data not shown). Second, addition ofATP is not sufficient to trigger dissociation in the absenceof catalytically active PERK. These data demonstrate that PERK-dependentphosphorylation is sufficient to trigger Nrf2/Keap1 dissociation.

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FIG. 6. Phosphorylation-dependent dissociation of Nrf2 from Keap1. (A) Nrf2 in vitro transcribed and translated in the presence of [³⁵S]methionine was mixed with recombinant Keap1 (lane 3) or eIF2 ${alpha}$ (lane 2). Complexes were affinity purified by nickel chromatography, resolved by SDS-PAGE, and visualized by autoradiography. Lane 1 is 10% Nrf2 input. (B) Nrf2/Keap1 complexes prepared as described for panel A and mixed with the catalytic domain of PERK in the absence (lanes 5 and 7) or presence (lanes 6 and 8) of ATP (500 µM) or a kinase-dead PERK in the presence of ATP (lane 4) for the indicated intervals. Lane 1 is 10% Nrf2 input, and lane 3 is Nrf2-Keap1 binding. Lane 2 is binding to the negative control, eIF2 ${alpha}$ . Upon completion of the kinase reactions, the complexes were washed, resolved by SDS-PAGE, and visualized by autoradiography. (C) Nrf2 was mixed with the catalytic domain of PERK in the absence (lane 2) or presence (lane 3) of ATP and then mixed with recombinant Keap1 as described above. After binding, the complexes were washed extensively and proteins were resolved by SDS-PAGE, transferred to a nitrocellulose membrane, and probed with an antibody specific for Nrf2. Lane 1 shows 100% Nrf2 input. (D) Nrf2 (lanes 2 and 5) or PERK-phosphorylated Nrf2 (lanes 3 and 6) was mixed with in vitro-transcribed and -translated MafG (lanes 5 and 6) along with a radiolabeled oligonucleotide containing a consensus ARE in an EMSA reaction. Also shown are EMSA reactions with MafG alone (lane 4) or no protein (lane 1) mixed with the radiolabeled oligonucleotide.

Having shown that PERK-dependent phosphorylation triggers dissociationof Nrf2/Keap1 complexes, we asked whether PERK phosphorylationof Nrf2 would inhibit reassociation of Nrf2/Keap1 complexes.In vitro-transcribed and -translated Nrf2 was incubated with ${Delta}$ NPERK in the presence (Fig. 6C, lane 3) or absence (lane 2)of ATP for 30 min at 30°C. Following phosphorylation, Nrf2was mixed with recombinant Keap1. Nrf2 phosphorylation was monitoredin parallel reactions by using [ ${gamma}$ -³²P]ATP (data not shown). Afterextensive washing, Western analysis revealed that the levelof Nrf2 associated with Keap1 was markedly decreased when Nrf2was prephosphorylated by ${Delta}$ NPERK (compare lanes 2 and 3). Theseresults demonstrate that not only does PERK-dependent phosphorylationpromote Nrf2/Keap1 dissociation, but also that once phosphorylatedby PERK, Nrf2 cannot stably associate with Keap1. These datademonstrate that PERK-dependent phosphorylation triggers Nrf2/Keap1dissociation and prevents reassociation.

To determine whether phosphorylation affects Nrf2 DNA-bindingactivity, purified recombinant Nrf2 that had been phosphorylatedwith purified recombinant ${Delta}$ NPERK, or left unphosphorylated, wasmixed with in vitro-transcribed and -translated MafG. The DNA-bindingactivity of these complexes was then assessed in an EMSA. MonomericNrf2, whether phosphorylated or unphosphorylated, exhibitedno detectable DNA-binding activity (Fig. 6D, lanes 2 and 3).However, when mixed with a heterodimeric DNA-binding partner,MafG, both forms of Nrf2 exhibited indistinguishable DNA-bindingactivity (lanes 5 and 6).

Nrf2 expression increases cell survival following ER stress. Chronic ER stress triggers apoptosis (6, 8, 31). Nrf2 activationplays a role in cell survival following oxidative stress (7,26). To directly assess the role of Nrf2 in survival followingactivation of the UPR, wild-type and Nrf2^-/- MEFs plated ata low density were challenged with tunicamycin for 8 h and subsequentlyfed with complete medium lacking tunicamycin. The cells wereallowed to recover for 7 days, at which point surviving cellswere visualized with Giemsa stain. The expression of Nrf2 greatlyenhanced the ability of cells to survive following ER stress(Fig. 7A). Similarly, Nrf2 overexpression increased cell survivalin tunicamycin-treated NIH 3T3 cells (data not shown).

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FIG. 7. Nrf2 promotes increased cell survival after chronic ER stress. (A) Wild-type and Nrf2^-/- MEFs were left untreated or treated with 1 µg of tunicamycin/ml for 8 h and then allowed to recover for 7 days in normal medium. Colonies were visualized by using Giemsa stain. (B to D) Wild-type ( ${blacktriangleup}$ ) and Nrf2^-/- ( ${blacksquare}$ ) MEFs proliferating on glass coverslips were left untreated or treated with 5 µg of tunicamycin/ml (B), 4 µM staurosporine (C), or 5 ng of TNF- ${alpha}$ /ml plus 10 µg of cycloheximide/ml (D) for the indicated intervals (in hours). Apoptotic cells were visualized with a FITC-conjugated annexin V antibody. Error bars represent the standard deviations from three independent experiments. (E) Wild-type and Nrf2^-/- MEFs were treated with 5 µg of tunicamycin/ml for the indicated intervals. Proteins were resolved by SDS-PAGE, and membranes were probed with antibodies specific for total and phosphorylated eIF2 ${alpha}$ .

To further assess the ability of Nrf2 to provide a protectiveadvantage to cells during ER stress, we assayed for early signsof commitment to apoptosis in wild-type and Nrf2^-/- MEFs. Cellswere treated with tunicamycin for the indicated intervals (Fig.7B) and then stained with annexin V. A sixfold increase in annexinV staining observed in Nrf2^-/- MEFs, relative to that in thewild type, was detectable by 4 h of tunicamycin treatment (Fig.7B), and levels of annexin V-positive cells increased through8 h of treatment. To rule out the possibility that the increasedrate of death is due to a generalized sensitivity of Nrf2^-/-MEFs to all death stimuli, we treated both wild-type and Nrf2^-/-MEFs with non-ER stress-inducing death stimuli: staurosporine(Fig. 7C) and TNF- ${alpha}$ (Fig. 7D). Nrf2^-/- MEFs were no more susceptibleto these death stimuli than wild-type MEFs. The fact that eIF2 ${alpha}$ phosphorylation is induced by tunicamycin treatment in Nrf2^-/-MEFs (Fig. 7E) demonstrates that the increased sensitivity ofNrf2^-/- MEFs does not reflect compromised eIF2 ${alpha}$ phosphorylation.These results provide support for a model wherein Nrf2 playsa prosurvival role during the UPR.

DISCUSSION

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Discussion

Identification of Nrf2 as a PERK substrate. The ER-localized PERK kinase regulates cell fate decisions followingcellular insults that perturb ER homeostasis. Upon exposureto ER stress-inducing agents, activated PERK phosphorylatesits only documented substrate, eIF2 ${alpha}$ (22, 38). PERK functionis crucial for cell survival following exposure of cells toER stress (21). While translational regulation is clearly acritical component of PERK-mediated signaling (21), it is alsoreasonable to consider that PERK signals contribute directlyto the expression of prosurvival genes. We performed a yeasttwo-hybrid screen with the goal of identifying novel PERK substratesthat contribute to cell survival during an ER stress response.We have identified the prosurvival transcription factor Nrf2as a novel PERK substrate. PERK directly phosphorylates Nrf2,thereby identifying Nrf2 as only the second known substratefor PERK. Preliminary data have failed to reveal PERK-dependentphosphorylation of other Nrf family members. Our experimentsreveal a role for this phosphorylation in the dissolution oflatent, cytoplasmic Nrf2 complexes, ultimately facilitatingNrf2 nuclear import and induction of Nrf2-dependent gene expression.

Under homeostatic conditions, Nrf2 is sequestered in a cytoplasmiccomplex through its interaction with the actin-binding proteinKeap1 (30). Induction of oxidative stress triggers Nrf2 nuclearimport and activation, presumably due to its capacity to enforceNrf2/Keap1 dissociation (28). Our results demonstrate that PERKsignaling from the stressed ER also promotes Nrf2 nuclear import.The UPR triggers Nrf2 nuclear import while Keap1 remains cytoplasmic,demonstrating that the UPR promotes the dissolution of Nrf2/Keap1complexes. Indeed, PERK activity triggers dissociation of Nrf2from Keap1 in vitro.

Previous models for the regulation of Nrf2/Keap1 dissociationhave focused on the possibility that ROS promote complex dissociation(46). While it is possible that under certain conditions ROScould act directly on Nrf2 or Keap1, our data reveal that PERKphosphorylation of Nrf2 is sufficient for Nrf2/Keap1 dissociationand that ROS are not required. While we have not yet identifiedthe residues within Nrf2 targeted by PERK, our preliminary dataindicate that the phosphorylation site lies within the aminoterminus of Nrf2. This portion of Nrf2 contains the Neh2 domain,which is critical for interaction with Keap1 (30). It seemslikely that Nrf2 phosphorylation triggers a conformational changethat disrupts Nrf2/Keap1 complexes.

Distinct mechanisms of PERK-dependent regulation of gene expression. While cellular protein translation is repressed due to eIF2 ${alpha}$ phosphorylation following ER stress, translation of ATF4 isselectively increased (19). ATF4 translation is not augmentedin PERK^-/- cells (19), indicating that during the UPR, ATF4synthesis is PERK dependent. While PERK signaling is necessaryfor ATF4 translation, an intermediate signaling step, eIF2 ${alpha}$ phosphorylation,is also required (21, 37). In contrast, our data demonstratethat Nrf2 is an immediate PERK substrate and its activationis independent of eIF2 ${alpha}$ phosphorylation. Consistent with thisidea, we found that stress-dependent Nrf2 nuclear import waslost in PERK^-/- cells; furthermore, dominant-negative PERK moleculesblocked the nuclear import (data not shown) and transcriptionalactivation of Nrf2, indicating that PERK activity is requiredfor Nrf2 activation. Unlike ATF4, Nrf2 is synthesized in unstressedcells, but is maintained in latent cytoplasmic complexes, byvirtue of its interaction with Keap1 (30). PERK signals Nrf2directly, resulting in a rapid response to ER stress. As illustratedin Fig. 8, our data demonstrate that following PERK activationsignals bifurcate, resulting in the regulation of cell survivalvia two distinct pathways. The first involves the translation-dependentaccumulation of ATF4, and the second is mediated by PERK-dependentphosphorylation of inactive Nrf2.

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FIG. 8. Model depicting the bifurcation of PERK-dependent survival signals (details in text).

PERK, Nrf2, and cell survival signaling. While most experiments have utilized cell culture systems toevaluate the consequences of increased ER stress, cells in thecontext of the whole organism are also vulnerable to perturbationsin ER homeostasis. Indeed, PERK^-/- mice exhibit massive levelsof apoptosis of pancreatic beta cells, leading to the developmentof diabetes (20, 44). Mice homozygous for a mutant, nonphosphorylatableeIF2 ${alpha}$ (S51A) also display a beta cell deficiency and die soonafter birth (37), indicating the importance of translationalcontrol during the UPR. These results suggest an important rolefor PERK signaling in cell survival following ER stress.

Our results demonstrate that Nrf2 activation regulates cellsurvival following UPR activation. The absence of Nrf2 increasedapoptosis following ER stress, but not in response to treatmentwith other death stimuli. Nrf2-dependent protection from UPR-inducedcell death likely results from its function as a regulator ofgenes encoding phase II detoxifying enzymes (7, 26). Nrf2 isrequired for inducible expression of phase II detoxifying enzymesfollowing cellular stress (10). As the UPR induces oxidativestress due to accumulation of ROS (23, 33), it is likely thatNrf2-dependent induction of phase II detoxifying enzyme expressionwill contribute to survival during the UPR response. Consistentwith this notion is the recent demonstration that cells containinga targeted deletion of ATF4, a heterodimeric partner for Nrf2,accumulate high levels of ROS resulting in increased cell death(23).

Taken together, the available data suggest a model wherein underconditions of ER stress, PERK senses the accumulation of unfoldedproteins in the ER and phosphorylates both Nrf2 and eIF2 ${alpha}$ (2,22). While protein translation is globally inhibited (11), translationincreases for selected proteins, including ATF4 (19) and ERresident chaperones, which facilitate proper protein folding(16, 32). Nrf2 phosphorylation promotes dissolution of Nrf2/Keap1complexes and triggers Nrf2 nuclear import. Once in the nucleus,Nrf2 heterodimerizes with small Maf proteins (12, 17, 29, 35)or ATF4 (27) to regulate a program of gene expression. Thisregulation likely includes the induction of phase II detoxifyingenzymes, whose actions maintain cellular redox homeostasis (7,26), and may also include repression of genes that promote apoptosis.

ACKNOWLEDGMENTS

We thank Y.W. Kan and J. Chan for providing the Nrf2^-/- MEFsand the Nrf2 cDNA; D. Scheuner for the eIF2 ${alpha}$ (S51A) MEFs; M. Olsonfor providing the Jac6 and 3F10 monoclonal antibodies; R. Wekfor providing anti-PERK antiserum; D. Ron and H. Harding forproviding the PERK cDNA and the PERK^-/- fibroblasts; C. B. Thompsonfor providing TNF- ${alpha}$ ; and M. C. Simon for providing luciferasecDNA.

This work was supported by AHA grant 0060360Z and the AbramsonFamily Cancer Research Institute (J.A.D.) and grants GM59213and ES11721 (M.H.).

FOOTNOTES

* Corresponding author. Mailing address: AFCRI, University of Pennsylvania Cancer Center 454 BRB II/III, 421 Curie Blvd., Philadelphia, PA 19104. Phone: (215) 746-6389. Fax: (215) 746-5511. E-mail: adiehl{at}mail.med.upenn.edu.

REFERENCES

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