Immunogenicity and Protective Efficacy of Prime-Boost Regimens with Recombinant {Delta}ureC hly+ Mycobacterium bovis BCG and Modified Vaccinia Virus Ankara Expressing M. tuberculosis Antigen 85A against Murine Tuberculosis

In the light of the recent emergence of multidrug-resistantand extensively drug-resistant strains of Mycobacterium tuberculosis,the epidemic of tuberculosis (TB) in populations coinfectedwith human immunodeficiency virus, and the failure of Mycobacteriumbovis bacillus Calmette-Guerin (BCG) to protect against disease,new vaccines against TB are urgently needed. Two promising newvaccine candidates are the recombinant ${Delta}$ ureC hly⁺ BCG (recBCG),which has been developed to replace the current BCG vaccinestrain, and modified vaccinia virus Ankara (MVA) expressingM. tuberculosis antigen 85A (MVA85A), which is a leading candidatevaccine designed to boost the protective efficacy of BCG. Inthe present study, we examined the effect of MVA85A boostingon the protection afforded at 12 weeks postchallenge by BCGand recBCG by using bacterial CFU as an efficacy readout. recBCG-immunizedmice were significantly better protected against aerosol challengewith M. tuberculosis than mice immunized with the parental strainof BCG. Intradermal boosting with MVA85A did not reduce thebacterial burden any further. In order to identify a markerfor the development of a protective immune response againstM. tuberculosis challenge, we analyzed splenocytes after primingor prime-boosting by using intracytoplasmic cytokine stainingand assays for cytokine secretion. Boosting with MVA85A, butnot priming with BCG or recBCG, greatly increased the antigen85A-specific T-cell response, suggesting that the mechanismof protection may differ from that against BCG or recBCG. Weshow that the numbers of systemic multifunctional cytokine-producingcells did not correlate with protection against aerosol challengein BALB/c mice. This emphasizes the need for new biomarkersfor the evaluation of TB vaccine efficacy.

INTRODUCTION

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INTRODUCTION

One-third of the world's population is latently infected withMycobacterium tuberculosis. This disease claims 2 million livesevery year, and 9 million new cases of active disease occurannually (25). The currently available tuberculosis (TB) vaccine,Mycobacterium bovis BCG, protects against childhood TB meningitisand miliary TB; however, its efficacy wanes with time and itaffords only variable protection against pulmonary disease (21).A more-effective TB vaccine is therefore a major global healthpriority.

Most current efforts to improve the level of protective immunityprovided by BCG are focused on regimens that incorporate primingwith BCG, recombinant BCG, or other attenuated mycobacteriafollowed by a heterologous booster immunization that aims toimprove the duration and efficacy of the response. Two promisingvaccine candidates are recombinant ${Delta}$ ureC hly⁺ BCG (recBCG), whichhas been developed to replace the current BCG vaccine strain,and the live vector modified vaccinia virus Ankara (MVA) expressingthe abundant and immunogenic M. tuberculosis antigen 85A (MVA85A)(13), which is a leading booster vaccine.

recBCG is a recombinant urease C-deficient BCG strain expressingthe membrane-perforating listeriolysin of Listeria monocytogenes.recBCG significantly improves protection against aerosol challengewith M. tuberculosis H37Rv and the Beijing family genotype overthe level provided by the parental BCG strain (7). It has beensuggested that listeriolysin promotes antigen translocationinto the cytoplasm, as well as apoptosis of infected macrophages,leading to efficient cross-priming and the induction of a strongerCD8 T-cell response (7).

MVA85A induces a strong specific cellular immune response inmice and cattle (14, 18, 22). In BALB/c mice, BCG followed byMVA85A, both given intranasally, induced significantly greaterprotection following an aerosol M. tuberculosis challenge thandid vaccination with BCG alone (6). Ongoing clinical trialsshow that MVA85A is safe and highly immunogenic in humans (13).

In the present study, we examined the effect of MVA85A boostingon the protection afforded by BCG and recBCG in two independentexperiments carried out in two separate laboratories. We alsoevaluated which characteristics of the immune response inducedby the priming or prime-boosting correlated with protection.

(Part of this work represents part of the Ph.D. thesis of ChristianeDesel [2].)

MATERIALS AND METHODS

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MATERIALS AND METHODS

Mycobacterial strains. The construction of recBCG has been described previously (9).BCG Pasteur 1173P2 (originally provided by B. Gicquel, InstitutPasteur, Paris, France) and recBCG were cultured in Dubos brothbase supplemented with Dubos albumin medium (Difco; BD Diagnostics,Heidelberg, Germany) at 37°C. Mid-logarithmic cultures werealiquoted and stored at –70°C until use. M. tuberculosis(H37Rv strain, obtained from J. K. Seydel, ForschungsinstitutBorstel, Germany) was grown in Middlebrook 7H9 broth supplementedwith BBL Middlebrook ADC enrichment (Difco; BD Diagnostics,Heidelberg, Germany). M. tuberculosis (Erdman strain) was providedby the Center for Biologics Evaluation and Research (CBER),U.S. FDA, Rockville, MD, and used directly from frozen stock.

Animals and immunizations. The experiments in Oxford were performed with 6- to 8-week-oldfemale BALB/c mice (Harlan Orlac, Blackthorn, United Kingdom),were approved by the animal use ethical committee of OxfordUniversity, and fully complied with the relevant Home Officeguidelines. BCG (1 x 10⁵ CFU) and recBCG (1 x 10⁶ CFU) wereadministered subcutaneously (s.c.) in the left hind footpadin a 30-µl volume.

In Berlin, female 6- to 8-week-old BALB/c mice were bred atthe Bundesinstitut für Risikobewertung (BfR), Berlin, Germany,and kept under specific-pathogen-free conditions in filter bonnetcages with food and water ad libitum. Animal experiments wereconducted with the approval of the Landesamt für Gesundheitund Soziales (LAGeSo, Berlin, Germany). BCG or recBCG was administereds.c. at the base of the tail at a dose of 1 x 10⁶ CFU in a 100-µlvolume.

In both Oxford and Berlin, the MVA85A booster immunization wasadministered intradermally (i.d.) 10 weeks after BCG or recBCGpriming (boosted mice are referred to hereafter as the MB andrecMB groups). Mice were anesthetized and immunized i.d. with25 µl in each ear totaling 50 µl containing 1 x10⁶ PFU of MVA85A per mouse. The construction, design, and preparationof MVA85A is described in reference 14.

M. tuberculosis aerosol challenge. Four weeks after the MVA85A booster immunization, mice werechallenged by aerosol. In Oxford the challenge was performedwith M. tuberculosis strain Erdman, using a modified Hendersonapparatus. In Berlin mice were challenged by aerosol with M.tuberculosis strain H37Rv using a Glas-Col inhalation exposuresystem (Schuett-Biotec; Goettingen, Germany). Deposition inthe lungs was measured 24 h after challenge and was $~$ 200 CFUper lung in both Oxford and Berlin.

Mice were sacrificed 12 weeks after M. tuberculosis challenge.Lungs were homogenized, and the bacterial load was determinedby plating 10-fold serial dilutions of tissue homogenates onMiddlebrook 7H11 agar plates (E & O Laboratories Ltd., Bonnybridge,United Kingdom) in Oxford or on Middlebrook 7H11 agar platessupplemented with BBL Middlebrook oleic acid-albumin-dextrose-catalaseenrichment (Difco; BD Diagnostics, Heidelberg, Germany), ampicillin,and cycloheximide in Berlin. Colonies were counted after 3 to4 weeks of incubation at 37°C.

Cell isolations and peptides. In Oxford, spleen cells were cultured in ${alpha}$ -minimal essentialmedium (Sigma-Aldrich, United Kingdom) supplemented with 10%heat-inactivated fetal bovine serum, L-glutamine, 2-mercapthoethanol,penicillin, and streptomycin. In Berlin, spleen cells were culturedin RPMI 1640 (Biochrom) supplemented with 10% heat-inactivatedfetal bovine serum, L-glutamine, 2-mercapthoethanol, penicillin,and streptomycin.

Cells were stimulated with purified protein derivative (PPD)at 20 µg/ml (SSI, Copenhagen, Denmark) or a pool of 6015-mer peptides overlapping by 10 amino acids and covering theentire sequence of antigen 85A. Each peptide was used at a finalconcentration of 8 µg/ml during the stimulation. In someexperiments, cells were stimulated with the CD4 (Ag85A_99-118aa[TFLTSELPGWLQANRHVKPT]) and CD8 (Ag85A_70-78aa [MPVGGQSSF] andAg85A_145-152aa [YAGAMSGL]) dominant peptide epitopes of antigen85A at 2 µg/ml in Oxford or at 10^–5 M in Berlin.Peptides were synthesized by Peptide Protein Research Ltd.,Fareham, United Kingdom, or by JPT Peptide Technologies, Berlin,Germany.

Flow cytometry. Cells harvested from the spleen were stimulated with PPD orpooled 85A peptides for 1 h at 37°C. GolgiPlug (BD Biosciences)was added according to the manufacturer's instructions, andcells were incubated for an additional 5 h before being stainedfor intracellular cytokines. Cells were washed and incubatedwith CD16/CD32 monoclonal antibodies to block Fc binding. Subsequently,the cells were stained for CD4, CD8, gamma interferon (IFN- ${gamma}$ ),interleukin-2 (IL-2), and tumor necrosis factor alpha (TNF- ${alpha}$ )(eBioscience) by using a BD Cytofix/Cytoperm kit according tothe manufacturer's instructions. Cells were fixed with phosphate-bufferedsaline-1% paraformaldehyde and run on a CyAN ADP analyzer (Dako,Ely, United Kingdom), and the results analyzed by using FlowJosoftware. The proportions of multiple-cytokine-producing cellswere calculated by using Spice 4.1.6, kindly provided by M.Roederer, Vaccine Research Centre, NIAD, NIH, United States.Cells of three individual mice were analyzed per group. Thecytokine frequencies and numbers presented are the values aftersubtraction of background of identically gated populations ofcells from the same sample incubated with medium only.

ELISPOT, cytometric bead array (CBA), and Bio-Plex assays. The enzyme-linked immunospot (ELISPOT) IFN- ${gamma}$ assay was carriedout in Oxford as previously described (6), using coating anddetecting antibodies from Mabtech Ab, Sweden. Spleen cells wereassayed following 18 to 20 h of stimulation with PPD, individual85A peptides, or peptide pool. Cells from three individual micewere tested in each group, and each condition was tested induplicate.

For the CBA assays (BD Biosciences), amounts of 2 x 10⁶ splenocyteswere stimulated in 200 µl for 18 h with 20 µg/mlPPD or 8 µg/ml pooled 85A peptides. The levels of cytokinesin the supernatant were measured by using mouse inflammationand Th1/Th2 CBA assays, following the manufacturer's instructions.Cells from three individual mice were tested for each group.Controls with cells cultured in medium alone were included,and the background cytokine production from these cultures subtracted.

The Bio-Plex bead-based assay (Bio-Rad, Munchen, Germany) wascarried out in Berlin. Amounts of 2 x 10⁶ splenocytes were stimulatedfor 18 h with 50 µg/ml PPD (SSI, Copenhagen, Denmark)or 10^–5 M pooled 85A peptides. Cytokines in the supernatantswere measured by using Bio-Plex mouse cytokine Th1/Th2 and IL-6assays according to the manufacturer's instructions. The experimentalgroups consisted of five mice; two pairs of spleens were pooled,and one was processed individually, resulting in three samplesof splenocytes per group of five mice for subsequent stimulation.Controls with cells cultured in medium alone were included,and the background cytokine production from these cultures subtracted.

Statistical analysis. Data were analyzed by using the nonparametric Mann-Whitney test.The experiments were performed once in Berlin and once in Oxford.

RESULTS

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RESULTS

recBCG improves protection compared to BCG. We used MVA85A to boost immunity in mice following BCG or recBCGs.c. priming. The boost was administered i.d. 10 weeks afterthe administration of BCG or recBCG (Fig. 1A). Aerosol challengewith either M. tuberculosis H37Rv (Berlin) (Fig. 1B) or Erdmann(Oxford) (Fig. 1C) was performed 4 weeks after the final immunization.Bacterial burdens in lungs and spleens were determined 12 weeksafter M. tuberculosis challenge. This time point was chosenbecause recBCG has been shown to increase protection duringthe late phase of the immune response (7). recBCG increasedprotection in the lungs by approximately 1 log compared to theprotection provided by parental BCG in both laboratories (Fig.1). A similar increase of 1 log in the protection provided byrecBCG over that from parental BCG was observed in the spleen(data not shown). MVA85A i.d. boosting did not increase protectionover that afforded by BCG or recBCG in the lung or spleen.

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FIG. 1. RecBCG increases protection over that provided by BCG. BALB/c mice were immunized with BCG or recBCG and, 10 weeks later, boosted with MVA85A (M in panel A and BM or recBM in panels B and C). Naïve mice (N) were used as challenge controls. Mice were challenged with M. tuberculosis by aerosol 4 weeks after the boost and sacrificed 12 weeks later, and lung CFU enumerated. (A) Timeline. (B) Aerosol challenge with 200 CFU M. tuberculosis H37Rv in Berlin. (C) Aerosol challenge with 200 CFU M. tuberculosis Erdman in Oxford. Results are expressed as individual CFU counts, with median values shown by horizontal rules. Asterisks indicate significance (*, P = 0.01 to 0.05; **, P = 0.001 to 0.01).

Multifunctional cytokine responses. We next studied immune responses to the BCG or recBCG prime-boostimmunizations 3 weeks after the boost and 1 week before theM. tuberculosis challenge. Because it has been demonstratedthat CD4⁺ cells simultaneously producing IFN- ${gamma}$ , IL-2, and TNF- ${alpha}$ may provide optimal effector function and protection againstLeishmania major, another intracellular pathogen, and possiblyagainst M. tuberculosis (1), we defined the proportions of multifunctionalcells in our immunized animals. Intracytoplasmic cytokine stainingwas performed in both laboratories with similar results, andthe data from Oxford are presented below.

Antigen 85A responses by CD4 T cells. We performed intracellular staining for cytokines IFN- ${gamma}$ , IL-2,and TNF- ${alpha}$ on splenocytes stimulated with a pool of peptides coveringthe whole of antigen 85A. MVA85A i.d. boosting induced the strongest85A-specific CD4 T-cell response after BCG priming (BM group)(Fig. 2A and B). Most cells producing all three cytokines (3+cells) were detected in the BM group, almost nine times morethan in the recBM-immunized mice (180,000 cells versus 20,000).BCG or recBCG alone induced very few splenic 85A-specific CD4T cells (<5,000).

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FIG. 2. Cytokine responses of splenic CD4 T cells to antigen 85A. Mice were primed with BCG or recBCG and boosted with MVA85A. Splenocytes were isolated 3 weeks after the boost and stimulated with pooled 85A peptides for 6 h. (A) The frequencies of IFN- ${gamma}$ -, IL-2-, and TNF- ${alpha}$ -producing cells were determined by flow cytometry of CD4-gated cells. Error bars show standard errors of the means of the results for three mice per group. (B) The frequency of cells expressing each of the seven possible combinations of the cytokines is shown. +, present; –, absent. (C) Pie charts indicate the proportions of 1+, 2+, and 3+ cells, producing IFN- ${gamma}$ , IL-2, and TNF- ${alpha}$ . *, P value of <0.05 compared to results with BCG or recBCG; Ag, antigen; IFNg, IFN- ${gamma}$ .

Figure 2C summarizes the proportions of 3+ cells and cells producingeither IFN- ${gamma}$ or TNF- ${alpha}$ (1+ cells) or both IFN- ${gamma}$ and TNF- ${alpha}$ (2+ cells)in the spleen. The BCG- and BM-immunized groups exhibited amuch higher proportion of 3+ cells than the recBCG or recBMgroup. Despite the presence of more 3+ CD4 cells, the BCG andBM groups were less well protected than the recBCG and recBMgroups. The administration of MVA85A in the recBCG regimen increasedthe proportion and absolute number of 3+ CD4 cells but did notimprove protection compared to that from recBCG. No consistentpattern of differences between the groups in the levels of cytokineproduction (median fluorescence indices) was observed (datanot shown).

Antigen 85A responses by CD8 T cells. MVA85A boosting of both parental and recBCG also induced CD8T-cell responses against antigen 85A (Fig. 3A and B). The majorityof the CD8 T cells in the recBM and BM mice were 2+ and 1+;only 0.025% of the CD8 T cells produced IL-2. Although the numbersof multifunctional CD8 T cells were approximately comparablein the BM and recBM groups ( $~$ 1,000 3+ and $~$ 12,000 2+ cells), theCFU in the lungs of these groups differed by 1 log after M.tuberculosis challenge. Furthermore, despite higher proportionsand absolute numbers of multifunctional CD8 T cells presentin the recBM mice than in the recBCG group, there was no differencein protection between these groups. Similarly, there were more85A-specific CD8 T cells in the BM group than in the BCG groupbut no difference between them in protection. The overall qualityof the 85A-specific CD8 T-cell response did not differ greatlybetween the groups (Fig. 3C), with the majority of the cellsbeing 2+ and 1+.

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FIG. 3. Cytokine responses of splenic CD8 T cells to antigen 85A. Splenocytes were isolated 3 weeks after the MVA85A boost and stimulated with pooled 85A peptides for 6 h for ICS. (A) The frequencies of IFN- ${gamma}$ -, IL-2-, and TNF- ${alpha}$ -producing cells were determined by flow cytometry on CD8-gated cells. (B) The frequency of cells expressing each of the seven possible combinations of the cytokines is shown. +, present; –, absent. (C) Pie charts indicate the proportions of 1+, 2+, and 3+ cells, producing IFN- ${gamma}$ , IL-2, and TNF- ${alpha}$ . (D) IFN- ${gamma}$ ELISPOT assay of splenocytes stimulated for 18 to 20 h with CD4 or CD8 individual peptides or 85A peptide pool. Cells from three individual mice were tested in each group, and each condition was tested in duplicate. Results are expressed as the means ± standard errors of the means of data for three mice per group. N indicates naïve mice. *, P value of <0.05 compared to results with BCG or recBCG; Ag, antigen; IFNg, IFN- ${gamma}$ .

The ability of MVA85A to induce functional CD8 and CD4 T-cellresponses was confirmed by ELISPOT assays using the CD8-dominantH-2L^d 85A_70-78aa peptide, the CD4 IE^d-restricted 85A_99-118aapeptide (3, 11), and a peptide pool covering the whole 85A antigen(Fig. 3D). The strongest response was directed against the dominantCD4 peptide, in agreement with previous studies of BALB/c mice(6, 17, 19). It is interesting to note that in the current experiments,in contrast to those reported previously (6), the antigen 85A-specificresponse differed very little in mice immunized with MVA85Aalone and the MB mice (data not shown). The reason for the differencebetween these results is unclear but could have significancefor the lack of enhanced efficacy with MVA85A boosting.

PPD-specific responses. Following PPD stimulation in vitro, no significant differencesin the magnitude and quality of the specific CD4 T-cell responseswere detected between the regimens (Fig. 4). Interestingly,the PPD-specific CD4 T-cell response was not significantly boostedby MVA85A, suggesting that although antigen 85A was abundantlyproduced early during mycobacterial infection (10, 12), neitherBCG nor recBCG primed appreciable numbers of antigen 85A-specificT cells in BALB/c mice. Minute numbers of CD8 T cells respondingto PPD were detected (data not shown). A similar lack of boostingof the PPD response was observed after the administration ofanother strongly immunogenic vaccine, antigen 85A-expressingadenovirus, known as Ad85A (5).

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FIG. 4. Cytokine responses to PPD. Splenocytes were isolated 3 weeks after the MVA85A boost and stimulated with PPD for 6 h. (A) The frequencies of IFN- ${gamma}$ -, IL-2-, and TNF- ${alpha}$ -producing cells were determined by flow cytometry on CD4-gated cells. (B) The frequency of cells expressing each of the seven possible combinations of the cytokines is shown. (C) Pie charts indicate the proportions of 1+, 2+, and 3+ cells, producing IFN- ${gamma}$ , IL-2, and TNF- ${alpha}$ . (D) IFN- ${gamma}$ ELISPOT assay of splenocytes stimulated for 18 to 20 h with PPD. Cells from three individual mice were tested in each group, and each condition was tested in duplicate. Results are expressed as the means ± standard errors of the means of data for three mice per group. N indicates naïve mice. IFNg, IFN- ${gamma}$ .

In a different experiment, we also assessed the immune responsesat a later time point, 12 weeks after the boost (data not shown).The number of antigen 85A-specific cells did not change substantiallyin the spleen, suggesting that an antigen-specific memory T-cellpopulation persisted for at least 3 months after the boost.

In summary, these results show that the magnitude of the responseto antigen 85A in the spleen, measured as either the numberof IFN- ${gamma}$ -secreting or multifunctional T cells, did not correlatewith protection against aerosol challenge with M. tuberculosisin BALB/c mice. Conversely, the response to PPD did not differbetween any of the regimens and yet the BCG- and recBCG-primedgroups showed significantly different levels of bacterial burdensin the lungs.

Cytokine secretion. The quality of responses elicited in the spleen was also assessedby measuring the actual secretion of cytokines by CBA or Bio-Plexassay after 18 h of restimulation with the antigen 85A peptidepool or PPD. Boosting with MVA85A of both parental and recBCGinduced more IFN- ${gamma}$ , TNF- ${alpha}$ , IL-2, IL-4, and IL-6 following antigen85A stimulation than the other regimens (Fig. 5 and 6B). Nosignificant differences in monocyte chemoattractant protein1, IL-10, IL-5, or IL-12 production were detected after antigen85A stimulation (data not shown).

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FIG. 5. Spleen cell antigen 85A-specific cytokine responses. Splenocytes were isolated 3 weeks after the boost and stimulated with pooled antigen 85A peptides for 18 h. IFN- ${gamma}$ , IL-2, TNF- ${alpha}$ , IL-4, and IL-6 production was determined by using a CBA assay in Oxford. All data are expressed in pg/ml. Controls with cells cultured in medium alone were included, and the background cytokine production from these cultures subtracted. Shown are the mean values for three mice per group, representative of two independent experiments. Results are expressed as the means ± standard errors of the means of data for three mice per group. N indicates naïve mice. *, P value of <0.05 compared to results with BCG or recBCG.

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FIG. 6. Spleen cell PPD-specific cytokine responses. Splenocytes were isolated 3 weeks after the boost and stimulated with PPD (A) or three antigen 85A peptides (Ag85A_99-118aa, Ag85A_70-78aa, and Ag85A_145-152aa) (B) for 18 h. IFN- ${gamma}$ , IL-2, TNF- ${alpha}$ , IL-4, and IL-6 production were determined by using a Bio-Plex bead-based assay in Berlin. Controls with cells cultured in medium alone were included, and the background cytokine production from these cultures subtracted. Experimental groups consisted of five mice; two pairs of spleens were pooled and one processed individually, resulting in three samples of splenocytes per group of five mice for subsequent stimulation. Results are expressed as the means ± standard errors of the means of data for three samples per group. N indicates naïve mice.

Stimulation with PPD induced higher cytokine production; however,there were no significant differences between the regimens inthe production of IFN- ${gamma}$ , IL-2, IL-4, IL-6, and TNF- ${alpha}$ (Fig. 6A).Low, not significantly different amounts of IL-5, IL-10, monocytechemoattractant protein 1, and IL-12 were also detected (datanot shown). It is striking that even though very few PPD-specificcells were detected by intracytoplasmic cytokine staining comparedto the numbers of cells specific for antigen 85A, the PPD-stimulatedcultures produced an impressive amount of cytokines. This mightbe due, in part, to the activation by PPD of other than CD4and CD8 T cells, for example, ${gamma}$ ${delta}$ or NK cells.

DISCUSSION

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DISCUSSION

Our data confirm that recBCG s.c. significantly increases protectioncompared to BCG 12 weeks after aerosol M. tuberculosis infectionin BALB/c mice, in accordance with the results of previous studiesin which the vaccines were administered intravenously (7). Boostingwith MVA85A i.d. did not increase protection in combinationwith either BCG or recBCG.

The reduction in bacterial CFU in the lung afforded by the parentalBCG was lower than expected in the Oxford experiment (0.7-logreduction versus results for naïve mice, compared to theusual 1.2- to 1.5-log reduction consistently observed in Oxfordand seen in the Berlin experiment) (Fig. 1B). This may be because,although it was intended to administer 1 x 10⁶ CFU BCG, subsequentanalysis of the administered BCG suspension showed that only1 x 10⁵ CFU BCG had been given. Although previous studies haveshown that the dose and route of application of BCG have a minorimpact on vaccine-induced protection (8, 15, 16), it is stillpossible that the reduced dose did have an effect. However,irrespective of the level of protection afforded by the parentalor recBCG, boosting with MVA85A i.d. in both laboratories didnot increase BCG- or recBCG-induced protection in the lungsor spleen.

Recently, multifunctional cells have been proposed as a putativecorrelate of protection against Leishmania major (1). In thesame study, multifunctional PPD-specific cells were detectedin BCG-vaccinated mice and humans. However, there was no directevidence that these are important for protection against M.tuberculosis, as no M. tuberculosis challenge was performed.In our experiments, MVA85A boosting induced strong splenic CD4and, also, weak CD8 T-cell responses against antigen 85A asmeasured by specific multifunctional cytokine responses (BMand recBM groups). However, this did not parallel increasedprotection compared to that in the BCG and recBCG groups. Incontrast, although there were no differences in the responsesto antigen 85A or PPD between the animals immunized with BCGor recBCG only, there was more than 1 log of difference in protectionbetween these two groups. Thus, neither the frequency of PPD-or antigen 85A-specific cells in the spleen nor the presenceof multifunctional cells specific for these antigens correlatedwith protection in either primed or prime-boosted animals.

A similar lack of correlation with systemic IFN- ${gamma}$ responses hasbeen shown following intravenous boosting with MVA85A in a mouselong-term survival experiment (18) or after oral and systemicvaccination with BCG (15). Recent data from BCG-vaccinated cattlealso showed that the systemic IFN- ${gamma}$ response did not correlatewith protection (23). Increased protection over that conferredby BCG can be achieved by regimens inducing a strong lung immuneresponse. Intranasal immunization with adenovirus-expressingantigen 85A induces a large lung-resident population and significantlyincreases protection over that from BCG (19, 20). Similarly,intranasal administration of MVA85A increased protection (6)and this correlated with the induction of a large pulmonaryCD4 T-cell response. Therefore, the route of administrationof the booster vaccine appears to be important in obtainingincreased protection over that from BCG or recBCG in mice. Incontrast, in monkeys challenged intratracheally with M. tuberculosisand in cows challenged intratracheally with Mycobacterium bovis,i.d. boosting with MVA85A showed improved protection (F. Verreck,A. Hill, and H. McShane, unpublished data; M. Vordermeier, L.G. Hewinson, A. Hill, H. McShane, S. Gilbert, and B. Villerreal,personal communication), suggesting a possible difference betweenspecies in the importance of the route of MVA administration.The immunogenicity of i.d. MVA85A boosting, as judged by ELISPOTassays, appears substantially greater in cattle (22), humans(13), and macaques (F. Verreck et al., unpublished data) thanin mice (6; this report).

In addition, a rapid accumulation of IFN- ${gamma}$ -secreting CD8 T cellsin the lungs after M. tuberculosis challenge has previouslybeen shown to correlate with BCG-induced protection (15). Wedo not know whether recBCG induces a similar or larger earlyinflux of CD8 T cells, as we did not study early postchallengeevents in these animals. However, we did not detect any differencesbetween the lung immune responses in the groups before M. tuberculosischallenge (data not shown). In fact, there were very few antigen-specificT cells in the lungs of either primed or prime-boosted animals.Thus, the mechanism of enhanced protection conferred by recBCG,as well as the mechanism of protection conferred by BCG itself,remains to be determined. While recBCG priming only slightlyincreased the response to M. tuberculosis antigens measuredin vitro, the MVA85A boosting substantially increased the antigen-specificT-cell response, suggesting that its mechanism of protectionmay differ from that of BCG or recBCG.

The lack of increased protection following boosting with MVA85Amay relate to the interval between the BCG prime and the MVAboost or, alternatively, the time between the boost and challengewith M. tuberculosis. In our schedule, both the boost and thechallenge are probably during the ongoing immune response toBCG (6) or MVA85A when effector or effector memory cells maybe present, while in contrast, there is some evidence that centralmemory cells are important for protection (24). This needs furtherexploration.

In summary, in this collaborative study we have demonstratedthat recBCG increases protection over that provided by parentalBCG, with very similar results obtained in two independent laboratories.Although CD4 T cells and IFN- ${gamma}$ are important components of protectionagainst M. tuberculosis (4), our data suggest that the measurementof systemic short-term in vitro-stimulated IFN- ${gamma}$ or multifunctionalcytokine-producing T cells does not correlate with protectionagainst aerosol challenge in BALB/c mice. A better understandingof the mechanisms underlying protection against TB will facilitatethe rational design of biomarkers which can serve as surrogatesof protection in clinical TB vaccine trials.

ACKNOWLEDGMENTS

This work was funded by the European FP6 integrated projectTBVAC to Stefan H. E. Kaufmann and to Adrian V. S. Hill. H.M.and A.V.S.H. are both Jenner Investigators and funded by theWellcome Trust. H.M. is a Wellcome Trust senior clinical researchfellow, and A.V.S.H. is a Wellcome Trust principal researchfellow. C.S. was funded by the European Union FP5 frameworkprogram project AFTBVAC.

FOOTNOTES

* Corresponding author. Mailing address for Elma Z. Tchilian (for experiments performed in Oxford): The Peter Medawar Building for Pathogen Research, South Parks Road, Oxford OX1 3SY, United Kingdom. Phone: 44-1865-271247. Fax: 44-1865-281531. E-mail: elma.tchilian{at}ndm.ox.ac.uk. Mailing address for Stefan H. E. Kaufmann (for experiments performed in Berlin): Max Planck Institute for Infection Biology, Department of Immunology, Charitéplatz 1, 10117 Berlin, Germany. Phone: 49/30-28460-500. Fax: 49/30-28460-501. E-mail: kaufmann{at}mpiib-berlin.mpg.de

Published ahead of print on 8 December 2008.

Editor: J. L. Flynn

E. Z. Tchilian and C. Desel are joint first authors.

H. McShane and S. H. E. Kaufmann are joint senior authors.

REFERENCES

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