Functional Analysis of Effector and Regulatory T Cells in a Parasitic Nematode Infection

Parasitic nematodes typically modulate T-cell reactivity, primarilyduring the chronic phase of infection. We analyzed the roleof CD4-positive (CD4⁺) T effector (T_eff) cells and regulatoryT (T_reg) cells derived from mice chronically infected with theintestinal nematode Heligmosomoides polygyrus. Different CD4⁺T-cell subsets were transferred into naïve recipients thatwere subsequently infected with H. polygyrus. Adoptive transferof conventional T_eff cells conferred protection and led to asignificant decrease in the worm burdens of H. polygyrus-infectedrecipients. Roughly 0.2% of the CD4⁺ T cells were H. polygyrusspecific based on expression of CD154, and cells producing interleukin4 (IL-4) and IL-13 were highly enriched within the CD154⁺ population.In contrast, adoptive transfer of T_reg cells, characterizedby the markers CD25 and CD103 and the transcription factor Foxp3,had no effect on the worm burdens of recipients. Further analysisshowed that soon after infection, the number of Foxp3⁺ T_regcells temporarily increased in the inflamed tissue while effector/memory-likeCD103⁺ Foxp⁺ T_reg cells systemically increased in the draininglymph nodes and spleen. In addition, T_reg cells representeda potential source of IL-10 and reduced the expression of IL-4.Finally, under in vitro conditions, T_reg cells from infectedmice were more potent suppressors than cells derived from naïvemice. In conclusion, our data indicate that small numbers ofT_eff cells have the ability to promote host protective immuneresponses, even in the presence of T_reg cells.

INTRODUCTION

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INTRODUCTION

Infections with parasitic nematodes have been shown to markedlymodulate the host's immune system as a means to escape immuneeffector mechanisms and to ensure parasite survival within animmunocompetent host (35, 55). Highly effective immune evasionmechanisms are key elements of the long-lasting persistenceof parasitic worms. Both parasite-specific and nonspecific immunesuppression are well documented (19, 47, 60). Usually, acuteinfection stimulates antigen-specific T-cell proliferation,but with increasing exposure to parasite antigens, the immunesystem becomes hyporesponsive (34).

Immune responses against gastrointestinal nematodes includestrong immunoglobulin G1 (IgG1) and IgE responses, eosinophilia,intestinal mastocytosis, goblet cell hyperplasia, and smooth-musclehypercontractility (1, 12, 70). Th2-driven effector mechanismswere shown to be protective against gastrointestinal helminths,whereby interleukin 13 (IL-13) and IL-4 play an important rolein primary, as well as secondary, infections (7, 13, 15, 53).Recently, alternatively activated macrophages have been introducedas an IL-4-dependent effector population essential for protectiveimmunity to challenge infections with Heligmosomoides polygyrus(4). However, there is a lack of information on the activityof CD4-positive (CD4⁺) T-cell subsets during the chronic phaseof primary nematode infections (when T-cell reactivity is suppressed)and on the T-cell subsets that contribute to host-protectiveor parasite-beneficial immune responses. In contrast, the interplayof T-cell subsets and regulation of effector responses in bacterial(28) and protozoan infections, like those with Leishmania (9,38, 66) and Plasmodium (21, 44) species, are well defined.

It has been suggested that nematode infections reduce both Th1-and Th2-mediated responses by profoundly influencing regulatorypathways (5, 35). Regulatory T (T_reg) cells represent a subsetof CD4⁺ T cells that are critically involved in balancing thereactivity of the immune system and preventing autoimmunity(40, 50). Alongside their role in preventing autoimmune reactions,T_reg cells have been shown to control excessive inflammatoryresponses against pathogens (20, 48). On the other hand, a strictcontrol of T effector (T_eff) cell responses by T_reg cells canpromote pathogen persistence (9, 28, 44, 67). Some cell markersused to identify T_reg cells are CD25, glucocorticoid-inducedtumor necrosis factor receptor family-related gene (GITR), andthe transcription factor forkhead box transcription factor P3(Foxp3). In addition, the integrin ${alpha}$ _E(CD103)β₇ is a markerfor a subset of highly potent effector/memory-like T_reg cells,and CD4⁺ CD103⁺ cells were found to be the most potent suppressorsof inflammatory processes in disease models, such as colitisand arthritis (22, 23, 30, 54). Here, we used CD25, CD103, andFoxp3 to identify T_reg cells. For the characterization of parasite-specificT_eff cells, we used CD154, a marker recently shown to exhibitexquisite specificity for antigen-activated T cells (15, 26).

To investigate the roles of different CD4⁺ T-cell subsets duringthe chronic phase of a primary nematode infection, we used thegastrointestinal nematode H. polygyrus, which resides in theproximal third of the mouse duodenum for up to several monthsduring primary infection. Mice become infected by ingestionof infective larvae (L3) that invade the duodenal wall, wheredevelopment to the L4 stage takes place. L4 reenter the gutlumen and mature to adults, which are chronically maintainedduring primary infection (42). We used H. polygyrus infectionto address the role of CD4⁺ T_eff cells and T_reg cells with regardto worm expulsion and the role of T_reg cells in modulating T_effcell function. Our data demonstrate that adoptive transfer ofT_eff cells leads to protective immune responses in which antigen-specificCD4⁺ T cells produce predominantly IL-4 and IL-13. In contrast,CD4⁺ T_reg cells from chronic infection show no effect on theadult worm burden after adoptive transfer, although they arehighly potent suppressors in vitro.

MATERIALS AND METHODS

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MATERIALS AND METHODS

Mice, parasites, and infection. H. polygyrus was maintained by serial passage in BALB/c mice.The infective larvae (L3) were obtained from feces culture,extensively washed, and stored in distilled water at 4°C.BALB/c and C57BL/6 mice were purchased from the Bundesinstitutfür Risikobewertung, Berlin, Germany. C57BL/6-Tg(CAG-EGFP)C15-001-FJ001Osbmice were a gift of M. Okawa, Osaka University. Male mice at7 to 10 weeks of age were infected with 200 L3 using a gavagetube. Infection was surveyed by fecal egg count. The worm burdenwas determined by collecting adult worms from the small intestineon the day of dissection. Animals were housed and handled followingnational guidelines and as approved by our animal ethics committee.

Preparation of adult worm antigen. Soluble worm antigen was prepared from adult worms kept in culturein RPMI medium containing 100 U/ml penicillin and 100 µg/mlstreptomycin for 24 h. The worm material was homogenized andsonicated (1 min; 60 W) on ice in phosphate-buffered saline(PBS) (pH 7.4). The homogenate was centrifuged (20 min; 20,000x g; 4°C), and the supernatant was passed through a 0.4-µmfilter (Schleicher & Schuell, Germany) for sterilization.The protein content was determined by the bicinchoninic acidtest (Pierce). Antigen extracts were stored at –80°Cuntil they were applied.

Antibodies, staining, and sorting reagents. The following antibodies and secondary reagents were purchasedfrom BD Biosciences (Heidelberg, Germany): ${alpha}$ CD4 fluorescein isothiocyanate(FITC)/PerCP (RM4-5), ${alpha}$ CD103 phycoerythrin (PE) (M290), ${alpha}$ CD25allophycocyanin (APC)/PerCP-Cy5.5 (PC61), ${alpha}$ CD3e (145-2C11), ${alpha}$ CD28(37.51), ${alpha}$ CD40 (HM40-3), ${alpha}$ IL-10 PE (JES5-16E3), ${alpha}$ IL-4 FITC (11B11), ${alpha}$ -gamma interferon ( ${alpha}$ IFN- ${gamma}$ ) FITC (XMG1.2), ${alpha}$ CD8 PE (53-6.7), SA-PE-Cy7,and SA-APC. ${alpha}$ CD103 biotin (M290), ${alpha}$ CD19 FITC (ID3), ${alpha}$ FcR II/III(2.4G2), and ${alpha}$ -digoxigenin PE were kindly provided by the GermanArthritis Research Center (Berlin, Germany). ${alpha}$ CD154 (CD40L) APC(MR1) was obtained from Miltenyi Biotec (Bergisch-Gladbach,Germany). ${alpha}$ IL-13 (38213.11) was obtained from R&D systems(Wiesbaden, Germany) and coupled with digoxigenin at the GermanArthritis Research Center. Foxp3 staining was performed usingthe PE ${alpha}$ -mouse Foxp3 staining set (clone FJK-16S) purchased fromeBioscience (San Diego, CA). ${alpha}$ CD4, ${alpha}$ CD90, ${alpha}$ PE, and ${alpha}$ APC microbeads,as well as FITC MultiSort kits, were obtained from MiltenyiBiotec.

Phenotypic analysis of lymphocytes by flow cytometry. Mesenteric lymph node cells (MLNC) and splenocytes from naïveand H. polygyrus-infected mice were dissociated by passing organsthrough a steel mesh in PBS, pH 7.4, containing 0.2% bovineserum albumin. In some experiments, intraepithelial lymphocytes(IEL) and lamina propria lymphocytes (LPL) were isolated fromthe small intestine. After visible Peyer's patches were removed,the small intestine was opened longitudinally; washed in PBS,pH 7.4; and incubated in RPMI at 37°C, 150 rpm for 40 min.The small intestine was washed twice in PBS, and the supernatantswere collected for isolation of IEL. The organ was cut intopieces and incubated (40 to 50 min; 37°C; 150 rpm) withcollagenases VIII and D (40 µg/ml each; both from Sigma),and then tissue was removed with a mesh. The supernatants werespun, and the cells were layered on a column of Percoll (GEHealthcare, Uppsala, Sweden) with a 40%-70% gradient. The cellswere spun at room temperature and 2,200 x g for 20 min, andthen collected from the interphase, washed, and kept in PBS-0.2%bovine serum albumin. For detection of changes in lymphocytecomposition, cell suspensions (1 x 10⁶ total cells) were stainedwith ${alpha}$ CD4, ${alpha}$ CD8, and ${alpha}$ CD19 monoclonal antibodies (MAbs). T_reg cellswere detected by staining them for CD4, CD25, and CD103. Nonspecificbinding of the MAbs was blocked by the addition of ${alpha}$ FcgRII/III(20 µg/ml). Intracellular detection of Foxp3 was performedaccording to the manufacturer's instructions. For intracellulardetection of CD154 and cytokines, cells were fixed in PBS containing2% formaldehyde for 15 min at room temperature. After permeabilizationwith 0.5% saponin (Sigma), the cells were blocked with wholerat IgG (0.1 mg/ml) for 15 min at 4°C to reduce nonspecificbinding of MAbs and stained with ${alpha}$ CD154 and two of the ${alpha}$ -mousecytokine MAbs for 30 min at 4°C. For combined detectionof CD154 and Foxp3, CD154 was stained on the cell surface directlyduring in vitro stimulation in complete culture medium as describedbelow (see "Culture conditions"). Cytometric analysis was performedusing FACSCalibur or LSRII (BD Biosciences) and FlowJo software(Tree Star, Inc.).

Isolation of T-cell subsets. The separation of T-cell subsets for transfers and in vitrostimulation was performed as follows. Cells were stained forCD25 (APC) and CD103 (PE). CD25⁺ and CD103⁺ cells were enrichedby the AutoMACS magnetic separation system using ${alpha}$ APC and ${alpha}$ PEmagnetic beads. For isolation of the different regulatory subsets,the bead-positive fraction was stained with FITC-labeled ${alpha}$ CD4,and the CD4⁺ CD25⁺ CD103⁺ cells and CD4⁺ CD25⁺ CD103^–cell subsets were separated using a FACS Diva cell sorter (BD,Heidelberg, Germany). After complete removal of cells expressingCD25 and/or CD103, the negative fraction was used to isolateconventional CD4⁺ T cells using ${alpha}$ CD4 beads. Naïve splenocytesdepleted of T cells using ${alpha}$ CD90 beads were irradiated (30 Gy)and used as antigen-presenting cells for in vitro assays. Forsome adoptive transfers, the whole CD4⁺ CD103⁺ subset (irrespectiveof CD25 expression) was isolated. Therefore, cells were stainedfor CD4 (FITC), CD25 (APC), and CD103 (PE). CD4⁺ cells wereisolated using the FITC-MultiSort kit by AutoMACS. After removalof the beads, CD103⁺ cells were isolated from CD4⁺ cells using ${alpha}$ PE beads.

Culture conditions. Cell cultures were performed in cRPMI (BioChrom, Berlin, Germany)containing 10% fetal calf serum, 20 mM L-glutamine, 100 U/mlpenicillin, and 100 µg/ml streptomycin as quadruplicateson 96-well plates. Culture of complete and T_reg cell-depletedMLNC was performed with 3.5 x 10⁵ cells for 72 h and a concentrationof 12 µg/ml of adult worm antigen, and then the supernatantswere harvested for cytokine detection. Culture of regulatorysubsets and CD4⁺ CD25^– CD103^– responder cells fordetection of polyclonal response to ${alpha}$ CD3 stimulation (1 µg/ml)was performed with 2.5 x 10⁴ CD4⁺ cells and 5 x 10⁴ antigen-presentingcells per well. The cells were incubated for 48 h, followedby the addition of 1 µCi of [methyl-³H]thymidine (AmershamPharmacia Biotech, Gent, Belgium) per well for 20 h to measureproliferation. In coincubation assays, the indicated numbersof T_reg cells were added to naïve responder cells and antigen-presentingcells and treated as described above. In some assays, bone marrow-deriveddendritic cells (DC) were used as antigen-presenting cells,together with sorted CD4⁺ T-cell populations. For the generationof DC, bone marrow was isolated from tibias and femurs of 6-to 8-week-old naïve BALB/c mice, and the cells were keptin 24-well plates at a concentration of 1.5 x 10⁶/ml in cRPMIsupplemented with 20 ng/ml of granulocyte-macrophage colony-stimulatingfactor (PeproTech, Hamburg, Germany) for 6 days, followed byincubation with 10 µg/ml of adult worm antigen for 12h. Control cells were left untreated. DC (1 x 10⁴) were culturedfor 72 h with 5 x 10⁴ T cells, and then the supernatants wereharvested for cytokine enzyme-linked immunosorbent assay (ELISA)and the cells were snap-frozen in liquid nitrogen and storedat –80°C for real-time PCR. Recombinant mouse IL-2(10 ng/ml; PeproTech, Hamburg, Germany) and 1 µg/ml ${alpha}$ CD28were added to some cultures for optimal stimulation. For measurementof CD154 (CD40L) expression of T cells and detection of cytokinesin antigen-specifically activated cells, splenocytes and MLNCfrom infected animals were incubated in 24-well plates at aconcentration of 4 x 10⁷ cells per ml with 20 µg/ml ofadult worm antigen and 1 µg/ml ${alpha}$ CD28 for 12 h. To surveycytokine production, brefeldin A (5 µg/ml; Sigma) wasadded after the first 2 h of stimulation. After 12 h, the cellswere washed and prepared for flow-cytometric analysis as describedabove. For surface staining of CD154, cells were incubated asindicated above but without the addition of brefeldin A. ${alpha}$ CD154-APC, ${alpha}$ FcR II/III MAbs (20 µg/ml), whole rat IgG (10 µg/ml),and ${alpha}$ CD40 (to avoid rapid removal of CD154 from the cell surfaceafter binding of CD40 expressed on antigen-presenting cells)were added to the culture. After 12 h, the cells were washedand stained for CD4, CD103, and Foxp3. We omitted staining ofCD25 in these assays due to the unreliability of the markerwith respect to T_reg characterization after restimulation.

Histology. Tissue samples from the proximal third of the small intestinesof naïve and H. polygyrus-infected mice were fixed in 4%phosphate-buffered formalin, embedded in paraffin, and usedfor cross sections. Immunohistology for Foxp3-expressing cellswas performed as described elsewhere (32, 33). Foxp3⁺ cellswere counted in 10 high-power fields (40-fold magnification)randomly distributed in sections from each animal (Peyer's patchareas were excluded).

Cytokine analysis and quantitative PCR. IL-4, IL-10, and IFN- ${gamma}$ in cell culture supernatants were quantifiedusing OptEIA ELISA kits (BD Biosciences) according to the manufacturer'sinstructions. IL-13 and active transforming growth factor β1(TGF-β1) were detected using DuoSets from R&D Systems.Active TGF-β1 was analyzed in culture supernatants withoutacidification. Transcript quantification by real-time PCR ofIL-4 and IL-10 in distinct CD4⁺ T_eff and T_reg populations wasperformed after coincubation of T cells with naïve or H.polygyrus antigen-pretreated bone marrow-derived DC (see "Cultureconditions" above). RNA extractions were performed using theRNeasy Mini Kit (Qiagen, Hilden, Germany), followed by digestionof DNA using the RNase-free DNase set (Qiagen) according tothe manufacturer's instructions. RNA was reverse transcribedusing the TaqMan reverse transcription reagent (Applied Biosystems,Warrington, United Kingdom) and oligo(dT)s. Quantitative real-timePCR was performed with the 7300 Real-Time PCR System (AppliedBiosystems) using TaqMan reagents (Applied Biosystems). PCRamplifications were done in triplicates containing 3 µlof cDNA, 2 µl of 20x TaqMan-labeled primer mixture, and10 µl of 2x TaqMan PCR buffer. The 20x TaqMan primer mixtureconsisted of two unlabeled PCR primers (900 nM [each] finalconcentration) and one 6-carboxyfluorescein dye-labeled TaqManMGBprobe (250 nM final concentration). All primers were obtainedfrom Applied Biosystems (IL-4 assay identifier, Mm00445259_m1;IL-10 assay identifier, Mm00439616_m1; GAPDH [glyceraldehyde-3-phosphatedehydrogenase] assay identifier, Mm99999915_g1). Real-time PCRwas performed using the following conditions: 10 min of denaturationat 95°C, followed by 40 amplification cycles of 15 s at95°C and 60 s at 60°C. The relative amounts of IL-10and IL-4 mRNA were normalized to the endogenous reference GAPDH.Quantification of transcripts in cells cultured in the presenceof DC pretreated with H. polygyrus antigen was done relativeto cells cultured with naïve DC using the 2^–CT methodas described elsewhere (31).

Adoptive-transfer experiments. Sorted CD4⁺ T-cell subpopulations (5 x 10⁵ cells per animal)were injected intraperitoneally into naïve mice in 0.2ml of sterile PBS. Control animals received PBS only. One dayafter transfer, the mice were infected with approximately 200L3 larvae. Four weeks after infection, animals were sacrificed,and the number of adult worms in each animal was determinedand calculated as a percentage of the exact dose of appliedL3 (set as 100%). The success of the infection was determinedby surveying the fecal egg output starting on day 10 postinfection(p.i.). To survey cell survival and to trace transferred cells,the mice received 1 x 10⁷ carboxyfluoroscein succinimidyl ester(CFSE)-labeled or enhanced green fluorescent protein (EGFP)-expressingCD4⁺ cells. Reanalysis by flow cytometry was performed 6 daysafter transfer to the spleen, MLN, and small intestine.

Statistical analysis. Statistical analysis was performed using GraphPad Prism software(San Diego, CA). Statistical significance as indicated in thefigure legends was analyzed by either the Mann-Whitney testor analysis of variance (ANOVA), in combination with Bonferroniposttests.

RESULTS

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RESULTS

Analysis of lymphocytes in MLNs of mice chronically infected with H. polygyrus. To gather information about changes occurring in the MLN afterinfection with H. polygyrus, we analyzed the lymphocyte compositionof the MLN in the chronic phase of infection (28 days p.i.).The absolute cell numbers obtained from the MLN showed a 5.2-foldincrease (P < 0.05) in infected compared to naïve animals(Table 1). CD4⁺ and CD8⁺ T cells, as well as B cells, were analyzedby flow cytometry staining. We found a 4.7-fold (P < 0.05)increase in absolute CD4⁺ and a 4.3-fold (P < 0.05) increasein absolute CD8⁺ T-cell numbers. The strongest increase in totalnumbers, however, was found for B cells (8.3-fold; P < 0.05)(Table 1). Interestingly, the number of CD25⁺ CD103⁺ T cellsincreased 7.8-fold (P < 0.05) within the CD4⁺ T-cell compartment,surpassing the outgrowth of CD25⁺ CD103^– T cells (5.1-fold;P < 0.05) and CD25^– CD103^– T_eff cells (4.5-fold;P < 0.05) (Table 1).

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TABLE 1. Total MLNC numbers and lymphocyte composition of MLNs from naïve and H. polygyrus-infected animals

Analysis of T_reg cells during the course of infection. To further characterize the regulatory CD4⁺ T-cell compartment,we analyzed the frequency of T_reg cells in the MLNs and spleensof H. polygyrus-infected mice at different time points afterinfection. Flow cytometry analysis was performed after stainingof CD4, CD25, CD103, and the transcription factor Foxp3. Bydetecting CD25 and CD103, we were able to distinguish betweenCD4⁺ CD25⁺ CD103^– naturally occurring and CD4⁺ CD25⁺ CD103⁺effector/memory-like T_reg cells (Fig. 1A). Foxp3 expressionlevels were >90% in CD4⁺ CD25⁺ CD103^– cells at mosttime points analyzed (naïve mice and 3, 21, and 28 daysp.i.), with the exception of 6 days p.i., showing a significantdecrease in Foxp3⁺ cells within this compartment (naïve,95.75% ± 0.05%; 6 days p.i., 86.72% ± 1.11%; P< 0.03), arguing for an increased proportion of recentlyactivated effector cells present in MLNC at this time point(Fig. 1B). The CD4⁺ CD25⁺ CD103⁺ subset displayed Foxp3 expressionlevels of >96% at all time points analyzed (Fig. 1B and notshown), while few (<1.8%) CD4⁺ CD25^– CD103^– cellsexpressed Foxp3 (not shown). Comparing percentages of CD4⁺ Foxp3⁺cells between naïve and infected animals (3, 6, 21, and28 days p.i.) revealed no significant differences (Fig. 1E andnot shown). Thus, the increase in total T_reg cells during infectionreflects the increase in CD4⁺ cell numbers. However, we detectedsignificant changes concerning the frequency of effector/memory-likeT_reg cells after infection with H. polygyrus. Within the MLNdraining the site of infection, we determined a significantincrease (P < 0.03) in CD103⁺ T_reg percentages as early asday 6 days p.i. in comparison to naïve animals (Fig. 1C).Within the spleen, a significantly increased percentage wasdetected from day 12 p.i. onward (P < 0.03) (Fig. 1D). Thehigher frequency of T_reg cells expressing CD103 was stable inboth lymphoid compartments until the chronic phase of infection(Fig. 1C and D) and returned to the level of naïve micewhen adult worms were expelled after 8 to 12 weeks (data notshown). The level of CD25⁺ CD103^– T_reg cells showed nosuch increase (data not shown). When analyzing the ratio ofCD103⁺ and CD103^– T_reg cells after gating on all Foxp⁺cells, we rather determined a decrease in CD103^– cellsin infected animals at the chronic stage, counterbalancing theincrease in CD103⁺ cells (Fig. 1F). This finding argues fora conversion of naturally occurring T_reg cells into effector/memory-likeT_reg cells, probably directly related to the infection.

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FIG. 1. Comparison of T_reg numbers in naive and H. polygyrus (H.p.)-infected mice. (A) T_reg cells were detected by flow cytometry based on surface expression of CD4, CD25, and CD103. Shown are plots derived from CD4⁺ MLNC of naïve and chronically infected animals. The data are representative of four animals per group and four independent experiments. (B) The predominantly regulatory phenotype of CD4⁺ CD25⁺ CD103^– (top) and CD4⁺ CD25⁺ CD103⁺ (bottom) cells derived from MLNs could be confirmed by intracellular staining of Foxp3. Four animals per group were analyzed in two independent experiments. (C and D) The frequencies of CD25⁺ CD103⁺ cells within CD4⁺ lymphocytes as detected in MLNs (C) and spleens (D) of animals at different time points after infection (black bars) compared to naïve controls (open bars). The data were derived from four animals per group, and analysis of T_reg cell numbers was performed at least twice for each time point. Means plus standard errors of the mean (SEM) are shown. (E) Frequencies of total Foxp3⁺ cells within CD4⁺ lymphocytes from MLN. Means plus SEM of four animals per group are shown. The data are representative of two independent experiments. (F) Proportion of CD25⁺ CD103^– and CD25⁺ CD103⁺ cells in CD4⁺ Foxp3⁺ cells. Means plus SEM of four animals per group are shown. The data are representative of two independent experiments. (G) Cross sections of the proximal third of the small intestine were stained for Foxp3-expressing cells. Foxp3⁺ T_reg cells were found in the epithelium and in the lamina propria (depicted by black arrowheads). The white arrowheads indicate tissue-dwelling larvae of H. polygyrus at day 6 p.i. (H) Significant increases in T_reg cells within the intestine were detected on days 3, 6, and 12 p.i. Stained cells in 10 high-power fields (HPF) (40-fold magnification) per animal were counted. Means of single animals (closed circles) and means of groups (horizontal lines) are shown. *, significant difference between naïve and infected animals as determined by the Mann-Whitney test (P < 0.05).

To test whether the changes in T_reg numbers found in the lymphaticorgans were also reflected at the site of inflammation, we detectedFoxp3-expressing cells in sections of the proximal third ofthe small intestine (Fig. 1G). In clear contrast to the findingsin lymphatic organs, we detected a transient maximal accumulationof Foxp3⁺ cells at day 6 p.i. (P < 0.016), which graduallyreturned to the basal level seen in naïve animals at latertime points of infection (Fig. 1H). The kinetics of Foxp3⁺ cellswas mirrored by a maximal production of IL-10 and TGF-β1in the small-intestinal tissue at day 6 p.i. (data not shown).Taken together, these data show that T_reg cells with an effector/memory-likephenotype increase strongly during infection with H. polygyrusin the MLN and spleen, while Foxp3-expressing cells accumulateonly transiently at the site of infection.

Cytokine production of complete and CD25/CD103-depleted MLNC. MLNC of H. polygyrus-infected mice were isolated at differenttime points after infection and cultured in the presence ofH. polygyrus antigen to analyze their cytokine profile. Ourdata show that the key Th2 cytokines IL-4 and IL-13 in particular,as well as IL-10, were readily produced in high concentrationsduring the early phase of infection (6 days p.i.), accompaniedby a weak IFN- ${gamma}$ response (Fig. 2A to D). Similar amounts of cytokineswere found during the acute phase (12 days p.i.), except forIFN- ${gamma}$ , which was only marginally produced at this time point(Fig. 2A). At the chronic phase of infection (28 days p.i.),all cytokines analyzed were produced in smaller amounts, especiallyIL-13 and IL-10. Although it did not reach statistical significance,the trend toward lower cytokine production by MLNC from thechronic phase argues for a generally down-regulated parasite-specificresponse. Active TGF-β1 was detected only in very smallamounts (<15 pg/ml) irrespective of the time point (datanot shown). Interestingly, depletion of cells with a mainlyregulatory phenotype (carrying the surface markers CD25 andCD103) (Fig. 2E) resulted in drastic changes in cytokine productionof the remaining MLNC (Fig. 2A to D). First, in the early phaseof infection (6 days p.i.), all cytokines analyzed were producedin smaller amounts after depletion of CD25⁺ and CD103⁺ cells.The finding of lower IL-4, IL-13, IL-10, TGF-β1 (not shown),and IFN- ${gamma}$ levels in cultures depleted of cells carrying CD25and/or CD103 argues for depletion of not only T_reg cells, butalso recently activated T_eff cells at this early time point.We could confirm the presence of effector cells within the CD4⁺CD25⁺ CD103^– subset at 6 days p.i. by detection of Foxp3expression (showing a decline at 6 days p.i.) (Fig. 1B) andby analyzing IL-4 and IL-10 mRNA levels in different CD4⁺ T-cellsubsets kept in cocultures with DC presenting H. polygyrus antigens(Fig. 2F). We determined that CD4⁺ CD25⁺ CD103^– T cellsexpressed large amounts of IL-4 and IL-10 transcripts at thisearly time point, indicating the presence of T_eff and T_reg cellswithin this population. In contrast, the CD4⁺ CD25⁺ CD103⁺ T_regpopulation from the early infection exclusively expressed highlevels of IL-10 (Fig. 2F). As we did not analyze the segregationof the IL-10 production to Foxp⁺ and Foxp3^– cells withinthe CD4⁺ CD25⁺ CD103^– compartment, we cannot exclude acontribution of recently activated effector cells to the IL-10production at the early time point. Hence, the depletion ofcells expressing CD25 and/or CD103 at the early time point removeda significant proportion of recently activated T_eff cells, aswell as T_reg cells, as seen by diminished production of theTh2 cytokines IL-4, IL-13, and IL-10 by the remaining cells.The depletion had no effect with respect to IL-10 productionat later time points (Fig. 2D), arguing that cells other thanT_reg cells may also represent important IL-10 sources duringthe acute and chronic phases. Interestingly, the IL-4 responsein the chronic phase of infection was more vigorous after depletion,indicating a suppressive effect of T_reg cells on the Th2 responsein the chronic phase of infection (Fig. 2B).

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FIG. 2. Cytokine production of MLNC during H. polygyrus infection. (A to D) The cytokine response of MLNC after restimulation with H. polygyrus adult worm antigen was analyzed with cells from animals at days 6, 12, and 28 p.i. The cytokine response of complete MLNC (open bars) was compared to that of MLNC depleted of cells expressing CD25 and CD103 (hatched bars). IFN- ${gamma}$ (A), IL-4 (B), IL-13 (C), and IL-10 (D) production was analyzed. The means plus standard deviations (SD) of three cell pools of two animals each are shown. *, statistical significance comparing cytokine responses before and after depletion as determined by two-way ANOVA, followed by Bonferroni posttests (P < 0.05). The data are representative of two independent experiments. (E) The efficiency of T_reg depletion was determined by flow cytometry. The expression of CD25 and CD103 (upper row) and Foxp3 (lower row) in CD4⁺ cells before (left) and after (right) depletion is shown. (F) The relative expression of IL-4 and IL-10 mRNAs by CD4⁺ T-cell subsets after coincubation with H. polygyrus-primed DC was assessed at day 6 p.i. Means plus SD of three measurements are shown.

Adoptive transfer of CD4⁺ T cells from H. polygyrus-infected mice. To analyze the functions of different CD4⁺ T-cell subsets, weperformed adoptive transfers of CD4⁺ T_eff cells in comparisonto CD4⁺ T_reg subsets derived from chronically H. polygyrus-infectedmice (28 days p.i.). T_eff cells (CD4⁺ CD25^– CD103^–)and CD4⁺ T cells with a regulatory phenotype, namely, CD4⁺ CD25⁺CD103^– and CD4⁺ CD25⁺ CD103⁺ T cells, were transferredto naïve recipients. Control animals received PBS only.One day after transfer, the recipients were infected with adefined dose of larvae. The purity of T_eff cells was >98%for expression of CD4⁺, with <3% remaining CD25⁺ and/or CD103⁺cells, whereas the T_reg compartments were >90% CD4⁺ CD25⁺CD103^– cells and >89% CD4⁺ CD25⁺ CD103⁺ cells, respectively(Fig. 3A). Four weeks after infection, the adult worm burdensof recipients and control animals were assessed. We detecteda significant reduction of 43.7% (P < 0.008) in the wormburden in animals receiving T_eff cells (CD4⁺ CD25^– CD103^–)compared to the PBS control group (Fig. 3B). In contrast, transferof CD4⁺ CD25^– CD103^– T cells from naive mice hadno influence (data not shown), indicating that the reductionwas due to parasite-specific T_eff cells. The protective rolecould be solely ascribed to CD4⁺ T cells, as the transfer ofCD4^– cells had no effect (data not shown). Animals receivingCD4⁺ CD25⁺ CD103^– T_reg cells (comprising >90% Foxp3⁺cells) had worm burdens comparable to that of the PBS control.Similarly, the transfer of CD4⁺ CD25⁺ CD103⁺ T_reg cells (comprising>95% Foxp3⁺ cells) did not result in significant changes.In contrast, transfer of a heterogeneous T-cell population containingT_reg and T_eff cells, namely, CD4⁺ CD103⁺ T cells (with a purityof >95% CD4⁺ cells and >85% CD103⁺ cells but comprisingonly about 70% Foxp3⁺ cells) led to a significant decrease inworm numbers (P < 0.03) comparable to pure CD4⁺ T_eff cells(Fig. 3B). We verified cell survival in separate experimentsusing CFSE-labeled CD4⁺ cells (data not shown). In addition,we performed transfers with EGFP-expressing CD4⁺ cells fromchronically infected donors. The recipients were infected thefollowing day. Six days after transfer, spleen and MLN, as wellas IEL and LPL from the small intestine, were analyzed for transferredcells (Fig. 3C and D). We were able to trace EGFP⁺ cells inall analyzed organs with no significant accumulation in anyof the compartments. The slightly elevated numbers of EGFP⁺cells within MLNC compared to splenocytes merely reflects thehigher CD4⁺ T-cell numbers found in lymph nodes (Fig. 3D). Wealso analyzed percentages of T_reg cells according to expressionof CD25, CD103, and Foxp3 within the EGFP⁺ population and couldshow that T_reg cells survived the transfer (data not shown).

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FIG. 3. Influence of adoptive CD4⁺ T-cell transfer on adult worm burden. T cells of the indicated subtypes (5 x 10⁵) obtained from MLNs and spleens of chronically H. polygyrus-infected mice were transferred to recipients that were subsequently infected with H. polygyrus larvae. Control animals received PBS only. (A) Purity of transferred cells as determined by flow cytometry. Representative data from one of three independent experiments are shown. (B) Adult worm burden in recipients 28 days p.i. Worm counts are shown as percentages of the number of applied larvae. Group sizes varied between 5 and 20 animals. The data originated from three individual experiments. Individual worm counts and medians are shown. The asterisks show statistical significance as determined by a Kruskal-Wallis test followed by a Mann-Whitney test: *, P < 0.05; **, P < 0.01. (C) Tracing of transferred cells in C57BL/6 mice receiving 1 x 10⁷ CD4⁺ cells from chronically infected EGFP-expressing donors. The recipients were infected with H. polygyrus the following day. Examples of flow cytometry plots derived from splenocytes, MLNC, and small-intestinal IEL and LPL 6 days after transfer are shown. (D) Percentages of EGFP⁺ cells within lymphocytes of recipients. Means plus standard deviations for four animals are shown. The data are representative of two experiments.

Hence, CD4⁺ T_eff cells from the chronic phase of an H. polygyrusinfection transferred protection to naïve recipients incontrast to naturally occurring or effector/memory-like T_regcells, which had no intrinsic effect on worm development. Furthermore,transfer of a mixed T-cell population comprising effector andregulatory T cells showed that T_reg cells were not efficientin suppressing the protective effect mediated by T_eff cells.

Cytokine production of CD4⁺ T-cell subsets in the chronic phase of infection. We then analyzed the cytokine production of the CD4⁺ T-cellsubsets used for the transfer experiments to gain informationabout mediators involved in worm expulsion or establishment.H. polygyrus-treated DC were used as antigen-presenting cellsto stimulate the T-cell subsets. We determined that T_eff cells(CD4⁺ CD25^– CD103^–) released IL-4 and IL-13 in thepresence of H. polygyrus-primed DC in contrast to T_reg cells(CD4⁺ CD25⁺ CD103^– or CD4⁺ CD25⁺ CD103⁺) (Fig. 4A and B).However, CD4⁺ CD25⁺ CD103⁺ T cells, in particular, releasedsignificant amounts of IL-10, arguing for the effector/memory-likeT_reg cell subset as an important source of IL-10 (Fig. 4C).Incubation of the CD4⁺ subsets with naïve DC resulted inmarginal release of cytokines by T cells, clearly showing theantigen specificity of the cytokine response. Analysis of activeTGF-β1 in culture supernatants revealed only marginal increasesin cultures with antigen-loaded DC compared to those with naïveDC (data not shown). The generally lower cytokine levels incultures of separated T_eff cells compared to complete MLNC cultures(Fig. 2) is probably due to fewer CD4⁺ T cells present in DCcocultures than in preparations of whole MLNC and to other cytokine-producingcells present in MLNC cultures, like basophils, mast cells,and eosinophils (16).

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FIG. 4. Cytokine production by CD4⁺ T-cell subsets. CD4⁺ T cells were isolated from pooled MLNC and splenocytes of eight mice in the chronic phase of infection (28 days p.i.) according to the indicated surface marker expression. T-cell subsets were incubated for 72 h with naïve bone marrow-derived DC (nDC) or DC pretreated with H. polygyrus adult worm antigen (HpDC). (A to C) Release of IL-4 (A), IL-13 (B), and IL-10 (C) was detected by ELISA. Means plus standard deviations (SD) of triplicate determinations are shown, and the data are representative of three independent experiments. (D to F) Release of IL-4 (D), IL-13 (E), and IL-10 (F) after addition of recombinant mouse IL-2 and ${alpha}$ CD28 to cultures. Mean values plus SD of triplicate determinations of one of two independent experiments with similar results are shown.

While only CD4⁺ CD25⁺ CD103⁺ T cells produced IL-10 in an antigen-specificmanner, we found that both CD25-expressing T-cell subsets producedlarge amounts of IL-10 when optimized conditions were providedby addition of exogenous IL-2 and enhanced costimulation through ${alpha}$ CD28 antibodies (Fig. 4F). Similarly, IL-4 and IL-13 were producedin much larger amounts almost exclusively by CD4⁺ CD25^–CD103^– T_eff cells after enhanced costimulation was provided(Fig. 4D and E). Levels of active TGF-β1 were only marginallyaffected (data not shown). None of the CD4⁺ T-cell subsets fromH. polygyrus-infected mice was found to produce relevant amountsof the Th1 cytokine IFN- ${gamma}$ (data not shown). Hence, our data indicatea dominant and parasite-specific Th2 response by CD4⁺ effectorcells from the chronic phase of infection, while effector/memory-likeCD4⁺ CD25⁺ CD103⁺ T_reg cells probably produce IL-10 in responseto H. polygyrus antigen.

Distribution of antigen-specific CD4⁺ T cells and their cytokine production. To assess the distribution of H. polygyrus-specific CD4⁺ T cellswithin the T_eff and T_reg cell populations, we examined the expressionof CD154 as a marker of antigen-specific CD4⁺ T-cell activation(15, 26). As the detection of CD154 directly ex vivo is notpossible, we used an optimized in vitro protocol (26). Comparisonof CD4⁺ T cells from spleen and MLN showed that in both sites,about 0.2% (MLN, 0.233 ± 0.036 naïve versus infected[P < 0.001]; spleen, 0.246 ± 0.040 naïve versusinfected [P < 0.0003]) of CD4⁺ CD103^– T_eff cells expressedCD154 when restimulated with adult worm antigen in vitro (Fig.5A and B). By additional detection of CD103 and Foxp3, we wereable to distinguish between CD154 expression on T_eff and T_regcells.

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FIG. 5. Distribution of antigen-specific CD4⁺ T cells (CD154⁺) and their cytokine responses. (A) Shown are examples of fluorescence-activated cell sorter plots of MLNC from naïve mice (upper row) and H. polygyrus-infected mice at day 28 p.i. (lower row). The cells were restimulated with H. polygyrus antigen in vitro and stained for CD4, CD154, CD103, and Foxp3. CD4⁺ cells were plotted for expression of CD103 and Foxp3 (left). The middle plots show CD154 expression within the CD4⁺ CD103⁺ Foxp3^– effector population. The right-hand plots show CD154 expression by CD4⁺ CD103^– Foxp3^– effectors. (B and C) Frequencies of CD154-expressing cells within the CD4⁺ CD103^– Foxp3^– (B) and CD4⁺ CD103⁺ Foxp3^– (C) effector populations of MLNs (black bars) and spleens (open bars) after restimulation in vitro. The data were obtained from eight infected and seven naïve mice. Means plus standard errors of the mean (SEM) are shown. The data are representative of three independent experiments. (D) Intracellular staining of cytokines within restimulated CD4⁺ T cells from spleens (28 days p.i.). The cells were gated for expression of CD4 and CD154 (left), and IL-4 and IL-13 (upper row) or IFN- ${gamma}$ and IL-10 (lower row) were determined in CD4⁺ CD154^– cells (center) and CD4⁺ CD154⁺ cells (right). The cytometry plots shown are representative of a group of eight infected mice. (E) IL-4/IL-13 and IFN- ${gamma}$ /IL-10 (F) responses in CD4⁺ CD154⁺ cells after restimulation with H. polygyrus antigen. Means plus SEM of eight animals are shown. The asterisks show statistical significance comparing cells from naïve and infected animals as determined by the Mann-Whitney test: **, P < 0.01; ***, P < 0.001.

Interestingly, when analyzing the level of CD154 on CD103⁺ cellsnot coexpressing Foxp3 and therefore not of regulatory phenotype,we found clearly higher percentages of antigen-specific cellswithin this T_eff subpopulation in MLNs (1.701% ± 0.306%CD4⁺ CD103^– versus CD4⁺ CD103⁺; P < 0.0006) and spleens(0.586% ± 0.144% CD4⁺ CD103^– versus CD4⁺ CD103⁺;P < 0.01) (Fig. 5A and C) of infected animals in comparisonto noninfected mice. In contrast, only low levels of CD154 expressionwere detected on Foxp3⁺ T_reg cells from MLN (<0.03%) andspleen (<0.05%) (data not shown). These data indicate thatmice that received T cells sorted for coexpression of CD4 andCD103 (irrespective of CD25 expression) in transfer studies(Fig. 3B) received a highly enriched T_reg population that stillcontained a small number of antigen-specific effector cellsnot expressing Foxp3. The percentage of antigen-specific effectorswithin the transferred CD4⁺ CD103⁺ cell compartment was as lowas 0.2%, according to CD154 expression, comparable to the valuesfor antigen-specific cells within the CD4⁺ CD103^– effectorcompartment. These CD103⁺ effectors may have led to protection,even though a large number of T_reg cells was cotransferred,arguing for an insufficient capacity of the T_reg cells to controlthe antigen-specific effectors.

We next determined the cytokine production of the antigen-specificCD154⁺ CD4⁺ T cells. Investigation of IL-4, IL-13, IL-10, andIFN- ${gamma}$ production after in vitro restimulation (Fig. 5D) revealeda dominant Th2 response in CD154⁺ CD4⁺ T cells of chronicallyinfected mice, characterized by high expression levels of IL-4(24.55% ± 1.32%), IL-13 (10.48% ± 1.99%), or both(10.26% ± 1.02%) (Fig. 5D and E). Only low levels ofIFN- ${gamma}$ -producing cells were detected in the antigen-specific T-cellcompartment (4.47% ± 0.82%), and the frequencies of IL-10-producingcells were hardly distinguishable from nonspecific background(1.60% ± 0.37%) (Fig. 5D and F). These data again indicatethat the lower worm burden in recipients receiving CD103-expressingCD4⁺ T cells might be due to cotransfer of antigen-specificeffector cells that were able to produce IL-4 and IL-13, therebymediating worm expulsion.

Suppressive effect of T_reg cells from H. polygyrus-infected mice in vitro. To further investigate T_reg cells from worm-infected animals,we analyzed the suppressive activities of sorted T_reg subsetsin vitro. CD4⁺ CD25⁺ CD103⁺ and CD4⁺ CD25⁺ CD103^– T_regcells were isolated from naïve and worm-infected mice inthe acute (12 days p.i.) and chronic (28 days p.i.) phases ofinfection. The cells were added to T_reg-depleted CD4⁺ T cellsfrom naïve mice, which were stimulated polyclonally by ${alpha}$ CD3 antibodies. CD4⁺ CD25⁺ CD103⁺ T_reg cells from infected micesuppressed the proliferation of naïve responder CD4⁺ Tcells more vigorously than their counterparts from naïvecontrols (Fig. 6A and Table 2). For the lowest ratio of CD4⁺CD25⁺ CD103⁺ T_reg cells to responder cells (1:20), reflectingthe in vivo situation, we found that T_reg cells from the chronicphase of infection exhibited the highest suppressive efficiency(P < 0.001 compared to naïve cells and day 12 p.i.).The CD4⁺ CD25⁺ CD103⁺ T_reg cells derived from infected animalswere more efficient in mediating suppression than CD4⁺ CD25⁺CD103^– T_reg cells (P < 0.03 for all tested ratios)(Fig. 6B). As expected, both T_reg subsets showed an anergicphenotype after ${alpha}$ CD3 stimulation (data not shown). These dataclearly indicate the high in vitro suppressive capacity of CD4⁺CD25⁺ CD103⁺ T_reg cells derived from the chronic phase of infectionwith regard to activation and proliferation of CD4⁺ T cells.

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FIG. 6. Suppressive capacities of T_reg cells in vitro. CD4⁺ CD25⁺ CD103^– and CD4⁺ CD25⁺ CD103⁺ T_reg cells were purified from splenocytes and MLNC of H. polygyrus-infected (12 and 28 days p.i.) and naïve mice. CD4⁺ CD25^– CD103^– responder cells were isolated from naïve animals. (A and B) The suppressive capacities of CD4⁺ CD25⁺ CD103⁺ T_reg cells (A) and of CD4⁺ CD25⁺ CD103^– T_reg cells (B) from naïve mice (open bars) and infected animals at the acute phase (12 days p.i.) (gray bars) or chronic phase (28 days p.i.) (black bars) of infection were analyzed. The ratios of T_reg cells and responder CD4⁺ T cells are indicated. Proliferation of CD4⁺ T cells after stimulation with ${alpha}$ CD3 antibodies was detected by [³H]thymidine uptake. Means plus standard errors of the mean of quintuple determinations are shown. The data shown are representative of two independent experiments.

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TABLE 2. Statistical analysis of suppressive efficiencies of T_reg cell subsets from naive and H. polygyrus-infected mice

DISCUSSION

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DISCUSSION

In this study, we investigated the roles of different CD4⁺ T-cellsubsets in a chronic intestinal worm infection. Adoptive transferof CD4⁺ cells from the chronic phase of an H. polygyrus infectioncontaining small numbers of antigen-specific T_eff cells ledto significant protection in recipients. In contrast, adoptivetransfer of T_reg cells did not alter the worm burden, althoughT_reg cells significantly suppressed CD4⁺ T-cell proliferationin vitro. Hence, our data clearly point to the importance ofCD4⁺ T_eff cells in mediating host protection and worm expulsion.Our data provide evidence for the following traits of T_eff/T_reginteraction. First, T_eff cells that arise during a primary H.polygyrus infection exhibit the ability to mediate protection.Second, T_eff cells persist in chronically infected mice, despitestrong cellular suppression (10, 49, 52). Third, about 0.24%of CD4⁺ T_eff cells are antigen-specific cells, based on expressionof CD154, containing highly enriched frequencies of IL-4- andIL-13-producing cells responding to parasite antigens. Fourth,T_reg cells are probably an important source of IL-10 duringchronic infection. Fifth, elevated numbers of effector/memory-likeT_reg cells persist in lymphatic organs until the chronic phase,and T_reg cells derived from infected animals show an augmentedsuppressive capacity in vitro.

Our study revealed a significant and permanent increase in effector/memory-like(CD103⁺) T_reg cell numbers in lymphatic organs as early as day6 p.i. However, only a transient increase in T_reg cells wasdetected at the site of inflammation, which might representa host reaction to control inflammatory responses induced byinnate immune and T_eff cells. The peak of T_reg cells in thesmall intestine at day 6 p.i. is in accordance with the timepoint of intense inflammation around tissue-invading larvae,characterized by accumulation of mainly granulocytes and, toa lesser extent, macrophages and CD4⁺ T cells (4, 43). Interestingly,it has been shown that T_reg cells not only control inflammatoryresponses directly or indirectly driven by T_eff cells, but alsosuppress innate immune responses in the absence of T_eff cells(36). Therefore, it is conceivable that T_reg cells induced bythe nematodes are recruited to modulate innate and adaptiveimmune responses. The resulting immunosuppression could controlexcessive pathology and favor prolonged parasite survival. Helminth-inducedT_reg cells have been shown to be involved in immunomodulationin various helminth infections, such as human infections withOnchocerca volvulus (51) or murine infections with Litomosoidessigmodontis (59), H. polygyrus (14), and Schistosoma mansoni(6, 29, 37). The general notion is that during helminth infections,T_reg cells might have the function of facilitating parasitesurvival and diminishing immunopathology (34, 35), but theirconcrete role is not yet fully elucidated.

We provide evidence that during the early phase of infection,activated T_eff and T_reg cells are both important sources ofIL-10. However, during the chronic phase of infection, T_regcells probably represent the main T-cell source of IL-10. Hence,our data indicate that not only T_reg cells, but also effectorcells provide IL-10 that could have a role in dampening exaggeratedinflammation, as shown previously for Th1 and Th2 effector cells(3, 8, 25, 61). Whether T_reg cells in nematode infections mediatesuppression via IL-10, TGF-β, or both is still under investigation(8, 27, 39, 59). Increases in TGF-β1 expression by CD4⁺and CD4^– cells and surface-bound TGF-β1 on CD4⁺ cells,as well as increased plasma levels of active TGF-β1 duringinfection with H. polygyrus, have been shown by others (14,56, 68). In our system, T_reg cells from the chronic stage ofinfection seem to exert their effects via IL-10, supported bythe fact that we detected only low levels of active T_reg-derivedTGF-β1. Of note, our analysis of the TGF-β1 productionby CD4⁺ T-cell subsets is restricted to the secreted activeform, and currently we cannot exclude differences with respectto the secreted inactive form of the molecule. By analyzingtissue samples from the small intestine, we found elevated TGF-β1levels at the site of infection in the early phase (6 days p.i.)(data not shown), perhaps indicating tissue repair in this phaseof active inflammation.

In addition to T cells, B cells can also serve as major sourcesof IL-10 (45, 46), and B cells in protozoan and helminth infectionshave been shown to produce IL-10 in response to pathogen-derivedantigens (2, 17, 46). To date, few data on B cells as a sourceof IL-10 in intestinal nematode infections are available. Wedetected large increases in B-cell numbers in MLNs of infectedanimals, and further analysis of these cells as possible sourceof IL-10 during H. polygyrus infection is needed.

This study showed that especially CD4⁺ CD25⁺ CD103⁺ T cellsfrom mice chronically infected with H. polygyrus produce IL-10in a parasite-specific manner. The high frequency of Foxp3-expressingcells within this T-cell population strongly suggests effector/memory-likeT_reg cells as a parasite-specific source for IL-10, althoughwe cannot completely rule out the possibility that Foxp3^–effector cells or adaptive T_reg cells may contribute to thedetected IL-10 production. In mice infected with S. mansoni,CD4⁺ CD25⁺ T cells, whether Foxp3⁺ or Foxp3^–, have beenidentified as sources of IL-10 (6, 58).

We revealed a disproportionate increase in CD25⁺ CD103⁺ T_regcells within the CD4⁺ T-cell compartments of infected animals.Similar to what has been described for infection with S. mansoni(6), we detected only minor changes in the total T_reg cell numbersas determined from Foxp3 expression in lymphatic organs. However,we found a significant increase in cells expressing CD103 withinthe regulatory T-cell compartment, arguing for a specific roleof these effector/memory-like T_reg cells in modulating the immuneresponse to H. polygyrus. To test this hypothesis, we performedsuppression assays with responder CD4⁺ T cells from naïvemice. These in vitro assays demonstrated that especially CD4⁺CD25⁺ CD103⁺ T_reg cells isolated from the chronic phase of infectionstrongly suppressed the proliferation of CD4⁺ T cells when addedin a physiological ratio of T_reg to responder cells (1:20).A particularly potent suppressive capability of CD4⁺ CD25⁺ CD103⁺T_reg cells in comparison to CD4⁺ CD25⁺ CD103^– T_reg cellsin vitro and in vivo has also been shown by others (30, 57).We expected that adoptive transfer of T_reg cells might interferewith the primary Th2 response to H. polygyrus, entailing increasedworm burdens, as studies on protective immunity against H. polygyrushave shown that severe combined immunodeficient mice lackingT and B cells and mice depleted of CD4⁺ T cells harbor higherworm burdens than wild-type or untreated controls (63, 64).However, in spite of the high suppressive capacity of CD103⁺T_reg cells in vitro, our adoptive-transfer model did not revealan influence of T_reg cells on the worm burden in vivo. Transferof CD4⁺ CD25⁺ CD103⁺ T_reg cells, as well as CD4⁺ CD25⁺ CD103^–T_reg cells, did not alter worm numbers, whereas transfer ofa mixture of T_reg and T_eff cells (CD4⁺ CD103⁺ T cells) significantlylowered worm burdens, arguing against a major control of effectorresponses by T_reg cells in vivo. The discrepancy between thesuppressive activity of CD103⁺ T_reg cells in vitro and the failureto interfere with worm expulsion in vivo might be due to multiplefactors. First, T_reg cells might be involved in suppressingpathology, but not in facilitating worm survival. Second, thetransferred CD4⁺ CD103⁺ T-cell population represented a heterogeneouspool of T_reg and T_eff cells containing the lowest percentageof Foxp3⁺ cells (<70%) in comparison to the CD4⁺ CD25⁺ CD103⁺and CD4⁺ CD25⁺ CD103^– subsets (both $≥$ 90%). Third, reductionof the adult worm burden in recipients receiving CD4⁺ CD103⁺T cells coincided with a significant proportion of parasite-specificeffector cells within the CD103⁺ Foxp3^– cell compartment,as shown by expression of CD154 after antigen stimulation. Finally,the conditions in vitro versus in vivo were clearly different.In vitro, T_reg cells drastically inhibited the proliferationof naïve CD4⁺ responder T cells after polyclonal stimulation,whereas in vivo, T_reg cells had to combat antigen-specificallyactivated T_eff cells.

We have provided data on the distribution and cytokine profileof parasite-specific CD4⁺ cells using the marker CD154, recentlyshown to exhibit exquisite specificity for antigen-activatedCD4⁺ cells in the human and mouse systems (15, 26). Our approachrevealed low percentages (<1%) of antigen-specific cellsin the chronic phase, producing predominantly IL-4 and IL-13.Although cytokine-producing CD4⁺ T cells were also detectedat low percentages among CD154^– cells, the respondersto worm antigens were highly enriched within the CD154⁺ population.In contrast, much higher frequencies of IL-4-producing cellsare described for infections with H. polygyrus in GFP-IL-4 reportermice (41). Several factors may have led to the marked discrepancies.First, Mohrs et al. reported that not all GFP⁺ cells secreteIL-4 in response to stimulation with H. polygyrus antigen extractsand provided evidence that CD4⁺ T cells recently producing IL-4in vivo are impaired in their cytokine response in vitro (41).This finding might, in part, explain the lower frequencies ofantigen-specific IL-4 producers detected in our in vitro assays.Second, different conditions, such as the infection time pointanalyzed, the source of antigen-presenting cells, in vitro cellnumbers during restimulation, or antigen dose, might have ledto an underestimation of specific CD4 T-cell numbers based onCD154 expression. However, despite the marked difference betweenthe frequencies of antigen-specific CD4⁺ T cells presented hereand for the IL-4 reporter system, our data show that the CD154technique facilitates the analysis of a broader spectrum ofpathogen-specific cytokine responses in a nonmanipulated immunesystem.

Adoptive transfer of CD4^– cells did not show an effecton the worm burden (data not shown). This observation furthersupports the concept that resistance to gastrointestinal helminthsis dependent on CD4⁺ Th2-type immune responses, as shown inanimal models with H. polygyrus or Nippostrongylus brasiliensis(11, 64, 65), as well as in humans infected with Ascaris lumbricoidesand Trichuris trichiura (24, 62).

Hence, our study is in line with the recent finding that memoryCD4⁺ T cells develop after infection with the gastrointestinalnematode Trichuris muris and mediate protection against rechallenge(69). In a recent publication introducing alternatively activatedmacrophages as an effector population essential for protectiveimmunity to challenge infections with H. polygyrus, it was shownthat memory Th2 cells derived from H. polygyrus-cured mice transferredprotection against a primary infection (4). The protective effectof Th2 memory cells was more pronounced than what we found inour transfer model using T_eff cells from an ongoing infection.It would be interesting to investigate whether differences in,e.g., the homing receptor repertoires or susceptibility to inducedcell death between memory and effector T cells might be responsiblefor this phenomenon.

In conclusion, our data indicate that in our model system, tippingthe balance of effector T cells during infection strongly influencesthe survival of parasitic nematodes, while T_reg cells may havefunctions that are not directly related to worm persistence.

ACKNOWLEDGMENTS

The study was supported by Deutsche Forschungsgemeinschaft SFB650 to S.H., R.L., J.H., and A.H.

We thank B. Sonnenburg and M. Müller for excellent technicalassistance and K. Raba and T. Kaiser for FACS sorting.

FOOTNOTES

* Corresponding author. Mailing address: Department of Molecular Parasitology, Humboldt-University Berlin, Philippstr. 13, 10115 Berlin, Germany. Phone: (49) 30 2093 6450. Fax: (49) 30 2093 6051. E-mail: susanne.hartmann{at}rz.hu-berlin.de

Published ahead of print on 3 March 2008.

Editor: J. F. Urban, Jr.

REFERENCES

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