Hepatitis C Virus Core Protein Induces an Anergic State Characterized by Decreased Interleukin-2 Production and Perturbation of Mitogen-Activated Protein Kinase Responses

Alterations of cytokine responses are thought to favor the establishmentof persistent hepatitis C virus (HCV) infections, enhancingthe risk of liver cirrhosis and hepatocellular carcinoma. Herewe demonstrate that the expression of the HCV core (C) proteinin stably transfected T cells correlates with a selective reductionof interleukin-2 (IL-2) promoter activity and IL-2 productionin response to T-cell receptor triggering, whereas the activationof IL-4, IL-10, gamma interferon, and tumor necrosis factoralpha was moderately increased. This altered cytokine expressionprofile was associated with a perturbation of mitogen-activatedprotein (MAP) kinase responses. Extracellular regulated kinaseand p38 were constitutively phosphorylated in C-expressing cells,while triggering of the costimulatory c-Jun N-terminal kinase(JNK) signaling cascade and activation of the CD28 responseelement within the IL-2 promoter appeared to be impaired. Theperturbations of MAP kinase phosphorylation could be eliminatedby cyclosporine A-mediated inhibition of nuclear factor of activatedT cells, suggesting that the inactivation of JNK signaling andhyporesponsiveness to IL-2 induction were downstream consequencesof C-induced Ca²⁺ flux in a manner that mimics the inductionof clonal anergy.

INTRODUCTION

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Introduction

Hepatitis C virus (HCV), a positive-strand RNA virus belongingto the Flaviviridae family, is estimated to infect approximately170 million people worldwide. Only a fraction of acute HCV infectionsresolve within a few months. In the majority of cases, the virusestablishes persistent infections, a significant proportionof which progress to fibrosis, cirrhosis, liver failure, orhepatocellular carcinoma (reviewed in reference 35). Althougha primary HCV infection often elicits a humoral immune responsethat modulates the acute infection, antibodies are not detectedin many patients or appear late (47). Furthermore, the presenceof isolate-specific antibodies against virus glycoproteins doesnot correlate with virus clearance (4), and their absence inHCV-infected agammaglobulinemic children does not increase therisk of virus persistence (7, 12), suggesting that the humoralresponse is neither sufficient nor required for the resolutionof HCV infection. In contrast, there is compelling evidencefor a role of cell-mediated immunity in the outcome of primaryHCV infection. HCV clearance is associated with a vigorous andsustained cellular immune response against multiple viral epitopes,whereas individuals with chronic infections often have a relativelyweaker and narrower cytotoxic T-lymphocyte (CTL) response (11,14, 19, 29, 42, 54, 72, 80). Furthermore, HCV-specific CD8⁺T cells detected during chronic infections often express a dysfunctionalphenotype characterized by a low expression level of gamma interferon(IFN- ${gamma}$ ) (2, 33), while CD4⁺ T cells display a Th2 phenotype characterizedby low IFN- ${gamma}$ and interleukin (IL-2) and high IL-4 and IL-10 production(23, 81, 83, 86).

The modulation of T-cell responses is the hallmark of many persistentinfections and is often associated with the expression of specificviral products. The HCV genome is translated into a polyproteinof about 3,000 amino acids that is cleaved by cellular and viralproteases into three structural proteins and at least six nonstructuralproteins (45). Three HCV gene products have been suggested tohave immunomodulatory functions. The structural protein E2 (78)and the nonstructural protein NS5A (27, 28) modulate interferonresponses by interacting with the interferon-inducible, double-strandedRNA-dependent protein kinase R (PKR). In addition, the HCV core(C) protein binds to certain members of the tumor necrosis factor(TNF) receptor superfamily and modulates TNF- ${alpha}$ responses in somecell types (63). Furthermore, in vitro (8, 9, 15, 55, 71, 76)and some in vivo (43, 57, 58, 76) studies have indicated thatHCV may replicate in B and T lymphocytes, suggesting that theactivity of immunocompetent cells may be directly influencedby virus infection. In line with this possibility, we have previouslyshown that the expression of HCV C affects intracellular signalingthat is essential for the activation of the IL-2 promoter inT cells (5).

The synthesis of IL-2 is tightly regulated at the transcriptionallevel and requires simultaneous triggering of the T-cell receptor(TCR) complex and the coreceptor CD28 (59). Triggering of theTCR causes the activation of a complex array of proximal signals,resulting in Ca²⁺ oscillations and protein kinase C (PKC)/p21^ras-mediatedactivation of two mitogen-activated protein (MAP) kinases, extracellularregulated kinase (ERK) and p38. The costimulatory pathway, inducedby simultaneous triggering of the TCR and CD28, includes theactivation of NF- ${kappa}$ B and a third MAP kinase pathway comprisingthe c-Jun N-terminal kinase (JNK). We have recently reportedthat the expression of HCV C in human T cells promotes the leakageof Ca²⁺ from intracellular stores and causes Ca²⁺ oscillationsthat favor the activation of nuclear factor of activated T cell(NFAT)-regulated promoters (6). We have now studied the effectsof HCV C expression on cytokine synthesis. We demonstrate herethat the stable expression of HCV C in T cells induces an anergicstate characterized by a decreased IL-2 response and impairedactivation of the JNK signaling pathway.

MATERIALS AND METHODS

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Materials and Methods

Chemicals and immunological reagents. All chemicals used were of analytical grade. Restriction endonucleases,T4 DNA polymerase, Taq polymerase, and T4 DNA ligase were obtainedfrom MBI Fermentas (Vilnius, Lithuania). Ionomycin, 12-O-tetradecanoylphorbol13-acetate (TPA), cyclosporine A, and puromycin were purchasedfrom Sigma-Aldrich Corp. (St. Louis, Mo.). The anti-CD3 antibody(Ab) HIT3a and the phycoerythrin-labeled anti-IL-2 Ab MQ1-17H12were obtained from Pharmingen (San Diego, Calif.). Horseradishperoxidase- and phycoerythrin-linked anti-immunoglobulins wereobtained from Dako A/S (Glostrup, Denmark). Beetle luciferinwas purchased from Promega Corp. (Madison, Wis.). The monoclonalAb (MAb) C7-50 (56), which recognizes HCV C, was a gift fromJack Wands (Harvard Medical School, Boston, Mass.). Antibodiesto I ${kappa}$ B- ${alpha}$ and the phosphorylated forms of SEK1, JNK1/2, ERK1/2,p38, and c-Jun were purchased from Cell Signaling (Beverly,Mass.). The MAb 9.3 recognizing CD28 was a gift from Bristol-MyersSquibb Pharmaceutical Research Institute (Seattle, Wash.).

Cells, cell culture, and plasmids. The human T-lymphoma Jurkat cell line, subclone E6-1, and itsHCV C-expressing derivatives JHC.d, JHC.g, and JHC.h (6) werecultured in RPMI 1640 supplemented with 10% fetal calf serum.For production of the pGL2-IL-2-luc plasmid, a PCR-amplifiedfragment corresponding to positions –393 to +3 of theIL-2 promoter (the primers for amplification were 5'-ACTCTTGCTCTTGTTCAC-3'and 5'-TGATAGGGAACTCTTGAA-3') was ligated into the pATg vectorby use of a LigATor kit (R&D Systems Europe Ltd). The IL-2fragment was then transferred to the KpnI and HindIII sitesof pGL2-Basic (Promega Corp.) containing the firefly luciferasegene. The following reporter plasmids were used: NFAT-luc, containingthe luciferase gene driven by three copies of the NFAT-responsiveelement (positions –286 to –257 of the human IL-2gene) linked to the human IL-2 promoter (–72 to +47) (61);IL-4-luc, containing nucleotides –741 to +60 of the murineIL-4 enhancer-promoter cloned upstream of the luciferase genein pBS-LUC (77); IL-10-luc, containing nucleotides –890to +120 of the human IL-10 gene cloned into the basic luciferasereporter plasmid pGL3B (49); TNF- ${alpha}$ -luc, containing a 1,311-nucleotideintervening sequence between the human TNF-ß and TNF- ${alpha}$ genes cloned into the luciferase plasmid pXPT2 (64); IFN- ${gamma}$ -lacZ,containing nucleotides –538 to +64 of the human IFN- ${gamma}$ genecloned upstream of the lacZ gene in pEQ3 (62); and RE/AP-luc,containing four CD28 response element/AP1 sites (positions –168to –143 of the human IL-2 gene) driving luciferase expression(70). The plasmid p-v-Jun carries the entire human v-jun genedriven by the cytomegalovirus immediate early promoter (3).

Analysis of cytokine gene expression. Jurkat cells and derivatives thereof were transfected by theDEAE-dextran procedure as previously described (5). The cellswere divided into aliquots at 40 h posttransfection and thenstimulated with 50 ng of TPA/ml and 1 µM ionomycin ora 1:5,000 dilution of the 9.3 MAb recognizing CD28. Seven hourslater, the cells were washed once in phosphate-buffered saline(PBS) and lysed in a buffer containing 25 mM Tris-phosphate(pH 7.8), 2 mM 1,4-dithiothreitol (DTT), 10% glycerol, and 1%Triton X-100. Luciferase and ß-galactosidase activitieswere measured with a Sirius luminometer from Berthold DetectionSystems (Pforzheim, Germany) by the use of beetle luciferinfrom Promega and a Galacto-Star kit from Tropix (Bedford, Mass.),respectively. Statistical significances were determined by Student'stwo-tailed t test.

Protein expression, degradation, and phosphorylation. For protein degradation and phosphorylation assays, cell cultureswere treated for 20 min at 37°C with TPA (50 ng/ml) andionomycin (1 µM) or mouse ascites of 9.3 (diluted 1:2,500).Cellular extracts were prepared by solubilization in sodiumdodecyl sulfate (SDS) sample buffer (65 mM Tris [pH 6.8], 2%SDS, 10% glycerol, 5% mercaptoethanol, and 1% bromphenol blue).Proteins were resolved by electrophoresis in an SDS-12% polyacrylamidegel and were then transferred to a nitrocellulose membrane (Schleicher& Schuell, Dassel, Germany). HCV C was recognized by MAbC7-50 (mouse ascites diluted 1:5,000) (56). The degradationof I ${kappa}$ B- ${alpha}$ was determined by quantitation of the remaining I ${kappa}$ B- ${alpha}$ bythe use of specific antibodies in an immunoblot assay. The phosphorylationof ERK1/2, p38, SEK1, and JNK1/2 was analyzed by immunoblottingwith phosphospecific antibodies to the respective antigens.Bound secondary Ab was detected by enhanced chemiluminescence(Pierce, Rockford, Ill.).

Flow cytometry. The expression of CD3 and CD28 was investigated by flow cytometrywith a phycoerythrin-conjugated anti-CD3 Ab (BD Biosciences,San Jose, Calif.) and a 1:300 dilution of 9.3 mouse ascites,respectively. A fluorescein isothiocyanate-conjugated anti-mouseAb was used as a secondary Ab for CD28 staining. As a negativecontrol, an equal mix of Simultest control ${gamma}$ ₁/ ${gamma}$ _2a and Simultestcontrol ${gamma}$ _2a/ ${gamma}$ ₁ was used. For flow cytometry analyses of IL-2 expression,0.5 x 10⁶ cells were stimulated with either TPA (10 ng/ml) andionomycin (1 µM) or monoclonal antibodies to the TCR andCD28 (HIT3a [0.8 µg/ml] and mouse ascites of 9.3 [diluted1:5,000], respectively) for 6 h in the presence of 2 µMmonensin. Washed cells were fixed in the presence of 4% paraformaldehydeand permeabilized in PBS containing 1% fetal calf serum, 0.1%NaN₃, and 0.1% saponin. The cells were then stained in the samebuffer with 3 µg of R-phycoerythrin-conjugated rat anti-humanIL-2 MAb MQ1-17H12/ml. Stained cells were analyzed on a FACScanflow cytometer (BD Biosciences), and data analysis was performedwith CellQuest software.

Electrophoretic mobility shift assay. Cell cultures were stimulated with TPA (50 ng/ml) and ionomycin(1 µM). After 4 h, nuclei were isolated by disruptionof the cells with a low-salt buffer followed by centrifugation.The cells were washed in PBS and lysed in a buffer containing10 mM HEPES (pH 7.4), 10 mM KCl, 1.5 mM MgCl₂, 0.5 mM DTT, 0.2mM phenylmethylsulfonyl fluoride, 10 µg of leupeptin/ml,and 0.025% NP-40. The nuclei were pelleted, and nuclear proteinswere extracted with a buffer containing 20 mM HEPES (pH 7.4),420 mM NaCl, 1.5 mM MgCl₂, 0.5 mM DTT, 0.2 mM EDTA, 0.2 mM phenylmethylsulfonylfluoride, 10 µg of leupeptin/ml, and 5% glycerol. Nuclearextracts equivalent to 5 µg of bovine serum albumin wereincubated together with 0.2 ng of the ³²P-labeled, double-strandedmonomer of the murine IL-2 distal NFAT binding site (5'-GATCGCCCAAAGAGGAAAATTTGTTTCATACAG-3')(38) in a buffer containing 10 mM Tris-Cl (pH 7.5), 50 mM NaCl,1 mM DTT, 0.5 mM EDTA, 5% glycerol, and 1 µg of poly(dI-dC)/ml.After 30 min at 25°C, the reaction mixture was resolvedin a 5% nondenaturing polyacrylamide gel, and the protein-DNAcomplexes were visualized by autoradiography.

ELISA. Cells were stimulated for 24 h with either TPA (50 ng/ml) andionomycin (1 µM) or monoclonal antibodies to the TCR andCD28 (HIT3a [100 ng/ml] and mouse ascites of 9.3 [diluted 1:5,000],respectively). The IL-2 concentrations in supernatants fromapproximately 200,000 cells were determined by use of a humanIL-2 Opt EIA ELISA kit (Pharmingen) according to the manufacturer'sinstructions.

RESULTS

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Results

Altered cytokine gene expression and protein production in HCV C-expressing cells. We have previously shown that the expression of HCV C inducesCa²⁺ oscillations in Jurkat cells and favors the selective activationof NFAT (5, 6). To investigate this phenomenon further, we investigatedcytokine promoter activity and protein production in parentalJurkat cells and in three stable HCV C-expressing sublines,namely, JHC.d, JHC.g, and JHC.h (Fig. 1A). Physiologic inductionwas mimicked by ligation of the TCR complex and CD28 with specificAbs. The concentration of secreted IL-2 in tissue culture supernatantswas determined after 24 h by ELISA. Supernatants from controlJurkat cells contained approximately 1.3 ng of IL-2/ml, whilesignificantly less IL-2 (0.3 to 0.5 ng/ml) was detected in supernatantsfrom HCV C-expressing cell lines (Fig. 1B). This decreased inducibilitywas not a consequence of a reduced expression of critical surfacereceptors, since HCV C-expressing cell lines analyzed by flowcytometry were indistinguishable from parental cells with respectto the expression of CD3 and CD28 (data not shown).

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FIG. 1. Decreased IL-2 production in HCV C-expressing cells. (A) The expression of HCV C was investigated in parental Jurkat cells (Jk) and C-transfected sublines (JHC.d, JHC.g, and JHC.h) by Western blotting. The position of the molecular size marker (in kilodaltons) is indicated. (B) IL-2 synthesis was induced by triggering of surface receptors with specific antibodies (anti-CD3 and anti-CD28, left panel) or by treatment with TPA and ionomycin (right panel). The amounts of IL-2 in cell culture supernatants were determined by an ELISA at 24 h postinduction. (C) Numbers of IL-2-secreting cells were determined by flow cytometry. Cell lines were stimulated with TPA and ionomycin in the presence of monensin. After 6 h, the cells were fixed, permeabilized, and stained with a phycoerythrin-labeled Ab recognizing human IL-2. (D) Transcriptional activation of IL-2 gene in cells expressing HCV C. Control and C-expressing cell lines were transfected with a luciferase reporter plasmid driven by the IL-2 promoter. At 40 h posttransfection, the cells were stimulated with TPA and ionomycin for 6 h, and the luciferase activity, presented in relative light units (RLU), was determined. The data presented are representative of three independent experiments.

The triggering of CD3 and CD28 initiates a complex signalingcascade including protein tyrosine phosphorylation and inositolphospholipid turnover that can be mimicked by stimulation withTPA and ionomycin, which act as a PKC activator and a Ca²⁺ ionophore,respectively. Although pharmacological triggering was a morepotent inducer of IL-2 in Jurkat cells (30 ng/ml) than the triggeringof surface receptors, C-expressing cells were also less (<3ng/ml) responsive to this treatment (Fig. 1B). To investigatewhether this deficiency was due to an impaired secretion ofIL-2, we detected intracellular IL-2 in permeabilized cellsby flow cytometry. Whereas approximately one-fourth of the parentalJurkat cells or mock-transfected clonal cells that did not containthe C-encoding plasmid expressed IL-2, only a minor fraction(1 to 4%) of the cells expressing HCV C were positive for IL-2(Fig. 1C).

The synthesis of IL-2 is regulated by both transcriptional andposttranscriptional mechanisms. To investigate whether the hyporesponsivenessof C-expressing cells correlated with a decreased activity ofthe IL-2 promoter, we transfected an IL-2 promoter-driven luciferasereporter plasmid into C-expressing and control cells. Strongreporter gene activity was observed when control cells werestimulated with TPA and ionomycin, as expected, whereas 5 to20% of this activity was observed with cell lines expressingHCV C (Fig. 1D).

To further characterize the cytokine profile of C-expressingcells, we compared the induction of other cytokine genes associatedwith either the Th1 (IFN- ${gamma}$ and TNF- ${alpha}$ ) or Th2 (IL-4 and IL-10)phenotype with that of IL-2 in reporter assays. Whereas theactivity of the IL-2, IL-4, and IFN- ${gamma}$ promoters was barely detectablein unstimulated C-expressing cells (data not shown), increasedbasal activities were observed for the IL-10 (two- to threefold)(P < 0.05; n = 16) and TNF- ${alpha}$ (three- to fivefold) (P <0.05; n = 22) promoters (Fig. 2A). Treatment with TPA and ionomycininduced all cytokine promoters (except IL-10 [data not shown])in Jurkat and C-expressing cell lines (Fig. 2B). However, whereasthe IL-2 gene was less inducible in C-expressing cells, increasedexpression was observed for IL-4 (2- to 7-fold) (P < 0.05;n = 19), IFN- ${gamma}$ (6- to 11-fold) (P < 0.01; n = 16), and TNF- ${alpha}$ (2- to 4-fold) (P < 0.05; n = 22).

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FIG. 2. Altered transcriptional activation of various cytokine promoters in HCV C-expressing cell lines. Cells were transiently transfected with proximal cytokine promoters coupled to either a luciferase (IL-2, IL-4, IL-10, or TNF- ${alpha}$ ) or a ß-galactosidase (IFN- ${gamma}$ ) reporter gene. At 40 h posttransfection, the cells were stimulated with TPA and ionomycin for 6 h, and the reporter activities were determined. (A) Relative cytokine induction without stimulation. (B) Relative cytokine induction after stimulation with TPA and ionomycin. For each reporter gene, all activities were normalized to those of control cells. Values are means ± standard errors of the means (SEM) of four to six independent experiments.

Decreased inducibility of the CD28 response element via the costimulatory pathway in HCV C-expressing cell lines. The induction of IL-2 synthesis is dependent on the triggeringof multiple signaling cascades and the activation of transcriptionfactors that bind to specific elements in the IL-2 promoter.Whereas TCR triggering is essentially mediated via the distal,composite NFAT/AP-1 element, the costimulatory activation ofIL-2 induction is mediated via the composite CD28 response element(CD28RE), which contains two nonconsensus binding sites, onefor NF- ${kappa}$ B and one for AP-1 (10, 40, 53, 70). To analyze whetherthe expression of HCV C affects the integrity of the TCR andcostimulatory signaling pathways, we transfected the cell lineswith reporter plasmids controlled by either the distal, compositeNFAT/AP-1 element or the composite CD28RE. In Jurkat cells,induction by TPA and ionomycin resulted in a potent activationof both promoters, as expected (Fig. 3). In C-expressing celllines, no significant difference in NFAT activation was observedcompared to the parental cell line. In contrast, significantlyless (2 to 30%) (P < 0.001; n = 14) activity was observedwith the CD28RE, indicating impaired inducibility via the costimulatorypathway.

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FIG. 3. Impaired inducibility of composite CD28 responsive element in cells expressing HCV C. Jurkat (Jk) and C-expressing cell lines (JHC.d, JHC.g, and JHC.h) were transfected with reporter plasmids containing either three distal composite NFAT elements or four composite CD28 responsive elements linked to the luciferase gene. At 40 h posttransfection, the cells were stimulated with TPA and ionomycin for 6 h, and the relative luciferase activities were determined. For each reporter gene, all activities were normalized to those of stimulated control cells. Values are means ± SEM of three independent experiments.

Increased DNA binding of NFAT in HCV C-expressing cells. Since the NFAT-luc reporter contains a trimer of one of thecomposite NFAT/AP-1 sites, the difference in inducibility betweenthe entire IL-2 promoter and the NFAT reporter might be a consequenceof the number of NFAT elements. To exclude the possibility thata potentially weaker activation of NFAT remained undetectedby the more sensitive NFAT-luc reporter, we analyzed the specificDNA binding of NFAT in an electrophoretic mobility shift assayby using a probe corresponding to a monomer of the distal NFATsite. In both cell lines, a mobility shift sensitive to a coldcompetitor was induced, indicating specific DNA binding (Fig.4). JHC.d cells displayed increased DNA binding of NFAT comparedwith parental Jurkat cells.

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FIG. 4. Specific DNA binding of activated NFAT in JHC.d cells. Nuclear extracts were prepared from stimulated Jurkat and JHC.d cells and were incubated with a labeled oligonucleotide corresponding to the IL-2 distal NFAT site in the absence or presence of a 50-fold excess of cold oligonucleotide. The bound complexes were resolved in a 5% native polyacrylamide gel. The positions of DNA complexes containing NFAT/AP1 (upper band) or NFAT (lower band) are indicated with arrows. Results that are representative of three experiments are shown.

Constitutive phosphorylation of the MAP kinases ERK1/2 and p38 in HCV C-expressing cells. Besides the requirement of NFAT, the induction of IL-2 requiresthe activation of different MAP kinase signaling pathways. Twoof these, the ERK and p38 MAP kinase pathways, are activatedby triggering of the TCR without concomitant costimulation (18).To elucidate whether the expression of C would compromise theactivation of the TCR-triggered MAP kinase pathways, we analyzedthe phosphorylation status of ERK1/2 and p38 in unstimulatedand stimulated cells. Whereas no basal phosphorylation of ERK1/2and p38 was detected in Jurkat cells, the addition of TPA andionomycin resulted in phosphorylation, as expected (Fig. 5).In C-expressing cells, ERK1/2 and p38 were constitutively phosphorylatedunder basal conditions and could be further phosphorylated bystimulation.

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FIG. 5. Activation of MAP kinases ERK1/2 and p38 in HCV C-expressing cells. Phosphorylated ERK1/2 and p38 in control cells (Jk) and HCV C-expressing cells (JHC.d, JHC.g, and JHC.h) were detected in Western blots by the use of phosphospecific antibodies to ERK1/2 and p38. Where indicated, the cells were stimulated with TPA and ionomycin (Iono) for 20 min. The expected positions of the two isoforms of ERK1/2 (42 and 44 kDa) and p38 are indicated to the left. The positions of molecular size markers (in kilodaltons) run in parallel are indicated to the right. The data presented are representative of three independent experiments.

No effect of HCV C on inducible degradation of I ${kappa}$ B- ${alpha}$ . Although TCR triggering is sufficient to activate NFAT and ERK,a simultaneous costimulation of CD28 is required for the activationof NF- ${kappa}$ B and JNK (65, 75). The activation of NF- ${kappa}$ B requires phosphorylation-dependentdegradation of the NF- ${kappa}$ B-associated inhibitor I ${kappa}$ B- ${alpha}$ , which actsby sequestering NF- ${kappa}$ B in the cytosol. To examine whether HCVC affected I ${kappa}$ B- ${alpha}$ degradation, we stimulated the cell lines withTPA and ionomycin and analyzed I ${kappa}$ B- ${alpha}$ expression by Western blotting.A time course analysis revealed that I ${kappa}$ B- ${alpha}$ levels reached a minimumat 20 min postinduction in Jurkat cells (data not shown). Thedegradation of I ${kappa}$ B- ${alpha}$ in C-expressing clones was not significantlydifferent from that in parental cells (Fig. 6).

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FIG. 6. Degradation of I ${kappa}$ B- ${alpha}$ in cells expressing the C protein. The degradation of I ${kappa}$ B- ${alpha}$ in control cells (Jk) and cells expressing HCV C (JHC.d, JHC.g, and JHC.h) was detected by immunoblotting. Where indicated, the cells were stimulated with TPA and ionomycin (Iono) for 20 min. The expected position of I ${kappa}$ B- ${alpha}$ (37 kDa) is indicated to the left, and the positions of molecular size markers (in kilodaltons) are indicated to the right. The data presented are representative of three independent experiments.

HCV C confers hyporesponsiveness to costimulation via the JNK signaling pathway. Besides NK- ${kappa}$ B activation, costimulatory signaling triggers theJNK pathway, which ultimately causes the phosphorylation-dependentactivation of c-Jun. To investigate whether the expression ofHCV affected JNK-mediated signaling, we analyzed the phosphorylationstatus of c-Jun and the upstream kinases SEK1 and JNK. Treatmentwith TPA and ionomycin resulted in the phosphorylation of SEK1,JNK, and c-Jun in Jurkat cells, as expected (Fig. 7). In contrast,no or only minimal phosphorylation of SEK1, JNK, and c-Jun wasdetected in C-expressing clones, indicating that these cellswere relatively insensitive to costimulation via the JNK signalingpathway.

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FIG. 7. Decreased inducibility of JNK signaling pathway in cells expressing HCV C. The activation of the JNK signaling pathway in control cells (Jk) and HCV C-expressing cells (JHC.d, JHC.g, and JHC.h) was analyzed in immunoblots by the use of phosphospecific antibodies to SEK1, JNK1/2, and c-Jun. Where indicated, the cells were stimulated with TPA and ionomycin (Iono) for 20 min. The expected positions of SEK1 (46 kDa), the two isoforms of JNK1/2 (46 and 54 kDa), and c-Jun (48 kDa) are indicated to the left. The positions of molecular size markers (in kilodaltons) are indicated to the right. The data presented are representative of four independent experiments.

Altered MAP kinase activation can be restored by calcium depletion or by cyclosporine A treatment. Since NFAT is activated by the Ca²⁺-dependent phosphatase calcineurin(26), we hypothesized that hyporeponsiveness in C-expressingcells might be a downstream consequence of HCV C-induced Ca²⁺oscillations. To address this question, we analyzed whetherconstitutive ERK1/2 and p38 phosphorylation and the defect inJNK signaling could be abolished by Ca²⁺ depletion or by a treatmentwith cyclosporine A, an inhibitor of calcineurin. After C-expressingcells were cultured for 24 h in the presence of cyclosporineA, the phosphorylation of ERK1/2 or p38 was no longer observed(Fig. 8A and B).

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FIG. 8. Altered MAP kinase activation is restored by treatment with cyclosporine A. Control cells (Jk) and cells expressing HCV C (JHC.d, JHC.g, and JHC.h) were stimulated with TPA and an anti-CD28 antibody ( ${alpha}$ -CD28) for 20 min. Where indicated, the cells had been pretreated with cyclosporine A (CsA; 50 ng/ml) or cultured in calcium-free medium (–Ca²⁺) for 24 h. Phosphorylated forms of ERK1/2 (A), p38 (B), and JNK1/2 (C) in cellular extracts were detected by Western blotting as described in the legend to Fig. 6. The positions of molecular size markers (in kilodaltons) are shown to the right. The data presented are representative of three independent experiments.

Besides its role in the activation of NFAT, calcineurin alsocooperates with PKC- ${theta}$ in the activation of JNK (85). Since theinhibition of calcineurin would interfere with the ionomycin-inducedactivation of JNK, a combination of TPA and a MAb recognizingCD28 was used for the induction of JNK phosphorylation in thisexperiment. As with TPA and ionomycin, the phosphorylation ofJNK was induced in Jurkat cells by this treatment but was notinduced in HCV C-expressing clones (Fig. 8C). However, afterovernight culturing in the presence of cyclosporine A, the phosphorylationof JNK could be induced in two (JHC.d and JHC.g) of the threeC-expressing clones, indicating that defective JNK activationcan be abolished by an inhibition of the Ca²⁺-calcineurin pathway.

Restored inducibility of the CD28 responsive element by ectopic expression of v-Jun. To investigate whether the impaired activation of c-Jun in C-expressingcells was a direct cause of the decreased inducibility of theCD28RE, we bypassed the JNK signaling cascade by cotransfectionof a plasmid expressing v-Jun, which is active independent ofJNK. The expression of v-Jun caused increased reporter activityin both Jurkat and JHC.d cells (Fig. 9). However, the effectof v-Jun was much more potent in JHC.d cells than in Jurkatcells, and the significantly decreased inducibility of the CD28REobserved in C-expressing cells was eliminated.

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FIG. 9. Restored inducibility of CD28 responsive element by ectopic expression of v-Jun. Jurkat (Jk) and C-expressing (JHC.d) cells were cotransfected with a luciferase reporter plasmid driven by four composite CD28REs and either an empty vector control (–) or a plasmid encoding v-Jun. At 40 h posttransfection, the cells were stimulated with TPA and an Ab recognizing CD28 ( ${alpha}$ -CD28) for 6 h, and luciferase activities was determined. The data presented are means ± SEM of four independent experiments, which were normalized to stimulated Jurkat cells.

DISCUSSION

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Discussion

The mechanisms by which HCV evades immune responses to establishand maintain persistent infections remain poorly understood.Whereas a cell-mediated immune response may result in the resolutionof an acute HCV infection, it is most often inadequate and maydisplay several abnormalities. The induction of adaptive immunityto HCV is remarkably slow and weak, as it often takes between4 and 8 weeks before HCV-specific CD8⁺ T cells can be detected(79). Furthermore, in patients who develop chronic infections,the frequencies of virus-specific CTL precursors are much lowerthan those typically observed for other viral infections (84).The effector T cells that recognize HCV peptides appear to beincompletely differentiated and functionally impaired (2, 33,84), and immature CTLs directed to unrelated viral peptideshave recently been discovered in HCV-infected individuals (48).Functionally impaired T cells are found in other persistentviral infections (2, 69, 87), and it has been suggested thatthese cells are arrested due to a lack of CD4⁺-T-cell help (39).During chronic HCV infections, CD4⁺ T cells are poorly activated(11, 54, 83), and since up to 40% of intrahepatic CD4⁺ T cellshave been shown to express viral antigens (8), we reasoned thatthe altered T-cell responsiveness may be due to the activityof HCV gene products. In line with such a scenario, we havepreviously shown that the expression of HCV C in the CD4⁺ JurkatT-cell line induces Ca²⁺ oscillations that favor the selectiveactivation of NFAT during transient expression (5, 6).

In the present study, we found that the stable expression ofHCV C in transfected Jurkat cells altered the basal cytokineprofile and induced a hyporesponsive state characterized bydecreased IL-2 inducibility. The overall alterations in thecytokine profile suggest that C expression drives Jurkat cellsto a Th2-like phenotype, which is in line with the observationthat chronic HCV infections are associated with a skewed cytokineprofile, including low IL-2 and high IL-10 production (23, 81,83, 86). Whereas IL-2 promotes Th1 cell proliferation and isrequired for sustained CD8⁺-T-cell responses (22), IL-10 actsas a general suppressor of inflammatory responses and inducesan anergic state in Th1 and Th2 cells (32). The hyporesponsivenessof the C-expressing Jurkat cells shared many features with clonalanergy, which is induced by the triggering of Ca²⁺ signalingwithout concomitant costimulation (reviewed in reference 67).Besides compromising IL-2 induction, the anergization of primaryT cells is also accompanied by defective proliferation, andalthough this effect cannot be addressed in the IL-2-independentJurkat lines, it is noteworthy that a decreased proliferativecapacity of CD4⁺ T cells has been observed during chronic HCVinfections (11, 54, 83). Notably, our C-expressing Jurkat cloneswere hyporesponsive not only to triggering of the TCR but alsoto treatment with TPA and ionomycin. Whereas potent pharmacologicalagents often overcome T-cell anergy (44), exceptions have beenreported when short incubation times between anergy inductionand restimulation are used (18). The fact that this did notoccur in C-expressing cells supports the significance of ourstudy.

Luciferase reporter assays indicated a decreased inducibilityof the IL-2 promoter in C-expressing cells. The IL-2 promotercontains binding sites for a variety of transcription factors,including NFAT, AP-1, NF- ${kappa}$ B, and Oct (reviewed in reference 68)(Fig. 10). The binding and transcriptional activation of thesefactors are regulated by a complex array of signals deliveredby the TCR and CD28, including protein tyrosine kinases, inositolphospholipid turnover, intracellular Ca²⁺ flux, calcineurin,protein kinase C, and MAP kinases. Whereas anergic T cells inducedby TCR triggering display normal Ca²⁺/NFAT signaling, defectshave been described in signaling that is essential for the activationof AP-1, e.g., p21^ras and the MAP kinases ERK, p38, and JNK(16, 25, 44). It is not clear whether an ERK deficiency contributesto anergization or is a consequence of anergy, since the inhibitionof ERK1/2 activity by the pharmacological agent PD90859 hasno effect on the induction of anergy (17). In C-expressing cells,the TCR-dependent signaling pathways remained inducible. Asreported previously, triggering of the TCR evokes a sustainedCa²⁺ flux in cells constitutively expressing HCV C (6). We havenow demonstrated that Ca²⁺- and calcineurin-dependent DNA bindingand activation of NFAT can be induced in C-expressing cells.NFAT binds in cooperation with AP-1, and the activation of thecomposite distal NFAT element is thus dependent on intact ERKsignaling, since ERK-dependent phosphorylation of Elk is requiredfor synthesis of the AP-1 component c-Fos. The phosphorylationof ERK1/2 and p38 was consistently induced by TPA and ionomycin.In addition, ERK1/2 and p38 were slightly phosphorylated evenin the absence of stimulation.

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FIG. 10. Simplified scheme of IL-2 promoter and the signaling pathways involved in its regulation. The targets for artificial inducers and inhibitors used in this study are indicated along with the targets affected by HCV C (arrows pointing up- or downwards). The composite distal NFAT/AP-1 and CD28RE/AP-1 elements are indicated by gray boxes. Notably, the effects on MAP kinase phosphorylation were likely downstream consequences of C-induced Ca²⁺ flux, since these perturbations could be eliminated by a cyclosporine A treatment. For further details, see the text. DAG, diacylglycerol; PLC- ${gamma}$ , phospholipase C- ${gamma}$ ₁; PTKs, protein tyrosine kinases.

The costimulatory pathway integrates signals from the TCR andCD28, resulting in the activation of NF- ${kappa}$ B and the JNK signalingcascade. Together with c-Rel, phosphorylated c-Jun mediatesthe costimulatory signal to the composite CD28RE in the IL-2promoter. We did not observe significant differences in thedegradation of the NF- ${kappa}$ B inhibitor I ${kappa}$ B- ${alpha}$ in control and HCV-expressingcells, suggesting that this signaling pathway remained intact.In contrast, the induction of the costimulatory MAP kinase cascadeinvolving SEK1, JNK1/2, and c-Jun was blocked and the inducibilityof the composite CD28RE was decreased, suggesting that the hyporesponsivenessin C-expressing cells was a consequence of selective inactivationof the JNK signaling cascade. Consistently, the inducibilityof the CD28RE could be restored by the ectopic expression ofv-Jun, which is active independent of JNK.

The effects of HCV C on signaling via the MAP kinases ERK, p38,and JNK were observed earlier in cells of nonhematopoietic origin,e.g., HepG2, BALB/3T3, and HEK293 cells (24, 30, 34, 73, 82).The MAP kinases are activated indirectly in a cell-dependentmanner by members of the conventional ( ${alpha}$ , ß1, ß2,and ${gamma}$ ) and novel ( ${partial}$ , ${varepsilon}$ , ${theta}$ , and ${eta}$ ) PKCs, with the latter being insensitiveto Ca²⁺ (reviewed in reference 37). Whereas in most cells bothERK and JNK kinases can be activated by PKC- ${alpha}$ , only ERK is activatedby conventional PKCs in T cells. Since conventional PKCs areactivated by Ca²⁺, a conceivable explanation is thus that thestimulatory effects that we and others have observed for HCVC on ERK are a consequence of the Ca²⁺-dependent activationof conventional PKCs. Furthermore, the different effects ofHCV C on JNK phosphorylation, by which JNK is activated in nonhematopoieticcells but not in T cells, may reflect the T-cell-specific inabilityof conventional PKCs to activate JNK.

The different effects of HCV C on cytokine expression likelyreflect structural differences in respective promoter regionsand specific requirements for induction. Except for IL-10, allanalyzed cytokine promoters contain binding sites for NFAT (52)and were hence responsive to TPA and ionomycin. However, whereasmost NFAT elements in the IL-2, IL-4, and IFN- ${gamma}$ genes in factare composite sites that require the cooperation of NFAT withAP-1, the predominant NFAT site in the TNF- ${alpha}$ promoter is a quasi-palindromic ${kappa}$ 3 site that recruits NFAT dimers and is hence inducible by triggeringof the Ca²⁺/NFAT pathway alone (51). Consistent with increasedCa²⁺ signaling, the basal expression of TNF- ${alpha}$ was indeed increasedin C-expressing cells. Finally, the IL-10 promoter is mainlyregulated via the p38 pathway (49), and the increase in constitutiveIL-10 production observed in C-expressing cells was conceivablya consequence of increased basal p38 activity.

The facts that TCR-triggered anergy induction can be preventedby cyclosporine A (66) and that it is associated with the expressionof a specific set of NFAT-regulated genes (50) underscore thecritical involvement of the Ca²⁺/calcineurin pathway for theinduction of clonal anergy. In C-expressing cells, inactivationof the Ca²⁺/calcineurin pathway by calcium deprivation or cyclosporineA treatment eliminated the constitutive phosphorylation of ERK1/2and p38 and restored the inducibility of JNK1/2 activation,indicating that the altered signaling of these pathways wasa downstream consequence of the increased Ca²⁺ flux. Conceivabletargets of the Ca²⁺/calcineurin pathway include the NFAT-driven,anergy-associated genes (50) and the MAP kinase phosphatases,which inhibit JNK activity by dephosphorylation (31, 46). Notably,treatment with cyclosporine A has been demonstrated to reducethe viral load during anti-HCV therapy (1, 36). Whereas cyclosporineA is normally used for the suppression of allograft reactions,its inhibitory effects on NFAT can also prevent the acquisitionof an anergic phenotype. Although direct antiviral effects cannotbe excluded, it is therefore conceivable that cyclosporine Atreatment facilitates the reversal of an anergic state, whichwould then allow a restart of the immune response. Furthermore,it should be stressed that the effects of C expression appearto be different in transient transfections than in stable celllines, since the transient expression of C is not associatedwith an anergic phenotype in spite of its potent activationof NFAT (5). These contradictory results may reflect differentexposure times to C in respective settings, since the acquisitionof the anergic phenotype requires sufficient time to allow theexpression of NFAT-regulated genes.

The ability of the C protein to activate NFAT can be abolishedby the deletion of its carboxy-terminal domain, which targetsC to the endoplasmic reticulum (ER) (5). Infection by virusesthat assemble on the ER membrane often results in the overexpressionand accumulation of structural proteins, which may cause nonspecificperturbations of the ER membrane that lead to activation ofthe Ca²⁺/NFAT pathway and subsequent conversion to an anergicstate. The overexpression of transfected C may have a similarnonspecific effect. However, it seems unlikely that the ectopicoverexpression of C is the sole cause of the phenotype observedin our experiments since we were able to isolate a C deletionmutant that failed to activate NFAT despite high-level accumulationin the ER (A. Bergqvist, unpublished observation). It shouldbe stressed that although the high replication rate (up to 10¹²infectious particles per day [60]) suggests that a substantialamount of the main virion component C is produced during a naturalHCV infection, the levels of C in infected lymphocytes havenot been determined and further studies are warranted to determinewhether the expression levels in the Jurkat lines reflect whatoccurs in vivo.

Our findings are in line with studies of the in vivo effectsof HCV C expression and JNK deficiency on T-cell responses.In heterologous expression systems based on either infectionwith recombinant vaccinia virus or T-cell-specific transgenicexpression, HCV C was demonstrated to be associated with immunesuppression characterized by a decreased activation of CTLsand a decreased expression of IL-2 and IFN- ${gamma}$ (41, 74). Experimentswith knockout mice suggest that JNKs are critical for Th1 differentiation,CTL function, and the resolution of infections with intracellularparasites (13, 20, 21). In summary, our results indicate thatHCV C expression in vitro leads to an inactivation of JNK signalingand hyporesponsiveness to IL-2 induction as downstream consequencesof the C-induced Ca²⁺ flux in a manner that mimics the inductionof clonal anergy. Given the requirement for IL-2 for sustainedCD8⁺-T-cell proliferation in nonlymphoid tissues, an anergicstate would reduce the prospects for a strong intrahepatic T-cellresponse, which is necessary to control the infection. Althoughthe relevance of our findings in the context of HCV infectionremains to be established and although other factors conceivablycontribute to chronicity, our data provide a plausible modelfor the insufficient CTL response that is typically associatedwith HCV persistence.

ACKNOWLEDGMENTS

We thank J. Economou, A. Kumar, K. M. Murphy, J. R. Wands, A.Weiss, and C. B. Wilson for providing antibodies and plasmids.We are also grateful to Victor Levitsky and Göran Magnussonfor critically reading the manuscript.

This work was supported by grants from the Swedish Cancer Societyand the Swedish Foundation for Strategic Research (to A.B. andM.G.M.) and by the Swedish Research Council, the Swedish Societyfor Medical Research, Åke Wibergs Stiftelse, Claes GroschinskysStiftelse, and Magnus Bergvalls Stiftelse (to A.B.).

FOOTNOTES

* Corresponding author. Mailing address: MTC, Karolinska Institutet, Box 280, SE-171 77 Stockholm, Sweden. Phone: 46-8-52487149. Fax: 46-8-331399. E-mail: anders.bergqvist{at}mtc.ki.se.

REFERENCES

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