Diversity of the T-Cell Response to Pulmonary Cryptococcus neoformans Infection

Cell-mediated immunity plays an important role in immunity tothe pathogenic fungus Cryptococcus neoformans. However, theantigen specificity of the T-cell response to C. neoformansremains largely unknown. In this study, we used two approachesto determine the antigen specificity of the T-cell responseto C. neoformans. We report here that a diverse T-cell receptor(TCR) Vß repertoire was maintained throughout theprimary response to pulmonary C. neoformans infection in immunocompetentmice. CD4⁺ T-cell deficiency resulted in relative expansionof all CD8⁺ T-cell subsets. During a secondary immune response,preferential usage of a TCR Vß subset in CD4⁺ T cellsoccurred in single individuals, but the preferences were "private"and not shared between individuals. Both CD4⁺ and CD8⁺ T cellsfrom the secondary lymphoid tissues of immunized mice proliferatedin response to a variety of C. neoformans antigens, includingheat-killed whole C. neoformans, culture filtrate antigen, C.neoformans lysate, and purified cryptococcal mannoprotein. CD4⁺and CD8⁺ T cells from the secondary lymphoid tissues of miceundergoing a primary response to C. neoformans proliferatedin response to C. neoformans lysate. In response to stimulationwith C. neoformans lysate, lung CD4⁺ and CD8⁺ T cells producedthe effector cytokines tumor necrosis factor alpha and gammainterferon. These results demonstrate that a diverse T-cellresponse is generated in response to pulmonary C. neoformansinfection.

INTRODUCTION

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Introduction

The fungal pathogen Cryptococcus neoformans can infect immunocompetentindividuals, but this organism causes disease primarily in individualswith defects in cellular immunity (5). T-cell-mediated immunityplays a critical role in clearance of pulmonary C. neoformansinfection in mice, but the antigen specificity of the respondingCD4⁺ and CD8⁺ T cells remains largely unknown. In this study,we used two approaches to determine the antigen specificityof the T-cell response to C. neoformans.

In ${alpha}$ ß T cells, which comprise the majority of T cells,the T-cell receptor (TCR) is expressed as a heterodimeric proteincomposed of ${alpha}$ and ß subunits. Somatic recombinationof diversity and joining regions in V ${alpha}$ and somatic recombinationof variable, diversity, and joining regions in Vßresult in the diversity of the TCR repertoire (3). A numberof studies, including studies of the pathogenic fungus Histoplasmacapsulatum, have demonstrated that there are Vß preferencesduring T-cell responses, which correlate to T-cell functionor antigen specificity (7-11). Similar to control of C. neoformansinfection, control of H. capsulatum infection is primarily dependenton CD4⁺ T cells. Based on these results, we studied the VßTCR expression by CD8⁺ and CD4⁺ T cells during pulmonary C.neoformans infection.

Our first objective in this study was to characterize the VßTCR usage by CD4⁺ and CD8⁺ T cells during primary and secondaryresponses to pulmonary C. neoformans infection. Our goals wereto determine (i) whether preferential expansion of specificVß subsets by either T-cell subset occurs during primaryinfection; (ii) whether Vß skewing, if present, representssuperantigen-induced proliferation or oligoclonal expansionof antigen-specific T cells; and (iii) whether tracking a singleor limited number of Vß subsets throughout the courseof the T-cell response could be used as a surrogate marker forantigen specificity.

C. neoformans has been shown to have mitogenic activity withhuman T cells in vitro (20, 21, 25). Superantigens are microbiallyderived proteins which bind directly to the Vß regionof a limited number of closely related TCR Vß subsets(17). Neonatal exposure to mouse mammary tumor virus superantigensresults in mouse strain-specific deletion of TCR Vßsubsets from the mature TCR repertoire (1). Exposure of matureT cells to superantigens (such as staphylococcal enterotoxinB) results in rapid expansion of T cells bearing Vßbound by the superantigen, followed by activation-induced celldeath. Our second objective was to determine whether C. neoformanshad superantigen activity in mice (in vitro or in vivo). Inaddition, we sought to determine the proliferative and effectorcytokine responses of CD4⁺ and CD8⁺ T cells from the lungs andthe secondary lymphoid tissues in response to C. neoformansantigens.

MATERIALS AND METHODS

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Materials and Methods

Mice. Female CBA/J mice (weight, 25 ± 4 g; age, 5 to 7 weeks)were obtained from the Jackson Laboratories (Bar Harbor, Maine).The mice were housed under pathogen-free conditions in enclosedfilter-topped cages. Clean food and water were provided ad libitum.The mice were handled and maintained using microisolator techniques,and there was daily veterinarian monitoring. Bedding from themice was transferred weekly to cages of uninfected sentinelmice that were subsequently bled at weekly intervals and werefound to be negative for antibodies to mouse hepatitis virus,Sendai virus, and Mycoplasma pulmonis. All studies involvingmice were approved by the University Committee on Use and Careof Animals at the University of Michigan.

C. neoformans. C. neoformans strain 52D (= ATCC 24067) was obtained from theAmerican Type Culture Collection (Manassas, VA). For infection,the yeast was grown to the stationary phase (48 to 72 h) at35°C in Sabouraud dextrose broth (1% neopeptone and 2% dextrose;Difco, Detroit, Mich.) on a shaker. The cultures were then washedin nonpyrogenic saline, counted with a hemacytometer, and dilutedto obtain a concentration of 3.3 x 10⁵ CFU/ml in sterile nonpyrogenicsaline. The precise number of organisms delivered was determinedby counting the CFU in an inoculum plated on Sabaraud dextroseagar (Difco).

Intratracheal inoculation of C. neoformans. Mice were anesthetized by intraperitoneal injection of ketamine(100 mg/kg; Fort Dodge Laboratories, Fort Dodge, IA) and xylazine(6.8 mg/kg; Lloyd Laboratories, Shenandoah, IA) and were restrainedon a small surgical board. A small incision was made throughthe skin over the trachea, and the underlying tissue was separated.A 30-gauge needle was attached to a 1-ml tuberculin syringefilled with a diluted C. neoformans culture. The needle wasinserted into the trachea, and 30 µl of inoculum (10⁴CFU) was dispensed into the lungs. The needle was removed, andthe skin closed with cyanoacrylate adhesive. The mice recoveredwith minimal visible trauma.

Lung, lymph node, and spleen leukocyte isolation. The lungs of each mouse were excised, washed in phosphate-bufferedsaline (PBS), minced, and digested enzymatically for 30 minin 15 ml/lung of digestion buffer (RPMI, 5% fetal calf serum[FCS], 1 mg/ml collagenase [Boehringer Mannheim Biochemical,Chicago, IL], 30 µg/ml DNase [Sigma Chemical Co., St.Louis, MO]). Following erythrocyte lysis using NH₄Cl buffer,the cells were washed, resuspended in complete medium, and centrifugedfor 30 min at 2,000 x g in the presence of 20% Percoll (Sigma)to separate leukocytes from the cell debris and epithelial cells.Total numbers of lung leukocytes were determined in the presenceof trypan blue using a hemocytometer; the viability was >85%.Lung-associated lymph nodes (LALN) and spleens were excised,and the cells dispersed with the plunger of a 3-ml syringe.Erythrocytes were lysed using NH₄Cl buffer, and the cells wereresuspended in complete medium (RPMI, 5% FCS, 2 mM L-glutamine,50 µM 2-mercaptoethanol, 100 U/ml penicillin, 100 µg/mlstreptomycin sulfate).

Flow cytometry. For surface staining, leukocytes were washed and resuspendedat a concentration of 10⁷ cells/ml in FA buffer (Difco, Detroit,MI) containing 0.1% NaN₃ (Sigma), and Fc receptors were blockedby addition of anti-CD16/32 (Fc block; BD Pharmingen, San Diego,CA). Following Fc receptor blocking, 10⁶ cells were stainedin 120-µl (final volume) mixtures in polystyrene tubes(12 by 75 mm; BD Pharmingen) for 20 min at 4°C. Leukocyteswere stained with the following antibodies, according to themanufacturer's instructions: CD4 (RM4-4 and H129.19), CD8 ${alpha}$ (5H10-1),CD8ß (53-5.8), and a mouse TCR Vß screeningkit (BD Pharmingen). Preliminary experiments confirmed thatCBA/J mice did not express Vß 3, 5, 6, 7, 8.1, 9,12, and 17 due to expression of endogenous proviruses and mousemammary tumor viruses and were thus were not included in theVß analysis. Cells were washed twice with FA bufferand resuspended, and 200 µl of 4% formalin (Fisher Chemical,Pittsburgh, PA) was added to fix the cells. A minimum of 20,000events were acquired with a FACScaliber flow cytometer (BD Pharmingen)using the Cell-Quest software (BD Pharmingen).

Intracellular flow cytometry. Leukocytes (2 x 10⁶ cells/ml) were cultured for 12 h in 12-wellplates in the presence of 0.1 µg/ml soluble anti-CD3 (145-2C11;BD Pharmingen) with or without 0.1 µg/ml anti-CD28 (37.51;BD Pharmingen). Brefeldin A and/or monensin (in the form ofGolgi-stop or Golgi-block) were added for the last 4 h of incubationaccording to the manufacturer's instructions (BD Pharmingen).Nonadherent cells were harvested and washed twice with FA buffer,and staining for cell surface molecules was performed as describedabove. For intracellular staining, cells were washed to removeexcess surface stains, fixed and permeabilized using Cytofix/Cytoperm(BD Pharmingen), and stained using anti-gamma interferon (IFN- ${gamma}$ )(XMG1.2) or anti-tumor necrosis factor alpha (TNF- ${alpha}$ ) (MP6-XT22;BD Pharmingen) in permeabilization buffer (FA buffer containing0.1% saponin [Sigma]) at 4°C for 30 min. Flow cytometrywas performed as described above for surface staining, exceptthat >50,000 events per sample were routinely collected.The specificity of anticytokine antibodies was tested by comparingstaining of experimental samples to at least two of the followingthree negative controls: (i) isotype control, (ii) excess unlabeledantibody, and (iii) preincubation of antibody with recombinantcytokine.

In some experiments, T cells were enriched from the lungs byfluorescence-activated cell sorting (FACS) and from lymph nodesand spleens by magnetism-activated cell sorting (MACS). ForFACS, lung leukocytes were stained using anti-CD4 (RM4-4) andanti-CD8 (5H10-1). Cell sorting was performed at the Universityof Michigan Cancer Center Flow Cytometry Core with a FACSVantageSE cell sorter (BD Immunocytometry Systems, San Jose, CA). Thepurity of the sorted population was >99%, as determined bypostsorting analysis. For MACS, cell suspensions from secondarylymphoid tissues were stained using a panel of biotinylatedantibodies, including anti-CD19 (1D3), anti-CD49b (DX5), anti-Gr-1(RB6-8C5), and anti-erythroid cells (TER-119) (all obtainedfrom BD Pharmingen), as well as anti-mouse F4/80 (CI:A3-1; CaltagLaboratories, Burlingame, CA), and T cells were enriched bynegative selection using antibiotin microbeads with a SuperMACSseparator (Miltenyi Biotec, Auburn, CA). A total of 10⁶ enrichedT cells were cocultured with 10⁶ adherent lung cells from uninfectedmice and stimulated with either (i) anti-CD3 and anti-CD28 or(ii) C. neoformans lysate.

Proliferation assay. Cells were assayed for proliferation using an in vitro fluorescence-basedassay. Briefly, 2 x 10⁶ cells from the various organs were stainedwith 5 µM 5-(and 6-)carboxyfluorescein diacetate, succinimidylester (CFSE) (Molecular Probes, Eugene, OR) in PBS containing5% FCS for 7 min at room temperature. The cells were washedthree times to remove the excess CFSE and cultured for 3 daysin the presence or absence of anti-CD3 antibodies (0.1 µg/ml).A minimum of 20,000 events were acquired with a FACScaliberflow cytometer (BD Pharmingen) using the Cell-Quest software(BD Pharmingen).

T-cell depletion using monoclonal antibodies. Depletion of CD4⁺ T cells was accomplished by intraperitonealadministration of monoclonal antibodies. Anti-CD4 (GK1.5, ratimmunoglobulin G2b) was prepared from ascites by dilution innonpyrogenic saline and filtration through a 0.45-µm syringefilter. Mice received 200 µg of GK1.5 or a nonpyrogenicsaline control in 200 µl nonpyrogenic saline at zero timeand on day 1 of infection, followed by 200 µg every 8days. The efficiency of T-cell depletion was assessed by flowcytometric analysis using anti-CD4 (RM 4-4), which binds a regionof CD4 distinct from the region bound by GK1.5. The efficienciesof CD4⁺ T-cell depletion in the lungs (>98%) and spleens(>99%) of mice were calculated by comparing the numbers ofT cells in treated mice with the numbers of T cells in controls.

Preparation of C. neoformans antigens. (i) Heat-killed C. neoformans. C. neoformans strain 52D (= ATCC 24067) was obtained from theAmerican Type Culture Collection. This yeast was grown to thestationary phase (72 h) at 34°C in Sabouraud dextrose broth(1% neopeptone and 2% dextrose; Difco, Detroit, Mich.) on ashaker platform. The yeast was washed three times in phosphate-bufferedsaline, counted with a hemacytometer, resuspended at a concentrationof 10⁹ cells/ml, and incubated in a 60°C water bath for2 h with periodic mixing. The absence of viable organisms wasconfirmed by plating an aliquot containing 10⁸ organisms onSabouraud dextrose agar (Difco, Detroit, MI).

(ii) C. neoformans culture filtrate. C. neoformans culture filtrate (CneF) was prepared from C. neoformansgrown to the stationary phase in asparagine broth. The yeastcells were pelleted by centrifugation at 1,500 x g for 30 min.The supernatant was filtered though a 0.22-µm bottle topfilter (Corning Incorporated, Corning, NY). The filtered culturesupernatant was concentrated 10-fold using an Amicon concentrationapparatus with a 50-kDa-cutoff filter (Millipore, Billerica,MA) and then was washed with five times the original culturevolume of nonpyrogenic saline. The protein concentration ofCneF (622 µg/ml) was determined by the bicinchoninic acidassay (Pierce Biotechnology, Rockford, IL).

(iii) Purified C. neoformans mannoprotein. Mannoprotein purified from culture supernatants of acapsularC. neoformans strain ATCC 52817 (19, 22) was a generous giftfrom Stuart Levitz, Boston University.

(iv) C. neoformans lysate. Lysate was prepared from stationary-phase organisms as follows.A 30-ml yeast culture was centrifuged at 1,500 x g for 20 minand washed three times with PBS, and the cells were resuspendedin a minimal volume of PBS. Then 0.5-mm glass beads were addedto cover the yeast (Biospec Products, Bartlesville, OK). Theyeast cells were lysed by 25 cycles consisting of 30 s of vortexingand 30 s in an ice bath. The yeast lysate was diluted with 10ml PBS and separated from the cellular debris by low-speed centrifugation(750 x g), and the supernatant was filtered through a 0.22-µmbottle top filter. The sterile lysate was frozen at –70°Cuntil it was used.

Secondary pulmonary C. neoformans infection in mice. CBA/J mice were infected intratracheally with 10³ CFU of C.neoformans strain 52D. The mice were housed in specific-pathogen-freeconditions with food and water provided ad libitum for 16 weeksto allow clearance of the primary infection. For secondary infections,mice were then infected intratracheally with 10⁴ CFU C. neoformans(a dose that was 10-fold higher than the primary dose).

Statistics. For preferential Vß usage during primary infectionin C. neoformans-infected CBA/J mice, an analysis of variancewas used to compare fold increases in each Vß⁺ T-cellpopulation. A P value of <0.05 was considered statisticallysignificant.

RESULTS

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Results

Vß TCR repertoires in the spleens and lungs of naive CBA/J mice. In order to establish a baseline to determine the relative enrichmentof any particular Vß subset, it was necessary to firstdetermine the naive Vß repertoire in uninfected controlmice. To do this, uninfected specific-pathogen-free mice weresacrificed, and leukocytes were recovered from spleens as describedin Materials and Methods. The expression of various Vßsubsets was determined by flow cytometry using a commerciallyavailable screening kit. The Vß repertoires in thespleens were different for CD4⁺ and CD8⁺ T cells. While someVß subsets were expressed at higher frequencies inboth CD4⁺ and CD8⁺ T cells (Vß 8.2 and Vß8.3) (Fig. 1A and B), other Vß subsets were expresseddifferentially in the populations. Vß 2, 11, 13, and14 were expressed at higher frequency in CD8⁺ T cells, and Vß4 and 10 were expressed at higher frequencies in CD4⁺ T cells(Fig. 1A and B). Although Vß 11-expressing T-cellsubsets would be expected to be eliminated from CBA/J mice,based on their expression of mammary tumor virus 9, incompletedeletion of the Vß 11⁺ CD8⁺ subset has been describedpreviously (16). In the CD4⁺ or CD8⁺ compartment, however, therelative frequency of each Vß subset was relativelyconserved (Fig. 1A and B). Thus, the splenic TCR Vßrepertoire was conserved from one animal to another in bothCD4⁺ and CD8⁺ T cells.

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FIG. 1. Vß TCR repertoire of CD4⁺ and CD8⁺ T cells in uninfected CBA/J mice. The frequencies of splenic CD8⁺ (A) and CD4⁺ (B) T cells expressing each Vß subset were determined as described in Materials and Methods by flow cytometric analysis. Each bar represents a single animal. The frequencies (C and D) and absolute numbers (E and F) of each Vß subset in lung CD4⁺ and CD8⁺ T cells were determined by flow cytometric analysis of lymphocytes recovered from enzymatic digests of whole lungs, as described in Materials and Methods. Each bar represents a single animal. The numbers indicate the mean for each group.

Our ultimate goal was to identify populations of T cells thatwere enriched during pulmonary C. neoformans infection. To determinewhether the population of T cells in the lungs mirrored thepopulation in the spleens of uninfected mice, we determinedthe frequency of each Vß subset expressed by CD4⁺and CD8⁺ T cells from the lungs of uninfected mice. In the CD8⁺T-cell compartment, there was slightly more variability in theTCR Vß usage of CD8⁺ T cells from the lungs than inthe TCR Vß usage of CD8⁺ T cells from the spleens(Fig. 1A and C). Lung CD4⁺ T cells had a pattern of Vßusage similar to that of CD4⁺ T cells from the spleen (Fig.1B and D). The TCR Vß usage of CD4⁺ T cells from thelungs was conserved, similar to the results found for lung CD8⁺T cells, but the frequencies of some CD4⁺ TCR Vß subsetswere more variable in the lungs than in the spleen (Fig. 1B and D).The total numbers of CD4⁺ and CD8⁺ T cells in the lungs wereconsistent for five uninfected mice, and so the absolute numberof each Vß subset mirrored the frequencies (Fig. 1E and F).Thus, although the Vß TCR repertoire in lung T cellswas similar to that in the splenic compartment and was conserved,there was some heterogeneity in the Vß TCR repertoirein lung T cells.

Lung TCR Vß repertoire during pulmonary C. neoformans infection. Our next objective was to determine whether particular Vßsubsets were enriched in either the CD4⁺ or CD8⁺ T-cell populationsduring pulmonary C. neoformans infection. In response to pulmonaryC. neoformans infection, resistant mice recruit both CD4⁺ andCD8⁺ T cells to the lungs (13). CD4⁺ T cells are relativelyenriched, particularly late in the response (13). To controlfor differences in the number of T cells in the lungs of infectedmice, we converted data to absolute numbers of each Vßsubset per lung and determined the relative increase comparedto uninfected controls for each subset. The absolute numberand fold increase for CD4⁺ and CD8⁺ T cells expressing eachof the Vß subsets were determined for mice at weeks1, 3, and 5 postinfection. At week 1 postinfection, no Vßsubsets were increased by more than onefold (data not shown),and there was no difference between subsets. At the peak ofthe T-cell response (week 3 postinfection), a modest increasein each of the CD8⁺ T-cell Vß subsets was observed,which represented 2.7- to 4.3-fold expansion compared to uninfectedcontrols (Fig. 2D). Similarly, in CD4⁺ T cells, expansion ofall Vß subsets occurred in response to infection (Fig.2B). In contrast to the data for CD8⁺ T cells, the CD4⁺ Vßsubsets were all expanded more than 11-fold compared to theCD4⁺ Vß subsets for uninfected control lungs (Fig.2B). The number of Vß13⁺ CD4⁺ T cells was significantlyexpanded compared to the controls (>70-fold) (Fig. 2B); however,Vß13⁺ CD4⁺ T cells comprised a minority of the totalCD4⁺ T-cell population in the lungs (6.3%) (Fig. 2A). This preferentialexpansion of Vß13⁺ CD4⁺ T cells was not observed atweek 5 postinfection (Fig. 2F), and Vß13⁺ T cellswere an even smaller proportion of the total lung CD4⁺ T cells(1.9%). Thus, during primary pulmonary C. neoformans infection,a diverse TCR Vß repertoire was maintained by bothCD4⁺ and CD8⁺ T cells infiltrating the lungs.

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FIG. 2. Vß TCR repertoire of lung T cells in CBA/J mice after C. neoformans infection. The absolute number (A, C, and E) of T cells expressing each Vß subset and the increase compared to uninfected control lungs (B, D, and F) are shown. Mice were infected intratracheally with 10⁴ CFU of C. neoformans. CD4⁺ T cells were recovered from the lungs of infected mice at weeks 3 (A and B) and 5 (E and F) postinfection, and CD8 T cells were recovered from the lungs of infected mice at week 3 postinfection (C and D). Each bar represents a single animal, and the numbers indicate the mean for each group.

Lung CD8⁺ TCR Vß repertoire during pulmonary C. neoformans infection in CD4⁺ T-cell-deficient mice. Pulmonary C. neoformans infection primarily affects individualswith compromised CD4⁺ T-cell immunity (5). To determine theeffect of CD4⁺ T-cell deficiency on the resulting CD8⁺ TCR Vßrepertoire, mice were made CD4⁺ T cell deficient by systemicadministration of anti-CD4 depleting monoclonal antibodies asdescribed in Materials and Methods. The expansion of CD8⁺ Tcells belonging to the various TCR Vß subsets wasassayed as described above. At week 3 postinfection, highernumbers of CD8⁺ T cells in each of the Vß subsetswere present in the lungs compared to the numbers in CD4⁺ mice(Fig. 3A and 2D). The numbers represented a much greater expansioncompared to uninfected controls (range, 6.9- to 42.0-fold),and Vß 2, 4, 10, and 14 all expanded more than 25-fold(Fig. 3A). At week 5 postinfection, Vß 2, 4, and 10were expanded more than 35-fold (Fig. 3B). These numbers reflecttotal CD8⁺ T-cell expansion, which was exaggerated in the absenceof CD4⁺ T cells. Thus, CD4⁺ T-cell deficiency resulted in expansionof all CD8⁺ Vß subsets compared to CD4⁺ mice, butthe expansion was particularly pronounced for Vß subsets2, 4, and 10.

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FIG. 3. Effect of CD4⁺ T-cell deficiency on the CD8⁺ Vß repertoire during pulmonary C. neoformans infection. The increases in the numbers of lung CD8 T cells at weeks 3 (A) and 5 (B) postinfection relative to the numbers in CD4⁺ T-cell-sufficient, uninfected control (UC) lungs are shown. CBA/J mice were made CD4⁺ T cell deficient throughout the infection by using anti-CD4 depleting monoclonal antibodies, as described in Materials and Methods. The TCR Vß repertoire of lung CD8⁺ T cells in CBA/J mice was assayed as described above. Each bar represents a single animal, and the numbers indicate the mean for each group.

TCR Vß repertoire during the secondary immune response to pulmonary C. neoformans infection. To determine whether mice maintained a diverse T-cell Vßrepertoire during secondary infection, mice were infected with10³ CFU of C. neoformans and then housed in specific-pathogen-freeconditions for 16 weeks to allow resolution of this primaryinfection. The mice were then given a secondary challenge consistingof 10⁴ CFU, and the Vß repertoire was characterized10 days after the secondary challenge. In the CD8⁺ T-cell compartment,very little expansion of CD8⁺ T cells was observed, and fourof eight Vß subsets were contracted compared to uninfectedcontrols (Fig. 4A). Whether increased numbers in the other fourVß subsets represented skewing of the CD8⁺ Vßrepertoire in the secondary response is unclear, because thetotal number of CD8⁺ T cells at day 10 after the secondary challengewas similar to the number of cells in uninfected controls (datanot shown). In the CD4⁺ T-cell compartment, preferential expansionof some Vß subsets was observed in individuals (Fig.4B). For example, mouse 4 exhibited skewing of the CD4⁺ repertoireto Vß 4 and Vß 13, whereas mouse 3 preferentiallyexpanded Vß 8.3 and Vß 14 (Fig. 4B). However,preferential usage of Vß subsets by CD4⁺ T cells wasnot consistent between individuals. Thus, during the secondaryT-cell response to pulmonary C. neoformans infection, individualsexhibited skewing of the CD4⁺ T-cell repertoire, but consistent,preferential expansion of any Vß subset was not observedacross the group.

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FIG. 4. Relative expansion of Vß TCR subsets in lung CD8⁺ (A) and CD4⁺ (B) T cells during the secondary response to C. neoformans. Mice were infected with 10³ CFU of C. neoformans and rested to allow resolution of the primary infection, as described in Materials and Methods. The mice were given a secondary infection consisting of 10⁴ CFU C. neoformans, and the Vß TCR usage of CD4⁺ and CD8⁺ T cells in the lungs was assayed by flow cytometry at day 10 after the secondary infection. Each bar represents a single animal, and the numbers indicate the mean for each group. UC, uninfected control.

Proliferative responses of T cells from immunized mice in response to C. neoformans antigens. The results described above demonstrated that a diverse TCRVß repertoire was maintained in the T-cell responseto pulmonary C. neoformans infection. Additionally, these resultssuggested that tracking any Vß subset would likelybe a poor surrogate for antigen specificity in the T-cell responseto pulmonary C. neoformans infection. Therefore, we shiftedthe focus of our investigation to determining whether we couldidentify a method for more specifically assaying the T-cellresponses to C. neoformans.

To do this, we studied the proliferative responses of CD4⁺ andCD8⁺ T cells from mice immunized with C. neoformans. CBA/J micewere infected with 10³ CFU of C. neoformans and allowed to recoverfrom the infection. Previous studies demonstrated that therewere enhanced T-cell responses to secondary C. neoformans infectionin such mice (D. Lindell, M. Ballinger, R. McDonald, G. Towes,and G. Huffnagle, submitted for publication). At 16 weeks postinfection,single-cell suspensions were prepared from pooled lymph nodesand spleens of immunized mice. To assay for C. neoformans-specificresponses, we generated a variety of antigen preparations fromC. neoformans, as described in Materials and Methods. C. neoformanscan persist in the lungs of resistant mice long after a primaryinfection (Lindell et al., submitted). The levels of cells recoveredfrom the secondary lymphoid organs of mice immune to C. neoformansmice were below the detectable levels of viable yeast cells(<50 CFU in the pooled sample for five mice).

The proliferation of CD4⁺ and CD8⁺ T cells from mice at week16 postinfection was assessed using a flow cytometry-based proliferationassay, as described in Materials and Methods. This assay hasan advantage over [³H]thymidine incorporation assays becausethe proliferation of multiple cell populations can be determinedindependently in a single treatment well. Following 2 days inculture, there was minimal proliferation (as indicated by adecrease in CFSE staining) of either CD4⁺ or CD8⁺ T cells fromimmunized mice in the absence of stimulation (Fig. 5). In responseto anti-CD3/anti-CD28 restimulation, a majority of CD4⁺ andCD8⁺ T cells proliferated (Fig. 5). A slight decrease in CFSEintensity was observed in both CD4⁺ and CD8⁺ T cells stimulatedwith C. neoformans lysate (Fig. 5). In contrast, after 4 daysin culture, significant proportions of both CD4⁺ and CD8⁺ Tcells from immunized mice had proliferated in response to C.neoformans lysate (Fig. 5).

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FIG. 5. Proliferation of T cells from secondary lymphoid tissues of immune mice. Cells from LALN and spleens of immunized mice were stained with CFSE and cultured with (i) no restimulation (No Stim), (ii) anti-CD3/anti-CD28 ( ${alpha}$ CD3 ${alpha}$ CD28), or (iii) C. neoformans lysate (C. neo Lysate). The histograms show the results for CD4⁺ or CD8⁺ gated populations after 2 and 4 days in culture.

Proliferative responses by both CD4⁺ and CD8⁺ T cells were alsoobserved in response to a number of other C. neoformans-derivedantigen preparations, including heat-killed organisms, culturefiltrate antigen (CneF), and purified cryptococcal mannoprotein(Fig. 6A). These results demonstrated that a portion of CD4⁺and CD8⁺ T cells in the secondary lymphoid tissues of immunemice proliferate in response to a number of C. neoformans antigenpreparations.

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FIG. 6. Proliferation of (A) and effector cytokine production by (B and C) T cells from immunized mice in response to a variety of C. neoformans antigens. (A) Pooled LALN cells and splenocytes from immunized mice were cultured with the following stimuli, as described in Materials and Methods: anti-CD3/anti-CD28, no stimulus (No Stim), heat-killed C. neoformans (Cneo), C. neoformans lysate, C. neoformans culture filtrate antigen (CneF), and purified C. neoformans mannoprotein (MP). The data are the data from one of two experiments in which similar results were obtained. (B and C) Frequency of production of IFN- ${gamma}$ and TNF- ${alpha}$ by CD4⁺ (B) and CD8⁺ (C) T cells from immunized mice in response to C. neoformans antigens. Pooled LALN cells and splenocytes from immunized mice were cultured with the various stimuli, as described in Materials and Methods. The frequency is the percentage of cytokine-positive T cells in the stimulated wells minus the percentage in unstimulated wells. The data are the data from one of two experiments in which similar results were obtained.

Effector cytokine production by T cells from immunized mice in response to C. neoformans antigens. Our next objective was to determine whether the preparationsof C. neoformans antigens (heat-killed organisms, lysate, CneF,or mannoprotein) could be used to assay effector cytokine production.To do this, lymphocyte suspensions from immune mice were culturedwith uninfected adherent splenocytes in the presence of eachstimulus, and the production of IFN- ${gamma}$ and TNF- ${alpha}$ was assayed byintracellular flow cytometry, as described in Materials andMethods. In response to each of the antigen preparations, CD4⁺T cells produced both IFN- ${gamma}$ and TNF- ${alpha}$ (Fig. 6B). In contrast,CD8⁺ T cells produced only IFN- ${gamma}$ in response to C. neoformansantigens (Fig. 6C). These results demonstrate that T cells fromthe secondary lymphoid tissues of immune mice produced effectorcytokines in response to nonviable C. neoformans antigen preparations.

Proliferation of CD4⁺ and CD8⁺ T cells from LALN of mice with pulmonary cryptococcal infections. Our next objective was to determine whether T cells from theLALN of mice during primary pulmonary infection proliferatein response to C. neoformans antigens. To do this, we assayedproliferation of LALN CD4⁺ and CD8⁺ T cells in response to C.neoformans lysate. The results obtained with immune mice suggestedthat maximal proliferation and effector cytokine productioncould be assayed using lysate, relative to the other antigenpreparations (Fig. 6). Adherent lung cells from uninfected micewere cultured with LALN cells from mice 2 weeks after a primaryinfection, as described in Materials and Methods. Minimal proliferationwas observed when LALN T cells were not stimulated; however,LALN T cells from infected mice proliferated in response toC. neoformans lysate (Fig. 7). We also investigated whetherC. neoformans lysate induced proliferation from naive T cells.Although no such activity has been demonstrated for murine Tcells, components of the C. neoformans cell wall have been shownto have mitogenic activity with human T cells (21, 25). After4 days in culture, there was no difference in CFSE stainingbetween unstimulated T cells from uninfected spleens and T cellsstimulated with C. neoformans lysate (Fig. 7). T cells fromuninfected spleens were capable of proliferation, however, anddivided extensively in response to anti-CD3/anti-CD28 stimulation(Fig. 7). Both CD4⁺ and CD8⁺ T cells obtained from the LALNof mice at week 2 postinfection proliferated in response toC. neoformans lysate (Fig. 7). These results demonstrated thatC. neoformans lysate did not induce mitogenic proliferationin naive murine T cells and that both CD4⁺ and CD8⁺ T cellsrecovered from the LALN proliferated in response to C. neoformanslysate. These data support the conclusion that a portion ofthe T cells in the LALN during pulmonary C. neoformans infectionare antigen specific.

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FIG. 7. Proliferative responses of T cells from the LALN of mice infected with C. neoformans. Splenocytes from uninfected mice were used as a control, because there were insufficient numbers of T cells from the LALN of uninfected specific-pathogen-free mice for analysis. T cells were enriched by MACS, stained with CSFE, and cultured with adherent splenocytes from uninfected controls for 4 days in the presence of (i) no additional stimulus (No Stim), (ii) C. neoformans lysate (C. neo Lysate), or (iii) anti-CD3 antibodies ( ${alpha}$ CD3). The histograms show data for viable cells gated on CD4⁺ or CD8⁺ cells, and the percentages indicate the percentages of daughter cells (cells which had undergone $≥$ 1 cell division). The data are the data from one of two experiments in which similar results were obtained.

Effector cytokine production by CD4⁺ and CD8⁺ T cells from C. neoformans-infected mice. Our next objective was to determine the frequencies of CD4⁺and CD8⁺ T cells producing the effector cytokines IFN- ${gamma}$ and TNF- ${alpha}$ in the lungs and secondary lymphoid tissues of C. neoformans-infectedmice. To do this, T cells from infected lungs, LALN, spleens,uninfected lungs, and uninfected spleens were enriched by MACSor FACS, as described in Materials and Methods. T cells werecultured with adherent cells from uninfected control lungs inthe presence of no stimulus or C. neoformans lysate. The resultswere expressed as the increase in the number of cytokine-positivecells compared with the number in unstimulated samples.

CD4⁺ T cells from infected lungs, but not CD4⁺ T cells fromsecondary lymphoid tissues, produced IFN- ${gamma}$ at a high frequencyin response to CD3/CD28 restimulation (Fig. 8). CD4⁺ T cellsin infected lungs produced TNF- ${alpha}$ in response to CD3/CD28 restimulation,but the frequency of TNF- ${alpha}$ ⁺ CD4⁺ T cells in uninfected tissueswas equal to or higher than the frequency of TNF- ${alpha}$ ⁺ CD4⁺ T cellsin infected lungs (Fig. 8). These results demonstrated thatin response to CD3/CD28 restimulation, lung CD4⁺ T cells frominfected mice produced IFN- ${gamma}$ . CD4⁺ T cells regulated the productionof TNF- ${alpha}$ less stringently than they regulated the productionof IFN- ${gamma}$ , however, as CD3/CD28 stimulation resulted in productionof TNF- ${alpha}$ by CD4⁺ T cells from uninfected mice. CD8⁺ T cells fromlungs and secondary lymphoid tissues produced IFN- ${gamma}$ in responseto CD3/CD28 restimulation (Fig. 8). However, similar frequenciesof CD8⁺ T cells from uninfected tissues produced IFN- ${gamma}$ in responseto CD3/CD28 (Fig. 8). Thus, CD8⁺ T cells can produce TNF- ${alpha}$ andIFN- ${gamma}$ in response to low-dose CD3/CD28 restimulation in the absenceof infection.

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FIG. 8. Frequency of production of effector cytokines by T cells from the lungs and secondary lymphoid tissues. T cells from the lungs, LALN, and spleens of infected mice and from the lungs and spleens of uninfected mice were enriched by MACS or FACS and cocultured with adherent lung cells from uninfected mice, as described in Materials and Methods. Cultures received no additional stimulus or C. neoformans lysate. The bars indicate the percentage of cytokine-positive T cells in the stimulated wells minus the percentage of cytokine-positive cells in unstimulated wells. The data are the data from one of two experiments in which similar results were obtained.

In response to C. neoformans lysate, CD4⁺ T cells from secondarylymphoid tissues did not produce IFN- ${gamma}$ or TNF- ${alpha}$ . Markedly higherfrequencies of IFN- ${gamma}$ and TNF- ${alpha}$ production were observed with CD4⁺T cells from infected lungs (Fig. 8). Although anti-CD3/anti-CD28restimulation resulted in significant IFN- ${gamma}$ production by CD8⁺T cells from the secondary lymphoid tissues (Fig. 8), CD8⁺ Tcells from secondary lymphoid tissues restimulated with lysatewere poor effector cytokine producers (Fig. 8). Similar to theresults obtained with CD4⁺ T cells, only lung CD8⁺ T cells frominfected lungs produced IFN- ${gamma}$ and TNF- ${alpha}$ in response to C. neoformanslysate (Fig. 8). These data show that C. neoformans lysate inducesminimal effector cytokine production by T cells in uninfectedmice. Furthermore, these results demonstrate that lung T cellsfrom C. neoformans-infected mice produce effector cytokinesin response to in vitro restimulation with C. neoformans lysateand that effector cytokine production occurs at a higher frequencythan it occurs in T cells from secondary lymphoid tissues.

DISCUSSION

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Discussion

In this paper we report that in immunocompetent mice, a diverseTCR Vß repertoire is maintained throughout the primaryresponse to pulmonary C. neoformans infection. While Vß13 CD4⁺ T cells were preferentially expanded at week 3 postinfection,they comprised a minority of the overall lung CD4⁺ T-cell population.Furthermore, this preferential expansion did not persist untilweek 5 postinfection. CD4⁺ T-cell deficiency resulted in relativeexpansion of all CD8⁺ T-cell subsets. During the secondary immuneresponse, preferential usage of CD4⁺ T-cell Vß subsetsoccurred in individuals, but not overall. Both CD4⁺ and CD8⁺T cells from the secondary lymphoid tissues of immunized miceproliferated in response to a variety of C. neoformans antigens,including heat-killed whole C. neoformans, culture filtrateantigen (CneF), C. neoformans lysate, and purified cryptococcalmannoprotein. CD4⁺ and CD8⁺ T cells from the secondary lymphoidtissues of immune mice produced IFN- ${gamma}$ in response to these stimuli,and CD4⁺ T cells also produced TNF- ${alpha}$ . Both CD4⁺ and CD8⁺ T cellsfrom the secondary lymphoid tissues of mice exhibiting a primaryresponse to C. neoformans proliferated in response to C. neoformanslysate. In response to stimulation with C. neoformans lysate,lung CD4⁺ and CD8⁺ T cells produced the effector cytokines TNF- ${alpha}$ and IFN- ${gamma}$ .

Our studies demonstrated that a diverse TCR Vß repertoireis maintained throughout the primary response, but focusingof the TCR Vß repertoire occurred in CD4⁺ T-cell populationsof individuals during the secondary immune response. Pulmonaryinfection of mice with H. capsulatum leads to significant skewingof the TCR Vß repertoire, as does protective vaccinationwith H. capsulatum heat shock protein 60 (9, 10, 23). Depletionof the preferentially expanded population in either case adverselyaffects clearance (9, 10, 23). Evidence obtained with otherexperimental systems, however, suggests that Vß preferencesduring primary infection are the exception rather than the rule.During primary Listeria monocytogenes infection, epitope-specificT cells have a diverse TCR Vß repertoire (4). In asecondary response, however, focusing of the Vß repertoireoccurs in the responding antigen-specific T-cell populations(4). Similar to the results reported here, variability betweengenetically identical individuals was also observed (4). A T-cellresponse in which a common TCR Vß repertoire is foundin all individuals has been termed a "public" repertoire, whereasa "private" repertoire is specific to an individual (6). Ina number of recent studies workers have sought to determinethe relative roles of private and public repertoires, chieflyin models of T-cell responses to viruses (14, 26). The CD8⁺T-cell response to influenza in C57BL/6 mice is directed primarilyagainst the immunodominant epitopes NP₃₆₆ and PA₂₂₄. The responseto NP₃₆₆ is characteristically public, whereas the responseto PA₂₂₄ is largely private (14, 15, 26). Although similar numbersof NP₃₆₆- and PA₂₂₄-specific T cells are generated in the primaryresponse, the secondary response is dominated by the publicNP₃₆₆ response, suggesting that public specificity may playa more prominent role in secondary T-cell responses (2). However,private specificity may play a more important role in regulatingdifferential responses to heterologous infections in geneticallyidentical mice (15). Although in our study we did not utilizetechniques such as spectratyping, the differences in Vßprofiles between individual mice suggest that the CD4⁺ T-cellVß repertoire during secondary C. neoformans infectioncould be characterized as largely private.

Our results indicated that during CD4⁺ T-cell deficiency, C.neoformans infection led to enhanced expansion of all CD8⁺ Vßsubsets compared to the expansion observed with CD4⁺ T-cellsufficiency. Previous studies demonstrated that hyperexpansionof CD8⁺ T cells occurs in response to C. neoformans during CD4⁺T-cell deficiency (18). The IFN- ${gamma}$ -producing CD8⁺ T-cell effectorsmediate a level of protection in a CD4⁺ T-cell-deficient host(18). Together, these results demonstrate that while the absenceof CD4⁺ T cells increases the magnitude of the CD8⁺ T-cell responseto C. neoformans infection, the CD8⁺ response to C. neoformansin a CD4⁺ T-cell-deficient host is also characterized by diversity.

If C. neoformans has superantigen activity in vivo in mice,we would have expected specific Vß subsets to be expandedin response to C. neoformans infection. Superantigens are microbiallyderived proteins which stimulate the proliferation of T cellsin a non-antigen-specific manner via direct binding of the Vßregion of the T-cell receptor (17). Superantigens may benefita pathogen by inducing a high frequency of nonspecific T cells,which can interfere with the antigen-specific response (12).C. neoformans produces a mitogen (CnM) for human T cells, whoseactivity is localized to proteins found in the cell wall andmembrane and can stimulate naive T-cell proliferation (20, 21).The mitogenic effect is similar to that of staphyloccocal enterotoxinB, a known superantigen, and requires phagocytosis and proteinprocessing (24). In our study, we observed no proliferationby CD4⁺ or CD8⁺ T cells in response to C. neoformans lysate,even after 5 days in culture. Thus, our results suggest thatC. neoformans mitogen is not active in mice.

Our data demonstrated that while T cells from the lymph nodesor spleens of mice at 2 weeks postinfection produced littleTNF- ${alpha}$ and IFN- ${gamma}$ in response to stimulation with C. neoformanslysate, a significant number of T cells in the lungs producedeach of these effector cytokines (Fig. 8). These results showthat there is compartmentalization of T-cell effector functionduring pulmonary C. neoformans infection. T cells encounterantigen-presenting cells in the LALN bearing cognate antigen,where they respond by proliferating. Concomitant with traffickingto the lungs, both CD4⁺ and CD8⁺ T cells acquire an antigen-dependenteffector cytokine-producing phenotype. Throughout the immuneresponse to pulmonary C. neoformans infection, both CD4⁺ andCD8⁺ T cells maintain a diverse TCR Vß repertoire,and the response is driven by multiple C. neoformans antigensrather than by one or two immunodominant antigens.

ACKNOWLEDGMENTS

We thank Stuart Levitz and his laboratory for providing purifiedmannoprotein.

This work was supported by National Institutes of Health grantsR01-HL065912 (to G.B.H.), R01-AI059201 (to G.B.H.), R01-HL051082(to G.B.T.), and T32-AI07413 (to D.M.L.) and by a Departmentof Veterans Affairs merit grant (to G.B.T.).

FOOTNOTES

* Corresponding author. Mailing address: Pulmonary and Critical Care Medicine, 6301 MSRB III, University of Michigan Medical Center, Ann Arbor, MI 48109-0642. Phone: (734) 936-9369. Fax: (734) 764-2655. E-mail: ghuff{at}umich.edu.

Editor: A. Casadevall

REFERENCES

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