• We are sorry, but NCBI web applications do not support your browser and may not function properly. More information
Logo of plosonePLoS OneView this ArticleSubmit to PLoSGet E-mail AlertsContact UsPublic Library of Science (PLoS)
PLoS ONE. 2008; 3(3): e1771.
Published online Mar 12, 2008. doi:  10.1371/journal.pone.0001771
PMCID: PMC2258413

Positive Feedback and Noise Activate the Stringent Response Regulator Rel in Mycobacteria

Martin Marinus, Academic Editor

Abstract

Phenotypic heterogeneity in an isogenic, microbial population enables a subset of the population to persist under stress. In mycobacteria, stresses like nutrient and oxygen deprivation activate the stress response pathway involving the two-component system MprAB and the sigma factor, SigE. SigE in turn activates the expression of the stringent response regulator, rel. The enzyme polyphosphate kinase 1 (PPK1) regulates this pathway by synthesizing polyphosphate required for the activation of MprB. The precise manner in which only a subpopulation of bacterial cells develops persistence, remains unknown. Rel is required for mycobacterial persistence. Here we show that the distribution of rel expression levels in a growing population of mycobacteria is bimodal with two distinct peaks corresponding to low (L) and high (H) expression states, and further establish that a positive feedback loop involving the mprAB operon along with stochastic gene expression are responsible for the phenotypic heterogeneity. Combining single cell analysis by flow cytometry with theoretical modeling, we observe that during growth, noise-driven transitions take a subpopulation of cells from the L to the H state within a “window of opportunity” in time preceding the stationary phase. It is these cells which adapt to nutrient depletion in the stationary phase via the stringent response. We find evidence of hysteresis in the expression of rel in response to changing concentrations of PPK1. Hysteresis promotes robustness in the maintenance of the induced state. Our results provide, for the first time, evidence that bistability and stochastic gene expression could be important for the development of “heterogeneity with an advantage” in mycobacteria and suggest strategies for tackling tuberculosis like targeting transitions from the low to the high rel expression state.

Introduction

Tuberculosis, responsible for more than a million deaths every year, constitutes a major health concern worldwide. The effectiveness of the killer disease stems from the fact that the mycobacterial pathogen M. tuberculosis, the causative agent of the disease, is remarkably resilient against various physiological and environmental stresses including that induced by drugs. The “successful” containment of tubercular infection either through the host immune response or by the application of drugs is beset by the problem of persistence [1]. When subjected to stress, a fraction of the bacterial population survives through adaptive response in host tissues (lesions) over long periods of time [2]. These survivors are reactivated once the host immune system is compromised giving rise to a new bout of infection. The failure to tackle persistent infection is a major stumbling block in efforts to control tuberculosis. Understanding the phenomenon of persistence is therefore one of the priorities in tuberculosis drug development programs.

On tubercular infection, granulomas form in the host tissues enclosing the infected cells. Mycobacteria encounter an altered physical environment in the restricted space of granulomas with a paucity of life-sustaining constituents like nutrients, oxygen and iron [3], [4]. The pathogens adapt to the stressed conditions and can survive over years in the so-called latent state. In vitro too, M. tuberculosis has been found to persist for years in the latent state characterized by the absence of active replication and metabolism [5]. Researchers have therefore attempted to develop models simulating conditions believed to be encountered by mycobacteria within the granuloma. One such model is the adaptation to nutrient-depleted stationary phase [6]. The processes leading to the slowdown of replicative and metabolic activity constitute the stringent response. In mycobacteria, the expression of rel initiates the stringent response which leads to persistence. The importance of Rel arises from the fact that it synthesizes the stringent response regulator ppGpp (guanosine tetraphosphate) [7]. Rel is essential for the long-term survival of M. tuberculosis under starvation [8] and for prolonged life of the bacilli in mice [9], suggesting that it is linked to persistence.

Persistence is a general phenomenon observed in microbial populations subjected to stress, e.g., when kept in fluctuating environments [10]. It is often linked to phenotypic heterogeneity arising in a genetically identical bacterial cell population with persisters forming a subset of the total cell population. Persistence against antibiotic treatment has been investigated in E. coli at the single cell level using microfluidic devices [10]. The experimental results suggest that stochastic transitions between normally growing cells and persister cells with reduced growth rates create phenotypic heterogeneity in bacterial populations even before the application of drugs. The preexisting heterogeneity may be advantageous for a bacterial population as it enables a fraction of the population to better cope with unfavorable circumstances. Phenotypic heterogeneity is often an outcome of gene expression dynamics involving positive feedback [11][13]. Two alternative scenarios have been proposed in this context. In one, positive feedback gives rise to multistability, i.e., the existence of more than one stable state for the same parameter values. The case most well-explored is that of bistability which gives rise to two stable expression states: low (L) and high (H). A transition from the L to the H state occurs when the magnitude of an appropriate parameter, say, inducer amount, exceeds a threshold value. Gene expression noise, i.e., fluctuations in expression levels also play a significant role in driving the transitions between the stable states. In this scenario, phenotypic heterogeneity implies the coexistence of two distinct subpopulations in L and H states. A recent experiment [14] on competence development in B. subtilis established the role of noise in driving the phenotypic transitions from the non-competent to the competent state. The network of regulatory interactions controlling competence development contains a core module, an autostimulatory positive feedback loop in which ComK proteins, synthesized from the comK gene, promote their own production. The non-competent and competent states correspond to low and high ComK levels. In the alternative scenario leading to positive feedback-based phenotypic heterogeneity, there is one stable expression state, mostly, the low expression state. The high expression state is unstable so that noise-driven activation to this state is followed by a relaxation to the low expression state. Competence development in B. subtilis has also been analysed in this alternative scenario [15] with the core circuit containing both a positive and a negative feedback loop. Evidence for a single stable expression state and transient activation to an alternative expression state has been obtained in some other cases [16].

Recent experiments provide knowledge of the stress signaling pathway in mycobacteria linking polyphosphate (poly P), the two-component response regulator MprAB, the alternate sigma factor SigE and Rel [17]. Figure 1 shows a sketch of the important components of the pathway. mprA and mprB encode the histidine kinase sensor MprB and its partner the cytoplasmic response regulator MprA respectively. The protein pair responds to environmental stimuli by initiating adaptive transcriptional programs. Polyphosphate kinase 1 (PPK1) catalyses the synthesis of polyphosphate (poly P) which is a linear polymer composed of several orthophosphate residues. MprB autophosphorylates itself with poly P serving as the phosphate donor [17].The phosphorylated MprB-P phosphorylates MprA via phosphotransfer reactions. There is also evidence that MprB-P functions as a MprA-P (phosphorylated MprA) phosphatase [18]. MprA-P binds the promoter of the mprAB operon [19] to initiate transcription. A positive feedback loop is functional in the network of interactions as the production of MprA brings about further MprA synthesis. The mprAB operon has a basal level of gene expression [18], [19] irrespective of the operation of the positive feedback loop. Once the mprAB operon is activated, MprA-P regulates the transcription of the alternate sigma factor gene Sig E, which in turn controls the transcription of rel.

Figure 1
Schematic diagram of MprAB-SigE-mediated rel transcription.

We hypothesized that positive feedback and stochastic gene expression likely play a role in the development of persistence in mycobacteria. To test this hypothesis, we studied the dynamics of rel expression in mycobacteria grown up to stationary phase, a model where nutrient depletion serves as the source of stress. We combined mathematical modeling with experiments to establish that bistability along with gene expression noise give rise to phenotypic heterogeneity in terms of the expression of rel. Our results indicate that noise influences cell fate under stringency in mycobacteria. By regulated expression of PPK1 from a tetracycline-inducible promoter in a ppk1 knockout mutant, we further demonstrated hysteresis in rel expression.

Results

Mathematical modeling of the mprAB-driven stress signaling pathway

The positive autoregulation of the master regulator mprAB (Figure 1) draws attention to the recently appreciated role of positive feedback loops in certain bacteria giving rise to bistability [11]. We constructed a mathematical model to study the dynamics of the above signaling pathway. The reaction scheme and the calculations are reported in the Supporting Information (Text S1). The theoretical study predicted the existence of bistability (Figures S1A–C) and provided the motivation to test the prediction in an actual experiment. In a deterministic scenario, all the cells in a population are in the same steady state if exposed to the same environment. To explain heterogeneity in a genetically identical cell population, a stochastic (probabilistic) description of cellular events is necessary. Gene expression involves biochemical events which are inherently probabilistic [20], [21]. The uncertainty introduces fluctuations (noise) around mean expression levels so that the single protein level of the deterministic model broadens into a distribution of levels. In the case of bistable gene expression, the distribution of protein levels in a population of cells is bimodal with two distinct peaks.

Bimodal rel Expression in M. smegmatis

Considering that persistent mycobacteria in lung lesions are nutritionally starved [8], the issue of persistence has been addressed in terms of how mycobacteria adapt to stress in the form of nutrient-depletion. The stringent response is a broad transcriptional program in prokaryotes that becomes operative under stress in order to enable survival of at least a fraction of the cell population. Key elements of the stringent response and the ability to survive over long periods of time under stress are shared between M. tuberculosis and M. smegmatis [22]. The protein Rel plays a central role in this stress response program. We therefore chose to study the dynamics of rel transcription in individual cells of M. smegmatis grown in nutrient medium up to stationary phase, with nutrient depletion serving as the source of stress. The experimental signature of bistability lies in the coexistence of two subpopulations. We employed flow cytometry to monitor the dynamics of green fluorescent protein (GFP) expression in M. smegmatis harboring the rel promoter fused to gfp [17] as a function of time. Initially, the fraction of cells with “low” GFP expression (L) is high (Figure 2). The fraction of cell population in the “high” GFP expression state (H) increases as a function of time due to transitions from the L to the H state. The coexistence of H and L cells in the population was also observed by fluorescence microscopy (Figure S2). The distribution of GFP-expressing cells (Figure 2) is bimodal indicating the existence of two distinct subpopulations. In the stationary phase [i.e. around 36 h (Figure S3)], the majority of cells (~ 70%) is in the H state. We term the GFP level in the L state as the basal level. Plots of the mean basal level (fluorescence intensity) (Figure 3A) and the fractions of cells in the H state (Figure 3B) against time could be fitted with sigmoids. The presence of two distinct subpopulations in the experiment confirmed the theoretical prediction of bistability. If clumping of mycobacterial cells and cell-to-cell variation of plasmid copy number were responsible for the observed bimodal fluorescence intensity distribution in Figure 2, bimodality would also likely be observed in the case of GFP expression being driven by a constitutve promoter. As a control, we therefore chose to analyze GFP expression driven by the constitutive hsp60 promoter as a function of time. A single bright population was observed at different times of growth (Figure S4). The unimodal, rather than bimodal distribution ruled out the possibility that the bimodality of rel promoter-driven GFP expression was artifactual. Our earlier observations have shown that mprAB expression increases with time of growth [17] and that mprAB regulates rel expression through its ability to drive the transcription of sigE. In order to establish that positive feedback is responsible for the bimodal distribution of GFP expression, we analyzed the time course of rel-driven GFP expression in a M. smegmatis knock-out mutant in which the chromosomal copy of sigE was disrupted (i.e. a situation in which the positive feedback loop activating mprAB expression, was decoupled from rel expression). In this strain, only a negligible fraction of the cell population was in the H state at any phase of growth (Figure 4A), supporting the view that positive feedback is essential for the bimodal distribution of GFP expression. The promoter of rel contains binding sites for SigA and SigE (Figure 4B). Mutation of the SigE binding site resulted in a negligible fraction of the cells being present in the H state (Figure 4C). On the contrary, we observed bimodality (Figure 4D) when the SigA binding site was mutated. Taken together, these results confirmed the role of MprAB/SigE-mediated positive feedback in bimodal rel expression in mycobacteria.

Figure 2
Time course of rel-GFP expression.
Figure 3
Analysis of the time course of rel expression.
Figure 4
Time course of rel-GFP expression in M. smegmatis.

Gene Expression Noise Drives Stochastic Transitions

We next probed the role of gene expression noise in effecting the switch from the L to the H state. A bistable system in the L state can undergo a transition to the H state if the basal level crosses a threshold value [SI]. We analyzed the rate of transition from the L to the H state as a function of time (Figure 3C). The transition rate initially increases with time, reaches a maximum (at around 20 h) and falls to zero before the cell population enters the stationary phase, suggesting that transition to the H state takes place within a limited “window of opportunity” in time. The inset of Figure 3C shows how the basal expression rate changes as a function of time. Flow cytometry measurements provided an estimate of the coefficient of variation (CV), a quantifier of noise (CV = standard deviation/mean), associated with the gene expression level. A plot of CV of the basal expression level of rel as a function of time (Figure 3C) showed a similar variation as the transition rate, with the maxima in both the curves occurring around the same time. A steep increase in the CV of the basal expression level is accompanied by a steep increase in the rate of transition to the high GFP expression state. The basal expression level has a low value and a comparatively slower increase during the same time period. Since CV is the ratio of standard deviation and mean, it appears that increasing basal expression fluctuations are predominantly responsible for the increasing rate of transition to the high expression state. To achieve a specific fraction of cells in the H state, the basal GFP level in these cells should cross a threshold value [SI]. This is possible in two ways: with low mean basal level and a large standard deviation or a high mean basal level with a low standard deviation. Figure 3 shows that the first strategy is adopted in this case. The choice could be dictated by the metabolic cost of sustaining a high mean basal level in the cells.

Hysteresis in rel Expression

In order to obtain further definitive evidence of bistability in rel expression, we attempted to detect hysteresis by analyzing the “history-dependent” response of the system. To demonstrate hysteresis in our system, we took advantage of the ppk1 knockout mutant (PPK-KO) of M. smegmatis [17] which did not show rel expression. We reasoned that regulated expression of PPK1 would serve to tune the positive feedback by virtue of the ability of the enzyme to synthesize poly P, the phosphate donor for phosphorylation of MprA. We therefore introduced the ppk1 gene under the control of the tet promoter [23] in PPK-KO harboring the rel-gfp plasmid, and confirmed tetracycline-inducible rel expression by fluorescence microscopy (Figure 5). The generic inducer-response curve predicted theoretically (Figure S1C) provided evidence of bistability. For the experimental analysis of hysteresis, we grew PPK-KO carrying the tetracycline-inducible [23] ppk1 and rel-gfp in medium with increasing concentrations of tetracycline (inducer) and analyzed the distribution of cells expressing GFP by flow cytometry in the stationary phase (steady state) (Figure 6A, going up). Similarly, we obtained the branch (Figure 6A, coming down) for decreasing concentrations of tetracycline with the mean GFP expression measured in the stationary phase. The standard error of each data point is not shown because of its small magnitude. We observed two distinct alternative states within a particular range of inducer concentrations depending on how the concentrations were changed. The distinct branches in Figure 6 confirm the existence of hysteresis supporting our prediction of bistability in the system. We analyzed the levels of PPK1 by Western blotting (Figure S5A,B) as well as levels of poly P (Figure S5C) in the “going up” and “coming down” experiments. Hysteresis was not observed in relation to PPK1 or poly P. Thus, hysteresis in rel expression levels could not be attributed to differences in levels of PPK1 or poly P in the two sets of experiments. We confirmed the critical role of PPK1 in rel expression by carrying out the same experiments (as a control) in PPK-KO harboring a tetracycline-inducible kinase-dead mutant of ppk1. No induction of rel expression was observed when bacteria were grown in the presence of tetracycline (data not shown) confirming the role of the enzymatic activity of PPK1 in the induction of rel expression. The set of GFP distributions as a function of the inducer concentration are shown in Figure 7. Stochastic simulation of the dynamical model (Figure 1) based on the well-known Gillespie algorithm [24] (Text S1) reproduces the qualitative features of the distributions shown in Figure 2 (Figure S6) and the plots in Figure 3C (Figure S7).

Figure 5
Fluorescence microscopy of tetracycline (tet)-inducible GFP expression.
Figure 6
Hysteresis in rel expression.
Figure 7
GFP distributions as a function of tetracycline inducer concentration.

Discussion

The phenomenon of persistence has been investigated in a host of microorganisms but the molecular mechanism which activates the switch to persistence in a cell is little understood in most cases. Persistence can develop in response to a variety of stresses some of which, like nutrient and oxygen deprivation, bring about the stringent response in bacterial systems. Rel is widely acknowledged as a key player enabling mycobacteria to persist under conditions of stress. In this paper, we identified the triggering mechanism of the switch to high rel expression in a growing population of mycobacteria with nutrient depletion serving as the source of stress. Summarising our present findings, we observe that rel expression is bistable and a combination of positive feedback along with gene expression noise select a subset of cells to be in the high rel expression state. Our results suggest that there is a temporal window during which fluctuations in the basal expression level drive the transitions from the low (L) to the high (H) expression state. Similar experimental observations have been made on competence development in B. subtilis [14], [25] in which phenotypic heterogeneity is linked to the coexistence of competent and non-competent cells.

Recent studies have pinpointed the contributions of positive feedback and gene expression noise towards creating phenotypic heterogeneity in B. subtilis [11], [12], [14], [15], [25], [26]. Two different mechanisms have been proposed to explain competence development in a fraction of cells: the case of bistability with two stable gene expression states [11], [26] and excitability [15] with one stable gene expression state. In our experiments on mycobacteria, we find evidence of bistability which gives rise to a bimodal distribution in rel expression in the stationary phase. We also find experimental evidence of another important feature of bistability, namely, hysteresis. Hysteresis is known to promote robustness in the maintenance of the induced state [13], [27]. In the case of excitability, the induced state is transient. In a bistable system, gene expression noise can give rise to transitions between the two stable states. In our experiments, stochastic switching is predominantly from the low to the high expression state with the latter being quite stable.

Cells in the H state in the mycobacterial population are generated in the exponential phase itself hinting at pre-existing heterogeneity in the cell populations. Such heterogeneity has been suggested [10] to be a strategy of “hedging the bet” adopted by microorganisms to be better prepared for coping with changing environmental conditions. Consistent with our view that positive feedback at the level of mprAB generates phenotypic heterogeneity, we observed that sigE-GFP expression is also bimodal (Figure S8).

One of our major findings relates to the observation (Figure 3C) that the rate of transition from the low to the high expression state is maximum close to the time point at which the coefficient of variation (CV) of the basal expression level attains the largest value. This result appears to suggest that transitions to the high expression state are aided by basal level noise. Mamaar et al. [14] studied competence development in B. subtilis and suggested that intrinsic noise associated with comK mRNA production and degradation are possibly major sources of variation in ComK protein levels. They tested the hypothesis by experimentally reducing the noise. This was achieved through increasing the rate of comK gene transcription and simultaneously reducing the translation rate by an equal amount so that the mean protein level remains the same. In this experiment, the reduction in noise led to fewer transitions to the competent state since basal level fluctuations required to trigger the positive feedback loop were lower in magnitude. A similar conclusion was reached in an earlier theoretical study [26] in which the amount of noise was changed by varying the rate constants for gene activation and deactivation keeping the mean expression level the same. Recent modeling and experimental results appear to reinforce the view that the combined effect of positive feedback and noise provide a universal mechanism for generating phenotypic heterogeneity in cell populations [11], [12], [14][16], [25], [26], [28].

As has been recently pointed out [29], the network of regulatory interactions controlling the stringent response likely differs in detail from that in E. coli. Elevated levels of (p)ppGpp favor the accumulation of poly P in E. coli [30]. On the other hand, in mycobacteria, poly P is essential for activating rel expression at least under a certain set of conditions [17] and subsequent biosynthesis of (p)ppGpp. Though the importance of poly P and the regulatory link between sigE and rel is now well established [17], a number of questions remain unanswered. These include how ppk1 expression is regulated, whether mprAB preferentially utilizes poly P and whether only ppk1 transcription is responsible for poly P accumulation [29]. Considering the role of rel in persistence, it would also be of great interest to analyze whether the high-rel population is antibiotic-tolerant and represent persistors. While the present study does not address these questions, our characterization of the high rel state and a systems level analysis of how mycobacteria attain this state offers important clues regarding possible drug targets. One aim of drug therapy could be the inhibition of the switching transition from the low to the high rel expression state thus reducing the chances of mycobacterial survival via the stringent response.

Materials and Methods

Strains

M. smegmatis mc2155 [31] was grown in Middle Brook 7H9 medium supplemented with 2% glucose and 0.05% Tween 20.

Construction of plasmids for fluorescence measurements

The rel promoter (−610 to +1 relative to the translational start site) fused to gfp in pFPV27 has been described [17]. Mutants of the rel promoter were generated by overlap extension PCR. The primers used are depicted in Supplementary Table S1. The initial rounds of PCR were carried out using primer pairs a and b, and c and d. The products of each PCR were purified and used as templates for the second round of PCR using the primers a and d. The resulting plasmid carying the wild type or mutant rel promoter was electroporated into wild-type M. smegmatis mc2155, or the isogenic strain inactivated in the ppk1 gene (PPK-KO) [17], or PPK-KO harboring the ppk1 gene under the control of a tetracycline-inducible promoter or in the sigE-inactivated (sigE KO) strain RH243, a gift from Prof. R.N. Husson [32]. As a positive control the constitutive hsp promoter was excised from pCKB115 [33] and fused to gfp in the replicative promoter-less gfp vector pFPV27 [34]

The sigE promoter[32] was amplified from the genomic DNA of M. smegmatis using the sense and antisense primers

  • 5′-TAAGGTACCGCGGGATACAGTTCCCCATGC-3′ [KpnI site in bold]
  • 5′-TAGGATCCTTCAACATGCTAAACGCATGT-3′ [BamHI site in bold]

respectively and cloned into the promoter-less replicative gfp vector pFPV27 [33] using asymmetric KpnI and BamHI sites. The resulting plasmid was electroporated into wild-type M. smegmatis mc2155, the isogenic PPK-KO and the tet-ppk1-complemented strain.

Expression of ppk1 under a tetracycline-inducible promoter

Expression of ppk1 under a tetracycline-inducible promoter was achieved by constructing an integrating vector containing a hygromycin-resistance cassette along with a positive-selection L5 integrase cassette. ppk1 was first amplified from genomic DNA using the sense and antisense primers 5′-TAACATATGATAAGCAATGATCGCAAG-3′ [NdeI site in bold] and 5′-TTAAAGCTTCAGGGGCTGCGGTGCCGTT-3′ [HindIII site in bold] respectively and cloned between same sites of pMIND [23] under the control of the tet promoter. The ppk1 gene along with the tet promoter was excised by digesting with KpnI and HindIII and cloned between the same sites in pUC19 to generate pTC-PPK. A 3.7 kb Hyg-integrase cassette from pUC-HY-INT [35] was cloned at the HindIII site of pTC-PPK to generate the integrating construct pTC-PPKINT which was electroporated into PPK-KO. Hygromycin-resistant colonies were selected and analyzed by PCR to confirm the presence an integrated copy of the wild-type ppk1. The kinase-dead ppk1 carrying mutations of two histidine residues (required for autophosphorylation) to alanine [17] [ppk1-KD] was amplified by PCR from a suitable construct essentially as described by Sureka et al. [17] using the above primers and integrated into M. smegmatis mc2155 as described above.

FACS analysis

M. smegmatis cells were grown for different periods of time, harvested, washed twice and resuspended in PBS. Fluorescent bacteria were analyzed on a FACS Caliber (BD Biosciences) flow cytometer. All data modes were set to log, and the forward scatter detector level was set to E-1. The fluorescence intensity of 20,000 ungated events was measured in FL-1 at a detector sensitivity of 780. A side scatter threshold was set to gate out inappropriate heterogeneities. It is difficult to analyze single mycobacteria by FACS because of their tendency to clump. Careful gating procedures were adopted to minimize the effect of clumping. The data files were analyzed using CellQuest Pro (BD Biosciences) and WINMIDI. The flow cytometry data is represented in histogram plots where the x-axis is a measure of fluorescence intensity and the y-axis represents the number of events.

Fluorescence microscopy

Cells were fixed by incubation for 15 minutes at room temperature followed by 45 minutes on ice in 2.5% (v/v) paraformaldehyde, 0.04% (v/v) glutaraldehyde, 30 mM sodium phosphate (pH 7.5). The cells were transferred to slides, washed with PBS, air-dried, dipped in methanol (−20°C) for 5 min and then in acetone (−20°C) for 30 s and allowed to dry. Brightfield and fluorescence images were taken using a 100× oil immersion objective on a Zeiss Axioimager A1 microscope equipped with a cooled CCD camera.

Supporting Information

Figure S1

Bistability and hysteresis in the deterministic model. Steady state concentrations of phosphorylated MprA versus basal production rate s (Eq. 2) (A) and the parameter α (Eq. 19) (B). A generic stimulus-response curve in the steady state. The points u1 and u2 denote the upper and lower bifurcation points respectively at which transitions occur from one branch to the other.

(6.62 MB TIF)

Figure S2

Fluorescence microscopy of rel-GFP expression. M. smegmatis harboring rel-GFP was grown as described in Fig. 2 and expression of GFP was visualized by fluorescence microscopy. Left, middle and right micrographs : phase contrast, fluorescence and merge respectively. Top panel: Rel-High (44 h); Bottom panel: Rel-Low (12 h)

(5.64 MB TIF)

Figure S3

Growth kinetics of M. smegmatis mc2155. Cells were grown for different periods of time as indicated and the growth was monitored by recording the absorbance at 600 nm spectrophotometrically.

(2.94 MB TIF)

Figure S4

Time course of hsp-GFP expression. M. smegmatis harboring hsp-GFP was grown for different periods of time and the expression of GFP was monitored by flow cytometry as described in Fig. 2. Representative histograms obtained after 8 and 44 h of growth are shown above. At all time points, a single peak (as shown above) was observed.

(6.13 MB TIF)

Figure S5

A. Western blots of tetracycline-inducible PPK1 in PPK-KO. PPK-KO harboring the integrated tet-inducible ppk1 and the construct of rel-gfp was grown upto stationary phase in the presence of different concentrations of tetracycline (inducer). Lysates were analyzed by SDS-PAGE and Western blotting using anti-PPK1. Blots were reprobed with anti-PBP3 to ensure equal loading. B. Densitometric analysis of Western blots (panel A) of PPK1. C. Cells were grown as described under panel A, and poly P levels were measured as described in Ref. 1.

(5.90 MB TIF)

Figure S6

GFP distributions obtained through stochastic simulation via the Gillespie algorithm. 5, 18, 25 and 50 represent time in h.

(3.84 MB TIF)

Figure S7

Rate of transition from the L to the H state and the CV of the low expression state versus time obtained through stochastic simulation based on the Gillespie algorithm.

(3.44 MB TIF)

Figure S8

Time course of sigE-GFP expression. M. smegmatis expressing the sigE-GFP construct was grown for different periods of time (0, 18, 48 h) as indicated and the expression of GFP was monitored by flow cytometry. The figure provides evidence of bimodal sigE expression.

(3.40 MB TIF)

Text S1

Mathematical models

(0.14 MB DOC)

Table S1

Primers used for mutation of the rel promoter

(0.02 MB DOC)

Acknowledgments

We thank Dr. R.N. Husson for the gift of the sigE mutant of M. smegmatis, and Drs. Richard Stokes, Brian Robertson and Lalita Ramakrishnan for the plasmids pUC-HY-INT, pMIND and pFPV27 respectively.

Footnotes

Competing Interests: The authors have declared that no competing interests exist.

Funding: B.G. was supported by a fellowship from the Council of Scientific and Industrial Research, Government of India. This work was supported in part by a grant from the Department of Biotechnology, Government of India.

References

1. McCune RM, Feldman FM, Lambert HP, McDermont W. Microbial persistence. II. Characteristics of the sterile state of tubercle bacilli. J Exp Med. 1966;123:445–468. [PMC free article] [PubMed]
2. Hingley-Wilson SM, Sambandamurthy VK, Jacobs WR., Jr Survival perspectives from the world's most successful pathogen, Mycobacterium tuberculosis. Nat Immunol. 2003;4:949–955. [PubMed]
3. Bishai W. Lipid lunch for persistent pathogen. Nature. 2000;406:683–685. [PubMed]
4. De Voss JJ, Rutter K, Schroeder BG, Barry CE., III Iron acquisition and metabolism by mycobacteria. J Bacteriol. 1999;181:4443–4451. [PMC free article] [PubMed]
5. Nyka W. Studies on the effect of starvation on mycobacteria. Infect Immun. 1974;9:843–850. [PMC free article] [PubMed]
6. Smeulders MJ, Keer J, Speight RA, Williams HD. Adaptation of Mycobacterium smegmatis to stationary phase. J Bacteriol. 1999;181:270–283. [PMC free article] [PubMed]
7. Braeken K, Moris M, Daniels R, Vanderleyden J, Michiels J. New horizons for (p)ppGpp in bacterial and plant physiology. Trends Microbiol. 2006;14:45–54. [PubMed]
8. Primm TP, Andersen SJ, Mizrahi V, Avarbock D, Rubin H, et al. The stringent response of Mycobacterium tuberculosis is required for long-term survival. J Bacteriol. 2000;182:4889–4898. [PMC free article] [PubMed]
9. Dahl JL, Kraus CN, Boshoff HIM, Doan B, Foley K, et al. The role of RelMtb-mediated adaptation to stationary phase in long-term persistence of Mycobacterium tuberculosis in mice. Proc Natl Acad Sci USA. 2003;100:10026–10031. [PMC free article] [PubMed]
10. Balaban NQ, Merrin J, Chait R, Kowalik L, Leibler S. Bacterial persistence as a phenotypic switch. Science. 2004;305:1622–1625. [PubMed]
11. Dubnau D, Losick R. Bistability in bacteria. Mol Microbiol. 2006;61:564–572. [PubMed]
12. Smits WK, Kuipers OP, Veening J-W. Phenotypic variation in bacteria: the role of feedback regulation. Nat Rev Microbiol. 2006;4:259–271. [PubMed]
13. Ferrell JE., Jr Self-perpetuating states in signal transduction: popsitive feedback, double-negative feedback and bistability. Curr Opin Cell Biol. 2002;14:140–148. [PubMed]
14. Maamar H, Raj A, Dubnau D. Noise in gene expression determines cell fate in Bacillus subtilis. Science. 2007;317:526–529. [PMC free article] [PubMed]
15. Süel GM, Kulkarni RP, Dworkin J, Garcia-Ojalvo J, Elowitz MB. Tunability and noise dependence in differentiation dynamics. Science. 2007;315:1716–1719. [PubMed]
16. Weinberger LS, Burnett JC, Toettcher JE, Arkin AP, Schaffer DV. Stochastic gene expression in a lentiviral positive-feedback loop: HIV-1 Tat fluctuations drive phenotypic diversity. Cell. 2005;122:169–182. [PubMed]
17. Sureka K, Dey S, Datta P, Singh AK, Dasgupta A, et al. Polyphosphate kinase is involved in stress-induced mprAB-sigE-rel signaling in mycobacteria. Mol Microbiol. 2007;65:261–276. [PubMed]
18. Zahrt TC, Wozniak C, Jones D, Trevett A. Functional analysis of the Mycobacterium tuberculosis MprAB two-component signal transduction system. Infect Immun. 2003;71:6962–6870. [PMC free article] [PubMed]
19. He H, Zahrt TC. Identification and characterization of a regulatory sequence recognized by Mycobacterium tuberculosis persistence regulator MprA. J Bacteriol. 2005;187:202–212. [PMC free article] [PubMed]
20. Kaern M, Elston TC, Blake WJ, Collins JJ. Stochasticity in gene expression: from theories to phenotypes. Nat Rev Genet. 2005;6:451–464. [PubMed]
21. Maheshri N, O'Shea EK. Living with noisy genes: how cells function reliably with inherent variability in gene expression. Annu Rev Biophys Biomol Struct. 2007;36:413–434. [PubMed]
22. Ojha AK, Mukherjee TK, Chatterji D. High intracellular level of guanosine tetraphosphate in Mycobacterium smegmatis changes the morphology of the bacterium. Infect Immun. 2000;68:4084–4091. [PMC free article] [PubMed]
23. Blokpoel MC, Murphy HN, O'Toole R, Wiles S, Runn ES, et al. Tetracycline-inducible gene regulation in mycobacteria. Nucleic Acids Res. 2005;33:e22. [PMC free article] [PubMed]
24. Gillespie DT. Exact stochastic simulation of coupled chemical reactions. J Phys Chem. 1977;81:2340–2361.
25. Leisner M, Stingl K, Rädler JO, Maier B. Basal expression rate of comK sets a ‘switching-window’ into the K-state of Bacillus subtilis. Mol Microbiol. 2007;63:1806–1816. [PubMed]
26. Karmakar R, Bose I. Positive feedback, stochasticity and genetic competence. Phys Biol. 2007;4:29–37. [PubMed]
27. Pomerening JR, Sontag ED, Ferrell JE., Jr Building a cell cycle oscillator: hysteresis and bistability in the activation of Cdc2. Nature Cell Biol. 2003;5:346–351. [PubMed]
28. Kashiwagi A, Urabe I, Kaneko K, Yomo T. Adaptive response of a gene network to environmental changes by fitness-induced attractor selection. PLoS ONE. 2006;1:e49. [PMC free article] [PubMed]
29. Manganelli R. Polyphosphate and stress response in mycobacteria. Mol Microbiol. 2007;65:258–260. [PubMed]
30. Rao NN, Liu S, Kornberg A. Inorganic polyphosphate in Escherichia coli: the phosphate regulon and the stringent response. J Bacteriol. 1998;180:2186–2193. [PMC free article] [PubMed]
31. Snapper SB, Melton RE, Mustafa S, Kieser T, Jacobs WR., Jr Isolation and characterization of efficient plasmid transformation mutants of Mycobacterium smegmatis. Mol Microbiol. 1990;4:1911–1919. [PubMed]
32. Wu Q, Kong D, Lam K, Husson RN. A mycobacterial extracytoplasmic function sigma factor involved in survival following stress. J Bacteriol. 2005;179:2922–2929. [PMC free article] [PubMed]
33. Choudhuri BS, Bhakta S, Barik R, Basu J, Kundu M, Chakrabarti P. Overexpression and functional characterization of an ABC (ATP-binding cassette) transporter encoded by the genes drrA and drrB of Mycobacterium tuberculosis. Biochem J. 2002;367:279–285. [PMC free article] [PubMed]
34. Valdivia RH, Hromockyj AE, Monack D, Ramakrishnan L, Falkow S. Applications for green fluorescent protein (GFP) in the study of host-pathogen interactions. Gene. 1996;173:47–52. [PubMed]
35. Mahenthiralingam E, Marklund BI, Brooks LA, Smith DA, Bancroft GJ, et al. Site-directed mutagenesis of the 19-kilodalton lipoprotein antigen reveals no essential role for the protein in the growth and virulence of Mycobacterium intracellulare. Infect Immun. 1998;66:3626–3634. [PMC free article] [PubMed]

Articles from PLoS ONE are provided here courtesy of Public Library of Science
PubReader format: click here to try

Formats:

Related citations in PubMed

See reviews...See all...

Cited by other articles in PMC

See all...

Links

Recent Activity

Your browsing activity is empty.

Activity recording is turned off.

Turn recording back on

See more...