Department of Molecular Microbiology and Immunology, Bloomberg School of Public Health, Johns Hopkins University, Baltimore, MD 21205, USA
Received 21 January 2003; returned 20 March 2003; revised 11 April 2003; accepted 16 April 2003
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Abstract |
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Keywords: weak acid, antimicrobial susceptibility, pH homeostasis, membrane potential, Mycobacterium tuberculosis
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Introduction |
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During our study of the mode of action of the frontline TB drug pyrazinamide, a drug that has shortened TB therapy from 912 months previously to 6 months, we have shown that Mycobacterium tuberculosis seems to be uniquely susceptible to the weak acid pyrazinoic acid (pKa = 2.9), the active form of pyrazinamide; whereas other mycobacteria (e.g. Mycobacterium smegmatis) or bacteria (e.g. Escherichia coli) are more resistant to pyrazinoic acid.3,4 In addition, it is well known that during pyrazinamide susceptibility testing, which requires acid pH for activity, the growth of M. tuberculosis is inhibited if the medium pH is below 5.5.5 M. tuberculosis appears to be quite susceptible to acid pH compared with other mycobacteria.68 In Sautons simple salt medium, the growth of M. tuberculosis was restricted at pH 6.0, whereas other mycobacterial species grew quite well.8 In this study, we tested whether M. tuberculosis is also susceptible to other weak acids in addition to pyrazinoic acid and compared the susceptibility of M. tuberculosis to acidic pH and a range of weak acids with that of M. smegmatis. We have shown that M. tuberculosis is significantly more susceptible to acidic pH and weak acids in general than M. smegmatis. The antimycobacterial activity of the weak acids is enhanced at acid pH. The basis of the susceptibility of M. tuberculosis to acid pH and weak acids is investigated.
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Materials and methods |
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M. tuberculosis strain H37Ra was grown in 7H9 liquid medium (DIFCO) supplemented with 0.05% Tween 80 and 10% bovine serum albumin-dextrose-catalase enrichment (DIFCO) at 37°C for 3 weeks with occasional shaking. M. smegmatis mc26 (MC2) was similarly cultivated in the 7H9 medium at 37°C for 4 days. To test the susceptibility of mycobacteria to different pH values, M. tuberculosis H37Ra or M. smegmatis cells were resuspended in sodium phosphate buffer adjusted to different pH levels (pH 3.0, 4.0, 5.0, 6.0, 7.0) in 1 mL to a cell density of 1.30 at OD600 and incubated at 37°C. At 1, 3, 5 and 7 days, aliquots of the cell suspension were removed, washed and diluted before plating on 7H11 plates. The plates were then incubated at 37°C for 4 weeks for M. tuberculosis and for 5 days for M. smegmatis to determine the number of surviving bacteria.
Susceptibility to weak acids and isolation of weak acid resistant mutants
Various weak acids were obtained from Sigma Chemical Co., and were dissolved in DMSO at appropriate concentrations. The weak acids were incorporated into 7H11 agar at various concentrations. Three-week-old stationary phase M. tuberculosis H37Ra culture or 4-day-old M. smegmatis mc26 culture were tested for susceptibility to weak acids on 7H11 plates at pH 6.8 and pH 5.5 as described.9 For the isolation of weak acid mutants, about 108 colony forming units (cfu) of M. tuberculosis H37Ra were plated on acidic 7H11 agar plates (pH 5.5) containing various concentrations of weak acids such as salicylate, benzoic acid, nonyloxybenzoic acid and mefenamic acid. The plates were incubated at 37°C for 4 weeks before being examined for the emergence of spontaneous mutants.
Measurement of intracellular pH and membrane potential
The internal pH of mycobacteria was measured as described previously.3 Membrane potential was measured with [3H]tetraphenylphosphonium bromide (TPP+) using the method as described.10 Briefly, 3-week-old H37Ra or 4-day-old M. smegmatis cells were resuspended in Sautons medium at different pH values to measure the change in the membrane potential in response to changes in external pH after incubating the cells at room temperature for 50 min. [3H]TPP+ (380 mCi/mmol) at 10 µM final concentration was then added to the cell suspension and the mixture was fully mixed before silicone oil was added and the mixture incubated for another 10 min. The mixture was spun at 12 000 rpm for 3 min, and 100 µL supernatant was taken for scintillation counting. The cell pellets were then snap-frozen in an alcohol/dry ice bath. The bottom of the tubes containing the cell pellets were cut off for scintillation counting. To determine the effect of weak acids on membrane potential and internal pH, various weak acids were incubated with mycobacterial cells resuspended in pH 5.5 Sautons medium for 1 h when the measurements were made as described above. Valinomycin (10 µM) and nigericin (10 µM) were used as controls for the membrane potential and internal pH measurements.
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Results |
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The acid sensitivity of M. tuberculosis and M. smegmatis was determined by exposing the bacilli to various acidic pH conditions using pH 7.0 as a control, and plated for survivors after exposure for different times. The relative sensitivity of the two mycobacterial species to acidic pH was expressed as the percentage of bacterial survival by dividing the cfu obtained after exposure to acid pH by that at neutral pH. At pH 3.0, there was relatively little difference between M. tuberculosis and M. smegmatis in terms of survival due to extreme acidity (Table 1). However, at pH 4.0 and 5.0, M. tuberculosis was significantly more sensitive to acid pH than M. smegmatis (Table 1).
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As shown in Table 2, M. tuberculosis was more susceptible than M. smegmatis to a range of weak acids. The antimycobacterial activity of the weak acids was more pronounced at acid pH than at close to neutral pH for both mycobacterial species. In addition, the activity of the weak acids appeared to correlate with their pKa values, i.e. the lower the pKa, the higher the antimycobacterial activity (Table 2). It is noteworthy that M. tuberculosis was susceptible to linoleic acid (MIC 37 mg/L at pH 5.5) but not to linoleic acid ethyl ester (MIC > 1000 mg/L at pH 5.5), indicating that the acid form COOH is active and that M. tuberculosis does not have an appropriate esterase to convert linoleic acid ethyl ester to the active acid form.
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We have shown previously that no pyrazinoic acid-resistant mutants of M. tuberculosis could be isolated.11 To determine whether this is a more generalized phenomenon, we attempted to isolate M. tuberculosis H37Ra mutants resistant to a range of weak acids such as salicylic acid, benzoic acid and 4-nonyloxybenzoic acid. However, we were unable to isolate any mutants resistant to the weak acids even at very high density of cells (109 cfu/mL) on 7H11 plates (data not shown).
Inefficient maintenance of intracellular pH in M. tuberculosis
We compared the intracellular pH of M. tuberculosis and M. smegmatis in response to changes in external pH (Figure 1a). Between pH 5 and pH 7, the two organisms behaved similarly in terms of changes in internal pH. However, under more acidic conditions (pH 35), the internal pH of M. smegmatis remained fairly stable at values of 5.75.9; in contrast, the internal pH of M. tuberculosis became more acidic, reaching 5.2 at an external pH of 3.2 (Figure 1a). This indicates that M. tuberculosis is less efficient at maintaining the internal pH than M. smegmatis. In addition, valinomycin and nigericin had a more pronounced effect on lowering the internal pH of M. smegmatis but had little effect on M. tuberculosis (Figure 1b and c). This finding lends further support to the idea that M. smegmatis has a more active apparatus to maintain its internal pH at acid pH conditions (pH 35) than M. tuberculosis.
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We compared the membrane potential of M. tuberculosis and M. smegmatis in response to changes in external pH. The membrane potential of M. tuberculosis was generally higher than that of M. smegmatis except at the very acidic pH of 3.5, at which there was little difference in the membrane potential between the two organisms. However, the membrane potential of M. tuberculosis was more sensitive to changes in external pH than M. smegmatis between pH 4 and pH 8.5 (Figure 2). The more responsive change in the membrane potential of M. tuberculosis compared with M. smegmatis is most likely due to a poor ability of M. tuberculosis to maintain its membrane potential under different external pH conditions.
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The susceptibility of M. tuberculosis and M. smegmatis to weak acids was examined in the context of membrane potential and internal pH. It was found that the susceptibility of M. tuberculosis to weak acids appeared to correlate with their ability to disrupt membrane potential (Figure 3a). In contrast, weak acids had little effect on the disruption of membrane potential in the non-susceptible species M. smegmatis (Figure 3a). The antimycobacterial activity of the weak acids did not correlate well with their ability to decrease the internal pH (Figure 3b).
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Discussion |
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An important observation of this study is that M. tuberculosis is uniquely susceptible to a range of weak acids compared with M. smegmatis (Table 2) and indeed other bacteria such as E. coli (data not shown). The antituberculous activity of the weak acids appeared to inversely correlate with the pKa of the weak acid (Table 2), i.e. the lower the pKa (the stronger the weak acid), the stronger the antituberculous activity. For example, salicylic acid and nicotinic acid have pKa values of 3 and 4.8, respectively, and their MICs for M. tuberculosis were 1020 and 200 mg/L at pH 5.5, respectively. In addition, the antimycobacterial activity of the weak acids was enhanced at acid pH (Table 2). This is consistent with the fact that, at acidic pH, weak acids become protonated and form uncharged species that permeates through the membrane easily compared with charged anion species.10 Enhanced activity of weak acids at acid pH is consistent with the observation that uptake and accumulation of weak acids are increased at acidic pH, as shown for pyrazinoic acid.3 The consequence of weak acid accumulation and recycling could lead to disruption of the proton motive force that is required for the transport of many nutrient substances into bacterial cells as a mechanism of action of weak acids.12
The finding that M. tuberculosis is susceptible to weak acids of diverse structures suggests that these weak acids do not have a specific cellular target besides their general effect on disrupting the membrane function. Failure to isolate M. tuberculosis mutants resistant to various weak acids is also in keeping with this proposition. The susceptibility of M. tuberculosis to weak acids may be a result of its inefficient ability to maintain membrane potential compared with M. smegmatis. The observation that various weak acids appeared to preferentially disrupt the membrane potential of M. tuberculosis over that of M. smegmatis (Figure 3a) supports this notion. This differential disruption of membrane potential in M. tuberculosis by the weak acids could result from the slow metabolism and consequently slow energy production in the slow growing M. tuberculosis and a defective efflux mechanism as shown for pyrazinoic acid.3
Whereas there is no difference in membrane potential between the two organisms at very acidic pH (pH 3), it is surprising that the membrane potential of M. smegmatis is generally lower than that of M. tuberculosis (Figure 2). This could indicate that the probe TPP+ used to measure the membrane potential is actively extruded by M. smegmatis but not by M. tuberculosis. The observation that valinomycin and nigericin did not affect the membrane potential in M. smegmatis but did so in M. tuberculosis (not shown) could be due to valinomycin and nigericin not getting into M. smegmatis cells or an active efflux mechanism for the membrane potential probe TPP+. Because valinomycin and nigericin were shown to affect the internal pH of M. smegmatis (Figure 1c), the first possibility of these agents not getting into the cells can be ruled out. Therefore, it is likely that M. smegmatis has an active efflux for TPP+, which is responsible for the measured lower membrane potential in this organism compared with M. tuberculosis.
That M. tuberculosis appears to be uniquely susceptible to weak acids may have implications for the design of new antituberculosis drugs. However, weak acids may not be easily absorbed through the gastrointestinal tract or bind to serum proteins. To circumvent this potential problem, it may be necessary to make precursors of weak acids such as ester or amide of weak acids for in vivo use. To show activity the weak acid precursors will have to be hydrolysed by enzymes present in M. tuberculosis, which is known to contain a range of esterases and amidases in the genome.13 Future studies are needed to determine whether weak acid precursors can be developed into antituberculosis agents useful for the treatment of TB.
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Acknowledgements |
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Footnotes |
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