Nuclear Oncoprotein Prothymosin {alpha} Is a Partner of Keap1: Implications for Expression of Oxidative Stress-Protecting Genes

Animal cells counteract oxidative stress and electrophilic attackthrough coordinated expression of a set of detoxifying and antioxidantenzyme genes mediated by transcription factor Nrf2. In unstressedcells, Nrf2 appears to be sequestered in the cytoplasm via associationwith an inhibitor protein, Keap1. Here, by using the yeast two-hybridscreen, human Keap1 has been identified as a partner of thenuclear protein prothymosin ${alpha}$ . The in vivo and in vitro dataindicated that the prothymosin ${alpha}$ -Keap1 interaction is direct,highly specific, and functionally relevant. Furthermore, weshowed that Keap1 is a nuclear-cytoplasmic shuttling proteinequipped with a nuclear export signal that is important forits inhibitory action. Prothymosin ${alpha}$ was able to liberate Nrf2from the Nrf2-Keap1 inhibitory complex in vitro through competitionwith Nrf2 for binding to the same domain of Keap1. In vivo,the level of Nrf2-dependent transcription was correlated withthe intracellular level of prothymosin ${alpha}$ by using prothymosin ${alpha}$ overproduction and mRNA interference approaches. Our data attributeto prothymosin ${alpha}$ the role of intranuclear dissociator of theNrf2-Keap1 complex, thus revealing a novel function for prothymosin ${alpha}$ and adding a new dimension to the molecular mechanisms underlyingexpression of oxidative stress-protecting genes.

INTRODUCTION

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Introduction

The defense against oxidative stress and electrophilic attackis mediated in animal cells by activation of a battery of genesencoding detoxification enzymes [such as glutathione S-transferase(GST) and NAD(P)H-quinone oxidoreductase-1 (NQO1)] and antioxidantproteins [such as ${gamma}$ -glutamylcysteine synthetase and heme oxygenase-1(HO-1)] (for a review, see reference 15). Coordinated up-regulationof expression of these genes is attained through the presenceof cis-acting antioxidant response elements (AREs), which arerecognized by the Nrf2 transcription factor in their regulatoryregions (35). Heterodimerization of Nrf2 with small Maf proteinsmay be required for efficient DNA binding and transcriptionactivation (18, 29). Nrf2 has been demonstrated to regulateboth the basal and induced expression of many ARE-responsivegenes (27), as the response to electrophilic and reactive oxygenspecies-producing agents is profoundly impaired in Nrf2-deficientcells (17). Accordingly, nrf2-deficient mice displayed elevatedsensitivity to chemical carcinogenesis and oxidative stress(31).

The ability of Nrf2 to direct transcription of the target genesis subject to regulation through an interaction with an ubiquitouslyexpressed inhibitor protein, Keap1 (19). Because Keap1 displayssimilarity to a Drosophila Kelch protein, which is an actin-bindingprotein (44), Keap1 was proposed to bridge Nrf2 to the cytoskeletonin the cytoplasm of nonstressed cells, thus mediating its inhibitoryaction (8, 19, 22). Recently, Keap1 was also reported to targetNrf2 for cytoplasmic ubiquitination and degradation by the proteosome(28, 45). Induction of oxidative stress and treatment of cellswith chemopreventive agents enable Nrf2 to escape Keap1-dependentcytoplasmic sequestration and degradation, leading to stabilizationof Nrf2, increased nuclear accumulation of Nrf2, and activationof Nrf2-dependent cytoprotective genes (19, 28, 45). The importanceof Keap1-mediated regulation of Nrf2 activity is emphasizedby the observations that in cells lacking Keap1, Nrf2 is constitutivelyaccumulated in the nucleus (20) and that mice with constitutivelyactivated Nrf2 due to the absence of Keap1 died postnatally,with the phenotype being reversed in keap1 nrf2 double mutants(40).

Attempts to identify how the stress signals are transduced tothe target genes point to the constituents of the Nrf2-Keap1complex as well. In particular, Nrf2 has been demonstrated tobe a protein kinase C and a PERK substrate, and in both casesNrf2 phosphorylation led to destabilization of the Nrf2-Keap1complex in stress-induced cells and promoted Nrf2 nuclear accumulationand transcriptional activity (3, 7, 16). On the other hand,Keap1 was also reported to be a sensor of oxidative and electrophilicstress due to the presence of several reactive Cys residues.Keap1 Cys273 and Cys288 mutants were impaired in their abilityto repress Nrf2-dependent transcriptional activation under basalconditions and in Keap1-dependent ubiquitination and degradationof Nrf2 (24, 41, 45). In vitro, exposure to electrophiles disruptedthe interaction of Keap1 with the Neh2 domain of Nrf2 (9).

Thus, the cytoplasmic Nrf2-Keap1 complex emerged as the criticalregulator of ARE-dependent transcription. Here, we report theidentification of a novel Keap1 partner which, quite unexpectedly,turned out to be the nuclear protein prothymosin ${alpha}$ (ProT ${alpha}$ ). Wedemonstrate that ProT ${alpha}$ releases Nrf2 from the Nrf2-Keap1 complexin vitro and contributes to Nrf2-dependent gene expression invivo. To lend mechanistic support for the involvement of ProT ${alpha}$ in the regulation of ARE-dependent transcription, we provideevidence that Keap1 is a nuclear-cytoplasmic shuttling proteinequipped with a functional nuclear export signal (NES), whichapparently confers nuclear-cytoplasmic shuttling to the Nrf2-Keap1complex.

ProT ${alpha}$ is a ubiquitously and abundantly expressed small nuclearprotein (6, 11, 25) that is involved in proliferation of mammaliancells (14) and in their protection against apoptosis (13, 21).Overexpression of ProT ${alpha}$ in NIH 3T3 and HL-60 cells was shownto accelerate proliferation (32, 43), whereas inhibition ofProT ${alpha}$ synthesis prevented cell division (36) and induced apoptosisin HL-60 cells (33). Overexpression of ProT ${alpha}$ in a rat fibroblastcell line resulted in loss of contact inhibition, anchorage-independentgrowth, and decreased serum dependence (30). Consistent withits properties, ProT ${alpha}$ is particularly abundant in tumor cells(10, 38). The antiapoptotic activity of ProT ${alpha}$ likely arises fromits ability to inhibit apoptosome formation (21), whereas themechanism of ProT ${alpha}$ action in stimulating proliferation is notclearly established. Mounting evidence suggests ProT ${alpha}$ involvementin transcription regulation (23, 26, 39). The newly identifiedProT ${alpha}$ -Keap1 interaction may have important implications for themechanism(s) of Nrf2-dependent gene expression.

MATERIALS AND METHODS

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Materials and Methods

Yeast two-hybrid screen. Manipulations with yeast cells were performed essentially asdescribed previously (Yeast protocols handbook, Clontech, PaloAlto, Calif., 2000). Saccharomyces cerevisiae strain L40ccUcontaining pBTM117c-ProT ${alpha}$ was transformed with GAL4 cDNA humanbrain (HB) and human bone marrow (HBM) libraries (Matchmaker;Clontech). Totals of 6 x 10⁶ and 4 x 10⁶ independent transformants,respectively, were plated on a minimal medium lacking tryptophan,leucine, histidine, and uracil. After incubation at 30°Cfor 4 to 8 days, a total of 47 colonies formed were picked toSD plates lacking Trp and Leu. After incubation at 30°Cfor 2 days, ß-galactosidase (ß-Gal) activitywas tested. ß-Gal-positive clones were picked to SDplates lacking Leu and containing canavanine to eliminate thebait, and ß-Gal activity was retested after incubationat 30°C for 2 days. Total DNA was prepared from ß-Gal-negativeclones and transformed into Escherichia coli JM109. To checkfor true positives, isolated plasmids were transformed intoL40ccU harboring pBTM117c, pBTM117c-ProT ${alpha}$ , pBTM117c-Sim1, orpBTM117c-Rev and tested for selective growth on SD plates lackingTrp, Leu, His, and Ura and for ß-Gal activity as describedabove. The inserts of library plasmids of positive clones, pACT2-HBMand pACT2-HB, were sequenced.

Human cells and fluorescence microscopy. HeLa and HepG2 cells were maintained in Dulbecco's modifiedEagle's medium supplemented with 10% fetal bovine serum (ICN).Transfections were done with Lipofectamine 2000 (Invitrogen),using 2 to 6 µg of plasmid DNA, according to the manufacturer'sprotocol. At 24 h after transfection, cells were fixed and processedfor microscopy as described previously (13). When indicated,cells were treated with 2 nM leptomycin B (LMB) (Sigma) for4 h prior to fixation. Protein fusions with enhanced green fluorescentprotein (EGFP) were intracellularly localized as described previously(12). For immunolocalization, anti-Keap1 2H5 and 2E4 monoclonalantibodies and rabbit anti-Nrf2 polyclonal antibodies (C-20;Santa Cruz Biotechnology) at a dilution of 1:300 were used asprimary antibodies. For Keap1 competition assay, the 2H5 antibody(0.64 µg) was preincubated with 12.8 µg of recombinantGST-Keap1(308-624) expressed in and purified from E. coli orwith 6.4 µg of GST at 4°C for 1 h prior to its additionto fixed cells. Fluorescein isothiocyanate-conjugated goat anti-mouseantibodies and rhodamine-conjugated goat anti-rabbit antibodies(Santa Cruz Biotechnology) were used as secondary antibodiesat a dilution of 1:400. Images were acquired through an Axiovert200 M fluorescence microscope equipped with an LSM510 confocallaser scanning module or with an AxioCam digital camera (CarlZeiss).

Plasmids. pBTM117c-ProT ${alpha}$ and its derivatives encoding wild-type human ProT ${alpha}$ and various deletion mutants thereof fused to LexA were constructedby in-frame ligation of the ProT ${alpha}$ -encoding DNA fragments derivedfrom pHT15A (12) downstream from the LexA-encoding sequencein pBTM117c (42). pHT15A(44,50) was obtained by replacing the110-bp StyI-AccI DNA fragment of pHT15A with that containingthe E44G E50G double mutation (34). The MProT ${alpha}$ (44,50)-encodingsequence was then used to replace the wild-type ProT ${alpha}$ -encodingsequence in pHP12A (37), pKTL1 (5), pcDNA4-enh-wt ProT ${alpha}$ (13),and pBTM117c-ProT ${alpha}$ .

To obtain the complete ORF of human Keap1, the missing N-terminalKeap1-encoding DNA fragment was amplified by PCR from a SW480cDNA library by using primers 5'-GGAACCGCATGCAGCCAGAT-3' and5'-GTGTAGGCGAATTCAATGAG-3'. The SphI-EcoRI-digested PCR productand the EcoRI-XhoI DNA fragment from pACT2-HBM were then ligatedin frame into the SphI-SalI-digested pQE32 (Qiagen) to producepQE32-Keap1. pACT2-Keap1 was generated by inserting the BamHI-EcoRIDNA fragment from pQE32-Keap1 into pACT2-HBM. The complete Keap1ORF in pACT2-Keap1 was then replaced with DNA fragments encodingdifferent domains of Keap1. pQE-Keap1(1-139) was constructedby deleting the Keap1-encoding region downstream from the EcoRIsite in pQE32-Keap1. pGEX-Keap1(308-624) was obtained by insertingthe EcoRI-XhoI DNA fragment from pACT2-HB into pGEX-4T-2 (AmershamPharmacia Biotech).

To produce Keap1 and its mutants as EGFP fusions in human cells,the Keap1-encoding DNA fragments were excised from pACT2-Keap1and ligated in frame into the polylinker regions of the pEGFP-Cseries of vectors (Clontech). The L(308,310)A double mutationwas introduced in Keap1 by PCR with a 5'-TCGAGGAGgcCACCgcGCACAAGC-3'mutagenic primer (lowercase letters indicate the nucleotidesubstitutions) and the pUC19 direct and reverse sequencing primers.The structure of the cloned PCR product was verified by sequencing.The Keap1mNES-encoding sequence was inserted into pQE32 andthen transferred, as the BamHI-HindIII and BamHI-XhoI DNA fragments,into pEGFP-C2 and pcDNA4/HisMaxC (Invitrogen) vectors, respectively.

pcDNA4/HisMax-Keap1 was constructed by transferring the BamHI-XhoIfragment from pACT2-Keap1 into pcDNA4/HisMaxA (Invitrogen).For overproduction of zz-Keap1 in yeast, the zz-encoding DNAfragment from pQEzz59 (5) and the Keap1-encoding DNA fragmentfrom pACT2-Keap1 were inserted in frame between the EcoRI andBamHI sites of the pYeDP1/8-2 yeast shuttle vector (34).

The cDNA fragment encoding human Nrf2 was amplified by PCR froma HeLa cDNA library (Clontech) with primers 5'-CGGGATCCCATGGATTTGATTGACATA-3'and 5'-CCGCTCGAGTCTAGTTTTTCTTAACATCT-3'. The PCR product wasdigested with BamHI and XhoI, inserted into pcDNA4/HisMaxB (Invitrogen),and then transferred into the BamHI-SalI-digested pQE31 (Qiagen).

pARE/luc was constructed by inserting a synthetic ARE of thehuman NQO1 gene (5'-GTACCGCAGTCACAGTGACTCAGCAGAATCGCTAG-3')between the NheI and KpnI sites of pGL3-Promoter (Promega).

pSuper-RNAi was constructed by ligating annealed double-strandedoligonucleotide 5'-CCCGAGACGCCCCTGCTAACGGTTCAAGAGACCGTTAGCAGGGGCGTCTCTTTTTGGAAA-3'with 5' overhangs GATC (sense strand) and AGCT (antisense strand)into the BglII-HindIII-digested pSuper (4) (kindly providedby R. Agami, The Netherlands Cancer Institute, Amsterdam, TheNetherlands). The structure of the resulting construct was confirmedby sequencing.

Antibodies and Western blotting analysis. Anti-ProT ${alpha}$ monoclonal antibodies 2F11 and 4F4 and anti-GFP monoclonalantibody 3A9 were described previously (37). Anti-Nrf2 (C-20),anti-I ${kappa}$ B ${alpha}$ (C-21), anti-histone H1 (AE-4), antiactin (C-2), andanti-LexA (N-19) antibodies were from Santa Cruz Biotechnology.Anti-caspase-3 antibodies were kindly provided by Y. Lazebnik(Cold Spring Harbor Laboratory, Cold Spring Harbor, N.Y.). MouseKeap1-specific monoclonal antibodies 2H5 and 2E4 and rabbitanti-Keap1(1-139) and anti-Keap1(308-624) polyclonal antibodieswere generated essentially as described previously (37), usingrecombinant GST-Keap1(308-624) [for 2H5], His₆-Keap1(1-139)[for 2E4 and anti-Keap1(1-139)] and His₆-Keap1(308-624), respectively,as immunogens. Antibodies were affinity purified from asciticfluids and sera by protein A-Sepharose (Amersham Pharmacia Biotech)chromatography, and polyclonal antibodies were additionallypurified with membrane-immobilized Keap1 fragments. Specificityof the antibodies was confirmed by enzyme-linked immunosorbentassay, immunoblotting, and immunoprecipitation techniques. Notably,anti-Keap1 polyclonal antibodies and the 2E4 monoclonal antibodycould bind both native and denatured Keap1, whereas the 2H5monoclonal antibody could recognize nondenatured Keap1 only.

Immunoprecipitations of ProT ${alpha}$ and Western blot analyses wereperformed as described previously (37). Detection of proteinbands was performed by using sheep anti-mouse immunoglobulin(Ig) or goat anti-rabbit Ig conjugated with horseradish peroxidaseas secondary antibodies and ECL Western blotting detection reagents(Amersham Pharmacia Biotech) or Western Lightning ChemiluminescenceReagent Plus (Perkin-Elmer Life Sciences). For coimmunoprecipitationof endogenous Keap1, 3 x 10⁶ HeLa cells, either nonstressedor treated with 100 µM diethyl maleate (DEM) (Sigma) for4 h, or HepG2 cells were lysed for 40 min on ice in 200 µlof EBC buffer (50 mM Tris-HCl [pH 8.0], 120 mM NaCl, 0.5% NP-40,1 mM EDTA) supplemented with 1 mM phenylmethylsulfonyl fluoride.The cleared lysates were preincubated with 20 µg of controlmouse IgG and protein A-Sepharose at 4°C for 2 h. Aftercentrifugation for 5 min, the supernatants were incubated with20 µg of 2F11 anti-ProT ${alpha}$ antibody or with control mouseIgG at 4°C overnight. Protein A-Sepharose was added, andincubation was continued for 1 h. The beads were collected bybrief centrifugation, washed two times with EBC buffer and twotimes with EBC buffer containing 0.5 M NaCl and 0.1% sodiumdodecyl sulfate (SDS) at 0°C, and boiled in Laemmli samplebuffer for 3 min. The samples were subjected to Western blotanalysis with affinity-purified rabbit anti-Keap1(1-139) oranti-Keap1(308-624) polyclonal antibodies.

Protein purification and in vitro protein binding assays. Recombinant human ProT ${alpha}$ and its derivatives were isolated fromE. coli BL21(DE3) cells transformed with appropriate plasmidsby a phenol extraction procedure and further purified by DEAE-chromatography(12). ³²P labeling of the ProT ${alpha}$ derivatives containing a proteinkinase recognition site was as described by Chichkova et al.(5). The specific radioactivity of ³²P-ProT ${alpha}$ thus obtained was10⁷ cpm/µg. Recombinant His₆-Nrf2, His₆-Keap1(1-139),His₆-Keap(308-624), and GST-Keap1(308-624) were overproducedin E. coli JM109 carrying an appropriate plasmid and isolatedwith Ni-nitrilotriacetic acid agarose (Qiagen) and glutathione-Sepharose4B (Amersham Pharmacia Biotech) chromatography, respectively.zz-Keap1 was isolated from galactose-induced S. cerevisiae 2805cells transformed with pYeDP1/8-2/zzKeap1 by cell disruptionwith glass beads at 0°C for 10 min and absorption of therecombinant protein onto IgG-Sepharose (Amersham Pharmacia Biotech).

Interaction of ³²P-ProT ${alpha}$ (30,000 cpm per sample) with IgG-Sepharose-immobilizedzz-Keap1 (150 ng of fusion protein per sample) or zz alone (30ng) was assessed in binding buffer (20 mM HEPES [pH 6.8], 100mM NaCl, 0.1% Tween 20). When indicated, the binding bufferwas supplemented with 100 µM ZnSO₄, CaCl₂, or MgCl₂. After1 h of incubation at 0°C with shaking, the resin was washedwith the same buffer, and the amounts of ³²P-ProT ${alpha}$ in pulled-downfractions and in supernatants were determined.

For competition assays, aliquots of IgG-Sepharose with immobilizedzz-Keap1 (50 ng of fusion protein per sample) were incubatedin binding buffer containing 100 µM ZnSO₄ with either³²P-ProT ${alpha}$ (30,000 cpm) or Nrf2 (250 ng) at 0°C for 1 h withshaking. The resin was washed with binding buffer and then incubatedin the same buffer containing 250 ng of Nrf2 (for the Keap1-ProT ${alpha}$ complex) and with the indicated amounts of wild-type ProT ${alpha}$ orMProT ${alpha}$ (44,50) mutant (for the Keap1-Nrf2 complex) at 0°C.Incubations with buffer alone served as controls. At the indicatedtime intervals, the amounts of ³²P-ProT ${alpha}$ and Nrf2 in pulled-downfractions and in supernatants were measured by radioactivitycounting and by immunoblotting with anti-Nrf2 antibodies, respectively

To assess binding of endogenous Keap1 in the lysates of HeLaand HeG2 cells to matrix-immobilized ProT ${alpha}$ , wild-type ProT ${alpha}$ andits MProT ${alpha}$ (44,50) mutant (1 mg each) were coupled in parallelto 1 ml of CNBr-activated Sepharose 4B (Amersham Pharmacia Biotech)according to the manufacturer's protocol. The beads were thenpreincubated with 5 mg of bovine serum albumin per ml in bufferA (50 mM Tris-HCl [pH 8.0], 120 mM NaCl, 1 mM EDTA, and 0.3%Tween 20) at 0°C for 15 min and washed with the same buffer.Whole-cell lysates of 1.5 x 10⁶ cells were incubated with 10-µlaliquots of ProT ${alpha}$ -Sepharose beads in 200 µl of buffer Aat 0°C overnight, the beads were washed with the same buffer,and the bound proteins were eluted with 1% SDS in buffer A at37°C for 10 min. Eluates were subjected to SDS-8% polyacrylamidegel electrophoresis (PAGE) and analyzed by Western blottingwith anti-Keap1(1-139) and anti-Keap1(308-624) polyclonal antibodies.

Reporter gene assays. Luciferase and ß-Gal were used as reporters. Cotransfectionwith ß-Gal-expressing plasmid pcDNA4/HisMax/lacZ (Invitrogen)was employed to normalize for transfection efficiencies. Cellswere lysed, 36 h after transfection, in reporter lysis buffer(Promega), and luciferase and ß-Gal assays were performedwith the Luciferase Assay System (Promega) according to theprotocol supplied. All experiments were performed in triplicate.

RNA isolation and Northern blotting. Total cellular RNA was isolated from 5 x 10⁵ transfected HeLacells with the RNAqueous total RNA isolation kit (Ambion) accordingto the protocol supplied by the manufacturer. RNA samples, in20-µg aliquots, were electrophoresed on 1.5% agarose-2.2%formaldehyde gels, transferred onto Hybond N+ membranes (AmershamPharmacia Biotech), and hybridized sequentially with [³²P]DNAprobes obtained by random-priming labeling of the indicatedcDNAs. Quantification was performed with ImageQuant softwareafter exposure of the membranes to a PhosphorImager (MolecularDynamics).

ProT ${alpha}$ overproduction and small interfering RNA (siRNA) knockdown in human cells. ProT ${alpha}$ lacking artificially added sequences was overproduced inHeLa cells transfected with pcDNA4-enh-wt ProT ${alpha}$ and pcDNA4-enh-MProT ${alpha}$ (44,50)as described previously (13). Cells were treated with 100 µMDEM or with diluent (dimethyl sulfoxide) only for 22 h priorto harvesting. For ProT ${alpha}$ mRNA interference experiments, HeLacells were grown on 35-mm-diameter dishes to 80% confluenceand transfected twice, at a 2-day interval, with 6 µgof pSuper or pSuper-RNAi. Total RNA was isolated from cells48 h after the last transfection step and subjected to Northernblot analysis. Aliquots of the same cells were used for Westernblot analysis with the indicated antibodies and for partialpurification of ProT ${alpha}$ followed by 7 M urea-8% PAGE (13).

RESULTS

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Results

Yeast two-hybrid screen for ProT ${alpha}$ -interacting proteins. A search for human proteins interacting with ProT ${alpha}$ was performedwith the yeast two-hybrid system. cDNA libraries from HB andHBM cloned downstream from the Gal4 activation domain (AD)-codingsequence served as prey, whereas full-length human ProT ${alpha}$ fusedto LexA served as bait. The bait construct alone failed to activatetranscription of the lacZ, HIS3, and URA3 reporter genes whenintroduced into S. cerevisiae L40ccU cells despite the synthesisof easily detectable amounts of the LexA-ProT ${alpha}$ protein (datanot shown). Yeast L40ccU cells cotransformed with the bait andthe library prey constructs were selected for the gained abilityto grow in the absence of uracil and histidine and were furtherscreened with the ß-galactosidase filter assay. Of10⁷ transformants tested, three positive clones from the HBlibrary (with identical inserts) and one positive clone fromthe HBM library (with a larger insert) were identified. Thelibrary plasmids rescued from these clones encoded putativeProT ${alpha}$ interactors, as they were able, upon the retransformationinto the yeast strain, to activate expression of the reportergenes in the presence of the bait construct encoding LexA-ProT ${alpha}$ but not in the absence of the bait or in the presence of unrelatedproteins fused to LexA. Sequencing of the inserts from the rescuedlibrary plasmids (one plasmid for each library) revealed thatthey encode portions of the same protein, known as Keap1 (KIAA0132),a 624-amino-acid protein inhibitor of the transcription factorNrf2. One plasmid (pACT2-HB) contained the Keap1 ORF startingfrom residue 308, and another (pACT2-HBM) contained the Keap1ORF starting from residue 50. We then restored the completeORF of human Keap1 and demonstrated that, in the yeast two-hybridassays, full-length Keap1 binds ProT ${alpha}$ efficiently (data not shown).

Delineating a Keap1-binding region in ProT ${alpha}$ . To learn which region in ProT ${alpha}$ is responsible for binding toKeap1, a set of ProT ${alpha}$ deletion mutants was constructed (Fig.1A). The ability of these mutants to bind full-length Keap1was assessed with the yeast two-hybrid system. A short centralregion of ProT ${alpha}$ (residues 32 to 52) turned out to be both necessaryand sufficient to provide the interaction (Fig. 1A). Furthermore,testing the ProT ${alpha}$ E(44)G,E(50)G double mutant [MProT ${alpha}$ (44,50)]from our collection (34) in the yeast two-hybrid assay demonstratedthe loss of interaction of this ProT ${alpha}$ mutant with Keap1 (Fig.1A). The effect was not due to instability of either the ProT ${alpha}$ or Keap1 derivatives in yeast cells (Fig. 1B and C) and providesa further argument for high specificity of the ProT ${alpha}$ -Keap1 binding.

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FIG. 1. Keap1 is a ProT ${alpha}$ interactor: evidence from yeast two-hybrid analysis. (A) Identification of a Keap1-binding region (black) in ProT ${alpha}$ . + and –, relative ß-Gal levels above 300 and below 10 U, respectively. wt, wild type. (B and C) Lack of detectable interaction between the MProT ${alpha}$ (44,50) mutant and Keap1 is not due to instability of either protein. Shown is Western blot analysis of lysates of yeast cells producing the following: lanes 1, LexA-ProT ${alpha}$ plus AD-Keap1; lanes 2, LexA-MProT ${alpha}$ (44,50) plus AD-Keap1; lanes 3, LexA plus AD-Keap1; lane 4, LexA-MProT ${alpha}$ (44,50) plus AD. The primary antibodies used were anti-LexA (B) and anti-Keap1 (C). (D) An intact Kelch (diglycine, GG) repeat domain of Keap1 is required for ProT ${alpha}$ binding. Individual repeats are numbered from 1 to 6. BTB/POZ, BTB/POZ domain of Keap1.

Domain in Keap1 involved in binding to ProT ${alpha}$ . We then identified a region in Keap1 that is involved in theinteraction with ProT ${alpha}$ . A set of Keap1 deletion mutants was constructed(Fig. 1D) and assayed for ProT ${alpha}$ binding by using the yeast two-hybridsystem. The carboxyl-terminal half of Keap1 turned out to bethe shortest Keap1 fragment capable of ProT ${alpha}$ binding (Fig. 1D).This area of Keap1 comprises six Kelch repeats which togetherform a tertiary structure known as the ß-propeller(1). Deletion of even one Kelch repeat in Keap1 resulted inthe elimination of ProT ${alpha}$ binding (Fig. 1D), suggesting that theintact ß-propeller structure in Keap1 is essentialfor ProT ${alpha}$ recognition.

Evidence for the ProT ${alpha}$ -Keap1 interaction in human cell lysates. To learn whether Keap1 could bind to ProT ${alpha}$ in human cells, awhole-cell lysate of HeLa cells ectopically expressing full-lengthKeap1 was treated with anti-ProT ${alpha}$ 2F11 monoclonal antibody orwith control mouse IgG, and the antigen-antibody complex wascollected with protein A-Sepharose and analyzed by Western blottingwith anti-Keap1 polyclonal antibodies. Figure 2A demonstratesthat Keap1 coprecipitated with endogenous ProT ${alpha}$ when anti-ProT ${alpha}$ antibody was used (lane 1), whereas control mouse IgGs wereinactive (lane 2). The possibility that anti-ProT ${alpha}$ antibody couldrecognize Keap1 directly was excluded by Western blot analysisof Keap1 with anti-ProT ${alpha}$ 2F11 monoclonal antibody (data not shown).Coimmunoprecipitation of the ectopically produced Keap1 withProT ${alpha}$ was then confirmed with lysates of HepG2 cells (data notshown).

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FIG. 2. Keap1 interacts with ProT ${alpha}$ in human cell lysates (A, B, and C) and in vitro (D). (A) Coimmunoprecipitation of the ectopically produced Keap1 with ProT ${alpha}$ from a whole-cell lysate of HeLa cells. Precipitation was performed with anti-ProT ${alpha}$ 2F11 monoclonal antibody (lane 1) or with control mouse IgG (lane 2). Lane 3, whole-cell lysate. Detection of Keap1 was performed by Western blot analysis with anti-Keap1 polyclonal antibodies. (B) Endogenous Keap1 associates with ProT ${alpha}$ . Left panel: Coprecipitation of endogenous Keap1 with ProT ${alpha}$ from whole-cell lysates of HeLa (lanes 1 and 2) and HepG2 (lanes 3 and 4) cells. Precipitation and detection were performed as described for (A). Right panel: Coprecipitation of endogenous Keap1 from lysates of HeLa cells either untreated (lanes 1 and 2) or treated with 100 µM DEM for 4 h (lane 3). Note that in panels A and B the membranes were exposed to X-ray film for 30 s and 30 min, respectively. (C) Binding of endogenous Keap1 to Sepharose-immobilized ProT ${alpha}$ is impaired by the (44,50) mutation in ProT ${alpha}$ . Lane 1, resin without ProT ${alpha}$ ; lane 2, wild-type ProT ${alpha}$ ; lane 3, MProT ${alpha}$ (44,50) mutant. The amount of Keap1 from HeLa whole-cell lysates bound to each resin was evaluated as described for panel A with two different anti-Keap1 antibodies. Bottom row: histone H1 binding to the same affinity resins, verifying equal amounts of immobilized ProT ${alpha}$ . (D) Interaction of the purified recombinant ProT ${alpha}$ and Keap1 in vitro. IgG-Sepharose-immobilized zz-Keap1 (150 ng) or zz alone (30 ng) was incubated with ³²P-radiolabeled wild-type (wt) ProT ${alpha}$ or the MProT ${alpha}$ (44,50) mutant, either in the absence or in the presence of the indicated metal cations (100 µM). After incubation, the unbound ProT ${alpha}$ was removed by washing the resin, and the amount of ³²P-ProT ${alpha}$ bound to each affinity resin was determined by measuring the radioactivity. Error bars indicate standard deviations.

Likewise, endogenous Keap1 could be coimmunoprecipitated withendogenous ProT ${alpha}$ from whole-cell lysates of HeLa and HepG2 cells,as determined by Western blot analysis with two different anti-Keap1polyclonal antibodies (Fig. 2B, left panel). Furthermore, evenlarger amounts of ProT ${alpha}$ -associated Keap1 were detectable in HeLacells treated with DEM, an oxidative stress inducer, relativeto the nonstressed sample (Fig. 2B, right panel). Of note, Keap1coimmunoprecipitated from the DEM-treated cell sample displayeda slightly lower electrophoretic mobility and appeared to bemore heterogenous (Fig. 2B, right panel, lane 3 versus lane2), probably due to posttranslational modification of the protein.

Therefore, the ProT ${alpha}$ -Keap1 interaction may occur in the homologouscell system, under both normal and oxidative stress conditions.

To further substantiate this conclusion and to check for thespecificity of the interaction, recombinant human ProT ${alpha}$ and itsMProT ${alpha}$ (44,50) mutant were immobilized on BrCN-activated Sepharoseand used for isolation of endogenous Keap1 from HeLa and HepG2cell lysates. The amount of Keap1 bound to each resin was evaluatedby Western blotting with two different types of anti-Keap1 antibodies.Binding of Keap1 to wild-type ProT ${alpha}$ was observed (Fig. 2C), whereasonly trace amounts of Keap1 could bind to the MProT ${alpha}$ (44,50) mutant,thus confirming our data on the specificity of the ProT ${alpha}$ -Keap1interaction obtained with the use of the yeast two-hybrid system.

Binding of Keap1 to ProT ${alpha}$ is direct. To test whether the interaction between ProT ${alpha}$ and Keap1 is director is mediated by some "bridging" component of cell lysates,a pull-down assay with purified recombinant human ProT ${alpha}$ and Keap1proteins was employed. Human Keap1 was overproduced as a fusionwith the zz domain (z is an IgG-binding domain of staphylococcalprotein A) and immobilized on IgG-Sepharose. For accurate andquantitative determination of ProT ${alpha}$ binding to this affinitymatrix, human wild-type ProT ${alpha}$ and MProT ${alpha}$ (44,50) were fused attheir N termini to a short peptide comprising the protein kinaseA recognition sequence and ³²P radiolabeled. Binding of thelabeled wild-type ProT ${alpha}$ to the immobilized zz-Keap1 was observedin this in vitro system (Fig. 2D), whereas binding of ProT ${alpha}$ tothe zz domain alone was negligible. Recombinant unlabeled ProT ${alpha}$ lacking artificially added sequences could compete with thebinding of the radiolabeled probe (data not shown), indicatingthat binding to Keap1 is specific for the ProT ${alpha}$ sequence. Furthermore,the MProT ${alpha}$ (44,50) mutant failed to bind Keap1 (Fig. 2D).

Previously, we have demonstrated that ProT ${alpha}$ binds Zn²⁺ and Ca²⁺(but not Mg²⁺) (5). Therefore, we tested whether these divalentcations could affect ProT ${alpha}$ biding to Keap1. In the presence of100 µM Zn²⁺ or Ca²⁺, this binding was markedly enhanced(Fig. 2D). Substitution of Mg²⁺ for these cations did not resultin ProT ${alpha}$ binding over the level seen in the absence of divalentcations (Fig. 2D).

Thus, ProT ${alpha}$ interacts with Keap1 directly and specifically, andthe divalent cations that bind to ProT ${alpha}$ significantly enhancethe ProT ${alpha}$ -Keap1 interaction.

How can ProT ${alpha}$ and Keap1 meet each other? The in vivo and in vitro data presented above seem to stronglysuggest that Keap1 might be a genuine partner of ProT ${alpha}$ . One majorobjection to this idea is that ProT ${alpha}$ and Keap1 have been thoughtto be localized to different subcellular compartments. WhileProT ${alpha}$ is known to be an exclusively nuclear protein, Keap1 wasreported to be cytoplasmic and excluded from the nucleus. Moreover,such a localization is consistent with the postulated role ofKeap1 as a cytoplasmic anchor for the Nrf2 transcription factor.

To test an idea that Keap1 might be a shuttling protein, welocalized Keap1 in HeLa cells before and after treatment withLMB, a known and specific inhibitor of nuclear export of proteinspossessing leucine-rich NESs. HeLa cells ectopically expressingKeap1 or EGFP-Keap1 fusion protein or containing endogenousKeap1 only were examined by fluorescence microscopy with anti-Keap1monoclonal antibodies or the intrinsic fluorescence of EGFP.In the absence of LMB, both the endogenous and ectopically producedKeap1 were predominantly cytoplasmic (Fig. 3A to C). Upon treatmentwith LMB, a dramatic relocation of all three proteins from thecytoplasm to the nucleus occurred (Fig. 3A to C). The specificityof detection of endogenous Keap1 with the anti-Keap1 2H5 monoclonalantibody was confirmed by using an exogenously added GST-Keap1competition assay (Fig. 3D) and a different anti-Keap1 monoclonalantibody, 2E4 (data not shown). A very similar nuclear translocationof Keap1 in response to LMB treatment was observed in anotherhuman cell line, HepG2 (data not shown). Our data thus implythat Keap1 is indeed a shuttling protein likely equipped witha leucine-rich NES. Importantly, an ability of Keap1 to enterthe nucleus lends further support to our conclusion that Keap1may be a true ProT ${alpha}$ interactor.

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FIG. 3. Keap1 is a NES-containing nuclear-cytoplasmic shuttling protein. (A to C) Treatment of HeLa cells with LMB induces nuclear translocation of the ectopically produced full-length Keap1 (A), of the EGFP-Keap1 fusion protein (B), and of endogenous Keap1 (C). Confocal images were obtained by using anti-Keap1 2H5 monoclonal antibody (A and C) or intrinsic fluorescence of EGFP (B). (D) Recognition of endogenous Keap1 in HeLa cells is prevented by preincubation of the anti-Keap1 2H5 monoclonal antibody with recombinant GST-Keap1(308-624) (+GST-Keap1 panel) but not with GST alone (+GST panel). Images were acquired with identical confocal microscope settings. (E) Schematic representation of the Keap1 mutants used for the identification of the NES of human Keap1. DGR, diglycine repeat; wt, wild type. The indicated proteins were fused to the C terminus of EGFP. (F) Western blot analysis of the production of the EGFP-fused Keap1 mutants shown in panel E in transfected HeLa cells. Anti-EGFP antibody was used for detection of the respective proteins. (G) Confocal images showing intracellular localization of the Keap1 mutants fused to EGFP in HeLa cells either untreated or treated with LMB for 4 h. The results presented are also summarized in panel E, right column. Bars, 10 µm.

Identification of a nuclear export signal in Keap1. To identify a putative NES of Keap1, a set of deletion mutantsof Keap1 fused to the C terminus of EGFP reporter protein wasconstructed (Fig. 3E). HeLa cells transfected with the respectiveplasmids and producing EGFP-Keap1 derivatives of the expectedsize (Fig. 3F) were inspected for intracellular localizationof the fusion proteins by fluorescence microscopy both beforeand after LMB treatment (Fig. 3G). Only the Keap1 derivativesencompassing the central "intervening" region of the proteindisplayed LMB-sensitive subcellular localization, being excludedfrom the nucleus in the absence of LMB and relocating into thenucleus after LMB treatment [Keap1(1-321) and Keap1(285-321)](Fig. 3G).

Within the Keap1(285-321) region, there is the amino acid sequenceL³⁰¹VKIFEELTL³¹⁰, which conforms to the consensus of the leucine-richNES, H-2/3X-H-2X-H-X-H (where H stands for hydrophobic [frequentlyLeu] residues). Within this putative Keap1 NES, we replacedtwo leucine residues (L³⁰⁸ and L³¹⁰) that are known to be themost essential for NES function with alanines to produce anEGFP-linked full-length Keap1 mutant (Keap1mNES). In contrastto the wild-type Keap1 (Fig. 3B), the mutant protein was nolonger excluded from the nuclei of HeLa (Fig. 3G, mNES) andHepG2 (data not shown) cells in the absence of the LMB treatment.Since our results indicate that the identified sequence is bothnecessary and sufficient for the LMB-sensitive nuclear exclusionof Keap1, we conclude that it represents a genuine NES in Keap1and that Keap1 is equipped with a single NES.

Coordinated nuclear-cytoplasmic shuttling of Nrf2 with Keap1. To learn whether shuttling of Keap1 between the nucleus andcytoplasm may be of functional significance, an effect of dysfunctionof the NES of Keap1 on the subcellular localization of Nrf2was studied by confocal laser scanning microscopy. In HeLa cellscotransfected with the Nrf2- and the wild-type Keap1-encodingplasmids, both proteins were essentially cytoplasmic (Fig. 4A,top row). LMB treatment of these cells resulted in the expectednuclear translocation of Keap1, similar to that observed withoutNrf2 overproduction, which was mimicked by nuclear accumulationof Nrf2 (Fig. 4A, middle row). Alternatively, in cells cotransfectedwith the Nrf2- and Keap1mNES-encoding plasmids efficient nuclearaccumulation of both proteins was observed even in the absenceof LMB (Fig. 4A, bottom row). Thus, nuclear translocation ofNrf2 triggered by the dysfunction of the Keap1 NES is indicativeof the nuclear-cytoplasmic shuttling of the Nrf2-Keap1 complex.

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FIG. 4. Impairment of the Keap1 NES function results in coordinated nuclear translocation of Keap1 and Nrf2 (A) and in transcriptional activation (B). (A) HeLa cells were cotransfected with the Nrf2- and either with the wild-type (wt) Keap1- or Keap1mNES-encoding plasmids. In the former case, transfected cells were either treated with 2 nM LMB for 4 h or left untreated. For simultaneous detection of Keap1 and Nrf2, fixed cells were incubated with mouse anti-Keap1 and rabbit anti-Nrf2 antibodies, followed by treatment with fluorescein isothiocyanate-labeled anti-mouse and Texas Red-labeled anti-rabbit secondary antibodies. The microscope settings used excluded cross-fluorescence between the red and green channels. Right column, nuclei stained with Hoechst 33342. Bar, 10 µm. (B) The pARE/luc reporter plasmid was transfected into HepG2 cells together with expression plasmids encoding Nrf2, wt Keap1, or Keap1mNES, as indicated. A ß-Gal-expressing plasmid was used as a transfection control. The total amount of DNA used for transfection was normalized with an empty vector. Cells were harvested at 48 h after transfection, and the luciferase activity of each sample was measured and normalized for ß-Gal activity. The intactness of wt Keap1 and Keap1mNES was verified by Western blotting analysis of the lysates with anti-Keap1 antibody and is shown in the inset. Error bars indicate standard deviations.

NES-less Keap1 is an activator, rather than an inhibitor, of Nrf2-mediated transcription. Alteration of the subcellular localization of Nrf2 and Keap1due to destruction of Keap1's NES might be expected to influenceNrf2-mediated transcriptional activation. To monitor Nrf2-dependenttranscription, the reporter plasmid pARE/luc was constructedby inserting a synthetic Nrf2-responsive ARE of the human NQO1gene into the luciferase-expressing pGL3-Promoter plasmid. Expressionof this luciferase reporter construct, upon transfection intoHepG2 cells, was confirmed to be up-regulated by ectopic productionof Nrf2 and down-regulated by the coexpression of wild-typeKeap1 together with Nrf2, as expected (Fig. 4B). However, coexpressionof the Keap1mNES mutant together with Nrf2 not only failed tosuppress luciferase gene expression but resulted in a very pronouncedenhancement of Nrf2-driven transcription (Fig. 4B). This activatingeffect was reproduced in HeLa cells (not shown). Thus, destructionof the NES by point mutations converted Keap1 from an inhibitorto an activator of Nrf2-dependent gene expression.

ProT ${alpha}$ competes with Nrf2 for binding to Keap1. As demonstrated above, ProT ${alpha}$ binds to the C-terminal half ofKeap1 comprising six Kelch (diglycine) repeats. Nrf2 was shownpreviously to interact with the C-terminal half of Keap1 aswell (19). To test whether ProT ${alpha}$ and Nrf2 could compete witheach other for Keap1 binding, an in vitro system utilizing purifiedrecombinant proteins was employed. A Keap1-ProT ${alpha}$ complex waspreformed by binding ³²P-ProT ${alpha}$ to zz-Keap1 immobilized on IgG-Sepharose.This complex was challenged with recombinant human Nrf2. A parallelsample was treated with buffer lacking Nrf2 to serve as a control.The amounts of ³²P-ProT ${alpha}$ shifted from the matrix-bound complexto the supernatant were determined at several time points. Asshown in Fig. 5A, addition of Nrf2 resulted in the efficientdissociation of ProT ${alpha}$ from Keap1. In the absence of Nrf2, dissociationof the Keap1-ProT ${alpha}$ complex was much slower (Fig. 5A), indicatingthat it was Nrf2 that forced ProT ${alpha}$ displacement from Keap1.

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FIG. 5. ProT ${alpha}$ competes with Nrf2 for binding to Keap1 in vitro. (A) Recombinant zz-Keap1 (50 ng) was immobilized on IgG-Sepharose and charged with ³²P-ProT ${alpha}$ . Unbound ProT ${alpha}$ was removed, and the immobilized Keap1-ProT ${alpha}$ complex was incubated with buffer alone (solid line) or with the same buffer containing recombinant Nrf2 (250 ng) (dotted line). At the indicated time intervals, the amount of ³²P-ProT ${alpha}$ in the pulled-down fractions was determined. The amount of matrix-bound ProT ${alpha}$ at zero time was taken as 100%. (B) Recombinant zz-Keap1 (50 ng) immobilized on IgG-Sepharose was charged with recombinant Nrf2 (250 ng). Unbound Nrf2 was removed, and the immobilized Keap1-Nrf2 complex was incubated in parallel with recombinant wild-type ProT ${alpha}$ (lanes 2 and 5), with the MProT ${alpha}$ (44,50) mutant (lanes 3 and 6) (50 µg each), or with buffer alone (lanes 1 and 4) for 1 h. The amount of Nrf2 in the pulled-down (Bound to Keap1, lanes 1 to 3) and supernatant (Displaced, lanes 4 to 6) fractions was determined by Western blotting analysis of each fraction with anti-Nrf2 antibody. Lane 7, Nrf2 used as a marker. (C) Displacement of Nrf2 from the Nrf2-Keap1 complex by ProT ${alpha}$ is dose dependent. zz-Keap1-Nrf2 complex was formed as in panel B and challenged with increasing amounts of wild-type ProT ${alpha}$ for 1 h. Amounts of displaced Nrf2 were determined by immunoblotting as in panel B. Lanes 1 to 4, 0.05, 0.5, 5.0, and 50 µg of ProT ${alpha}$ , respectively. Lane 5, Nrf2 used as a marker.

To verify the competition, a reciprocal experiment was performed.IgG-Sepharose-immobilized zz-Keap1 was charged with Nrf2 andchallenged, in three experiments performed in parallel, witheither wild-type ProT ${alpha}$ , the MProT ${alpha}$ (44,50) mutant that fails tobind Keap1, or buffer alone. After 1 h of incubation, the amountsof Nrf2, both displaced from the complex with immobilized Keap1and remaining bound after this treatment, were monitored byimmunoblotting with anti-Nrf2 antibodies. Displacement of Nrf2from its complex with Keap1 occurred upon challenge with wild-typeProT ${alpha}$ , with a concomitant decrease in the amount of Nrf2 remainingbound to Keap1 (Fig. 5B, lanes 2 and 5). Only trace amountsof displaced Nrf2 were observed when the Keap1-Nrf2 complexwas challenged with the MProT ${alpha}$ (44,50) mutant or with buffer alone(Fig. 5B, lanes 4 and 6 versus lanes 1 and 3). Displacementof Nrf2 by wild-type ProT ${alpha}$ was dose dependent (Fig. 5C). Thesefindings indicate that ProT ${alpha}$ , when competent for Keap1 binding,is able to specifically liberate Nrf2 from its complex withKeap1. It should be noted, however, that despite the use ofa high molar excess of the competitor, ProT ${alpha}$ was able to displaceNrf2 only partially (Fig. 5B, lane 5 versus lane 2).

ProT ${alpha}$ contributes to Nrf2-dependent gene expression. We then assessed the physiological relevance of the ProT ${alpha}$ -Keap1interaction. Binding of ProT ${alpha}$ to Keap1 may indicate involvementof ProT ${alpha}$ in regulation of the Nrf2-mediated transcription ofthe stress-protective genes. Because ProT ${alpha}$ was able to liberateNrf2 from its complex with Keap1, the latter being an inhibitorof the transcription factor, we proposed a role for ProT ${alpha}$ thatconsists of dissociation of the Nrf2-Keap1 complex and thusof up-regulation of the expression of the Nrf2-dependent genes.If this was true, then alteration of the intracellular ProT ${alpha}$ level should influence the Nrf2 transcriptional activity.

To test this idea, the effect of ProT ${alpha}$ overproduction on Nrf2-driventranscription was assessed first. RNA samples from HeLa cellstransfected with either the wild-type ProT ${alpha}$ - or the MProT ${alpha}$ (44,50)-encodingplasmid or with an empty vector were analyzed by Northern blothybridization with an HO-1 probe. The HO-1 gene contains anARE, and its expression is known to be regulated in an Nrf2-dependentfashion (2, 17). A ß-actin probe served as a control.Overproduction of the wild-type ProT ${alpha}$ (Fig. 6A, top panel) resultedin a concomitant increase in the HO-1 mRNA level, relative tothe empty vector control (Fig. 6A, middle panel), both in nonstressedcells (lanes 1 to 3) and in cells treated with DEM to induceoxidative stress (lanes 4 to 6). The ß-actin mRNAlevel remained unaffected (Fig. 6A, bottom panel). Importantly,overproduction of the MProT ${alpha}$ (44,50) mutant, which has an impairedability to bind Keap1 in vivo and in vitro and to liberate Nrf2from the Nrf2-Keap1 complex (Fig. 5B), failed to up-regulateHO-1 gene expression (Fig. 6A). Thus, in agreement with ourmodel, an increase in the ProT ${alpha}$ level could stimulate transcriptionof an Nrf2-dependent gene, and this effect appeared to be specificallymediated by the ProT ${alpha}$ binding to Keap1 (see Fig. 6B for quantification).

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FIG. 6. HO-1 gene expression in HeLa cells is directly proportional to the ProT ${alpha}$ level. (A) ProT ${alpha}$ overproduction enhances HO-1 transcription. Lysates of HeLa cells transfected with the wild-type ProT ${alpha}$ - or with the MProT ${alpha}$ (44,50)-encoding plasmid or with vector alone were analyzed 48 h after transfection for the ProT ${alpha}$ content (top panel) and for relative levels of expression of HO-1 mRNA (Nrf2 dependent, middle panel), and ß-actin mRNA (Nrf2 independent, bottom panel). Lanes 1 to 3, nonstressed cells; lanes 4 to 6, cells treated with 100 µM DEM for 22 h prior to harvesting. Top panel: Partially purified ProT ${alpha}$ was fractionated in a 7 M urea-8% polyacrylamide gel and visualized by methylene blue staining. tRNA present in the partially purified ProT ${alpha}$ samples verifies equal loading. Middle and bottom panels: Northern blot analysis of lysates with HO-1 and ß-actin probes, respectively. The same membrane was used with both probes. (B) Quantitative analysis of the data presented in panel A. In panels B and E, all transfection experiments were performed a minimum of four times before calculating means and standard deviations. The amount of the corresponding mRNA from vector-transfected cells was taken as 1.0. panel C Down-regulation of ProT ${alpha}$ level through ProT ${alpha}$ mRNA interference. HeLa cells were transfected with either ProT ${alpha}$ siRNA-expressing plasmids or with empty vector, as described in Materials and Methods. Two days after the last transfection step, cell lysates were analyzed for the ProT ${alpha}$ content (top panel) as described for panel A. In parallel, the lysates were analyzed for the levels of several unrelated proteins by Western blotting with antibodies to actin, histone H1, I ${kappa}$ B ${alpha}$ , and procaspase-3 (bottom panels). (D) ProT ${alpha}$ mRNA interference down-regulates HO-1 gene expression. Lysates of HeLa cells transfected as described for panel C were analyzed by Northern blotting with ProT ${alpha}$ , HO-1, and ß-actin probes. (E) Quantitative analysis of the data presented in panel D.

To further verify our model, a reciprocal, ProT ${alpha}$ mRNA interferenceapproach was taken. Plasmid-driven production of a hairpin siRNAtargeted to the ProT ${alpha}$ mRNA region encoding amino acid residues30 to 36 of the protein (ProT ${alpha}$ siRNA) led to a significant reductionin the intracellular ProT ${alpha}$ level relative to the vector-transfectedsample, as revealed by PAGE upon partial purification of theprotein (Fig. 6C, top panel) and confirmed by sandwich ELISAwith crude cell lysates and a pair of anti-ProT ${alpha}$ monoclonal antibodies(data not shown). No difference from the control sample wasobserved when the lysates were probed for actin, histone H1,I ${kappa}$ B ${alpha}$ , and procaspase-3 contents by Western blotting (Fig. 6C,bottom panels), indicating that the effect of RNA interferencewas ProT ${alpha}$ specific.

At the RNA level, expression of the ProT ${alpha}$ siRNA resulted in amarked decrease in the amount of ProT ${alpha}$ mRNA detected, relativeto the empty vector control (Fig. 6D, top panel), while it hadno effect on the level of ß-actin mRNA (Fig. 6D, middlepanel). To determine whether the reduction in the ProT ${alpha}$ levelcould influence Nrf2-dependent gene expression, the RNA blotdepicted in Fig. 6D was rehybridized with the HO-1 probe. Down-regulationof the expression of HO-1 mRNA was observed in cells expressingProT ${alpha}$ siRNA (Fig. 6D, bottom panel; see also Fig. 6E for quantification).Thus, the level of Nrf2-dependent gene expression was correlatedwith the intracellular level of ProT ${alpha}$ by using both up- and down-regulationof ProT ${alpha}$ synthesis.

DISCUSSION

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Discussion

Interaction of the Nrf2 transcription factor with its inhibitorKeap1 is central in regulation of expression of the genes defendingcells against oxidative stress and electrophilic attack. Accordingto current thinking, in the absence of stress, actin-bound Keap1serves as a cytoplasmic anchor for Nrf2, preventing nuclearuptake of the transcription factor and activation of expressionof Nrf2-dependent genes and targeting Nrf2 for proteosome-mediateddegradation. Upon induction of stress, the Nrf2-Keap1 interactionis destabilized, most probably due to posttranslational modificationof Nrf2, Keap1, or perhaps both constituents, thus liberatingNrf2 from sequestration and permitting its nuclear translocationto induce expression of stress-preventing genes.

In this study, we searched for protein partners of the smallnuclear protein ProT ${alpha}$ . ProT ${alpha}$ is an essential protein involvedin the proliferation of mammalian cells and in their protectionagainst apoptosis. We provided in vivo and in vitro evidencethat Keap1 is a genuine partner of ProT ${alpha}$ and that ProT ${alpha}$ contributesto Nrf2-dependent gene expression. The notion that ProT ${alpha}$ mightbe involved in up-regulation of expression of genes protectingcells from oxidative stress was not anticipated earlier andilluminates a novel function of this small but evidently multifunctionalprotein. However, our results appear to provide clues to thefunctioning of the Nrf2-Keap1 system as well.

First, we demonstrated that Keap1 is a shuttling protein thatmigrates dynamically between the nucleus and the cytoplasm.Nuclear export of Keap1 is Crm1 (exportin-1) dependent and ismediated by a functional leucine-rich NES positioned in thecentral intervening region of Keap1 (residues 301 to 310). Besides,because Keap1, even when overproduced, is rapidly translocatedto the nucleus upon LMB- and point mutation-mediated NES dysfunction,Keap1 is expected to possess a nuclear localization signal aswell. Mutating the NES in Keap1 results in a profound nuclearaccumulation of both Keap1 and Nrf2, implying that, besidesshuttling by itself, Keap1 confers nuclear-cytoplasmic shuttlingon the Nrf2-Keap1 complex. The shuttling model proposed heremay have several advantages over the accepted cytoplasmic anchoringmodel, as follows. (i) The shuttling Nrf2-Keap1 complex couldgain an ability to sense stress conditions in both compartments,nuclear and cytoplasmic. (ii) The appearance of Nrf2, albeitin complex with Keap1, in the nuclei of nonstressed cells isin line with the occurrence of the basal ARE-mediated transcription,which is not readily explicable in terms of the cytoplasmicanchoring model. (iii) Shuttling of Keap1 could provide a mechanismfor termination of the induced expression of the stress-protectivegenes by withdrawing Nrf2 from the nucleus when the insult issurmounted.

Second, our in vivo and in vitro data indicate that interactionof ProT ${alpha}$ with Keap1 is highly specific (e.g., suppressed by pointmutations in ProT ${alpha}$ ) and functionally relevant [Nrf2-dependenttranscription was found to be directly proportional to the intracellularlevel of wild-type ProT ${alpha}$ but not to that of MProT ${alpha}$ (44,50)]. Cluesto the mechanism of ProT ${alpha}$ involvement in Nrf2-Keap1 functioningcame from the identification of the ProT ${alpha}$ -binding domain in Keap1.We showed that ProT ${alpha}$ binds to the C-terminal half of Keap1 comprisingsix Kelch repeats, as Nrf2 does. Consistent with this finding,ProT ${alpha}$ competed with Nrf2 for binding to Keap1. Furthermore, challengingthe Nrf2-Keap1 complex with ProT ${alpha}$ leads to displacement of Nrf2.Significantly, the ProT ${alpha}$ mutant with an impaired ability to bindKeap1 failed to liberate Nrf2. A high molar excess of ProT ${alpha}$ requiredfor partial displacement of Nrf2 may, of course, be consideredto represent a limitation of the in vitro assay. However, wethink that this situation is close to the natural one, as ProT ${alpha}$ is a very abundant nuclear protein. Limited release of Nrf2triggered by ProT ${alpha}$ is likely to provide basal ARE-mediated transcription.Upon stress induction, destabilization of the Nrf2-Keap1 complexshould facilitate its dissociation by ProT ${alpha}$ and result in a farlarger amount of liberated Nrf2, leading to enhanced expressionof the ARE-containing genes.

Our results attribute a role to ProT ${alpha}$ as the intranuclear dissociatorof the Nrf2-Keap1 complex. According to our model, the Nrf2-Keap1complex shuttles constantly between the cytoplasm and the nucleus.Once in the nucleus, the complex is attacked by ProT ${alpha}$ presentin large excess, resulting in ProT ${alpha}$ binding to Keap1 and concomitantdisplacement of Nrf2, with the latter being directed to thetarget genes to activate their expression. This liberation ofNrf2 is partial in nonstressed cells, providing a basal levelof transcription, and is far more pronounced in stress-inducedcells due to predestabilization of the Nrf2-Keap1 complex. Aftercompletion of stress, an excess of free Nrf2 is withdrawn fromthe nucleus by binding to the shuttling Keap1 because dissociationof the stabilized (nonmodified) Nrf2-Keap1 complex by ProT ${alpha}$ againbecomes inefficient.

In conclusion, our data have revealed an unexpected functionof ProT ${alpha}$ and contribute to understanding of molecular mechanismsof expression of oxidative stress-protecting genes.

ACKNOWLEDGMENTS

We thank R. Agami for providing pSuper and Y. Lazebnik for providinganti-caspase-3 antibodies. We are grateful to Tatyana Pestovaand Christopher Hellen for their constant support.

This work was supported in part by the Ludwig Institute forCancer Research (to A.B.V.) and by grants from the Russian Foundationfor Basic Research (to N.V.C., A.G.E., and A.B.V.), the U.S.Civilian Research and Development Foundation for the IndependentStates of the Former Soviet Union (CRDF) (to A.B.V.), and theRussian Frontiers in Genetics Program (to A.B.V.).

FOOTNOTES

* Corresponding author. Mailing address: Belozersky Institute of Physico-Chemical Biology, Moscow State University, Moscow 119992, Russia. Phone: (7) (095) 939-4125. Fax: (7) (095) 939-3181. E-mail: varta{at}genebee.msu.su.

REFERENCES

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