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Cells Expressed during Pulmonary InfectionDiscover Antigens Targeted by Human T
Gene Expression Approach TotuberculosisMycobacteriumAn Unbiased Genome-Wide
Geluk and Tom H. M. OttenhoffSchoolnik, Fredrik Oftung, Gro Ellen Korsvold, AnnemiekeFranken, Gregory Dolganov, Igor Kramnik, Gary K. van den Eeden, Annemieke H. Friggen, Kees L. M. C.Prins, Alexander V. Pichugin, Karin Dijkman, Susan J. F. Susanna Commandeur, Krista E. van Meijgaarden, Corine
http://www.jimmunol.org/content/190/4/1659doi: 10.4049/jimmunol.1201593January 2013;
2013; 190:1659-1671; Prepublished online 14J Immunol
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Referenceshttp://www.jimmunol.org/content/190/4/1659.full#ref-list-1
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The Journal of Immunology
An Unbiased Genome-Wide Mycobacterium tuberculosis GeneExpression Approach To Discover Antigens Targeted byHuman T Cells Expressed during Pulmonary Infection
Susanna Commandeur,* Krista E. van Meijgaarden,* Corine Prins,*
Alexander V. Pichugin,†,1 Karin Dijkman,* Susan J. F. van den Eeden,*
Annemieke H. Friggen,* Kees L. M. C. Franken,* Gregory Dolganov,‡ Igor Kramnik,†,2
Gary K. Schoolnik,‡ Fredrik Oftung,x Gro Ellen Korsvold,x Annemieke Geluk,*
and Tom H. M. Ottenhoff*
Mycobacterium tuberculosis is responsible for almost 2 million deaths annually.Mycobacterium bovis bacillus Calmette-Guerin, the
only vaccine available against tuberculosis (TB), induces highly variable protection against TB, and better TB vaccines are
urgently needed. A prerequisite for candidate vaccine Ags is that they are immunogenic and expressed by M. tuberculosis during
infection of the primary target organ, that is, the lungs of susceptible individuals. In search of new TB vaccine candidate Ags, we
have used a genome-wide, unbiased Ag discovery approach to investigate the in vivo expression of 2170 M. tuberculosis genes
duringM. tuberculosis infection in the lungs of mice. Four genetically related but distinct mouse strains were studied, representing
a spectrum of TB susceptibility controlled by the supersusceptibility to TB 1 locus. We used stringent selection approaches to
select in vivo–expressedM. tuberculosis (IVE-TB) genes and analyzed their expression patterns in distinct disease phenotypes such
as necrosis and granuloma formation. To study the vaccine potential of these proteins, we analyzed their immunogenicity. Several
M. tuberculosis proteins were recognized by immune cells from tuberculin skin test-positive, ESAT6/CFP10-responsive individ-
uals, indicating that these Ags are presented during natural M. tuberculosis infection. Furthermore, TB patients also showed
responses toward IVE-TB Ags, albeit lower than tuberculin skin test-positive, ESAT6/CFP10-responsive individuals. Finally, IVE-
TB Ags induced strong IFN-g+/TNF-a+ CD8+ and TNF-a+/IL-2+ CD154+/CD4+ T cell responses in PBMC from long-term latently
M. tuberculosis–infected individuals. In conclusion, these IVE-TB Ags are expressed during pulmonary infection in vivo, are
immunogenic, induce strong T cell responses in long-term latently M. tuberculosis–infected individuals, and may therefore
represent attractive Ags for new TB vaccines. The Journal of Immunology, 2013, 190: 1659–1671.
Tuberculosis (TB) remains a leading cause of death, par-ticularly in low and middle income countries (1). One thirdof the world population is estimated to be latently infected
with Mycobacterium tuberculosis, and 3–10% of these will developactive TB during their lifetime. In HIV-infected individuals thisproportion increases to 7–10% per life year. The emergence ofmultidrug-resistant, extensively drug-resistant, and more recentlyalso totally drug-resistant M. tuberculosis strains is further ag-gravating the TB epidemic. Currently, Mycobacterium bovis ba-cillus Calmette-Guerin (BCG) is the only available vaccine against
TB. Although BCG vaccination can prevent severe childhood TB(2), it induces highly variable and inconsistent protection againstpulmonary TB, the contagious form of TB in adults (3). A morerecently identified drawback of live BCG vaccination is the oc-currence of disseminating BCG infections in HIV-infected chil-dren (4), similar to severe BCG infections in individuals withgenetic defects in the IL-12/IL-23/IFN-g axis (5, 6). Thus, new TBvaccines are needed that are more effective and safer than BCG.Understanding the intracellular behavior of M. tuberculosis
during in vivo infection is important not only for understanding its
*Department of Infectious Diseases, Leiden University Medical Center, 2300 RCLeiden, The Netherlands; †Department of Immunology and Infectious Diseases,Harvard School of Public Health, Boston, MA 02115; ‡Department of Microbiologyand Immunology, Stanford University School of Medicine, Stanford, CA 94305; andxDivision of Infectious Disease Control, Department of Bacteriology and Immunol-ogy, Norwegian Institute of Public Health, NO-0403 Oslo, Norway
1Current address: Malaria Vaccine Branch, Military Malaria Vaccine Program, WalterReed Army Institute of Research, Silver Spring, MD.
2Current address: National Emerging Infectious Diseases Laboratories Institute, Bos-ton University School of Medicine, Boston, MA.
Received for publication June 14, 2012. Accepted for publication December 10,2012.
This work was supported by European Commission Projects FP7 NEWTBVAC andFP7 VACTRAIN (the text represents the authors’ views and does not necessarilyrepresent a position of the Commission, which will not be liable for the use made ofsuch information), Top Institute Pharma Project D-101-1, and European and Devel-oping Countries Clinical Trials Partnership Project AE-TBC. The funding agencieshad no role in study design, data collection and analysis, decision to publish, orpreparation of the manuscript.
Address correspondence and reprint requests to Prof. Tom H. M. Ottenhoff, Depart-ment of Infectious Diseases, Leiden University Medical Center, Building 1, C5-43,Albinusdreef 2, P.O. Box 9600, 2300 RC Leiden, The Netherlands. E-mail address:[email protected]
The online version of this article contains supplemental material.
Abbreviations used in this article: B6, C57BL/6J; BCG, Mycobacterium bovis bacil-lus Calmette-Guerin; C3H, C3HeB/FeJ; E/C, ESAT6/CFP10 hybrid; EHR, enduringhypoxic response; HC, healthy control (donor not exposed to Mycobacterium tuber-culosis); iMFI, integrated median fluorescence intensity; INH, isoniazid; Ipr1, intra-cellular pathogen resistance 1; IVE-TB, in vivo–expressed Mycobacteriumtuberculosis; LTBI, latent tuberculosis infection; ltLTBI, long-term latent tuberculo-sis infection; QFT-GIT, QuantiFERON-TB Gold In-Tube test; RGCN, relative genecopy number; RT, reverse transcriptase; sst1, supersusceptibility to tuberculosis 1;TB, tuberculosis; TST, tuberculin skin test; WBA, whole blood assay.
Copyright� 2013 by TheAmerican Association of Immunologists, Inc. 0022-1767/13/$16.00
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infection biology, but it is also essential for the identification ofpossible novel TB vaccine candidate Ags. Infection stage and site-related differences in in vivo M. tuberculosis gene expressionpatterns can clearly affect the repertoire of potential M. tubercu-losis Ags that is available for immune recognition in the primaryinfected organ, the lung. Ags expressed in the lungs of M. tu-berculosis–infected, susceptible individuals could represent in-teresting new candidate Ags for TB vaccination, because theywould induce responses capable of recognizing in situ M. tuber-culosis–infected cells.M. tuberculosis has a remarkable ability to adapt to environ-
mental changes by altering its metabolic state. A major environ-mental stress factor that M. tuberculosis is thought to encounterduring host infection is the deprivation of oxygen and nutrients.In vitro hypoxia induces the expression of the M. tuberculosisdormancy regulon (7), which is controlled by the master regulatorDosR (Rv3133c). The expression of the M. tuberculosis DosRregulon is also induced by low-dose NO, carbon monoxide ex-posure, and during infection in IFN-g–activated macrophages (7,8). Previously, we have reported broad human T cell responses toM. tuberculosis DosR regulon–encoded Ags and showed that re-sponses to these Ags were prominent and associated with latentTB infection (LTBI) in ethnically and geographically distinct po-pulations (9–13). Other work has shown that nutrient limitationcan induce the expression of specific M. tuberculosis genes suchas Rv2660c (14). This gene was found to encode a “starvation” Agwith promising long-term vaccine efficacy in preclinical TB in-fection models, both in mice (15) and in nonhuman primates (16).The more recently described enduring hypoxic response (EHR)genes represent an alternative hypoxia-induced response model,which includes most of the DosR regulon–encoded genes com-plemented with an additional number (.200) of M. tuberculosisstress response genes (17). This model has also helped to identifynew M. tuberculosis Ags (18).A limitation of the models discussed above is that the identi-
fication of differentially regulated M. tuberculosis genes relies onin vitro models supposed to recapitulate relevant environmentalstress conditions that M. tuberculosis encounters upon host in-fection. First, however, many of these environmental stress factorsmay not be known as yet, limiting the value of such hypothesis-driven studies. Second, there may be additive or synergistic effectsbetween multiple stress factors in vivo that may easily be missedwhen studied in isolation in vitro. Third, and perhaps more im-portantly, certain key features of host response–induced stresscannot readily be recapitulated in vitro, including granuloma for-mation and TB necrosis, both being cardinal features of TB. Toovercome these limitations several laboratories have started toanalyze the gene expression profiles of intracellular M. tubercu-losis, either in infected human or murine macrophages (8, 19), inthe infected tissue of different mouse strains (BALB/c, SCID)(20), or in artificial granuloma mouse models (21). However, noneof these mouse models developed granulomatous necrotic TBlesions (22). We therefore have studied M. tuberculosis genome-wide gene expression patterns in mice strains carrying differentgenotypes of the supersusceptibility to TB 1 (sst1) locus. Thisgenetic locus is located on chromosome 1 and controls the pro-gression ofM. tuberculosis infection to severe and necrotic lesionsin a lung-specific manner: C3HeB/FeJ (C3H) mice carrying thesusceptible sst1 allele develop TB pneumonia with strong in-flammatory responses with exudation throughout the lung andearly onset of massive necrosis, whereas C57BL/6J (B6) micecarrying the resistant sst1 allele develop smaller, interstitialgranulomas without necrotic lesions that control bacterial multi-plication. C3H.B6-sst1 congenic mice carrying the (B6-derived)
resistant sst1 locus on the C3H background showed increasedsurvival after M. tuberculosis infection compared with the sus-ceptible C3H mice, but less prominently than did the resistant B6mice. Finally, M. tuberculosis–infected B6.C3H-sst1 mice, car-rying the susceptible C3H-sst1 locus on the B6 background, de-velop robust granulomas that are fenced from the healthy tissuewhere lesions contain foamy macrophages and develop late-onsetnecrosis, resembling pulmonary TB in human adults. In contrast,the B6 strain does not display this phenotype, confirming thespecific role for sst1 in the control of cell death (23).The sst1 locus carries 22 genes, 1 of which was highly ex-
pressed in M. tuberculosis–infected lungs of C3H.B6-sst1 but notof hypersusceptible C3H mice. Interestingly, the expression of thisgene, termed intracellular pathogen resistance 1 (Ipr1), decreasedM. tuberculosis multiplication in susceptible macrophages andinduced a switch from necrotic to apoptotic cell death (24). Thelack of Ipr1 expression in C3H-susceptible sst1 locus is thereforeresponsible for the development of lung-specific necrosis uponM. tuberculosis infection (25). The closest human homolog ofIpr1 is SP110b. The expression of both Ipr1 and SP110b is re-gulated by IFNs, indicating a role in immunity (26–28). Geneticassociation studies performed in West Africa identified threepolymorphisms in the SP110b gene that were associated withgenetic susceptibility to TB (29). However, a number of otherstudies performed in Ghana, Russia, South Africa, and Indonesiadid not replicate this finding (30–33). A SP110b homolog was alsoidentified in cattle, which correlated to susceptibility to Myco-bacterium avium ssp. paratuberculosis (34).These four (congenic) mouse models we have used in this study
show a spectrum of TB susceptibility that ranges from highlysusceptible (C3H) to resistant (B6) mice, with the developmentof necrotic lesions depending on the sst1 locus and the modifyinggenetic background in which the locus is expressed. This mousemodel replicates key features of human M. tuberculosis infection.In this study, we have taken advantage of this disease spectrumand 1) analyzed quantitative real-time expression patterns of allM. tuberculosis genes predicted to be the first gene in each operon,in the lungs of M. tuberculosis–infected mice, aiming to identifythe M. tuberculosis genes that are highly or differentially ex-pressed in the lung during in vivo infection (in vivo–expressedMycobacterium tuberculosis [IVE-TB] genes); 2) compared theseM. tuberculosis gene expression patterns between susceptible(B6.C3H-sst1 and C3H) and resistant (C3H.B6-sst1 and B6)mouse strains in an attempt to correlate expression patterns toinfection phenotype; and 3) selected a set of the most consistentlyexpressed M. tuberculosis genes, produced these as recombinantproteins, and analyzed their immunogenicity in tuberculin skintest (TST)+ healthy, TB-affected individuals as well as long-termLTBI (ltLTBI) as a first step toward their validation as new TBvaccine candidate Ags.
Materials and MethodsMouse strains
C3H and B6 mice were purchased from The Jackson Laboratory (BarHarbor, ME). Congenic C3H.B6-sst1 and B6.C3H-sst1 mouse strainscarrying the resistant and susceptible alleles of the sst1 locus, respectively,were generated as previously described (24, 35). Briefly, an ∼20-cMsegment of chromosome 1, containing the sst1 locus, was introgressed inthe opposite background strain via $10 backcrosses. Mice were bred andhoused under specific pathogen-free conditions at the Harvard MedicalSchool of Public Health.
Bacterial strains
M. tuberculosis suspensions were used as previously described (36). Inshort, M. tuberculosis (Erdman strain; Trudeau Institute, Saranac Lake,
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NY) cultures were grown to midlog phase in Middlebrook 7H9 medium(BD Biosciences, Franklin Lakes, NJ) (10% oleic acid/albumin/dextrose/catalase [OADC; Difco], 0.05% Tween 80 [Sigma-Aldrich], and 0.5%glycerol [Sigma-Aldrich]). Bacteria were washed and stored at 280˚C.Prior to infection, bacteria were thawed, sonicated, and diluted in PBSto 106 CFU/ml.
Infection of mice
Mice were infected by aerosol with 25–50 CFU M. tuberculosis usinga Madison chamber (College of Engineering shops at the University ofWisconsin, Madison, WI) with n = 2 per time point (24). B6 and C3H micewere sacrificed both 6 and 9 wk postinfection, whereas B6.C3H-sst1 andC3H.B6-sst1 mice were sacrificed 9 and 6 wk postinfection, respectively.For the reactivation model, B6 and B6.C3H-sst1 mice were infected i.v. viathe tail vein with 5 3 104 CFU M. tuberculosis per mouse as previouslydescribed (23). Twelve weeks after challenge the mice were given isoni-azid (INH) supplied via the drinking water (10 mg/100 ml) for 90 d. Micewere sacrificed 8 wk after INH treatment withdrawal.
Genome-wideM. tuberculosis transcription profiling via a two-step multiplex real-time RT-PCR
Quantification of M. tuberculosis mRNA gene expression was performedas previously described (15, 37, 38). The protocol is based on first-strandcDNA synthesis and controlled multiplex amplification of cDNAs, whichis followed by individual real-time PCR (TaqMan) quantification of am-plified cDNAs in a 384-well format using a LightCycler 480.
Total M. tuberculosis RNA was isolated from the infected mouse lungtissue by homogenization in TRIzol and bacillary disruption by beadbeating (MP Biomedicals, Solon, OH). Total RNA was isolated usingRNeasy columns (Qiagen, Valencia, CA). RNA was precipitated, cleanedwith two consecutive off-column RQ1 DNase digestions (Promega, Madi-son, WI), and resuspended in 50 ml RNase-free water (Applied Biosystems/Ambion, Austin, TX).
cDNA synthesis was performed using 50 ng total RNA, which wasseparated in reverse transcriptase (RT)+ and RT2 reactions to control forDNA contamination. Exo-resistant random primer (0.5 ml), 1 ml 10 mMdNTPs, and nuclease-free water was added and incubated for 3 min at70˚C in a thermal cycler. Subsequently, 4 ml 53 Maxima RT buffer, 0.5 mlRiboLock RNase inhibitor, 0.5 ml Maxima RT enzyme (replaced by waterfor RT2 control samples) (all Fermentas, Glen Burnie, MD), and nuclease-free water were added and incubated at 50˚C for 1 h, 95˚C for 2 min toinactivate, and then kept at 4˚C.
The generated cDNAs were further amplified via controlled multiplexpreamplification with a mix of 2179 M. tuberculosis gene-specific prim-ers (23.8 ml primer mix: ∼50 nM per amplification reaction), 2 ml cDNA,3 ml 103 Advantage 2 buffer (Clontech, Mountain View, CA), 0.6 ml 13Advantage 2 polymerase mix (Clontech, CA), and 0.6 ml 10 mM dNTPs(Fermentas) to a volume of 30 ml (ftp://smd-ftp.stanford.edu/tbdb/rtpcr/taqman_oligos.fa) (15). Sequences and design of PCR primer/probe setsare available at: http://genes.stanford.edu/technology.php and http://www.tbdb.org/rtpcrData.shtml. A comparative control of 100 pg (2 3 104 genecopy number) genomic H37Rv DNA was also included. As an additionalcontrol, 25 M. tuberculosis reference genes were used to control for var-iation across amplification mixes. The gene primer sets were designedusing Primer Express software (PerkinElmer, Foster City, CA) to cover atleast one gene of each predictedM. tuberculosis operon. Each reaction washeated at 95˚C for 5 min, followed by 15 cycles at 95˚C for 30 s, 60˚C for20 s, and 68˚C for 1 min. Previously we have validated conditions formultiplex PCR preamplification via linearity of amplification assay usingall the genes used in the assay. We also validated all individual TaqManassays from our collection for sensitivity and linearity before we startedusing them in gene expression profiling in this study.
Individual gene transcript quantification was carried out using TaqManprimer/probe sets (Biosearch Technologies). Quantitative real-time PCRmix contained 0.07 ml preamplified cDNA, 2 ml TaqMan primer/probemix, 5 ml 23 LightCycler 480 Probes Master Mix, and 2.93 ml ProbesMaster PCR-grade water (Roche) to a final volume of 10 ml. Reactionswere heated at 95˚C for 5 min, followed by 40 cycles at 95˚C for 30 s and60˚C for 20 s. A cool down step of 40˚C for 30 s was run for one cycle.Cycle threshold values were converted to relative gene copy numbers(RGCN) based on logarithmic transformation/linear regression equationsdevised from calibration curves. The data set is available at: http://www.tbdb.org/pubdata/tbdb/publications/Raw-Data-Harvard-Mice.xls.
Correction for some biological heterogeneity between the different miceand mouse strains such as differences in bacterial load was not possiblebecause these were inherent to the extensive differences in genetic TBsusceptibility.
IVE-TB gene selection procedure
First, genes were selected that were expressed in one data set (.1000RGCN) but not in the other data set (+/2), thus selecting M. tuberculosisgenes that are differentially expressed owing to genetic host susceptibilityand/or infection phenotype variations.
The second approach was to select genes that were highly expressed inboth data sets from two different mouse strains in the chosen comparison(+/+), selecting for M. tuberculosis genes that are expressed independentof the genetic makeup of the host. For this selection, the RGCN data wereranked from the highest to the lowest value and overlapping genes wereselected from the top 100 highest expressed genes of both data sets. Thisnumber of 100 genes was arbitrarily chosen to limit the number of can-didates to be analyzed further.
The third and last approach included genes that were expressed in dataset 2 (.1000 RGCN) but not in data set 1 (2/+), following the same ra-tionale as approach 1. Hence, approaches 1 and 3 included differentiallyexpressed genes. There was no number restriction limit (because fewergenes were identified compared with the second approach [+/+]) (Figs. 1, 2).
Recombinant proteins
Recombinant proteins were produced from the selected M. tuberculosisgenes as described previously (39). Briefly, M. tuberculosis genes wereamplified by PCR from genomic H37Rv DNA and cloned by Gatewaytechnology (Invitrogen, Carlsbad, CA) in a bacterial expression vectorcontaining a histidine tag at the N terminus. Vectors were overexpressed inEscherichia coli BL21 (DE3) and purified. Size and purity of recombinantproteins were analyzed by gel electrophoresis and Western blotting with ananti-His Ab (Invitrogen) and an anti–E. coli polyclonal Ab (gift of StatensSerum Institute, Copenhagen, Denmark). Rv2380c, Rv2435c, andRv2737c proteins were prepared as two or three recombinant proteinfragments owing to their large sizes (C, middle [M], and N termini). En-dotoxin contents were ,50 IU/ mg as tested using a Limulus amebocytelysate assay (Cambrex, East Rutherford, NJ). All recombinant proteinswere tested in lymphocyte stimulation assays to exclude Ag nonspecificT cell stimulation and cellular toxicity using PBMC of in vitro–purifiedprotein derivative of M. tuberculosis–negative healthy Dutch donors(Sanquin Blood Bank, Leiden, The Netherlands) (12, 40–42). Purifiedprotein derivative of M. tuberculosis was purchased from Statens SerumInstitute.
FIGURE 1. Overview of IVE-TB gene selection procedure. (A) The M.
tuberculosis RGCN profiles of each mouse model were independently
compared with each other. (B) Three gene selection procedures were used
to select genes for each comparison: genes that were expressed in data set
1 (.1000 RGCN) but not in data set 2 (+/2); genes highly expressed in
both data sets (top 100 highest expressed genes in both models and select
overlapping genes) (+/+); and genes not expressed in data set 1 but
expressed in data set 2 (.1000 RGCN) (2/+) (see also Materials and
Methods).
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M. tuberculosis lysate
M. tuberculosis H37Rv organisms were grown to a late log phase ina culture flask at 37˚C and collected in a V-bottom tube. The pellet waswashed twice with PBS and heat killed for 30 min at 80˚C. The cellsuspension was subsequently collected in a BioSpec tube containing 0.1-mm glass beads. The bacteria were disrupted using a MiniBeadBeater(BioSpec Products). Concentrations of lysates were measured using theBCA assay (Thermo Scientific Pierce).
Study subjects
One hundred thirty-three donors were selected that responded to M.tuberculosis–purified protein derivative by TST (weak positive, 5–11mm [n = 26]; positive, $12 mm [n = 90]; not determined [n = 17],ranging from 6 to 32 mm [average, 16 mm]) and that had documentedexposure to a TB index case (n = 63) and/or had traveled to high en-demic countries (n = 76). TST+ individuals entered a follow-up studyand at recruitment a QuantiFERON-TB Gold In-Tube test (QFT-GIT)was performed (Cellestis, Carnegie, VIC, Australia). The test wasconsidered positive when there were $0.3 IU/ml. Blood samples werecollected by venipuncture. M. tuberculosis–unexposed donors wereincluded as healthy control (HC) donors (n = 11). PBMC from TST+
donors and treated TB patients (n = 7) were used in lymphocyte stimu-lation assays. PBMC from ltLTBI (41, 42) (n = 6) were used for poly-chromatic flow cytometry assays. Informed consent was obtained prior tovenipuncture. The study protocols (P07.048 and P027/99) were approvedby the Institutional Review Board of the Leiden University Medical Centerand the Regional Committees for Medical and Health Research Ethics inNorway.
Whole blood assay
Blood was diluted 1:10 in AIM-V medium (Invitrogen, Breda, TheNetherlands), incubated in 48-wells plates (Nunc, Roskilde, Denmark), andcultured with or without recombinant protein (10 mg/ml), PHA (2 mg/ml),orM. tuberculosis lysate (5 mg/ml) at 37˚C, 5% CO2. After 6 d supernatantwas harvested and stored at 220˚C for use at a later stage.
Lymphocyte stimulation test
PBMC (1.5 3 105/well) were cultured in triplicate in 96-well round-bottom plates (Nunc) and incubated with or without protein (10 mg/ml) inIMDM (Life Technologies/Invitrogen) containing 10% pooled humanserum (Invitrogen) at 37˚C in 5% CO2. After 6 d, supernatants wereharvested, pooled, and stored at 220˚C for future use in IFN-g ELISAs.
IFN-g ELISAs
IFN-g concentrations in supernatants were measured with a standardELISA technique (U-CyTech, Utrecht, The Netherlands). ELISA sampleswere tested in duplicate and the assay was performed according to themanufacturer’s guidelines. Detection limit of the assay was set arbitrary at20 pg/ ml for whole blood assay (WBA) and 100 pg/ml for a lymphocytestimulation test.
Flow cytometric analysis
PBMC (1–2 3 106/tube) were thawed and rested overnight and subse-quently stimulated for 16 h with protein (10 mg/ml) in the presence ofcostimulatory Abs anti-CD28 and anti-CD49d (Sanquin and BD Bio-sciences, respectively). Brefeldin A (3 mg/ml; Sigma-Aldrich) was addedafter the first 4–6 h. Cells were stained with Live/Dead fixable violet deadcell stain (ViViD; Invitrogen) to discriminate between live and dead cellsaccording to manufacturer’s instructions. Cells were stained for 1 h at 4˚Cwith the following surface markers: anti-CD3 PE-Cy5 (BD Biosciences),anti-CD4 Texas Red (Caltag), and anti-CD8 V500 (BD Biosciences).Additionally, anti-CD14 Pacific Blue and anti-CD19 Pacific Blue (bothInvitrogen) were included to select for CD142 and CD192 live cells. In-tracellular staining was performed with anti–IFN-g Alexa 700 (BD Phar-mingen), anti–TNF-a PE-Cy7 (BD Biosciences), anti–IL-2 PE (BDPharmingen), and CD154 allophycocyanin-Alexa 780 (eBioscience) usingthe ADG Fix&Perm kit (An Der Grub Bio Research, Vienna, Austria).Data were acquired on a BD LSRFortessa (BD Biosciences) and analyzedusing FlowJo version 7.6.5 (Tree Star, Ashland, OR). Single CD142/CD192/CD3+ live cells were gated to analyze CD4+ and CD8+ cytokineresponses. Final Ag-specific CD4+ and CD8+ T cell subset populations allcontained at least 200 events. For comparative purposes, medium back-ground values were subtracted for each response in each donor.
Statistical analysis
Statistical analysis was performed using GraphPad Prism (version 5.1). AMann–Whitney U test was used to analyze 1) the difference between cu-mulative IFN-g responses for the ESAT6/CFP10 hybrid (E/C)+, E/C2, andHC individuals and 2) the difference between PHA-induced IFN-g re-sponses measured in E/C+ and E/C2 donors. A p value #0.05 was con-sidered significant.
ResultsIdentification of IVE-TB genes in the lungs of geneticallyresistant and/or susceptible mice
To start identifying novel candidate M. tuberculosis Ags in anunbiased and M. tuberculosis genome-wide fashion, we analyzedthe gene expression patterns of 2170 M. tuberculosis genes, mostof which represent the first gene of each predicted M. tuberculosisoperon, in the lungs of four different M. tuberculosis–infectedmouse strains (B6, C3H, C3H.B6-sst1, and B6.C3H-sst1) thatshow a spectrum of TB susceptibility (Table I). The RGCN weredetermined using quantitative PCR (15). This allows for absolutequantization of the level of transcripts per sample, because thedata are normalized against a standard reference gene numbercopy (as described in Materials and Methods).In this IVE-TB gene selection screen we used the following
criteria to select candidate genes for further analysis. First, we usedthe most strongly upregulated M. tuberculosis genes in all four an-alyzed mouse models. This group of genes includes genes that areexpressed independently of the host susceptibility background.Second, we used M. tuberculosis genes specifically upregulated ineither B6, C3H, B6.C3H-sst1, or C3H.B6-sst1. The expression ofthese genes is influenced by the host genetic background and maytherefore include genes whose expression is associated to partic-ular TB disease characteristics such as granuloma formation and
FIGURE 2. Selection of IVE-TB genes. Numbers of M. tuberculosis
genes obtained after each comparison of two different mouse strains for
every approach described in Fig. 1 are shown in (A)–(G).
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necrosis. The obtained RGCN of all four mouse models wereindependently compared with each other as visualized in Fig. 1A.All four mouse models were infected with a low-dose aerosol M.tuberculosis inoculum. Additionally, a subset of B6.C3H-sst1was infected using a previously described TB relapse model tostudy features of gene expression during M. tuberculosisreactivation (23).Every individual M. tuberculosis gene’s expression data (e.g.,
B6 versus C3H, B6 versus B6.C3H-sst1) was subjected to threedifferent selection approaches as indicated in Fig. 1B and de-scribed in detail in Materials and Methods. The gene selectionresults for each comparison are visualized in Fig. 2 and Supple-mental Table I. The results shown in Fig. 2 were then used toselect IVE-TB genes whose expression was associated with par-ticular disease characteristics as indicated in Fig. 3. These in-cluded 1) M. tuberculosis genes highly expressed independentlyof host genetic background (expressed in all four mouse models;these M. tuberculosis genes included esxA encoding ESAT6 andother esx genes); 2)M. tuberculosis genes expressed in associationwith necrosis (expressed in both C3H and B6.C3H-sst1, but not inB6 or C3H.B6-sst1); 3) M. tuberculosis genes expressed in asso-ciation with severe necrotic infection or susceptibility (expressedin C3H, but not in B6, C3H.B6-sst1, or B6.C3H-sst1); 4) M. tuber-culosis genes expressed in association with dense granuloma devel-opment (only expressed in B6.C3H-sst1 but not in C3H, B6, or C3H.B6-sst1); 5) M. tuberculosis genes expressed in association withdiffuse granuloma development (expressed in C3H but not in B6.C3H-sst1, B6, or C3H.B6-sst1); 6) M. tuberculosis genes expressedin association with resistance (expressed in every more resistantmouse strain per comparison); 7) M. tuberculosis genes expressedin association with low inflammation (expressed in B6, but not inC3H.B6-sst1); 8) inflammation (expressed in C3H.B6-sst1, but notin B6); and 9) relapse (expressed in i.v. M. tuberculosis–infected,INH-treated B6.C3H-sst1, but not low-dose aerosol–infected B6.C3H-sst1). An overview of the resulting IVE-TB genes is pre-sented in Supplemental Table II.
Immunogenicity of newly identified IVE-TB Ags
Further down selection of IVE-TB genes. The goal of the aboveselection of IVE-TB genes was to identify potentially interestingnew vaccine candidate Ags. Thus, we next determined their im-munogenicity. To this end, a number of M. tuberculosis genes werefurther selected that were either present in more than one group orwere among the top number of genes in the IVE-TB selectionsperformed (Table II). Some M. tuberculosis genes identifiedusing our unbiased genome-wide approach were also identifiedin previous studies as environmental stress induced proteins(7, 14, 17).A subsequent literature search revealed that almost all further
selected IVE-TB proteins (14 of the 16) have been identified pre-viously inM. tuberculosis proteomic studies, confirming the protein
expression of the M. tuberculosis genes identified in our study(44–57) (Table III). Indeed, we observed that M. tuberculosis–
Table I. Mouse strains, genetic background, and TB infection phenotypes
Mouse StrainaGenetic
Background Sst1 Allele Inflammation Lung Necrosis Clinical TB Correlate
C3H C3H Susceptible +++ + (Early) Caseous pneumoniaC3H.B6-sst1 C3H Resistant +++ 2 Progressive interstitial
granuloma without necrosisB6.C3H-sst1 B6 Susceptible ++ + (Late) Caseous granulomaB6 B6 Resistant + 2 Chronic persistent interstitial
granuloma without necrosis
+, ++, and +++ indicate intensity of inflammation.aPichugin et al. (23) and Pan et al. (24).
FIGURE 3. Selection of IVE-TB genes associated with particular TB
disease characteristics. Flowchart of analysis to identify IVE-TB genes re-
lated to TB disease phenotypes is shown. Letters in graphs refer to the spe-
cific selections indicated in Fig. 2. M. tuberculosis genes highly expressed
independent of host genetic background are presented in Fig. 2A (b), 2B (e),
2C (h), 2D (k), 2E (n), and 2F (q).M. tuberculosis genes highly expressed in
association with necrosis are presented in Fig. 2A (c), 2B (f), 2D (j), and/or
2F (p). M. tuberculosis genes highly expressed in association with severe
necrotic infection or susceptibility are presented in Fig. 2A (c), 2D (j), and/or
2C (i). M. tuberculosis genes highly expressed in association with dense
granuloma are presented in Fig. 2C (g), 2B (f), and/or 2F (p).M. tuberculosis
genes highly expressed in association with diffuse granuloma are presented
in Fig. 2C (i), but also Fig. 2A (c) and 2D (j). M. tuberculosis genes highly
expressed in association with resistance are presented in one or more of the
following selections: Fig. 2A (a), 2B (d), 2D (l), 2E (m) (although not related
to the susceptible sst1 locus), 2F (r) and/or 2G (s). M. tuberculosis genes
highly expressed in association with low inflammation are presented in Fig.
2E (m). M. tuberculosis genes highly expressed in association with inflam-
mation are presented in Fig. 2E (o). M. tuberculosis genes highly expressed
in association with relapse-associated genes presented in Fig. 2G (u).
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infected C3H mice recognized most of the selected IVE-TB Ags
as measured by Ag-specific IFN-g production by splenocytes
(Supplemental Fig. 1). Furthermore, we analyzed the conserva-
tion of these IVE-TB proteins using protein BLAST searches on
different M. tuberculosis strains as well as other mycobacterial
species. This showed that the IVE-TB protein sequences are
strongly conserved among all tested M. tuberculosis, M. bovis,
and Mycobacterium africanum strains. Strong conservation wasobserved also for other mycobacterial strains (Table IV).
Recognition of IVE-TB proteins by TST+ donors. To assess theimmunogenicity of the 16 selected IVE-TB proteins, recombinantproteins of the IVE-TB genes were generated and analyzed for theinduction of IFN-g responses in 133 TST+ individuals. Approxi-
mately one third of the TST+ individuals responded to M. tuber-
Table II. Predicted function and classification of selected IVE-TB genes
Gene Name IVE-TB Selectiona Selectionsa Functionb Categoryc Classification Reference
Rv1284 Rv1284 High expression b + e + h + k+ n + q + t
Conserved hypothetical protein(carbonic anhydrase)
7 EHR/starvation 14, 17, 43
Rv2380c mbtE High expression b + e + h + k+ n + q + t
Peptide synthetase mbtE 1 21
Rv3515c fadD19 High expressed sst1s h + q + t Probable fatty acid-CoA ligasefadD19 (involved in lipid
degradation)
1 EHR 17, 21
Rv0079 Rv0079 Necrosis and sni c + f + j + p Hypothetical protein 10 DosR 7, 9, 12, 20, 21Rv2324 Rv2324 sni and relapse c + j + u Probable transcriptional regulator,
asnC family9 EHR 17
Rv2737c recA Necrosis and sni c + f + j + p Recombination protein recombinaseA (recA; M. tuberculosis
recA intein)
2
Rv2838c rbfA sni, diffuse granuloma,and relapse
c + i + j + u Probable ribosome-binding factor A(P15B protein)
2
Rv3420c rimI sni, diffuse granuloma,and relapse
c + i + j + u Ribosomal-protein-alanineacetyltransferase rimI
2
Rv2034 Rv2034 Inflammation o arsR type repressor protein 9 EHR/starvation 14, 17, 20Rv1956 Rv1956 Resistance, diffuse
granuloma, lowinflammation, and relapse
d + i + j + m+ u
Transcriptional regulator (possibleantitoxin; TA operon with Rv1955)
0 EHR/starvation 14, 17, 21
Rv2225 panB Dense granuloma f + g + p Probable 3-methyl-2-oxobutanoatehydroxymethyltransferase (panB)
7 21
Rv2465c rpiB Dense granuloma f + g + p Isomerase (ribose 5-phosphateisomerase)
7 EHR 17, 20
Rv2982c gpsA Resistance, inflammation,and relapse
l + o + r + u Probable glycerol-3-phosphatedehydrogenase (gpdA2)
1
Rv3353c Rv3353c Relapse u Conserved hypothetical protein 10Rv1363c Rv1363c Resistance s Possible membrane protein 3Rv2435c Rv2435c Resistance and
inflammationl + o Probable cyclase (adenylate or
guanylate cyclase)7
aIn reference to Figs. 2 and 3.bAvailable at: http://genolist.pasteur.fr/TubercuList/ and www.tbdb.org.cTubercuList functional classification codes are available art: http://genolist.pasteur.fr/tuberculist.sni, Severe necrotic infection.
Table III. Identification of IVE-TB proteins in M. tuberculosis
GeneProteinName
ProteinIdentification
Protein Location
Essential In Vitro Essential In VivoMembrane/Lipid
Associated Cytosol CF WCL
Rv0079 Rv0079 49, 51, 52 X No (53) Yes (57)Rv1284 Rv1284 45–48, 51 X X X Yes (53) Yes (54)Rv1363c Rv1363c 45, 46 X X No (53)Rv1956 Rv1956 46 X No (53, 55)Rv2034 Rv2034 45, 46 X No (53)Rv2225 panB 46, 52 X X Yes (53)Rv2324 Rv2324 45, 46 X X No (53)Rv2380c mbtE 51, 52 X X Probably yes (55)Rv2435c Rv2435c No (53)Rv2465c rpiB 44–48 X X X No (53)Rv2737c recA 52 X Slow grow mutant (53)Rv2838c rbfA 46 X NTRv2982c gpsA 45, 46, 50, 51 X X No (53)Rv3353c Rv3353c No (53)Rv3420c rimI 52 X No (53)Rv3515c fadD19 46, 49, 50 X X No (53, 55); yes (56)
Note that the locations of the proteins indicated may not be exclusive given limitations and difficulties in annotating exact protein localization (46).CF, Culture filtrate; NT, not tested; WCL, whole cell lysate.
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culosis–specific E/C protein (32%, 61–9980 pg/ml). ESAT6 and
CFP10 M. tuberculosis–specific proteins are frequently used as
immunodiagnostic Ags to identify M. tuberculosis exposure (12).
One third of our population also responded to these diagnostic Ags
(ESAT6, CFP10 complemented with TB7.7 [p4] peptides) using
the commercial QFT-GIT. The responses in the QFT-GIT corre-
lated very well with responses to our E/C protein measured in
WBA (84%). Division of the group into WBA E/C+ and WBA
E/C2 donors showed that 74% of the E/C+ donors responded to
M. tuberculosis lysate (87–3112 pg/ml) and 40% to Ag85B Ag
(97–735 pg/ml) (Fig. 4A). Importantly, high levels of recognition
of the newly identified M. tuberculosis proteins were seen within
this population, with responses ranging from 10 to 60% of the
donors. To identify the Ags that are well recognized, we first ex-
amined which ones were recognized by $25% of the E/C+ donors.
From all 20 proteins and protein fragments (derived from the 16
selected Ags) tested, 13 were recognized by $25% (n $ 3 of 10
and $11 of 43) of the donors. Six of 13 Ags induced only inter-
mediate levels of IFN-g (60–600 pg/ml) after stimulation, whereas
high levels of IFN-g were produced after stimulation with
Rv1363c (102–1053 pg/ml), Rv1956 (100–1861 pg/ml), Rv2034
(77–1256 pg/ml), Rv2324 (63–2130 pg/ml), Rv2380c-C (80–1159
pg/ml), Rv3353c (70–899 pg/ml), and Rv3420c (88–660 pg/ml),
representing the seven best recognized proteins.Of the TST+ E/C2 donors still 47% responded to M. tubercu-
losis lysate and 20% to Ag85B (Fig. 4B). Additionally, HC were
analyzed for possible IVE-TB responses (Fig. 4C). Most impor-
tantly, limited responses to no responses against the IVE-TB
proteins were detected in the TST+ E/C2 and HC groups, dem-
onstrating clear specificity of recognition, presumably linked to
M. tuberculosis exposure.To further verify that the IVE-TBAgs are specifically recognized
by E/C+ donors, the cumulative IFN-g response to the 20 testedAgs per individual was calculated, as described before (9). A highlysignificant difference between the E/C+ and E/C2 population wasobserved (p , 0.0001). As expected, a significant difference wasalso observed between E/C+ and HC donors (p = 0.049) (Fig. 5),confirming the association between Ag recognition and E/C testpositivity. Interestingly, of the seven best recognized proteins,Rv3420c was the most discriminatory between the E/C+ ($25%)and E/C2 group (#1%) (p, 0.0001) and was not recognized by HCdonors (p = 0.016), suggesting a possible role as M. tuberculosis–specific biomarker Ag in addition to ESAT6, CFP10, and TB7.7.
Recognition of IVE-TB proteins by PBMC from TB patients. We
next investigated whether TB patients could also recognize theseAgs. PBMC from WBA E/C+ TST+ donors (Fig. 6A) and TBpatients (Fig. 6B) were therefore stimulated with the 20 proteinsand protein fragments and IFN-g production was measured. HighIFN-g responses (123–3391 pg/ml) to the IVE-TB Ags were ob-served in the PBMC cultures from the WBA E/C+ TST+ pop-ulation, confirming the results obtained in the WBA assay above.Nine of the tested Ags were recognized by $50% of the donorsand eight Ags by 38% of the donors. Only one protein fragmentwas not recognized in this assay (Rv2380c-M). In contrast, sevenof the tested IVE-TB Ags did not induce detectable IFN-g pro-duction in PBMC from TB patients, whereas most of the IVE-TBAgs induced only low levels of IFN-g compared with the WBA E/C+
TST+ individuals (107–1825 pg/ml). Only two Ags induced highlevels of IFN-g in the TB patients. Additionally, only one Ag wasrecognized by 50% of the TB patients, whereas the remainder of
the Ags were recognized by relatively fewer TB patients (14–
43%). Thus, IVE-TB Ags seem to be less immunogenic in TB
patients than in TST+ individuals.Table
IV.
IVE-TBprotein
sequence
identity
amongmycobacterial
strains
Mycobacterial
Species
Strain
Rv0079
Rv1284
Rv1363c
Rv1956
Rv2034
Rv2225
Rv2324
Rv2380c
Rv2435c
Rv2465c
Rv2737c
Rv2838c
Rv2982c
Rv3353c
Rv3420c
Rv3515c
tuberculosis
Erdmann
100
100
100
100
100
100
100
100
100
100
100
100
100
100
100
100
tuberculosis
H37Rv
100
100
100
100
100
100
100
100
100
100
100
100
100
100
100
100
tuberculosis
C100
100
100
100
99
100
100
100
100
100
99
100
99
100
100
94
tuberculosis
Haarlem
100
100
100
100
99
ND
100
100
100
100
100
100
99
100
100
99
tuberculosis
F11
100
100
100
100
99
100
100
100
100
100
100
100
99
100
100
100
tuberculosis
CDC1551
100
100
100
100
99
100
100
100
100
100
100
100
99
100
100
100
africanum
GM041182
100
100
100
100
100
100
100
100
99
100
99
100
99
100
100
99
bovis
AF2122/97
100
100
99
100
100
100
100
100
100
100
100
100
99
100
100
100
bovis
BCG
100
100
100
100
100
100
100
100
100
100
100
100
99
100
100
100
avium
Paratuberculosis
K-10
ND
80
74
ND
41
88
91
65
65
91
96
77
84
50
82
90
avium
104
ND
80
74
ND
41
87
89
65
65
91
96
77
40
51
82
90
ulcerans
Agy99
62
85
70
ND
39
86
83
43
60
90
96
81
86
65
82
90
smegmatis
Mc2
155
33
79
58
ND
39
78
81
66
59
84
93
76
75
ND
67
83
marinum
M63
85
72
ND
39
86
84
43
81
91
96
81
87
64
82
90
leprae
TN
ND
ND
ND
ND
ND
82
ND
ND
32
89
61
80
77
ND
72
ND
LocalBLASTprotein
sequence
identities
areavailable
at:http://www.tbdb.org
andhttp://www.ncbi.nlm
.nih.gov/blast/.ND,Notdetected.
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T cell responses toward IVE-TB Ags in long-term latent M.
tuberculosis–infected individuals. Because the IVE-TB Ags were
strongly recognized by TST+ individuals, we subsequently ana-lyzed the immune responses toward the seven best recognized Agsin more detail using PBMC from donors that had been exposed toM. tuberculosis decades ago, but had never developed TB despitethe lack of any preventive treatment, designated ltLTBI (41, 42). Ofadditional importance, the availability of several vials of PBMCalso allowed more detailed cell subset analysis.Interestingly, high frequencies of TNF-a– and IL-2–producing
CD4+ T cells were observed after stimulation with the IVE-TB Ags,whereas only intermediate frequencies of IFN-g–producing CD4+
T cells were detected (Fig. 7A). In contrast, high frequencies ofIFN-g–producing as well as TNF-a+ CD8+ T cells were present inthese donors, whereas fewer IL-2+ T cells were detected comparedwith CD4+ T cells. Besides IFN-g, TNF-a, and IL-2, also the Ag-induced CD4+ T cell activation marker CD154 (58) was expressed.More detailed analysis of the multifunctional Th1 responses
among CD4+ and CD8+ T cells showed that CD154+CD4+ T cells
were mostly TNF-a+/IL-2+ and TNF-a+ (Fig. 7B). Furthermore,
intermediate frequencies of IFN-g+/TNF-a+/IL-2+ CD154+CD4+
T cells were detected. Finally, a CD154+ population was detected,
producing none of the IFN-g, TNF-a, and IL-2 cytokines. In-
triguingly, the same pattern was observed for every IVE-TB Ag
or E/C control Ag. Furthermore, interindividual variation of Ag
recognition was observed. Remarkably, few TNF-a+/IL-2+ CD8+
T cells were detected compared with TNF-a+/IL-2+ CD4+ T cells.
IFN-g+/TNF-a+ CD8+ T cells were the most prominent population
present, followed by TNF-a+ CD8+ T cells. Also, intermediate
IFN-g+/TNF-a+/IL-2+ and IFN-g+ CD8+ T cells were observed.
Again, as mentioned for CD4+ T cells, the same patterns were
observed for every Ag within the CD8+ T cell population as well
as interindividual variation of Ag recognition.The integrated median fluorescence intensity (iMFI) was cal-
culated to determine the quantitative contribution of cytokines
produced by the different multiple and single cytokine producing
CD154+/CD4+ and CD8+ T cells (Fig. 8). IFN-g+/TNF-a+/IL-2+
CD154+/CD4+ T cells had the highest iMFI, which gradually
declined for double producing and single IFN-g+ CD154+/CD4+
T cells. IFN-g+/TNF-a+ CD8+ T cells contributed the most to
IFN-g production, directly followed by the IFN-g+/TNF-a+/IL-2+
CD8+ T cells. IFN-g+/TNF-a+ CD8+ T cells are also the main
contributors for TNF-a, whereas IFN-g+/TNF-a+/IL-2+ CD8+
T cells showed a higher IL-2 iMFI. TNF-a and IL-2 iMFI were
also the highest for TNF-a+/IL-2+ CD154+/CD4+ T cells, followed
by the IFN-g+/TNF-a+/IL-2+ CD154+/CD4+ T cells. Thus the
TNF-a+/IL-2+ CD4 and IFN-g+/TNF-a+ CD8 T cells contribute
strongly to the production of Th1 cytokines, followed by the
triple-positive T cells. Single cytokine–producing cells only showed
a relatively minor contribution.In conclusion, seven of the identified IVE-TB Ags are strongly
immunogenic, triggering specific and high cellular immune
responses in E/C+ TST+ individuals and long-term ltLTBI indi-
viduals, but not in E/C2 TST+ individuals, healthy mycobacterial
naive individuals, and TB patients. The strong IVE-TB responses
that were measured in the ltLTBI group were identified as IFN-g+/
TNF-a+ CD8+ T cells and TNF-a+/IL-2+ CD4+ T cells, which
were the most prominent contributors to the produced cytokines,
followed by triple-positive T cells.
DiscussionUsing quantitative genome-wide M. tuberculosis transcriptionalprofiling, we have identified a series of M. tuberculosis genes that
FIGURE 4. IFN-g responses to IVE-TB Ags in E/C+ (A), E/C2 (B), and
HC donors (C). A total of 43 E/C+ donors (A), 90 E/C2 donors (B), and 11
HC donors (C) were analyzed for their IFN-g WBA responses to Ags and
controls; the Ags wereM. tuberculosis Rv1284, Rv1956, Rv2034, Rv2324,
Rv3353c, and Rv3420c. Ten E/C+ donors (A), 36 E/C2 donors (B), and 9
HC donors (C) were also analyzed for responses to M. tuberculosis Ags
Rv0079, Rv1363c, Rv2225, Rv2380c, Rv2435c, Rv2465c, Rv2737c,
Rv2828c, Rv2982c, and Rv3515c IFN-g. The proportion of responders for
each Ag is indicated at the top of the graph. For comparative purposes,
medium background values were subtracted for each response in each
donor. Horizontal bars represent the median IFN-g responses. The dotted
line indicates the cut-off value for positivity, arbitrarily calculated as 3 3medium value.
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are expressed during in vivo M. tuberculosis infection in the lungsof resistant and susceptible mice, which we term IVE-TB. Most ofthe genes identified have previously been found to be expressed inthe M. tuberculosis proteome, and thus encode bona fide M. tu-berculosis proteins. This is further supported by their immuno-genicity profiles, as many of these proteins triggered IFN-gproduction in human WBA and lymphocyte stimulating assaysin M. tuberculosis ESAT6/CFP10-responsive patients, but not
in ESAT6/CFP102 TST+ individuals, HC donors, or TB patients.This is particularly relevant in the case of Rv2435c and Rv3353c,as their protein products have not been identified yet; however,IFN-g responses were demonstrated in E/C+ TST+ individuals,indirectly showing that these M. tuberculosis proteins are presentedto the human immune system during mycobacterial infection.Many of the IVE-TB genes we identified have been described
previously in relationship to the adaptative response of M. tu-
FIGURE 5. Cumulative IFN-g responses induced
by IVE-TB Ags, calculated per individual in the E/C+,
E/C2, and HC groups. Cumulative IFN-g responses
to all 20 IVE-TB protein and protein fragments in E/
C+ (n = 43), E/C2 (n = 90), and HC donors (n = 11).
Squares indicate cumulative IFN-g response of all 20
IVE-TB Ags, and circles indicate cumulative IFN-g
response of Rv1284, Rv1956, Rv2034, Rv2324,
Rv3353c, and Rv3420c Ags. Horizontal bars rep-
resent the median cumulative IFN-g responses.
FIGURE 6. PBMC IFN-g responses toward
IVE-TB Ags in TB patients and WBA E/C+
TST+ donors. PBMC of WBA E/C+ TST+
donors (n = 8) (A) and TB patients (n = 7) (B)
were stimulated with IVE-TB Ags and control
conditions for 6 d. Levels of IFN-g were mea-
sured and medium background values were
subtracted for each response in each donor for
comparative purposes. The proportion of re-
sponders for each Ag is indicated at the top of
the graph. Horizontal bars represent the median
IFN-g responses. The dotted line indicates the
cut-off value for positivity, arbitrarily set at 100
pg/ml.
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berculosis to environmental stress conditions, especially thosethat M. tuberculosis likely encounters during host infection. Weidentified one M. tuberculosis DosR regulon–encoded gene(Rv0079) (7) as well as six genes that are part of the EHR regulon(Rv1284, Rv1956, Rv2034, Rv2324, Rv2465, and Rv3515) (17).Three of these have also been described as starvation/nutritionalstress genes (Rv1284, Rv1956, and Rv2034) (14). This functionof the IVE-TB genes in responding to host-induced stressconditions during in vivo pulmonary infection enhances thebiological plausibility of our findings and lends validity to ourapproach.Of further interest, nine of the M. tuberculosis genes identified
in this study have not been described previously in relationship toM. tuberculosis host infection, although some of their functionshave been linked to possible adaptation to in vitro host-induced
stress conditions (Supplemental Table III). Several of these geneshave a role in metal transport, metalloregulatory transcriptionalregulation, or represent metalloenzymes. Furthermore, genes wereidentified that play a role in lipid metabolism. This is in agreementwith the documented shift toward using fatty acids as an alter-native carbon source instead of carbohydrates under nutrient-limiting conditions. Altogether, many of the IVE-TB genes wehave identified appear to be related to the adaptation of M. tuber-culosis to environmental stress conditions encountered in the host.Of additional importance, the identification of these genes in ourin vivo model supports previous findings mostly obtained inin vitro models by showing that they are induced during pulmonaryM. tuberculosis infection in vivo. On a cautionary note, however,our data do not allow us to discriminate whether the observeddifferential M. tuberculosis gene expression patterns are cause or
FIGURE 7. Polychromatic flow cytometric analysis of IVE-TB–specific T cell responses in long-term latentM. tuberculosis–infected individuals. PBMC
from long-term ltLTBI (n = 6) were stimulated for 16 h with the seven best recognized Ags as determined in Fig. 4. Frequencies of IFN-g–, TNF-a–, IL-2–,
and CD154-producing CD4+ and CD8+ T cells were determined (A). Subsequently, “multifunctional” responses were determined by analyzing combi-
nations of IFN-g, TNF-a, IL-2, and CD154 responses for CD4+ T cells and IFN-g, TNF-a, and IL-2 responses for CD8+ T cells. Results for two rep-
resentative IVE-TB Ags are shown (Rv2034 and Rv3420c) (B). For comparative purposes, medium background values were subtracted for each response in
each donor. Horizontal bars represent the median frequency of cytokine-producing CD4+ or CD8+ T cells.
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consequence of variations in host susceptibility (background and/or sst1 locus).As already mentioned, M. tuberculosis gene expression profiling
has been performed in the past, mostly focusing on in vitro–culturedbacteria grown under a variety of different conditions. Subsequentwork assessed M. tuberculosis gene expression profiles followinginfection of host cells (8, 19, 43), and some recent studies haveanalyzed M. tuberculosis gene expression patterns also in vivo (20,59). Ward et al. (59) showed that there was little overlap in theM. tuberculosis genes reported to be expressed in different studiesreporting onM. tuberculosis intracellular infection, likely as a resultof methodological differences. Nonetheless, the two studies Wardet al. described (8, 60) indicate that similar functional categoriesof M. tuberculosis genes are expressed during intracellular infec-tion. In line with this notion, when comparing our data to previousreports there are few overlapping individual M. tuberculosis genes,but we nevertheless do identify genes with previous describedfunctional categories. These differences are probably due to dif-ferences in selection criteria, in experimental settings such as in-fection route, and the specific mouse models we have used, whichhave not been analyzed previously.Despite these differences, several of our selected IVE-TB genes
do overlap with M. tuberculosis genes identified in other studiesas indicated in Table II. The M. tuberculosis gene Rv2225 whoseexpression was TB granuloma associated was also significantlyexpressed in the artificial granuloma model of Karakousis et al.
(21). This strengthens their association with host granuloma for-mation. Our in vivo pulmonary TB granuloma-associated M. tu-berculosis–expressed genes did not overlap with the granuloma-associated genes or macrophage-associated genes described byRamakrishnan and colleagues (61, 62) for M. marinum, whichmight be due to differences between the mycobacterial speciesstudied. Moreover, several of the IVE-TB genes we identified tobe highly expressed have also been described previously, includingRv0467 (icl), which encodes an enzyme in the glyoxylate path-way, which is important for M. tuberculosis persistence of M.tuberculosis (63, 64), and Rv0991c, which is part of the so-calledin vivo–expressed genomic island (20).The new M. tuberculosis Ags we have identified in this study
may represent interesting targets for vaccination, as they areexpressed during M. tuberculosis infection in the (geneticallysusceptible) lung, which we consider a critical parameter for ap-propriate Ag selection. Moreover, successful vaccine Ags shouldbe conserved between multiple M. tuberculosis strains. All proteinsequences examined were conserved among the tested M. tuber-culosis strains. Additionally, for almost all IVE-TB genes multipleproteome studies have documented their expression as proteinsin M. tuberculosis (Table III). A subset of the analyzed IVE-TBproteins was shown to be strongly immunogenic as judged by Th1responses in WBA, lymphocyte stimulation assays, and poly-chromatic flow cytometry. Indeed, the highest IFN-g responseswere identified within the E/C+ population of our TST+ cohort,
FIGURE 8. iMFI of IVE-TB–specific CD154+CD4+ and CD8+ T cell subsets in long-term latent M. tuberculosis–infected individuals. iMFI values for
IFN-g, TNF-a, and/or IL-2 were calculated via multiplication of CD154+CD4+ and CD8+ T cell subset frequency by their MFI. Six ltLTBI donors were
analyzed. For comparative purposes, medium background iMFI values were subtracted for each response in each donor. Light gray boxes represent CD154+
CD4+ T cell responses and dark gray boxes CD8+ T cell responses. Lines within boxes represent the medians. The lower boundary of the box represents the
25th percentile and upper boundary the 75th percentile. Whiskers extend to the lowest and highest values.
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whereas no differences in mitogen-induced responses were seen.No responses were seen in M. tuberculosis nonresponder healthyindividuals, suggesting that T cell recognition of IVE-TB Ags isindeed Ag specific and is correlated with M. tuberculosis exposurebased on TST and QFT-GIT conversions. Interestingly, TB patientsshowed relatively low recognition of the IVE-TB Ags, suggestingthat they did not develop strong Th1 immunity against these Ags.Importantly, IVE-TB Ag-specific responses could be detected in
ltLTBI, which have been exposed to M. tuberculosis many yearsago and never developed TB symptoms despite not having hadpreventive treatment. The most prominent T cell subsets withactivity against IVE-TB Ags included IFN-g+/TNF-a+ CD8+
T cells and TNF-a+/IL-2+ CD154+CD4+ T cells. Thus, CD8+
T cells were the major contributors of IFN-g production. Inter-estingly, also a population of Ag-specific–activated CD154+CD4+
T cells was observed that did not produce IFN-g, TNF-a, or IL-2.These cells may exert alternative functions, which could includeIL-17 production, immune regulation, or yet other functions,which need further study. Finally, we previously reported multi-functional CD4+ and CD8+ T cell responses toward resuscitationpromoting factor and DosR proteins and showed that IFN-g+/TNF-a+ CD8+ T cells were also the most prominent subset in theresponse to these Ags, suggesting that the development of specificdifferential T cell subsets may be unrelated to the nature of thespecific protein Ag involved.CD8+ T cells are activated upon recognition of epitopes pre-
sented via MHC class I molecules, indicating that the Ags arepresent and processed via the canonical cytosolic pathway or viaalternative (e.g., cross-priming) pathways (65). Both CD4+ andCD8+ T cells are important in M. tuberculosis control, and CD4+
and CD8+ T cell–deficient mice, for example, have increasedsusceptibility to M. tuberculosis (66). CD4+ T cells were recentlyshown to play an important (IFN-g–independent) role in the in-direct activation of IFN-g+ CD8+ T cells (67). In any case, our dataobtained in the ltLTBI individuals show that the M. tuberculosisAg-specific CD4+ and CD8+ T cells recognizing IVE-TB Ags mustbe long lived.The immunogenicity of some of the IVE-TB Ags has been an-
alyzed previously. The immunogenicity of the DosR Rv0079 proteinwas analyzed in TST+ (endemic) individuals as well as (cured) TBpatients (9, 12, 68). In these studies Rv0079 protein was recognizedby a minority of individuals, in agreement with our results in thisstudy. The immunogenicity of EHR and starvation Ags Rv1284 andRv1956 was previously analyzed in M. bovis–exposed cattle (17,69). Rv1284 was one of the five best recognized Ags, whereasRv1956 was also highly recognized. In contrast to the responsesobserved in M. bovis–exposed cattle, Rv1284 was moderately rec-ognized in our study, whereas Rv1956 was better recognized.In conclusion, by combining M. tuberculosis genome-wide
transcriptional profiling in the lungs of infected mice with strik-ingly differing host susceptibility backgrounds, we have identifiedM. tuberculosis genes that are specifically expressed in resistantor susceptible animals during pulmonary infection. These genesreveal a signature of the M. tuberculosis stress response in vivodepending on the genetic host background and host susceptibility.From these genes we selected 16 proteins, of which proved to behighly immunogenic in E/C+ TST+ donors and ltLTBI andtherefore represent interesting TB vaccine candidate and possiblyTB biomarker Ags (70).
AcknowledgmentsWe thank Louis Wilson for the production of theM. tuberculosis lysates, as
well as all blood donors who participated in this study.
DisclosuresT.H.M.O. is coinventor of an M. tuberculosis latency Ag patent, which is
owned by Leiden University Medical Center. The other authors have no
financial conflicts of interest.
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