Proinflammatory and Immunomodulatory Cytokine mRNA Time Course Profiles in Hamsters Infected with a Virulent Variant of Leptospira interrogans

In order to quantify in vivo the mRNAs of cytokines which playimportant roles in leptospirosis, we have developed quantitativereal-time PCR assays for interleukin-2 (IL-2), IL-4, IL-10,IL-12p40, tumor necrosis factor alpha (TNF- ${alpha}$ ), gamma interferon(IFN- ${gamma}$ ), transforming growth factor ß, and two housekeepinggenes (encoding ß-actin and hypoxanthine phosphoribosyltransferase). Weused a lethal hamster model reflecting severe leptospirosisin humans. The LightCycler system was used to quantify the geneexpression levels with the SYBR green I detection format usingexternal standard curves for each target. We compared the expressionlevels of cytokine mRNA in the peripheral blood mononuclearcells of both control (uninfected) hamsters and Leptospira interrogans-inoculated hamstersfrom 1 to 24 h and then 1 to 4 days postinfection. In this kineticstudy, there was pronounced expression of Th1 cytokine mRNA(TNF- ${alpha}$ , IFN- ${gamma}$ , and IL-12), with transcripts being detected asearly as 1 h postinfection. Expression of anti-inflammatorycytokines, such as IL-4 and IL-10, was prominent in delayedsamples from 1 to 4 days postinfection in response to infection withLeptospira interrogans. Our data are the first to establishthat pathogenic leptospires can stimulate in vivo the productionof type 1 cytokines involved in cellular immunity by using thisinformative animal model. Measuring and assessing cytokine profilesmay provide a useful method for accurate study of the mechanismsof anti-Leptospira immunity, indications of prognosis factors,and prospective evaluation of leptospirosis vaccine efficacyin humans.

INTRODUCTION

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Introduction

Leptospirosis is a widespread zoonosis caused by members ofthe genus Leptospira, with the incidence of the disease beinghigher in tropical climates (10). Human leptospirosis is highlyvariable in its clinical expression. The course of the diseaseranges from mild flu-like symptoms to rapidly fatal forms, clinicallyresembling sepsis with multiple organ failure (mainly kidneyand liver) and shock-like syndrome.

Despite socioeconomic consequences, such as significant productionlosses in cattle and greater risk of infection with increasingfatality rates in humans, there is a lack of knowledge regardingspecific immune response leading to protection against Leptospirainterrogans infection and immune mechanisms elicited after immunizationwith vaccine candidates. Establishing the correlation betweena Th1 and Th2 profile for dissecting the mechanisms of anti-Leptospira immunityis of major importance in obtaining a successful vaccine againstleptospirosis as well as in understanding the pathogenesis of naturalor induced infection (20). Regarding innate immune response,interesting results were obtained by Werts et al. (32) whenthey demonstrated that activation of macrophages by leptospiral lipopolysaccharideoccurred through CD14 and the Toll-like receptor 2. Consideringinduced immune response, despite a serovar specificity, protectiveimmunity to leptospirosis is not exclusively humoral (10). Thisparadigm was reexamined by Naiman et al. (21, 22), Baldwin etal. (2), and Brown et al. (3). Indeed, by evaluating the cellularimmune response induced by a protective monovalent serovar Hardjovaccine in cattle, a potent Th1-type immune response and the involvementof ${gamma}$ ${delta}$ T cells were clearly in evidence. At the same time, therewas also evidence that antilipopolysaccharide antibodies werenot the only mechanism playing a role in naturally acquiredprotective immunity (29).

The mechanism by which leptospires activate the immune systemhas been pointed out in several studies, mainly in vitro, highlightingthe importance of cytokines (17, 33). Indeed, the role of cell-mediatedimmunity in host defense to Leptospira remains poorly understoodin both animal and human diseases. Briefly, after skin or mucosalpenetration and a bacteremic stage, virulent leptospires reachand colonize the target tissues of the host organism (29, 30).Primarily, vasculitis is the characteristic lesion found inleptospirosis, leading to major cellular damage (10). Fluidand cell leakage occur in the presence of few leptospires, suggestingthe involvement of factors from either the spirochete or thehost. As an example, limited studies have reported a significantincrease of tumor necrosis factor alpha (TNF- ${alpha}$ ) in human patientswith leptospirosis (9) and levels of expression in plasma wereassociated with severity of disease and mortality (28). However,these results represent a global response of the host. The naturalhistory of the disease is often unknown, and producing cells werenot characterized (type and kinetics of production), nor were molecularevents (cascade of activation) investigated. Concerning the pathogen,the glycolipoprotein is a toxic Leptospira interrogans cellularcomponent able to induce cellular activation in vitro, as assessedby cytokine secretion and cell surface antigen expression (7). Preliminaryresults were obtained in 1980 by Cinco et al. (5) with the invitro release of TNF- ${alpha}$ from human monocytes by Leptospira peptidoglycans.However, no link with virulence could be established (11). Ina later study, Klimpel et al. (12) showed that Leptospira inducedthe in vitro production of Th1 cytokines by peripheral bloodmononuclear cells (PBMCs) and cell proliferation in both ${alpha}$ ßT cells and ${gamma}$ ${delta}$ T cells. These ${gamma}$ ${delta}$ T cells recognized Leptospira withoutantigen-processing or antigen-presenting cells. Knowledge ofmolecular mechanisms implied in the in vivo response to leptospireswould shed new light on the delineation between severe and mildforms of the disease.

The rapid and efficient production of cytokines occurs by theaccurate control of their gene transcription and RNA stability.A current method to analyze cytokine production is to quantifytheir corresponding mRNA by real-time (RT)-PCR. Cytokine mRNAquantification is widely used to investigate cytokine profiles,particularly in small samples where transcripts such as cytokinemRNAs are lowly expressed (14, 16, 26, 27). This technique allowsthe quantification of a larger pattern of cytokines than quantificationat the protein level, which is limited to a smaller number ofcytokines (15) and does not fully reflect the expression profile.

After experimental infection of hamsters with a virulent strainof Leptospira, the purpose of this study was to perform the accuratequantification of peripheral blood cytokine mRNA levels, based onthe combination of tubes containing an mRNA stabilizer for blood collectionand the real-time PCR methodology on the LightCycler. In thisapplication, we have developed sensitive and reproducible SYBR greenI RT-PCR protocols which allow measurement of various cytokine mRNAsin hamsters (interleukin-2 [IL-2], IL-4, IL-10, IL-12p40, TNF- ${alpha}$ ,gamma interferon [IFN- ${gamma}$ ], and transforming growth factor ß[TGF-ß]). We used both absolute quantification, todetermine a numerical value for the target concentrations, andrelative quantification, to describe the change in expressionof the target genes in relation to two housekeeping (reference)genes (encoding ß-actin and hypoxanthine phosphoribosyltransferase[HPRT]). This approach should provide greater insight into theimmunological processes underlying protection after immunizationwith leptospirosis vaccine candidates.

(This work was presented in part at the 2005 Roche LightCyclerUser Group meeting, Taupo, New Zealand.)

MATERIALS AND METHODS

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Materials and Methods

Leptospira strain and cultivation. The virulent L. interrogans serovar Icterohaemorrhagiae strain Verdunwas obtained from the Reference Collection of the Institut Pasteurin Paris, France. Leptospires were grown in liquid Ellinghausen McCulloughJohnson and Harris (EMJH) medium at 30°C under aerobic conditions(8) to a density of about 10⁸ bacteria per ml and counted ina Petroff-Hausser counting chamber. Virulence was maintainedby deep-freeze preservation and iterative lethal passages inSyrian golden hamsters (Mesocricetus auratus). Briefly, specific pathogen-freeanimals were purchased from Charles River Laboratories (CharlesRiver Wiga GmbH, Sulzfeld, Germany) and bred at the Institut Pasteurof New Caledonia. Two animals weighing 50 to 60 g were lethallyinfected intraperitoneally with 10⁸ leptospires of a virulentculture in EMJH medium. Another group of two animals was inoculatedby the same route with sterile EMJH medium and used as a control.When prostration and anorexia appeared between 4 and 6 daysafter inoculation, blood from infected hamsters was collectedby cardiac puncture and cultured in EMJH medium. After 7 to10 days of culture (at least 10⁸ leptospires per ml), this highly virulentstrain was used for experimental infections.

Experimental infections. All in vivo studies were carried out using 6- to 8-week-oldoutbred golden hamsters individually identified by subcutaneous-implantedtransponders (Virbac, France) and handled according to Frenchnational regulations. Each experimental set was composed ofa group comprising three inoculated animals and one noninfectedhamster per checking point. Hamsters were lethally infectedwith 10⁸ leptospires of a virulent culture in EMJH medium by subcutaneousinjection to reproduce as much as possible by the conventionalway of infection (29), whereas noninfected hamsters receivedby the same route sterile EMJH medium. Each set of experiments,including control animals, was conducted in duplicate. Bloodsamples were collected by cardiac puncture under sublethal anesthesiavia Vacutainer collection tubes (15% K3E; Becton Dickinson,France) or PAXgene blood RNA tubes (PreAnalytiX; QIAGEN, Australia).

In vitro cell stimulation. External DNA standards were generated after in vitro stimulationin order to obtain marked concentrations of all target genes.A maximum amount of blood (2 to 3 ml) was collected from healthyhamsters on Vacutainer collection tubes as described above.PBMCs were isolated by Ficoll-Hypaque density gradient centrifugation(Histopaque; Sigma-Aldrich, St Louis, MO). Then, PBMCs wereplated in a 24-well plate in duplicate cultures at 10⁶ cells/mlin Dulbecco modified Eagle medium supplemented with 10% heat-inactivatedcalf serum and 1% penicillin-streptomycin, according to thefollowing stimulation schedule: (i) medium only, (ii) 10 ng/ml ofphorbol myristate acetate plus 500 ng/ml inomycin, and (iii)1 µg/ml Escherichia coli lipopolysaccharide (all from Sigma).Overnight cultures were performed at 37°C in a 5% CO₂ atmosphereprior to harvesting the cells and carrying out RNA isolation.

Total RNA isolation and cDNA synthesis. Total RNA extracted from in vitro-stimulated cells was obtainedusing the High Pure RNA isolation kit (Roche Applied Science,Auckland, New Zealand), whereas total RNA from in vivo experiments,with larger amount of cells, was isolated using the PAXgeneblood RNA system (PreAnalytiX), both according to the manufacturers'instructions. cDNA was synthesized using the Transcriptor firststrand cDNA synthesis kit (Roche Applied Science) followingthe manufacturer's protocol, with the supplied random hexamersas the priming strategy.

Oligonucleotides. Sequences of all primers used in this study are listed in Table 1.They were designed according to Melby et al. (18) with the LightCyclerPrimer Probe Design Software 2.0 (Roche Applied Science) andsynthesized by Proligo Singapore Pte Ltd. (Biopolis, Singapore). Thefollowing criteria were applied during the design: product size from200 to 350 bp (357 bp for ß-actin), primer size from17 to 30 bp, and a mean melting temperature of 60°C. Proposedoligonucleotides were selected according to intron spanningto prevent amplification of genomic DNA and percentage of G+C.

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TABLE 1. Detailed primers and conditions used for real-time PCR assays

Standard curve construction. For all cytokine and reference genes, a standard curve fromserial dilutions of a known concentration of purified DNA wasachieved (24). This quantified DNA consisted of the target PCRproduct prepared by conventional PCR from cDNA positive forthe corresponding target mRNA. The copy number of each standardwas calculated by standard methods using the Avogadro constantas described by Overbergh et al. (23). The log ranges of thedifferent standard curves were from 10⁷ copies to 1 copy. Threefoldmeasurements for each standard dilution point over the wholestandard curve range were produced to generate a reliable standardcurve.

Real-time PCR and amplification protocol. PCR amplification and analysis were achieved using a LightCycler2.0 instrument (Roche Applied Science) with software version4.0. All reactions were performed with the LightCycler FastStartDNA master SYBR green I (Roche Applied Science) by using a 20-µlvolume in each reaction capillary. For quantification of thecytokines, 2 µl DNA standard dilution or 2 µl cDNAwas added before capillaries were capped, centrifuged, and placedin the LightCycler sample carousel. Amplification conditionsconsisted of an initial preincubation at 95°C for 10 min(FastStart Taq DNA polymerase activation), followed by amplificationof the target DNA for 45 cycles (95°C for 8 s, 60°Cor 61°C for 5 s, and a variable extension time at 72°C). Meltingcurve analysis was performed immediately after amplificationat a linear temperature transition rate of 0.1°C/s from65 to 95°C with continuous fluorescence acquisition.

Result expression. In our protocol, results were systematically normalized to expressionlevels of two different reference genes in order to correctvariations in nucleic acid quality and quantity (26). The concentration ofan unknown sample was calculated by comparing its crossing point (Cp)with the corresponding standard curve. The cycle number at theCp (y axis) was plotted versus the log of the initial template amount(x axis) of the standards. After amplification, three analyseswere sequentially performed with the data: (i) absolute quantificationresulted in an absolute value (e.g., copies/µl), (ii)relative quantification was expressed as a ratio between a cytokinegene and a reference gene, and (iii) results were normalized toa calibrator sample. Finally, a calibrator-normalized ratiowas obtained, providing indirect information on cytokine mRNAincreases and decreases and taking into account correctionsfor experimental variations in different samples (23).

Nucleotide sequence accession numbers. The GenBank accession numbers for the Syrian golden hamstercytokines and housekeeping gene cDNAs are as follows: IFN- ${gamma}$ ,AF034482; IL-2, AF046212; IL-4, AF046213; IL-10, AF046210; IL-12p40, AF046211;TNF- ${alpha}$ , AF046215; TGF-ß, AF046214; HPRT gene, AF047041;and ß-actin gene, AJ312092.

RESULTS AND DISCUSSION

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Results and Discussion

We compared the expression levels of cytokine mRNAs in the PBMCsof both control (uninfected) hamsters and Leptospira-inoculatedhamsters from 1 to 24 h and then 1 to 4 days postinfection (p.i.).In this study, administration of 10⁸ leptospires by subcutaneousinoculation resulted in a bacteremia averaging 10⁴ leptospires/mlduring the first 24 h postinfection, before reaching a peakof more than 10⁶ leptospires/ml at 4 days p.i (29). We hypothesized thatthe immune mechanisms related to changes over time in the density ofvirulent leptospires would be demonstrative during the first 24h and then following days of infection.

Real-time PCRs were developed for accurate cytokine mRNA quantification,first from cultured cells (i.e., PBMCs and hepatocytes) andsecond from whole blood (i.e., blood samples from experimentallyinfected laboratory animals). Whole blood presents a key advantagecompared to real-time PCR performed from in vitro-purified culturedcells: it is more representative of the in vivo immune responseof the host. One of the difficulties encountered using whole bloodis that the cell lysis generates large amounts of proteins.All methods that isolate RNA from whole blood involve purificationsteps before RNA extraction. This time-consuming protocol canbe avoided using commercially available reagents, such as PAXgenetubes. This method was successfully applied by Stordeur et al. (26, 27).This prompted us to combine the use of PAXgene and real-timePCR with the LightCycler to monitor systemic inflammatory responsesduring leptospirosis.

First, the linearity of cDNA synthesis was verified. When smallRNA amounts were used, absorbance values at 260 nm were notreliable enough to allow accurate amounts of total RNA to be addedto the cDNA synthesis reaction (14). Therefore, for the cDNAsynthesis, a constant volume (2 µl) of total RNA was used. IsolatedRNA was serially diluted and used for cDNA synthesis. Then, allcDNAs were amplified in real-time PCR for all tested cytokinesand housekeeping genes. A linear relationship of the cDNA synthesisas a function of various RNA contents was observed, ensuringthat various quantities of RNA did not affect the reverse transcription(data not shown).

The appropriate amplicons corresponding to each cytokine andreference gene were purified, quantified, and serially diluted,as described in Materials and Methods. Figure 1 shows the standardcurves for TNF- ${alpha}$ , TGF-ß, IFN- ${gamma}$ , HPRT, and ß-actin.The curves were obtained by plotting the mean values of log-calculatedconcentration (copy number) versus the Cp. The amplificationefficiencies varied between 1.77 and 1.94 for the differentamplicons. As expected, the standard deviation increased withdecreasing copy number. The regression coefficient was –1.00in all cases.

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FIG. 1. Standard curves for TNF- ${alpha}$ , TGF-ß, and IFN- ${gamma}$ as well as the two housekeeping genes HPRT and ß-actin. Curves were constructed using 10-fold dilutions ranging from 10⁷ copies to 1 copy/µl. The curves were obtained by plotting the mean values of log-calculated concentration (copy number) versus the Cp. The error bars show the standard deviations (n = 3). The error (E) values of the standard curves are the mean squared errors calculated by the LightCycler software. The regression coefficient was –1.00 in all cases.

After relative quantification and normalization, we found asignificant increase (as soon as 1 h p.i.) in the expressionof TNF- ${alpha}$ , a proinflammatory cytokine that can have both protectiveand damaging consequences for the host. Basically, two peaklevels were observed during the first 24 h p.i. (Fig. 2). Themaximum value, with a 4.8-fold increase compared to the baselineexpression, was observed at 16 h p.i. The expression of TNF- ${alpha}$ then remained at the baseline level from 24 h p.i. At the sametime, we detected a significant increase in the mRNA for IFN- ${gamma}$ .Indeed, a 2.9-fold increase was found as early as 8 h p.i.,followed by decreasing levels of expression over the next 16h (Fig. 2). Interestingly, the first peak of TNF- ${alpha}$ was detectedjust before the increase in the mRNA for IFN- ${gamma}$ , thus indicatingthat TNF- ${alpha}$ seems to act synergistically with IFN- ${gamma}$ . Whether thisearly expression of TNF- ${alpha}$ could stimulate the production of IFN- ${gamma}$ in the course of infection cannot be determined until reagentsare available for neutralization of the first cytokine. Ourfindings are consistent with existing clinical data. Indeed,elevated plasma concentrations of TNF- ${alpha}$ have been observed inpatients affected by leptospirosis, and correlations were establishedbetween high levels of TNF- ${alpha}$ and the worsening of symptoms (9, 25, 28).

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FIG. 2. Normalized relative quantification of mRNA expression by real-time PCR for TNF- ${alpha}$ , IFN- ${gamma}$ , and IL-12. Shown are the means ± standard errors of the mean of the ratio of the cytokine to HPRT. The same ratios were obtained with ß-actin. Hours (from 1 to 22) and days (from D1 to D4) p.i. are indicated on the x axis.

There was a considerable increase in the IL-12 mRNA in infected hamsters,with a reproducible 1,900-fold amplification at 4 h p.i. A verylimited production of transcripts was visible 2 h before andafter the main peak. However, this 1,900-fold induction is notlikely to be accurate as little or no expression of IL-12 transcriptscorresponding to the background was detected in uninfected hamsters.Compared to that for TNF- ${alpha}$ and IFN- ${gamma}$ , the profile of productionwas consistently different. Where a progressive expression ofTNF- ${alpha}$ and IFN- ${gamma}$ was observed over a 6- to 16-h period, productionof IL-12p40 was sudden, rapid, and strong. IL-12 is releasedfrom antigen-presenting cells and the subunit p35 is ubiquitouslyproduced, whereas the subunit p40 is inducible and detectedonly in cells producing biologically active IL-12 (13). Considering leptospirosis,interestingly, de Fost et al. (6) evidenced the production ofIFN- ${gamma}$ , IL-12p40, and TNF- ${alpha}$ in human whole blood after incubationwith heat-killed pathogenic Leptospira interrogans. Experimentswere performed in vitro, and cytokines were measured by specificenzyme-linked immunosorbent assays (ELISAs). Their data establishedthat the production of IFN- ${gamma}$ was largely dependent on IL-12p40.In our in vivo kinetic study using live pathogenic leptospires,a similar observation was made, confirming these previous invitro results. Indeed, IL-12p40 was found to be released 4 hbefore the secretion of IFN- ${gamma}$ . Unfortunately, at present, noreagents for the neutralization of IL-12p40 in hamsters arereadily available. Our data establish that pathogenic leptospirescan stimulate in vivo, in this informative animal model reflectingsevere leptospirosis in humans, the production of type 1 cytokinesinvolved in cellular immunity. Immunological mechanisms haveto be further dissected to provide comprehensive interactionsbetween (i) TNF- ${alpha}$ and IL-12p40 and (ii) IFN- ${gamma}$ and its potent inducers,TNF- ${alpha}$ and IL-12p40, in our model. Data from Chierakul et al. (4)evidenced high plasma concentrations of IL-12p40 and TNF- ${alpha}$ inadult Thai patients with leptospirosis. However, depending onthe pathogen investigated, the few studies that suggest a directrelationship between these two cytokines are conflicting (13).Therefore, the relationship between TNF- ${alpha}$ and IL-12 remains complex,as it strongly relies on the differentiation stage of producing cells.

Prominent expression of IL-4 mRNA (Fig. 3 was observed for PBMCsamples obtained at 3 days p.i. (450-fold increase). Interestingly,this increase in IL-4 transcripts was observed very late duringthe course of infection. Similar results were obtained withIL-10. A significant expression of IL-10 mRNA was observed onlyin delayed specimens from 2 days p.i., with a maximum at day3 p.i. (eightfold increase). In a previous study (7), it wasdemonstrated that glycolipoprotein of Leptospira interroganscould induce in vitro and ex vivo lymphocyte and monocyte activation,leading to TNF- ${alpha}$ and IL-10 secretion. IL-10 production showedtypically delayed kinetics compared to TNF- ${alpha}$ production. In ourpresent experiments, we observed in vivo the same sequence ofevents, showing a cytokine pattern with a delayed inductionof anti-inflammatory cytokines, such as IL-10. This cytokineis essential in the control of a sepsis-like infection and regenerationof tissue lesion (1). Further experiments should be performedto show the correlation between IL-10 and TNF- ${alpha}$ , as a high IL-10/TNF- ${alpha}$ ratio seems to be a good prognosis in human leptospirosis (28).In our hamster model, the average ratio is 1.7 (8.0/4.8) andwas not consistent with recovery and healing because all infectedhamsters died from 6 to 8 days p.i (30). However, this animalmodel cannot be fully compared to the natural course of leptospirosisin humans. Indeed, a high number of virulent leptospires isneeded to develop acute or carrier leptospirosis, and the model descriptionapplies to young animals. In a previous study (29), we evidenceda critical threshold (density of 10⁴ leptospires/ml of blood) forthe vital prognosis by using a quantitative PCR assay duringthe course of human leptospirosis. According to our resultshere, the suitability of this quantitative method should alsoinclude a specific pro- and anti-inflammatory cytokine ratio.

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FIG. 3. Normalized relative quantification of mRNA expression by real-time PCR for IL-4, IL-10, and TGF-ß. Shown are the means ± standard errors of the mean of the ratio of the cytokine to HPRT. The same ratios were obtained with ß-actin. Hours (from 1 to 22) and days (from D1 to D4) p.i. are indicated on the x axis.

A low-level basal expression of IL-2 was detected in uninfectedhamsters but did not increase in response to infection withL. interrogans. A prominent baseline TGF-ß expressionwas also observed in uninfected animals. As reported by Melbyet al. (19), the constitutive expression level of this cytokineis not surprising as TGF-ß is strictly transcriptionallyregulated. However, a single peak was reached at 13 h p.i.,followed by a gradual progressive decrease in Leptospira-infectedhamsters. Remembering that TGF-ß is a potent inhibitorof macrophage function, the role of this cytokine in this leptospire-hamstermodel needs to be confirmed with analysis of protein expression.

Real-time PCR is advantageous for cytokine transcript quantification,because it can be used to accurately monitor the simultaneousexpression of an array of cytokines from a single sample andrequires only small quantities of template. Up to now, studies investigatingcytokine expression in leptospirosis were performed by ELISA.However, such studies at the protein level are not always possibledue to the lack of sensitivity of ELISA kits. Processing of hamstersamples is also impaired by the lack of commercialized ELISA kits.Indeed, high-sensitivity ELISA kits are available for rats and mice,but one should be extremely cautious when analyzing resultsas such animal models are not relevant for studying experimental leptospirosis.We improved our real-time PCR assay to enable large increases(n-fold) (IL-12p40 and IL-4) as well as slight increases (TNF- ${alpha}$ ,IFN- ${gamma}$ , TGF-ß, and IL-10) in cytokines to be accuratelymeasured.

Little is known about the cellular immune response to pathogenicleptospires, either in vitro or in vivo, by PBMCs. The experimentspresented here provide a constructive basis for the proinflammatoryand anti-inflammatory cytokine responses in in vivo diseaseoutcome. This informative hamster model, which does not needimmunosuppressive treatment such as cyclophosphamide (10), mimicssevere human leptospirosis with jaundice, hemorrhages, hepatitis,and nephritis. The innovative findings from this study indicatethat in vivo interactions of hamster PBMCs with a virulent strainof Leptospira interrogans result in the production of cytokinesassociated with a Th1-type immune response. Measurement and assessmentof cytokine profiles may provide a useful method for accuratestudy of the mechanisms of anti-Leptospira immunity, indicationsof prognosis factors, and prospective evaluation of leptospirosisvaccine efficacy. Signaling pathways involved in the productionof cytokines should be studied. Therefore, genetic backgroundof the host needs also to be investigated as innate immunity isessential in early infection by pathogenic leptospires. Indeed,the recent observations of Viriyakosol et al. (31) demonstratedthat intact Toll-like receptor 4 signaling contributes to thecontrol of the tissue burden of Leptospira in nonlethal infectionby using a mouse model. According to the diversity of symptomsin humans, a study of cytokine gene polymorphisms in the hostwould provide key findings for understanding human predispositionto leptospiral infection.

ACKNOWLEDGMENTS

We thank Françoise Charavay for expert technical assistancein virulence procedures and infection of animals. We are indebtedto John F. Mackay for critical reading of the manuscript andeditorial contribution.

FOOTNOTES

* Corresponding author. Mailing address: Institut Pasteur of New Caledonia, BP 61 98845 Noumea cedex, New Caledonia, France. Phone: 00 (687) 27 75 31. Fax: 00 (687) 27 33 90. E-mail: fmerien{at}pasteur.nc.

Editor: W. A. Petri, Jr.

REFERENCES

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