Role of Interferon-Stimulated Gene Factor 3{gamma} and Beta Interferon in HLA Class I Enhancement in Synovial Fibroblasts upon Infection with Chlamydia trachomatis

Chlamydia trachomatis infection can cause reactive arthritisthat is associated with the persistence of chlamydial organismsin the joint. Fibroblasts of the synovial membrane representhost cells for Chlamydia during articular infection. In thisstudy we investigated the expression of HLA class I moleculesin synovial fibroblasts following infection with C. trachomatisD. The expression of HLA class I heavy chain (HLA-I) was up-regulatedin infected cultures as shown by reverse transcription-PCR andimmunoblotting. The increase in cell surface expression of HLA-Iand ß₂ microglobulin on infected fibroblasts was demonstratedby flow cytometric analysis. Suppression of enhanced productionof interferon-stimulated gene factor 3 ${gamma}$ (ISGF3 ${gamma}$ ) in infected cellcultures by antisense oligonucleotide treatment reduced thelevel of HLA-I. Blocking antibodies to beta interferon (IFN-ß)inhibited the Chlamydia-induced enhancement of both ISGF3 ${gamma}$ andHLA-I. These findings show that the up-regulation of HLA-I insynovial fibroblasts infected with C. trachomatis is causedby the induction of IFN-ß, which in turn stimulatesthe synthesis of ISGF3 ${gamma}$ , a transcription factor participatingin the regulation of the HLA-I gene. The IFN-ß-mediatedexpression of HLA-I on Chlamydia-infected cells may be a regulatoryfactor in the immune response in chlamydial infections.

INTRODUCTION

Top

Introduction

Chlamydia trachomatis, an obligate intracellular bacterium,is a major cause of urogenital infections that tend to chronicity.Chronic infections in women can lead to salpingitis and tubalocclusion. Moreover, Chlamydia is a triggering agent of reactivearthritis which is associated with the persistence of bacteriain the joint (9). Since primary target cells of urogenital C.trachomatis serovars (serovars D through K) represent nonprofessionalphagocytes which constitutively express HLA class I but onlyweakly produce HLA class II molecules, it is conceivable thatCD8⁺-T-cell-mediated immune mechanisms are important for thecontrol of these chlamydial infections. Although a Th1 CD4⁺response seems to be dominant in protective immunity duringChlamydia infection, the involvement of cytotoxic CD8⁺ T lymphocyteshas been described previously (7, 17). A macaque model of salpingitisdemonstrated that repeated chlamydial infections of the femaleupper genital tract lead to Th1-like cytokine milieus and dominantCD8⁺-T-cell infiltrates that are associated with progressionto fibrosis and infertility (28). Chlamydia-induced reactivearthritis is associated with HLA-B27, which obviously influencesthe severity of disease (reviewed in reference 5). The arthritogenicpeptide theory is one of the most-favored hypotheses of thisassociation: some HLA-B27 alleles bind a specific arthritogenicpeptide which is recognized by cytotoxic T lymphocytes. HLA-B27binding peptides derived from different C. trachomatis proteinshave been identified previously (14).

In the HLA class I antigen presentation pathway cytoplasmicallylocated antigens are degraded to peptides which are transportedinto the endoplasmic reticulum, assemble with the HLA classI heavy chain (HLA-I) and ß₂ microglobulin (ß₂M)to form the HLA class I complex. This complex is transportedto the cell surface and can be recognized by cytotoxic T lymphocytes.Although chlamydiae replicate within an endosome, there is increasingevidence that chlamydial proteins gain access to the host cellcytoplasm and enter the HLA class I pathway (4).

Inhibition of HLA molecule synthesis by intracellular pathogensis considered as a strategy to establish persisting infections(2). A recent study has demonstrated that C. trachomatis serovarL2, the causative agent of lymphogranuloma venereum, suppressesthe expression of both HLA class I and HLA class II moleculesin HeLa cells (30, 32). This effect was due to a chlamydialprotease-like activity factor which is secreted into the hostcell cytoplasm and degrades regulatory factor X-5 and upstreamfactor-1, two transcription factors participating in class Iand class II gene expression, respectively (30, 31).

Immunoelectron microscopy on synovial membrane samples frompatients with Chlamydia-induced reactive arthritis has revealedthat synovial fibroblasts are suitable host cells for C. trachomatisduring articular infection (18). Furthermore, Chlamydia-infectedsynovial fibroblasts from Lewis rats caused an arthritis withintense synovitis in rats after intra-articular injection intothe knee joints (8). In previous studies we have demonstratedthat the infection of synovial fibroblasts with C. trachomatisserovar D stimulates the production of beta interferon (IFN-ß)and interferon-stimulated gene factor 3 ${gamma}$ (ISGF3 ${gamma}$ ), the DNA-bindingcomponent of the ISGF3 complex (21, 22). The expression of HLAclass I molecules can be up-regulated by type I IFN signalingthrough the induction of ISGF3 binding to the interferon-stimulatedresponse element within the major histocompatibility complexclass I promoter (19). Therefore, this study was designed toexamine the effect of C. trachomatis D on HLA class I expressionin human synovial fibroblasts and to investigate the involvementof IFN-ß and ISGF3 ${gamma}$ in the modulation of HLA classI production by chlamydiae.

MATERIALS AND METHODS

Top

Materials and Methods

Chlamydia strains and fibroblast cultures. C. trachomatis serovar D strain IC Cal 8 (obtained from theInstitute of Ophthalmology, London, United Kingdom) was propagatedin BGM cells as previously described (21). Infectivity titersof chlamydial stocks were quantified by titrating the numberof inclusion-forming units (IFU) per milliliter in BGM cells.These titers were used to determine the infectious doses forfibroblasts.

Cultures of human synovial fibroblasts were established fromsynovial biopsy specimens obtained during meniscusectomies andarthroscopies of traumatic joint injury patients, using previouslydescribed methods (21). The fibroblasts used in this work wereHLA-B27 negative as examined by a PCR assay according to theprotocol of Bon et al. (1).

Chlamydia infection of synovial fibroblasts. Prior to infection, cells were seeded into 35-mm-diameter culturewells. Confluent monolayers (7 x 10⁵ to 10⁶ cells/well) wereinfected with C. trachomatis by centrifugation at 4,000 x gat 37°C for 45 min. After the inoculum was decanted, thecells were washed in medium and further incubated with Dulbecco'smodified Eagle's medium (Biochrom, Berlin, Germany) containing10% fetal calf serum (Biochrom). For mock-infected cultures,cells were centrifuged without a chlamydial inoculum. For someexperiments, infected fibroblasts were stimulated with tumornecrosis factor alpha (TNF- ${alpha}$ ) (200 U/ml; Biochrom) after infection.For heat inactivation, chlamydial suspensions were held at 75°Cfor 10 min prior to inoculation onto cell monolayers. For UVinactivation, chlamydial suspensions were placed under a UVlamp (15 W at 30 cm) for 15 min. Sheep polyclonal antibody tohuman IFN-ß (Chemicon, Hofheim, Germany) was usedto neutralize IFN-ß activity in infected cultures.

Inhibition of ISGF3 ${gamma}$ expression by antisense oligodeoxynucleotide (ODN) treatment. Antisense (5'-TGCCCTGCCTGATGCCAT-3') and sense (5'-ATGGCATCAGGCAGGGCA-3')phosphorothioate ODNs corresponding to the human ISGF3 ${gamma}$ cDNAsequence extending from the initiation codon to 18 nucleotidesdownstream were synthesized and high-performance liquid chromatography-purifiedby E. Birch-Hirschfeld (Institute of Virology, University ofJena, Jena, Germany). Transfection of fibroblasts with ODNswas performed using the Effectene transfection reagent kit (Qiagen,Hilden, Germany) according to the manufacturer's protocol.

Reverse transcription (RT)-PCR assay. Total RNA was prepared from mock-infected and Chlamydia-infectedfibroblasts using the RNeasy Mini Kit (Qiagen). For each sample,first-strand cDNA was reverse transcribed from 1 µg ofRNA in a total reaction volume of 20 µl, using the Promega(Mannheim, Germany) reverse transcription system. Each 25 µlof PCR mixture contained 1 µl of cDNA (corresponding to50 ng of RNA), 10 mM Tris-HCl (pH 8.3), 50 mM KCl, a 0.2 mMconcentration of each deoxynucleoside triphosphate, 1.5 mM MgCl₂,0.4 µM sense and antisense primers, and 1.25 U of Taqpolymerase (Promega). The sequences of specific primers usedin this work are given in Table 1. As an internal control, cDNAwas amplified for pyruvate dehydrogenase (PDH). Twenty-fivecycles of amplification were carried out in a TRIO-Thermoblock(Biometra, Göttingen, Germany). Reactions consisted ofan initial incubation at 95°C for 7 min and then cyclingat 95°C for 30 s, 60°C (ISGF3 ${gamma}$ and PDH primers) or 54°C(IFN-ß, HLA-I, and ß₂M primers) for 30 s,and 72°C for 1 min, with a final incubation at 72°Cfor 10 min. Negative controls were performed by omitting RNAfrom cDNA synthesis and PCR amplification (data not shown).Products were electrophoresed on 1% agarose gels and visualizedwith SYBR green staining. All HLA-I (A, B, C), ß₂M,ISGF3 ${gamma}$ , and IFN-ß band volumes (optical density x area[square millimeters]) were normalized against the PDH signalfrom the same sample. All results shown are representative oftwo separate experiments.

View this table:
[in this window]
[in a new window]
TABLE 1. Primers used for RT-PCR

The specificity of the PCR products was confirmed by the presenceof a DNA band of the expected size (Table 1) and by sequencingin an automated ABI Prism 310 genetic analyzer (Perkin-Elmer,Applied Biosystems, Weiterstadt, Germany) as previously described(22).

Immunoblotting. Immunoblot assays were carried out as we described in a previouspaper (22). HLA-I protein was detected with a mouse monoclonalantibody purchased from DPC Biermann (Bad Nauheim, Germany)(Anogen clone LY5.1). ISGF3 ${gamma}$ protein was detected with a mousemonoclonal antibody purchased from BD Transduction Laboratories(Heidelberg, Germany) (clone 6). Alkaline phosphatase-conjugatedgoat anti-mouse IgG (Dianova, Hamburg, Germany) was used assecondary antibody. The bands were visualized with 5-bromo-4-chloro-3-indolylphosphatetoluidine salt-p-nitroblue tetrazolium chloride (BCIP/NBT) (Sigma,Deisenhofen, Germany). All results shown are representativeof two separate experiments.

Flow cytometry. Cells were detached from the culture wells with 0.2 mM EDTA,washed in phosphate-buffered saline, and incubated with fluoresceinisothiocyanate (FITC)-conjugated mouse monoclonal antibody toHLA-I (clone R-phycoery-thrin-2.6; BD PharMingen, Heidelberg,Germany) or FITC-conjugated rabbit polyclonal antibody to ß₂M(Dako, Hamburg, Germany) at room temperature for 20 min. Forthe dual-color assay, cell suspensions were incubated with RPE-conjugatedmonoclonal antibody to HLA-I (clone G46-2.6; BD Pharmingen).After washing, the cells were permeabilized with FACS permeabilizingsolution (BD Immunocytometry Systems) and stained with FITC-conjugatedantibody to C. trachomatis major outer membrane protein (TrinityBiotech, Frankfurt, Germany). Two additional washes were performed,and labeled cells were analyzed with a FACScan (BD ImmunocytometrySystems) flow cytometer and CELL Quest software. Ten thousandcells were analyzed for each sample.

RESULTS

Top

Results

Up-regulation of HLA class I expression by C. trachomatis D in synovial fibroblasts. To study the effect of C. trachomatis infection on HLA classI expression in synovial fibroblasts, we first examined thelevels of HLA-I and ß₂M mRNA using a semiquantitativeRT-PCR assay. Mock-infected fibroblasts produced a basal levelof HLA-I and ß₂M. Infection with C. trachomatis Dcaused an increase in the mRNA level of HLA-I in a dose-dependentmanner at 24 h after infection, whereas the level of ß₂MmRNA remained unchanged (Fig. 1A). Expression of the housekeepinggene PDH was not affected in response to the infection.

View larger version (35K):
[in this window]
[in a new window]
FIG. 1. HLA class I expression in synovial fibroblasts infected with C. trachomatis D. (A) HLA-I and ß₂M mRNA levels in cells infected with various doses of chlamydiae. RT-PCR analysis was conducted on total RNA extracted at 24 h after infection. (B) Immunoblot analysis of HLA-I protein in cells infected with various doses of chlamydiae. Total cell lysates were prepared at 48 h after infection. (C) Time course of HLA-I production determined by immunoblotting. Fibroblasts were infected with 5 x 10⁶ IFU/well.

Further experiments were performed to examine whether enhancedHLA-I mRNA levels in infected cultures were associated withincreased protein synthesis. Immunoblot analyses of total celllysates showed a specific band of HLA-I of approximately 46kDa. The amount of HLA-I protein increased with larger infectiousdoses (Fig. 1B). Chlamydia-exposed cells showed enhanced levelsof HLA-I protein at 24, 48, and 72 h after infection comparedto mock-infected cells (Fig. 1C).

Cell surface expression of HLA class I was measured by flowcytometry. These experiments revealed an increase in the surfaceexpression of both HLA-I and ß₂M following chlamydialinfection (Fig. 2A). In infected cultures about 98% of the cellscontaining Chlamydia were HLA-I positive, indicating that therewas no selective inhibition of HLA-I expression in Chlamydia-positivecells (Fig. 2B).

View larger version (35K):
[in this window]
[in a new window]
FIG. 2. Flow cytometric analysis of HLA class I expression on fibroblasts with and without C. trachomatis infection. (A) HLA-I and ß₂M surface expression on cells in mock-infected and infected cultures. MFI, mean fluorescence intensity. (B) Dual-color assay for HLA-I and Chlamydia antigen expression. HLA-I-positive cells are shown in the top quadrants. Chlamydia-positive cells are shown in the right-hand quadrants. (A and B) The cells were infected with 5 x 10⁶ IFU/well and harvested 48 h after infection. Results are representative of three experiments.

The stimulation of HLA-I expression required infectious chlamydiae,since fibroblasts exposed to heat or UV inactivated bacteriaproduced HLA-I mRNA levels similar to that of mock-infectedcells (Fig. 3).

View larger version (53K):
[in this window]
[in a new window]
FIG. 3. Effects of heat and UV inactivation of Chlamydia on HLA-I and ß₂M mRNA levels in synovial fibroblasts. Cells were infected with 5 x 10⁶ IFU/well or centrifuged with an equivalent inoculum of inactivated chlamydiae. RT-PCR analysis was conducted on total RNA isolated at 24 h after infection.

Contribution of ISGF3 ${gamma}$ and IFN-ß to the HLA class I enhancement in C. trachomatis-infected fibroblasts. In previous studies we have shown that C. trachomatis infectionup-regulates ISGF3 ${gamma}$ and IFN-ß synthesis in fibroblasts(21, 22). It is known that the expression of HLA-I is regulatedby ISGF3 (19). Therefore, an antisense ODN technique was employedto investigate the role of ISGF3 ${gamma}$ in the HLA-I enhancement inChlamydia-infected synovial fibroblasts. We first examined theeffect of different amounts of antisense and sense ODN (0.5,1, and 2 µg per 35-mm-diameter culture well) on ISGF3 ${gamma}$ protein levels in infected cultures (data not shown). Inhibitionof ISGF3 ${gamma}$ protein synthesis was observed at an amount of 2 µgof antisense ODN per culture well, whereas the level of mRNAremained unchanged (Fig. 4). In all further transfection experimentswe used 2 µg of ODN per well and harvested the cells forRT-PCR and immunoblot assays at 24 h after transfection. Asdemonstrated in Fig. 4, inhibition of ISGF3 ${gamma}$ production by antisenseODN was associated with a decrease in mRNA and protein levelsof HLA-I. The induction of IFN-ß mRNA was only slightlysuppressed by antisense ODN (Fig. 4A). Treatment of Chlamydia-infectedfibroblasts with ISGF3 ${gamma}$ sense ODN had no inhibitory effect onthe expression of any gene analyzed in this study (Fig. 4).

View larger version (30K):
[in this window]
[in a new window]
FIG. 4. Effects of ISGF3 ${gamma}$ antisense ODN on HLA class I expression in synovial fibroblasts infected with C. trachomatis D. The cells were incubated with medium alone or with ODN (2 µg/well) and collected 24 h after infection. (A) mRNA levels of ISGF3 ${gamma}$ , IFN-ß, HLA-I, and ß₂M were analyzed by RT-PCR. (B) ISGF3 ${gamma}$ and HLA-I proteins were detected by immunoblotting.

The up-regulation of ISGF3 ${gamma}$ in synovial fibroblasts followingchlamydial infection may be caused by the production of IFN-ß.In the presence of neutralizing antibodies against IFN-ßthe production of ISGF3 ${gamma}$ mRNA and protein was clearly inhibitedwhen sufficient amounts of antibody were added (150 neutralizingunits/ml) (Fig. 5). This effect was paralleled by a decreasein the levels of HLA-I mRNA and protein (Fig. 5). Furthermore,IFN-ß neutralization results in partial inhibitionof IFN-ß gene induction, confirming that IFN-ßregulates its own synthesis (Fig. 5A) (6, 29).

View larger version (28K):
[in this window]
[in a new window]
FIG. 5. Blocking of Chlamydia-mediated HLA-I enhancement by IFN-ß antibodies. Fibroblasts were infected with C. trachomatis D and incubated with medium alone or with anti-IFN-ß. The cells were collected 24 h after infection. (A) mRNA levels of ISGF3 ${gamma}$ , IFN-ß, HLA-I, and ß₂M were analyzed by RT-PCR. (B) ISGF3 ${gamma}$ and HLA-I proteins were determined by immunoblotting.

The time course of mRNA levels demonstrated that the accumulationof ISGF3 ${gamma}$ mRNA did not precede the induction of IFN-ßmRNA; stimulation of IFN-ß, ISGF3 ${gamma}$ , and HLA-I expressionwas observed 24 and 48 h after infection (Fig. 6).

View larger version (57K):
[in this window]
[in a new window]
FIG. 6. Time course of ISGF3 ${gamma}$ , IFN-ß, HLA-I, and ß₂M mRNA expression in fibroblasts infected with C. trachomatis D. mRNA levels were determined by RT-PCR. The cells were infected with 5 x 10⁶ IFU/well.

Effect of TNF- ${alpha}$ on Chlamydia-stimulated HLA class I expression. Since TNF- ${alpha}$ interacts with chlamydial infection in the inductionof the host cell type I IFN response, we examined the effectof TNF- ${alpha}$ on HLA class I expression in C. trachomatis-infectedfibroblasts (22, 23). Treatment of infected cells with TNF- ${alpha}$ at 200 U/ml clearly enhanced the synthesis of HLA-I mRNA andprotein, compared to mock-infected cells incubated with TNF- ${alpha}$ or infected cells cultured in medium alone (Fig. 7). Moreover,ß₂M levels were found to be elevated in infected fibroblastsafter TNF- ${alpha}$ stimulation (Fig. 7A).

View larger version (38K):
[in this window]
[in a new window]
FIG. 7. Effect of TNF- ${alpha}$ treatment on HLA class I expression in C. trachomatis-infected fibroblasts. (A) Detection of HLA-I and ß₂M mRNA by RT-PCR. (B) Immunoblotting of HLA-I protein. Cells were collected 24 h after infection.

DISCUSSION

Top

Discussion

In this work the effect of C. trachomatis infection of synovialfibroblasts on HLA class I expression was investigated. We usedthis in vitro model because fibroblasts of the synovial membranerepresent host cells for chlamydiae during articular infectionin reactive arthritis (18). Whether fibroblasts are infectedby Chlamydia during infections of the urogenital tract remainsunclear. In situ hybridization of chlamydial DNA and detectionof bacterial antigen in tubal biopsy specimens from women withpostinfectious sterility suggested that C. trachomatis persistsin submucosal tissues (20). These observations correspond tostudies of a macaque model of Chlamydia-induced salpingitis,in which the pathogen was found not only in the mucosa but alsoin the submucosa and deep tissues, including connective tissueand smooth muscle layers (3).

We have shown that the infection of synovial fibroblasts withC. trachomatis D stimulates the expression of HLA class I molecules.This effect could be reduced by IFN-ß neutralizationin infected cultures, demonstrating that a mechanism of theHLA class I enhancement is a secondary effect of IFN-ßinduced by Chlamydia. The expression of HLA-I is regulated atthe transcriptional level (27). The interferon-stimulated responseelement which is bound by interferon regulatory family (IRF)transcription factors such as IRF-1 and ISGF3 ${gamma}$ , is one of themain control elements within the HLA-I promoter (27). Usingan antisense ODN technique we could demonstrate that the increasedproduction of ISGF3 ${gamma}$ is involved in the up-regulation of HLA-Iin C. trachomatis-infected cultures. Type I IFN can induce thetranscription of IFN-stimulated genes by activating the functionof the ISGF3 complex and by enhancing the level of ISGF3 ${gamma}$ (12,13). Therefore, the increased production of ISGF3 ${gamma}$ is a criticalregulator of the IFN response. Neutralization of IFN-ßactivity in infected cell cultures clearly reduced the levelof ISGF3 ${gamma}$ , whereas ISGF3 ${gamma}$ antisense ODN treatment had only littleeffects on induction of the IFN-ß gene. These findingsindicate that the IFN-ß initially produced in responseto the chlamydial infection stimulates ISGF3 ${gamma}$ production, resultingin enhanced expression of HLA-I.

The treatment of infected cells with TNF- ${alpha}$ caused an additionalincrease in the synthesis of HLA-I, whereas TNF- ${alpha}$ stimulationof mock-infected cells had only little effect. It is known thatTNF- ${alpha}$ alone inefficiently induces the IFN-ß gene butacts in synergism with IFNs in the activation of IFN-induciblegenes (10). Our observations correspond to previous studiesin which an interaction of TNF- ${alpha}$ and chlamydial infection inthe induction of IFN-ß and ISGF3 ${gamma}$ was found (22, 23).

Recently, Zhong et al. reported that C. trachomatis suppressesthe expression of HLA class I molecules in HeLa cells and othertumor cell lines (30). This phenomenon was due to a Chlamydia-specificfactor (chlamydial protease-like activity factor) which is secretedinto the host cell cytoplasm and degrades regulatory factorX-5, a transcription factor participating in HLA-I gene expression(27, 30, 31). However, the activation of specific CD8⁺ T cellsin chlamydial infections provides an argument against the hypothesisof a general inhibition of HLA-I in all Chlamydia-infected cells.Our data indicate that the induction of the type I IFN responseof the host cell plays an important role in the expression ofHLA class I molecules after chlamydial infection.

In contrast to the stimulatory effect on HLA class I synthesis,C. trachomatis D inhibits the IFN- ${gamma}$ -induced expression of HLAclass II molecules in synovial fibroblasts (21). Therefore,it is possible that an HLA class I-restricted CD8⁺-T-cell responseparticipates in the recognition of Chlamydia-infected nonprofessionalphagocytes. The involvement of cytotoxic T lymphocytes in theimmune response to C. trachomatis infections has been demonstratedin several studies (7, 11, 15, 17, 25). Besides the abilityto lyse infected cells, the production of IFN- ${gamma}$ is another potentialmechanism for CD8⁺ T cells to limit the spread of infection(15).

In conclusion, we have shown that the infection of synovialfibroblasts with C. trachomatis D results in an up-regulationof HLA-I which is caused by the induction of IFN-ßand ISGF3 ${gamma}$ . Further studies are needed to elucidate whether theIFN-ß-mediated expression of HLA class I moleculeson Chlamydia-infected cells has any impact on the activationof CD8⁺ T lymphocytes and influences the control of chlamydialinfection.

ACKNOWLEDGMENTS

This work was supported by grant BMBF 01ZZ9602 from the Bundesministeriumfür Bildung und Forschung, Berlin, Germany.

We thank the collaborators of the Bundesinstitut für GesundheitlichenVerbraucherschutz und Veterinärmedizin Jena for performingMycoplasma testing, W. Lungershausen (Clinic of Surgery, Universityof Jena) for providing synovial tissue, and E. Birch-Hirschfeld(Institute of Virology, University of Jena) for providing PCRprimers and phosphorothioate ODN.

FOOTNOTES

* Corresponding author. Mailing address: Institute of Medical Microbiology, Friedrich Schiller University of Jena, Semmelweisstr. 4, D-07740 Jena, Germany. Phone: 49-3641-933105. Fax: 49-3641-933474. E-mail: juergen.roedel{at}med.uni-jena.de.

Editor: J. D. Clements

REFERENCES

Top