Characterization of Protective Mucosal and Systemic Immune Responses Elicited by Pneumococcal Surface Protein PspA and PspC Nasal Vaccines against a Respiratory Pneumococcal Challenge in Mice

Pneumococcal surface protein A (PspA) and PspC are virulencefactors that are involved in the adhesion of Streptococcus pneumoniaeto epithelial cells and/or evasion from the immune system. Here,the immune responses induced by mucosal vaccines composed ofboth antigens as recombinant proteins or delivered by Lactobacilluscasei were evaluated. None of the PspC vaccines protected miceagainst an invasive challenge with pneumococcal strain ATCC6303. On the other hand, protection was observed for immunizationwith vaccines composed of PspA from clade 5 (PspA5 or L. caseiexpressing PspA5) through the intranasal route. The protectiveresponse was distinguished by a Th1 profile with high levelsof immunoglobulin G2a production, efficient complement deposition,release of proinflammatory cytokines, and infiltration of neutrophils.Intranasal immunization with PspA5 elicited the highest levelof protection, characterized by increased levels of secretionof interleukin-17 and gamma interferon by lung and spleen cells,respectively, and low levels of tumor necrosis factor alphain the respiratory tract.

INTRODUCTION

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INTRODUCTION

Pneumococcal diseases kill more than 1 million children worldwideevery year. The situation is worse in developing countries,where 90% of deaths occur. In Latin America, there are at least1.6 million cases of pneumococcal disease every year, killing18,000 children (53). While appropriate treatment, includingthe use of antibiotics and good nutrition, lowers the incidenceof pneumococcal diseases, vaccines are the most efficaciousway of preventing them. The existing pneumococcal conjugatevaccine dramatically reduces diseases, disabilities, and deaths,but elevated cost and protection restricted to included serotypeshave prevented its implementation in large-scale immunizationprograms in developing countries. For these reasons, there isconsiderable interest in using conserved pneumococcal proteinantigens as vaccines to provide cost-effective broad protectionin all age groups. A number of leading candidates have beenshown to elicit protection in mice (10, 51); among these antigens,two of the most promising candidates are pneumococcal surfaceprotein A (PspA) and PspC.

An additional concern in the development of cost-effective vaccinesagainst pneumococcal disease is the route of immunization. Humanvaccines are traditionally administered intramuscularly by needleinoculation, which brings the risk of transmitting blood-bornepathogens such as human immunodeficiency virus and hepatitisviruses (20). Furthermore, the cost of equipment and well-trainedpersonnel for delivering vaccines by parenteral routes is severaltimes higher than the cost of the vaccines themselves. Thisaspect is extremely important for vaccine implementation inlarge-scale immunization programs for developing countries.Mucosal delivery of pediatric vaccines has become an explicitgoal of the WHO (20). Immunization via mucosal surfaces wouldgreatly increase the ease of vaccination and would be more readilyacceptable than parenteral immunization in many populations.Therefore, the move from injection to mucosal application wouldbe very positive from economical, logistical, and safety standpoints.Mucosal immune responses are also important for the preventionof many infectious diseases because they represent the firstbarrier from the hosts that pathogens must evade.

Research into the host immune response to pneumococcal diseaseshas focused primarily on the role of innate and adaptative humoralimmune responses. However, in the last few years, attentionhas been drawn to cellular immune responses against Streptococcuspneumoniae, with interesting results. The majority of thesestudies analyzed cellular aspects of innate immunity and proposedthat lymphocytes, neutrophils, and macrophages orchestrate effectiveimmune responses without the presence of specific antibodies.In this context, proinflammatory cytokines promote an adequatemilieu for pneumococcal clearance (22, 24, 25, 31, 34, 50, 54).A Th1-biased immune response has also been shown to be engagedin the resolution of pneumococcal infection in humans (21).Nevertheless, inflammatory cell influx into the lung and mucosalresponses must be regulated to avoid exacerbated tissue injury.This is evidenced in recent studies of the role of ${gamma}$ ${delta}$ T cellsand/or anti-inflammatory cytokines, such as interleukin-10 (IL-10),in pneumococcal infection (26, 42, 55).

Protective immune responses against invasive pneumococcal diseaseand colonization were shown using pneumococcal whole-cell vaccines(28, 46) or recombinant proteins as mucosal vaccines (2, 6,7, 9, 40). In recent approaches, lactic acid bacteria (3, 11,18, 37), which are able to activate and modulate the innateimmune system (35, 42), were used for pneumococcal antigen presentation,with promising results.

Very few works compared pulmonary and systemic immune responsesinduced by pneumococcal antigens using parenteral and mucosalimmunizations (13). The present study aims at investigatinglocal and systemic cellular and humoral immune responses requiredfor protection against invasive intranasal (i.n.) challengewith S. pneumoniae strain ATCC 6303 using PspA and PspC antigensadministered by both routes, without the use of adjuvants, orpresented by Lactobacillus casei through the nasal route.

MATERIALS AND METHODS

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MATERIALS AND METHODS

Bacterial strains and growth conditions. Lactococcus lactis cultures were grown in M17 medium (Difco);L. casei CECT5275 cultures were grown in Man, Rogosa, and Sharpemedium (Difco); and S. pneumoniae ATCC 6303 cultures (serotype3, PspA clade 5) were grown in Todd-Hewitt broth (Sigma) supplementedwith 0.5% yeast extract (THY). Bacteria were grown at 37°Cwithout shaking. Pneumococcal strain ATCC 6303 was always platedin blood agar and grown overnight at 37°C before inoculationin THY. All bacterial stocks were maintained at –80°Cin their respective media containing 20% glycerol.

Recombinant proteins. Expression and purification of the N-terminal fragment of PspAfrom clade 5 (from strain 122/02, serotype 23F) were performedas previously described (14). The fragment encoding the PspCN-terminal region was amplified from S. pneumoniae strain 491/00(Instituto Adolfo Lutz, São Paulo, Brazil) using forwardprimer 5'-TAGGGATCCCATGCGACAGAGAACGAGA-3' and reverse primer5'-CTGCAGTTATTGTGGTTGTTCAGC-3'. The gene product was clonedinto a pGEMT-Easy vector (Promega), and the sequence was confirmedby DNA sequencing. The fragment was subcloned into linearizedvector pAE (43) and used to transform Escherichia coli BL21(DE3)SI competent cells (Invitrogen). Protein expression was inducedin mid-exponential-phase cultures by the addition of 300 mMNaCl. The recombinant proteins bearing N-terminal histidinetags were purified from the soluble fraction by affinity chromatographyusing Ni²⁺-charged resin (HisTrap HP; GE Healthcare). Elutionwas carried out with 250 mM imidazole. The purified fractionswere analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis,dialyzed against 10 mM Tris-HCl (pH 8.0)-20 mM NaCl-0.1% glycine,and stored at –20°C.

Cloning and recombinant procedures in lactic acid bacteria. Vector pT1NX (11) was used for the constitutive intracellularexpression of the N-terminal region of PspA5 and PspC in L.casei. The following primers were used for amplification: PspAlacF(5'-ATGCATCGATATCAGAAGAAGCTCCCGTAGCT-3') and PspAlacR (5'-GGATCCTTAAGATCTTTTTGGTGCAGGAGCAGCTGG-3')for the amplification of pspA5 and PspClacF (5'-ACCGGTGATATCCCATGCGACAGAGAACGAG-3')and PspClacR (5'-GGATCCTTAAGATCTTTGTGGTTGTTCAGC-3') for theamplification of pspC. After sequencing confirmation, the fragmentswere cloned into vector pT1NX, and ligation products were usedto transform competent L. lactis cells as previously described(37). Plasmids isolated from L. lactis were then used for theelectroporation of L. casei (37). L. lactis and L. casei transformantswere selected by plating onto the respective medium containing1.8% agar and 5 µg/ml of erythromycin. Protein expressionwas confirmed by Western blotting of L. casei lysates usingspecific antibodies.

Immunization of mice. Five- to seven-week-old female C57BL/6 mice from the CentralAnimal Facility of Butantan Institute were supplied with foodand water ad libitum. Animal experimental protocols were approvedby Use Ethics Committee of Instituto Butantan (São Paulo,Brazil). Groups of 4 to 10 animals were anesthetized throughthe intraperitoneal (i.p.) route with 200 µl of a mixtureof 0.5% xylazine and 0.2% ketamine and inoculated i.n. with6 doses (5 µg in 10 µl) on days 0, 3, 14, 17, 28,and 31 or subcutaneously (s.c.) with 3 doses on days 0, 14,and 28 (5 µg in 100 µl) of PspC or PspA5 previouslytreated with Triton X-114 to remove lipopolysaccharide as describedpreviously (1) and without the use of adjuvants. L. casei cellsexpressing PspC or PspA5 or carrying the empty vector were grownuntil stationary phase (optical density at 550 nm [OD₅₅₀] of $≥$ 2), collected by centrifugation, washed with saline, and thensuspended to 10⁹ viable cells in 10 µl. The cell suspensionwas inoculated i.n. on days 0, 1, 14, 15, 28, and 29.

Detection of anti-PspC- and anti-PspA-specific antibodies through ELISA. Mice were bled through the retroorbital plexus 15 days afterthe last immunization. Vaginal washes were collected from days15 to 19 after the last immunization by gentle pipetting of25 µl of saline twice, and samples were pooled for eachanimal. Antibody levels in serum, vaginal washes, and bronchoalveolarlavage fluid (BALF) (collected as described below) were evaluatedby enzyme-linked immunosorbent assay (ELISA) in plates coatedwith PspC or PspA5. The assay was performed using goat anti-mouseimmunoglobulin G [IgG], IgA, IgG1, or IgG2a and rabbit anti-goatantibody conjugated with horseradish peroxidase (Southern Biotech).Differences in antibody titers were analyzed by the Mann-WhitneyU test, and a P value of $≤$ 0.05 was considered to be significantlydifferent. Titers were defined as the last dilution in whichabsorbances at 492 nm reached 0.1.

Antibody binding and complement deposition assays. Frozen stocks of S. pneumoniae ATCC 6303 were plated onto bloodagar overnight and then grown in THY to an OD₆₀₀ of 0.4 to 0.5( $~$ 10⁸ CFU/ml) and harvested by centrifugation. Bacteria werewashed, resuspended in phosphate-buffered saline (PBS), andincubated with 10% of pooled sera during 30 min at 37°C.Samples were washed once with PBS before incubation with fluoresceinisothiocyanate-conjugated anti-mouse IgG (Sigma) for 30 minon ice. For complement deposition assays, sera were previouslyheated at 56°C for 30 min and incubated with bacteria ata concentration of 25% at 37°C for 30 min. Samples werewashed once with PBS and incubated with 10% normal mouse serumas the source of complement in Gelatin Veronal buffer (Sigma)at 37°C for 30 min. After washing, samples were incubatedwith fluorescein isothiocyanate-conjugated anti-mouse C3 IgG(MP Biomedicals) in PBS for 30 min on ice. Samples were fixedwith 2% formaldehyde after two washing steps and stored at 4°C.Flow cytometry analysis was conducted using a FACSCalibur apparatus(Becton Dickinson), and 10,000 gated events were recorded. Themedian of fluorescent bacteria was used to compare the groups.

i.n. challenge. i.n. challenge was performed to monitor mouse survival and toanalyze immune cell responses, since in previous work from ourgroup, such responses were not detected in nonchallenged immunizedmice (our unpublished data). S. pneumoniae ATCC 6303 cells weregrown in THY medium until the OD₆₀₀ reached 0.4, aliquoted,and kept frozen at –80°C. A suspension containing10⁵ bacteria in 30 µl was inoculated into one nostrilof mice previously anesthetized through the i.p. route with200 µl of a mixture of 0.5% xylazine and 0.2% ketamine21 days after the last immunization. Survival was monitoredfor 10 days. Differences in survival rates were analyzed byFisher's exact test, and differences in survival time were measuredby Kaplan-Meier survival curve analysis. In both cases, a Pvalue of $≤$ 0.05 was considered to be significantly different.

Collection of BALF and cytospin. Mice were sacrificed 13 h after i.n. pneumococcal challengeby injection of a lethal dose of urethane (15 mg per 10 g ofbody weight) to collect the spleen, lung, and BALF samples.A catheter was inserted into the trachea of the mice, and lungswere rinsed with 0.5 ml of sterile PBS, followed by an additionalrinse with 1 ml of PBS. The fluids from both rinses were pooled.Cells obtained from the pooled fluid were washed and resuspendedin PBS and counted, and 4 x 10⁴ cells were spun onto glass slides(4 min at 1,300 rpm) by the use of a cytocentrifuge (StatSpinCytofuge). Cytospin slides were stained, and 100 cells weredifferentially counted to analyze the percentage of infiltrationof each cell type. Fluid samples were stored at –80°Cfor subsequent analyses.

Detection of antigen-specific cytokines. Lung tissue was dissected into small pieces and digested witha collagenase-DNase solution (collagenase type IV-DNase-150,50 units/ml; Sigma-Aldrich). Single-cell suspensions of spleenwere obtained as described previously (17). Viable cell countswere determined by trypan blue exclusion. Lung and spleen cellsfrom each group were pooled, and cells secreting gamma interferon(IFN- ${gamma}$ ) were detected using an enzyme-linked immunospot (ELISPOT)set (BD Biosciences) as described previously (17) using dilutionsfrom 5 x 10⁶ to 1 x 10⁷ cells/ml and stimulation with recombinantproteins (5 µg/ml) for 20 h. The average number of spot-formingcells (SFCs) was calculated from duplicate wells, subtractingnonstimulated wells. Detection of IL-17, tumor necrosis factoralpha (TNF- ${alpha}$ ), and IL-5 secretion in the supernatants of spleenand lung cell cultures stimulated for 72 h with recombinantproteins (5 µg/ml) was performed by use of sandwich ELISA(BD Biosciences) using 1 x 10⁷ cells/ml.

Nucleotide sequence accession number. The nucleotide sequence for the PspC gene fragment was depositedin GenBank under accession no. EF424119.

RESULTS

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RESULTS

Infiltration of cells after i.n. pneumococcal challenge in PspC-immunized mice. Mice were i.n. immunized with the PspC protein without the useof an adjuvant or L. casei cells expressing this antigen. Animalsimmunized with L. casei cells carrying the empty vector (L.casei) or nonimmunized animals were used as control groups.An additional group received PspC s.c. Animals were bled 15days after the last immunization, and antibodies in sera andvaginal washes were analyzed through ELISA. Specific anti-PspCIgGs were detected only in sera from s.c.-immunized animals(IgG titer of 1:800). For the other groups, no reactivity wasobserved even at the lowest dilution tested (1:20). In addition,anti-PspC IgA was not observed in vaginal washes collected fromimmunized animals (the minimal dilution tested was 1:4). Twenty-onedays after the last immunization, all groups were challengedwith strain ATCC 6303 through the i.n. route, and 13 h afterchallenge, BALF and tissue samples were collected. The timepoint of 13 h was chosen because at this time, the animals donot yet show any sign of the disease, and there is no detectableCFU in blood. In addition, no differences in lung CFU countsamong all groups were observed at this point (data not shown).Even 13 h after challenge, anti-PspC antibodies were not detectedin BALF samples by ELISA. Analysis of cells recovered from BALF(Fig. 1) showed a significant infiltration of neutrophils inL. casei PspC-immunized animals compared with the L. casei controlgroup (P = 0.0004). Nasal immunization with PspC also inducedan augmentation in neutrophil infiltration compared with neutrophilinfiltration in nonimmunized animals, but this difference wasnot statistically significant. No difference was observed inthe percentages of neutrophils recovered from mice s.c. immunizedwith PspC compared with nonimmunized animals.

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FIG. 1. BALF cell counts. Slides were prepared with 4 x 10⁴ cells from BALF. Percentages of infiltrated cells are expressed as means of data from four to five mice per group. # represents a significant difference in neutrophil infiltration between the group immunized with L. casei (L.c.) and the group immunized with L. casei PspC (P = 0.0004 by Mann-Whitney U test). Non, nonimmunized group.

IFN- ${gamma}$ and IL-17 secretion by lung and spleen cells in PspC-immunized mice. After collection of BALF, lung and spleen were excised frommice. Secretion of IFN- ${gamma}$ and IL-17 from pooled cells of eachgroup was detected through ELISPOT assay and sandwich ELISA,respectively. As observed in Fig. 2A, nasal immunizations withL. casei PspC and PspC were able to induce an increase in thenumber of lung cells secreting IFN- ${gamma}$ compared with control groupsor even with the group immunized s.c. with PspC. This effectwas more pronounced for L. casei PspC than for PspC nasal immunization.IFN- ${gamma}$ secretion from spleen cells was also analyzed, and PspCimmunization was able to induce an increase in numbers of SFCswhen administered through the s.c. route. Interestingly, theL. casei PspC-immunized group showed the same level of IFN- ${gamma}$ -secretingcells as the group immunized s.c. with PspC, whereas no inductionof IFN- ${gamma}$ secretion by spleen cells was observed in the groupi.n. immunized with PspC (Fig. 2B). As for IL-17, all immunizedgroups displayed elevated levels of secretion of this cytokinein lung cell culture supernatants. The most pronounced secretionwas observed in the group immunized i.n. with PspC that presentedan eightfold increase in the concentration of this cytokine(Fig. 2C). On the other hand, this immunization induced fourfold-lessIL-17 secretion than L. casei PspC immunization in spleen cells,whereas subcutaneous immunization with PspC did not produceany increase at all (Fig. 2D).

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FIG. 2. Cellular immune response in lung (A and C) and spleen (B and D) induced by immunization with PspC antigen after i.n. challenge with strain ATCC 6303. Spleen and lung cells were isolated from immunized mice 13 h after i.n. challenge and incubated with PspC in ELISPOT plates previously coated with anti-IFN- ${gamma}$ . SFCs of IFN- ${gamma}$ were detected through ELISPOT, and the average number of spots in duplicate wells was calculated by subtracting nonstimulated wells and considered as the number of SFCs/10⁶ cultured cells (A and B). Cells were also incubated with PspC, and IL-17 secretion in the supernatants was detected through sandwich ELISA (C and D). Results are representative of two independent experiments. L.c., L. casei; Non, nonimmunized group.

Serum and mucosal anti-PspA antibody responses. The levels of anti-PspA antibodies were measured by ELISA. Asshown in Fig. 3A, i.n. immunization of mice with PspA5 elicitedsignificantly higher IgG responses than in nonimmunized mice(P = 0.0001). L. casei PspA5 immunization also led to a significantincrease in levels of anti-PspA antibodies compared with thosefound with L. casei immunization (P = 0.002). s.c. immunizationwith PspA5 induced an elevated level of antibody productioncompared with that of nonimmunized animals (P = 0.001), butthe level was slightly lower than the one observed for miceimmunized i.n. with PspA5. i.n. immunization induced intermediateanti-PspA5 IgG1/IgG2a ratios in protein groups (IgG1/IgG2a ratioof 91) and lower ratios when the antigens were delivered byL. casei (IgG1/IgG2a ratio of 0.1) (Fig. 3B). The highest ratiowas observed in the group immunized with PspA5 s.c. (IgG1/IgG2aratio of 358). Specific anti-PspA secreted IgA (sIgA) was detectedonly in vaginal washes obtained from mice i.n. immunized withPspA5 (Fig. 3C). These antibodies were not detected in samplesfrom the other groups, even at a 1:4 dilution.

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FIG. 3. Evaluation of anti-PspA antibodies in mice immunized with PspA5 vaccines. Two weeks after the last immunization, anti-PspA IgG (A), IgG1, and IgG2a (B) in sera and IgA in vaginal washes (C) were detected through ELISA. Log₁₀ values of antibody titers are shown, and IgG1/IgG2a titer ratios are indicated above the bars (B). Results are representative of two experiments. Asterisks represent significant differences from the indicated control group (*, P = 0.002; **, P = 0.001; ***, P = 0.0001 [Mann-Whitney U test]). L.c., L. casei; Non, nonimmunized group.

Binding of anti-PspA antibodies and complement deposition onto ATCC 6303. In order to investigate whether anti-PspA antibodies detectedby ELISA would be able to bind to the surface of intact pneumococciand mediate C3 deposition, sera from mice immunized i.n. ors.c. with PspA5 or immunized i.n. with L. casei PspA5 were incubatedwith strain ATCC 6303 in an antibody binding assay. Sera fromnonimmunized mice or mice immunized with L. casei were usedas controls. As shown in Fig. 4A, we observed that L. caseiPspA5 immunization elicited antibodies that showed the highestbinding capacity, which was especially surprising compared withs.c. immunization with PspA5. Furthermore, when the abilityto mediate C3 deposition onto the pneumococcal surface was analyzed(Fig. 4B), sera from animals i.n. inoculated with L. casei PspA5or PspA5 elicited a more pronounced increase in C3 depositionthan did sera from mice s.c. immunized with PspA5. It is importantthat PspA5 immunization through the s.c. route, without adjuvant,elicited larger amounts of specific PspA5 antibodies than didthe L. casei PspA5 group (Fig. 3A). However, these Igs did notdisplay the same efficacy in binding onto the pneumococcal surfaceand enhancing complement deposition.

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FIG. 4. Binding of anti-PspA5 antibodies and complement deposition onto the pneumococcal surface. Sera from mice i.n. immunized with PspA5 (dotted lines) or L. casei PspA5 (solid heavy lines) or s.c. immunized with PspA5 (solid thin lines) were tested for the ability to bind to the pneumococcal surface (A) and to mediate C3 deposition (B). S. pneumoniae ATCC 6303 was incubated with 10% (A) or 25% (B) serum from each group serum. Sera from nonimmunized (Non) animals (gray areas) and animals immunized with L. casei (L.c.) (dashed lines) were used as controls. The median fluorescence of the bacteria is shown for each sample. Data are representative of two independent experiments. FITC, fluorescein isothiocyanate.

Enhancement of infiltration of neutrophils and presence of anti-PspA5 antibodies in BALF after i.n. pneumococcal challenge. BALF cell samples were recovered from animals immunized withPspA5 vaccines 13 h after a respiratory challenge with strainATCC 6303. A significant increase in the level of infiltrationof neutrophils was observed in mice immunized with L. caseiPspA5 compared with mice immunized with L. casei (P = 0.005)(Fig. 5). BALF recovered from mice immunized i.n. with PspA5also demonstrated an increase in levels of these cells comparedwith nonimmunized mice (P = 0.001). Further investigation showedthat only mice immunized i.n. with PspA5 presented anti-PspA5sIgA (mean log of antibody titer of 1.12 ± 0.51) in BALFrecovered after pneumococcal challenge (data not shown).

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FIG. 5. BALF cell counts. Slides were prepared with 4 x 10⁴ cells from BALF. Percentages of infiltrated cells are expressed as means of data from four to five mice per group. An * represents a significant difference in neutrophil infiltration between mice immunized i.n. with PspA5 and nonimmunized mice (Non). ** represents a significant difference in neutrophil infiltration from mice immunized with L. casei PspA5 and L. casei (L.c.) (*, P = 0.001; **, P = 0.005 [Mann-Whitney U test]).

Cytokine secretion by lung and spleen cells in PspA5-immunized mice. Analyzes of the cellular immune response showed that L. caseiPspA5 immunization led to an intense increase in the numberof lung cells secreting IFN- ${gamma}$ (fourfold increase) compared withother groups, including mice immunized i.n. with PspA5 (Fig.6A). In spleen cells, the highest level of IFN- ${gamma}$ secretion wasobserved in the group immunized with PspA5 s.c., followed byPspA5 i.n. immunization (Fig. 6B). Conversely, IL-17 secretionwas augmented in lung cells obtained from the groups immunizedwith PspA5 s.c. and PspA5 i.n. (Fig. 6C). This last group presentedthe most pronounced increase in levels of IL-17 secretion inthe supernatant of lung and spleen cells (Fig. 6D). The levelof IL-5, a Th2 cytokine, was also measured, and IL-5 was detectedonly in the group immunized s.c. with PspA5 (Fig. 6E). Additionally,the group immunized with PspA5 i.n. displayed the lowest levelof secretion of the proinflammatory cytokine TNF- ${alpha}$ by lung cells13 h after pneumococcal challenge (Fig. 6F), indicating a controlledinflammatory response.

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FIG. 6. Cellular immune response in lung (A, C, E, and F) and spleen (B and D) induced by immunization with PspA5 antigen after i.n. challenge with strain ATCC 6303. Spleen and lung cells were isolated from immunized mice 13 h after i.n. challenge and incubated with PspA5 in ELISPOT plates previously coated with anti-IFN- ${gamma}$ . SFCs of IFN- ${gamma}$ were detected through ELISPOT assay, and the average number of spots in duplicate wells was calculated by subtracting nonstimulated wells and considered as the number of SFCs/10⁶ cultured cells (A and B). Cells were also incubated with PspA5, and IL-17 (C and D), IL-5 (E), and TNF- ${alpha}$ (F) secretion in the supernatants was detected through sandwich ELISA. Results are representative of two independent experiments. L.c., L. casei; Non, nonimmunized group.

Evaluation of protection conferred by PspC and PspA vaccines against invasive i.n. challenge. Mice immunized with the different PspC- and PspA-based vaccineswere challenged 21 days after the last immunization with strainATCC 6303 through the i.n. route and were sacrificed 13 h laterfor determinations of CFU in lungs or were monitored during10 days for observation of survival. No significant changesin CFU counts in the lungs were observed among all the groups13 h after challenge (data not shown). By analyzing PspC-basedvaccines, we observed that despite the cellular immune responseselicited, no significant survival was observed in mice immunizedwith any formulation or by any administration route (Table 1).Sequence comparison of the N-terminal region of the PspC moleculeused in our vaccines and ATCC 6303 PspC showed 47% amino acidconservation (identical plus conserved residues). Vaccines composedof PspC molecules with higher degrees of conservation remainto be tested in this model. On the other hand, as shown in Table2, i.n. PspA5 and L. casei PspA5 immunizations were able toconfer significant protection against this invasive pneumococcalchallenge compared with nonimmunized mice (60% for mice immunizedwith PspA5 i.n. and 40% for mice immunized with L. casei PspA5i.n.) (P = 0.002 and P = 0.02, respectively, by Fisher's exacttest). Through this type of analysis, s.c. administration ofPspA5 was not able to confer protection against this challengemodel. Kaplan-Meier analysis confirmed significant protectionin mean survival times for animals i.n. immunized with PspA5(P = 0.0006) and L. casei PspA5 (P = 0.005) compared with nonimmunizedmice. An increase in mean survival time was also observed inanimals s.c. immunized with PspA5 (P = 0.04) (Fig. 7). The L.casei control group did not elicit significant protection inthis pneumococcal challenge model neither in total survivalrate (P = 0.21) nor in mean survival time analysis (P = 0.15).

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TABLE 1. Survival of mice after i.n. challenge with S. pneumoniae ATCC 6303

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TABLE 2. Survival of mice after i.n. challenge with S. pneumoniae ATCC 6303

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FIG. 7. Mean survival time of mice after i.n. challenge. Immunized mice were challenged with 10⁵ CFU of pneumococcal strain ATCC 6303 through the i.n. route, and survival was monitored for 10 days. Results were evaluated by Kaplan-Meier survival curve analysis. A P value of $≤$ 0.05 was considered to be significantly different (*). L.c., L. casei.

Histological analysis of lung tissue 13 h after challenge revealedan increase in cell infiltration in mice immunized i.n. withPspA5, L. casei, or L. casei PspA5 compared with nonimmunizedmice or mice immunized s.c. with PspA5. However, no inflammatoryinjuries were observed in any group at this point (see Fig.S1 in the supplemental material).

DISCUSSION

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DISCUSSION

The precise mechanisms of the resolution of S. pneumoniae lunginfection conferred by effective mucosal vaccines have not yetbeen elucidated. In the present study, we used two of the mostpromising pneumococcal vaccine candidates, PspC and PspA, throughdifferent routes of immunization (mucosal and parenteral) andalso used the lactic acid bacterium L. casei as a delivery systemof these antigens in order to evaluate the induction of pulmonaryand systemic immune responses and their protective potentialagainst an invasive challenge with S. pneumoniae in mice.

The investigation of PspC-based vaccines revealed that the groupvaccinated with L. casei expressing this antigen was the onlygroup that presented a significant enhancement in the infiltrationof neutrophils in BALF compared with the control group inoculatedwith L. casei. As for the humoral response, antibodies againstPspC were observed only in sera from mice s.c. immunized withthe recombinant protein. The better efficacy of the s.c. routeover the mucosal route of immunization for the induction ofanti-PspC IgG in sera may be a consequence of differences inantigen capture and presentation as well as protein stabilityin each environment, favoring s.c. immunization. None of theformulations were able to elicit mucosal antibodies under theconditions tested. Immunization with recombinant PspC throughdifferent routes has been shown to induce specific antibodiesand to confer protection against different pneumococcal challengemodels (7, 12, 36). The absence of anti-PspC antibodies in miceimmunized with our PspC protein-based vaccines maybe explainedby the fact that we have removed residual lipopolysaccharidesresultant from E. coli purification and tested them in the absenceof adjuvants. It is also important that the experiments describedin the present work were performed using C57BL/6 mice, whereasprevious works used BALB/c mice. It is known that the susceptibilitiesof these two mouse strains to pneumococcal infection are differentand may also have contributed to the differences observed (19).

The cellular immune response was characterized by the secretionof IFN- ${gamma}$ and IL-17 by lung and/or spleen cells. Despite the detectionof antigen-specific cellular immune responses, protection wasnot observed in PspC-immunized mice. However, further studiesto analyze the protective capacity of vaccines composed of PspCmolecules displaying a higher degree of conservation with thePspC-expressed ATCC 6303 must be considered.

In our hands, PspA5 was shown to be more immunogenic than PspC.Antibodies elicited by all PspA5 formulations were able to bindto strain ATCC 6303. Even with lower levels of IgG induced byL. casei PspA5, serum obtained from this group showed superiorbinding compared with those of sera from other groups. Theseresults may be explained by the fact that the antigen expressedand delivered by L. casei may have a more appropriate folding,resulting in antibodies that recognize epitopes present in thePspA molecule attached to the pneumococcal surface.

Nasal PspA5 vaccines displayed higher levels of IgG2a than didthe s.c. vaccine, which was reflected in more balanced IgG1/IgG2aratios. Nevertheless, the L. casei PspA5 group was the onlygroup that displayed larger amounts of IgG2a than IgG1. Theseisotyping results are in accordance with previous work withlactic acid bacteria showing that L. lactis administration throughthe i.n. route induced a Th1-biased immune response with higherlevels of IgG2a production, while its administration thoughthe i.p. route led to the production of elevated amounts ofIgG1 (45). It has also been reported that lactobacilli may facilitatethe polarization of the naive immune system by skewing it awayfrom Th2 responses and toward Th1 immune responses (35).

When evaluating complement deposition, we observed that thegroups immunized i.n. with L. casei PspA5 and PspA5 presentedthe greatest ability in mediating complement deposition ontothe pneumococcal surface. Interestingly, complement depositionobserved with sera from L. casei PspA5-immunized mice was similarto that observed for sera from mice immunized i.n. with PspA5despite the smaller amounts of antibody elicited. These resultscan be explained by the fact that the lactobacillus vaccineelicited predominantly IgG2a, in contrast with the other groups.In a previous work by our group, we proposed that since anti-PspAIgG2a would be the isotype with the greatest capacity to mediatecomplement deposition onto the pneumococcal surface, large amountsof IgG1 (in this case elicited by s.c. immunizations) couldcompromise complement deposition by impairing the binding ofIgG2a antibodies (17). Arulanandam and colleagues have alsoshown that Th1 immune responses, as the one elicited by PspAusing IL-12 as an adjuvant through the i.n. route, led to theproduction of large amounts of IgG2a and IgA and correlatedthis increase with protection against lung infection. Blockingthese Igs with specific proteins significantly inhibited pneumococcaluptake by phagocytic cells (2).

i.n. immunization with PspA5 also induced specific sIgA antibodiesdetected in vaginal washes 2 weeks after the last immunizationand in BALF samples 13 h after challenge. This finding correlatedwith better protection in our model. The role of sIgA againstcolonization by S. pneumoniae in nasal mucosa is controversial.While some studies demonstrated that protection can occur inthe absence of B cells (30, 31), a crucial role for sIgA wasdemonstrated in a model using pIgR^–/– and IgA^–/–mice (49). Still, it is well known that sIgA exerts protectionby noninflammatory mechanisms such as the inhibition of bacterialadhesion or opsonization not mediated by complement (39). Sucha response may therefore contribute to the survival of mice.

The highly encapsulated strain ATCC 6303 (serotype 3) is extremelyvirulent to mice in the i.n. challenge used in this study. Invitro studies have shown that neither human nor rat polymorphonuclearcells are able to phagocytose this strain (8, 16). Even withthis high virulence, in this study, we showed a significantprotection of mice i.n. immunized with PspA5 (60%) or with L.casei PspA5 (40%) compared with nonimmunized animals. It isimportant that the pspA5 fragment used in this study was amplifiedfrom a Brazilian pneumococcal isolate (strain 122/02, serotype23F) (14) and not from the same strain used for the challenge.Using the s.c. route, protection was observed only by mean survivaltime analysis, showing that i.n. immunization was importantto elicit an adequate immune response required in this challengemodel.

Elevated levels of IFN- ${gamma}$ and low levels of IL-17 secretion bylung cells were observed after immunization with L. casei PspA5.The opposite (high levels of IL-17 and low levels of IFN- ${gamma}$ ) wasobserved for i.n. immunization with PspA5. The protective roleof IL-17 in a mouse model of pneumococcal colonization was verywell characterized by the works of Malley and collaborators.In those studies, the authors elegantly showed the role of IL-17-expressingCD4⁺ T cells in the protection conferred by a killed whole-cellvaccine. However, all the correlations determined to date arerelated to protection against the pneumococcal nasopharyngealcolonization model (27, 29, 52). IL-17 acts on the recruitmentof neutrophils to sites of infection and is also involved inpulmonary host defenses against various pathogens (4, 5, 41).Nevertheless, we have no knowledge of data on IL-17 expressionby lung cells in mouse models of pneumococcal infection. Inour model, increases in levels of IL-17 secretion and neutrophilinfiltration after challenge were observed for i.n. immunizationwith PspA5, correlating with the highest protection level. InL. casei PspA5-immunized mice, neutrophil infiltration was alsoobserved, but no IL-17 secretion was observed 13 h after challenge,suggesting different mechanisms for protection elicited by thetwo vaccines.

It was recently reported that i.n. IL-12 administration in naivemice led to IFN- ${gamma}$ production by NK cells and TNF- ${alpha}$ productionby macrophages in the lung, increasing neutrophil recruitment(50). Nonrecombinant lactobacilli are known to induce high levelsof IL-12 release, inhibiting Th2 cytokine responses (IL-4 andIL-5) (35). Although a Th1-biased immune response seems to bea key component of the host defense against invading pathogenssuch as pneumococcus, this polarized immune response has alsobeen implicated in inflammatory disorders (32, 33) and may causelung injury (48). Secretion of IFN- ${gamma}$ by lung cells and protectionagainst pneumonia were described previously (50, 54). On theother hand, in some cases, secretion of this cytokine seemsto be detrimental (44, 47). In a mouse model of pneumonia, ithas been shown that elevated levels IFN- ${gamma}$ secreted by NK cellspresent in lungs of scid mice are unfavorable for recoveringfrom infection (23). Accordingly, the high levels of IFN- ${gamma}$ releasedby lung cells observed in the L. casei PspA5-immunized groupmay be prejudicial, resulting in only 40% protection. Otheraspects of such polarized immune response are beneficial, suchas the large amounts of IgG2a, leading to enhancement in complementdeposition.

Previous studies reported that the release of TNF- ${alpha}$ early ininfection would be beneficial but that its levels have to becontrolled (22). Protection against lung injuries caused byS. pneumoniae infection after oral administration of nonrecombinantL. casei was related to a balanced induction of the proinflammatorycytokine TNF- ${alpha}$ and the anti-inflammatory IL-10, leading to arapid increase in the infiltration of neutrophils with subsequentcontrol of the inflammatory response in the lung of treatedanimals (42).

Although no histological signs of inflammatory injuries wereobserved 13 h after challenge, a possible deleterious effect,in advanced stages, of the intense release of TNF- ${alpha}$ observedin control groups as well as in groups i.n. immunized with L.casei PspA5 or s.c. immunized with PspA5 cannot be discarded.The group of mice i.n. immunized with PspA5 was the only groupwith low levels of TNF- ${alpha}$ release by lung cells 13 h after challenge,and this was exactly the group that presented the best protection.

Protection using lactic acid bacteria as an antigen deliverysystem was previously reported with L. lactis or L. casei cellsexpressing PspA against respiratory or i.p. challenge with differentpneumococcal strains (11, 18). However, those previous worksdid not clarify the mechanisms involved in protection againstS. pneumoniae. The present work is the first to aim at characterizingboth humoral and cellular immune responses induced locally (lung)and systemically (spleen) by the administration of a pneumococcalantigen through a lactic acid bacterium delivery system. Furthermore,quantitative and qualitative features of mucosal and s.c. immunizationshave been identified. Differences between the two routes ofadministration using two promising protein vaccine candidateswere evaluated. The bias toward the Th1 immune response obtainedby i.n. immunization with PspA5 is of particular interest sinceIFN- ${gamma}$ as well as IgG2a are critical in defense mechanisms againstpneumococci. A concern about the administration of antigensthrough the i.n. route is the need for a safe and good adjuvant(38). Different tests showed the difficulty in maintaining adjuvanticitywhile reducing toxic effects of an adjuvant molecule (15). Inthis work, we showed that PspA5 is highly immunogenic and isable to induce protective humoral and cellular immune responsesthrough i.n. administration without the use of adjuvant. Wethus propose that the protection against this invasive challengeis likely due to both complement deposition induced by specificanti-PspA5 IgG2a and elevated pulmonary immunity with secretionof proinflammatory cytokines. Nevertheless, control of TNF- ${alpha}$ cytokine release is important to increase protection.

ACKNOWLEDGMENTS

We are deeply grateful to Ana Paula Christ for help with theimplementation of BALF collection protocols and Vania Gomesde Mattaria for the animal facilities coordination.

This work was supported by CAPES, CNPq, FAPESP, FundaçãoButantan, and Millenium Institute-Gene Therapy Network (MCT-CNPq).

FOOTNOTES

* Corresponding author. Mailing address: Centro de Biotecnologia, Instituto Butantan, Av. Vital Brasil 1500, 05503-900 São Paulo, Brazil. Phone: 55-11-3726-7222, ext. 2244. Fax: 55-11-3726-1505. E-mail for M. L. S. Oliveira: mloliveira{at}butantan.gov.br. E-mail for E. N. Miyaji: enmiyaji{at}butantan.gov.br

Published ahead of print on 11 March 2009.

Supplemental material for this article may be found at http://cvi.asm.org/.

REFERENCES

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