Murine Oviduct Epithelial Cell Cytokine Responses to Chlamydia muridarum Infection Include Interleukin-12-p70 Secretion

Epithelial cells play an important role in host defense as sentinelsfor invading microbial pathogens. Chlamydia trachomatis is anintracellular bacterial pathogen that replicates in reproductivetract epithelium. Epithelial cells lining the reproductive tractlikely play a key role in triggering inflammation and adaptiveimmunity during Chlamydia infections. For this report a murineoviduct epithelial cell line was derived in order to determinehow epithelial cells influence innate and adaptive immune responsesduring Chlamydia infections. As expected, oviduct epithelialcells infected by Chlamydia muridarum produced a broad spectrumof chemokines, including CXCL16, and regulators of the acute-phaseresponse, including interleukin-1 ${alpha}$ (IL-1 ${alpha}$ ), IL-6, and tumor necrosisfactor alpha. In addition, infected epithelial cells expressedcytokines that augment gamma interferon (IFN) production, includingIFN- ${alpha}$ /ß and IL-12-p70. To my knowledge this is thefirst report of a non-myeloid/lymphoid cell type making IL-12-p70in response to an infection. Equally interesting, infected epithelialcells significantly upregulated transforming growth factor alphaprecursor expression, suggesting a mechanism by which they mightplay a direct role in the pathological scarring seen as a consequenceof Chlamydia infections. Data from these in vitro studies predictthat infected oviduct epithelium contributes significantly tohost innate and adaptive defenses but may also participate inthe immunopathology seen with Chlamydia infections.

INTRODUCTION

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Introduction

Chlamydia trachomatis serovars D to K, referred to as the urogenitalserovars, are sexually transmitted intracellular bacterial pathogensthat cause acute urethritis, epididymitis, and pelvic inflammatorydisease. C. trachomatis serovars A to C cause an eye infectioncalled trachoma. Serovars L1 to L3 cause lymphogranuloma venereum(LGV), a disseminating sexually transmitted disease that beginswith a primary small ulcerative lesion and progresses to fever,regional lymphadenopathy, and genital ulceration and/or lymphaticobstruction in later stages. Trachoma and LGV are uncommon inthe developed world, while the urogenital serovars D to K areubiquitous. With the exception of neonatal pneumonia and eyeinfections, urogenital serovars of C. trachomatis replicateexclusively in the epithelium lining the reproductive tract.The infectious particle is a metabolically inactive intermediateknown as an elementary body. Elementary bodies deposited ontoreproductive tract mucosa are endocytosed by epithelial cells,become metabolically active, and replicate in modified vacuoles,termed inclusions. The replicating form of C. trachomatis isa noninfectious form known as the reticulate body. As the developmentalcycle progresses, progeny Chlamydia condense into infectiouselementary bodies that are released by exocytosis or host celllysis. Urogenital strains release apically, infecting adjacentmucosal epithelial cells, while disseminating serovars releasebasolaterally, penetrating beyond the mucosal epithelium (71).

During C. trachomatis infections with the urogenital serovars,progression of the infection into the upper female reproductivetract causes marked inflammation of the Fallopian tubes (47).Clinical data suggests that C. trachomatis evades immune-mediatedelimination to cause persistent infections in some individuals(4, 11, 45, 54, 57, 64, 68). In women, chronic or recurrentC. trachomatis urogenital infections scar the Fallopian tubes,resulting in infertility and ectopic pregnancies, the two clinicallyimportant sequelae of infection (12, 13).

Epithelial cells lining mucosal surfaces serve as sentinelsfor invasion by microbial pathogens through the release of inflammatorycytokines (reviewed in reference 30). Because epithelial cellsare the only cell type productively infected by C. trachomatis,they are the logical epicenter for the local inflammatory response.An increasing body of clinical data supports the existence ofchronic Chlamydia infections and raises the possibility thatinfected epithelial cells directly contribute to Fallopian tubescarring, infertility, and ectopic pregnancies (reviewed inreference 65).

Studies of epithelial cell responses to C. trachomatis infectionhave utilized human epithelial tumors. HeLa cervical carcinomacells infected with LGV secreted interleukin-1 ${alpha}$ (IL-1 ${alpha}$ ), IL-6,IL-8, granulocyte-macrophage colony-stimulating factor (GM-CSF),and Gro ${alpha}$ (CXCL1) (58). Polarized HEC-1-B endometrial adenocarcinomacells infected with C. trachomatis urogenital serovar E upregulatedmRNA for neutrophil chemokines ENA-78 (CXCL5) and GCP-2 (CXCL6)(72). Microarray analysis of serovar D in nonpolarized HeLacells showed upregulation of 18 genes. Of the 18, 4 were cytokines:IL-8, IL-11, leukemia inhibitory factor, and macrophage inhibitoryprotein 2 ${alpha}$ (MIP-2 ${alpha}$ ; CXCL2) (25). Similarly, analysis of C. trachomatisserovar E-infected polarized HeLa cells showed upregulationof IL-11 mRNA and secretion of IL-6, IL-8, and IL-11 (20). HeLacells infected by LGV, urogenital serovars, and C. muridarumsecreted preformed IL-18 via a posttranslational mechanism dependenton caspase-1 (39). Recently, the effects of Chlamydia infectionon HeLa cells were investigated by using high-density oligonucleotidemicroarrays (73). Nonpolarized HeLa cells infected with LGValtered the transcription of 130 genes on a 15,000-gene microarray.Upregulated cytokine transcription was seen for IL-1ß,IL-6, and IL-16 (73). Analysis of the response of primary epithelialcells to Chlamydia infection is very limited (32). No studiesto date have examined the response of oviduct epithelial cellsto C. trachomatis infection.

Previous studies utilizing human epithelial tumors have identifieda cadre of inflammatory cytokines induced by C. trachomatisinfection. However, the existing data set was notable for theabsence of some expected key inflammatory mediators, such astumor necrosis factor alpha (TNF- ${alpha}$ ) (3), IP-10 gamma interferon(IFN- ${gamma}$ )-inducible 10-kDa protein (CXCL10), and RANTES (CCL5)(44). This suggested that existing in vitro models based onepithelial tumor cell lines might not fully mimic the immunobiologyof Chlamydia-infected epithelium. To address this possibility,a nontransformed primary murine oviduct epithelial cell linewas derived for experiments with C. muridarum, a murine pathogenclosely related to C. trachomatis that is often used as an experimentalsurrogate for human infections (5, 14, 35). The cytokine datafrom those experiments, presented here, are consistent withthe histopathology and cytokine polarization seen during naturalinfections with urogenital Chlamydia serovars.

MATERIALS AND METHODS

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Materials and Methods

Mice. Female B6.C-H2^bm1/ByJ mice were purchased from The Jackson Laboratory(Bar Harbor, Maine) and were housed in Indiana University PurdueUniversity—Indianapolis specific-pathogen-free facilities.The Institutional Animal Care and Utilization Committee approvedall experimental protocols.

Cell lines. McCoy mouse fibroblasts were generously provided by BarbaraVan der Pol (Indiana University School of Medicine, Indianapolis).Murine B-cell lymphoma A20 (TIB-208) and normal mouse fibroblastCL.7 (TIB-80) were obtained from the American Type Culture Collection(Manassas, Va.). A murine oviduct cell line designated Bm1.11was generated by resection of the proximal two-thirds of theoviducts, excluding the ovaries, from a female B6.C-H2^bm1/ByJmouse. Oviduct epithelial cells were released from oviduct lumensby canulating the lumens with a 0.5-ml syringe and insufflatingthem with pancreatin-hyaluronidase-collagenase cocktail (69)and then rinsing the lumens with the same cocktail after 15min at 37°C. Released cells were recovered and grown in1:1 Dulbecco's modified Eagle medium:F12K (Sigma Chemical Co.,St. Louis, Mo.) supplemented with 10% characterized fetal bovineserum (HyClone, Logan, Utah), 2 mM L-alanyl-L-glutamine (GlutamaxI; Gibco/Invitrogen, Carlsbad, Calif.), 5 µg of bovineinsulin/ml, and 12.5 ng of recombinant human FGF-7 (KGF; SigmaChemical Co.)/ml. Ciprofloxacin (10 µg/ml), gentamicin(25 µg/ml) (Sigma Chemical Co.), and 10 mM HEPES (Biowhittaker,Walkersville, Md.) were included in the culture medium for thefirst 4 weeks after explantation. Once a stable line was established,cloned cell lines were generated by dispersion at low density.Individual colonies were picked by using cloning rings. Resultingcell lines were screened for morphology, expression of cytokeratins,and IFN- ${gamma}$ -inducible expression of I-A^b. A cloned cell line designatedBm1.11 had an epithelial morphology, expressed cytokeratins,and had IFN- ${gamma}$ -inducible major histocompatibility complex (MHC)class II expression. The Bm1.11 cell line, maintained as describedabove, showed no evidence for senescence after more than 100passages. All cell lines tested negative for mycoplasma contaminationby either susceptibility to 6-methylpurine deoxyriboside (MycoTectkit; Invitrogen Corp.) or PCR (Mycoplasma detection kit; AmericanType Culture Collection).

Chlamydia. C. muridarum, previously known as C. trachomatis strain MoPn,was generously provided by Barbara Van der Pol and was grownin McCoy cells. A mycoplasma-free stock was generated by exposureof existing stocks to 1% Triton X-100 as previously described(53), followed by detergent removal with Extracti-Gel D beads(Pierce Chemical, Rockford, Ill.) and limiting dilution on McCoymonolayers. Wells with visible cytopathic effect at the highestdilution (calculated to be $~$ 800 inclusion-forming units [IFU]prior to detergent treatment) after 5 days were harvested andexpanded. Treated stocks were tested for the presence of mycoplasmaby exposing nonpermissive A20 B cells to Chlamydia stocks, passingthe A20 cells for more than 2 weeks in the absence of antibiotics,and then testing for A20 susceptibility to 6-methylpurine deoxyriboside(MycoTect kit; Invitrogen Corporation). The titers of mycoplasma-freeC. muridarum stocks were determined on McCoy cells with centrifugationas previously described (61).

Infections. Bm1.11 cells were plated in 6-well tissue culture plates andwere used when confluent to minimize changes in cell numberover the time course of individual experiments. For all experiments,Bm1.11 cells were infected with 10 IFU of C. muridarum/cellin 2 ml of culture medium without centrifugation or subsequentchange of medium. Mock-infected wells (0 h) received an inoculum-equivalentvolume of sucrose-phosphate-glutamic acid buffer (SPG buffer)but lacked C. muridarum in the medium.

Immunohistochemistry. Bm1.11 cells grown on glass chamber slides (Labtek, Naperville,Ill.) were fixed for 2 min at room temperature with 1:1 methanol-acetone,blocked with 5% normal goat serum-phosphate-buffered salinefor 45 min, and then stained with 36-7-5, a monoclonal antibodyspecific for H-2K^k (an epitope not present on Bm1.11 cells)(BD Pharmingen, San Diego, Calif.) or monoclonal antibody cocktailAE1/AE3 specific for acidic and basic cytokeratins (Cappel/ICN,Irvine, Calif.). Detection was accomplished with a fluoresceinisothiocyanate-coupled goat anti-mouse immunoglobulin G F(ab')₂affinity-purified antiserum (Cappel/ICN).

Flow cytometry. Bm1.11 cells were dislodged from tissue culture plastic by usinga Hank's salt-based enzyme-free cell dissociation buffer (Gibco/Invitrogen).Cells were fixed with StabilCyte (Ebio, St. Paul, Minn.) andthen were washed and stained for 20 min on ice in phosphate-bufferedsaline-2% bovine serum albumin with phycoerythrin-coupled M5/114.15.2(I-A^b) (Ebioscience, San Diego, Calif.). IFN- ${gamma}$ induction wasaccomplished by addition of 10 ng of murine recombinant IFN- ${gamma}$ (Sigma Chemical Co.)/ml to the culture medium for 14 h priorto fixation and staining. Cells were analyzed with a FACS Caliburcytometer (BD Biosciences, San Diego, Calif.).

RPA. Standard template sets mCK-1b, mCK-3b, and mCK-5c were purchasedfrom a commercial vendor. In addition, a custom template wasdesigned and purchased that included probe templates for IL-12-p35,IL-12-p40, IL-1ß, IL-11, IL-7, IL-1 ${alpha}$ , transforminggrowth factor ${alpha}$ (TGF ${alpha}$ ), and IFN ${alpha}$ -4. ³²P-multiprobe RNase protectionassays (RPA) were done with a commercial kit according to themanufacturer's protocol (Riboquant; BD Pharmingen). In all experiments2 µg of yeast tRNA served as the control for hybridization;L32 and GAPDH probes served as loading and RNA quality controls.Untreated ³²P probe (2,000 cpm) was loaded on each denaturingpolyacrylamide gel to generate the standard curves used to identifyprotected RNA fragments. Experimental probe hybridizations containedtotal RNA from 5 x 10⁵ Bm1.11 cell equivalents. Total RNA wasisolated with a commercial kit according to manufacturer protocols(RNeasy; QIAGEN, Valencia, Calif.).

Generation of mature peritoneal macrophages. Peritoneal macrophages were isolated from three female C57BL/6mice by peritoneal lavage. Recovered cells were suspended at10⁶ cells/ml in RPMI 1640 complete medium containing 20 ng ofrecombinant murine IL-3 (R&D Systems, Minneapolis, Minn.)/mland were plated at 2 ml per well in a 12-well tissue culture-treatedplate. On day 3, 1 ml of the medium was removed and replacedwith 1 ml of fresh medium containing IL-3 as described above.On day 6 the cultures were activated by adding 10 ng of E. coliLPS/ml and 10 ng of recombinant murine IFN- ${gamma}$ (Sigma ChemicalCo.)/ml. After 24 h total RNA from each well was isolated withthe RNeasy commercial kit as described above.

RT-PCR. Optimized primer pairs were designed using Vector NTI Suite(Infomax Inc., Frederick, Md.). Primer pairs (Amitof, Alston,Mass.) are described in Table 1. Reverse transcriptase PCR (RT-PCR)was accomplished by using a single-tube avian myeloblastosisvirus RT-Tfl polymerase kit (Access RT-PCR; Promega, Madison,Wis.) with 32 cycles. RT-negative reactions were included torule out DNA artifacts. ABCD-1 (CCL22) and TARC (CCL17) primerpairs did not generate specific RT-PCR products in infectedepithelial cells. The ABCD-1 (CCL22) primer pair detected ABCD-1(CCL22) mRNA in LPS-treated splenocyte and activated peritonealmacrophage total RNA by RT-PCR. A 280-bp spurious PCR productrepresenting mouse mitochondria RNA was also amplified by theCCL22 primer pair based on 10 out of 11 and 8 out of 9 baseidentities with mitochondria RNA in the primer termini. I donot have an adequate positive control to confirm the TARC RT-PCRassay. TARC (CCL17) expression is limited to activated Langerhanand myeloid dendritic cells. It is not expressed in the spleeneven during systemic microbial infection (2).

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TABLE 1. Primers used for RT-PCR

Northern blots. RT-PCR products from monokine induced by IFN- ${gamma}$ (Mig; CXCL9),CX3CL1, CXCL16, and MARC (CCL7) primer pairs were gel purifiedand cloned into pCRII-TOPO (Invitrogen). Insert identity wasconfirmed by sequencing each cloned chemokine fragment. A mouseß-actin control amplimer was purchased from a commercialvendor (Clontech/BD Biosciences). In all experiments total RNAfrom 5 x 10⁵ Bm1.11 cells was loaded into each lane of a 1%agarose formaldehyde gel. Digoxigenin-labeled RNA molecularsize markers were purchased from a commercial vendor (RocheDiagnostic Corp., Indianapolis, Ind.). Neutral transfer to positivelycharged nylon membranes was accomplished by using a downwardtransfer system (Schleicher & Schuell, Keene, N.H.). Aftertransfer to the membrane, RNA was UV cross-linked to the membrane.Membranes were probed with PCR-generated digoxigenin-labeledDNA probes (Roche Diagnostic Corp.). Approximately 500 ng oflabeled probe was denatured at 95°C for 3 min and then washybridized with the membrane for 1 h at 68°C in ExpressHybfollowing the manufacturer's protocol (Clontech/BD Biosciences).Digoxigenin-labeled probes retained on the membrane were detectedby using chemiluminescence with a digoxigenin-specific monoclonalantibody coupled to alkaline phosphatase and disodium 3-(4-methoxyspiro{1,2-dioetane-3,2-(5-chloro)tricyclo[3,3,1,13,7]decon}-4yl)phenylphosphate (CSPD) substrate according to the manufacturer'sprotocol (Roche Diagnostic Corp.). All film exposures were for1 h.

Multiplex ELISA determination of cytokine production. Confluent Bm1.11 monolayers in 12-well tissue culture-treatedplates were infected with 10 IFU of C. muridarum/cell in 2 mlof fresh medium (to minimize concentrations of cytokines madeconstitutively) without centrifugation or subsequent changeof the medium. Mock-infected wells (0 h) received an inoculum-equivalentvolume of SPG buffer but did not have C. muridarum in the medium.At indicated time points supernatants were harvested, spun for2 min at 16,000 x g in a microcentrifuge to remove debris, broughtto 0.5% (vol/vol) NP-40 (to neutralize C. muridarum), and frozenat –80°C. Samples representing two independent experimentswere shipped to a commercial vendor to be analyzed for cytokinecontent by multiplex enzyme-linked immunosorbent assay (ELISA)technology (Searchlight; Pierce Chemical Co.). Cytokines testedincluded murine GM-CSF, TNF- ${alpha}$ , IL-6, IL-12-p70, KC (CXCL1), MIP-2(CXCL2), MCP-1 (CCL2), RANTES (CCL5), and MCP-5 (CCL12). Basal-levelsecretion of chemokine MCP-1 (CCL2) by Bm1.11 cells exceededthe capacity of the multiplex ELISA (data not shown). Per themanufacturer, sensitivity of the assay for individual cytokinesranged from 0.2 to 2.7 pg/ml.

Analysis of cytokine data. To permit semiquantitative comparisons of cytokine mRNA levels,all cytokines detected by RPA were quantified by densitometry(Quantiscan software; Biosoft, Ferguson, Mo.). The resultingvalues were normalized to the untreated GAPDH probe band oneach gel, thereby adjusting for exposure differences betweenfilms. Northern blots were also quantified by densitometry.Determination that a cytokine had been upregulated by infectionwas defined as a more than threefold increase in intensity afternormalizing data for slight differences in loading as determinedby a parallel ß-actin blot (Fig. 3D). Like the RPA,all Northern blots were done with 5 x 10⁵ Bm1.11 cell equivalentsper lane, permitting at least crude comparisons of cytokinemRNA levels between the RPA and Northern blots. Multiplex ELISAdata are quantitative. Every cytokine upregulated by C. muridaruminfection was assigned a relative expression value of 1+ to4+ (low level to high level). The breakpoints for ELISA concentrations(in picograms/milliliter) and densitometry values (in arbitraryunits) are depicted in Table 2.

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FIG. 3. RPA analysis of Bm1.11 cell cytokine responses to C. muridarum infection. On all gels the leftmost lane (P) is the untreated probe set. ³²P RNA probes that detected mRNA transcripts are further labeled with diagrammatic bars. Asterisks on the right of each panel highlight the protected RNA fragments indicated by the bars on the left. Y, control hybridization with yeast tRNA. 0, 12, 18, and 24 represent the time course of C. muridarum infection in hours. Data presented are representative of three independent experiments with each probe set showing the same results.

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TABLE 2. ELISA break points and densitometry values

Cytokines analyzed by both ELISA and RPA were used to crudelystandardize the results of the two techniques. ELISA breakpointswere empirically chosen based on the desire to have an expressionscale range of 1+ to 4+. The ELISA breakpoints were then usedto set the breakpoints for the RPA such that the RPA and ELISAdata gave the same 1+ to 4+ score for each cytokine analyzedby both techniques. RPA chemokine breakpoints differ from thecytokine breakpoints, because chemokine mRNA levels were 10to 20 times higher than that of any nonchemokine cytokine. Adifferent set of chemokine breakpoints was therefore neededto reflect the spectrum of chemokine expression levels. As inany large survey of cytokines based on mRNA quantification,the results presented here are open to the criticism that mRNAlevels do not necessarily reflect relative levels of secretedcytokines due to differences in mRNA stability (62), RNA translationefficiency (23), and efficiency of secretion. Furthermore, relativeprotein levels of individual cytokines do not address theirrelative biologic potency, much less how cytokine biologic activitiesmay be altered in a complex cytokine milieu. These considerationsaside, it is useful to apply reasonable assumptions and attemptto analyze cytokine survey data for the purpose of generatinghypotheses to drive future experimentation.

RESULTS

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Results

Characterization of an oviduct epithelial cell line. A primary murine oviduct cell line designated Bm1.11 was derivedto study the epithelial cytokine response to infection in theabsence of leukocytes and nonepithelial stroma. Murine epithelialcells have several properties that are not shared by other murinestromal cell types, including expression of cytokeratins andIFN- ${gamma}$ -inducible expression of MHC class II genes. Figure 1 showsBm1.11 expression of cytokeratins by immunohistochemistry andmarked upregulation of MHC II expression with IFN- ${gamma}$ treatment.Expression of the I-A^b ${alpha}$ chain was confirmed by RT-PCR (Fig.2). IFN- ${gamma}$ treatment of CL.7, a murine fibroblast cell line, didnot induce MHC II expression (data not shown).

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FIG. 1. Characterization of oviduct epithelial cell line Bm1.11. (A) Bm1.11 cells grown in chamber slides were fixed and stained with irrelevant monoclonal antibody 36-7-5 specific for H-2K^k (Bm1.11 cells are H-2K^bm1). (B) Bm1.11 cells stained with the monoclonal antibody cocktail AE1/AE3 specific for acidic and basic cytokeratins. Cell nuclei in panels A and B were visualized by staining with 4',6'-diamidino-2-phenylindole. (C) Flow cytometry analysis of cell surface levels of MHC II without treatment and after 14 h of exposure to 10 ng of recombinant murine IFN- ${gamma}$ /ml. Control refers to autofluorescence. PE, phycoerythrin.

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FIG. 2. Detection of I-A^b ${alpha}$ chain mRNA in Bm1.11 cells exposed to 10 ng of IFN- ${gamma}$ /ml for 14 h. MW designates the lane of the 100-bp molecular size ladder. +RT, RT-PCR containing RT; –RT, control reaction lacking RT.

Chlamydia infection induces multiple inflammatory cytokines. Multiprobe RPA were chosen for initial analysis of the epithelialcytokine response to infection by C. muridarum, because thetechnique yields quantitative data on multiple gene transcriptswithout risk of amplification artifacts. Wells of Bm1.11 cellswere infected with 10 IFU of C. muridarum/cell in a staggeredfashion such that simultaneous harvest of multiple wells gavetime points for mock infection (0 h) and for infection at 12,18, and 24 h (Fig. 3). RPA analysis revealed infection-associatedinduction of mRNA for TNF- ${alpha}$ , IL-6, IFN-ß, IL-12-p35,IL-12-p40, IL-1 ${alpha}$ , IFN- ${alpha}$ , MIP-2 (CXCL2), and TCA-3 (CCL1) and infection-associatedupregulation of IL-7, TGF ${alpha}$ , IL-15, IL-3, RANTES (CCL5), IP-10(CXCL10), and MCP-1 (CCL2). Transcription of housekeeping genesL32 and GAPDH was not affected by infection, nor were mRNA levelsof TGFß1, MIF, and IL-11. Interestingly, levels ofTGFß2 and TGFß3 mRNA were reproducibly decreasedin response to C. muridarum infection.

Commercially available RPA probe template sets for murine cytokinesare relatively limited; therefore, RT-PCR was used to broadenthe analysis of the chemokine response of oviduct epithelialcells to infection by C. muridarum. Primers pairs were designedfor the inducible chemokines MARC (CCL7), MCP-5 (CCL12), ABCD-1(CCL22), Mig (CXCL9), CXCL16, and CX3CL1. RT-PCR products forMARC (CCL7), MCP-5 (CCL12), Mig (CXCL9), CXCL16, and CX3CL1were detected in Bm1.11 cells infected for 18 h with C. muridarumat 10 IFU/cell (data not shown). No RT-PCR products were detectedfor ABCD-1 (CCL22) (Fig. 4).

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FIG. 4. Absence of ABCD-1 (CCL22) mRNA in infected Bm1.11 cells. RT-PCR assays for ABCD-1 and Mig (CXCL9) were performed on total RNA isolated from Bm1.11 cells infected with C. muridarum for 18 h and activated peritoneal macrophages (Activated MACS) as a positive control. Asterisks mark the specific RT-PCR products for each primer pair. There is a spurious PCR band (280 bp) in the ABCD-1 (220 bp) RT-PCR that is present in both activated peritoneal macrophages and infected Bm1.11 cells (see Materials and Methods). Mig, a low-level transcript in infected epithelial cells, is readily detected in infected Bm1.11 cells by using the same RNA samples. Data are representative of three independent experiments showing the same result.

To get quantitative data on the levels of MARC (CCL7), Mig (CXCL9),CXCL16, and CX3CL1, Northern blot analysis was performed onBm1.11 cells mock infected or infected with C. muridarum for12, 18, and 24 h. RT-PCR products for MARC (CCL7), Mig (CXCL9),CXCL16, and CX3CL1 were gel purified, cloned, and sequencedto confirm identity. Cloned gene fragments for each chemokinewere then used as templates to make digoxigenin-labeled probesfor Northern blot analysis. Representative Northern blots fromtwo independent time course experiments are shown in Fig. 5.C. muridarum infection of Bm1.11 cells induced very modest levelsof Mig (CXCL9) mRNA and robust levels of MARC (CCL7) and CXCL16mRNA. Very low levels of CX3CL1 mRNA are present constitutivelyand were not upregulated by Chlamydia infection. MCP-5 (CCL12)levels were determined by multiplex ELISA (see below).

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FIG. 5. Northern blot analysis of additional chemokines induced by C. muridarum infection. (A) Mig (CXCL9), 1,284 bp; (B) MARC (CCL7), 777 bp; (C) CX3CL1, 3,095 bp; (D) CXCL16, 1,375 bp. The higher-molecular-mass band is likely a splicing precursor of CXCL16. (E) ß-actin, 1,892 bp. 0, 12, 18, and 24 represent the time course of C. muridarum infection in hours. Data presented are representative of two independent experiments for each chemokine showing the same result.

To further characterize the cytokine response and confirm secretionof cytokines detected by RPA, time course experiments were repeatedto generate cell culture supernatants for analysis by multiplexELISA. Cell culture supernatants from Bm1.11 cells mock infectedor infected with C. muridarum at 10 IFU/cell for 6, 12, 18,24, and 36 h were collected and analyzed for GM-CSF, TNF- ${alpha}$ , IL-6,IL-12-p70, KC (CXCL1), MIP-2 (CXCL2), RANTES (CCL5), and MCP-5(CCL12). Results of two independent experiments are presentedin Table 3.

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TABLE 3. Results of time course experiments

Summary of cytokine data. RNA levels determined by RPA have previously been shown to correlatewell with protein levels in other experimental systems (26,38). In this report, there was good agreement between mRNA transcriptlevels detected by RPA and the amount of protein detected inculture supernatants by ELISA for all cytokines [TNF- ${alpha}$ , IL-6,IL-12-p70, RANTES (CCL5), and MIP-2 (CXCL2)] analyzed by bothtechniques (compare Fig. 3 and Table 3). There was also goodagreement between the time course of mRNA induction and theappearance of a specific cytokine in the culture medium. Earlytranscription of IL-6 mRNA correlated with detectable IL-6 inthe ELISA by 6 h postinfection. In contrast, later inductionof transcripts for TNF- ${alpha}$ and IL-12 were reflected by delays indetection of these cytokines out to 18 and 24 h in the ELISA.No mRNA was detected for TNF-ß, lymphotoxin ß,IFN- ${gamma}$ , IL-1ß, IL-4, IL-5, IL-10, IL-13, IL-9, IL-2,lymphotactin, MIP-1 ${alpha}$ , MIP-1ß, eotaxin (CCL11), andABCD-1 (CCL22). Figure 6 is a semiquantitative summary of allcytokines upregulated by oviduct epithelial cells in responseto infection by C. trachomatis based on the algorithm describedin Materials and Methods. This type of analysis ignores potentialdifferences in mRNA stability, efficiency of translation, andcytokine potency but provides a useful starting point for discussingresults of a large cytokine survey.

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FIG. 6. Summary of Bm1.11 oviduct epithelial cell cytokine responses to infection by C. muridarum. Expression levels of cytokines upregulated by C. muridarum infection were graded on a scale of 1+ to 4+ (low to high) as described in Materials and Methods. Relative expression levels are reflected by type sizes within the figure, with 4+ represented by the largest type size [e.g., MARC (CCL7)], 3+ represented by the second-largest type size (e.g., CXCL16), 2+ represented by the second-smallest type size (e.g., TNF- ${alpha}$ ), and 1+ indicated by the smallest type size (e.g., IL-3). PMN, polymorphonuclear cell; Eos, eosinophil.

DISCUSSION

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Discussion

To facilitate understanding of the multifaceted oviduct epithelialresponse to C. muridarum infection, cytokines induced by infectionwith respect to their predicted biological effects are discussedbelow. The first panel of Fig. 6 depicts the predicted roleof Chlamydia-infected epithelial cells in leukocyte recruitmentbased on their cytokine response. Chemokines are critical cytokinesfor leukocyte recruitment (52). Bm1.11 cells infected by C.muridarum transcribed a plethora of chemokines, including myeloid-activechemokines KC (CXCL1), MIP-2 (CXCL2), MCP-1 (CCL2), MARC (CCL7),and MCP-5 (CCL12) that are important in neutrophil, monocyte/macrophage,and dendritic cell recruitment, and RANTES (CCL5), a chemokineinvolved in recruitment of monocyte/macrophage and dendriticcells. NK cell and lymphocyte-active chemokines upregulatedby infection included TCA-3 (CCL1), RANTES (CCL5), MARC (CCL7),Mig (CXCL9), IP-10 (CXCL10), and CXCL16. Eotaxin (CCL11), thedominant chemokine for eosinophil recruitment (29), was notdetected. Additional cytokines detected that have roles in leukocyterecruitment included IL-15, an important T-cell growth factorthat also serves as a chemoattractant for T lymphocytes (70),and IL-1 ${alpha}$ and TNF- ${alpha}$ , which play indirect roles in leukocyte recruitmentby upregulating ICAM-1, E-selectin, and VCAM-1 on adjacent endothelia(41). Recruitment of neutrophils, monocytes, and lymphocyteswithout recruitment of eosinophils is consistent with the histologyseen in humans with C. trachomatis salpingitis (17, 47).

Cytokines released at sites of infection trigger antimicrobialactivity in NK cells, T cells, and phagocytes. The second panelof Fig. 6 depicts the predicted effects of infected epithelialcells on local leukocyte activation and homeostasis. Bm1.11cells infected by C. muridarum secreted TNF- ${alpha}$ , a major activatorof neutrophils within infected tissues. TNF- ${alpha}$ , IL-1 ${alpha}$ , and GM-CSFmade by infected epithelial cells would activate macrophagesand trigger dendritic cell maturation. IFN- ${alpha}$ /ß increasethe cytolytic function of NK cells and T cells (10). IL-15 cantrigger NK killing (34). IL-6 is an important cytokine in cytotoxicT-cell differentiation (46, 51).

Growth factors for T cells and macrophages released at the sitesof infection may affect homeostasis by counteracting apoptoticor anergizing stimuli, thereby prolonging functional immuneresponses at sites of infection (21, 49, 59, 75) and possiblycontributing to local expansion of effector cells (1). C. muridarum-infectedepithelial cells expressed or secreted IL-3 and GM-CSF, growthfactors for neutrophils and monocytes/macrophages, and upregulatedtranscription of IL-7 and IL-15, growth factors for T lymphocytesand NK cells. Anergy is a major theoretical barrier for T lymphocytesresponding to infection, because epithelial cells do not expressthe CD28 ligands CD80 and CD86 (reviewed in reference 42). However,cytokines have been demonstrated to provide alternative costimulatorysignals capable of substituting for the classic costimulatorysignal delivered through CD28. Naïve CD4 T cells use IL-1as an alternative costimulatory signal, while naïve CD8T cells use IFN- ${alpha}$ /ß (15). C. muridarum-infected oviductepithelial cells make IL-1 ${alpha}$ and IFN- ${alpha}$ /ß, thereby potentiallymaking up for their perceived antigen presentation deficienciesrelated to lack of CD80 and CD86 expression.

The host immune response to urogenital infections by C. trachomatisis dominated by IFN- ${gamma}$ in animal models and human infections (48).The third panel of Fig. 6 shows the predicted effects of infectedepithelial cells on T-lymphocyte cytokine polarization. Thedata presented in this report suggest that Chlamydia-infectedoviduct epithelial cells could facilitate IFN- ${gamma}$ production throughthree different mechanisms. The first would be through expressionof chemokines that preferentially recruit T_h1 over T_h2 lymphocytes.C. muridarum-infected Bm1.11 cells induced or upregulated transcriptionof chemokines Mig (CXCL9), IP-10 (CXCL10), and CXCL16 that selectivelyrecruit T_h1 lymphocytes bearing CXCR3 and CXCR6 receptors (8,33, 60). CXCR6, the receptor for CXCL16, is highly expressedon intraepithelial lymphocytes (43), consistent with a rolein the reproductive tract mucosal immune compartment. To myknowledge this is the first report suggesting a role for CXCL16in host defense against Chlamydia infections. RANTES (CCL5),the chemokine ligand for CCR5, also preferentially favors T_h1recruitment based on its receptors' relative distribution onT_h1 and T_h2 lymphocytes (8, 60). The only T_h2-selective chemokinetranscribed by infected Bm1.11 cells was TCA-3 (CCL1). TCA-3(CCL1) is the ligand for CCR8 on T_h2 cells, and T_h2-selectivechemotaxis has been demonstrated in vitro (76). However, therole of CCR8 in recruitment of T_h2 cells within a complex ofin vivo T_h2 cytokine milieu is unclear (7). The other importantT_h2 chemokine receptors are CCR3 and CCR4. Infected Bm1.11 cellsdid not transcribe mRNA for the CCR3 ligand eotaxin (CCL11)or the CCR4 ligand ABCD-1 (CCL22). The other CCR4 ligand isTARC. We did not detect mRNA for TARC in infected oviduct epithelialcells by RT-PCR but have not rigorously excluded its presence,lacking an adequate positive control (data not shown). TARCis not likely to be made by infected oviduct epithelial cells,as it is selectively produced by activated myeloid dendriticcells and Langerhans cells (2). The chemokine data presentedhere would predict that Chlamydia-infected epithelium in vivowould favor recruitment of T_h1 over T_h2 lymphocytes.

A second mechanism for facilitating IFN- ${gamma}$ production would bethrough IFN- ${alpha}$ and IFN-ß. Infected Bm1.11 cells expressedIFN- ${alpha}$ and IFN-ß. IFN- ${alpha}$ /ß facilitate IFN- ${gamma}$ productionby activating CD8 T cells through an IL-12 independent pathway(50). Conversely, IFN- ${alpha}$ /ß are known to downmodulateIL-12 production by dendritic cells (6). The latter effect wouldpresumably be counterbalanced by epithelial secretion of IL-12.

The third and potentially most important mechanism is IL-12-p70secretion by infected oviduct epithelial cells. Surprisingly,C. muridarum-infected Bm1.11 cells transcribed both chains,IL-12-p35 and IL-12-p40, of the IL-12-p70 heterodimer and secretedIL-12-p70 into culture supernatants. IL-12-p70 is the principlemediator of cytokine polarization in vitro and in vivo, actingdirectly on T cells and NK cells to enhance IFN- ${gamma}$ production.While IL-12-p35 is made constitutively by many cell types, IL-12-p70secretion is classically the exclusive domain of macrophagesand dendritic cells (67). The finding of IL-12-p70 secretionby infected epithelial cells was surprising and suggests theremay be redundant sources of IL-12-p70 locally during genitaltract Chlamydia infections. The biology of IL-12 is complex,as the binding of the bioactive IL-12-p70 heterodimer by theIL-12 receptor is antagonized by IL-12-p40 homodimers (22, 31).At the same time, there is evidence that IL-12-p40 plays animportant role in host defense against microbes that is independentof IL-12-p70 (18, 27, 36). In this report, RPA analysis showedroughly balanced mRNA levels for IL-12-p35 and IL-12-p40 at24 h postinfection. Assessment of IL-12-p40 homodimer proteinlevels in infected cell supernatants was not done.

Immunopathologic scarring of the Fallopian tubes is a clinicallyimportant aspect of human urogenital infections caused by C.trachomatis. The fourth panel of Fig. 6 illustrates the predictedrole of infected epithelial cells in scarring. C. muridarum-infectedoviduct epithelial cells transcribed TGF ${alpha}$ , TNF- ${alpha}$ , and large quantitiesof IL-1 ${alpha}$ and IL-6. These cytokines have been associated withscarring and fibrosis in animal models and humans (37, 40, 55,74), raising the possibility that Chlamydia-infected epithelialcells directly contribute to scarring of the Fallopian tubes.TGFß family members have been strongly associatedwith scarring (28). Interestingly, in Bm1.11 cells TGFß2and TGFß3 were reproducibly downregulated by C. muridaruminfection. The data presented here raise the possibility thatTGF ${alpha}$ rather than TGFß is the cytokine driving the scarringseen during C. trachomatis infections. TGF ${alpha}$ is translated asa transmembrane glycoprotein known as a TGF ${alpha}$ precursor. TGF ${alpha}$ precursorRNA levels at 24 h postinfection were upregulated fourfold (normalizedto GAPDH housekeeping gene transcript) compared to that forthe mock-infected epithelial cell control (Fig. 3). TGF ${alpha}$ precursoris cleaved by cell surface proteases, releasing TGF ${alpha}$ . Both TGF ${alpha}$ precursor and TGF ${alpha}$ are biologically active. Selective overexpressionof TGF ${alpha}$ in the lungs of transgenic mice causes fibrosis and dilationof the airways (24). There are no commercial sources for recombinantmurine TGF ${alpha}$ or antibodies to murine TGF ${alpha}$ . Within the 50 aminoacids of TGF ${alpha}$ there are 4 amino acid differences between humanand mouse TGF ${alpha}$ . To our knowledge, there are no published studiessuccessfully using anti-human TGF ${alpha}$ immunoreagents to study murineTGF ${alpha}$ . We are generating mouse TGF ${alpha}$ immunoreagents to address therole of TGF ${alpha}$ precursor and TGF ${alpha}$ in scarring. Other cell types,such as T_h3 lymphocytes, tissue macrophages, or nonepithelialstromal components, could still serve as sources of TGFß.

Infected Bm1.11 oviduct epithelial cells have a unique cytokinesignature. Analysis of cytokines within genital secretions ofinfected mice reflects all cell types participating in the inflammatoryresponse. Genital secretions of mice infected with C. muridarumhave detectable levels of IL-1ß, IL-6, GM-CSF, andMIP-2 (CXCL2) by ELISA (16). Infected Bm1.11 oviduct epithelialcells in this report secreted IL-6, GM-CSF, and MIP-2 (CXCL2),but no mRNA for IL-1ß was detected by RPA analysis,suggesting that leukocytes or other stromal components are thesource of IL-1ß. Semiquantitative RT-PCR has shownincreased IL-11 mRNA levels in genital tract homogenates frommice infected with C. muridarum (19). A less than twofold increasein basal transcription of IL-11 was seen in infected Bm1.11cells (Fig. 3B), suggesting that other cell types or epithelialcells lower in the reproductive tract are the source of IL-11mRNA in vivo. IL-11 is an antiinflammatory cytokine that antagonizesIL-12, TNF- ${alpha}$ , and IL-1 production by macrophages (66) and influencesCD4 T-cell polarization toward a T_h2 phenotype (9). Chemokineanalyses of the upper and lower reproductive tracts of miceinfected by C. muridarum have been performed. IP-10 (CXCL10),Mig (CXCL9), and RANTES (CCL5) were the predominant chemokinesinduced in the upper reproductive tract by infection; modestamounts of eotaxin (CCL11) were seen during the resolution phaseof the infection (44). Bm1.11 oviduct epithelial cells in thisreport upregulated expression of RANTES (CCL5), Mig (CXCL9),and IP-10 (CXCL10) during infection, though Mig (CXCL9) inductionwas modest. Maxion and Kelly (44) defined the sources of IP-10(CXCL10) within the upper tract by immunohistochemistry showingstaining of columnar epithelial cells, endothelial cells, andstromal cells.

Cytokine profiles of dendritic cells pulsed with heat-inactivatedC. muridarum elementary bodies have been investigated with RPA.C. muridarum-pulsed dendritic cells upregulated several cytokinesnot seen in C. muridarum-infected oviduct epithelial cells,including MIP-1 ${alpha}$ (CCL3), MIP-1ß (CCL4), and IL-1ß.Conversely, C. muridarum-infected Bm1.11 cells expressed TCA-3(CCL1), a chemokine not detected in C. muridarum-pulsed dendriticcells. Among the cytokines investigated for both cell types,infected oviduct epithelial cells and Chlamydia-pulsed dendriticcells shared IL-1 ${alpha}$ , IL-6, IL-12-p40, TNF- ${alpha}$ , RANTES (CCL5), MIP-2(CXCL2), MCP-1 (CCL2), and IP-10 (CXCL10) (63).

The spectrum of inflammatory cytokines made by the Bm1.11 oviductepithelial cell line was somewhat surprising in light of previouswork with human HeLa and HEC-1-B cell lines. Those studies identifiedthe principle cytokines induced by Chlamydia infection to beIL-1 ${alpha}$ , IL-1ß, IL-6, IL-8, IL-11, IL-16, IL-18, GM-CSF,Gro ${alpha}$ (CXCL1), ENA-78 (CXCL5), and GCP-2 (CXCL6). Murine Bm1.11cells infected by C. muridarum initiated or enhanced transcriptionand/or secretion of IL-1 ${alpha}$ , IL-3, IL-6, IL-7, IL-12, IL-15, IFN- ${alpha}$ ,IFN-ß, TNF- ${alpha}$ , TGF ${alpha}$ , GM-CSF, KC (CXCL1), MIP-2 (CXCL2),TCA-3 (CCL1), MCP-1 (CCL2), RANTES (CCL5), MARC (CCL7), MCP-5(CCL12), Mig (CXCL9), IP-10 (CXCL10), and CXCL16. The spectrumof cytokines made by Bm1.11 cells infected with C. muridarumencompassed all mutually investigated cytokines previously documentedin the human HeLa and HEC-1-B cells, with the exception of IL-1ßand IL-11.

The broader spectrum of cytokines made by the Bm1.11 oviductcell line may reflect differences in the Chlamydia serovarstested, differences between mice and humans, or differencesbetween cell and tissue types. HeLa cells and HEC-1-B cellsare carcinomas that originated in the cervix and uterus, respectively.Epithelium lining the cervix and uterus may have a differentbiology than epithelium lining the oviducts. This could explaindifferences such as IL-11 upregulation in infected HeLa cellsbut not in infected Bm1.11 cells. An additional possibilityis that the process of transformation and evasion of host tumorimmunosurveillance has changed the biology of HeLa and HEC-1-Bcells. HeLa cells contain multiple integrated copies of humanpapillomavirus 18 and actively transcribe human papillomavirusgenes (56).

The oviduct epithelial data presented here support the hypothesisthat oviduct epithelial cells contribute directly to innateand adaptive immunity during C. trachomatis infections. Theepithelial contributions to host defense include recruitingleukocytes and facilitating production of IFN- ${gamma}$ critical forcontrolling Chlamydia infections, but epithelial cytokines suchas TGF ${alpha}$ may contribute to detrimental scarring associated withthe infection.

ACKNOWLEDGMENTS

I gratefully acknowledge Roger Rank and Stanley Spinola fortheir thoughtful comments during preparation of the manuscript,Darron Brown for assistance with immunohistochemistry, ThomasWeinzerl for graphics assistance with Fig. 6, and Barbara Vander Pol at the Indiana University Chlamydia Laboratory for McCoycells and C. muridarum.

This work was supported by grant 1K08AI52128-01 from the NationalInstitute of Allergy and Infectious Diseases.

FOOTNOTES

* Mailing address: Division of Infectious Diseases, Department of Medicine, Indiana University School of Medicine, 545 Barnhill Dr. #435, Indianapolis, IN 46202. Phone: (317) 278-6968. Fax: (317) 274-1587. E-mail: raymjohn{at}iupui.edu.

Editor: J. D. Clements

REFERENCES

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