Finding of the Low Molecular Weight Inhibitors of Resuscitation Promoting Factor Enzymatic and Resuscitation Activity

Background Resuscitation promoting factors (RPF) are secreted proteins involved in reactivation of dormant actinobacteria, including Mycobacterium tuberculosis. They have been considered as prospective targets for the development of new anti-tuberculosis drugs preventing reactivation of dormant tubercle bacilli, generally associated with latent tuberculosis. However, no inhibitors of Rpf activity have been reported so far. The goal of this study was to find low molecular weight compounds inhibiting the enzymatic and biological activities of Rpfs. Methodology/Principal Findings Here we describe a novel class of 2-nitrophenylthiocyanates (NPT) compounds that inhibit muralytic activity of Rpfs with IC50 1–7 µg/ml. Fluorescence studies revealed interaction of active NPTs with the internal regions of the Rpf molecule. Candidate inhibitors of Rpf enzymatic activity showed a bacteriostatic effect on growth of Micrococcus luteus (in which Rpf is essential for growth protein) at concentrations close to IC50. The candidate compounds suppressed resuscitation of dormant (“non-culturable”) cells of M. smegmatis at 1 µg/ml or delayed resuscitation of dormant M. tuberculosis obtained in laboratory conditions at 10 µg/ml. However, they did not inhibit growth of active mycobacteria under these concentrations. Conclusions/Significance NPT are the first example of low molecular weight compounds that inhibit the enzymatic and biological activities of Rpf proteins.


Introduction
Tuberculosis (TB) still kills millions of people around the Globe. Moreover, Mycobacterium tuberculosis has been suggested to persist in a dormant state in approximately 2 billion of people [1] (Dormancy is a reversible physiological state of the bacteria characterized by low metabolic activity, in which cells can persist for extended periods without division). Due to reasons that are not fully clear, such latent infection can reactivate at any time causing active tuberculosis [2] (Latency is a clinical state of asymptomatic, chronic infection). Importantly, dormant mycobacteria are less susceptible to antibiotics which are normally used for treatment of active tuberculosis. Therefore, finding of new compounds with potential activity against latent forms of tuberculosis is an urgent task for the scientific community. Ideally, such compounds should sterilize dormant M. tuberculosis in the host environment or block its reactivation.
The discovery of Rpfs (resuscitation promoting factor), a family of proteins involved in the control of dormancy and ''nonculturability'' of mycobacteria and related organisms, has provided a promising opportunity to explore new strategies on targeting M. tuberculosis persistent organisms associated with latent infections. M. tuberculosis contains five rpf-like genes which products, RpfA-E expressed as recombinant proteins in E. coli stimulated replication and resuscitation of mycobacterial cells [3,4]. The importance of the Rpf proteins for resuscitation of dormant (''non-culturable'') M. tuberculosis cells in vitro and for growth of viable cells in vivo was also confirmed in the study of the Rpf knockout mutants [5,6].Despite these mutants were defective for reactivation from chronic tuberculosis [7,8] the possible significance of Rpfs for establishing and maintenance of latent tuberculosis has yet to be clarified. Therefore, Rpfs represent attractive targets for development of new drugs preventing resuscitation of dormant M. tuberculosis. Such drugs will have a great potential for prophylaxis of latent TB reactivation, provoked by the application of anti-TNF antibodies therapy [9]. However, until recently, no substances inhibiting the biological activity of Rpf have been reported.
Despite the progress in the Rpf research, the mechanisms of its biological activity remain unclear. Recent findings suggest that Rpfs are probably involved in the remodelling of bacterial cell envelope [10,11,12]. According to NMR [13] and X -ray diffraction [14] studies of the conserved domain of Rpf is structurally close to the c-type lysozyme. However, functionally it is more similar to lytic transglycosylases [12]. Several experimental results confirmed that Rpf possesses cell wall hydrolysing activity. Moreover, a correlation between this enzymatic activity and the resuscitation activity of Rpf has been found [15]. In particular, the ability of recombinant Rpf protein to hydrolyze the artificial lysozyme substrate, 4-methylumbelliferyl-b-D-N,N9,N0-triacetylchitotrioside (4-MUF-3-NAG) [15,16] opened a possibility for the fast screening of low molecular weight compounds which could serve as inhibitors of the Rpf proteins. In this paper we report on several nitrophenylthiocyanates (NPT) with anti-Rpf activity.

Chemistry
Melting points were determined according to the BP procedure and are uncorrected (Electrothermal 9001, GB). If analyses are indicated only by the symbols of the elements, analytical results are within 6 0.3% of the theoretical values (Carlo-Erba 5500, Italy). NMR spectra were determined with a Varian Unity Plus 400 (USA). Shifts for 1 H NMR are reported in ppm downfield from TMS (s). Mass spectra were obtained using a Finnigan SSQ-700 (USA) instrument with direct inject. Silicagel 60 F 254 aluminium sheets (Merck Co, Germany) were used for all analytical thin layer chromatography (TLC). All chemicals were purchased from Alfa Chemicals (Lancashire, England) including starting otho-chloronitroaryles for synthesis target compounds (III), (IV), (V), (VI), (VIII), (IX), (X). 4-chloro-6-methoxy-5-nitropyrimidine was synthesised according to [17].

Bacterial Growth
Micrococcus luteus, Fleming strain 2665, NCIMB13267 was grown in Nutrient Broth (Hi Media) on an orbital shaker at 30uC. Mycobacterium smegmatis mc 2 155 was grown in Sauton's medium on an orbital shaker at 37uC. M. tuberculosis H37Rv was grown under agitation at 37uC (200 rpm), in Sauton's medium supplemented by ADC with 0.05% w/v Tween 80 [19] or in 7H9 liquid supplemented with 10% v/v of OADC (BD) and 0.05% w/v of Tween 80. Specially modified media (see below) were applied for generation of ''non-cultutrable'' mycobacteria.

MIC Determination
Cells of M. luteus were grown to the stationary phase in the rich medium (NB, Himedia) for 48 h. Cultures were washed twice by centrifugation and diluted to 10 5 cells/ml by the same medium. Diluted cells were distributed on 96 well plates (250 ml per well) and incubated in the Multiskan Analyzer (Thermo, Finland) with 620 nm filter at 30uC for 24 h with shaking. Prior the incubation, the inhibitors, freshly dissolved in DMSO (1 mg/ml), were added in 0.5-10 mg/ml concentration range to the appropriate wells in triplicates. The culture of M. luteus without inhibitors served as a control. Bacterial growth was followed by measurement of optical density at 620 nm. Cells of M. smegmatis grew in NB medium to the stationary phase for 24-26 h and were diluted to 10 5 cells/ml by the same medium containing 0.05% w/v Tween-80. Cell growth with and without inhibitors was detected at 37uC in the Multiskan Analyzer, similarly to M. luteus experimental conditions. M. tuberculosis grew in Sauton's medium supplemented by ADC in the presence of 0.05% Tween-80 for 8 days. Cells were inoculated in 2 ml of fresh medium at ca 10 6 cells/ml in test tubes. Inhibitors were added at 1-25 mg/ml in triplicates. Test tubes were incubated without shaking at 37uC OD 600 was measured periodically, using Eppendopf Biophotometer for 14 days.

Formation of ''Non-Culturable'' Cells of M. smegmatis and M. tuberculosis
M. smegmatis mc 2 155 harbouring the pAGR plasmid with the rpf gene was used to produce ''non-culturable'' (NC) cells in the stationary phase as described previously [20]. M. tuberculosis ''nonculturable'' cells [21] were established after the prolonged storage (4-5 months) of stationary cultures after cell growth in the modified Sauton's medium without K + for 50 days [22].

Resuscitation of ''Non-Culturable'' Cells of M. smegmatis and M. tuberculosis
Resuscitation and most probable number (MPN) assays of M. smegmatis were performed in 48-well plastic plates (Corning) containing 1 ml of Sauton's medium diluted 1:1 with 0,6% (w/ v) glycerol in water. Some wells contained inhibitors at 0.1-25 mg/ ml. All wells were supplemented with 0.05%(w/v) yeast extract (LabM). Appropriate serial dilutions of the starved M. smegmatis cells (100 ml) were added to each well. Plates were incubated at 37uC with agitation at 150 rpm for 10-14 days. Wells with visible bacterial growth were counted as positive, and MPN values were calculated using standard statistical methods [23]. The identity of cells was verified by microscopy using a Nikon microscope (Japan).
Similar procedure was applied for resuscitation of M. tuberculosis cells, save that the diluted Sauton's medium was supplemented by 10% v/v ADC, and cell dilutions were prepared in screw capped test tubes which were kept standing at 37uC for 2 months.

Isolating and Purification of Recombinant Rpf Proteins
The truncated form of M.luteus Rpf (RpfSm) was used for the analysis. The truncated protein contained conserved Rpf domain and additional 20 amino acids of the gene product, corresponding to the following amino acid sequence: ATVDTWDRLAECESNGTWDINTGNGFYGGVQFTLSS-WQAVGGEGYPHQASKAEQIKRAEILQDLQGWGAWPLCS-QKLGLTQADADAGDVDATE. The truncated gene was amplified by PCR from the pET-19b-Rpf described before [24], using a T7 promoter primer CGCGAAATTAATACGACTCACTAT and a reverse primer: CGACGGATCCTCACTCGGTGGCGT-CACGT (BamH1 restriction cite is underlined). After denaturation for 5 min at 94uC, samples were subjected to 2 cycles of: 30 s at 94uC, 30 s at 58uC, 60 s at 72uC, followed by 2 cycles of: 30 s at 94uC, 30 s at 56uC, 60 s at 72uC and 25 cycles of: 30 s at 94uC, 30 s at 54uC, 60 s at 72uC, followed by 5 min at 72uC. The purified PCR product was digested with XbaI and BamH1, purified, ligated into pET19b vector and established in E. coli DH5a. The construct containing the truncated rpf gene (RpfSm) was sequenced and transformed in E. coli HSM174 (DE3). RpfSm was purified from 350 ml cultures of the E. coli producer strain, grown at 37uC in the rich medium (Hi Media) containing 100 mg/ ml ampicillin to optical density OD 600 nm 0.65-0.8. After induction with 1 mM IPTG, growth continued for 2 h at room temperature. Cells were collected by centrifugation at 3000 g for 15 min and frozen in the binding buffer (BB) (20 mM Tris-HCl pH 8.0; 0.5 M NaCl; 5 mM imidazole). After thawing out, RNAase and DNAase, both at concentrations of 10 mg/ml were added in the presence of 10 MM MgSO 4 , followed by addition of 8 M urea. After sonication, the crude extract was centrifuged at 6000 g for 30 min to remove cell debris, and supernatant was applied to the Ni 2+ -chelation column (V = 2 ml) («Sigma», Germany), equilibrated with BB. The Biological LP system («Biorad») was employed for the elution and refolding of the protein on the Ni-NTA column: first, the series of washing steps, with the BB contained 8 M urea, were applied. The second (refolding step) was the application of BB with urea concentration declining linearly from 8 M to zero. The protein was eluted by linear gradient of imidazole from 5 mM to 500 mM. Protein was collected in the range of imidazole concentrations of ,250 mM in a total volume of 4-5 ml. Dialysis of Rpf contained fraction (30-50 mg/ml) was performed against 50 mM citric acid-sodium citrate buffer, pH 6.0. The protein was stored at +4uC for one week without significant loss of the activity.
DDUF RpfB was expressed and purified under native conditions according to [25] save that incubation with IPTG was 2 h at room temperature. Final concentration of the protein was 150-250 mg/ ml. Dialysis step and storage were similar to RpfSm.

Muralytic Activity of Rpf
To determine a muralytic activity of the recombinant Rpfs', 4methylumbelliferyl-b-D-N, N9, N0-triacetylchitotrioside (4-MUF-3-NAG) (''Sigma'', Germany) was applied. 6 mM of 4-MUF-3-NAG was mixed with the proteins (1-10 mg/ml) in 100 mM citric acid-sodium citrate buffer, pH 6.0 with 0.5 mM MgSO 4 in total volume of 0.4 ml. A number of experiments were performed in the presence of NPT compounds, in concentration range of 0.5-10 mg/ml. After 3 hours of incubation at 37uC, 2 ml of 10 M NaOH was added and the samples were frozen and kept at 220uC. The kinetic analysis of Rpf activity and inhibition was performed using the range of concentrations of the substrate from 3 to 24 mM and the inhibitor (VII) from 0.5 to10 mg/ml. The intensity of fluorescence was detected by the RF-5301PC fluorimeter (''SHIMADZU'', Japan) using excitation wavelength of 364 nm and a read-out of 448 nm.

CD Spectra
CD analysis of Rpf proteins was performed in a buffer 220 mM phosphate, 50 mM sodium chloride, pH 7.0. The traces of imidazole in the protein were removed by extensive dialysis prior to the CD spectra recording. Measurements were performed using Jasco -720 automatic recording spectrophotometer; 1 mm path length quvette was used; slit width 1.5 nm; time constant 3 sec.
Experiment was performed at 20uC. Inhibitors were used as acetonitrile solution (1 mg/ml).

Fluorescence Quenching Measurements
The steady-state fluorescence excitation and emission spectra of DDUF Rpf B were recorded at room temperature using the RF-5301PC fluorimeter (''SHIMADZU'', Japan) in 0.361 cm path length quartz quvette with slit width 1.5 nm for excitation and 3 nm for emission channels. Proteins (40-50 mg/ml) were dissolved in 50 mM phosphate buffer, pH 7.5. The fluorescence emission spectra were measured under excitation wavelength at 280 nm. Fluorescence quenching measurements were analysed using the Stern-Volmer equation [26]: and the modified form of the equation for the heterogeneous type of quenching: where F 0 and F are the relative fluorescence intensities in the absence and presence of quencher, respectively, [Q]-concentration of quencher and K q is the Stern -Volmer quenching constant.

Enzymatic Activity of Rpf Is Inhibited by NPT Compounds
Hydrolytic enzymes play a key role for spore germination in many microorganisms [27,28]. Recently synthesized a family of nitrophenylthiocyanates (NPT), which strongly suppressed germination of fungal spores (unpublished results ) and therefore could be considered as promising inhibitors of cell wall hydrolases, including lytic transglycosylases, a class of enzymes structurally similar to Rpf which are known to be first activated during endospore germination [27] and chitinase involved in fungi spore germination [28]. Therefore, the effect of the influence the NPT compounds ( Figure 1) on the enzymatic and biological activities of Rpfs was studied. We first tested the effect of compounds on Rpf muralytic activity judging by the hydrolysis of the artificial fluorogenic substrate, 4-MUF-3-NAG, previously applied to analyze the activity of the recombinant Rpf of M. luteus [15]. The Rpf proteins are generally very unstable and inactivate soon after purification [15]. To solve this problem we used two different recombinant Rpf proteins that possess higher stability, solubility and retain activity for longer period of time. Firstly, a truncated form of M. luteus Rpf lacking the last 89 amino acid residues of the C-terminal part (Rpf Sm) and secondly, recently described truncated form of Rpf B ( DDUF RpfB) [14]. Both proteins were able to hydrolyze 4-MUF-3-NAG with the maximum specific activity at 7.663.3 nmol/mg?h and 2.561.4 nmol/mg?h for RpfSm and DDUF RpfB correspondingly. We found that four out of five of the initially tested compounds (I)-(IV) and (IX) inhibited muralytic activities of both proteins in the 1-7 mg/ml concentration range ( Table 1). The most potent compound for DDUF RpfB, (IX), was used for synthesis of derivative compounds (V-VIII, X). Apart of negatively charged compound (VIII), the derivative compounds displayed inhibitory activity on the Rpf-mediated MUF-3-NAG hydrolysis (VIII) ( Table 1). The Lineweaver-Burk plot revealed non-competitive inhibition of Rpf-Sm muralytic activity by the compound (VII) ( Figure S1).

The Influence of NPT on the Secondary Structure of Rpf
To exclude possible alterations of the Rpf secondary structure caused by NPT, CD measurement studies were undertaken using both Rpfs. Figure S2 A, B shows that the addition of the inhibitor (VII) did not produce significant changes in the CD spectra.

Interaction of NPT Compounds with Rpf (Fluorescence Quenching Analysis)
The existence of several tryptophanes and phenylalanines residues in the Rpf molecule enables one to analyse an interaction between NPTs and Rpf by fluorescence quenching. The addition of the highly efficient inhibitor of the enzymatic activity of Rpf, the compound (VII), to DDUF RpfB resulted in significant quenching of its auto-fluorescence (excitation 280 and emission 340) (Figure 2A). Application of the standard Stern-Volmer equation, (1) clearly showed a heterogeneous type of quenching with different accessibility of tryptophan residues for the inhibitor. In this case, we applied a modified form of the Stern-Volmer equation (2) where f a is an accessible fraction of fluorochromes. From equation (2), the accessible fraction of DDUF RpfB tryptophanes for compound (VII) (f a ) was close to 65%. These results were compared with quenching of DDUF RpfB by iodide which interacts with the exposed fluorochromes only [26]. Similar to the NPT compounds, iodide produced the heterogeneous type of quenching ( Figure 2B); however, the accessible fraction in this case was estimated close to 40%. Because the DDUF RpfB molecule contains 5 tryptophan residues (the major contributors in an autofluorescence under excitation used), 65% of accessibility to (VII) corresponds to three tryptophanes. 40% accessibility for iodide corresponds two exposed tryptophan residues localized on the molecule surface, indicating that the substance (VII) interacted with at least two exposed and one buried tryptophan. Note, that in case of inactive compound (VIII) the accessible fraction was similar to iodide (not shown).

Biological Activity of the NPT Compounds
The biological effect of the NTP compounds was studied in three different Rpf-producing bacteria, such as M. luteus, M. smegmatis and M. tuberculosis. M. luteus, containing the single rpf gene essential for growth [29], is an excellent model organism for study the inhibitors of Rpf. Seven out of ten tested compounds inhibited M. luteus growth in the NB liquid medium (MICs were between 1-10 mg/ml). Moreover, there was clear correlation between inhibition of the enzymatic activity of Rpf and bacteriostatic effects displayed by the compounds. For example, the compounds (II) and (VIII) did not influence the Rpf enzymatic activity and had no effect on M. luteus growth (Table 1).
However, the main known function of Rpfs is resuscitation of dormant or ''non-culturable'' cells [15,20]. Therefore, we tested the effect of NPT on resuscitation of dormant mycobacteria in two dormancy models, which we had previously developed.
In the first model the majority of M. smegmatis cells lose the ability to produce colonies on agar or grow in a liquid medium upon incubation in prolonged stationary phase [30]. Such ''nonculturable'' cells could be resuscitated in a liquid medium when Rpfs added exogenously or overexpressed from a high-copy number plasmid [20,21]. A Most Probable Number assay was applied to estimate the number of resuscitated cells. We consider resuscitation successful when the ratio MPN/CFU is equal or more than 1000. As follows from Figure 3 the addition of any NTP compound, (except (I), (II) and (VIII)), significantly suppressed resuscitation of M. smegmatis cells. The observed inhibitory effect was concentration dependent (Figure 4), and the most potent compounds (III, IV, VII, IX) were active at 0.1-1 mg/ml concentrations which did not inhibit growth of active cells of M. smegmatis ( not shown). In the second model ''non-culturable'' cells of M.tuberculosis resuscitate spontaneously, nevertheless this process is Rpf-dependent since the Rpf mutants were unable to resuscitate [6]. We found that compound (IX) and its derivatives (V-VII and X) as well as compound (IV) at concentration 10 mg/ml increased time which need for developing of visible growth in the MPN assay and decreased the final values of MPN in comparison with untreated resuscitating cells ( Figure 5, Table S1). However, one of the most potent compounds for inhibition of resuscitation of M.smegmatis (III) practically did not influence resuscitation of M.tuberculosis. Compounds (I,VIII) had no influence on the resuscitation kinetics (not shown). None of the compounds tested suppressed growth of active cells of M. tuberculosis at the same concentration (not shown).

Discussion
The structural studies of the conserved domain of Rpf could be considered as a ''compact hybrid'' of c-type lysozyme and lytic transglycosylases [13,14], two classes of enzymes cleaving 1, 4-bglycosidic bond between N-acetylmuramic acid and N-acetylglucosamine in peptidoglycan. Two inhibitors of lytic transglycosylases from Gram-negative bacteria (bulgecine and NAG-thiazoline) were reported, but they have never been tested against Grampositive bacteria [31,32]. Therefore, a novel class of NPT inhibitors of the muralytic activity of Rpf opens a new way in the study of cell-wall hydrolyzing enzymes from Gram-positive bacteria, in particular, mycobacteria.
Through our efforts related to the search of new antimicrobial compounds we observed that derivatives of ortho-nitrodialkyldithiocarbamate have potent antimycobacterial activity [33]. As a result of different chemical modifications of this basic structure we smegmatis ''non-culturable'' cells. Resuscitation was performed by the MPN assay (for details see ''Materials and methods''). Inhibitors were added at 1 mg/ml to some wells. Plates were incubated for 2 weeks at 37uC with shaking, 100 rpm. CFU of the culture before resuscitation was ,5 cells/ml. Bars represent (95%) confidence limits for MPN assay. This experiment was repeated six times using different starved cultures with similar results. One typical experiment is shown. doi:10.1371/journal.pone.0008174.g003 replaced the dialkyldithiocarbamate group by a thiocyanate group which has similar electron affinity. Using a facile synthesis of the target we obtained several ortho nitroarylthiocyanate derivatives (Figure 1), based on the reaction of nucleophylic substitution, the active chloroatom in nitroaryl moiety was substituted by thiocyanate ion.
We found that some of these compounds strongly suppressed germination of fungal spores (unpublished). Structural similarity between Rpf and cell wall lytic enzymes involved in spore germination (see above) allowed us to suggest that NPTs may influence on the activity of Rpf.
We first showed that most of candidate compounds indeed inhibit muralytic activity of Rpf in the non-competitive mode ( Figure S1). The measurements of the fluorescence quenching unequivocally prove a strong interaction between inhibitory NPTs and the internal region of Rpf, providing a molecular basis for inhibition of the enzymatic activity. Based on the published crystal structure of DDUF RpfB [14], we suggest that the compound (VII) is able to interact with the exposed Trp residues, 349, 285 and with one out of three buried Trp-297,316 and 352. Because buried Trp-316 and Trp-297 are localized closely, their accessibility to the quencher would be similar, therefore we could suggest that compound (VII) interacts not with these two residues but with Trp-352 which lies in the catalytic site of the molecule [13]. From this, interaction of the inhibitor (VII) with the catalytic site appears plausible. The absence of significant changes in the secondary structure of Rpf ( Figure S2) ruled out a possible non-specific inactivation of the enzyme, for example, protein aggregation, under NPT binding. Specificity of NPT as inhibitors of Rpf enzyme remains to be proved however, NPT did not influence the activity of some well-known enzymes as alkoholdehydrogenase  Table S2). The observed inhibitory effect of NPTs on growth of M. luteus is in a good accordance of Rpf essentiality in this bacterium. Remarkably, we found a good correlation between the effectiveness of different NPTs to inhibit the enzymatic activity of Rpf and to arrest growth of M. luteus cells (with the exception of compound (I)). The inhibitory concentration range for these compounds was also similar for both processes.
It was stated that Rpf proteins stimulate growth of cells at suboptimal or stressful conditions, but not of actively multiplying cells [24]. In particular, the deletion of rpf genes did not significantly impair the growth of the axenic cultures of M. tuberculosis, but exhibited a vital effect on their resuscitation in the liquid medium in vitro [5,6] or an activation of chronic infection in vivo [8]. According to this, NPT were active against resuscitation of ''non-culturable'' cells of both M. smegmatis and M.tuberculosis but to the less extent against the growth of viable cells, providing additional evidence for collective non-essentiality of rpf genes in M.tuberculosis [6]. Thus, on the basis of data obtained from several experimental models we may conclude that 2-nitrophenylthiocyanates represent a first group of inhibitors of the Rpf-mediated mycobacterium resuscitation.
Availability of derivatives of NPT with different effects against Rpf activities provides some insight in the mechanism of their action. So, the failure of the compound (VIII) to inhibit 4-MUF-3-NAG hydrolyzing activity, growth of M. luteus and resuscitation of M. smegmatis, most likely could be explained by presence the negative charge on the molecule. Indeed, in published crystal structure of DDUF RpfB, a negatively charged region in the catalytic site has been established [14]. This may produce a significant obstacle for interaction of the compound (VIII) with the catalytic site. Indeed, according to the fluorescence studies, (VIII) doesn't interact with the buried tryptophanes.
Despite a rather good correlation between anti-enzymatic and anti-resuscitation activities observed in this study, more experiments are required to confirm that Rpf proteins are, indeed, the targets for NPT in cells. The unique ability of NPT to suppress or at least delay resuscitation of ''non-culturable'' mycobacteria makes them attractive agents for specific target -non-replicating mycobacteria.
Because Rpf proteins are likely important for the establishing of chronic [7,8] and even probably acute [5] form of experimental (mice) tuberculosis, such compounds could be prospective for preventing of the latent tuberculosis activation or could be efficient against active TB. The task of the future is to study an activity of the NPT compounds in the animal experimental tuberculosis models. Figure S1 Inhibition of 4-MUF-3-NAG hydrolysis by RpfSm in the presence of (VII). 4-MUF-3-NAG hydrolysis by RpfSm (30 mg/ml) was performed according to ''Materials and methods'' without inhibitor (¤) or in the presence of (VII): -0.5 mg/ml; m -1 mg/ml; 6 -5 mg/ml; *-10 mg/ml. The Lineweaver-Burk plot Found at: doi:10.1371/journal.pone.0008174.s001 (4.81 MB TIF) Figure S2 Influence of compound (VII) on the secondary structure of Rpfs. CD spectra of DDUFRpf B (A) and Rpf Sm (B) in absence and presence of (VII) were obtained as described in the ''Materials and methods''. Concentration of Rpf Sm was 40 mg/ml and DDUFRpf B-60 mg/ml. Concentration of (VII) were 2 and 4 mg/ml. Inhibitor was dissolved in acetonitrile. The spectra were recorded from 195 to 260 nm and the average of three wavelength scans is presented. Found at: doi:10.1371/journal.pone.0008174.s002 (5.81 MB TIF) Table S1 Influence of NPT compounds on resuscitation of M. tuberculosis ''non-culturable'' cells obtained in vitro. Confidence  Table S2 Influence of compounds (III) and (VII) on activity of some enzymes t 1/2 -time is needed to achieve a 50% level of substrate conversion. Alcoholdehydrohenase(1.1.1.1) activity: ADH was dissolved in 50 mM phospahe buffer pH 7 at the concentration 10 mg/ml. The rate of the reaction was judged by transformation of NAD + (1 mM) into NADH+H + . As the substrate ethanol was used. Activity was measured by OD 340 . Laccase(1.10.3.2) activity: Laccase was dissolved in the 50 mM citrate-phosphate buffer, pH4.5 at concentration 9 mg/ml. Pyrocatechin was used at concentration 11 mg/ml. Activity was measured by OD 410 . Trypsin(3.4.21.4) activity: The enzyme at concentration 8.0 mg/ml was dissolved in 50 mM Tris-HCl buffer pH 8.0. Concentration of the substrate (N-CBz-Gly-Gly-Arg-b-naphthylamide -Sigma-Aldrich)-11 mg/ml. Registration of the kinetic curves was made fluorimetrically -excitation wavelength -330 nm; emission -420 nm. Found at: doi:10.1371/journal.pone.0008174.s004 (0.02 MB DOC)