Regulating Intracellular Antiviral Defense and Permissiveness to Hepatitis C Virus RNA Replication through a Cellular RNA Helicase, RIG-I

Virus-responsive signaling pathways that induce alpha/beta interferonproduction and engage intracellular immune defenses influencethe outcome of many viral infections. The processes that triggerthese defenses and their effect upon host permissiveness forspecific viral pathogens are not well understood. We show thatstructured hepatitis C virus (HCV) genomic RNA activates interferonregulatory factor 3 (IRF3), thereby inducing interferon in culturedcells. This response is absent in cells selected for permissivenessfor HCV RNA replication. Studies including genetic complementationrevealed that permissiveness is due to mutational inactivationof RIG-I, an interferon-inducible cellular DExD/H box RNA helicase.Its helicase domain binds HCV RNA and transduces the activationsignal for IRF3 by its caspase recruiting domain homolog. RIG-Iis thus a pathogen receptor that regulates cellular permissivenessto HCV replication and, as an interferon-responsive gene, mayplay a key role in interferon-based therapies for the treatmentof HCV infection.

INTRODUCTION

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Introduction

Hepatitis C virus (HCV) is a major public health problem, infectingnearly 200 million people worldwide and causing hepatic fibrosis,end-stage cirrhosis, and hepatocellular carcinoma (16). A memberof the Flaviviridae, HCV's positive-sense RNA genome containshighly structured 5' and 3' nontranslated regions (NTRs) flankinga large open reading frame (ORF) encoding a polyprotein thatis processed into both structural (core-E2) and nonstructural(NS) proteins (Fig. 1A). The NS3-NS5B proteins support viralgenome replication, which is also dependent upon conserved RNAsequences within the 5'NTR and 3'NTR that are highly structuredand required for both protein translation and RNA replication(15, 20). HCV infection is treated with alpha interferon (IFN- ${alpha}$ )-basedtherapy, but treatment is effective at best in only 50% of patients(10). The nearly unique ability of HCV to establish persistentinfections in humans has been attributed, in part, to a varietyof strategies to evade host immune and IFN-induced defenses(12). Epidemiological studies suggest that 25 to 50% of allpersons resolve acute HCV infection without treatment (16),however, indicating that innate and/or adaptive immune responsesare indeed capable of controlling the outcome of HCV infection.Processes that regulate innate intracellular antiviral responsesmay therefore serve as pivotal points of control, potentiallylimiting host permissiveness for HCV replication and favorablymodulating subsequent adaptive immune responses.

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FIG. 1. The host response and cellular permissiveness to HCV RNA replication. (A) Diagram of the HCV genome (upper) and related replicon (lower). The polyprotein coding region and positions of individual protein products are shown. Arrows indicate positions of the RNA motifs described in the present study, including the IRES within the 5'NTR. (B) Huh7 cells were mock transfected or transfected with the indicated HCV replicon RNA and harvested 3, 8, 12, or 24 h later. ISG, replicon (HCV), and glyceraldehyde-3-phosphate dehydrogenase (GAPDH) transcript abundance was monitored by Northern blot analysis. (C) Huh7 cells were transfected with an IFN-ß promoter-luc construct and 24 h later were mock treated (mock), infected with SenV, or transfected with the indicated RNA. Cells were harvested 20 h after virus infection or 8 h after RNA transfection and then assayed for firefly luciferase activity. Bars show the average values and standard deviation (SD) of firefly luciferase activity relative to a Renilla luciferase control from three experiments (relative luc activity). (D) In the left panel is shown RNA abundance in Huh7 cells that were mock transfected (mock) or transfected with luc-poly(A), HCV 5'NTR-luc, or encephalomyocarditis virus IRES-luc RNA were assessed by Northern blot with probes specific to the indicated ISGs or GAPDH. Cells were harvested at the time shown in hours above each lane, and transfected RNA was detected with a luciferase-specific probe (Luc). For the right panel, cells were mock transfected or transfected with purified L2198S HCV replicon RNA, luc-poly(A), or HCV 5'NTR-luc transcript and then harvested 12 h later. mRNA levels were quantified by real-time PCR. Bars show the average level ± the SD of IFN-ß mRNA relative to GAPDH control from three experiments. (E) HCV RNA replication and cellular G418 resistance transduction efficiency were evaluated after transfection of ${Delta}$ 5B or HP replicon RNAs into Huh7 or Huh7.5 cells. On the left is shown the average fold increase ± the SD of HP replicon RNA relative to ${Delta}$ 5B replicon RNA at the indicated times. The replicon abundance was estimated from the luciferase activity expressed by a firefly luciferase sequence that was inserted in lieu of the Neo sequence in the replicon shown in Fig. 1A. This provides an accurate assessment of HCV RNA abundance (28). On the right, G418-resistant colony-forming efficiency of the indicated HCV replicon RNAs was determined by cell staining 3 weeks after transfection of Huh7 (panels 1 to 3) or Huh7.5 cells (panels 4 to 6) followed by G418 selection. The numbers at the bottom show the fold increase in numbers of Huh7.5 cell colonies compared to Huh7 colonies. The results shown are representative of three independent experiments.

Virus-induced production of IFN- ${alpha}$ and IFN-ß and thesubsequent expression of IFN-stimulated genes (ISGs) are centralto these antiviral defenses (22). This host response is initiatedby cellular recognition of a pathogen-associated molecular pattern(PAMP) presented by the infection, in which a host protein receptoris engaged by the PAMP ligand and signals downstream componentsto activate intracellular immune defenses. In mammalian cells,replicating viral RNAs present features of nucleic acid sequenceor structure that are recognized as distinct PAMPs by membrane-spanningToll-like receptors (TLRs) or intracellular proteins coupledto signaling pathways that induce interferon production. Double-strandedRNA (dsRNA) and GU-rich single-stranded RNA (ssRNA) are recognizedby TLR3 and TLR7/8, respectively (18). However, viral dsRNAcan also initiate cellular responses through an intracellular,TLR3-independent mechanism (5, 32), thereby activating a setof latent transcription factors, including IFN-regulatory factor3 (IRF3) and NF- ${kappa}$ B that coordinately assemble onto the IFN-ßpromoter and induce IFN expression, ISG production and an intracellularantiviral state. Among these, IRF3 is essential for IFN production(21). Its activation occurs through redundant actions of TBK1or IKK ${varepsilon}$ protein kinases, which catalyze its carboxyl-terminalphosphorylation and result in nuclear translocation, DNA binding,and transcription-effector actions (6, 23). The IRF3-mediatedinduction of IFNs and ISGs, initiated by the recognition ofan HCV-specific PAMP, is likely to impose intracellular restrictionsto viral replication that limit host cell permissiveness (7,25). To define how this host response influences HCV infection,we investigated the relationship between innate antiviral responsesand cellular permissiveness for HCV RNA replication in a cellculture model.

MATERIALS AND METHODS

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Materials and Methods

Cell culture and viruses. Huh7.5 cells were a gift from C. Rice. Huh7 and Huh7.5 cells(3) were propagated in Dulbecco modified Eagle medium supplementedwith 10% fetal bovine serum, 200 µM L-glutamine, and Sigmaantibiotic-antimycotic solution. For treatment of cells, mediumwas removed and replaced with medium containing the indicatedconcentration of IFN- ${alpha}$ 2a (PBL Laboratories), anisomycin (Sigma)or interleukin-1 (R&D Systems). Sendai virus (SenV; Cantellstrain) was obtained from Charles River Laboratory. Vesicularstomatitis virus (VSV) was a gift from M. Whitt. Virus infectionof Huh7 or Huh7.5 cells was conducted as previously described(7, 9). For SenV infection, cells were exposed to 100 hemagglutininunits of SenV/ml of culture medium. For VSV infection, cellswere exposed to a multiplicity of infection of 5.

DNA methods. pHCV 1bpt luc, pHCV HP luc, and pHCV ${Delta}$ 5B luc encode variantsof the Con1 HCV 1b subgenomic RNA sequence (15) possessing thefirefly luciferase gene under the control of the HCV 5'NTR/internalribosome entry site (IRES) and were constructed by ligatinga DNA fragment encoding firefly luciferase into the AscI/PmeIsites of the respective pHCV 1bpt, pHCV HP, or pHCV ${Delta}$ 5B constructs(7, 25). Plasmids pHCV 1b K2040 and pHCV 1b L2198S, respectively,encoding the Con1-derived K2040 and L2198S subgenomic HCV RNAreplicons were previously described (25, 31). cDNA was preparedfrom mRNA isolated from Huh7 or Huh7.5 cells. Full-length cDNAproducts encoding IKK ${varepsilon}$ , TBKI, RIP2, TRIF, or RIG-I were amplifiedfrom each by PCR with the specific primer sets shown in TableS1 in the supplemental material. Endotoxin-free plasmid DNAwas prepared by using the endo-free Midiprep kit (Sigma). pCMV-IRF-35D was a gift from J. Hiscott. pIRF-3-EGFP was a gift from A.Garcia-Sastre. pEF Bos (encoding an amino-terminal FLAG epitopetag; vector control), pEF Bos-TBK1, and pEF Bos-IKK ${varepsilon}$ were giftsfrom T. Maniatis. pEF Bos-TRIF was a gift from K. Fitzgerald.The wild-type RIG-I cDNA was cloned into the XbaI/ClaI restrictionsites of pEF Bos to generate pEF Bos-RIG-I. pEF Bos-N-RIG andpEF Bos-C-RIG encode amino acids (aa) 1 to 284 and aa 218 to925 of RIG-I (32). Full-length RIP2 was cloned into the HindIII/EcoRIrestriction sites of pFLAG CMV-2 (Sigma) to yield pFlag RIP2.pEF Bos-RIG-I T55I and pEF Bos N-T55I were created from pEF-Bos-RIG-Iand pEF Bos N-RIG, respectively, by a site-directed mutagenesisstrategy using the QuikChange kit from Stratagene and the mutagenicprimers T55Is (5'-GCCCAATGGAGGCTGCCATACTTTTTCTCAAGTTCC-3') andT55Ia (5'-GGAACTTGAGAAAAAGTATGGCAGCCTCCATTGGGC-3'). pF3-EGFPwas constructed by by ligating a HindIII/XbaI fragment frompEGFP (Clontech) into pF3-Luc (a gift from J. Hiscott). pDsRedwas purchased from Clontech. pSP6 luc poly(A) was constructedby ligating a HindIII/XbaI fragment derived from pGL3-Basic(Promega) and encoding the firefly luciferase gene into pSP6poly(A) (Promega). pCDNA3.1 luc poly(A) was then constructedby ligating a HindIII/EcoRI fragment from pSP6 luc poly(A) intopCDNA3.1 DNA transfections were performed by using Lipofectamine2000 transfection reagent (Invitrogen).

Promoter-reporter luciferase assays were conducted as describedpreviously (7) from 2 x 10⁴ cells transfected with 50 ng ofpIFN-ß-luc, pISG56-luc or pISRE-luc encoding fireflyluciferase and 12.5 ng of pCMV-luc encoding the Renilla luciferasegene (8). Luciferase activity was quantified by using a Bio-Radluminometer.

RNA methods. HCV replicon RNA was transcribed and purified from the respectivelinearized plasmids exactly as described previously (7). RNAwas synthesized from plasmids by using the T7 Megascript kit(Ambion) and the manufacturer's protocol. Luciferase poly(A)RNA was transcribed from pCDNA3.1 luc poly(A). HCV 5'NTR-lucRNA was transcribed from pHCV 1bpt luc. Encephalomyocarditisvirus IRES-luc RNA was transcribed from pIRES luc, which wasconstructed by ligating firefly luciferase into pIRES (Clontech)digested with SmaI. HCV ss1 RNA was transcribed from pCDNA3.1HCV 1bpt NS3/4A (7) linearized with SgrAI. HCV ss2 RNA was transcribedfrom pCDNA3.1 HCV 1bpt NS5A (25). HCV 5'NTR and 3'NTR were transcribeddirectly from the PCR products T7 HCV 5'NTR and T7 HCV 3'NTR,respectively, which were amplified from pHCV 1bpt by using theprimer set (encoding the T7 promoter) T7 HCV 5'NTRs (5'-GTAATACGACTCACTATAGGGCCAGCCCCCTGATGGGGGCGACA-3')and pHCV 1bpt 520a (5'-TGCGTGCAATCCATCTTGTTC-3') and the primerset T7 HCV 3'NTRs (5'-TAATACGACTCACTATAGGGAGATGAAGGTTGGGGTAAACACTC-3')and HCV 3'NTRa (5'-ACATGATCTGCAGAGAGGCCA-3'), respectively.Amplified DNA was purified by agarose gel electrophoresis andextracted from the gel by using a QIAquick kit according tothe manufacturer's protocol (Qiagen). RNA was purified by gelextraction, resuspended in water, and transfected by using theTransmessenger RNA transfection reagent (Qiagen) according tothe manufacturer's protocol.

Northern blot analysis of RNA levels was performed exactly asdescribed previously (7) with the indicated cDNA probes. Real-timePCR analyses were performed as described previously (25) withthe oligonucleotide primer pairs listed in Table S2 in the supplementalmaterial.

For small interfering RNA (siRNA) studies, Huh7 cells were transfectedwith 5 to 20 pmol of control siRNA (Ambion Silencer negativecontrol #1) or the RIG-I si265 oligonucleotides si265s [5'-GAGGUGCAGUAUAUUCAGG(dTdT)-3'])and si265a [5'-CCUGAAUAUACUGCACCUC(dTdT)-3'] by using Lipofectamine2000 (Invitrogen) according to the manufacturer's protocol.

Assessment of replicon RNA transduction efficiency and initial HCV RNA replication. Transduction efficiency for HCV subgenomic RNA replicons inHuh7 and Huh7.5 cell lines was determined exactly as describedpreviously (3). For determination of initial HCV RNA replicationefficiency, 4 x 10⁴ Huh7 or Huh7.5 cells were plated per wellof a 24-well plate. After 24 h the cells were transfected withHCV replicon RNA transcribed from pHCV1b ${Delta}$ NS5B luc or pHCV 1bHP luc. Then, 3 h later the cells were harvested for luciferaseassay to determine relative transfection efficiencies or thecells were replated and cultured in six-well dishes to facilitatethe evaluation of HCV RNA replication defined by luciferaseactivity. With this system the level of HCV RNA replicationdirectly parallels luciferase activity values (28). The datawere expressed as the increase in luciferase activity from cellstransfected with HP luc RNA compared to cells transfected withthe ${Delta}$ NS5B luc RNA control and normalized for transfection efficiencyderived from the initial 3-h time point.

Nucleotide sequence analysis. Plasmids were verified by nucleotide sequence analysis (ABIPrism). For mRNA analysis cDNA was first produced from totalcellular RNA isolated from Huh7 or Huh7.5 cells by using Omniscript(Qiagen) reverse transcriptase and an oligonucleotide dT primer(Ambion). A total of 10% of the reverse transcriptase reactionwas used for PCR (ExTaq; Takara). Amplicons were sequenced directly,and complete mRNA sequences were assembled by using Vector NTIsoftware (Informax).

Protein analysis. Protein kinase assays and IRF3 dimerization analysis were performedexactly as described previously (11, 33). For evaluation ofprotein expression, cell extracts were prepared, and immunoblotanalysis was conducted (7). Antibodies used for immunoblot analysisincluded anti-PKR monoclonal antibody 71/10 (A. Hovanessian),rabbit polyclonal anti-IRF3 (M. David), rabbit polyclonal anti-ISG56(G. Sen), rabbit polyclonal anti-RIG-I (32), rabbit polyclonalanti-VSV (M. Whitt), rabbit polyclonal anti-SenV (I. Julkunen),monoclonal anti-TBK1 (Imgenex), monoclonal anti-IKK ${varepsilon}$ (Imgenex),rabbit polyclonal anti-phospho-Ser51-eIF2 ${alpha}$ (Cell Signaling Technologies),monoclonal anti-eIF2 ${alpha}$ (Research Genetics), rabbit polyclonalanti-phospho-Thr180/Tyr182-P38 (Cell Signaling Technologies),rabbit polyclonal anti-P38 (Cell Signaling Technologies), monoclonalanti-Flag M2 (Sigma), and goat polyclonal anti-actin (SantaCruz). Proteins were detected with a secondary antibody coupledto horseradish peroxidase and were visualized by chemiluminescence.

For immunofluorescence analysis of intracellular protein localization,2 x 10⁴ cells were cultured and treated on chamber slides thenfixed and probed with polyclonal rabbit anti-IRF3 serum or monoclonalanti-Flag serum and fluorescein isothiocyanate-conjugated orrhodamine donkey anti-rabbit secondary antibodies exactly asdescribed previously (7). After antibody staining, the nucleiwere stained with DAPI (4',6'-diamidino-2-phenylindole). Cellswere visualized by fluorescence microscopy by using a ZeissAxiovert digital imaging microscope in the UT Southwestern PathogenImaging Facility.

RNA-binding analysis of RIG-I. For RNA-binding analysis, we used agarose beads (Sigma) conjugatedto poly(C) or poly(I). The beads were washed several times in50 mM Tris (pH 7.0)-200 mM NaCl and then resuspended in 50 mMTris (pH 7.0)-50 mM NaCl. To make poly(I-C)-coated agarose beads,poly(I)-coated beads were resuspended in 2 volumes of 2 mg ofpoly(I) (Sigma)/ml prepared in 50 mM Tris (pH 7.0)-150 mM NaCl.The mixture was then rocked gently overnight at 4°C, collectedby centrifugation at 1,000 x g, washed with 50 mM Tris (pH 7.0)-150mM NaCl, resuspended in the same buffer as a 50% final slurry,and stored at 4°C for use. For poly(C) and poly(I-C) pull-downassays, poly(C)- or poly(I-C)-coated beads were equilibratedin binding buffer (50 mM Tris [pH 7.5], 150 mM NaCl, 1 mM EDTA,1% NP-40) as a 10% slurry and then combined with an equal volumeof whole-cell extract that was prediluted to contain 3 µgof protein. The cell extracts were supplemented with proteaseand phosphatase inhibitors and 25 U of RNase inhibitor/ml. Themixture was incubated with gentle agitation for 1 h at 4°C.For competition experiments, pull-down reactions were supplementedwith 10 to 50 µg of the indicated competitor RNA/ml. Beadswere centrifuged at 1,000 x g, rinsed three times with bindingbuffer, and then resuspended in 3 volumes of 1x sodium dodecylsulfate-polyacrylamide gel electrophoresis sample buffer. Sampleswere incubated at 100°C for 5 min, centrifuged at 13,000x g for 30 s, and loaded immediately onto sodium dodecyl sulfate-polyacrylamidegel electrophoresis gels and processed for immunoblot analysis.

RESULTS

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Results

Structured HCV RNA presents a PAMP that induces antiviral responses. Since HCV replication in cultured cells is insufficient forsupport of molecular virologic studies (20), we constructeda series of subgenomic HCV RNA replicons that encode differentadaptive mutations and replicate autonomously, albeit with differentefficiencies, when introduced into cultured human hepatoma (Huh7)cells (L2198S, HP, and K2040; Fig. 1A). We also studied a replication-defectiveHCV RNA ( ${Delta}$ 5B) with a deletion in the RNA-dependent RNA polymerase.Regardless of its replication properties, each HCV repliconRNA induced expression of ISGs, including ISG6-16, ISG56, andISG15 within 12 h of transfection into Huh7 cells (Fig. 1B).To determine whether structured regions of the HCV genome specificallypresent a dsRNA-like PAMP capable of stimulating this host response,we transfected cells with purified, in vitro-transcribed RNArepresenting the 5'NTR or 3'NTR of HCV. Cells were similarlytransfected with RNAs corresponding to nucleotides 3423 to 3772or nucleotides 6261 to 6702 of HCV, which, unlike the NTRs,do not contain well-documented RNA structures (termed ss1 andss2, respectively; Fig. 1A) (27). Transfection of cells withthe 5'NTR or 3'NTR RNAs induced IFN-ß promoter activity,whereas only minimal increases were seen with the nonstructuredss1 or ss2 HCV (Fig. 1C). To confirm these results, we transfectedHuh7 cells with RNA transcripts encoding firefly luciferase(luc), either with or without an upstream structured viral RNAsegment. Northern blotting revealed that luciferase RNA appendedwith a poly(A) tail and lacking a structured upstream segment[luc-poly(A)] was a poor inducer of ISG expression (Fig. 1D,left panel). In contrast, inclusion of the HCV 5'NTR or thestructured IRES of encephalomyocarditis virus resulted in ISGexpression within 8 h of transfection. Luciferase activity assaysconfirmed efficient transfection of each RNA (data not shown),indicating that the luc sequence or its gene product were notresponsible for ISG induction. The level of induction of IFN-ßpromoter activity by the 5'NTR-luc RNA was comparable to thatinduced by the entire subgenomic L2198S HCV replicon RNA 8 hafter transfection (Fig. 1D, right panel). We conclude thatstructured regions of the HCV RNA, including the 5'NTR and 3'NTRpresent a specific PAMP capable of triggering a host responsecharacterized by IFN-ß and ISG expression.

Lesion(s) in the host response to the HCV RNA PAMP enhance cellular permissiveness to viral RNA replication. Most HCV replicon RNAs containing wild-type sequence replicatepoorly or not at all in Huh7 cells, and efficient replicationrequires specific cell culture-adaptive mutations (1). However,a subline of Huh7 cells, termed Huh7.5, exhibit a marked increasein permissiveness for HCV RNA replication (3). We compared thecapacity of Huh7 and Huh7.5 cells to support replication aftertransfection of an HCV replicon RNA directing expression ofluciferase. Replication of this RNA, as reflected in increasesin luciferase activity relative to that produced by a replication-defectivecontrol RNA, was significantly greater in the Huh7.5 cells.Similarly, we observed a 74- to 128-fold increased efficiencyin selection of G418-resistant cell colonies in the Huh7.5 cellsafter transfection of replicon RNAs expressing the selectableneo marker (Fig. 1E).

We examined dsRNA signaling pathways and the host response tovirus infection and IFN treatment in these cell lines. Bothdemonstrated equivalent activation of protein kinase R (PKR)and p38 mitogen-activated protein after infection with VSV (Fig.S1 in the supplemental material). Thus, these dsRNA signalingpathways are intact in both cell lines. Similarly, IFN treatmentinduced robust expression of ISG56, a well-defined ISG and IRF3target gene (19), in both Huh7 and Huh7.5 cells. However, unlikeHuh7 cells, the Huh7.5 cells failed to induce ISG56 expressionin response to SenV infection or transfection of the HCV 5'NTR-lucRNA (Fig. 2A). Moreover, infection with VSV or Sendai virus(SenV) failed to induce IFN-ß promoter activity inthe Huh7.5 cells but did so in Huh7 cells (Fig. 2B), despitethe fact that the viruses replicated equally well in both celllines (Fig. 2A and Fig. S1C in the supplemental material). Strikingly,transfection of the Huh7 cells with HCV RNA triggered ISG expressionwithin 8 to 12 h, whereas this response was not observed inHuh7.5 cells despite equivalent transfection efficiency (Fig.2C). Similar results were observed when cells were transfectedwith the synthetic dsRNA, poly(I-C) (data not shown). Thus,signaling pathways that confer responsiveness to virus infectionor HCV RNA and that are intact in Huh7 cells are defective inHuh7.5 cells.

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FIG. 2. Cells highly permissive to HCV RNA replication have a defective host response. (A) Huh7 and Huh7.5 cells were mock treated (mock), infected with SenV for 20 h (SenV), treated with 10 or 50 U of IFN- ${alpha}$ 2a/ml for 12 h, or transfected with luc-poly(A) or 5'NTR-luc RNA (HCV) for 8 h. Extracts were subjected to immunoblot analysis for ISG56, SenV, and ß-actin abundance. (B) The activity of a transfected IFN-ß promoter expression constructs was measured in cells that were mock infected or infected with SenV for 24 h or VSV for 10 h. The results shown are the average firefly luciferase activity ± the SD relative to a Renilla luciferase control. (C) Huh7 and Huh7.5 cells were mock transfected or transfected with 5'NTR-luc, L2198S, or HP HCV replicon RNA. Total cellular RNA was collected at 3, 8, or 12 h, and the level of replicon (HCV), 2'-5' oligoadenylate synthetase 1 (OAS1), ISG6-16, ISG56, ISG15, and GAPDH RNA as determined by using specific probes. 5'NTR-luc RNA was monitored by using the Luc probe. (D) Huh7 and Huh7.5 cells were mock treated (mock), infected with SenV for 24 h, or transfected with luc-poly(A) (poly A) or HCV 5'NTR-luc RNA (HCV 5'NTR) for 8 h. Cells were processed and stained with anti-IRF3 rabbit serum and a rhodamine-conjugated secondary antibody (panels 1 to 8). Nuclei were visualized by staining with DAPI (panels 9 to 16). Magnification, x40. The transfection efficiency was monitored by a parallel assessment of luciferase activity; the unit activity values are shown below the corresponding panels. (E) In the left panel, IRF3, ISG56, and actin abundance were evaluated by immunoblot analysis of extracts from untreated Huh7 and Huh7.5 cells or cells treated with 10 U of IFN ${alpha}$ -2a/ml for 12 h (IFN) or transfected with HCV 5'NTR-luc RNA for 0, 4, or 8 h. The line at left denotes the position of the high-mass hyperphosphorylated IRF3 isoforms. On the right, proteins were separated on a nondenaturing gel in order to define the abundance of the inactive IRF3 monomer and the active IRF3 dimer complex (indicated at right) in cells that were mock infected or infected with SenV for 20 h.

The lack of IFN-ß promoter activity and ISG56 expressionin Huh7.5 cells could reflect a lesion in the IRF3 activationpathway. We therefore compared the subcellular distributionof endogenous IRF3 in these cells in response to virus infectionor HCV RNA transfection. In resting Huh7 cells, IRF3 is distributedin a perinuclear and/or cytoplasmic context; it redistributesto the nucleus, a finding consistent with its activated state,after infection with SenV (Fig. 2D) (7). A similar redistributionof IRF3 occurs in Huh7 cells upon transfection with HCV 5'NTR-lucRNA, but not the luc-poly(A) control RNA, demonstrating thatHCV RNA triggers IRF3 activation. In contrast, in Huh7.5 cells,there was no activation of IRF3 by SenV or HCV RNA, since IRF3was retained in the cytoplasm under all conditions (Fig. 2D).In addition, transfection of the 5'NTR-luc RNA triggered accumulationof high-mass hyperphosphorylated, active isoforms of IRF3 within4 h after transfection into Huh7 cells but not into Huh7.5 cells(Fig. 2E, left panel set). A similar difference was observedafter SenV infection (data now shown). Consistent with this,SenV infection induced the formation of active, phosphorylation-dependentIRF3 dimers only in Huh7 cells (Fig. 2E, right panel). Thus,the Huh7.5 cells possess a lesion in essential transducer(s)of IRF3 phosphorylation that normally trigger its activationin response to virus infection or the HCV RNA PAMP.

Characterization of the Huh7.5 defect in IRF3 activation. Further studies indicated that the lack of response in the Huh7.5cells was most likely due to defects in signaling to IRF3 andnot in IRF3 itself, since an ectopically expressed green fluorescentprotein (GFP)-IRF3 protein accumulated in the nucleus of Huh7cells, but not Huh7.5 cells, in response to SenV infection (Fig.S2A in the supplemental material). In addition, the lack ofIRF3 nuclear accumulation in Huh7.5 cells was not due to disruptionof nuclear transport, because the active, phosphomimetic IRF35D mutant was constitutively localized to the nucleus upon expressionin Huh7 or Huh7.5 cells (Fig. S2B in the supplemental material).Ectopic expression of the TLR3 adaptor protein, TRIF (30), inducedIFN-ß promoter activation in both cell types, demonstratingthat under these conditions the endogenous IRF3 kinases wereintact and were themselves competent to signal IRF3-dependentpromoter activation (Fig. S2C in the supplemental material).Consistent with this, there was an equivalent abundance of endogenousTBK1 and IKK ${varepsilon}$ protein (Fig. S2D in the supplemental material)and TRIF mRNA (data not shown) in Huh7 and Huh7.5 cells, andthese proteins were found to signal to IRF3 in a genetic complementationassay (described below). We found no mutations in the sequencesof TBK1, IKK ${varepsilon}$ , and TRIF cDNAs recovered from Huh7.5 cells (datanot shown). Huh7 cells express little, if any, TLR3, and theydo not respond to extracellular pIC (14), indicating that theirresponse to intracellular HCV RNA is TLR3 independent. Together,these data suggest that the lesion in the IRF3 pathway in Huh7.5cells is within a previously undefined intracellular signalingpathway that triggers IRF3 activation, either independent ofor above the level of the TBK1 or IKK ${varepsilon}$ kinases.

RIG-I complements the IRF3 activation defect. To identify a defective upstream signaling component that normallyactivates the IRF3 pathway, we subjected Huh7.5 cells to a geneticcomplementation assay searching for cDNA products capable ofrestoring IRF3 responsiveness to virus infection. Among othercandidate cellular proteins selected because of prior evidencefor roles in innate immune signaling, retinoic acid induciblegene I (i.e., RIG-I) was unique in restoring virus responsivenessto an IRF3-dependent promoter in Huh7.5 cells (Fig. 3A). Recentlyidentified as an intracellular pattern recognition moleculethat signals the downstream activation of IRF3 during virusinfection (32), RIG-I is 925 aa in length and contains an amino-terminalregion possessing tandem motifs with limited homology to thecaspase activation and recruitment domain (CARD) (4) and a downstreamDExD/H-box helicase domain that binds to RNA (Fig. 3B). RIG-Iis a cytosolic protein that is expressed at a low basal level.We found that RIG-I mRNA (Fig. S3 in the supplemental material)and protein in Huh7 and Huh7.5 cells were increased in responseto IFN treatment in a fashion similar to ISG56. In Huh7 cellsthe level of RIG-I and ISG56 also increased in response to SenVinfection, but infection did not signal an increase in RIG-Iexpression in Huh7.5 cells, a finding consistent with an IRF3activation defect (Fig. 3C). Importantly, ectopic expressionof RIG-I led to accumulation of activated IRF3 dimers in Huh7.5cells, restoration of ISG56 expression (Fig. 3D), and IRF3 nucleartranslocation in response to either SenV infection or HCV 5'NTR-lucRNA transfection (Fig. S4 in the supplemental material).

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FIG. 3. RIG-I is an essential transducer of IRF3 activation. (A) Huh7.5 cells were subjected to complementation analysis with cotransfected plasmids encoding the IRF3-dependent F3-EGFP reporter construct and the constitutively expressed dsRed protein with a vector control plasmid or a plasmid from a panel of constructs encoding proteins implicated in antiviral signaling, including IRF3 5D (positive control), RIG-I (32), TBK1, IKK ${varepsilon}$ (6, 23), TRIF (30), and RIP2 (13). At 24 h posttransfection the cells were mock infected (–) or infected with SenV (+). On the left, cells were transfected with RIG-I or control constructs and visualized by direct fluorescence imaging of EGFP and dsRED after mock or SenV infection. A summary of results from this particular analysis is shown on the right; "–" and "+" indicate the absence or presence of EGFP expression. (B) RIG-I structural features. The regions comprising the N-RIG and C-RIG constructs are shown. The RIG-I expression constructs used in the present study contained an amino-terminal FLAG epitope tag fused in frame to the RIG-I coding region. (C) The abundance of SenV proteins, endogenous RIG-I, ISG56, and ß-actin was determined by immunoblot analysis of Huh7 and Huh7.5 cells that were mock treated, treated with 10 U of IFN- ${alpha}$ 2a/ml, or infected with SenV for 20 h. (D) On the left, IRF3 dimer and monomer abundance in nontransfected Huh7 cells or Huh7.5 cells transfected with either empty vector or a vector expressing RIG-I. Cells were mock treated, infected with SenV for 20 h, or transfected with HCV 5'NTR-luc RNA for 4 or 8 h prior to harvest and electrophoresis of extracts through a nondenaturing gel. The positions of the IRF3 monomer and dimer complex are indicated. On the right is shown ISG56, SenV, ectopically expressed RIG-I, and ß-actin abundance in extracts from Huh7.5 cells transfected with empty vector or vector encoding RIG-I. At 24 h after transfection, cells were mock treated, infected with SenV for 20 h, or transfected with HCV 5'NTR-luc for 0, 6, 9, or 12 h prior to harvesting for immunoblot analysis. Ectopically expressed RIG-I was detected by using anti-FLAG M2 antibody. (E and F) Huh7 cells transfected with IFN-ß-luc or ISG56-luc promoter expression constructs were transfected with a control siRNA (control) or a specific siRNA directed to the first exon of RIG-I (RIG-I si265), after which cells were mock infected or infected with SenV for 20 h, followed by quantification of relative luc activity. Bars show the average ± the SD values from triplicate experiments. In panel E, the left panel shows cells transfected with increasing amounts of RIG-I si265 siRNA. The right panel set shows endogenous RIG-I, ISG56, and actin protein abundance in extracts of mock-infected (–) or SenV-infected (+) cells transfected with control or RIG-I si265 siRNA.

To confirm that RIG-I signals IRF3 activation, we demonstratedthat siRNA silencing of RIG-I suppressed SenV induction of IFN-ßpromoter activity in Huh7 cells. Suppression was dose dependent,not observed with a control siRNA (Fig. 3E), and associatedwith a block in SenV induction of ISG56 (Fig. 3F). We concludefrom these results that RIG-I is essential for triggering IRF3activation and ISG expression in response to virus infectionor the HCV RNA PAMP in human hepatocytes and that RIG-I complementsthe IRF3 signaling defect in Huh7.5 cells, restoring responsivenessto the IRF3 pathway.

Unique domains of RIG-I bind HCV RNA and direct signaling to IRF3 in hepatocytes. To determine which domains of RIG-1 confer host cell responsivenessto the viral PAMPs, we assessed the ability of the amino-terminalCARD homology domain and the carboxyl-terminal helicase domain(see Fig. 3B) to signal IFN-ß promoter activity inresponse to SenV infection. When expressed in Huh7 cells, theCARD-homology domain (N-RIG) constitutively activated the IRF3pathway, whereas expression of the carboxyl-terminal helicasedomain (C-RIG) resulted in dominant-negative inhibition of virus-inducedIRF3 activation (Fig. S5 in the supplemental material). Thisfinding is consistent with those of another recent study (32).We verified that the helicase function of RIG-I is essentialfor IRF3 signaling, since RIG-I with a mutation (K270A) thatdisrupts the conserved Walker-A motif and eliminates helicaseactivity (32) failed to restore SenV or HCV RNA activation ofIRF3 in Huh7.5 cells (R. Sumpter and M. Gale, Jr., unpublishedobservations). These results provide evidence that the CARD-homologydomain of RIG-I mediates RNA signaling to the IRF3 pathway inhuman hepatocytes and indicate a regulatory role for the helicasedomain in this process.

RNA-binding activity maps to the helicase domain of RIG-I (32).We demonstrated that ectopically expressed RIG-I was recoveredfrom cell extracts in a pIC-agarose pull-down assay (Fig. 4A),a finding consistent with a role for dsRNA binding in RIG-Isignaling. The specificity of this assay for dsRNA binding proteinswas confirmed by the recovery of endogenous PKR, a known dsRNAbinding protein (12), but not endogenous actin. RIG-I dsRNAbinding activity was specifically competed for by the additionof increasing concentrations of soluble pIC and HCV 5'NTR or3'NTR RNAs but not by the unstructured ss2 RNA (Fig. 4B). Thus,RIG-I is a dsRNA binding protein that recognizes and binds RNAPAMP(s) residing within structured regions of the HCV genome.

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FIG. 4. Characterization of RIG-I function. (A) Extracts from Huh7 cells that were transfected with empty vector or a vector expressing RIG-I were mixed with pIC-coupled agarose beads. The input proteins and those recovered as pull-down products (PD) were evaluated by immunoblot analysis with anti-FLAG (to detect plasmid-encoded RIG-I), anti-PKR, or anti-ß-actin antibodies. (B) Extracts from Huh7 cells transfected with the RIG-I expression vector were mixed with pIC-coupled agarose beads, and the binding reactions were supplemented with 10 or 50 µg of soluble pIC, HCV ss1, 5'NTR, or 3'NTR RNA/ml. Input proteins and pull-down products (PD) were evaluated by immunoblot analysis with anti-FLAG and anti-ß-actin antibodies. Competitive inhibition of pIC binding to RIG-I was quantified by densitometry and expressed as the percentage of the initial RIG-I pull-down signal remaining in each respective lane. (C) Comparison of the nucleotide sequences of RIG-I mRNA present in Huh7 and Huh7.5 cells demonstrates a C-to-T substitution at nucleotide position 164 in the RIG-I ORF in Huh7.5 cells. This changes codon 55 from threonine to isoleucine (T55I) as shown in the structural diagram. (D) In the left panel, Huh7 cells were cotransfected with IFN-ß-luc expression plasmid and 50 ng of vector only (vector) or IFN-ß-luc expression plasmid with (from left to right) increasing amounts (25, 50, and 100 ng) of expression vector encoding RIG-I, the full-length T55I mutant (T55I), N-RIG, N-RIG containing the T55I mutation (N-T55I), or full-length T55I mutant with 50 ng of RIG-I expression vector (T55I + RIG-I). Cells were mock infected or infected with SenV for 20 h, harvested, and subjected to luciferase assay. Bars show the average value ± the SD of each relative luciferase activity. In the right panel, Huh7.5 cells were transfected with vector control or plasmids encoding IRF3-5D (control), RIG-I, N-RIG, full-length T55I mutant (T55I), or N-T55I. After 24 h cells were mock infected (–) or infected with SenV (+) for 20 h and then harvested, and extracts were subjected to immunoblot analysis for ISG56, SenV, RIG-I, N-RIG, N-T55I, and ß-actin. RIG-I proteins were detected with anti-FLAG antibody. (E) Huh7 cells were transfected with empty vector or vectors encoding RIG-I, C-RIG, or the full-length T55I mutant (T55I). Cells were harvested at 24 h, and extracts were mixed with agarose beads coupled to poly(C) or pIC. Proteins in the pull-down fraction (PD) and input were subjected to immunoblot analysis. RIG-I proteins were detected as in panel B.

RIG-I is defective in cells highly permissive for HCV RNA replication. The distinct domain features of RIG-I indicate that mutationsin either domain could potentially confer defects in dsRNA signalingto IRF3 during virus infection. To determine whether this couldexplain the phenotype of Huh7.5 cells, we sequenced the RIG-IcDNA derived from mRNA isolated from Huh7 and Huh7.5 cells.We found a single nucleotide substitution that rendered an aminoacid change at codon 55 (T55I) in the RIG-I ORF and locatedwithin the first CARD-homology domain of a single sequence thatwas repeatedly recovered from Huh7.5 cells (Fig. 4C). When introducedinto wild-type RIG-I, the T55I mutation caused a loss of signalingto IRF3. In an IFN-ß promoter assay, ectopic expressionof the T55I mutant had a dominant-negative effect upon endogenousRIG-I signaling in Huh7 cells, causing a reduction in promoteractivity triggered by SenV infection (Fig. 4D, left panel).When introduced into a construct expressing only the amino-terminalCARD-homology domain, the T55I mutation resulted in a loss ofconstitutive activation of the IRF3-dependent IFN-ßpromoter (Fig. 4D). However, the dominant-negative activityof T55I required its expression as the full-length protein,because the endogenous response to SenV infection remained intactin cells expressing N-RIG T55I. Immunoblot analysis demonstratedthat the T55I mutation disrupted RIG-dependent SenV-inducedISG56 expression in Huh7.5 cells (Fig. 4D, right panel set).

The T55I mutation had no effect upon the ability of RIG-I tobind dsRNA, since the RIG-I carboxyl-terminal helicase domain(C-RIG; aa 218 to 925) was sufficient for dsRNA binding (Fig.4E). These experiments further confirmed the specificity ofRIG-I interaction with dsRNA, since there was no binding tosingle-stranded poly(C)-agarose beads. Thus, the loss of functioncaused by the T55I mutation is due to disruption of one or moresignaling events directed by the CARD-homology domain and notto alteration of the RNA binding activity of the protein.

RIG-I regulates permissiveness to HCV RNA replication in Huh7.5 cells. To define the role of RIG-I in cellular permissiveness to HCVRNA replication, we measured HCV RNA replicon amplificationover a 120-h time course in Huh7.5 cells transfected eitherwith an empty vector or one expressing RIG-I in the absenceof G418 selection and using the replicon-encoded luciferaseexpression as a read out of HCV RNA levels. This approach alloweda direct assessment of the influence of RIG-I upon viral RNAreplication over a short time course, without confounding effectsdue to the selection of cell culture-adaptive mutations in thereplicon RNA (1, 28). As expected, transfection of HCV repliconRNA induced a host response leading to ISG56 expression in Huh7cells, but not in Huh7.5 cells (Fig. 5A). The ectopic expressionof RIG-I complemented the defect in Huh7.5 cells, restoringISG56 expression after transfection of replicon RNA. RIG-I expressionwas maintained in the transfected Huh7.5 cells throughout anextended 144-h time course (Fig. 5B, upper and lower panel sets,respectively). To assess viral RNA replication in Huh7.5 cellscomplemented with ectopic RIG-I, we compared the activity ofthe luciferase protein encoded by replication-competent (HP)versus replication-defective ( ${Delta}$ 5B) replicon RNA in cells in parallelas a direct marker of HCV RNA abundance. As shown in Fig. 5C,the HP replicon levels remained low and did not amplify beyondan approximately twofold increase in Huh7.5 cells expressingthe functional RIG-I, whereas in those transfected with theempty vector, the HP RNA-encoded luciferase was continuouslyamplified over the same 120-h time course. At the end of thisperiod the HP replicon had amplified by >13-fold over thelevel of the ${Delta}$ 5B replication-defective control RNA. Thus, RIG-Icomplementation of IRF3 signaling and restoration of the hostresponse in Huh7.5 cells results in a phenotypic switch fromhyperpermissiveness for HCV RNA replication to a relativelynonpermissive phenotype characterized by recognition of HCVRNA and suppression of viral RNA amplification.

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FIG. 5. Effect of RIG-I on cellular permissiveness for HCV RNA replication. (A) Huh7 and Huh7.5 cells were mock transfected or transfected with ${Delta}$ 5B or HP HCV replicon RNA. After 24 h, the cells were harvested and extracts were subjected to immunoblot for ISG56 and ß-actin. (B) Huh7.5 cells were transfected with vector alone or a vector encoding RIG-I. In the upper panel the cells were secondarily transfected, 24 h later, with ${Delta}$ 5B or the HP replicon RNA. After 24 h, cells were harvested, and extracts were subjected to immunoblot analysis for ß-actin, ISG56, and the ectopically expressed RIG-I protein. The lower panel shows an immunoblot analysis of ß-actin and ectopic RIG-I protein abundance over a 144-h time course posttransfection. (C) Huh7.5 cells were transfected with empty vector (vector) or vector expressing RIG-I. At 24 h, parallel cultures were secondarily transfected with ${Delta}$ 5B or HP HCV replicon RNA containing the firefly luciferase sequence in lieu of Neo, as described in the legend for Fig. 1E. The level of HCV replicon-encoded luciferase activity was measured as a specific marker of HCV RNA abundance (28). The bars show the average fold increase in luciferase expression ± the SD compared to that expressed by the replication-defective ${Delta}$ 5B replicon control. (D) Model of viral RNA binding and IRF3 signaling by RIG-I. Details are given in the text.

DISCUSSION

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Discussion

RIG-I is a signal transducer and HCV RNA PAMP receptor. Our results define the cellular RNA helicase, RIG-I, as a transducerof signals that activate innate antiviral defenses limitingHCV RNA replication. In cultured hepatocytes, RIG-I plays anessential role as a TLR-independent PAMP receptor that specificallybinds dsRNA and structured regions within the HCV genome tosignal IRF3 activation, IFN production, and ISG expression.This response is an important component of the acute hepaticantiviral defenses that are triggered in vivo within days ofexposure to HCV (2) and is therefore likely to contribute tothe resolution of acute infection (26). Our data also demonstratethat RIG-I is essential for triggering IRF3 activation in responseto SenV or VSV infection in hepatocytes (Fig. 2B and 3E), afinding consistent with its role as a viral PAMP receptor. Wespeculate that secondary or tertiary RNA structures, often presentin viral RNAs (24), present a specific PAMP that is engagedby RIG-I. RIG-I specifically bound the structured 5'NTR and3'NTR segments of the HCV genome but not the predicted nonstructuredviral RNAs (Fig. 4B and E). The RIG-I-based cellular responseexploits the need for HCV to conserve unique structured terminalRNA segments that are essential to viral replication. This interactionsignals the induction of IRF3 responsive genes and other ISGs,including ISG56, that have been shown to suppress HCV RNA replication(7, 29). The binding of RIG-I to viral RNA thus induces criticalantiviral effectors impacting cellular permissiveness for HCVthrough processes that limit viral RNA replication.

CARD signaling activates downstream IRF3. CARD-containing proteins mediate signaling events in responseto a variety of intracellular and extracellular pathogen-relatedstimuli that direct NF- ${kappa}$ B activation via TLR-independent mechanisms(4). RIG-I and other CARD-containing DExD/H box helicase proteinsthus appear to represent a family of proteins that activatea TLR3-independent response against a variety of viral pathogens(32). The RIG-I CARD-homology domain is capable of inducingIRF3 activation. Sequence differences, which distinguish theRIG-I homolog from other CARD proteins (4, 32), may providefor recruitment of unique signaling components that activateIRF3 through processes that depart from the canonical CARD-CARDhomotypic interaction pathways. The kinase TBK1, which doesnot contain a CARD, is essential for dsRNA or virus-inducedIRF3 activation (17), suggesting that it is required for RIGsignaling to IRF3. TBK1 does not directly associate with RIG-I(E. Foy and M. Gale, Jr., unpublished observations). The mostlikely scenario for RIG-I-mediated IRF3 activation involvesinteraction with downstream adaptor(s) or CARD-containing proteinsthat ultimately results in TBK1/IRF3 activation. In this regard,the location of the T55I mutation in the first CARD domain ofthe Huh7.5 RIG-I mutant is of particular interest. It uncoupledsignal transduction from viral RNA binding. Huh7.5 cells arederived from and are isogenic to Huh7 cells (3). Among otherpotential lesions in antiviral processes within Huh7-derivedcells, the hyperpermissive phenotype of Huh7.5 cells can beattributed to the RIG-I T55I mutation that abolishes PAMP signalingto IRF3. The IRF3 response contributes to control of HCV RNAreplication (7). Thus, activation of IRF3 is a critical determinantof cellular permissiveness for HCV RNA replication, althoughdefects in other, RIG-I-independent innate antiviral defensepathways could contribute to the overall level of cellular permissivenessfor HCV.

A new model for virus activation of IFN- ${alpha}$ /ß and ISGs. We propose a model in which within the infected hepatocyte RIG-Ibinding to the HCV RNA PAMP induces events that are regulatedby its helicase domain and alter its conformation sufficientlyto recruit or interact with signaling partners that direct thedownstream phosphorylation of IRF3 and expression of antiviraleffector genes (Fig. 5D). This response is likely to be triggeredby the HCV RNA PAMP immediately upon introduction of the viralgenome into the host cell cytoplasm (see Fig. 5A). Moreover,recently published observations demonstrate that HCV RNA replicationcan trigger IRF3 activation (25), implying that RIG-I engagesHCV during the process of viral replication. Since RIG-I isstrongly IFN inducible (Fig. S3 in the supplemental material),one of the effects of IFN therapy is an enhanced sensing ofvirus replication, which initiates a cascade of antiviral events.The importance of the RIG-I pathway for cellular permissivenessto viral replication is underscored by the variety of ways thatviruses antagonize downstream IRF3 actions (12). Indeed, HCVhas the potential to block virus triggering of IRF3 phosphorylationthrough the actions of its NS3/4A serine protease (7). The resultsfrom recent work now indicate that this regulation is attributedto blockade of RIG-I-dependent signaling imposed by the proteasefunction of NS3/4A (7a), and it is likely that upon its accumulationNS3/4A antagonizes RIG-I signaling in the infected cell. Therapeuticapproaches to control RIG-I and NS3/4A function may providenovel strategies to limit HCV infection by modulating cellularpermissiveness for virus replication.

ACKNOWLEDGMENTS

This study was supported by NIH grants AI48235 and AI060389(M.G.), U19-AI40035 (S.M.L.), T32-GM08203 (R.S.), and T32 AI07520 (E.F.); a Burroughs Wellcome Fund Investigator in Pathogenesisof Infectious Disease award (M.G.); the Ellison Medical FoundationNew Scholars in Global Infectious Disease Research program (ID-NS-0032;M.G.); and a gift from Mr. and Mrs. R. Batcheldor. K.L. is theJohn Mitchell Hemophilia of Georgia Liver Scholar of the AmericanLiver Foundation. M.G. is the Nancy C. and Jeffrey A. MarcusScholar in Medical Research in Honor of Bill S. Vowell.

FOOTNOTES

* Corresponding author. Mailing address: Department of Microbiology, University of Texas Southwestern Medical Center, 5323 Harry Hines Blvd., Dallas, TX 75390-9048. Phone: (214) 648-5940. Fax: (214) 648-5905. E-mail: michael.gale{at}UTSouthwestern.edu.

Supplemental material for this article may be found at http://jvi.asm.org/.

REFERENCES

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