Systematic Identification of Mycobacterium tuberculosis Effectors Reveals that BfrB Suppresses Innate Immunity*

Mycobacterium tuberculosis (Mtb) has evolved multiple strategies to counter the human immune system. The effectors of Mtb play important roles in the interactions with the host. However, because of the lack of highly efficient strategies, there are only a handful of known Mtb effectors, thus hampering our understanding of Mtb pathogenesis. In this study, we probed Mtb proteome microarray with biotinylated whole-cell lysates of human macrophages, identifying 26 Mtb membrane proteins and secreted proteins that bind to macrophage proteins. Combining GST pull-down with mass spectroscopy then enabled the specific identification of all binders. We refer to this proteome microarray-based strategy as SOPHIE (Systematic unlOcking of Pathogen and Host Interacting Effectors). Detailed investigation of a novel effector identified here, the iron storage protein BfrB (Rv3841), revealed that BfrB inhibits NF-κB-dependent transcription through binding and reducing the nuclear abundance of the ribosomal protein S3 (RPS3), which is a functional subunit of NF- κB. The importance of this interaction was evidenced by the promotion of survival in macrophages of the mycobacteria, Mycobacterium smegmatis, by overexpression of BfrB. Thus, beyond demonstrating the power of SOPHIE in the discovery of novel effectors of human pathogens, we expect that the set of Mtb effectors identified in this work will greatly facilitate the understanding of the pathogenesis of Mtb, possibly leading to additional potential molecular targets in the battle against tuberculosis.

specific effectors into the host to subvert the signaling pathways of the innate immune system, thereby allowing Mtb to avoid elimination and survive within macrophages for long periods of time (10,11). The presently best-characterized survival mechanisms of Mtb are the inhibition of phagosomal acidification and maturation, and the inhibition of apoptosis of infected macrophages (12,13).
However, there are presently only a limited number of wellcharacterized Mtb effectors that have been described, and only a few whose corresponding host-interacting proteins have been identified (14 -23) (supplemental Table S1). These interactions were mainly discovered by yeast two-hybrid (Y2H) (21,24) and affinity purification followed by mass spectrometry analysis (AP/MS) (22,25). For example, Mehra et al. applied a high-throughput Y2H platform to identify Mtb secreted virulence factors and Mtb-host interacting proteins (21). However, one of the disadvantages of Y2H is that it detects only about 20% of all interactions because of its high false-negative rate (21,26,27). AP/MS can detect proteins in complexes but is unable to distinguish between direct from indirect interactions when several proteins are purified together (24,26). Thus, because of the intrinsic limitations of Y2H and AP/MS, these methods are not well-suited for the global screening of protein-protein interactions (PPI) between Mtb and the host.
Systematic identification of Mtb and macrophage interactions holds the promise for revealing the complex mechanism underlying pathogenesis of Mtb (28,29). Because of the lack of suitable proteome-scale techniques, we do not yet have a global picture of the Mtb-host interactions at the protein level.
Proteome microarrays, usually composed of thousands of proteins from one species that are affinity purified and functionally active, are high-throughput platforms for the global profiling of thousands of molecular interactions in a single experiment (30). They provide a versatile platform for investigating many aspects at the systems-level, such as discovering serum biomarkers for various diseases (31) and globally investigating interactions with proteins (32), DNA (33), RNA (34), lipids (35), and small molecules (36,37).
Recently, we constructed a functional Mtb proteome microarray (with Ͼ95% coverage of the Mtb proteome) (38). The power of this Mtb proteome microarray has already been demonstrated in investigations of PPI (39) and small molecule/drug-protein binding (40).
Herein, we took advantage of this Mtb proteome microarray and established a strategy for the global identification of the Mtb proteins involved in Mtb-macrophage interactions. With this, we identified a total of 26 Mtb membrane proteins and secreted proteins that may play important roles in Mtb-host interactions. We focused on BfrB (Rv3841), a ferritin-like protein that was known to play a key role in the maintenance of Mtb iron homeostasis (41). Interestingly, BfrB was recently identified as a secreted protein that is enriched from infected macrophages and is also present in the exosomes of patients, suggesting that it may play additional roles in the interactions with the host (42)(43)(44). However, the mechanism by which BfrB functions in the modulation of the host immune response is poorly known. Therefore, we sought to identify crucial host target proteins to which BfrB binds. We found that BfrB subverts NF-B function by binding and reducing the nuclear abundance of its subunit RPS3 (45) to inhibit host immune defense. Thus, our findings reveal a previously unknown mechanism by which BfrB, as a newly identified effector, subverts innate immunity.

EXPERIMENTAL PROCEDURES
Global Profiling of Mtb Proteins Interact with Proteins from Macrophage-THP-1 and U937 cell were differentiated into macrophagelike cells using 100 ng/ml PMA (Sigma-Aldrich, Saint Louis, MO) for 24 h. Then the medium was replaced and cells cultured in RPMI 1640 medium supplemented with 10% FBS for 24 h. The cells were washed twice, and the cell lysates were prepared using cell lysis buffer as described (46). The whole cell lysates were biotinylated using EZ-Link Sulfo-NHS-LC-Biotin protein biotinylation kit (Thermo Scientific, Bremen, Germany) according to the manual. Mtb proteome microarrays were blocked for 1 h at room temperature with shaking in blocking buffer as described (46). Microarrays were incubated in the biotinylated whole cell lysates for 12 h at 4°C with shaking, then washed three times in 1ϫ PBS (pH 7.4) with 0.1% Tween 20 (PBST). Arrays were probed with Cy3-streptavidin and incubated in a humidified chamber for 1 h at room temperature. After washing three times in PBST and once ddH 2 O, microarrays were dried in a SlideWasher (CapitalBio, Beijing, China) and then scanned with a GenePix 4200A microarray scanner (Molecular Devices, CA). Data were analyzed with GenePix Pro 6.1 (Molecular Devices, CA).
GST Pull-down Assay-To identity the host targets of Mtb effectors, GST-tagged BfrB were purified as previously described (38). PMA-differentiated THP-1 cells lysed in Nonidet P-40 lysis buffer (Beyotime, Shanghai, China) supplemented with 0.5 mM PMSF (Sigma-Aldrich). The GST pull-down was performed as described (11). The pull-down proteins were eluted by 2ϫ SDS sampling buffer and denatured at 95°C for 10 min and analyzed by standard silver staining.
Proteins Identification and LC-MS/MS Analysis-To determine the proteins interacted with BfrB, the human proteins enriched by BfrB were subjected for electrophoresis and silver staining, the major bands in the gel were excised, destained and reduced by incubation in a solution of 10 mM DTT at 60°C for 20 min, followed by alkylating in a solution of 25 mM IAM at room temperature for 15 min. The pieces were digested in-gel with trypsin (Promega, Madison, WI) overnight at 37°C . The tryptic peptide digests of the proteins were analyzed using a LC system (Nano Pump, Ultimate 3000, Dionex, Thermofisher) coupled with an ESI-Q-TOF mass spectrometer (maXis Impact, Bruker Daltonik, Bremen Area, Germany).
Tandem mass spectra were extracted, charge state deconvoluted and deisotoped by Compass Data Analysis version 4.1 (Bruker Daltonics). The peak list was directly generated from raw data using centroid algorithm with peak width set as 0.1 m/z and intensity above 100. No peak smooth or filter process was applied. After the charge states were calculated, the de-isotoped. Peak list was exported as mgf file for further mascot search. Mascot (version 2.4, Matrix Science, Boston, MA) was set up to search the SwissProt 2013_12 Homo sapiens database (20,274 entries). The following parameters were considered for the searches: peptide mass tolerance was set to 20 ppm, fragment mass tolerance was set to 0.05 Da, and a maximum of two missed cleavage of trypsin was chosen. Carbamidomethyl (C) was set as fixed modification, and oxidation (M) was set as variable modifications. The threshold score was greater than or equal to 30, expectation value was 0.01 and the number of peptides was more than 2 for accepting individual spectra.
Monitoring the Kinetics of BfrB and RPS3 Interaction by BLI-The binding kinetics of BfrB and RPS3 were measured using ForteBio Octet system (Pall, Menlo Park, USA). Affinity purified BfrB was biotinylated using EZ-Link Sulfo-NHS-LC-Biotin protein biotinylation kit as described above. Biotinylated BfrB was tethered on the tip surface of a streptavidin-coated sensor. The binding partner, RPS3, in S.D. buffer (1ϫ PBS [pH 7.4] with 0.02% Tween-20 and 0.1% BSA) was then exposed to tethered biotinylated BfrB, and binding was measured by coincident change in the interference pattern.
Cell Transfection, Immunoblot Analysis, and Immunoprecipitation-Transfection was performed using Attractene Transfection Reagent (Qiagen, Hilden, Germany) according to the manufacturer's instruction. HEK293T cells were collected 24 h after transfection and lysed in Nonidet P-40 lysis buffer (Beyotime, Shanghai, China) supplemented with 0.5 mM PMSF (Sigma-Aldrich). The immunoprecipitation assay was performed as (11). The immunoblot analysis was followed as previously described (32). The results were then recorded by the Odyssey Infrared Imaging System (LI-COR Biosciences, Lincoln, NE).
RPS3 Nuclear Translocation-Cytosolic and nuclear protein extracts were prepared from HEK293T cells transfected with FLAG-BfrB/FLAG plasmids as previously described (48). All the following steps were carried out at 4°C. TNF -␣ stimulation was used to promote RPS3 translocation into the nucleus with 30 ng/ml for 1 h.
RT-PCR-Total RNA was isolated with the RNAprep pure Cell/ Bacteria Kit (TIANGEN, Beijing, China) and was reverse-transcribed into cDNA using the Quantscript RT Kit (TIANGEN, Beijing, China) with oligo (dT) primers. RT-PCR reactions were performed in triplicate with primers by using the SYBR Green PCR Master Mix (Roche, Basel, Switzerland) in the ABI StepOne Plus system (Applied Biosystems, Foster City, CA). The relative transcription level was calculated by using the 2 Ϫ⌬⌬Ct method and were normalized to the expression of the control gene Gapdh.
Molecular Docking-Molecular docking were performed to investigate the binding mode between the Mtb BfrB to the human RPS3 using the ZDOCK server. The three-dimensional (3D) structures of the BfrB (PDB ID: 3QD8) and the RPS3 (PDB ID: 1WH9) were downloaded from Protein Data Bank. The top ranked pose as judged by the docking score was subjected to visual analysis using PyMoL 1.7.6 software.
CFU Counting-THP-1 cells were seeded at 3.5 ϫ 10 6 cells/well in a 6-well plate and differentiated as described above. After 12 h, the cells were washed once and cultured in fresh RPMI 1640 medium for an additional 8 h before infection. The Msm infection and CFU counting assay performed as (11).
Experimental Design and Statistical Rationale-The proteome microarray data were extracted from the microarray images by GenePix Pro 6.1 (Molecular Devices, CA) and then processed using an R package developed in our lab (http://www.proteinmicroarray.cn/). Briefly, the SNR of each protein was averaged for the two duplicated spots on each microarray and was defined as the ratio of the median of foreground signal to the median of background signal. The SNRs for microarrays incubated with natural or denatured protein were set as SNR (ϩ) and SNR (-), respectively. Another index, "Ratio" was defined as SNR (ϩ)/SNR (-). To call the candidates, the cutoff was set as ratio Ն 1.5 and p value Յ2 ϫ 10 Ϫ5 .

Screening of Mtb Proteins that Interact with Macrophage
Proteins Using the Mtb Proteome Microarray-To globally identify the Mtb proteins that bind proteins from human macrophages, we developed the strategy, SOPHIE (Systematic unlOcking Pathogen and Host Interacting Effectors) (Fig.  1A). Briefly, the total cell lysate of human macrophages was prepared. After biotinylation, the lysate was incubated on the functional Mtb proteome microarray (38). The Mtb proteins that bind to proteins from the macrophage were then identified as potential effectors. These potential effectors were tagged with GST and used as bait to enrich for their binding partners from macrophage lysates through GST pull-down. Finally, the identities of the enriched proteins were determined by MS. As shown in the schematic diagram in Fig. 1A, two human monocytic cell lines, THP-1 and U937, were treated with Phorbol 12-myristate 13-acetate (PMA) to induce the differentiation into macrophages (Fig. 1B). Cell lysates were biotinylated and aliquoted. One aliquot of the cell lysates was denatured at 95°C and included as a negative control. To identify potential candidates, the cut-off was set as the signalto-noise ratio (SNR) Ͼ 1.5. In this way, we identified 51 and 42 proteins from the PMA-treated THP-1 and U937 cells, respectively, with 34 proteins in common between the two cell lines. This indicates a high reliability of the microarray experiments (Fig. 1B, supplemental Fig. S1 and supplemental Table S2).
Compared with other fractions of Mtb, the membrane proteins and secreted proteins have higher potential to interact with macrophage proteins (49,50). Interestingly, of the 34 shared proteins (supplemental Fig. S1), 21 are membrane or secreted proteins. In addition, there are 2 (Rv0462, Rv3339c) and 3 (Rv3240c, Rv0203, and Rv2164c) unique membrane or secreted proteins that interact with proteins from the THP-1 or U937 cells, respectively. Thus, 26 Mtb membrane proteins or secreted proteins that are potential Mtb effectors were discovered with SOPHIE ( Fig. 1C and supplemental Table S3).
Identification of the BfrB Binding Protein in Human Macrophages-One of the effectors identified here, BfrB, was previously found to be required for Mtb survival in macrophages (41,51) and is enriched from infected macrophages (43), suggesting that BfrB may play an important role in the interaction with the host. To identify the macrophage binding partners of BfrB, we purified GST-tagged BfrB and incubated it with PMA-treated THP-1 lysate before performing GST pull-down and silver staining ( Fig. 2A). Subsequent MS identified a major pull-down protein of BfrB as RPS3 (Fig. 2B, supplemental Table S4), an essential subunit of NF-B important for NF-B binding to specific regulatory sites and for the inducible expression of a variety of genes (45).
To further validate the interaction of BfrB and RPS3, we examined the strength of their interaction using Bio-Layer Interferometry (BLI), finding that there is indeed a strong interaction between BfrB and RPS3 with an equilibrium dissociation constant (K D ) value of 4.2 ϫ 10 Ϫ7 M (Fig. 2C).
To verify that RPS3 interacts with BfrB in vivo, a FLAGtagged BfrB was overexpressed in HEK293T using an empty vector with only a FLAG epitope as control, followed by immune-precipitation with an anti-FLAG antibody. In this way, we found that endogenously expressed RPS3 could be enriched (Fig. 2D). Likewise, FLAG-tagged BfrB could also be enriched by immunoprecipitation with an anti-RPS3 antibody (Fig. 2E). Thus, consistent with the in vitro data, these results strongly suggest that BfrB interacts with RPS3 in vivo.
To map the binding domain of RPS3 on BfrB, we carried out a structure-function study with deletions of RPS3 that include its known functional domains (Fig. 3A). Co-immunoprecipitation revealed that the N-terminal region of RPS3 (amino acids 1-111), particularly residues 1-42, is required for RPS3 binding to BfrB (Fig. 3B).
Mtb BfrB has an extended C termini (residues 164 -181) that is unlike most other bacterial ferritins (52). Co-immunoprecipitation revealed that the C-terminal region of BfrB (residues 164 -181) is important for the binding of BfrB to RPS3 (supplemental Fig. S2A and S2B) that is consistent with the aforementioned results.
BfrB Reduces the Nuclear Abundance of RPS3 and Alters Host NF-B Activity-The RPS3 N-terminal (residues 1-42) contains a nuclear localization signal (NLS), which mediates translocation to the nucleus in response to TNF-␣ stimulation and DNA-damage (45,53). We hypothesized that BfrB may mask the NLS of RPS3 by binding to the RPS3 N-terminal (residues 1-42).
To determine if BfrB binding to RPS3 inhibits translocation of RPS3 into the nucleus, we detected the abundance

FIG. 2. Validation of the interaction between BfrB and RPS3.
A, GST Pull-down of BfrB. GST tagged BfrB was incubated with PMAdifferentiated THP-1 cell lysates followed by GST Pull-down, whereas GST only was included as the negative control. The unique band was then trypsin digested and subjected to MS/MS analysis. B, RPS3 was identified as the major binder of BfrB by LC-MS/MS analysis. C, The binding kinetics of BfrB to RPS3 measured by BLI assay. Biotinylated BfrB was immobilized on a streptavidin-coated biosensor and exposed to RPS3 in buffer. The binding was measured by coincident changes in the interference pattern. Results presented are representative of three experiments. D, Co-immunoprecipitation of RPS3 with FLAG-BfrB. Samples were immunoprecipitated with ␣-FLAG antibody to capture BfrB and immunoblotted with ␣-RPS3 to detect RPS3. Experiments were carried out in triplicate. E, Co-immunoprecipitation of FLAG-BfrB with RPS3. Samples were immunoprecipitated with ␣-RPS3 antibody to capture RPS3 and immunoblotted with ␣-FLAG antibody to detect BfrB. Experiments were carried out in triplicate. of nuclear and cytoplasmic RPS3. HEK293T cells were transfected with bfrB, with or without stimulation with 100 ng/ml TNF-␣ for 1 h. The cells were fractionated to separate the nuclear-from the cytoplasmic-components. The lack of PARP and tubulin within the cytoplasmic and nuclear fractions, respectively, demonstrated the absence of crosscontamination among the fractions (Fig. 4A). We found that BfrB reduces the nuclear translocation of RPS3, suggesting that BfrB may also inhibit the host immune response by alteration of the transcription of NF-B dependent genes.
To test this, we performed RT-PCR to assess the regulation of several RPS3-dependent genes (IL2, IL8), which are important to the innate response to infection (45). We indeed found that BfrB efficiently inhibits RPS3-dependent gene expression following the stimulation of TNF-␣ (Fig. 4B).
We also investigated whether Mtb BfrB modulates the NF-B signaling pathway using a dual-luciferase reporter assay. Ectopic expression of Mtb bfrB in HEK293T cells efficiently blocked TNF-␣ induced NF-B luciferase reporter activation (Fig. 4C). Further, BfrB affected neither the TNF-␣ (100 ng/ml, 1 h) induced phosphorylation of IB␣ nor altered total IB␣ concentrations (supplemental Fig. S2). Thus, these data suggest that BfrB plays a role in the reduction of RPS3 nuclear abundance, without significant impact on other NF-B subunits.
BfrB Inhibits Cytokine Production of Macrophages and Promotes the Survival of Mycobacteria in Macrophages-We next investigated whether BfrB modulates the expression of inflammatory cytokines in macrophages by analyzing the expression of mRNA encoding TNF-␣ and IL-1␤ in macrophages infected with bfrB-overexpressing Mycobacterium smegmatis (Msm). We found that overexpression of bfrB in Msm significantly inhibits the expression of TNF and IL-1␤ mRNA and increased bacterial survival in THP-1 (Fig. 5). The expression of cytokines was markedly decreased in cells infected with bfrB-overexpressing Msm after 8 h, whereas the wild-type Msm and bfrB-overexpressing Msm strains had similar bacterial colony-forming units (CFU) until 12 h after infection. Thus, Mtb BfrB can promote survival of mycobacteria in macrophages by inhibiting cytokine production in host cells. FIG. 3. BfrB binds to the N terminus of RPS3. A, Diagram of RPS3 and EGFP-tagged truncation mutants. KH, K homology. B, HEK293T cells transfected with constructs expressing FLAG-tagged BfrB and full-length or truncated EGFP-tagged RPS3 proteins, lysed after 48 h, and immunoblotted for EGFP-tagged RPS3 proteins after immunoprecipitation with FLAG antibody for BfrB in lysates. Experiments were carried out in triplicate. C, Detailed view of the interaction between the RPS3 (pale green) and BfrB (pink); Amino acids 164 -181 of the BfrB were showed in rose red, and amino acids 1-42 of the RPS3 were displayed in green.

DISCUSSION
In this study, we developed a strategy that we call SOPHIE to identify potential effectors of Mtb. We identified 26 Mtb membrane and secreted proteins that interact with macrophage proteins. We found that BfrB, identified here for the first time as an Mtb effector, subverts the host innate immune system by binding the NF-B subunit RPS3 and promotes the survival of mycobacteria in macrophages by inhibiting cytokine production in host cells.
One of the most important goals of present TB studies is to identify Mtb effectors that interact with macrophage proteins (54). The strategy of SOPHIE based on the Mtb proteome microarray has several advantages over more traditional approaches. First, the strategy can globally and unbiasedly profile the bindings of 4262 Mtb proteins with the macrophage cell lysate in a single experiment. Second, all the Mtb proteins on the microarray are expressed and affinity purified in a high-throughput manner following the same procedure. Thus, the local concentrations of proteins are relatively high that could greatly facilitate the identification of Mtb effectors. Third, as demonstrated in this study, the proteome-wide Mtbmacrophage PPI identification consumes only a limited num-ber of microarrays in less than 18 h. In addition, the macrophage cell lysate was incubated on the Mtb proteome microarray, and so, the host proteins were maintained in a physiological condition that ensures more reliable results.
Mtb BfrB is a ferritin that exists as a macromolecular assembly composed 24 identical subunits (52). BfrB is required for Mtb to overcome iron limitation and oxidative stress, and Mtb lacking BfrB were found to be unable to persist in mice (41). In addition, we note that iron is limited in the host cells (51). A recent report showed that pupylation of ferritin triggers HEK293T cells were co-transfected with a firefly luciferase construct with a renilla luciferase plasmid, and bfrB, or a FLAG control driven by a consensus B site. The cells were cultured for 24 h, in the presence or absence of TNF-␣ (100 ng/ml) stimulation for 1 h. Experiments were carried out in triplicate. C, Quantitative PCR analysis of IL2 mRNA and IL8 mRNA in HEK293T transfected with or without bfrB for 24 h. 0.01Ͻ*p Ͻ 0.05, 0.001Ͻ**p Ͻ 0.01, ***p Ͻ 0.001 (two-tailed unpaired t test). Data are representative of one experiment with three independent biological replicates. the partial or complete disassembly of the 24-meric ferritin, which is required for adaption of Corynebacterium glutamicum to iron limitation (59). The BfrB of Msm has been shown to be pupylated at Lys-10 that is located on the outer surface of its crystal structure (60). Previous work has suggested that bacterial proteins smaller than 70 KDa can cross the host phagosomal membrane (61). Although the exact mechanism by which BfrB secreted across the Mtb membrane to macrophage remains unclear (43,44), the disassembly of Mtb BfrB triggered by pupylation may be important in this regard.
Our results show that BfrB is a novel effector that inhibits the immune system by binding the NF-B functional subunit, RPS3. The NF-B signaling pathway is one of the most attractive targets exploited by pathogens to modulate host cell events (48,62). For example, Mtb PtpA can block the host adaptor TAB3 mediated NF-B signaling by competitively binding to the ubiquitin-interacting domain of TAB3 (11). The Escherichia coli strain O157:H7 effector NleH1 specifically binds and inhibits the phosphorylation of RPS3 at Ser-209, thus retarding its nuclear translocation and subsequent NF-B function (48,63). In this work, we found that BfrB interacts with the NLS region of RPS3 and reduces the nuclear abundance of RPS3 to reduce host transcriptional output. Mtb BfrB participation in the host immune response may provide a new insight into why BfrB is essential for Mtb during chronic infection of mice (41,51). In addition, we also showed that Mtb BfrB promotes survival of mycobacteria in macrophages by inhibiting cytokine production in host cells.
We note that the secreted proteins of Mtb have not yet been comprehensively determined. A variety of studies have identified a series of secreted proteins through different strategies, e.g. detecting Mtb proteins in culture filtrate (CF) (42, 64 -66), prediction by bioinformatics (67), or individual in-depth functional studies (11,23). However, proteins may be in the CF because of bacterial lysis rather than secretion, and bioinformatics predictions may not be accurate. Thus, other proteins that were identified on the microarray but not included in the 26 protein-list may also possess important interactions with host proteins.
Finally, we believe that the 26 Mtb membrane or secreted proteins identified in this study could serve as a valuable resource for further basic research. In addition, some of these proteins may potentially be promising targets for Mtb drug development, because inhibitors targeting secreted or membrane proteins do not need to penetrate the unique and extremely impermeable mycobacterial cell wall (68 -70). For example, some of the targets of the first-and second-line TB drugs, such as isoniazid and ethambutol (71,72), are the proteins necessary for the biosynthesis and assembly of the mycobacterial cell wall and outer membrane (73). In our list, some proteins may be potential targets of anti-TB drug development. For example, SecA1, as the component of the canonical mycobacteria Sec secretion system, is essential and responsible for the bulk of proteins export (74). FadD13 is involved in maintaining the appropriate cell wall architecture of Mtb on exposure to the acidic pH encountered within macrophages (75). Mtb BfrB plays an important role in the interaction with the NF-B subunit RPS3, suggesting a po- tential TB treatment via targeting of BfrB-RPS3 interfaces. Because these potential drug targets are different from the known ones, once effective drugs for these targets are successfully developed, they should have novel mode of action (MOA), thus, providing new "bullets" for combating with MDR and XDR TB.
In summary, we have performed a comprehensive survey of the effectors of Mtb using our novel strategy, SOPHIE. It is expected that these effectors will be a valuable resource for basic Mtb study and drug development. In addition, we fully anticipate that SOPHIE will become a highly effective strategy to identify effectors in other human pathogens, thus providing a versatile method in drug development strategies more generally.