Campylobacter jejuni Induces Maturation and Cytokine Production in Human Dendritic Cells

Campylobacter jejuni is a leading bacterial cause of human diarrhealdisease in both developed and developing nations. Colonic mucosalinvasion and the resulting host inflammatory responses are thoughtto be the key contributing factors to the dysenteric form ofthis disease. Dendritic cells (DCs) play an important role inboth the innate and adaptive immune responses to microbial infection.In this study, the interaction between human monocyte-deriveddendritic cells and C. jejuni was studied. We found that C.jejuni was readily internalized by DCs over a 2-h period. However,after a prolonged infection period (24 or 48 h) with C. jejuni,only a few viable bacteria remained intracellularly. Minimalcytotoxicity of C. jejuni to dendritic cells was observed. C.jejuni induced the maturation of dendritic cells over 24 h,as indicated by up-regulation of cell surface marker proteinsCD40, CD80, and CD86. In addition, Campylobacter-infected DCstriggered activation of NF- ${kappa}$ B and significantly stimulated productionof interleukin-1ß (IL-1ß), IL-6, IL-8, IL-10,IL-12, gamma interferon, and tumor necrosis factor alpha (TNF- ${alpha}$ )compared to uninfected DCs. Active bacterial invasion of DCswas not necessary for the induction of these cytokines, as heat-killedC. jejuni stimulated similar levels of cytokine production aslive bacteria. Purified lipooligosaccharide of C. jejuni appearsto be the major stimulant for the increased production of cytokinesby DCs. Taken together, these data indicate that during infection,Campylobacter triggers an innate inflammatory response throughincreased production of IL-1ß, IL-6, IL-8, and TNF- ${alpha}$ and initiates a Th1-polarized adaptive immune response as predictedfrom the high level of production of IL-12.

INTRODUCTION

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Introduction

Campylobacter jejuni is a spiral, gram-negative, microaerophilicbacterium. This pathogen is a leading bacterial cause of humandiarrheal disease throughout the world. In the United States,about 2 million cases of diarrhea per year are caused by C.jejuni. Illness caused by C. jejuni is characterized by fever,headache, abdominal cramping, diarrhea, and the presence oferythrocytes and leukocytes in the stool (4, 5). Two to 3 weekspostinfection, C. jejuni is sometimes associated with the extraintestinalmanifestations of Guillain-Barré syndrome or reactivearthritis (43). The pathogenic mechanisms of C. jejuni are notyet well understood. In developing countries, C. jejuni triggersprimarily a noninflammatory, watery diarrhea. However, in developedcountries infection via bacterial invasion of the colonic mucosais thought to lead to intestinal inflammation and microulcerationof the colonic mucosa. As is the case with shigellosis, theacute host inflammatory responses are thought to contributeheavily to disease pathogenesis (reviewed in reference 22).

Dendritic cells (DCs) play important roles in both the innateand adaptive immune responses to microbial pathogens. They arethe major antigen-presenting cells (APCs) and are widely distributedin tissues, including the intestinal mucosa (reviewed in references26, 32, 53). Dendritic cells regulate the type of T-cell-mediatedimmune response to an offending agent and are also a sourceof proinflammatory cytokines. They are the only cells that areable to initiate proliferation in naïve T cells, therebyinducing the primary immune response and permitting the establishmentof immunological memory.

Immature DCs can capture antigens by phagocytosis, macropinocytosis,and endocytosis (17, 37, 38). Exposure of DCs to inflammatorystimuli converts these cells from antigen-capturing immatureDCs to antigen-presenting mature DCs. This process is accompaniedby up-regulation of major histocompatibility complex (MHC) classI and II molecules, costimulatory receptors, and adhesion molecules(2, 7, 11). Once a DC has captured an antigen, its ability tocapture additional antigens rapidly declines. The process ofdifferentiation from an immature DC into a mature professionalAPC can be induced by whole bacteria, their components, or cytokinesas well as other inflammatory stimuli and infectious agents.Upon activation, DCs migrate from the inflammatory site intothe lymphoid tissues, such as the lymph nodes and spleen, down-regulatetheir phagocytic ability, and up-regulate their antigen-presentingcapacity (2).

Numerous studies have shown that DCs play an important rolein the host-pathogen interaction during infection with entericpathogenic bacteria. For example, DCs that phagocytose Salmonellaenterica serovar Typhimurium can process and present bacterialantigens and produce cytokines that are critical to the immuneresponse (25, 56). Helicobacter pylori also induces maturationand cytokine release from human DCs (24). Shigella flexneriinfection of DCs leads to up-regulation of interleukin-1ß(IL-1ß) and IL-18 and rapid DC death (8). In contrast,Yersinia enterocolitica is able to invade DCs and does not inducenecrosis or apoptosis but impairs DC function (40).

During infection, Campylobacter can invade and traverse theepithelial barrier and comes into contact with numerous leukocytes(49, 50). In addition, DCs are capable of traversing the tightjunctions of the intestinal mucosa, which enables them to interactdirectly with bacteria on the mucosal surface (35, 39). Althoughthe infection of macrophages by C. jejuni has been studied previously(14, 19, 20, 42, 44, 51), Campylobacter's interaction with DCshas not been reported to date. Understanding the interactionbetween DCs and C. jejuni will provide insight into the roleof DCs in stimulating Campylobacter-induced inflammatory pathologyand in controlling the infection. The goal of this work wasto study the interaction between human DCs and C. jejuni withrespect to DC activation and induction of a number of cytokinesknown to be involved in both the innate and adaptive immuneresponses.

MATERIALS AND METHODS

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Materials and Methods

Bacterial strains and culture conditions. Campylobacter jejuni strain 81-176, obtained following a diseaseoutbreak in Minnesota, has been shown to cause colitis in twohuman challenge studies (4, 23; D. Tribble et al., unpublisheddata). C. jejuni 81-176 and its mutant RY213 (a cheY⁺ diploid)that is noninvasive (55), as well as the genome-sequenced C.jejuni NCTC 11168 (33), were grown in Mueller-Hinton (M-H) biphasicbroth or on M-H agar (Difco) at 37°C under a Campylobactergas atmosphere of 10% carbon dioxide, 5% oxygen, and 85% nitrogen(16).

Preparation of human monocyte-derived dendritic cells. Mononuclear cells were obtained by apheresis of normal volunteerdonors as performed by the Blood Services Section of the Departmentof Transfusion Medicine at the National Institutes of HealthWarren G. Magnuson Clinical Center (Bethesda, MD). The mononuclearcells were further enriched for monocytes by centrifugal elutriationas performed by the Cell Processing Section of the Departmentof Transfusion Medicine. Similar to the work of Pickering etal. (34), the elutriated monocytes were then cultured (1 x 10⁶/well)in six-well tissue culture plates with 3 ml/well of RPMI 1640medium (Mediatech, Inc., Herndon, VA) containing 5% human ABserum (Nabi, Miami, FL), 800 U/ml granulocyte-macrophage colony-stimulatingfactor (GM-CSF; Peprotech, Rocky Hill, NJ), and 500 U/ml IL-4(Peprotech). The nonadherent and loosely adherent cells wereharvested after incubating the plates for 6 days at 37°Cin 5% CO₂. The cells were centrifuged for 10 min at 1,200 rpmin a Beckman GS-6KR centrifuge and then plated in 96- (50,000cells/well) or 6-well plates (10⁶ cells/well) containing freshRPMI (Mediatech) with 5% human AB serum (Nabi) and 800 U/mlGM-CSF (Peprotech). This resulted in the generation of immaturemonocyte-derived dendritic cells that were positive for CD11cbut negative for CD14 (data not shown).

Infection of DCs. C. jejuni was added to the cultured DCs at different multiplicitiesof infection (MOIs). Bacterium-DC interactions were initiatedby centrifugation at 1,000 rpm in a Beckman GS-6KR centrifugefor 5 min, followed by incubation at 37°C in 5% CO₂. Forassessment of the number of intracellular bacteria, 2 x 10⁵infected DCs/well in 24-well plates were cultured for 2, 4,24, and 48 h. After the 4-h time point, gentamicin (20 µg/ml)was added to inhibit the growth of extracellular bacteria (19).At the specified time points (2, 4, 24, and 48 h), cells werewashed three times with RPMI 1640, followed by incubation ofDCs for 2 h in fresh medium including 100 µg/ml gentamicinto kill any remaining extracellular bacteria. The infected monolayerswere then washed three times to remove the gentamicin. The DCswere lysed with 0.1% Triton X-100 in phosphate-buffered saline(PBS) for 15 min. Following serial dilutions in PBS, the viableinternalized bacteria were enumerated by plate count on M-Hagar. For cytokine measurements, the infected culture supernatantsin 96-well plates were harvested, centrifuged, and frozen at–80°C prior to analysis (12, 34).

In control studies, 100 µg/ml gentamicin was found tokill all extracellular bacteria within 2 h. The MIC of gentamicinat which 50% of the C. jejuni 81-176 organisms were inhibitedwas $~$ 6.25 µg/ml for C. jejuni 81-176. At 20 µg/mlof gentamicin, we found that extracellular C. jejuni could notmultiply in cell culture medium. We used 20 µg/ml gentamicinto block any extracellular growth of released C. jejuni overlonger periods (i.e., 24 to 48 h), because higher antibioticconcentrations over long periods can leak into the host cellsand cause death of some intracellular bacteria.

Cell cytotoxicity assay. The CytoTox 96 assay (Promega, Madison, WI) was used to determinehost cell cytotoxicity over time induced by bacterial preparationsthat were added to the DCs. This assay qualitatively measuressupernatant lactate dehydrogenase (LDH), a stable cytosolicenzyme that is released upon cell lysis. The DC number was evaluatedvia the assay instructions and determined to be optimal at 50,000cells/well. The ratios of effector cells to bacteria used toassess host cell cytotoxicity were 1:1, 1:10, 1:20, and 1:100.Supernatants were collected following centrifugation at 4, 24,and 48 h postinfection with C. jejuni 81-176. Maximum LDH releasewas determined by measuring the amount of LDH release from uninfectedDCs that were treated with lysis buffer. The percentage of cytotoxicitywas calculated according to the following formula (OD is anabbreviation for optical density): [(OD_sample) – (OD_medium/OD_max_{LDH release}) – OD_{adjusted medium}] x 100.

Cytokine measurement of DC supernatants by Luminex assay. Immature DCs were incubated in 96-well plates (5 x 10⁴ DCs/well)for 4, 24, and 48 h with live C. jejuni 81-176, heat-killed(i.e., 70°C for 30 min) C. jejuni 81-176, lipooligosaccharide(LOS) of C. jejuni 81-176 (extracted by using the hot phenol-watertechnique [52]), or hot phenol-water-extracted lipopolysaccharide(LPS) of Escherichia coli (Sigma, St. Louis, MO). PBS (InvitrogenCorporation)-incubated DCs served as unstimulated controls.Cytokine assays were performed by using human cytokine 10-plexand IL-12p70 antibody bead kits (Biosource International, Camarillo,CA) and a Luminex 100 analyzer (Luminex Corporation, Austin,TX) for IL-1ß, IL-2, IL-4, IL-5, IL-6, IL-8, IL-10,IL-12, gamma interferon (IFN- ${gamma}$ ), tumor necrosis factor alpha(TNF- ${alpha}$ ), and GM-CSF. Cytokine data analysis was performed usingthe MasterPlex QT quantitation software (MiraiBio, Alameda,CA).

Flow cytometry. Flow cytometric analysis was performed in order to examine thecell surface maturation markers CD40, CD80, and CD86 in Campylobacter-infectedDCs. Dendritic cells were infected as described above. Maturationof DCs was determined at 24 and 48 h after infection with C.jejuni (MOI, 10) by checking the expression of the surface maturationmarkers by flow cytometry. Cell samples (5 x 10⁵ cells) wereincubated (20 min, 4°C) with 4% human AB serum (Nabi) inPBS (Invitrogen Corporation) to block nonspecific binding sitesand Fc receptors. The cells were washed via centrifugation (1,200rpm; 10 min) with fluorescence-activated cell sorter buffercontaining 0.2% bovine serum albumin (Sigma) and 0.1% sodiumazide (Sigma) in PBS (Invitrogen Corporation) and then incubated(45 min, 4°C) with anti-CD40 (5C3), anti-CD 80 (L307.4),or anti-CD86 (2331 [FUN-1]) fluorescein isothiocyanate-labeledantibody (1 µl; Becton Dickinson, San Jose, CA) or theisotype-matched (1 µl of immunoglobulin G1; X40) controlantibody (Becton Dickinson). After washing again, the cellswere resuspended in 0.5% paraformaldehyde (Sigma) in cold PBS(Invitrogen) and 0.1% sodium azide. The cell-associated immunofluorescencewas measured with a FACSCalibur flow cytometer (Becton DickinsonImmunocytometry Systems, San Jose, CA) and analyzed using CellQuestsoftware (B-D Biosciences).

NF- ${kappa}$ B transcription factor assay. The TransAM NF- ${kappa}$ B kit p65 (Active Motif, Carlsbad, CA) was employedto detect the activation of NF- ${kappa}$ B. At 4 h postinfection, thenuclear extracts were prepared as per the manufacturer's instructions.Protein concentrations were determined using a 2'-benzoyloxycinnamaldehydeprotein assay reagent kit (Pierce, IL). Nuclear extracts (10µg/ml) were added into each well of a 96-well plate andincubated with anti-p65, and NF- ${kappa}$ B concentrations were determinedspectrophotometrically per the kit instructions.

Statistical analysis. Results are presented as the mean ± standard error ofthe mean from three independently conducted assays. P valueswere calculated with Student's t test.

RESULTS

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Results

Viable intracellular bacteria in dendritic cells after C. jejuni infection. C. jejuni was added to DCs at MOIs of 1, 10, 20, and 100. Aftera 2-, 4-, 24-, or 48-h invasion period, followed by a 2-h gentamicin(100 µg/ml) treatment to kill all extracellular bacteria,the numbers of viable, intracellular Campylobacter were quantifiedby plate count after host cell lysis. At 2 and 4 h postinfection,the uptake was generally dose dependent, and higher doses ofbacteria led to greater levels of bacterial internalizationby DCs (Fig. 1). The average number of viable intracellularbacteria per DC was $~$ 1.5 bacteria/DC on average at 2 or 4 h atan MOI of 10 and increased about fourfold at an MOI of 100.By 24 or 48 h postinfection, however, the numbers of viableintracellular bacteria were dramatically reduced. For example,at an MOI of 100, only $~$ 1% of DCs contained one viable bacterium,with even less observed at 48 h. These data suggest that C.jejuni is internalized at early time points, but most intracellularbacteria are killed by 24 and 48 h postinfection. This assumptionis predicated on little or no cytotoxicity to DCs during bacterialinfection, which was studied next.

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FIG. 1. Measurement of viable intracellular bacteria in dendritic cells after C. jejuni infection. C. jejuni was added to DCs at MOIs of 1, 10, 20, and 100. After various invasion periods, the cells were washed three times, followed by an incubation of the DCs for 2 h in fresh medium containing 100 µg/ml gentamicin to kill any remaining extracellular bacteria. The data represent the mean ± standard deviation of duplicate wells from three independent assays. *, the number of viable intracellular bacteria had markedly decreased at 24 to 48 h and does not appear on this graph.

DC viability after infection with C. jejuni. To assess the viability over time of DCs following infectionwith C. jejuni, LDH release assays were performed using thesupernatants of both uninfected and infected cells. No significantdifferences in DC viability were detected at 4 and 24 h afterinfection at any bacterial MOI, in comparison to the uninfectedcontrols (Fig. 2). At 48 h postinfection, all infected DCs showeda minimal increase in cytotoxicity over the uninfected control.However, the 9.5% dead cells in the uninfected control at 48h was only doubled to $~$ 20% death in the infected DCs at the highestMOI. These data suggest that limited host cell cytotoxicitywas associated with both long infection times and higher MOIs.However, infection-induced DC death over 48 h was very limitedeven at the highest MOI.

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FIG. 2. DC viability after infection with C. jejuni 81-176. LDH in the supernatants of infected and uninfected DCs was sampled and measured at 4, 24, and 48 h after infection at various MOIs. The data are presented as means ± standard errors of the means from three separate experiments. The values are expressed as percent host cell cytotoxicity, relative to the uninfected cell control obtained by lysing uninfected DCs. The insert shows the data on an expanded scale for detailed comparison.

C. jejuni effects on DC maturation. To study the effects on DC maturation of Campylobacter infection,the expression of cell surface costimulatory molecules CD40,CD80, and CD86 was measured with flow cytometry. Compared touninfected cultures, C. jejuni-infected DCs showed increasedexpression of all three surface molecules at 24 h postinfection,as indicated by increased fluorescence intensity of DCs (Fig.3). The averaged mean fluorescence intensity measurements forCD40, CD80, and CD86 at 24 h in all three sets of control DCswere 12.52 ± 0.99, 7.01 ± 0.38, and 45.28 ±10.83, respectively. Infection with C. jejuni 81-176 significantlyincreased these maturation marker averaged mean fluorescenceintensity measurements to 21.66 ± 3.84 (P < 0.05),25.99 ± 10.83 (P < 0.01), and 96.16 ± 7.35(P < 0.005), respectively. As a positive control, purifiedE. coli LPS induced DC maturation similarly to that observedwith live C. jejuni (data not shown). These data show that C.jejuni infection stimulates an increase in the expression ofDC surface costimulatory molecules, which are indicators ofDC maturation.

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FIG. 3. Surface molecules of DCs as determined by flow cytometry 24 h after exposure to C. jejuni 81-176. The DCs were stained with fluorescence-conjugated monoclonal antibodies to human CD40, CD80, and CD86. Histograms depict the level of surface expression, and the value indicated on each histogram is the mean fluorescence intensity of the marker-specific antibody from one representative experiment of three different donors. Black histograms indicate the levels of fluorescence using isotype control antibodies, and the open histograms represent the cell surface molecule expression in infected or uninfected DCs.

C. jejuni infection induces the production of cytokines in human DCs. The kinetics and profile of cytokine secretion from human DCsduring Campylobacter infection were analyzed. Cell culture supernatantswere collected at 4, 24, and 48 h from uninfected DCs or afterinfection with strain 81-176 at different MOIs, and cytokinelevels were measured in multiplex bead assays. Campylobacterinfection of DCs induced enhanced production of IL-1ß,IL-6, IL-8, IL-10, IL-12, IFN- ${gamma}$ , and TNF- ${alpha}$ (Fig. 4) but not IL-2,IL-4, or IL-5 (data not shown).

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FIG. 4. Cytokine induction in human DCs by C. jejuni 81-176 at different MOIs. Culture supernatants were tested at 4, 24, and 48 h postinfection with C. jejuni 81-176 at an MOI of 10, 20, or 100 and compared to that of uninfected DCs. The release of IL-1ß, IL-6, IL-8, IL-10, IL-12, IFN- ${gamma}$ , and TNF- ${alpha}$ is shown (A, B, C, D, E, F, and G, respectively). Data are presented as the mean ± standard deviation of duplicate wells from three independent assays.

At 4 h postinfection with C. jejuni at an MOI of 10, the titersof IL-6, IL-8, and TNF- ${alpha}$ were increased $~$ 29-fold (837.80 ±83.00 pg/ml), 34-fold (1,073.70 ± 282.90 pg/ml), and1,959-fold (46,596.30 ± 11,977.78 pg/ml), respectively,compared to the uninfected controls (Fig. 4B, C, and G). Theproduction of IL-6 and IL-8 as well as IL-12 and IFN- ${gamma}$ (Fig.4E and F) was significantly increased at 24 and 48 h postinfectionin comparison to the 4-h time point. TNF- ${alpha}$ was detected at highlevels at all time points from infected DCs. C. jejuni 81-176induced comparatively lower quantities of IL-1ß orIFN- ${gamma}$ than the other cytokines; however, IL-1ß andIFN- ${gamma}$ levels were significantly increased at 24 and 48 h postinfectionrelative to the 4-h time point (Fig. 4A and F). Finally, substantialincreases in IL-10 were only observed at the 48-h time point(Fig. 4D). These data show that increases in the CampylobacterMOI from 10 to 100 had little impact on overall cytokine production.Cytokine production increased over time, with peak amounts at24 or 48 h.

Is active bacterial invasion or bacterial viability necessary to induce cytokine production in DCs? Wild-type invasive C. jejuni 81-176, the noninvasive RY213 mutantstrain of 81-176 (55), NCTC 11168, a minimally invasive C. jejunistrain (1), and heat-killed 81-176 were compared for their abilityto trigger DC secretion of selected cytokines. C. jejuni 81-176was heat treated at 70°C for 30 min and subsequently shownby plate count to be nonviable. The production levels of IL-1ß,IL-6, IL-8, IFN- ${gamma}$ , and TNF- ${alpha}$ (Fig. 5A, B, C, F, and G) at 24 hpostinfection were similar for all strains. The mutant RY213and NCTC 11168 showed slightly lower IL-10 and IL-12 inductionlevels compared to live 81-176 (Fig. 5D and E). Heat-killed81-176 cells generally induced slightly lower cytokine levelsthan live 81-176 cells, but this difference was, in most cases,not significant. Using an MOI of 100, the heat-killed bacteriadid not induce any higher cytokine levels than when at an MOIof 20 (data not shown). These data suggest that neither activebacterial invasion of DCs nor bacterial viability is necessaryfor C. jejuni to induce cytokine production, but live wild-type81-176 cells generally result in slightly better induction thanother stimulants.

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FIG. 5. Comparison of cytokine levels induced in DCs infected by live invasive, noninvasive, or heat-killed strain 81-176. Culture supernatants were tested 24 h postinfection with C. jejuni at an MOI of 20. The release of IL-1ß, IL-6, IL-8, IL-10, IL-12, IFN- ${gamma}$ , and TNF- ${alpha}$ is shown (A, B, C, D, E, F, and G, respectively). Data are presented as the mean ± standard deviation of duplicate wells from three independent assays.

Comparing polysaccharides of C. jejuni and E. coli for ability to induce cytokines in DCs. LOS was prepared from C. jejuni 81-176 by the hot phenol-waterextraction method and identified as LOS on silver-stained sodiumdodecyl sulfate-polyacrylamide gel electrophoresis gels (datanot shown). LOS (100 ng/ml) was added to DCs for 24 h. An equalamount of purified LPS from E. coli, known to induce cytokineproduction in DCs, was used as a control. Both LOS and LPS inducedcytokine levels similar to that seen with live C. jejuni (Fig.6), with the exception of a lower IL-10 induction by C. jejuniLOS. These data suggest that LOS of C. jejuni is a key contributorto the induction of cytokine production by DCs.

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FIG. 6. Comparison of the potential of C. jejuni LOS and E. coli LPS to induce cytokine production in human DCs. LOS (100 ng/ml) from C. jejuni and LPS (100 ng/ml) from E. coli were added to DCs for 24 h. The release of IL-6, IL-8, and TNF- ${alpha}$ (A) or IL-1ß, IL-10, and IFN- ${gamma}$ (B) are compared to values for uninfected DCs (due to the scale, uninfected DC data are too low to be visible in panel A). Data are presented as the mean ± standard deviation of duplicate wells from three independent assays.

NF- ${kappa}$ B activation after infection of DCs with C. jejuni. The host transcription factor NF- ${kappa}$ B promotes transcription ofvarious immune response genes, including cytokines (10). Thenuclear extracts exhibited low NF- ${kappa}$ B activation in the uninfectedcontrol DCs. In contrast, NF- ${kappa}$ B activation increased threefold(P < 0.05) in DCs infected with C. jejuni 81-176 for 4 h(Fig. 7).

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FIG. 7. C. jejuni-induced activation of NF- ${kappa}$ B in DCs. DCs were incubated with C. jejuni 81-176 for 4 h. Nuclear extracts were prepared and incubated with anti-NF- ${kappa}$ B p65 per the instructions of the manufacturer. The NF- ${kappa}$ B concentrations were determined spectrophotometrically. The data represent the mean ± standard deviation from three independent assays.

DISCUSSION

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Discussion

DCs play important roles in both the innate and adaptive immuneresponses to microbial pathogens (26). The intestinal immunesystem DCs lie beneath the mucosal surface in Peyer's patchesand form an early line of defense against invading pathogens.Intestinal DCs can internalize bacterial pathogens followingtheir uptake through M cells or more directly through paracellulardendrite extensions into the intestinal lumen (35). Here, weanalyzed the interaction between C. jejuni and human DCs toinvestigate DC activation, potential bacterial or DC toxicity,and the induction of cytokines associated with disease inflammationand immune responses to infection. Our data show that DCs internalizeC. jejuni at early time points (i.e., 2 h postinfection), takingup one to six bacteria per DC on average at MOIs of 10 to 100.Ninety-nine percent of internalized C. jejuni were killed within24 h, and there was virtually no cytotoxicity to DCs inducedover 24 h, with only minimal increased DC death ( $~$ 10%) after48 h. Wassenaar et al. (51) found that activated human monocytes/macrophagesalso efficiently killed C. jejuni, causing a 5-log reductionin 24 h. Our results differ from those of Siegesmund et al.(42), who reported that C. jejuni F38011 induced apoptosis in63% of THP-1 (human monocyte line) cells 48 h after inoculation.

In striking contrast, many studies report that Salmonella isinternalized by and survives within both human and murine DCs(6, 9, 18, 29, 45), although Salmonella has been reported torapidly kill infected DCs and macrophages (21, 25, 48). Shigellainfection of human DCs results in rapid IpaB-dependent DC death(8), which probably dampens the adaptive immune response tothis enteric pathogen. Similar to our findings with Campylobacter,Y. enterocolitica enters DCs and does not induce necrosis orapoptosis (40). However, Yersinia reverses the activation ofDCs, reduces DCs' abilities to stimulate an adaptive response,and prolongs infection. For Campylobacter and some enteric pathogens,it is still largely unclear as to what primary factor(s) determinesintracellular bacterial survival or triggers host cell necrosis/apoptosis.

In this study, C. jejuni stimulation of immature DCs resultedin their maturation to APCs, as evidenced by enhanced expressionof cell surface costimulatory molecules CD40, CD80, and CD86.Similarly, other enteric pathogens, such as S. enterica serovarTyphimurium (30) or Helicobacter pylori (24), have been shownto up-regulate DC surface expression of MHC class II, CD40,CD80, and CD86 molecules. Coordinated up-regulation of the costimulatorymolecules and translocation of MHC molecules to the cell surfaceare essential molecular events for subsequent antigen presentationand ultimate activation of both CD4⁺ and CD8⁺ T cells (36).

Monocytes/macrophages are considered early host responders toinfection and are also an important source of proinflammatorycytokines. C. jejuni has recently been reported to induce IL-1,IL-6, IL-8, and TNF- ${alpha}$ in human monocytes (14, 19). Dendriticcells also produce various cytokines and chemokines upon interactionwith pathogenic bacteria (8, 24, 25, 56). Our data show thatC. jejuni activates the transcriptional factor NF- ${kappa}$ B and inducesthe production of significant amounts of IL-1ß, IL-6,IL-8, IL-10, IL-12, IFN- ${gamma}$ , and TNF- ${alpha}$ in DCs. These cytokines playcrucial roles in the induction of inflammation and in adaptiveimmune responses (28, 31, 47).

Proinflammatory cytokines IL-1ß, IL-6, IL-8, and TNF- ${alpha}$ were induced rapidly in DCs infected with C. jejuni and weresecreted and maintained at high levels over 48 h. The cytokineexpression pattern was not markedly altered by increasing theMOI from 10 to 100. These findings add to the growing body ofinformation which shows that C. jejuni triggers the innate immunesystem to produce proinflammatory cytokines, which likely serveto initiate and modulate local inflammation in the Peyer's patches,leading to disease symptoms. Previous studies of C. jejuni-infectedhuman cell lines have shown that this pathogen also inducesepithelial cell secretion of IL-8 and some chemokines (13, 15,27), attracting phagocytic cells that may be important in bothcontaining and in exacerbating the infection (54). Consistentwith these results, our studies show that many proinflammatorycytokines, including IL-8, were stimulated in a significantand rapid fashion in DCs.

As DCs mature, they synthesize cytokines essential for the developmentof T-cell interactions (i.e., adaptive responses). Comparedto other types of APCs, DCs are 1,000-fold more efficient inactivating resting T cells (3). Interleukin-12 appears to bea key cytokine produced by APCs to stimulate a Th1-directedresponse (7, 46). C. jejuni induced very high levels of IL-12at 24 and 48 h after infection. IL-10 is an important Th2-typecytokine that up-regulates humoral and down-regulates cell-mediatedimmune responses (31, 41). The high IL-12 production (i.e.,10,000-fold induction) and relatively low IL-10 induction (i.e.,100- to 500-fold induction) by C. jejuni favors a Th1 response.

The induction of cytokine production in DCs was not significantlydifferent between live and heat-killed bacteria, except forIL-10, which was slightly lower with the heat-killed bacterialstimulus. Similar findings were previously reported in C. jejuni-infectedmonocytes (19). The noninvasive RY213 strain and C. jejuni NCTC11168, which have low invasion efficiencies (1), induced cytokinesIL-10, IL-12, and TNF- ${alpha}$ at levels reduced only by about one-halfversus strain 81-176. These data argue that invasion is notnecessary for the induction of these cytokines. In fact, purifiedLOS from strain 81-176 induced high levels of the selected cytokinesstudied, with the exception of IL-10. These data indicate thatthe predominant induction of cytokines in DCs may be due tointeraction with LOS. Some alternate pathway is likely neededfor full IL-10 induction. The signal transduction pathways modulatedby the interaction of C. jejuni with DCs are currently beinginvestigated in our lab. Taken together, these data suggestthat DCs are an important component of the host-pathogen interactionwith Campylobacter. Further, DCs play a role in triggering inflammatorycytokines likely involved in disease pathogenesis and in initiatinga Th1-directed adaptive immune response during C. jejuni infection.

ACKNOWLEDGMENTS

We acknowledge T. T. Wai for help in preparing CampylobacterLOS and thank R. I. Walker, M. Akkoyunlu, and S. Dharwan forcritical review of the manuscript.

FOOTNOTES

* Corresponding author. Mailing address: Laboratory of Enteric and Sexually Transmitted Diseases, Center for Biologics Evaluation and Research, Food and Drug Administration, 29 Lincoln Drive, NIH Campus, Bldg. 29/420, HFM440, Bethesda, MD 20892. Phone: (301) 496-1893. Fax: (301) 402-8701. E-mail: kopecko{at}cber.fda.gov.

Editor: J. T. Barbieri

REFERENCES

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