Contribution of NK, NK T, {gamma}{delta} T, and {alpha}{beta} T Cells to the Gamma Interferon Response Required for Liver Protection against Trypanosoma cruzi

In the present work, we show that intracellular Trypanosomacruzi is rarely found in the livers of acutely infected mice,but inflammation is commonly observed. The presence of numerousintrahepatic amastigotes in infected gamma interferon (IFN- ${gamma}$ )-deficientmice corroborates the notion that the liver is protected byan efficient local immunity. The contribution of different cellpopulations was suggested by data showing that CD4- and CD8-deficientmice were able to restrain liver parasite growth. Therefore,we have characterized the liver-infiltrating lymphocytes anddetermined the sources of IFN- ${gamma}$ during acute T. cruzi infection.We observed that natural killer (NK) cells increased by day7, while T and B cells increased by day 14. Among CD3⁺ cells,CD4⁺, CD8⁺, and CD4^– CD8^– cell populations weregreatly expanded. A large fraction of CD3⁺ cells were positivefor PanNK, a ß1 integrin expressed by NK and NK Tcells. However, these lymphocytes were not classic NK T cellsbecause they did not express NK1.1 and showed no preferentialusage of Vß8. Otherwise, liver NK T (CD3⁺ NK1.1⁺)cells were not increased in acutely infected mice. The majorityof PanNK⁺ CD4⁺ and PanNK⁺ CD8⁺ cells expressed T-cell receptor ${alpha}$ ß (TCR ${alpha}$ ß), whereas PanNK⁺ CD4^– CD8^–cells were positive for TCR ${gamma}$ ${delta}$ . In fact, ${gamma}$ ${delta}$ T cells showed the mostremarkable increase (40- to 100-fold) among liver lymphocytes.Most importantly, intracellular analysis revealed high levelsof IFN- ${gamma}$ production at day 7 by NK cells and at day 14 by CD4⁺,CD8⁺, and CD4^– CD8^– TCR ${gamma}$ ${delta}$ ⁺ cells. We concluded thatNK cells are a precocious source of IFN- ${gamma}$ in the livers of acutelyinfected mice, and, as the disease progresses, conventionalCD4⁺ and CD8⁺ T cells and ${gamma}$ ${delta}$ T cells, but not classic NK-T cells,may provide the IFN- ${gamma}$ required for liver protection against T.cruzi.

INTRODUCTION

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Introduction

During acute infection by Trypanosoma cruzi, the causative agentof Chagas' disease, a hepatic affection has been demonstratedboth in human patients (7, 53) and experimental animals (4,9, 47), i.e., hepatomegaly, one of the clinical features mentionedby Carlos Chagas in the original description of the illnessthat bears his name (12). A priori, macrophages, Kupffer cells,and hepatocytes (41) can be colonized by T. cruzi parasites.Moreover, because it contains cells from the mononuclear phagocyticsystem, the liver plays a major role in the clearance of bloodtrypomastigotes, a function that gains special relevance afterthe generation of specific antibodies (51).

A preliminary histological study by our research group of thelivers of acutely infected mice revealed the presence of inflammatoryinfiltration, but amastigote nests were rare, a surprising resultsince these animals had high levels of parasitemia. The paucityof liver T. cruzi organisms could be due to an efficient controlof the parasite by the local immune system. This is an attractivehypothesis, considering that the liver is a peculiar organ,which guarantees both an effective first line of protectionagainst pathogens (52) and a tolerogenic response to gut-derivedantigens that come through the portal vein (64).

Many different cell types and soluble molecules have been shownto participate in the systemic control of T. cruzi parasites.Mice lacking B cells or helper or cytotoxic T cells (46, 57,60) and mice deficient in gamma interferon (IFN- ${gamma}$ ), interleukin-12(IL-12), tumor necrosis factor ${alpha}$ , or granulocyte-macrophage colony-stimulatingfactor are highly susceptible to infection (2, 33, 42, 59).The major protective role of IFN- ${gamma}$ suggests that parasite controlis dependent on the TH1 pathway of immune response. IFN- ${gamma}$ notonly activates macrophages to destroy ingested parasites (63)but also recruits mononuclear cells through chemokine production,induces immunoglobulin isotype switch to cytophilic and complement-fixingimmunoglobulin G2a antibodies (54), and up-regulates the expressionof high-affinity Fc receptors (Fc ${gamma}$ RI) on macrophages, which increaseparasite clearance (61).

Natural killer (NK) cells also seem to play a protective roleat the early stages of infection (48). The role of NK T cellsis, nevertheless, controversial, since opposite conclusionscan be taken from reports that evaluated the course of T. cruziinfection in CD1d knockout (CD1dKO) and J ${alpha}$ 281KO mice, two strainsknown to be deficient in the NK T cell population (18, 19, 38,44). These discrepancies could be attributed to the source ofT. cruzi used in these studies or to the differences betweenthe two KO strains, inasmuch as besides classic NK T cells,which express the invariant T-cell receptor ([TCR] J ${alpha}$ 281), CD1dKOmice lack nonclassic NK T cells that use other TCRs (18).

The phenotypic and functional characterization of the differentlymphocyte populations infiltrating the liver during the acuteT. cruzi infection has not been thoroughly investigated. Thisanalysis could be of great value to unravel the elements involvedin the local control of the parasite. Besides that, it willpermit evaluation from the beginning of the infection of theanti-T. cruzi effector mechanisms in a nonlymphoid tissue, aperspective ignored by most of ex vivo analyses that focus eitherthe blood or the secondary lymphoid organs. Moreover, as theliver is an organ that selectively recruits NK and NK T cells(17), this study could contribute to elucidating the role ofthese cell populations in the immune response to the parasite.

In this paper, we have approached the phenotypic characterizationof IFN- ${gamma}$ -producing cells in the liver in acutely infected mice.In order not to draw conclusions that may reflect the peculiaritiesof a particular mouse strain, this study was carried out withfour different mouse strains that are known to differ in theirsusceptibility to T. cruzi.

MATERIALS AND METHODS

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Materials and Methods

Mice. Six to eight-week-old C57BL/6, BALB/c, A/J, C3H/HePAS (lipopolysaccharide-responsive)(55), C57BL/6 IFN- ${gamma}$ -KO (16), C57BL/6 CD4KO, and C57BL/6 CD8KOfemale mice were bred under specific pathogen-free conditionsat the Isogenic Mice Facility, Instituto de Ciências Biomédicas,Universidade de São Paulo, Brazil.

Parasites and infection. T. cruzi from the Y strain was maintained by weekly passagesin A/J mice. Mice were infected with 1,000 trypomastigote bloodforms. Parasitemia levels were determined by microscopic examinationof 5-µl blood samples obtained from the tail vein.

Isolation of intrahepatic leukocytes. Intrahepatic leukocytes were isolated as previously described(15). Briefly, after perfusion with phosphate-buffered saline,the liver was removed, and a cellular suspension was prepared,treated with collagenase 0.2% (Invitrogen, Carlsbad, CA), washed,admixed with 40% metrizamide (Sigma, St. Louis, MO) solutionin phosphate-buffered saline, and gently overlaid with RPMI1640 medium supplemented with penicillin (100 U/ml), streptomycin(100 µg/ml), 2-mercaptoethanol (50 µM), L-glutamine(2 mM), sodium pyruvate (1 mM), and 1% heat-inactivated fetalcalf serum. Culture medium and supplements were purchased fromInvitrogen. After centrifugation at 1,500 x g and 4°C, leukocyteswere harvested from the medium-metrizamide interphase.

Phenotypic characterization of intrahepatic leukocyte populations. The phenotype of intrahepatic leukocytes was determined usinga three-color FACSCalibur cytometer (Becton-Dickinson, San Jose,CA), after cells were stained with fluorescein isothiocyanate-,phycoerythrin-, Cy-Chrome-, or biotin-conjugated monoclonalantibodies (MAbs) to CD4 (clone H129.19), CD8 (clone 53-6.7),B220 (clone RA3-6B2), CD3 (clone 145-2C11), TCR ${alpha}$ ß (cloneH57-597), TCR ${gamma}$ ${delta}$ (clone GL3), Vß8.1 and 8.2 (clone F23.1),CD11b (Mac-1; clone M1/70), CD11c (clone HL-3), Ly6G (cloneRB6-8C5), NK1.1 (clone PK136), and PanNK (clone DX5) purchasedfrom PharMingen (San Diego, CA). When biotin-conjugated MAbswere used, fluorochrome-labeled streptavidin (PharMingen) wasadded as a second-step reagent. The number of each cell populationper liver was determined by multiplying its respective frequencyamong liver leukocytes by the total number of leukocytes perliver estimated in a Neubauer chamber.

Intracellular detection of IFN- ${gamma}$ . Intrahepatic leukocytes were cultured overnight with Golgistopat 37°C in a 5% CO₂ atmosphere, according to the manufacturer'sinstructions, in the presence or absence of plate-bound anti-CD3(10 µg/ml; clone 145-2C11) and soluble anti-CD28 (2 µg/ml;clone 37.51) MAbs. After being washed, cells were surface stainedwith fluorescein isothiocyanate- or Cy-Chrome-conjugated MAbsto CD4, CD8, NK1.1, and TCR ${gamma}$ ${delta}$ . Cells were then fixed with theCytofix/Cytoperm buffer and incubated with phycoerythrin-labeledMAb to IFN- ${gamma}$ (XMG-1.2) diluted in Perm/Wash buffer. The analysiswas done in a FACSCalibur cytometer. All reagents were purchasedfrom PharMingen.

Histopathological analysis. Liver and heart tissue specimens were collected and fixed inparaformaldehyde (Merck, La Jolla, CA) for further processing.Paraffin-embedded tissue sections were stained with hematoxylin-eosinand analyzed by optical microscopy. The hepatic inflammatoryinfiltrates were photographed using an image analysis system(Image Pro Plus Media Cybernetics, Silver Spring, Md.).

Statistics. Statistical analysis was performed by analysis of variance andTukey's multiple comparison tests, using GraphPad PRISM 4 software.Differences between two groups were considered significant atP values of <0.05.

RESULTS

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Results

T. cruzi parasitism in the liver of acutely infected mice of different strains. To evaluate whether the paucity of T. cruzi cells in the liveris a general phenomenon, mice of four different isogenic strainswere infected with 1,000 blood forms of the Y strain, a virulentand reticulotropic parasite isolate (1). According to parasitemiacurves and survival indexes (Fig. 1), C57BL/6 mice displayeda resistant phenotype, with a low first parasitemia peak, anegligible second peak, and absence of mortality. A/J and C3H/HePASmice were highly susceptible, with 100% of the animals dyingduring an abrupt second parasitemia peak. BALB/c mice exhibitedan intermediate phenotype, with a low second parasitemia peakand increased survival time in relation to A/J and C3H/HePASmice.

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FIG. 1. Parasitemia curves and survival index in acutely T. cruzi-infected C57BL/6, BALB/c, A/J, and C3H/HePAS mice. Mice were infected with 1,000 blood forms of T. cruzi, and the parasitemias were screened by microscopic observation of 5-µl blood aliquots at different time points after infection. In panel A, results represent the mean ± SD of parasitemia levels (n = 5). In panel B, results represent the survival index (n = 5). A representative experiment (out of three experiments) is shown.

Analysis of liver sections up to days 14 to 16 postinfection(p.i.) revealed the presence of cell infiltrates, which wasmore pronounced in C57BL/6 (Fig. 2A) and BALB/c mice than inC3H/HePAS and A/J mice (data not shown). Liver lesions consistedof focal infiltrates all over the hepatic lobules. Because oftheir intrasinusoid location and the presence of hyaline secretion,cell aggregates often had a pseudo-granuloma appearance (Fig.2C). Mononuclear cells, a few neutrophils, and, rarely, eosinophilsconstitute these focal infiltrates. Liver inflammation was discreteat day 7 (focal infiltrates occupied less than 2% of the hepatictissue), but it increased by days 12 to 14 p.i., both as intrasinusoidalfocal aggregates and as a diffuse infiltration of mononuclearcells scattered along the sinusoids.

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FIG. 2. Histopathological analysis of the liver in acutely T. cruzi-infected C57BL/6 and IFN- ${gamma}$ -KO mice. Representative photographs of C57BL/6 (A and C) and IFN- ${gamma}$ -KO (B, D, E, and F) mice at days 14 and 12 p.i., respectively. Parasite nests (E) and scattered amastigotes (F) amid infiltrates in the livers of infected IFN- ${gamma}$ -KO mice are shown. Scale bars, 200 µm (A and B), 50 µm (C and D), and 25 µm (E and F).

In spite of this intense inflammatory scenario and of the presenceof blood parasites, we were unable to visualize liver T. cruzinests in most of these mice, though at least six nonconsecutiveslides were carefully screened. Moreover, the few amastigotenests showed signs of degeneration. These results were in sharpcontrast to those of the heart, where T. cruzi nests were foundin the myocardium of all mice of the four strains, in most caseswithout surrounding infiltrates or degenerative signs (datanot shown). Taken together, these results indicate that thedifficulty in visualizing T. cruzi parasites in the liver duringacute infection is a general phenomenon that occurs in micewith different levels of parasitemia.

Contribution of IFN- ${gamma}$ and CD4⁺ and CD8⁺ T cells for liver protection against T. cruzi. The scarcity of T. cruzi nests found in the livers of acutelyinfected mice could be due to low invasion of hepatic cellsand/or to efficient control of the parasite by local immunity.To evaluate the latter possibility, we did a histopathologicalanalysis of the livers of infected mice lacking IFN- ${gamma}$ , a keymediator of the anti-T. cruzi immune response (24, 59). At day10 p.i., liver sections of IFN- ${gamma}$ -KO mice revealed the presenceof parasite nests, as well as extracellular amastigotes scatteredamong the inflamed tissue, a picture that dramatically increasedby day 12 p.i. (Fig. 2E and F). At this time, liver inflammatoryinfiltrates in IFN- ${gamma}$ -KO mice were considerably more intense (Fig.2B and D) and, as reported in mycobacteria infections (20),contained higher numbers of eosinophils (Fig. 2F) than C57BL/6mice (Fig. 2A and C) or than mice of the other nondeficientstrains (data not shown). Multiple necrotic foci were observedin the livers of acutely infected IFN- ${gamma}$ -KO mice. In accordancewith its susceptible phenotype, IFN- ${gamma}$ -KO mice showed high levelsof parasitemia, with the majority of them dying around day 14p.i. (data not shown). These results indicate that T. cruzireplication inside liver cells is tightly controlled by theimmune system and, most importantly, that IFN- ${gamma}$ has a major rolein this process.

To evaluate the contribution of CD4⁺ and CD8⁺ T cells for liverprotection against T. cruzi, we then analyzed the parasitemiaand the hepatic lesions in acutely infected CD4KO and CD8KOmice. Liver inflammation in these mice was notably less intensethan in infected IFN- ${gamma}$ -KO mice but slightly higher than in infectedC57BL/6 mice, with maximum values attained from days 13 to 20p.i. (data not shown). Unlike results in IFN- ${gamma}$ -KO mice, parasiteswere not detected in liver sections of CD4KO and CD8KO miceuntil day 13 of infection (Table 1). At day 13 p.i., 9 to 12amastigote nests were found per liver slide of these mice, whichcontrasted with both the scarcity of parasites detected in C57BL/6mice and the massive T. cruzi replication observed in IFN- ${gamma}$ -KOmice. Interestingly, by day 16 p.i., the number of amastigotenests in the livers of CD4KO and CD8KO mice declined to 0.3± 0.5 (mean ± standard deviation [SD]) and 1.2± 2.1, respectively, and remained at this low level upto day 20 p.i. The apparent control of liver parasites in CD4KOor CD8KO mice at the late acute phase contrasted with theirparasitemia curves, which, although not different from thoseof C57BL/6 mice up to day 13 p.i., steadily increased from thistime point until the death of mice around day 20 p.i. (datanot shown). Moreover, in infected CD4KO and CD8KO mice, theevolution of tissue parasitism in the liver differed from thatobserved in the heart, where the number of amastigote nestspersisted at similarly high levels from days 13 to 20 p.i. (datanot shown). From these experiments, we concluded that neitherCD4⁺ T cells nor CD8⁺ T cells are essential for liver protectionagainst T. cruzi, even though the presence of both T cell populationsensures an earlier parasite control.

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TABLE 1. Liver parasitism in the acute phase of T. cruzi infection^a

Analysis of leukocyte populations in the liver of acutely infected mice. To analyze the leukocyte populations involved in liver protectionagainst T. cruzi, we have characterized by flow cytometry theinfiltrating cells of perfused livers at days 7 and 14 of infection.In C57BL/6, C3H/HePAS, BALB/c and A/J mice, the numbers of cellsisolated from the liver progressively increased in parallelwith acute infection (data not shown). Moreover, confirmingthe histological analysis, acutely infected C57BL/6 mice showedhigher numbers of infiltrating cells, followed by BALB/c mice,compared with the other mouse strains.

The overall picture of lymphocyte subsets was similar in thefour mouse strains and consisted of an early increase in NK(PanNK⁺ CD3^–) cells and a late increase in T and B cells(Fig. 3). At day 7 p.i., PanNK⁺ CD3^– cells predominatedamong liver lymphocytes in the four mouse strains, with totalnumbers reaching three to eight times those of noninfected controls(Fig. 3A). In infected C3H/HePAS and BALB/c mice, PanNK⁺ CD3^–cells attained remarkable frequencies of up to 30% of liverleukocytes. PanNK⁺ CD3^– cells were already increased atday 4 p.i, with their frequency among liver leukocytes, butnot their total numbers per liver, even higher than at day 7p.i. (data not shown). At day 14 p.i., total numbers of liverPanNK⁺ CD3^– cells remained high (Fig. 3A), but their percentagesdecreased due to a sharp increase in T- and B-cell populations(Fig. 3C to F). Liver-infiltrating T cells included CD4⁺, CD8⁺,and CD3⁺ CD4^– CD8^– cells. Interestingly, in thedifferent mouse strains, the increase in liver lymphocyte populationswas always higher for CD8⁺ cells than for CD4⁺ cells. Thus,while in noninfected livers the CD4⁺/CD8⁺ cell ratio rangedfrom 1.3 to 3.5 at days 7 and 14 p.i., it dropped to 0.9 to1.8 and 0.6 to 1.2, respectively. The number of B (B220^HIGH)cells also increased in the livers of acutely infected mice;for T cells, the increase was only evident by day 14 of infection.Concerning the peculiarities of the different mice, it is worthnoting the low numbers of CD3⁺ CD4^– CD8^– cells inC57BL/6 mice (P < 0.05) and B cells in C3H/HePAS mice (P< 0.001)at day 14 p.i., compared to mice from the other strains.A complementary observation was that infected C3H/HePAS micepresented low numbers of B cells not only in the liver but alsoin the spleen (data not shown), indicating that the B cell responseto T. cruzi is impaired in these mice.

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FIG. 3. Total numbers per liver of the different cell populations in acutely T. cruzi-infected C57BL/6, BALB/c, A/J, and C3H/HePAS mice. Seven and fourteen days after infection, intrahepatic leukocytes were isolated from perfused livers. The total numbers of NK (PanNK⁺ CD3^– Mac1^LOW) cells (A), macrophages and PMN cells (Mac1^HIGH PanNK^– CD3^– B220^–) (B), CD4⁺ (CD4⁺ CD8^– CD3⁺) T cells (C), CD8⁺ (CD4^– CD8⁺ CD3⁺) T cells (D), double-negative (CD4^– CD8^– CD3⁺) T cells (E), and B (B220^HIGH) cells (F) were estimated as described in Material and Methods. Noninfected animals were used as controls. Results represent the mean ± SD (n = 3) of a representative experiment (out of three experiments).

Besides lymphocytes, for the four mouse strains, a notable increasein the number of Mac1^HIGH PanNK^– CD3^– B220^–liver cells was observed at day 7 p.i., with a little incrementat day 14 p.i. (Fig. 3B). These nonlymphocytic hepatic leukocytes,which reached higher numbers in infected C57BL/6 mice (P <0.05, at day 14 p.i.), included cells with size and granularitytypical of macrophages and polymorphonuclear (PMN) cells. Moreover,a fraction of these cells expressed high levels of Ly6G (Gr-1,a PMN cell marker), both in controls (21 to 33% for the differentstrains) and in infected mice (53 to 57% at day 7 p.i. and 46to 61% at day 14 p.i.). Microscopic analysis of Giemsa-stainedslides of liver leukocyte suspensions confirmed the increaseof PMN cells during the acute infection (data not shown).

Characterization of NK cells in the liver of acutely infected mice. NK cells constitute an early source of IFN- ${gamma}$ in infections bydiverse pathogens, including T. cruzi (10). In Fig. 3A, NK cellswere characterized by the absence of CD3 and the presence ofVLA-2 ${alpha}$ chain (CD49b, recognized by PanNK MAb), a ß1integrin mostly expressed by NK and NK T cells (6). To confirmthat PanNK⁺ CD3^– cells were indeed NK cells, CD3^–cells were analyzed for the concomitant expression of PanNKand NK1.1. This study was done in C57BL/6 mice once the NK1.1epitope detected by PK136 MAb was restricted to this strain.As shown in Fig. 4A, at days 7 and 14 p.i., 79% and 76% of PanNK⁺CD3^– cells, respectively, coexpressed NK1.1, confirmingthat this population is mainly composed by NK cells. In theCD3^– population, we also observed small percentages ofNK1.1⁺ PanNK^– and NK1.1^– PanNK⁺ cells. Most importantly,after T. cruzi infection, a large fraction of liver NK cellsspontaneously produced IFN- ${gamma}$ , a phenomenon that attained itsmaximum at day 7 p.i. In Fig. 4B, we show the data from a representativeexperiment in which 6.9% ± 1.5% of NK cells from C57BL/6mice at day 7 p.i. produced IFN- ${gamma}$ . Indeed, at this time of infection,NK cells comprised around 90% of all IFN- ${gamma}$ -producing cells inthe liver. Considering the total numbers of IFN- ${gamma}$ -producing NKcells, an 8- to 58-fold increase was observed at day 7 p.i.in relation to noninfected controls, although A/J mice presentedsignificantly lower numbers compared to the other mouse strains(P < 0.01) (Fig. 4C). From these results, we concluded thatNK cells are an early source of IFN- ${gamma}$ in the livers of T. cruzi-infectedmice. The notable accumulation of PanNK⁺ CD3^– large cellsin the four mouse strains (Fig. 4D) confirmed that activation/proliferationof NK cells is a general phenomenon in a liver response to T.cruzi parasites.

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FIG. 4. Characterization of NK cells in the livers of acutely T. cruzi-infected C57BL/6, BALB/c, A/J and C3H/HePAS mice. Seven and fourteen days after infection, intrahepatic lymphocytes were isolated from perfused livers and analyzed by fluorescence-activated cell sorting. Noninfected animals were used as controls. In panel A, dot plots of a representative C57BL/6 mouse show the coexpression of PanNK and NK1.1 among gated CD3^– cells (expressing either one or both these markers). Numbers represent the mean of cell percentages in each region from mice (n = 3) of the same experiment (out of three experiments). Numbers in parenthesis indicate the percentage of PanNK⁺CD3^– cells coexpressing NK1.1. In panel B, dot plots of a representative C57BL/6 mouse show the spontaneous IFN- ${gamma}$ production by gated NK1.1⁺ CD3^– cells, estimated by intracellular staining. Numbers represent the mean of the percentages of IFN- ${gamma}$ -producing NK1.1⁺ CD3^– cells from mice (n = 3) of the same experiment (out of three experiments). In panel C, total numbers of IFN- ${gamma}$ -producing PanNK⁺CD3^– cells in the livers of mice of the four strains are given. Bars represent the mean ± SD (n = 3) of a representative experiment (out of two experiments). In panel D, the percentages of large cells among PanNK⁺CD3^–Mac1^LOW cells in the livers of the four mouse strains are given. Results represent the mean ± SD (n = 3) of a representative experiment (out of three experiments).

Characterization of NK T cells in the liver of acutely infected mice. NK T cells are involved in liver protection against infectionsby diverse intracellular parasites (3, 21). To investigate theparticipation of this subset in a liver response to T. cruzi,we analyzed the CD3⁺ cell population according to the expressionof NK cell markers. At first, we noticed that a considerablefraction of T cells in the livers of noninfected mice was positivefor PanNK, ranging from 15 to 30% of CD3⁺ cells in the differentmouse strains (data not shown). According to CD4 and CD8 expression,liver PanNK⁺ CD3⁺ cells had a CD4⁺, CD8⁺, or CD4^– CD8^–phenotype. At day 7 p.i., even though the numbers of PanNK⁺CD3⁺ cells per liver were similar to those of noninfected controls(Fig. 5A), these cells seemed to be activated and proliferatingsince 50 to 60% of them were large compared to 20% in noninfectedcontrols (Fig. 5B). Moreover, 1 week later, a drastic increasein three subsets was observed in the four mouse strains (Fig.5A). At that time, no major difference was observed among thestrains in terms of PanNK⁺ CD4⁺ and PanNK⁺ CD8⁺ cells. For PanNK⁺CD3⁺ CD4^– CD8^– cells, however, infected C3H/HePASand BALB/c mice presented the highest cell numbers per liver(P < 0.05), resulting in a 12- and 30-fold expansion in relationto noninfected controls, respectively.

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FIG. 5. Characterization of PanNK⁺ T cells in the livers of acutely T. cruzi-infected C57BL/6, BALB/c, A/J, and C3H/HePAS mice. Seven and fourteen days after infection, intrahepatic lymphocytes were isolated from perfused livers and analyzed by fluorescence-activated cell sorting. Noninfected animals were used as controls. In panel A, total numbers per liver of CD3⁺, CD4⁺, CD8⁺, and CD4^– CD8^– cells expressing PanNK in the four mouse strains are given. Results represent the mean ± SD (n = 3) of a representative experiment (out of three experiments). In panel B, percentages of large cells among PanNK⁺ CD3⁺ cells in the four mouse strains are given. Results represent the mean ± SD (n = 3) of a representative experiment (out of three experiments). In panel C, dot plots of a representative C57BL/6 mouse show the coexpression of PanNK and NK1.1 among gated CD3⁺ cells. Mean percentages (n = 3) of cells in each region from the same experiment (out of three experiments) are shown.

Analysis of the concomitant expression of CD3, PanNK, and NK1.1by liver lymphocytes of C57BL/6 mice revealed that nearly halfof the PanNK⁺ CD3⁺ cell population in noninfected mice was positivefor NK1.1. Unexpectedly, however, less than 10% of PanNK⁺ CD3⁺cells expressed NK1.1 at day 14 p.i. (Fig. 5C). In addition,considering the total numbers of cells per liver bearing theclassic NK T cell phenotype (PanNK⁺ NK1.1⁺ CD3⁺), no significantchange was observed in relation to noninfected controls (from[17.8 ± 9.4] x 10⁴ cells in controls to [21.2 ±4.1] x 10⁴ cells at day 7 p.i. and [27.5 ± 13.1] x 10⁴cells at day 14 p.i.). To rule out the possibility that an increasein NK T cells occurred earlier than day 7 p.i., additional experimentswere carried out in C57BL/6 mice at day 4 p.i. These studies(data not shown) confirmed that the PanNK⁺ NK1.1⁺ CD3⁺ cellpopulation was not expanded in the livers of acutely infectedmice, even though a huge fraction of infiltrating lymphocytesexpressed the PanNK cell marker. Analysis of IFN- ${gamma}$ productionby liver NK T cells of infected C57BL/6 mice revealed that 6.7%± 2.9% and 3.9% ± 1.4% of CD3⁺ NK1.1⁺ cells producedIFN- ${gamma}$ at days 7 and 14 p.i., respectively, frequencies not significantlydifferent from those found in controls (4.1% ± 1.9%).In terms of the total number of IFN- ${gamma}$ -producing cells, the contributionof NK-T cells at day 7 p.i. was approximately one-seventh ofthat of NK cells.

As deduced from data shown in Fig. 3 and 5, at day 14 p.i.,around 30 to 60% of both CD4⁺ and CD8⁺ cells in the differentmouse strains expressed PanNK, but the great majority was negativefor NK1.1. To investigate the possibility that CD4⁺ PanNK⁺ andCD8⁺ PanNK⁺ cells were NK T cells that had lost NK1.1 expressionfollowing activation (43), we analyzed Vß8 usage bythese populations. This analysis was done because classic NKT cells preferentially use the Vß8 segment of theTCR ß chain together with an invariant ${alpha}$ chain (32).First, we confirmed that liver CD4⁺ and CD8⁺ cells of acutelyinfected mice expressed TCR ${alpha}$ ß (>95%) (data not shown).In noninfected mice, around 50% of both PanNK⁺ CD4⁺ cells andPanNK⁺ CD8⁺ cells were positive for Vß8, comparedto 15% and 25% in PanNK^– CD4⁺ and PanNK^– CD8⁺ cells,respectively (Fig. 6A). At day 14 p.i., Vß8 usagewithin the PanNK^– CD4⁺ and PanNK^– CD8⁺ cell populationsremained practically the same. However, in the PanNK⁺ CD4⁺ andPanNK⁺ CD8⁺ cell populations, the frequency of Vß8⁺cells was slightly (from 54.3% to 36.9%) or drastically (from51.6% to 15.4%) reduced, respectively. These data indicate thatafter T. cruzi infection, a selective loss of Vß8usage occurs in both PanNK⁺ CD4⁺ and PanNK⁺ CD8⁺ cells, a resultthat argues against the notion that classic NK T cells predominatein these cell populations.

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FIG. 6. Expression of Vß8 and CD11c by CD4⁺ or CD8⁺ T cells in the livers of acutely T. cruzi-infected C57BL/6 mice. Fourteen days after infection, intrahepatic lymphocytes were isolated from perfused livers and analyzed by fluorescence-activated cell sorting. Noninfected animals were used as controls. Dot plots of a representative C57BL/6 mouse show the coexpression of PanNK and Vß8 (A) or CD11c (B) among gated CD4⁺ or CD8⁺ cells. Mean percentages (n = 3) of cells in each region from the same experiment (out of three experiments) are shown.

Because the molecule recognized by PanNK MAb is a ß1integrin, its expression in liver infiltrating lymphocytes ofacutely infected mice could indicate that these cells have adopteda tissue migratory phenotype. To investigate further in thisdirection, we evaluated two ß2 integrins, CD11c foundin dendritic cells and other cell types and CD11b expressedin PMN cells, macrophages, NK cells, and migration-prone T cells(34). At day 14 p.i., while the percentage of CD4⁺ cells expressingCD11c was similar to that of controls (from 10.7% ± 2.1%to 10.3% ± 1.7%), a huge increase in the percentage ofCD11c⁺ cells was found among CD8⁺ cells (from 16.8% ±0.1% to 79.2% ± 2.9%) (Fig. 6B). Interestingly, the increaseof CD11c⁺ cells affected both the CD8⁺ PanNK⁺ (from 51.6% ±3.4% to 84.4% ± 2.4%) and CD8⁺ PanNK^– (from 10.7%± 1.3% to 71.7% ± 4.6%) cell subsets. The greatmajority of CD11c⁺ CD8⁺ cells was positive for CD3, and theirsize and granularity were characteristic of lymphocytes, confirmingthat these cells were not dendritic cells (data not shown).Additionally, at day 14 p.i., we also observed moderate increasesin the percentages of CD4⁺ CD11b⁺ cells (from 10.8% ±3.4% to 29.7% ± 6.9%) and CD8⁺ CD11b⁺ cells (from 9.5%± 2.1% to 47.9% ± 10.0%). Taken together, ourresults show that T cells infiltrating the liver of acutelyinfected mice express ß1 and ß2 integrins,which can be involved in their homing to the inflamed hepatictissue.

Characterization of ${gamma}$ ${delta}$ T cells in the liver of acutely infected mice. Besides NK T cells, lymphocytes bearing TCR ${gamma}$ ${delta}$ ( ${gamma}$ ${delta}$ T cells) frequentlydisplay a CD4^– CD8^– phenotype. ${gamma}$ ${delta}$ T cells can be foundin very different locations, including the liver, where theycan be involved in the protective response against infections(23). As liver CD3⁺ CD4^– CD8^– cells showed the moststriking increase during acute T. cruzi infection (Fig. 3),we evaluated the expression of TCR ${gamma}$ ${delta}$ within the CD3⁺ cell population.As shown in Fig. 7A, 10% of CD3⁺ cells in the livers of noninfectedC57BL/6 mice were positive for TCR ${gamma}$ ${delta}$ , a percentage that increasedto 25% at day 14 of infection. Interestingly, 83.0% ±1.9% of the TCR ${gamma}$ ${delta}$ ⁺ cells in acutely infected C57BL/6 mice showeda double-negative phenotype. The increase in TCR ${gamma}$ ${delta}$ ⁺ cells wasa general feature of a liver response to T. cruzi. Thus, atday 14 p.i., considering the different mouse strains, a 40-to 100-fold increase in the total number of ${gamma}$ ${delta}$ T cells per liverwas observed in relation to noninfected controls (Fig. 7C).As for other lymphocyte populations, TCR ${gamma}$ ${delta}$ ⁺ cells seemed to beactivated and proliferating, since 20 to 25% of them were largecompared to 5 to 8% in noninfected controls (data not shown).On the other hand, it is worth noticing that, in acutely infectedC57BL/6 mice, 71.2% ± 6.2% of TCR ${gamma}$ ${delta}$ ⁺ cells were positivefor PanNK and 22.3% ± 4.1% of them coexpressed NK1.1(Fig. 7B). These results suggest that ${gamma}$ ${delta}$ T cells bearing NK cellmarkers participate in a liver response against T. cruzi duringthe acute phase of the disease.

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FIG. 7. Characterization of CD4^– CD8^– ${gamma}$ ${delta}$ T cells in the livers of acutely T. cruzi-infected C57BL/6 mice. Fourteen days after infection, intrahepatic lymphocytes were isolated from perfused livers and analyzed by fluorescence-activated cell sorting. Noninfected animals were used as controls. In panel A, dot plots of a representative C57BL/6 mouse show the coexpression of CD4/CD8 and TCR ${gamma}$ ${delta}$ among gated CD3⁺ cells. Mean percentages (n = 3) of cells in each region from the same experiment (out of three experiments) are shown. In panel B, dot plots of a representative C57BL/6 mouse show the coexpression of PanNK and NK1.1 among gated TCR ${gamma}$ ${delta}$ ⁺ cells. Mean percentages (n = 3) of cells in each region from the same experiment (out of three experiments) are shown. In panel C, total numbers of TCR ${gamma}$ ${delta}$ ⁺ cells in the livers of mice of the four strains. Bars represent the mean ± SD (n = 3) of a representative experiment (out of two experiments).

IFN- ${gamma}$ production by CD4⁺, CD8⁺, and TCR ${gamma}$ ${delta}$ ⁺ CD4^– CD8^– liver cells of acutely infected mice. During T. cruzi infection, both NK and T cells from the spleenand blood have been shown to produce IFN- ${gamma}$ (25, 27, 62), a cytokinethat plays a crucial role in defense against this parasite (24,59). To evaluate the contribution of the different T cell subsetsfor IFN- ${gamma}$ production in the livers of acutely infected mice,the production of this cytokine was examined by intracellularstaining in C57BL/6 and C3H/HePAS mice that are opposite strainsin terms of disease susceptibility.

Spontaneous IFN- ${gamma}$ production by liver CD4⁺ and CD8⁺ T cells ofboth mouse strains was dramatically increased at day 14 p.i,with percentages of 37.8% ± 0.3% and 32.8% ± 2.5%for CD4⁺ cells and of 19.1% ± 2.5% and 29.0% ±3.4% for CD8⁺ cells (Fig. 8). A small increase in IFN- ${gamma}$ productionwas already observed at day 7 p.i., with frequencies around8% for both CD4⁺ and CD8⁺ cells (data not shown). At day 14p.i., liver CD4^– CD8^– TCR ${gamma}$ ${delta}$ ⁺ cells spontaneously producingIFN- ${gamma}$ were also enhanced in acutely infected C57BL/6 and C3H/HePASmice, attaining percentages of 28.1% ± 0.2% and 28.1%± 5.1%, respectively, while control values varied from8.0% ± 0.9% to 9.0% ± 2.4% (Fig. 8). Moreover,in terms of total cells per liver, the numbers of IFN- ${gamma}$ producingCD4⁺, CD8⁺, and TCR ${gamma}$ ${delta}$ ⁺ CD4^– CD8^– cells by day 14 p.i.were (3.1 ± 1.0) x 10⁶, (2.5 ± 0.1) x 10⁶, and(1.9 ± 0.4) x 10⁶ in C57BL/6 mice and (2.9 ± 0.7)x 10⁶, (3.4 ± 1.6) x 10⁶ and (4.1 ± 1.4) x 10⁶in C3H/HePAS mice. It is worth remarking that, at this timeof infection, CD4⁺, CD8⁺, and TCR ${gamma}$ ${delta}$ ⁺ CD4^– CD8^– livercells comprised the great majority of IFN- ${gamma}$ producing cells (datanot shown).

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FIG. 8. Production of IFN- ${gamma}$ by CD4⁺, CD8⁺, and CD4^– CD8^– ${gamma}$ ${delta}$ T cells in the livers of acutely T. cruzi-infected C57BL/6 and C3H/HePAS mice. Fourteen days after infection, intrahepatic lymphocytes were isolated from perfused livers and analyzed by fluorescence-activated cell sorting. Noninfected animals were used as controls. Dot plots of a representative C57BL/6 or C3H/HePAS mouse show the spontaneous and anti-CD3/CD28-stimulated IFN- ${gamma}$ production by gated CD4⁺, CD8⁺, and ${gamma}$ ${delta}$ ⁺ cells, estimated by intracellular staining. Mean percentages (n = 3) of IFN- ${gamma}$ -producing cells from the same experiment (out of three experiments) are shown.

To estimate the potential capacity of liver lymphocytes to produceIFN- ${gamma}$ , cells stimulated overnight with plate-bound anti-CD3/anti-CD28MAbs were also analyzed. Following stimulation, the great majorityof liver CD4⁺, CD8⁺, and ${gamma}$ ${delta}$ T liver cells from mice at day 14p.i. became IFN- ${gamma}$ producers (Fig. 8), confirming their differentiationtoward a TH1/TC1 phenotype. These data sharply contrasted withthose of liver cells from noninfected mice that presented littleIFN- ${gamma}$ production after anti-CD3/anti-CD28 stimulation, suggestingthat other T-cell phenotypes exist in controls. In conclusion,during acute T. cruzi infection, similar levels of IFN- ${gamma}$ areproduced by CD4⁺, CD8⁺, and CD4^– CD8^– TCR ${gamma}$ ${delta}$ ⁺ T cellsof resistant and susceptible mice.

DISCUSSION

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Discussion

In the present work, we have shown that the presence of inflammationassociated with rare T. cruzi nests observed in the livers ofacutely infected mice is a general phenomenon, occurring inC57BL/6, BALB/c, A/J, and C3H/HePAS mice, which differ in termsof systemic susceptibility to the parasite. This observationcorroborates previous findings showing the existence of a hepaticinflammation (4, 7, 28, 53) with scarce presence of amastigotenests (26, 37, 58) in both chagasic patients and T. cruzi-infectedmice. Interestingly, however, in our experiments, the lack ofhepatic amastigote nests in more than half of the acutely infectedmice should not be taken as an indication of the absence ofT. cruzi, since, by using a sensitive amplification method (36),we were able to detect living parasites in perfused livers ofmice of the four strains (data not shown).

The presence of low numbers of amastigote nests in the liversof resistant (C57BL/6), intermediate (BALB/c), and susceptible(C3H/HePAS and A/J) mice, in clear dissonance with parasitemialevels and heart parasitism, indicates that local factors mayinhibit T. cruzi replication inside liver cells. IFN- ${gamma}$ seemsto play a major role in liver protection against T. cruzi sinceacutely infected IFN- ${gamma}$ -KO mice presented a high level of hepaticparasitism. The relevance of IFN- ${gamma}$ for controlling hepatic parasitismwas also indirectly suggested by our experiments in acutelyinfected CD4KO and CD8KO mice. Thus, the fact that both groupsof deficient mice were able to restrain the parasite growthin the liver, but not systemically, supports the idea that theeffector mechanism responsible for liver protection againstT. cruzi is not peculiar to either CD4⁺ T cells or CD8⁺ T cells.IFN- ${gamma}$ -mediated mechanisms are an attractive possibility for thiseffector activity, since IFN- ${gamma}$ can be produced by several lymphocytepopulations infiltrating the liver, including CD4⁺ and CD8⁺T cells. Activation of Kupffer cells or even hepatocytes (30)and recruitment of macrophages are examples of effector mechanismsmediated by IFN- ${gamma}$ that could operate in local parasite control.

The precocious source of IFN- ${gamma}$ in the livers of acutely infectedmice seems to be NK cells, a concept supported by the findingthat an IFN- ${gamma}$ -producing PanNK⁺ CD3^– cell population coexpressingNK1.1 in C57BL/6 mice drastically increases by day 7 of infection.The involvement of NK cells in the initial phase of the diseaseis also supported by the fact that, in the four mouse strains,a great proportion of liver PanNK⁺ CD3^– cells showed anactivated cell phenotype. These results extend to the liverprevious observations suggesting that NK cells are early participantsof the anti-T. cruzi response. Thus, acutely infected mice undergoan increase in spleen NK cell activity against tumor targets(5, 62), and NK cell depletion by anti-asialo GM1 or anti-NK1.1antibodies results in parasitemia increases (10, 48, 62). HumanNK cells also seem to respond to T. cruzi, inasmuch as stimulationof peripheral blood mononuclear cells from chagasic patientswith parasite antigen boosts their NK cell cytotoxic activity(8). Accumulation of NK cells in the liver could result fromcell recruitment mediated by locally released chemokines (49).Alternatively, it could be a consequence of cytokine-inducedproliferation (40), a possibility supported by the high proportionof large cells within the liver NK cell population of acutelyinfected mice. In this respect, IL-12 produced by T. cruzi-infectedmacrophages (2) and released in acutely infected mice (62) couldparticipate in the activation and proliferation of liver NKcells. This is indirectly supported by data showing that accumulationof NK cells is not observed in the spleen of T. cruzi-infectedIL-12p35KO mice (39). Later on, at day 14 p.i., when the NKcell population shows no further increase, a noticeable increasein T-cell numbers occurs in the liver. The increase of T cellsaffects CD4⁺ and CD8⁺ cells and, more intensively, CD4^–CD8^– CD3⁺ cells, a population mainly composed of ${gamma}$ ${delta}$ T cellspoorly represented in noninfected mice. Interestingly, verysimilar numbers of liver infiltrating T cells were observedin the four mouse strains, even though lower numbers of CD3⁺CD4^– CD8^– cells (mostly ${gamma}$ ${delta}$ T cells) were present inC57BL/6 mice. By producing huge amounts of IFN- ${gamma}$ , all three liverT-cell populations guarantee a strong and diverse source ofIFN- ${gamma}$ when its production by NK cells has already declined.

Besides IFN- ${gamma}$ -producing NK and T cells, other leukocyte populationswere increased in the livers of acutely infected mice. Thus,macrophages and PMN cells were present in the four mouse strainsfrom day 7 onward. These cells might contribute to T. cruzicontrol through phagocytosis of extracellular parasites. B cellswere observed at day 14 p.i. in the livers of infected miceexcept in those of the C3H/HePAS strain, which also showed reducedB cell numbers in the spleen. This is an interesting matterthat deserves further investigation, inasmuch as similar anti-parasiteantibody titers were found in T. cruzi-infected C3H/He and C57BL/6mice (45).

NK T cells participate in protection against diverse parasites(3, 21), by producing IFN- ${gamma}$ and by establishing a bridge betweenthe innate and acquired immune responses. Since a large fractionof the CD4⁺, CD8⁺, and CD4^– CD8^– CD3⁺ cells in thelivers of acutely infected mice were positive for the PanNKmarker, the ${alpha}$ chain of the VLA-2 integrin expressed by NK T cells(6), it was important to determine if NK T cells were includedin the PanNK⁺ CD3⁺ cell population. Although classic NK T cellshave CD4⁺ or CD4^– CD8^– phenotypes (32), PanNK⁺ CD8⁺cells could still be nonclassic CD8⁺ NK T cells (22), a liverpopulation increased during Plasmodium yoelii infection (35).However, our study suggests that during acute T. cruzi infection,most liver PanNK⁺ CD3⁺ cells are not NK T cells, consideringthat in infected C57BL/6 mice very few of them coexpress NK1.1,a more reliable NK T cell marker than PanNK, which is sharedby a fraction of conventional T cells with effector functions(29, 56). This conclusion is reinforced by the fact that PanNK⁺CD4⁺ and PanNK⁺ CD8⁺ cells, which express the TCR ${alpha}$ ß,do not show a preferential usage of Vß8, a TCR chainfrequently used by classic NK T cells (32). Furthermore, follow-upof NK1.1⁺ CD3⁺ cells in acutely infected C57BL/6 mice revealeda progressive decrease in their frequencies among liver lymphocytes.A persistent reduction in the percentage of this cell populationwas also observed by Duthie et al. (19) in C57BL/6 mice infectedwith T. cruzi of the CL strain. These findings, however, donot rule out the participation of NK T cells in the acute liverresponse to T. cruzi, since the low production of IFN- ${gamma}$ by thispopulation could be important for activating NK cells (31) and/orfor T-cell polarization. Thus, in relation to the role of classicNK T cells in protection against acute T. cruzi infection (18,19, 38, 44), our data indicate that this population does notshow major expansions in the liver, nor does it directly contributeto protection with a strong IFN- ${gamma}$ production.

${gamma}$ ${delta}$ T cells can be found in different tissues, where they are involvedin innate immune responses, operating through recognition ofpathogen-derived molecules (14) or of autologous proteins overexpressedas a consequence of infection, cell disregulation, or tumortransformation (13). In contrast to classic NK T cells, liver ${gamma}$ ${delta}$ T cells expressing a CD4^– CD8^– phenotype showedthe most notable increase during acute T. cruzi infection. Exceptfor C57BL/6 mice, this cell population attained values of thesame magnitude or even higher than those of CD4⁺ and CD8⁺ Tcells. In addition, a large fraction of ${gamma}$ ${delta}$ T cells in acutelyinfected C57BL/6 mice coexpressed PanNK and NK1.1, which couldindicate the presence of a recently defined rare populationof nonclassic NK T cells (22). Indeed, the most remarkable observationwas that ${gamma}$ ${delta}$ T cells spontaneously produce IFN- ${gamma}$ , a fact compatiblewith a proinflammatory protective effect against T. cruzi. Thisobservation extends previous studies showing that, at the beginningof infection by different viruses and bacteria, ${gamma}$ ${delta}$ T cells arefrequently proinflammatory but, later on, when parasite proliferationis under control, they mediate regulatory functions (11). Thefact that T. cruzi infection in ${gamma}$ ${delta}$ T-cell-deficient mice resultsin milder inflammatory heart lesions and lower mortality comparedto control mice (50) reinforces the proinflammatory role ofthis population.

The present study suggests that a broad array of lymphocytepopulations, such as NK, ${gamma}$ ${delta}$ T, CD4⁺ T, and CD8⁺ T cells, may providethe IFN- ${gamma}$ required for liver protection against acute T. cruziinfection. Moreover, a clear polarization to the type 1 functionalprofile is observed in T cells that infiltrate the liver ofacutely infected mice, as evidenced by the boost in IFN- ${gamma}$ productionupon in vitro restimulation with anti-CD3/anti-CD28 antibodies.Remarkably, IFN- ${gamma}$ production by liver CD4⁺, CD8⁺, and ${gamma}$ ${delta}$ T cellswas found to attain similar levels in C57BL/6 and C3H/HePASmice, two strains that show opposite behavior in terms of theability to control the systemic proliferation of the parasite.This observation is of great relevance because it could explainwhy amastigote nests are rarely found in the livers of bothresistant and susceptible mice. Considering the crucial roleof IFN- ${gamma}$ in protection against T. cruzi infection, the fact thatdifferent liver populations respond to acute infection by secretinglarge amounts of IFN- ${gamma}$ could be very important to ensure thedestruction of intrahepatic parasites, transforming the liverat a site where the effector arm of the immune response operateswith great efficiency.

ACKNOWLEDGMENTS

Financial support was provided by grants FAPESP, numbers 02/03133-7and 00/13756-6, and CNPq, numbers 301291/85-3 and 305049/2004-6.

We acknowledge Rogério Silva do Nascimento and BernardoPaulo Albe for technical support.

FOOTNOTES

* Corresponding author. Mailing address: Departamento de Imunologia, ICB, Av. Prof. Lineu Prestes, 1730, Universidade de São Paulo, São Paulo, SP CEP-05508-000, Brazil. Phone: 55 11 3091 7374. Fax: 55 11 3091 7224. E-mail: luizsard{at}usp.br.

Editor: J. F. Urban, Jr.

REFERENCES

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