Identification of Direct Transcriptional Targets of the Kaposi's Sarcoma-Associated Herpesvirus Rta Lytic Switch Protein by Conditional Nuclear Localization

Lytic reactivation from latency is critical for the pathogenesisof Kaposi's sarcoma-associated herpesvirus (KSHV). We previouslydemonstrated that the 691-amino-acid (aa) KSHV Rta transcriptionaltransactivator is necessary and sufficient to reactivate thevirus from latency. Viral lytic cycle genes, including thoseexpressing additional transactivators and putative oncogenes,are induced in a cascade fashion following Rta expression. Inthis study, we sought to define Rta's direct targets duringreactivation by generating a conditionally nuclear variant ofRta. Wild-type Rta protein is constitutively localized to cellnuclei and contains two putative nuclear localization signals(NLSs). Only one NLS (NLS2; aa 516 to 530) was required forthe nuclear localization of Rta, and it relocalized enhancedgreen fluorescent protein exclusively to cell nuclei. The resultsof analyses of Rta NLS mutants demonstrated that proper nuclearlocalization of Rta was required for transactivation and thestimulation of viral reactivation. RTA with NLS1 and NLS2 deletedwas fused to the hormone-binding domain of the murine estrogenreceptor to generate an Rta variant whose nuclear localizationand ability to transactivate and induce reactivation were tightlycontrolled posttranslationally by the synthetic hormone tamoxifen.We used this strategy in KSHV-infected cells treated with proteinsynthesis inhibitors to identify direct transcriptional targetsof Rta. Rta activated only eight KSHV genes in the absence ofde novo protein synthesis. These direct transcriptional targetsof Rta were transactivated to different levels and includedthe genes nut-1/PAN, ORF57/Mta, ORF56/Primase, K2/viral interleukin-6(vIL-6), ORF37/SOX, K14/vOX, K9/vIRF1, and ORF52. Our data suggestthat the induction of most of the KSHV lytic cycle genes requiresadditional protein expression after the expression of Rta.

INTRODUCTION

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INTRODUCTION

Kaposi's sarcoma-associated herpesvirus (KSHV; also known ashuman herpesvirus-8) is the etiologic agent of the human cancersprimary effusion lymphoma (PEL) and Kaposi's sarcoma (KS) (8,22). Since B-cell infection predicts future KS development andlatent KSHV infection is established before KS onset, the reactivationof productive (lytic) KSHV infection from the latently infectedB-cell reservoir is a necessary step in KS development (2, 51,54, 78). Deciphering the mechanisms that function at the molecularlevel to control KSHV reactivation is therefore essential forunderstanding the pathogenesis of the virus.

During KSHV reactivation in PEL tissue culture models, de novoexpression of viral genes unfolds sequentially in a cascadefashion (31, 44). A fraction of the cells in which the virusinitiates reactivation support completion of the gene expressionprogram, resulting in the production of progeny virus and lysisof the host cells (46, 47, 60). The reactivation program hasthus been termed the KSHV lytic cycle. Similarly to other DNAviruses, the KSHV lytic cycle genes have been classified asimmediate early (IE), delayed early (DE), or late (L) genes.Genes whose expression is resistant to protein synthesis inhibitorshave been formally classified as IE genes (62, 67, 81). Geneswhose transcription requires viral DNA replication have beenclassified as L genes (44). By default, lytic genes that havenot been classified as IE or L fall into the DE class. Twelveof the 17 viral genes that are candidates for contributing directlyto KSHV pathogenesis are expressed during lytic reactivation,primarily with DE kinetics (13, 17, 44, 53, 57). Those observationssuggest that the expression of the candidate DE pathogenic genesis one mechanism by which KSHV lytic reactivation contributesto KS development.

We and others have demonstrated that the KSHV Rta protein, expressedby the open reading frame (ORF50), is necessary and sufficientfor lytic viral reactivation in tissue culture models of latency(24, 46, 47, 68, 79). The viral gene expression program inducedby ectopic Rta in latently infected PEL cells is similar tothat induced by chemicals that stimulate complete viral reactivation(14, 56). Rta is expressed with IE kinetics (67, 81) and encodesa 691-amino-acid (aa) protein that transactivates the putativepromoters of many DE genes when they are cloned upstream ofreporters (e.g., firefly luciferase [10, 12, 18, 32, 45-47,63, 72, 73, 82]). These promoters include those for the candidateviral pathogenic genes. Rta functions as a tetramer to transactivateviral transcription and reactivate the lytic cycle (3). Rtaspecifies genes for transactivation by binding directly to promoterDNA and interacting with the cellular DNA binding proteins recombinationsignal binding protein Jk (RBP-Jk), Octamer 1 (Oct-1), CAAT-enhancerbinding protein ${alpha}$ (C/EBP ${alpha}$ ), and c-Jun (6, 7, 37, 39, 74, 76).The requirement for each of these molecular interactions inRta function appears to be cell and promoter specific (59).

Studies of Rta-dependent reactivation at the single-cell levelsuggest that the expression of Rta alone does not ensure completionof the lytic cycle and the production of mature virions fromevery infected cell (46, 47). To understand the factors thatdetermine the progression of the lytic cycle during Rta-dependentreactivation demands the identification of the authentic, direct-transcriptionaltargets of Rta in infected cells. However, the strategies describedin the current literature have been insufficient for this purpose.Genome-wide analyses of the kinetic order of KSHV gene expressionduring reactivation fail to reveal Rta's direct transcriptionaltargets because additional transactivators are expressed downstreamof Rta (23, 26, 30, 34, 59, 75). Other lytic cycle proteinsthat are induced by Rta inhibit viral transcription and reactivation(5, 29, 36, 40). Mechanistic studies of Rta-dependent reactivationare also complicated by reports that ectopic Rta can transactivatethe transcription of Rta from the endogenous KSHV genome (11,14, 24, 56). The results of transient assays of the Rta-dependenttransactivation of promoter-reporter plasmids in transfectedcells can be difficult to interpret since they rely on testingviral promoters removed from their authentic contexts in theviral genome.

In this study, our goal was to establish a strategy to overcomethe shortcomings described above. We generated a conditionallynuclear variant of Rta by fusing it to a modified hormone-bindingdomain (HBD) of the murine estrogen receptor (ER) (Rta-ER).We employed Rta-ER to identify Rta's direct transcriptionaltargets in the viral genome in infected cells. Addition of theprotein synthesis inhibitor hygromycin permitted the identificationof the Rta-dependent transcriptome in the absence of translationof the other viral transcriptional regulatory proteins. We demonstratethat a C-terminal (aa 516 to 530) lysine-rich sequence is necessaryfor nuclear localization and transactivation by Rta. The deletionof this nuclear localization sequence (NLS) was critical, permittingtight control of Rta's nuclear localization by the additionor omission of the synthetic hormone 4-hydroxytamoxifen (4-OHT)to the cell growth medium.

MATERIALS AND METHODS

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MATERIALS AND METHODS

Plasmids. All plasmids were propagated and purified as described previously(59). Plasmids constructed by PCR amplification were verifiedby DNA sequencing.

For pcDNA3.1-FLc50-RFP-Timer (expresses WT Rta), full-length(FL) ORF50 was PCR amplified from the template plasmid pGem3-FLc50(46); the 3' primer removed the translation termination codon.The product was digested with EcoRI and EcoRV (introduced byprimers) and ligated with the plasmid pcDNA3.1/V5-HisB (Invitrogen)that had been digested with the same enzymes. The resultantclone was named pcDNA3.1-V5-FLc50 and expressed FL Rta fusedC terminally to the V5 epitope tag and a six-His epitope. Next,the V5 and His tags were replaced, in frame, by the mutant redfluorescent protein (RFP) DsRed1-E5: the insert encoding thisRFP was excised from the plasmid pTimer-1 (Clontech) by digestionwith SacII and HpaI and ligated into pcDNA3.1-V5-FLc50 thathad been digested with SacII and PmeI.

For pcDNA3.1-ORF50 ${Delta}$ NLS1-RFP-Timer (expresses Rta with NLS1 deletedfrom the first AUG of ORF50 exon 2, at nucleotide [nt] 181 [Rta ${Delta}$ NLS1]),pcDNA3.1-FLc50-RFP-Timer was digested with BsiWI (ORF50 nt 544)and EcoRI (in the polylinker 5' of the insert) and ligated tothe insert of pBS1.3 (described in reference 46) that was digestedwith the same enzymes.

For pcDNA3.1-ORF50 ${Delta}$ NLS2-RFP-Timer (expresses Rta ${Delta}$ NLS2; see Fig.1A), two PCR products, spanning nt 1 to 1545 (PCR I) and 1591to 2076 (PCR II), respectively, were sequentially cloned. PCRI was digested with EcoRV/NheI (introduced by the primers) andligated to pcDNA3.1/Zeo (Invitrogen) that had been digestedwith the same enzymes. PCR II was digested with NheI/EcoRV andligated to the plasmid constructed from PCR I that had beendigested with NheI and NruI. This created the plasmid namedpcDNA3.1Zeo-ORF50 ${Delta}$ NLS2. This plasmid then was used as a templateto PCR amplify the FL insert (PCR product PCR III), digestedwith BsiWI (internal)/EcoRV (introduced by the 3' primer), andligated to pcDNA3.1-FLc50-RFP-Timer that had been digested withthe same enzymes.

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FIG. 1. Putative NLS1 is dispensable for Rta function. (A) Schematics of WT Rta (top) and Rta ${Delta}$ NLS1 (bottom). Numbers refer to amino acid positions. ex, exon; +++, basic-amino acid rich; LR, leucine repeat; ST, serine-threonine amino acid rich; AD, transcriptional activation domain. (B) BL-41 cells were coelectroporated with the indicated amounts of plasmids expressing WT Rta (WT) or Rta ${Delta}$ NLS1 ( ${Delta}$ NLS1), the pGL3-nut-1 promoter/reporter (expressing luciferase), and pcDNA3.1-His-lacZ (expressing β-galactosidase) as an internal control. The level of activation was calculated by comparison to that of the reporter coelectroporated with empty expression vector. (C) BL-41 cells were electroporated similarly to the description for panel B, but the pGL3-TK promoter/reporter (expressing luciferase) was tested. (D) BCBL-1 cells were coelectroporated with the indicated plasmids and a plasmid expressing hepatitis delta virus large delta antigen and treated with tetradecanoyl phorbol acetate (TPA), as indicated. At 72 h postelectroporation, the percentage of transfected cells expressing large delta antigen and coexpressing ORF59 or K8.1 was calculated for each transfection. Levels of induction were calculated by comparison to that in cells transfected with the empty vector, which was normalized as onefold. Error bars show standard deviations for each transfection.

For pcDNA3.1-ORF50 ${Delta}$ NLS1,2-RFP-Timer (expresses Rta with NLS1and NLS2 deleted [Rta ${Delta}$ NLS1,2]), PCR III was amplified and digestedas described in the paragraph above and then ligated to pcDNA3.1-ORF50 ${Delta}$ NLS1-RFP-Timerthat had been digested with the same enzymes.

ORF50 Sal 7 is a plasmid clone of the 7-kb SalI fragment containingthe genomic ORF50/Rta locus and its natural promoter (47).

For pEGFP-C1-NLS1 and pEGFP-C1-NLS2 (express Rta NLS1 and NLS2,respectively, fused to enhanced green fluorescent protein [eGFP]),double-stranded oligonucleotides encoding NLS1 and NLS2, respectively,of ORF50 were cloned in frame with eGFP at the BamHI/SalI sitesof pEGFP (Clontech).

For pcDNA3.1-ZeoFL50-ER-Tm (expresses WT Rta ER protein), pBS-SK-ER-Tm(containing the tamoxifen [TM]-responsive HBD of the murineER; a gift of Gerard Evan [42]) was digested with BamHI andEcoRI to release the ER-TM fragment, which was ligated intopcDNA3.1/Zeo (Invitrogen) that had been digested with the sameenzymes. This created the plasmid pcDNA3.1ZeoER-Tm. Rta wasthen constructed as a C-terminal fusion to the ER-TM domainby using a two-step procedure. First, Rta was PCR amplifiedby using the plasmid pGem3-FLc50 (46) as a template and a 3'primer that changed the Rta termination codon from TGA to TGG(Trp). The 3' primer also introduced a BamHI restriction siteto that end; following amplification, the PCR product was digestedwith BamHI (which also cuts internally in Rta, at nt 335). Theresulting fragment was ligated into pcDNA3.1ZeoER-Tm, whichhad been digested with BamHI and treated with shrimp alkalinephosphatase (Promega) to inhibit self-ligation. The resultantplasmid was named pcDNA3.1-50Bam-ER-TmZeo. The N terminus ofRta was added in the second step by PCR amplifying Rta nt 1to 815, using pGem3-FLc50 as template and a 5' primer that introducedan NheI restriction site 5' to the Rta start codon. This PCRproduct was digested with NheI and NarI (which cuts at Rta nt630) and ligated with pcDNA3.1-50BamER-TmZeo that had been digestedwith the same enzymes.

For pcDNA3.1-ORF50 ${Delta}$ NLS1-ER-Tm (expresses ER and Rta with NLS1deleted[Rta ${Delta}$ NLS1-ER]), pcDNA3.1-50BamER-TmZeo was digested withNar I (ORF50 nt 630) and NheI (which cuts in the polylinker),and ligated to the Nar I/SpeI fragment of pBS-1.3 (46).

For pcDNA3.1-ORF50 ${Delta}$ NLS1,2-ER-Tm (expresses Rta ${Delta}$ NLS1,2-ER), theBstEII fragment from pcDNA3.1-ORF50 ${Delta}$ NLS2-GFP-Timer was ligatedto pcDNA3.1-ORF50 ${Delta}$ NLS1-ER-Tm.

The pGL3 promoter expresses firefly luciferase under the controlof the simian virus 40 early promoter (Promega). pcDNA3-His-lacZexpresses β-galactosidase under the control of the humancytomegalovirus major IE enhancer (Invitrogen).

Cell culture, transfections, and inductions. BL-41 and BCBL-1 cells were propagated, transfected, and inducedas previously described (3, 6). Luciferase/β-galactosidasereporter assays were performed exactly as previously described(3). At least two transfections were performed in triplicatefor each experiment.

HeLa cells were propagated in complete DME as previously described(7). For transfections, 5 x 10⁴ cells were seeded on coverslipsin each well of six-well plates and grown overnight (ON). Approximately4 h before transfection, the medium was replaced with freshcomplete medium. DNA cocktails were prepared, consisting of10 µg of total DNA, 10 µl 10x NTE (10 mM Tris-Cl,pH 7.4, 100 mM NaCl, 1 mM EDTA), 12.5 µl 2 M CaCl₂, andH₂0 to a final volume of 100 µl. The DNA cocktails wereadded dropwise to an equal volume of 2x transfection buffer(100 µl 0.5 M HEPES, 810 µl H₂0, 90 µl 2 MNaCl, 2 µl 1 M Na₂HPO₄) in a 1.5-ml centrifuge tube, andstreams of bubbles were blown through the mixture 5 to 10 timesusing a pipette. The mixture was left at room temperature for15 to 30 min and then added dropwise to the wells containingmedium and cells. DNA precipitates were distributed by rotatingplates in a figure-eight motion, and the plates were returnedto the incubator for ON growth. The medium/precipitates wereaspirated, cells were washed with fresh medium, and then 3 mlof medium was added to each well. The plates were returned tothe incubator for additional ON growth of cells.

Vero cells infected with the recombinant KSHV construct rKSHV.219(Vero-rKSHV.219) were grown in complete Dulbecco's modifiedEagle's medium supplemented with 6 µg/ml puromycin aspreviously described (71). For transfection, cells were seededat 1 x 10⁶ per 10-cm plate to obtain approximately 50 to 70%confluence the following day and transfected with TransIT-LT1transfection reagent with 10 µg DNA according to the manufacturer's(Mirus) instructions. For gene expression studies, 4-OHT (0.1mM; Sigma), cycloheximide (CHX) (10 or 25 µg/ml; Sigma),hygromycin B (300 µg/ml; Invitrogen), or neomycin (5 µl/ml;Sigma) was added to the cultures at the times indicated in eachfigure.

Immunofluorescence. The levels of reactivation in BCBL-1 cells were quantitatedby measuring the KSHV DE marker ORF59 or the L marker K8.1,as described in reference 47. The results of at least two experimentsperformed in duplicate were quantitated. The levels of reactivationin Vero-rKSHV.219 cells were quantitated by measuring the K8.1marker at 48 h after the addition of 4-OHT, using the formulasdescribed in reference 3.

For adherent Vero-rKSHV.219, HeLa, or 293 cells, coverslipswere washed three times with 1x phosphate-buffered saline (PBS),and liquid was aspirated completely. Fresh 4% paraformaldehyde(wt/vol in 1x PBS) was added to fix the cells at room temperaturefor 30 min. The coverslips were washed three times with 1x PBSand then incubated in permeabilization buffer (1x PBS, 0.1%Triton X-100, 0.1% sodium citrate) at 4°C for 10 min. Cellswere washed twice with 1x PBS and incubated in blocking buffer(1x PBS, 1.0% Triton X-100, 0.5% Tween-20, 3% bovine serum albumin)at room temperature for 30 min. The primary antisera (anti-ORF50or anti-ORF57 diluted 1:1,000 in blocking buffer [47, 59]) wereadded to cover the cells ( $~$ 250 µl) and incubated at roomtemperature for 1 h. Coverslips were washed three times with1x PBS and then incubated with secondary antibodies (goat anti-rabbitconjugated to tetramethyl rhodamine iso-thiocyanate [TRITC;MP Biomedical] or Alexa Fluor 350 [Invitrogen molecular probe]diluted 1:1,000 in blocking buffer) at room temperature for1 h in the dark. Coverslips were washed three times with 1xPBS, and all liquid at the edges of the coverslips was removedby aspiration. A drop of DNA mounting solution (standard orcontaining the DNA dye 4',6-diamidino-2-phenylindole [DAPI];Vector Laboratories) was placed on the slide, and coverslipswere mounted inverted and sealed to the slides with nail polish.Slides were viewed immediately or stored at 4°C in the dark.Nuclear/cytoplasmic ratios were determined with the softwareprogram ImageJ (1).

All immunofluorescence procedures were performed under conditionsin which autofluorescence from GFP or RFP fused to ORF50 wasnot visible.

KSHV infections. Vero-rKSHV.219 cells were transfected with the pcDNA3.1-ORF50 ${Delta}$ NLS1,2-ER-Tmplasmid. At 16 h posttransfection, cells were left untreatedor treated with 0.1 mM 4-OHT, as indicated in Fig. 7. The supernatantmedium was collected 7 days after the addition of 4-OHT, andcells and debris were removed by centrifugation and passageof supernatants through 0.4-µm filters. Filtered viruswas transferred to 80%-confluent 293 cells plated on coverslipsin 35-mm plates. Infected 293 cells were detected by GFP expressionfrom rKSHV.219 at 2 days postinfection.

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FIG. 7. Nuclear relocalization of Rta reactivates the complete KSHV lytic cycle. (A) Vero-rKSHV.219 cells were transfected with the Rta ${Delta}$ NLS1,2-ER expression vector. Three hours following transfection, half of the cells were left untreated or treated with 4-OHT, as indicated. At 40 h following 4-OHT addition, total cellular RNA was purified and analyzed by Northern blotting; probes are indicated at left. Vec, vector. (B) Vero-rKSHV.219 cells were transfected with Rta ${Delta}$ NLS1,2-ER plasmid and treated with 4-OHT as described for panel A. At the indicated times following 4-OHT addition, total cellular RNA was purified and analyzed by Northern blotting; probes are indicated at left. The blot was quantitated by phosphorimager; each signal for Nut-1/PAN and ORF50 was normalized to the corresponding signal for 7SK. The level of induction was calculated by comparison to the signal for untreated cells at each time point. (C) Vero-rKSHV.219 cells were transfected and treated with 4-OHT as described for panel B. At 24 h after the addition of 4-OHT, cells were analyzed by indirect immunofluorescence using ORF50/Mta-specific primary antiserum and Alexa Fluor 350-conjugated secondary antibody. GFP and RFP fluorescence and immunofluorescent images of representative cells were captured digitally. (D) Vero-rKSHV.219 cells were transfected and treated with 4-OHT as described for panel B. At 72 h following 4-OHT addition, total cellular RNA was purified and analyzed by real-time qRT-PCR with primers that detect the indicated true L transcripts. (E) Vero-rKSHV.219 cells were transfected with the indicated plasmids, and indicated cells were treated with 4-OHT as described for panel A. At 48 h following 4-OHT addition, viral reactivation was quantitated by measuring the percentage of cells expressing the true L marker K8.1. Positive controls were transfection of WT Rta plasmid or treatment with sodium butyrate (Na Bu). Results are from two experiments performed in triplicate, in each of which 500 K8.1 positive cells were counted. (F) Vero-rKSHV.219 cells were transfected with the indicated plasmids, and the indicated cells were treated with 4-OHT as described for panel A. Seven days after the addition of 4-OHT, cell supernatants were transferred to naïve 293 cell monolayers. KSHV-infected 293 cells were detected by GFP expression, and nuclei were detected with DAPI. Infection was quantitated by counting 500 GFP-positive cells in triplicate experiments. Error bars show standard deviations. +, treated; –, not treated.

RNA isolation. RNA isolation was performed as described in reference 59.

Northern blotting. Northern blotting was performed as described in reference 46.The double-stranded probes were the EcoRI fragment of pCR2.1-nut-1(+) (for nut-1/PAN), the BamHI/HindIII fragment of pRSET-0.8(for ORF50/Rta) (47), and the AccI/KpnI fragment of pGem-7SK(for 7SK) (59). The probes were labeled with [ ${alpha}$ ³²P]dCTP by usinga HexaLabel DNA labeling kit (Fermentas Life Sciences) and purifiedby chromatography (Spin-25; USA Scientific). The signals onthe Northern membranes were quantitated by using a phosphorimager.

Western blotting. Western blotting was performed as described in reference 59.Antitubulin antibody was purchased from Sigma.

Microarray printing, cDNA labeling, hybridization, and data analysis. The KSHV microarray consisted of 60- to 70-mer oligonucleotidesdesigned to detect 96 predicted KSHV ORFs and splice variantsidentical to those published by Lu et al. (44) and updated toinclude newer annotated transcripts. Detector oligonucleotidesfor human housekeeping genes (Operon Biotechnologies) were alsosynthesized. Oligonucleotides were spotted in triplicate ontopoly-L-lysine-coated glass microscope slides by using a GeneMachinesOmnigrid 100 arrayer (Genomic Solutions) and SMP3 pins (Telechem).

Six pairs of total-RNA samples from five independent transfectionswere analyzed. The RNA quality was assessed by visual inspectionby formaldehyde-agarose gel electrophoresis and Northern blotting.Three or 6 µgs of each RNA sample (equal amounts per pair)were adjusted to 11 µl with distilled water. A 2.2-µlamount of random hexamers (2 µg/µl; Sigma-Genosys)was added and the mixture was heated at 98°C for 2 min andthen snap-cooled on ice. An 11.1-µl amount of master mix(5.0 µl first-strand buffer, 2.5 µl 100 mM dithiothreitol,2.3 µl low-dT deoxynucleotide triphosphate mix [5 mM A,G, and C and 0.2 mM T stock], containing either 1.5 µlCy3 [in mixture without 4-OHT] or Cy5 [in mixture with 4-OHT][PerkinElmer]) was added. The mixture was subsequently supplementedwith 1.2 µl SuperScript (Invitrogen) and then incubatedfor 10 min at 25°C, followed by 90 min at 42°C. Microcon10 columns (YM 10; Millipore) were primed with 400 µl1x TE buffer (Tris-EDTA, pH 8.0) by centrifugation at room temperaturefor 10 min. Paired Cy3-labeled and Cy5-labeled cDNAs were combined,added to the primed column, and purified by centrifugation.When approximately 25 µl of liquid remained above themembrane, an extra 200 µl 1x TE buffer was added to washthe column. Centrifugation was continued until approximately4.5 µl of liquid remained above the membrane. The purified,labeled cDNAs were transferred to a new tube and combined withan equal volume of hybridization mixture (0.5 µl 10 mg/mltRNA [Sigma], 0.5 µl 10 mg/ml salmon sperm DNA [Sigma],1.0 µl 20x SSC [1x SSC is 0.15 M NaCl plus 0.015 M sodiumcitrate], 2.5 µl formamide [Fisher], and 1.0 µl1% sodium dodecyl sulfate [SDS]). The mixture was heated for2 min at 98°C and cooled for 5 min at room temperature immediatelybefore being loaded on the microarray slides.

Prior to hybridization, the slides were blocked in prehybridizationsolution (3.0 g bovine serum albumin [fraction V; Roche], 1.2ml 10% SDS, 106.0 ml Milli-Q water) at 42°C for 1 h. Theprehybridized slides were washed with nuclease-free water for2 min and isopropanol for 2 min and subsequently dried by centrifugation.The labeled cDNAs were applied to slides, covered by a 22- by22-mm coverslip (Corning), sealed into a hybridization chamber(GeneMachines), and hybridized at 50°C overnight. Afterhybridization, coverslips were removed by submerging the slidesin solution I (2x SSC, 1% SDS), and slides were rinsed in solutionII (1x SSC, 0.05% SDS) for 1 min and solution III (0.06x SSC)for 2 min. Slides were dried by centrifugation and scanned immediatelywith a GenePix 4000B scanner (Molecular Devices). The imageswere processed by using GenePix 5.1. The data were filteredby removing all spots that were below the background noise orflagged as "bad." Spots were considered to be below the backgroundnoise if the sum of the median intensities of the two channelswas less than twice the highest mean background of the chip.The chips were normalized by the print-tip loess method (80).The ratio of the mean median intensity of Cy5 over the meanmedian intensity of Cy3 was determined for each spot (dye ratios).

Replicate dye ratios from identical RNA samples hybridized toindependent arrays were normalized to glyceraldehyde 3-phosphatedehydrogenase (GAPDH). Replicate dye ratios from independentRNA samples were then normalized to the averaged dye ratiosof the KSHV true L ORF25/major capsid protein transcript (asquantitated by Northern blotting, the major capsid protein transcriptwas unaffected by Rta WT-ER and mutants in the presence of proteinsynthesis inhibitors).

The five resulting data sets were tested for significant changesin levels of gene expression by using two methods. For method1 (to find the z-score), the dye ratios of each spot for Rta ${Delta}$ NLS1,2-ERwere divided by the dye ratios for the ER vector to determinethe spot-specific effects of 4-OHT addition. The means of thetriplicate dye ratios were calculated to determine the gene-specificeffects of 4-OHT addition. Each data set was log transformedand fit to a normal (Gaussian) distribution, and the means ofthe normalized gene-specific values were calculated. The resultingset of gene-specific means was fit to a normal distribution,outliers were excluded by using Peirce's criterion (hypothesis:one outlier per gene measurement) (35), and the average numberof standard deviations from the mean was calculated for eachgene (z-score). For method 2 (to find q values), gene-specifict tests and q values (minimum false-positive rate that can beattained when calling a change in gene expression significant)were calculated by comparing the dye ratios of each spot forRta ${Delta}$ NLS1,2-ER to the dye ratios for the ER vector by using thesoftware program Significance Analysis of Microarrays (SAM)(70).

The levels of change in expression for genes whose means werethe greatest number of standard deviations from the populationmean and with the lowest q values were quantitated by usingreal-time reverse transcriptase PCR (RT-PCR).

qRT-PCR. Primers for quantitative PCR (qPCR) were designed by using Primer3software (http://frodo.wi.mit.edu) as described in reference16; sequences are available from the authors by request. Fiveor 100 ng of total RNA (per experiment) were quantitated byusing an iScript one-step RT-PCR kit with Sybr green (Bio-Rad)according to the manufacturer's recommendations, with the followingmodifications: the total reaction mixture volume was 25 µl,containing 12.5 µl 2x Sybr green RT-PCR mix, 0.5 µliScript reverse transcriptase, 0.75 µl forward primer,0.75 µl reverse primer, and nuclease-free water. The mixtureswere amplified by incubation at 50°C for 10 min and 95°Cfor 5 min, followed by 50 cycles of 95°C for 10 s, 55°Cfor 30 s, and 72°C for 1 min, in a Corbett RotorGene instrument.The reaction products were examined by melting curve analysisand 2.5% agarose gel electrophoresis to ensure that a singleamplicon was generated, without primer dimers. In each experiment,one control lacking RT was included to ensure that ampliconswere not generated from contaminating viral genomic DNA in theextracts. The respective take-off cycles for each reaction weredetermined by using the comparative quantitation function ofthe Corbett Research software package and used as the thresholdcycles (C_T) to calculate the levels of change in expressionby the ${Delta}$ ${Delta}$ C_T method (43). The control reactions for ${Delta}$ ${Delta}$ C_T used GAPDHprimers for internal controls or matched primer pairs to compareviral genes in matched transfections in the presence or absenceof 4-OHT. The means and standard deviations of the results foreach gene were calculated from the results of at least two reactionsfrom at least two different transfections.

Microarray data accession number. Raw and normalized microarray data are available at the GeneExpression Omnibus (GEO; http://www.ncbi.nlm.nih.gov/geo) underaccession number GSE 11432.

RESULTS

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RESULTS

Rta does not require the putative NLS1. We and others have previously performed structure-function analysesof the KSHV ORF50/Rta protein, whose results are summarizedin Fig. 1A. Rta contains an N-terminal, basic DNA binding domain(45, 65), a proline-rich leucine repeat that is required forthe tetramerization of Rta (3), and a C-terminal transcriptionalactivation domain (46, 72). Rta is constitutively localizedto the nuclei in transfected and infected cells (47).

Further analysis of the amino acid sequence of Rta revealedtwo distinct lysine/arginine-rich domains, which we hypothesizedmight function as NLSs. NLS1 (aa 6 to 12) and NLS2 (aa 516 to530) are indicated in Fig. 1A. We deleted exon 1 from a genomicclone of Rta, generating an insert that expresses Rta proteininitiating at methionine 72 (see Fig. 1A). We call this mutantRta ${Delta}$ NLS1.

We first tested whether or not Rta ${Delta}$ NLS1 could activate transcriptionfrom two promoters that we previously showed were activatedby the WT Rta protein (46, 47). We cotransfected reporter vectorsfor the Nut-1/PAN or thymidine kinase (TK) promoters togetherwith increasing amounts of the WT or Rta ${Delta}$ NLS1 expression vectorsinto BL-41 cells. We calculated the change in the level of activationby comparison to the basal activity of each promoter transfectedwith empty vector alone. The transactivation of both promotersby either WT Rta or Rta ${Delta}$ NLS1 was indistinguishable. The nut-1promoter was activated by both proteins to a maximum of 50-to 60-fold (Fig. 1B), while the TK promoter was activated byboth proteins to about 40-fold (Fig. 1C). These data suggestthat aa 1 to 71 of Rta, including the putative NLS1, are dispensablefor the transactivation of KSHV DE promoters.

We also tested Rta ${Delta}$ NLS1 for its ability to reactivate KSHV fromlatency in BCBL-1 cells. We coelectroporated BCBL-1 cells withthe Rta expression plasmids and a plasmid expressing the hepatitisdelta antigen to permit the quantitation of transfected cells.At 48 h after electroporation, we counted the percentage oftransfected cells scoring positive for either the DE proteinORF59 or the true L protein K8.1 by indirect immunofluorescence.Each value was compared to that for BCBL-1 cells transfectedwith the empty expression vector to calculate the change inthe level of reactivation.

The results presented in Fig. 1D show that the treatment ofvector-transfected cells with tetradecanoyl phorbol acetateleads to about a fivefold and twofold induction of ORF59 andK8.1, respectively. The ectopic expression of either WT Rtaor Rta ${Delta}$ NLS1 results in similar induction of the lytic markers(Fig. 1D); these data suggest that aa 1 to 71 of Rta, includingNLS1, are also dispensable for stimulating the reactivationof latent KSHV. The control DNA for the effects of transfection,the ORF50 genomic locus controlled by its native promoter (ORF50Sal 7), was unable to reactivate the virus since Rta is notexpressed from this clone in untreated PEL cells (Fig. 1D).The results presented in Fig. 1 therefore show that aa 1 to71, including NLS1, are not required for Rta transactivationor the stimulation of KSHV reactivation.

Putative NLS2 is required for transactivation by Rta. We also deleted aa 516 to 530, designated NLS2 (Fig. 1A), inthe context of the FL WT Rta or Rta ${Delta}$ NLS1. This strategy generatedthe mutants Rta ${Delta}$ NLS2 and Rta ${Delta}$ NLS1,2, respectively. We comparedthese two mutants for their abilities to activate reportersfor the ORF57 and nut-1/PAN promoters in transfections of BL-41cells. As we have previously shown (3, 6, 7, 46, 47, 59), WTRta transactivates the ORF57 promoter by at least 400-fold (Fig.2A) and the nut-1 promoter by 60- to 80-fold (Fig. 2B). However,neither Rta ${Delta}$ NLS2 alone nor the double-mutant Rta ${Delta}$ NLS1,2 transactivatedeither promoter. We concluded that NLS2 was required for Rtato transcriptionally transactivate both promoters.

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FIG. 2. Putative NLS2 is required for Rta function. BL-41 cells were coelectroporated with plasmids expressing the indicated proteins and the levels of activation calculated as described in the legend to Fig. 1B. Reporter plasmids were pGL3-ORF57 (A) or pGL3-Nut-1 (B), both expressing luciferase. Black triangles indicate relative amounts of transfected expression vectors. Error bars show standard deviations.

NLS2, but not the putative NLS1, is required for nuclear localization of Rta. To determine whether nuclear localization corresponded withthe transactivation phenotypes of the NLS mutants, we transfectedHeLa cells with the vectors expressing WT Rta or each of themutants and determined the subcellular localization of eachby indirect immunofluorescence. Using the nuclear stain DAPIas a reference, Rta ${Delta}$ NLS1 was found to localize completely tothe nuclei of HeLa cells, indistinguishably from WT Rta (Fig.3).

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FIG. 3. NLS2, but not putative NLS1, is required for nuclear localization of Rta. HeLa cells were transfected with plasmids expressing the indicated proteins and analyzed by indirect immunofluorescence using Rta-specific antiserum. Nuclei were visualized by DAPI stain. Images of representative cells were captured digitally and converted to grayscale.

However, the deletion of putative NLS2 resulted in a strikinglydifferent subcellular localization for Rta. Both Rta ${Delta}$ NLS2 andRta ${Delta}$ NLS1,2 were well expressed but were confined to the cytoplasmof transfected HeLa cells. (Fig. 3). For both mutants, we observednearly 100% discordance between the nuclear stain (DAPI) andthe Rta stain in all transfected cells. The deletion of NLS2resulted in a similar inability to enter the nucleus in CV-1and SLK cells (not shown). Together with the results shown inFig. 1 and 2, these data suggested that aa 1 to 71, includingthe putative NLS1, were not required for (i) nuclear localizationof Rta, (ii) transactivation by Rta, or (iii) reactivation ofthe virus from latency. These results also suggested that thefailure of the Rta ${Delta}$ NLS2 and Rta ${Delta}$ NLS1,2 proteins to transactivatetranscription was due to their failure to access the nucleiof transfected cells.

NLS2, but not putative NLS1, is sufficient to relocalize a heterologous protein to the nucleus. To determine whether each of the putative NLS motifs could redirecta heterologous protein to the cell nucleus, we fused each independentlyto the ORF of eGFP. As shown in Fig. 4, GFP alone is distributednonspecifically between the nuclei and cytoplasm of transfectedHeLa cells. Fusion of the putative NLS1 to eGFP had little effecton its subcellular localization (Fig. 4). However, fusion ofNLS2 to eGFP resulted in dramatic and exclusive relocalizationof eGFP to HeLa cell nuclei (Fig. 4). Considered together withthe data presented above, Rta NLS2 is necessary and sufficientto localize proteins to cell nuclei.

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FIG. 4. NLS2 is sufficient to completely relocalize eGFP to the cell nuclei. HeLa cells were transfected with plasmids expressing the indicated proteins and analyzed by DAPI staining of nuclei. GFP and DAPI images of representative cells were captured digitally and converted to grayscale. Nuclear/cytoplasmic localization ratios (Nucl:Cyto) are shown under the images; SD, standard deviations; NA, not applicable.

Nuclear/cytoplasmic localization of Rta can be regulated by fusion to a heterologous HBD. Deletion of the putative C-terminal NLS2 of Rta resulted inconstitutive relocalization of the mutant protein to the cytoplasmof transfected cells and inhibition of its ability to transactivatetranscription. It has been reported that a protein's nuclearlocalization can be controlled in a hormone-dependent fashionif fused to the HBD of the murine ER gene (42). Since the ERHBD lacks the ER DNA binding domain (DBD), it lacks the abilityto bind to its cognate DNA elements but can be directed to DNAby the DNA binding specificity of the protein to which it isfused. This approach has been used successfully to generateconditionally active, hormone-dependent variants of c-Myc, v-Myb,MyoD, Epstein-Barr virus EBNA2, and adenovirus E1a, among others(19, 20, 28, 33, 66).

To determine whether relocalization of the NLS2 mutant of ORF50to the cell nucleus could rescue its activity, we fused WT Rtaand Rta ${Delta}$ NLS1,2, at their respective C-termini, to a modifiedform of the ER HBD. This modified HBD is called ER-TM and containsa point mutation, G525R, that eliminates drawbacks of the originalER HBD (42). In this way, ER-TM no longer binds 17β-estradiolthat is frequently present in cell culture media and it lacksendogenous transcriptional activity; however, it remains responsiveto activation by the synthetic steroid 4-OHT.

In HeLa cells, most but not all Rta WT-ER was redistributedto the cytoplasm in the absence of 4-OHT but still retainedobservable nuclear localization (Fig. 5A, top panel). In contrast,Rta ${Delta}$ NLS1,2-ER was found constitutively in the cytoplasm in theabsence of inducing hormone 4-OHT (Fig. 5B, top panel), i.e.,we observed complete discordance between the nuclear (DAPI)stain and the ORF50/Rta stain in all transfected cells. Thesedata suggest that ER-TM is incompletely dominant to the endogenousRta NLS2 in controlling the distribution of Rta WT-ER in transfectedcells. In WT Rta, NLS2 seems to partially overcome the cytoplasmicretention of the ER fusion by heat shock proteins in the absenceof inducing hormone. We saw a similar incomplete dominance ofthe ER domain when it was fused to Rta ${Delta}$ NLS1 (not shown).

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FIG. 5. 4-OHT-regulated nuclear localization of Rta. HeLa cells were transfected with plasmids expressing WT Rta-ER (A) or Rta ${Delta}$ NLS1,2-ER (B), and half of each set of transfected cells was treated with 4-OHT. Cells were analyzed and visualized as described in the legend to Fig. 3.

When we added the synthetic hormone 4-OHT to the cell medium,all of the WT Rta (Fig. 5A, bottom panel) and mutant (Fig. 5B,bottom panel, and data not shown) fusion proteins were dramaticallyrelocalized to the nuclei of transfected cells. Therefore, weconcluded that the nuclear/cytoplasmic localization of Rta ${Delta}$ NLS1,2-ER,but not Rta WT-ER, was very tightly regulated by the additionor omission of 4-OHT to tissue culture media.

Rta must be nuclear to transactivate transcription. To test the functional significance of the nuclear/cytoplasmiclocalizations of the Rta-ER fusion proteins, each was cotransfectedwith the ORF57/Mta promoter-reporter vector into BL-41 cells.At 3 h postelectroporation, 4-OHT was added to half of the transfectioncultures and the other half remained untreated. Twenty-fourhours later, the cells were harvested, and the luciferase activitiesof the reporter gene were quantitated.

In the absence of the inducing hormone, Rta WT-ER, Rta ${Delta}$ NLS1-ER,and Rta ${Delta}$ NLS1,2-ER were all unable to transactivate the ORF57/Mtapromoter (Fig. 6A). The small amount of nuclear localizationof Rta WT-ER and Rta ${Delta}$ NLS1-ER in the absence of hormone (Fig.5A and data not shown) seems to be inconsequential for transactivationof the ORF57 promoter by either fusion protein. However, theaddition of 4-OHT resulted in robust transactivation by allthree proteins (50- to 120-fold), suggesting that each proteinis rendered active by translocation to the nucleus. We speculatethat transactivation by Rta ${Delta}$ NLS1,2-ER at 10 µg did notincrease relative to the level at 3 µg due to nonspecifictranscriptional squelching over the range of input plasmidstested. The negative control transfections of the empty expressionvector (pcDNA3) showed no transactivation in the presence orabsence of 4-OHT. The positive control transfections of cognateWT Rta without the ER-TM fusion transactivated the ORF57 promoterregardless of 4-OHT addition, as expected.

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FIG. 6. Nuclear localization of Rta is required for transactivation. BL-41 cells were coelectroporated with plasmids expressing the indicated proteins, and half of each set of transfected cells was treated with 4-OHT. The level of activation was calculated as described in the legend to Fig. 1B. Reporter plasmids were pGL3-ORF57 (A) or pGL3-Nut-1 (B), both expressing luciferase. Error bars show standard deviations. +, treated; –, not treated.

To confirm these data for a second KSHV DE promoter, we repeatedthe above approach using the nut-1/PAN promoter-reporter vector.Identically to results with the ORF57/Mta promoter, Rta ${Delta}$ NLS1,2-ERonly activated nut-1/PAN in cells treated with 4-OHT (Fig. 6B).Interestingly, Rta WT-ER activated the nut-1/PAN promoter evenin the absence of hormone (Fig. 6B), a result agreeing withthe partial nuclear localization of the WT fusion protein underthose conditions (Fig. 5A). Regardless of this effect, whenwe added the hormone, transactivation by the Rta-ER fusion proteinwas stimulated by 60- to 80-fold. The positive control transfectionsof cognate WT Rta (without the ER-TM fusion) transactivatedthe nut-1 promoter regardless of 4-OHT addition, as expected(Fig. 6B).

Taken together, these data demonstrate a tight correspondencebetween nuclear localization of WT and mutant Rta proteins andtheir abilities to transactivate transcription. The transcriptionaldefect in Rta ${Delta}$ NLS1,2 was the result of its incorrect localizationto the cytoplasm, but it transactivated promoters at a levelquantitatively similar to that of cognate Rta when it was relocalizedto the nucleus by the addition of 4-OHT. The cognate WT Rtaprotein, not fused to the ER, was constitutively localized tothe nucleus of BL-41 cells and robustly transactivated the Mtaand nut-1 promoters in the presence or absence of tamoxifen.For both promoters, there was no background stimulation by 4-OHT,as control cells transfected with the empty vector (Fig. 6)showed only basal activity in the absence or presence of thehormone.

Nuclear localization is required for Rta to reactivate KSHV from latency. To determine whether the entire KSHV lytic cycle could be reactivatedby conditionally relocalizing Rta to the cell nucleus, we focusedour analyses on the effects of Rta ${Delta}$ NLS1,2-ER since it offeredthe most-stringent control among the ER HBD fusion proteins.As our infected model cell line, we chose easily transfectableVero-rKSHV.219 cells (71). This is a subclone of the Vero cellline that is infected with an rKSHV clone derived from the JSC-1PEL cell line ("rKSHV.219"). The rKSHV.219 virus constitutivelyexpresses eGFP and puromycin resistance and produces infectiousvirus following various methods of inducing reactivation (71).

Among KSHV genes, the nut-1/PAN promoter is strongly activatedby Rta in transient transfections, and the nut-1/PAN transcriptis induced by Rta in latently infected PEL cells (47, 68). Totest whether regulated nuclear localization of Rta ${Delta}$ NLS1,2-ERwould function similarly in latently infected Vero cells, wetransfected multiple dishes of Vero-rKSHV.219 cells with theRta ${Delta}$ NLS1,2-ER expression vector or the empty vector. Half ofeach set of transfectants was treated with the inducer 4-OHT3 h later. Analyses of total RNA by Northern blotting showedthat background levels of the nut-1/PAN transcript were expressedin untreated cells that were transfected with either vector(Fig. 7A, lanes 1, 3, and 4). The small amount of nut-1 expressionin the absence of 4-OHT (Fig. 7A) suggests that a low levelof spontaneous reactivation is occurring; presumably, spontaneouslyexpressed endogenous Rta transactivates nut-1. The additionof 4-OHT to the growth medium resulted in dramatic inductionof nut-1/PAN in cells expressing Rta ${Delta}$ NLS1,2-ER, but not in vector-transfectedcells (Fig. 7A, compare lane 2 with lanes 5 and 6). This provedthat the induction of nut-1/PAN expression by 4-OHT requiredectopic expression of the Rta fusion protein and was not mediatedindirectly by effects of 4-OHT on the cells alone. The middlepanel of Fig. 7A shows that the Rta transcript was only detectablein cells expressing Rta ${Delta}$ NLS1,2-ER, regardless of 4-OHT addition;the Northern probe detects both the endogenous ORF50 messageand the ectopically expressed Rta ${Delta}$ NLS1,2-ER message, and thetwo transcripts are indistinguishable in size. These data suggestedthat the relocalization of Rta to the cell nucleus was capableof reactivating the KSHV lytic cycle in a fashion similar tothat in PEL cells.

Similar to other DNA viruses, individual KSHV genes are expressedin an ordered cascade during reactivation, in kinetically classifiablegroups (31, 44). To determine the kinetics of the expressionof nut-1/PAN in response to nuclear relocalization of Rta ${Delta}$ NLS1,2-ER,we analyzed nut-1/PAN expression over a 64-h period following4-OHT addition to transfected cells. The Nut-1/PAN transcriptwas induced at all time points in transfected cells that hadbeen treated with 4-OHT (Fig. 7B, top panel). Nut-1/PAN waseasily detected at 16 h and peaked in expression at 40 h posttransfection(22.2-fold). The lack of Nut-1/PAN expression in untreated cellsdemonstrates tight control of Rta ${Delta}$ NLS1,2-ER function at all timepoints. Untransfected cells were the control (Fig. 7B, firstlane). Rta expression remained relatively constant in transfectedcells (Fig. 7B, center panel). Finally, the cellular 7SK RNAshowed strong expression regardless of transfection or the additionof 4-OHT (Fig. 7B, bottom panel). These data demonstrate thatthe Rta ${Delta}$ NLS1,2-ER protein induces Nut-1/PAN expression from thelatent KSHV genome in Vero cells in a 4-OHT-dependent manner.The kinetic pattern of nut-1/PAN expression is similar to thatof virus reactivated with chemicals (67), with a slightly delayedpeak of expression.

The reactivation of rKSHV.219 can also be monitored by the expressionof the RFP dsRed, which was cloned into the rKSHV.219 genomeunder the control of an ectopic copy of the lytic nut-1/PANpromoter (71). We combined the detection of RFP with indirectimmunofluorescence by using our ORF57/Mta-specific antiserum(59) 24 h after adding 4-OHT to half of the cells. The resultsin Fig. 7C show that GFP, expressed constitutively from therKSHV.219 virus, was easily and uniformly detectable in allVero-rKSHV.219 cells, regardless of 4-OHT treatment. However,both RFP and Mta were expressed only in the cells that weretreated with 4-OHT, and not in cells that were not treated with4-OHT (Fig. 7C). As a negative control, Vero-rKSHV.219 transfectedwith empty vector and treated with 4-OHT did not express eithermarker of reactivation (not shown). The data shown in Fig. 7therefore confirmed that the relocalization of Rta to infected-cellnuclei induced the expression of both RNA and protein markersof KSHV lytic reactivation.

Nuclear relocalization of Rta reactivates the entire KSHV lytic cycle. True L genes in KSHV are those whose transcription strictlyrequires the prior initiation of viral DNA replication (44).In PEL cells, ectopic expression of Rta induced the expressionof the true L gene K8.1 in the absence, but not the presence,of ganciclovir, an inhibitor of KSHV replication (47). Thosedata proved that ectopic Rta protein induced authentic KSHVreactivation in PEL cells.

To determine whether nuclear relocalization of Rta could inducetrue L gene expression in Vero-rKSHV.219 cells, we asked whethertranscription from the true L genes K8.1, ORF20, and ORF33 (44)was induced by the addition of 4-OHT to cells transfected withthe Rta ${Delta}$ NLS1,2-ER vector. K8.1, ORF20, and ORF33 were all transactivatedfollowing the relocalization of Rta to the nuclei of the infectedVero cells (Fig. 7D). The average range of expression for thethree genes was 13- to 76-fold, as determined by real-time qRT-PCR.Negative control reactions in which RT was omitted did not yielda PCR product. Therefore, the relocalization of Rta to the nucleiof KSHV-infected Vero cells induces true L gene expression.

We sought confirmation of the real-time RT-PCR data by quantitatingK8.1 protein expression in the KSHV-infected Vero cells. Asshown in Fig. 7E, Rta ${Delta}$ NLS1,2-ER only stimulated K8.1 expressionin cells treated with 4-OHT. Interestingly, Rta WT-ER inducedK8.1 expression even in the absence of hormone (Fig. 7E), agreeingwith the partial nuclear localization of the WT fusion proteinunder those conditions (Fig. 5A). As expected, the positivecontrol transfection of the cognate WT Rta vector (without theER-TM fusion) and treatment of the cells with the histone deacetylaseinhibitor sodium butyrate induced K8.1 expression without furtheraddition of 4-OHT (Fig. 7E).

The ultimate proof of complete, productive viral reactivationis the release of mature, infectious virus to the tissue culturemedium of infected cells. At 7 days after the addition of OHTto cells transfected with the Rta ${Delta}$ NLS1,2-ER vector, we transferredclarified supernatants to monolayers of naïve 293 cellsand detected rKSHV.219 by observing the 293 cells for GFP expression.Figure 7F shows representative images from these 293 cell monolayers,which were performed in triplicate. In the top panel of Fig.7F, supernatant from cells transfected in the absence of 4-OHTshows a low level of spontaneously reactivated KSHV that istransmissible. The middle panel of Fig. 7F shows a reproducible,approximately sevenfold increase in the amount of infectiousvirus produced by 4-OHT-mediated nuclear relocalization of Rta ${Delta}$ NLS1,2-ERprotein. Finally, this induction is equivalent to the amountof infectious virus produced by transfecting Vero-rKSHV.219with cognate, WT Rta expression vector (Fig. 7F, bottom panels).The increase in viral titers observed in all panels of Fig.7F was similar to the induction of latent virus shown in Fig.7E.

In summary, our data demonstrate that the entire productiveKSHV lytic cycle is induced and viral promoters are transactivatedin direct concordance with the nuclear localization of the Rtaprotein.

Nut-1/PAN is a direct transcriptional target of Rta in infected cells. The data above showed that the fusion of Rta ${Delta}$ NLS1,2 to the modifiedHBD of the ER generated a variant of Rta (Rta ${Delta}$ NLS1,2-ER) whosenuclear localization, transactivation, and stimulation of thecomplete KSHV lytic cycle could be regulated by the additionof 4-OHT to the tissue culture growth medium. The transfectionof Rta ${Delta}$ NLS1,2-ER into Vero-rKSHV.219 cells constituted an idealsystem for identifying Rta's direct transcriptional targetsin infected cells. Rta could be constitutively expressed inan inactive, cytoplasmic form and then induced to relocalizeto the cell nuclei in the presence of protein synthesis inhibitorsto prohibit de novo expression of any other viral or cellulartransactivators. Furthermore, the shutoff of de novo proteinsynthesis could be confirmed by monitoring RFP expression fromthe recombinant virus (rKSHV.219).

Since CHX alone induced the expression of nut-1/PAN and otherviral transcripts in these cells (not shown), we tested twoother protein synthesis inhibitors, hygromycin and neomycin(Fig. 8A to D) (52). As expected, nut-1/PAN was not inducedby 4-OHT treatment (alone) in cells transfected with the negativecontrol empty expression vector (Fig. 8E, lanes 1 and 2, toppanels). The positive controls show 4-OHT-dependent inductionof nut-1/PAN in Vero-rKSHV.219 cells transfected with Rta ${Delta}$ NLS1,2-ER(Fig. 8E, lanes 3 to 6, top panels). In agreement, Fig. 8B showsthat RFP expression, driven by the ectopic nut-1/PAN promoter,is also dependent on the addition of 4-OHT to cells transfectedwith Rta ${Delta}$ NLS1,2-ER. In cells transfected with Rta ${Delta}$ NLS1,2-ER andtreated with either hygromycin or neomycin, nut-1/PAN inductionis 4-OHT dependent (Fig. 8E, lanes 7 to 14). The results presentedin Fig. 8E also show that the induction of nut-1/PAN in thepresence of neomycin (lanes 13 and 14) is much more robust thanin the presence of hygromycin (lanes 9 and 10). In fact, theinduction of nut-1/PAN in the presence of neomycin is indistinguishablefrom induction without the addition of a protein synthesis inhibitor(Fig. 8E, compare lanes 11 to 14 with lanes 3 to 6). In contrast,in the presence of hygromycin, 4-OHT-dependent induction ofnut-1/PAN is only detectable upon long exposure of the Northernblot (Fig. 8E, second panel down, lanes 7 to 10). Spontaneousnut-1/PAN expression (i.e., in the absence of 4-OHT) is alsoextinguished in the presence of hygromycin (Fig. 8E, lanes 7and 8).

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FIG. 8. Nut-1/PAN is a direct transcriptional target of Rta in infected cells. (A, B, C, D) Strategies for testing the protein synthesis inhibitors hygromycin and neomycin in Vero-rKSHV.219 cells are given above the panels. In the experiments whose results are shown in panels B, C, and D, each half of the experimental strategy (untreated or treated with 4-OHT) was performed in duplicate; panels labeled GFP and RFP show images representative of the results of each experiment (converted to grayscale). (E) Total cellular RNAs corresponding to cells in the experiments diagrammed in panels A, B, C, and D were purified and analyzed by Northern blotting; probes are indicated at left. (F) Vero-rKSHV.219 cells were transfected with the reporter vectors pGL3-promoter (expressing firefly luciferase; Promega) and pcDNA3.1-His-lacZ (expressing β-galactosidase; Invitrogen). Cells were left untreated or treated with hygromycin as described forpanel C, and reporter expression was analyzed 40 h after the addition of hygromycin. Error bars show standard deviations. (G) Vero-rKSHV.219 cells were left untreated or treated with hygromycin as described for panel C, and endogenous tubulin expression was analyzed by Western blot 40 h after the addition of hygromycin. –, untreated; +, treated with 4-OHT; hygro, hygromycin; neo, neomycin; Luc, luciferase; βgal, β-galactosidase.

The difference in nut-1/PAN induction shown in Fig. 8E, lanes7 to 13, might be attributable to different potencies of neomycinand hygromycin. As shown in Fig. 8D, neomycin fails to eliminatede novo expression of RFP induced by 4-OHT treatment, suggestingthat translation is not inhibited by neomycin under these conditions.However, Fig. 8C shows that hygromycin extinguishes RFP expression.Therefore, we hypothesize that the more-robust nut-1/PAN expressionin cells treated with neomycin compared to that in cells treatedwith hygromycin results from the expression of additional lyticcycle transactivators only in the neomycin-treated cells. Thus,hygromycin is the ideal protein synthesis inhibitor for thedetection of direct transcriptional targets of Rta.

Two additional approaches confirmed that hygromycin extinguishedde novo protein synthesis in these cells. Both firefly luciferaseand β-galactosidase expression were reduced by more than95% in Vero-rKSHV.219 cells transfected with reporter vectors(Fig. 8F). As detected by Western blotting, endogenous tubulinexpression was reduced by a similar magnitude (Fig. 8G).

Identification of direct transcriptional targets of Rta in infected cells. To identify all of Rta's direct transcriptional targets, wetested the entire KSHV transcriptome using the strategies outlinedin Fig. 8A (vector transfected with or without 4-OHT) and Fig.8C (Rta ${Delta}$ NLS1,2-ER transfected with or without 4-OHT). As hygromycintreatment for 40 h was cytotoxic (observe rounding in the toppanels of Fig. 8C), we harvested total cellular RNA 15 h after4-OHT addition (30 h after hygromycin addition). The KSHV transcriptomewas queried by hybridizing labeled cDNAs to a KSHV oligonucleotidemicroarray. The microarray contains probes for every KSHV ORFand some of the alternatively spliced transcripts (as originallydesigned by Lu and colleagues [44]), with updated probes fornewly annotated transcripts.

We analyzed the statistical significance of the gene responsesusing two methods and quantitated individual gene responsesby real-time qRT-PCR. The statistical methods, described indetail in Materials and Methods, were (i) generating a normal(Gaussian) curve of the data and determining the number of standarddeviations from the mean of each gene's response (z-score) and(ii) performing gene-specific t tests using Significance Analysisof Microarrays (SAM) software (70). The output of the SAM softwareis a q value, which represents the minimum false-positive ratethat can be attained when calling a change in gene expressionsignificant.

Overall, we identified eight genes that were induced at a levelat least 1.1 standard deviations from the mean level of inductionby relocalizing Rta ${Delta}$ NLS1,2-ER to the nuclei of infected cellswhile inhibiting de novo protein synthesis (Table 1). Thesegenes were nut-1/PAN, ORF57/Mta, ORF56/Primase, K2/vIL-6, ORF37/SOX,K14/vOX, K9/vIRF1, and ORF52. All had q values of <0.01 (i.e.,<1% chance they are false positives). As determined by real-timeqRT-PCR, Rta activated six of these genes directly, over a rangefrom 3.5- to 49.2-fold (ORF56 and nut-1/PAN, respectively).K14 and K9 induction were not quantitated by qRT-PCR since threeindividual sets of primers failed to specifically amplify thecorresponding mRNAs.

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TABLE 1. Identification of direct transcriptional targets of the Rta protein

We also selected eight genes that were not significantly activatedby relocalizing Rta ${Delta}$ NLS1,2-ER to the nuclei of infected cellswhile inhibiting de novo protein synthesis (Table 1). Thesegenes were K11.1/vIRF2, ORF41, ORF36/CHPK, K8.1, ORF34, K10.5/vIRF3,ORF73/LANA-1, and ORF38. q values for these genes ranged from0.05 to 0.14 (four genes), and two were not significantly changed(Table 1). As quantitated by real-time qRT-PCR, the expressionlevel of these genes only changed from 0.8- to 1.4-fold, confirmingtheir insignificance as direct transcriptional targets of Rta.

DISCUSSION

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DISCUSSION

Reactivation of KSHV from latency in B cells is essential forKS development (4, 21, 50, 55, 61, 78). KSHV Rta is a nuclear,transcriptional transactivating protein that is necessary andsufficient for viral reactivation (24, 46, 47, 68, 79). Duringreactivation, transcripts encoding Rta are expressed with IEkinetics prior to the detection of KSHV DE transcripts (67,81). Rta transactivates many KSHV promoters, but none of thecorresponding genes had been formally demonstrated to be directtargets of Rta in infected cells. Since progression throughthe lytic cycle during reactivation is critical for KSHV pathogenesis,delineating the regulation of lytic-gene expression circuitsrequires the identification of the genes that are regulateddirectly or indirectly by Rta, independently or in combinationwith other viral or cellular transcriptional proteins.

To begin to answer these questions, we developed a system inwhich the Rta protein is the only viral transactivator expressedin KSHV-infected cells so that we could identify Rta's directtranscriptional targets. By fusing Rta to a modified HBD ofthe murine ER, we generated a variant of Rta whose nuclear localization(Fig. 5) and transactivation (Fig. 6) were strictly controlledby the addition of 4-OHT to the cell culture medium.

To optimize the regulation of the nuclear/cytoplasmic localizationof the Rta fusion protein, we characterized two putative lysine/arginine-richNLSs in ORF50/Rta (Fig. 1A). We showed that the putative NLS1(aa 6 to 12) was dispensable (Fig. 1 and 3), while NLS2 (aa516 to 530) was essential for nuclear localization (Fig. 3),transactivation (Fig. 2), and stimulation of reactivation byRta (Fig. 7). NLS2 was also sufficient to restrict GFP to thenuclei of transfected cells (Fig. 4). The deletion of both NLSsin the ORF50-ER fusion protein generated a variant of Rta (calledRta ${Delta}$ NLS1,2-ER) that was expressed exclusively in the cytoplasmin the absence of 4-OHT (Fig. 5) and failed to transactivate(Fig. 6). Following the addition of 4-OHT to the medium of transfectedcells, the fusion protein was redirected completely to the nucleus(Fig. 5), regained its ability to transactivate transcription(Fig. 6), and reactivated the entire KSHV lytic cycle (Fig.7). These data suggested that the transcriptional defect inRta ${Delta}$ NLS1,2 was due largely to its inability to access the nucleusand that targeting of Rta ${Delta}$ NLS1,2 to the nucleus in a heterologousfashion can rescue its function. Point mutations in NLS2 havebeen shown to eliminate Rta transactivation (9, 25), but thenuclear localization of those mutant proteins was not examined.

Our strategy for constructing the NLS1 deletion mutant of Rta,which effectively deleted aa 1 to 72 (Fig. 1A), extends ourinsight into the structure-function relationships of the cognateprotein. We have previously shown that DNA binding and the oligomerizationof WT Rta are mediated by aa 1 to 272 and 1 to 414, respectively(3, 45, 46). Rta ${Delta}$ NLS1 was indistinguishable from WT ORF50 innuclear localization (Fig. 3), transactivation of the nut-1and TK promoters (Fig. 1B and C), and viral reactivation (Fig.1D). As both DNA binding and tetramerization of Rta are requiredfor KSHV reactivation (3, 7), our data suggest that aa 1 to72 are dispensable for both essential molecular interactionsof Rta. Chen et al. (12) have reported that an NLS1 deletionmutant of Rta similar to ours was unable to transactivate theK9 and DNA polymerase promoters in transient assays in uninfectedcells. That mutant Rta protein was partially localized to cellnuclei, so it is not clear why its transactivation phenotypediffered from ours. We found that fusion with NLS1 could partiallyrelocalize GFP to the nuclei of transfected cells, but not asdramatically as the similar GFP fusion of NLS2 (Fig. 4).

The Vero-rKSHV.219 cell line was ideal for identifying the directtranscriptional targets of Rta. The cells were easily transfectableand permitted monitoring of RFP to ensure that de novo proteinsynthesis was extinguished by treatment with translational inhibitors(Fig. 8). However, our observation that CHX treatment aloneincreased the expression of nut-1 and other viral transcripts(not shown) suggested that CHX can induce viral lytic cyclegene expression outside the context of full KSHV reactivationin these cells. This effect of CHX was probably due to its establishedpleiotropy in animal cells (41, 69). As hygromycin did not causesimilar pleiotropic effects on these cells, we used it to extinguishprotein synthesis (Fig. 8C).

The genes that were significantly activated by Rta ${Delta}$ NLS1,2 inthe absence of de novo protein synthesis were determined bystatistical analyses of the microarray data and quantitatedby real-time qRT-PCR (Table 1). In our model system, the eightdirect transcriptional targets of Rta were nut-1/PAN, ORF57/Mta,ORF56/Primase, K2/vIL-6, ORF37/SOX, K14/vOX, K9/vIRF1, and ORF52(Table 1). The results of previous studies showed that sequencesupstream of five of these genes, nut-1/PAN, ORF57, K2, K14,and K9, were sufficient for directing Rta-mediated, transienttransactivation of reporter molecules in uninfected cells (12,15, 34, 39, 46, 47, 63). Our data establish that in the contextof the intact viral genome in infected cells (i) those six genesare indeed authentic, direct transcriptional targets of Rtaand (ii) their proximal upstream sequences are authentic promoters.The mechanisms used by Rta to transactivate some of these promotershave been well defined by using transient assays. Among thetranscriptional mechanisms employed by Rta, direct DNA bindingand interactions with the cellular protein RBP-Jk are essentialfor KSHV reactivation (6, 7, 38).

However, our data provide further support for the idea thatRta-mediated transactivation is very complex. Our data demonstratethat in the context of a viral infection, Rta's target genescannot be easily predicted only by identifying an Rta or RBP-Jkbinding site in the putative promoter of a gene. For example,the nut-1/PAN, K12/kaposin, and ori-Lyt promoters all containhigh-affinity Rta binding sites that are required for Rta transactivationin transient assays (10, 64). However, only nut-1/PAN was activatedby Rta when we inhibited de novo protein synthesis in infectedcells (Fig. 8E and Table 1). Likewise, the presence or absenceof particular cis promoter elements did not distinguish betweenthe magnitudes of Rta transactivation of particular genes. Forexample, the binding of RBP-Jk to the promoters of ORF57/Mta,K8/K-bZIP, K14, and ORF6 is required for Rta-mediated transactivationof those promoters in transient assays (6, 7, 37, 39). However,only ORF57/Mta was activated by Rta when we inhibited de novoprotein synthesis.

In fact, the KSHV genome contains 177 consensus RBP-Jk elements(our unpublished data), yet nuclear-relocalized Rta inducedonly eight genes when we inhibited de novo protein synthesis(Table 1). Our data suggest that regardless of the autonomousmechanism used by Rta to transactivate promoters during reactivation,the transcription of the majority of the lytic genes requirede novo expression of additional proteins. There is ample evidencefor both viral and cellular proteins that could satisfy thisproposed role as Rta-cooperating factors. The most apparentis the Mta transactivator protein encoded by KSHV ORF57, anessential protein whose expression at the single-cell levelappears to correspond to viruses that are "committed" to fullreactivation (26, 49, 59). Other lytic cycle transactivatorsare K9/vIRF-1, K-bZIP, and ORF49 (23, 30, 75). Therefore, theinduction of some lytic genes by Rta is probably indirectlymediated through the other lytic cycle transactivators.

The requirement for de novo expression of cellular transcriptionalregulatory proteins for KSHV reactivation can be interpretedby considering the results of studies of Rta transactivationin transient promoter-reporter assays in uninfected cells. Thesetransient assays have shown that Rta transactivates many promotersfrom KSHV lytic cycle genes. Since the majority of these geneswere not identified in the present study as direct transcriptionaltargets of Rta in infected cells, we hypothesize that de novoexpression of cellular proteins by Rta also contributes to Rta-mediatedtransactivation of these promoters. For example, Rta transactivatesthe K-bZIP promoter in uninfected cells, yet we did not detectinduction of K-bZIP by Rta-ER in infected cells when de novoprotein synthesis was extinguished. Transactivation of the KSHVK-bZIP promoter by Rta requires the cellular protein RBP-Jk(7, 77). While the expression level of RBP-Jk does not changewhen KSHV reactivates (6), the cellular proteins Oct-1 and C/EBP ${alpha}$ are induced during reactivation and contribute to the Rta-mediatedtransactivation of K-bZIP (6, 76). In fact, C/EBP ${alpha}$ is inducedby the ectopic expression of Rta. We therefore propose thatin infected cells, K-bZIP transactivation by Rta requires theinduction of cellular proteins that participate not just asaccessory proteins in transactivation but as promoter-bindingfactors that are essential for reactivation.

The limited number of viral genes autonomously activated byRta also has significant implications for KSHV pathogenesisand the progression of reactivation. Rta directly activatedonly one of the nine viral core replication proteins (48), ORF56/Primase(Table 1). Similarly, we have previously demonstrated that lessthan 10% of PEL cells ectopically expressing Rta coexpress theORF59 (DNA polymerase processivity) protein during reactivation(46, 47). Therefore, our data provide formal proof that Rtarequires additional viral and/or cellular proteins to committhe lytic program to initiate viral DNA replication. On a single-celllevel, the expression of Rta is insufficient to commit everycell in an infected population to support productive lytic viralreplication. Instead, Rta is sufficient to initiate the lyticreactivation program, but cellular and viral proteins expressedsubsequent to Rta are key regulators of successful progressiondown the lytic cycle cascade.

Indeed, one direct transcriptional target of Rta identifiedin this study, the ORF57/Mta transactivator, does not autonomouslyreactivate the KSHV lytic cycle but cooperates with Rta to stimulatereactivation and is required for producing mature KSHV virions(6, 26, 47, 49, 59). "Mosaic" patterns of expression of Mta(or other proteins expressed de novo subsequent to Rta) in apopulation of Rta-expressing cells could determine which cellsprogress to complete reactivation and which ones might allowthe expression of pathogenic lytic cycle genes in the absenceof productive replication and cell lysis. In this regard, Rtaalso directly transactivated K2/vIL-6, K14/vOX, and K9/vIRF1(Table 1), each of which encodes a protein with a potentialdirect effect on the abnormal cell growth phenotypes associatedwith KSHV infection.

The results of analyses of genes that are expressed as singleunits of multicistronic transcripts when reactivation is inducedwith chemicals suggest qualitative differences in transactivationwhen Rta is the only transactivator expressed. In response tochemical inducers, ORF37 is expressed in two different multicistronicmessages that also contain ORF34, -35, and -36 or ORF35 and-36 (27). We detected only ORF37 as a direct target of Rta (Table1), suggesting that transcriptional start site selection mightbe altered when Rta is the only transactivator expressed.

Finally, it is likely that we have not detected every directtranscriptional target of Rta using the present experimentalconditions. One significant influence on our data is the temporalrelationship of treatment with the two chemicals hygromycinand 4-OHT and the RNA harvest. Although we optimized the concentrationand length of hygromycin treatment to inhibit de novo proteinsynthesis (Fig. 8), we could not avoid significant cytotoxicityof the drug under the present conditions (Fig. 8C). The cytotoxicitymight have globally lowered intracellular transcript levels.The effective intracellular concentration of the Rta-ER fusionprotein might also influence the activation of different genesin a promoter-specific fashion. We optimized our experimentalconditions for detection of the nut-1/PAN transcript (Fig. 7and 8). Two alterations of our protocol might allow for higherintracellular concentrations of the Rta-ER fusion protein: delayingthe time prior to hygromycin treatment or altering the timeperiod between 4-OHT addition and RNA harvest. Increased concentrationsof the Rta-ER fusion protein might reveal additional targetsof Rta that require a higher threshold of the activator. Ofcourse, increased intracellular concentrations of Rta mightglobally result in decreased overall RNA expression, as Rtais proapoptotic in heterologous systems (58). By blocking denovo protein synthesis, we are likely inhibiting the expressionof antiapoptotic proteins that counteract Rta's putative stimulationof programmed cell death in our system. Finally, since CHX inducedviral transcription independent of Rta expression (not shown),it is conceivable that hygromycin had the same effect on a subsetof Rta's targets and that subsequent relocalization of Rta tocell nuclei resulted in undetectable changes in the level ofexpression of those transcripts.

ACKNOWLEDGMENTS

We gratefully thank Jeff Vieira for the gift of Vero-rKSHV.219cells and Gerard Evan for the gift of the ER clone.

The research was supported by the American Cancer Society, theAmerican Heart Association, the UMDNJ Foundation, and the NJMedical School/University Hospital Cancer Center.

FOOTNOTES

* Corresponding author. Mailing address: 225 Warren St., ICPH E350C, Newark, NJ 07101. Phone: (973) 972-4483, ext. 0907. Fax: (973) 972-8981. E-mail: Lukacdm{at}umdnj.edu

Published ahead of print on 20 August 2008.

These authors contributed equally to this work.

Present address: HIV DRP Retroviral Replication Laboratory,National Cancer Institute, Frederick, MD.

REFERENCES

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