• We are sorry, but NCBI web applications do not support your browser and may not function properly. More information
Logo of nihpaAbout Author manuscriptsSubmit a manuscriptNIH Public Access; Author Manuscript; Accepted for publication in peer reviewed journal;
Nat Chem Biol. Author manuscript; available in PMC Nov 1, 2012.
Published in final edited form as:
PMCID: PMC3329571
NIHMSID: NIHMS345807

Signaling-Mediated Bacterial Persister Formation

Abstract

Here we show that bacterial communication through indole signaling induces persistence, a phenomenon in which a subset of an isogenic bacterial population tolerates antibiotic treatment. We monitor indole-induced persister formation using microfluidics, and identify the role of oxidative stress and phage-shock pathways in this phenomenon. We propose a model in which indole signaling “inoculates” a bacterial sub-population against antibiotics by activating stress responses, leading to persister formation.

Bacterial persisters are dormant cells1 within an isogenic bacterial population that tolerate antibiotic treatment2 and have been implicated in chronic and recurrent infections35. Persister formation occurs heterogeneously within an antibiotic-susceptible population, predominantly at the transition to stationary phase6,7. Though numerous genes have been associated with persistence810, a complete understanding of persister formation remains elusive.

There is increasing evidence that bacterial communication via chemical signaling plays a role in establishing population heterogeneity11. The bacterial stationary phase signaling molecule indole12,13 is produced14,15 (Supplementary Fig. 1) under conditions known to increase persistence. Indole is actively transported by Mtr16 but may enter the cell by other means17 (see Supplementary Results). Indole signaling affects membrane stress and oxidative stress responses18,19 and has been shown to increase antibiotic resistance (MIC) via multi-drug transport14,19,20. Given the above, we hypothesized that indole signaling may trigger the formation of bacterial persisters.

To test this hypothesis, we incubated exponential phase cultures of wild-type E. coli in M9CG medium with physiological levels of indole (500 μM) for one hour, then treated with high concentrations of bactericidal antibiotics (see Supplementary Methods). As expected, wild-type E. coli showed different levels of persistence to different antibiotics7. Further, we found that incubation with indole increased persister levels to each of the three antibiotics tested by at least an order of magnitude (Supplementary Fig. 2), indicating that the protective effects of indole are not specific to a single antibiotic mode of action and suggesting that indole induces the transition to a persistent state (Supplementary Results, Supplementary Fig. 3 and 4).

To further explore the role of indole in persister formation, we tested the indole-induced persistence of a genetic knockout strain (ΔtnaA) unable to catabolize tryptophan to indole. Stationary phase conditions were used to maximize persister levels and indole concentration in the growth medium. As expected, we found no significant difference between survival of the wild-type and ΔtnaA strains in tryptophan-free M9CG medium (Fig. 1a, Supplementary Table 1), since wild-type E. coli produce very little indole when grown in this medium (Supplementary Fig. 5). By contrast, in rich Luria-Bertani (LB) medium, high levels of extracellular indole were present in wild-type but not ΔtnaA cultures (Supplementary Fig. 6), and the ΔtnaA mutation decreased persister formation by nearly an order of magnitude (Fig. 1a, Supplementary Table 1). In the ΔtnaA strain, incubation with indole increased persister formation by an order of magnitude in both M9CG and LB (Fig. 1a; Supplementary Table 1), and complementation with a plasmid bearing the wild-type tnaA gene reversed the low-persistence phenotype observed in rich medium (Supplementary Fig. 7). These results indicated that the effect of the ΔtnaA mutation on persister levels was a result of the lack of indole in ΔtnaA cultures. Consistent with earlier work14, we found that the ΔtnaA mutant showed a greater deficit in persister formation relative to wild-type at low temperature (Supplementary Fig. 8). The ΔtnaA mutation did not completely eliminate persister formation, suggesting that mechanisms in addition to indole signaling are also involved in persister formation. Interestingly, the increased persistence in LB relative to M9CG was abolished in the ΔtnaA strain, suggesting that indole signaling in LB may account for the observed difference (Fig. 1a, Supplementary Results).

Figure 1
Indole induces persistence in E. coli

Having demonstrated that indole signaling induces persister formation, we next sought to determine whether indole uptake plays a role in this process. We assayed persister levels in stationary phase cultures of a mutant strain (Δmtr) with impaired indole import16. We verified the role of Mtr in indole import using HPLC (Supplementary Fig. 5) and auxotrophy experiments (Supplementary Results, Supplementary Fig. 9). In M9CG and in LB, we found that the Δmtr strain demonstrated approximately an order of magnitude greater survival than wild-type, even without the addition of indole, and addition of indole did not further induce persistence (Fig. 1a). Overnight incubation of wild-type cultures with 15 μM indole, to mimic indole concentrations in Δmtr cultures, increased wild-type persistence to the levels observed in Δmtr (Supplementary Results, Supplementary Fig. 10). Heterologous expression of mtr in the knockout strain restored wild-type persister levels (Supplementary Fig. 7), and eliminating indole production in the Δmtr mutant abolished the high-persistence phenotype in this strain (Supplementary Fig. 11). These results suggest that indole-induced persistence is, in part, a response to indole levels in the periplasm or extracellular space.

We next sought to determine if the cells with the strongest indole response were persistent to antibiotic treatment. Using fluorescently activated cell sorting (FACS), we confirmed indole response in the fluorescent reporter plasmid PtnaC (Supplementary Methods, Supplementary Fig. 13a–c). The Δmtr strain had higher induction than wild-type, suggesting that increasing extracellular indole increases indole response. We sorted wild-type E. coli PtnaC to obtain sub-populations exhibiting “low” (bottom 10%) and “high” (top 10%) fluorescence and found that the sub-population with “high” fluorescing cells was more persistent to ofloxacin than the “low” fluorescing sub-population (Supplementary Fig. 13d). Similar results were obtained with ΔtnaA PtnaC + 500 μM indole (Supplementary Fig. 13e).

We sought to directly observe the generation of indole-induced persisters using a microfluidic chemostat (Supplementary Fig. 14, Supplementary Movies 1–3). Low levels of fluorescence were observed during growth of wild-type cells in indole-free media (Fig. 1b, I). During one hour of incubation with 500 μM indole, a heterogeneous increase in fluorescence was evident (Fig. 1b, II). Treatment with high concentrations of ampicillin caused massive lysis (Fig. 1b, III–V). Lysis reached a plateau after one hour of ampicillin treatment (Supplementary Fig. 15), leaving a small number of viable cells (Fig. 1b, V). (Consistent with previous results1, persister frequency differed between microfluidic and batch cultures.) We found that cells that survived antibiotic treatment had higher indole-responsive fluorescence than cells that did not survive (Fig. 1c), suggesting that cells that sensed indole to a greater degree were more likely to become persisters. These results demonstrate that indole response within a population is heterogeneous and, further, that indole signaling plays an important role in the formation of individual persister cells.

We next sought to investigate the biological effects of indole signaling by examining the genome-wide transcriptional response to indole. RNA from wild-type cultures (exponential and stationary phase) incubated with and without indole was harvested for microarrays as described in Supplementary Methods. Microarray analysis indicated that incubation with indole significantly (p ≤ 0.05) increased expression of genes in oxidative stress (OxyR) and phage shock (Psp) pathways in stationary phase (Supplementary Fig. 16) and exponential phase cultures (Supplementary Fig. 17). We did not observe statistically significant increases in expression of drug exporter systems (Supplementary Results, Supplementary Table 2), consistent with the hypothesis that the increase in survival after incubation with indole is due to an increase in persister formation rather than antibiotic resistance. qPCR was used to validate microarray results for selected targets (Supplementary Fig. 18). A detailed analysis of microarray data and a comparison to previous indole studies are presented in the Supplementary Results.

Given that both the oxidative stress and phage shock pathways play a protective role during bacterial stasis21,22, we next used genetic knockouts to determine whether these pathways are involved in indole-induced persistence. The ΔfluΔoxyR and ΔpspBC mutants were constructed to allow inactivation of the OxyR and phage shock responses, respectively (see Supplementary Methods). We found that indole-induced persistence was substantially reduced in both the ΔfluΔoxyR and ΔpspBC mutant strains relative to the parent strains (Fig. 2a, Supplementary Fig. 19). Further, we found that simultaneous inactivation of both pathways (Δflu pspBCΔoxyR) completely abolished indole-induced persistence (Fig. 2a, Supplementary Fig. 19). These results suggest that both the OxyR and phage shock responses are involved in indole-induced persistence.

Figure 2
Indole induces persistence through the phage shock and OxyR pathways

As non-toxic levels of indole induce persister formation, we sought to determine whether a known antimicrobial agent and OxyR inducer (hydrogen peroxide, H2O2)23 could also induce persistence. Treatment with moderate levels of this agent has been shown to increase tolerance as part of the bacterial adaptive response24. We found that pre-incubation of stationary phase cultures with 300–600 μM H2O2 increased persister levels by an order of magnitude (Fig. 2b). Using qPCR, we verified that treatment with H2O2 (300 μM) induced the OxyR regulon, and we found that it also induced the phage shock response (Supplementary Fig. 18). Interestingly, bactericidal concentrations of H2O2 (3 mM) did not have a protective effect (Fig. 2b). These results indicate that activation of the OxyR and phage shock responses in the absence of cytotoxic stress may be sufficient to induce persister formation, suggesting that activation of these responses by non-lethal stimuli “inoculates” a population against future stress.

On the basis of our findings, we propose the following mechanism for indole-induced persister formation (Fig. 2c). The bacterial signaling molecule indole is sensed in a heterogeneous manner by a population of cells, causing induction of oxidative stress (OxyR) and phage shock (Psp) pathways via a periplasmic or membrane component, thereby inducing the creation of a persistent sub-population. Indole is not toxic at physiological levels, but triggers protective responses, acting to “inoculate” a sub-population (persisters) against possible future stress.

Here we have shown that bacterial communication through indole signaling induces persister formation in E. coli. This process involves the activation of oxidative stress and phage shock pathways, and allows bacteria to protect a sub-population against antibiotic treatment. These findings add to an understanding of persister formation as a bacterial “bet-hedging” strategy in uncertain environments25. Indole, produced under nutrient-limited conditions, allows E. coli to alter the frequency of persister formation, thereby providing a mechanism by which a bacterial population can adjust its bet-hedging strategy based on environmental cues. Our findings demonstrate that persister formation is influenced by communication within a population of cells, and it is not simply the result of an isolated, random switching event in individual cells.

Supplementary Material

Acknowledgments

We would like to thank Raymond H. W. Lam for help with microfluidics. This work was supported by funding from the NSF, the NIH Director’s Pioneer Award Program, and the Howard Hughes Medical Institute.

Footnotes

Author Contributions

All authors designed experiments, discussed results, and contributed to the manuscript. N.M.V. performed all experiments. N.M.V., K.R.A., and A.S.K. analyzed data. A.S.K. developed the microfluidics platform and performed the microfluidic experiments.

Competing Financial Interests

The authors declare no competing financial interests.

References

1. Balaban NQ, et al. Science. 2004;305:1622–1625. [PubMed]
2. Lewis K. Nat Rev Microbiol. 2007;5:48–56. [PubMed]
3. Smith PA, Romesberg FE. Nat Chem Biol. 2007;3:549–556. [PubMed]
4. Allison KR, Brynildsen MP, Collins JJ. Nature. 2011;473:216–220. [PMC free article] [PubMed]
5. Levin BR, Rozen DE. Nat Rev Microbiol. 2006;4:556–562. [PubMed]
6. Gefen O, Balaban NQ. FEMS Microbiol Rev. 2009;33:704–717. [PubMed]
7. Keren I, et al. FEMS Microbiol Lett. 2004;230:13–18. [PubMed]
8. Moyed HS, Bertrand KP. J Bacteriol. 1983;155:768–775. [PMC free article] [PubMed]
9. Wang X, Wood TK. Appl Environ Microbiol. 2011;77:5577–5583. [PMC free article] [PubMed]
10. Wang X, et al. Nat Chem Biol. 2011;7:359–366. [PMC free article] [PubMed]
11. Bassler BL, Losick R. Cell. 2006;125:237–246. [PubMed]
12. Wang DD, Ding XD, Rather PN. J Bacteriol. 2001;183:4210–4216. [PMC free article] [PubMed]
13. Di Martino P, et al. Can J Microbiol. 2003;49:443–449. [PubMed]
14. Lee J, et al. Isme J. 2008;2:1007–1023. [PubMed]
15. Han TH, et al. Res Microbiol. 2010;7:108–116. [PMC free article] [PubMed]
16. Yanofsky C, Horn V, Gollnick P. J Bacteriol. 1991;173:6009–6017. [PMC free article] [PubMed]
17. Pinero-Fernandez S, Chimerel C, Keyser UF, Summers DK. J Bacteriol. 2011;193:1793–1798. [PMC free article] [PubMed]
18. Garbe TR, Kobayashi M, Yukawa H. Arch Microbiol. 2000;173:78–82. [PubMed]
19. Hirakawa H, et al. Mol Microbiol. 2005;55:1113–1126. [PubMed]
20. Lee HH, Molla MN, Cantor CR, Collins JJ. Nature. 2010;467:82–85. [PMC free article] [PubMed]
21. Weiner L, Model P. Proc Natl Acad Sci U S A. 1994;91:2191–2195. [PMC free article] [PubMed]
22. Dukan S, Nystrom T. J Biol Chem. 1999;274:26027–26032. [PubMed]
23. Storz G, Tartaglia LA, Ames BN. Antonie Van Leeuwenhoek. 1990;58:157–161. [PubMed]
24. Crawford DR, Davies KJ. Environ Health Perspect. 1994;10:25–28. [PMC free article] [PubMed]
25. Rotem E, et al. Proc Natl Acad Sci U S A. 2010;107:12541–12546. [PMC free article] [PubMed]

Formats:

Related citations in PubMed

See reviews...See all...

Cited by other articles in PMC

See all...

Links

  • Cited in Books
    Cited in Books
    PubMed Central articles cited in books
  • PubMed
    PubMed
    PubMed citations for these articles
  • Substance
    Substance
    PubChem Substance links

Recent Activity

Your browsing activity is empty.

Activity recording is turned off.

Turn recording back on

See more...