Membrane ATPases and acid tolerance of Actinomyces viscosus and Lactobacillus casei.

Lactobacillus casei ATCC 4646 and Actinomyces viscosus OMZ105E were found to differ markedly in acid tolerance. For example, pH profiles for glycolysis of intact cells in dense suspensions indicated that glycolysis by L. casei had an optimal pH of about 6.0 and that glucose degradation was reduced by 50% at a pH of 4.2. Comparable values for A. viscosus cells were at pHs of about 7.0 and 5.6. The difference in acid tolerance appeared to depend mainly on membrane physiology, and the addition of 40 microM gramicidin to cell suspensions increased the sensitivity of the glycolytic system by as much as 1.5 pH units for L. casei and up to 0.5 pH unit for A. viscosus. L. casei cells were inherently somewhat more resistant to severe acid damage than were A. viscosus cells, in that Mg release from L. casei cells in medium with a pH of 3.0 occurred only after a lag of some 4 h, compared with rapid release from A. viscosus cells. However, the major differences pertinent to the physiology of the organisms appeared to be related to proton-translocating ATPases. Isolated membranes of L. casei had about 3.29 U of ATPase per mg of protein, compared with only about 0.06 U per mg of protein for those of A. viscosus. Moreover, the ATPase of L. casei had a pH optimum for hydrolytic activity of about 5, compared with an optimal pH of about 7 for that of A. viscosus.(ABSTRACT TRUNCATED AT 250 WORDS)     

Role of the arginine deiminase system in protecting oral bacteria and an enzymatic basis for acid tolerance

The arginine deiminase system was found to function in protecting bacterial cells against the damaging effects of acid environments. For example, as little as 2.9 mM arginine added to acidified suspensions of Streptococcus sanguis at a pH of 4.0 resulted in ammonia production and protection against killing. The arginine deiminase system was found to have unusual acid tolerance in a variety of lactic acid bacteria. For example, for Streptococcus rattus FA-1, the pH at which arginolysis was reduced to 10% of the maximum was between 2.1 and 2.6, or more than 1 full pH unit below the minimum for glycolysis (pH 3.7), and more than 2 units below the minimum for growth in complex medium (pH 4.7). The acid tolerance of the arginine deiminase system appeared to be primarily molecular and to depend on the tolerance of individual enzymes rather than on the membrane physiology of the bacteria; pH profiles for the activities of arginine deiminase, ornithine carbamoyltransferase, and carbamate kinase in permeabilized cells showed that the enzymes were active at pHs of 3.1 or somewhat lower. Overall, it appeared that ammonia could be produced from arginine at low pH values, even by cells with damaged membranes, and that the ammonia could then protect the cells against acid damage until the environmental pH value rose sufficiently to allow for the reestablishment of a difference in pH (delta pH) across the cell membrane.     

Role of the arginine deiminase system in protecting oral bacteria and an enzymatic basis for acid tolerance.

The arginine deiminase system was found to function in protecting bacterial cells against the damaging effects of acid environments. For example, as little as 2.9 mM arginine added to acidified suspensions of Streptococcus sanguis at a pH of 4.0 resulted in ammonia production and protection against killing. The arginine deiminase system was found to have unusual acid tolerance in a variety of lactic acid bacteria. For example, for Streptococcus rattus FA-1, the pH at which arginolysis was reduced to 10% of the maximum was between 2.1 and 2.6, or more than 1 full pH unit below the minimum for glycolysis (pH 3.7), and more than 2 units below the minimum for growth in complex medium (pH 4.7). The acid tolerance of the arginine deiminase system appeared to be primarily molecular and to depend on the tolerance of individual enzymes rather than on the membrane physiology of the bacteria; pH profiles for the activities of arginine deiminase, ornithine carbamoyltransferase, and carbamate kinase in permeabilized cells showed that the enzymes were active at pHs of 3.1 or somewhat lower. Overall, it appeared that ammonia could be produced from arginine at low pH values, even by cells with damaged membranes, and that the ammonia could then protect the cells against acid damage until the environmental pH value rose sufficiently to allow for the reestablishment of a difference in pH (delta pH) across the cell membrane.     

Triclosan inhibition of membrane enzymes and glycolysis of Streptococcus mutans in suspensions and biofilms

Triclosan was found to be a potent inhibitor of the F(H+)-ATPase of the oral pathogen Streptococcus mutans and to increase proton permeabilities of intact cells. Moreover, it acted additively with weak-acid transmembrane proton carriers, such as fluoride or sorbate, to sensitize glycolysis to acid inhibition. Even at neutral pH, triclosan could inhibit glycolysis more directly as an irreversible inhibitor of the glycolytic enzymes pyruvate kinase, lactic dehydro genase, aldolase, and the phosphoenolpyruvate:sugar phosphotransferase system (PTS). Cell glycolysis in suspensions or biofilms was inhibited in a pH-dependent manner by triclosan at a concentration of about 0.1 mmol/L at pH 7, approximately the lethal concentration for S. mutans cells in suspensions. Cells in intact biofilms were almost as sensitive to triclosan inhibition of glycolysis as were cells in suspensions but were more resistant to killing. Targets for irreversible inhibition of glycolysis included the PTS and cytoplasmic enzymes, specifically pyruvate kinase, lactic dehydrogenase, and to a lesser extent, aldolase. General conclusions are that triclosan is a multi-target inhibitor for mutans streptococci, which lack a triclosan-sensitive FabI enoyl-ACP reductase, and that inhibition of glycolysis in dental plaque biofilms, in which triclosan is retained after initial or repeated exposure, would reduce cariogenicity.     

Diversity and mechanisms of alkali tolerance in lactobacilli

We determined the maximum pH that allows growth (pHmax) for 34 strains of lactobacilli. High alkali tolerance was exhibited by strains of Lactobacillus casei, L. paracasei subsp. tolerans, L. paracasei subsp. paracasei, L. curvatus, L. pentosus, and L. plantarum that originated from plant material, with pHmax values between 8.5 and 8.9. Among these, L. casei NRIC 1917 and L. paracasei subsp. tolerans NRIC 1940 showed the highest pHmax, at 8.9. Digestive tract isolates of L. gasseri, L. johnsonii, L. reuteri, L. salivarius subsp. salicinius, and L. salivarius subsp. salivarius exhibited moderate alkali tolerance, with pHmax values between 8.1 and 8.5. Dairy isolates of L. delbrueckii subsp. bulgaricus, L. delbrueckii subsp. lactis, and L. helveticus exhibited no alkali tolerance, with pHmax values between 6.7 and 7.1. Measurement of the internal pH of representative strains revealed the formation of transmembrane proton gradients (DeltapH) in a reversed direction (i.e., acidic interior) at alkaline external-pH ranges, regardless of their degrees of alkali tolerance. Thus, the reversed DeltapH did not determine alkali tolerance diversity. However, the DeltapH contributed to alkali tolerance, as the pHmax values of several strains decreased with the addition of nigericin, which dissipates DeltapH. Although neutral external-pH values resulted in the highest glycolysis activity in the presence of nigericin regardless of alkali tolerance, substantial glucose utilization was still detected in the alkali-tolerant strains, even in a pH range of between 8.0 and 8.5, at which the remaining strains lost most activity. Therefore, the alkali tolerance of glycolysis reactions contributes greatly to the determination of alkali tolerance diversity.     

Effects of High Pressure on Inactivation Kinetics and Events Related to Proton Efflux in Lactobacillus plantarum

Knowledge of the mechanism of pressure-induced inactivation of microorganisms could be helpful in defining an effective, relatively mild pressure treatment as a means of decontamination, especially in combination with other physical treatments or antimicrobial agents. We have studied the effect of high pressure on Lactobacillus plantarum grown at pH 5.0 and 7.0. The classical inactivation kinetics were compared with a number of events related to the acid-base physiology of the cell, i.e., activity of F(0)F(1) ATPase, intracellular pH, acid efflux, and intracellular ATP pool. Cells grown at pH 5.0 were more resistant to pressures of 250 MPa than were cells grown at pH 7.0. This difference in resistance may be explained by a higher F(0)F(1) ATPase activity, better ability to maintain a DeltapH, or a higher acid efflux of the cells grown at pH 5.0. After pressure treatment at 250 MPa, the F(0)F(1) ATPase activity was decreased, the ability to maintain a DeltapH was reduced, and the acid efflux was impaired. The ATP pool increased initially after mild pressure treatment and finally decreased after prolonged treatment. The observations on acid efflux and the ATP pool suggest that the glycolysis is affected by high pressure later than is the F(0)F(1) ATPase activity. Although functions related to the membrane-bound ATPase activity were impaired, no morphological changes of the membrane could be observed.     

Some peculiarities of functioning of H+-ATPase from the membranes of the anaerobic bacterium Lactobacillus casei

Radiation inactivation analysis gave the target sizes of 176 +/- 5 kDa and 275 +/- 33 kDa for ATPase from anaerobic Lactobacillus casei and aerobic Micrococcus luteus bacteria respectively. The values are close to the known molecular masses of the enzymes. Thus, to function the L. casei ATPase, like the F1-ATPases, requires a complete structure composed of all the enzyme subunits. L. casei ATPase is inhibited by 4-chloro-7-nitrobenzo-2-oxa-1,3-diazole owing to modification of an amino acid residue(s) with pK greater than 8.5. L. casei ATPase consists of six identical subunits and differs from alpha 3 beta 3 gamma delta epsilon-type F1-ATPases in a number of catalytic properties. Namely, ATP hydrolysis under the 'unisite' conditions proceeds at a relatively high rate suggesting the absence of cooperative interactions between the catalytic sites. Contrary to mitochondrial F1-ATPase. L. casei ATPase does not form an inactive complex with ADP. These findings imply essential differences in the operating mechanism for L. casei ATPase and F1 ATPase.     

Adhesion of Actinomyces viscosus to Porphyromonas (Bacteroides) gingivalis-coated hexadecane droplets.

Interbacterial adhesion (coadhesion) is considered a major determinant of dental plaque ecology. In this report, we studied several aspects of the adhesion of Porphyromonas (Bacteroides) gingivalis to hexadecane in order to use the liquid hydrocarbon as a convenient substratum for coadhesion assays. Washed suspensions of hydrophobic P. gingivalis 2561 cells were vortexed with hexadecane to yield highly stable cell-coated droplets. Kinetics of coadhesion between Actinomyces viscosus cells and P. gingivalis-coated hexadecane droplets (PCHD) was subsequently studied. Aliquots of PCHD were added to A. viscosus suspensions, and the mixtures were gently rotated. Avid adhesion of A. viscosus cells to the immobilized P. gingivalis layer could be readily measured by the decrease in turbidity in the aqueous phase, following phase separation. Despite the ability of A. viscosus cells to adsorb to hexadecane following vigorous mixing, gentle mixing did not appreciably promote adhesion to bare hexadecane. Moreover, extensive microscopic examinations revealed that A. viscosus cells adhered exclusively to the bound P. gingivalis cells rather than to exposed areas of hexadecane. Coadhesion of A. viscosus to the PCHD appeared to follow first-order kinetics, attaining 80% levels within 30 min. Electron micrographs revealed A. viscosus cells adhering to the P. gingivalis cell layer adsorbed at the hexadecane-water interface. Interestingly, P. gingivalis cells did not appear to penetrate the hexadecane. A viscosus mutants lacking type 1 or type 2 fimbriae or both were still able to bind to the PCHD. No obvious correlation was observed between relative hydrophobicity of A. viscosus strains and their binding to PCHD. However, defatted bovine serum albumin, an inhibitor of hydrophobic interactions, was the most potent inhibitor among those tested. The data suggest that this approach provides a simple, quantitative technique for studying kinetics of bacterial coadhesion which is amenable to both light and electron microscopic observation.     

Increasing acidification of nonreplicating Lactococcus lactis deltathyA mutants by incorporating ATPase activity

Lactococcus lactis MBP71 deltathyA (thymidylate synthase) cannot synthesize dTTP de novo, and DNA replication is dependent on thymidine in the growth medium. In the nonreplicating state acidification by MBP71 was completely insensitive to bacteriophages (M. B. Pedersen, P. R. Jensen, T. Janzen, and D. Nilsson, Appl. Environ. Microbiol. 68:3010-3023, 2002). For nonreplicating MBP71 the biomass increased 3.3-fold over the first 3.5 h, and then the increase stopped. The rate of acidification increased 2.3-fold and then started to decrease. Shortly after inoculation the lactic acid flux was 60% of that of exponentially growing MBP71. However, when nonspecific ATPase activity was incorporated into MBP71, the lactic acid flux was restored to 100% but not above that point, indicating that control over the flux switched from ATP demand to ATP supply (i.e., to sugar transport and glycolysis). As determined by growing nonreplicating cells with high ATPase activity on various sugar sources, it appeared that glycolysis exerted the majority of the control. ATPase activity also stimulated the rate of acidification by nonreplicating MBP71 growing in milk, and pH 5.2 was reached 40% faster than it was without ATPase activity. We concluded that ATPase activity is a functional means of increasing acidification by nonreplicating L. lactis.     

Activity of plasma membrane H+-ATPase and expression of PMA1 and PMA2 genes in Saccharomyces cerevisiae cells grown at optimal and low pH

Cells of Saccharomyces cerevisiae grown in media with an initial pH of 2.5–6.0, acidified with a strong acid (HCl), exhibited the highest plasma membrane H⁺-ATPase-specific activity at an initial pH of 6.0. At a lower pH (above pH 2.5) ATPase activity (62–83% of the maximum level) still allowed optimal growth. At pH 2.5, ATPase activity was about 30% of the maximum value and growth was impaired. Quantitative immunoassays showed that the content of ATPase protein in the plasma membrane was similar across the entire pH range tested, although slightly lower at pH 2.5. The decrease of plasma membrane ATPase activity in cells grown at low pH was partially accounted for by its in vitro stability, which decreased sharply at pH below 5.5, although the reduction of activity was far below the values expected from in vitro measurements. Yeast growth under acid stress changed the pattern of gene expression observed at optimal pH. The level of mRNA from the essential plasma-membrane-ATPase-encoding gene PMA1 was reduced by 50% in cells grown at pH 2.5 as compared with cells grown at the optimal pH 5.0, although the content of ATPase in the plasma membrane was only modestly reduced. As observed in response to other kinds of stress, the PMA2 promoter at the optimal pH was up to eightfold more efficient in cells grown at pH 2.5, although it remained several hundred times less efficient than that of the PMA1 gene. Received: 22 April 1996 / Accepted: 6 August 1996     

Adaptive acid tolerance response of Streptococcus sobrinus

Streptococcus mutans and Streptococcus sobrinus are the bacteria most commonly associated with human dental caries. A major virulence attribute of these and other cariogenic bacteria is acid tolerance. The acid tolerance mechanisms of S. mutans have begun to be investigated in detail, including the adaptive acid tolerance response (ATR), but this is not the case for S. sobrinus. An analysis of the ATR of two S. sobrinus strains was conducted with cells grown to steady state in continuous chemostat cultures. Compared with cells grown at neutral pH, S. sobrinus cells grown at pH 5.0 showed an increased resistance to acid killing and were able to drive down the pH through glycolysis to lower values. Unlike what is found for S. mutans, the enhanced acid tolerance and glycolytic capacities of acid-adapted S. sobrinus were not due to increased F-ATPase activities. Interestingly though, S. sobrinus cells grown at pH 5.0 had twofold more glucose phosphoenolpyruvate:sugar phosphotransferase system (PTS) activity than cells grown at pH 7.0. In contrast, glucose PTS activity was actually higher in S. mutans grown at pH 7.0 than in cells grown at pH 5.0. Silver staining of two-dimensional gels of whole-cell lysates of S. sobrinus 6715 revealed that at least 9 proteins were up-regulated and 22 proteins were down-regulated in pH 5.0-grown cells compared with cells grown at pH 7.0. Our results demonstrate that S. sobrinus is capable of mounting an ATR but that there are critical differences between the mechanisms of acid adaptation used by S. sobrinus and S. mutans.     

Comparative acid tolerances and inhibitor sensitivities of isolated F-ATPases of oral lactic acid bacteria.

pH activity profiles and inhibitor sensitivities were compared for membrane ATPases isolated from three oral lactic acid bacteria, Lactobacillus casei ATCC 4646, Streptococcus mutans GS-5, and Streptococcus sanguis NCTC 10904, with, respectively, high, moderate, and low levels of acid tolerance. Membranes containing F1F0 ATPases were isolated by means of salt lysis of cells treated with muralytic enzymes. Membrane-free F1F0 complexes were then isolated from membranes by detergent extraction with Triton X-100 or octylglucoside. Finally, F1 complexes free of the proton-conducting F0 sector were obtained by washing membranes with buffers of low ionic strength. The pH activity profiles of the membrane-associated enzymes reflected the general acid tolerances of the organisms from which they were isolated; for example, pH optima were approximately 5.5, 6.0, and 7.0, respectively, for enzymes from L. casei, S. mutans, and S. sanguis. Roughly similar profiles were found for membrane-free F1F0 complexes, which were stabilized by phospholipids against loss of activity during storage. However, profiles for F1 enzymes were distinctly narrower, indicating that association with F0 and possibly other membrane components enhanced tolerance to both acid and alkaline media. All of the enzymes were found to have similar sensitivities to Al-F complexes, but only F1F0 enzymes were highly sensitive to dicyclohexylcarbodiimide. The procedures described for isolation of membrane-free F1F0 forms of the enzymes from oral lactic acid bacteria will be of use in future studies of the characteristics of the enzymes, especially in studies with liposomes.     

Comparative acid tolerances and inhibitor sensitivities of isolated F-ATPases of oral lactic acid bacteria.

pH activity profiles and inhibitor sensitivities were compared for membrane ATPases isolated from three oral lactic acid bacteria, Lactobacillus casei ATCC 4646, Streptococcus mutans GS-5, and Streptococcus sanguis NCTC 10904, with, respectively, high, moderate, and low levels of acid tolerance. Membranes containing F1F0 ATPases were isolated by means of salt lysis of cells treated with muralytic enzymes. Membrane-free F1F0 complexes were then isolated from membranes by detergent extraction with Triton X-100 or octylglucoside. Finally, F1 complexes free of the proton-conducting F0 sector were obtained by washing membranes with buffers of low ionic strength. The pH activity profiles of the membrane-associated enzymes reflected the general acid tolerances of the organisms from which they were isolated; for example, pH optima were approximately 5.5, 6.0, and 7.0, respectively, for enzymes from L. casei, S. mutans, and S. sanguis. Roughly similar profiles were found for membrane-free F1F0 complexes, which were stabilized by phospholipids against loss of activity during storage. However, profiles for F1 enzymes were distinctly narrower, indicating that association with F0 and possibly other membrane components enhanced tolerance to both acid and alkaline media. All of the enzymes were found to have similar sensitivities to Al-F complexes, but only F1F0 enzymes were highly sensitive to dicyclohexylcarbodiimide. The procedures described for isolation of membrane-free F1F0 forms of the enzymes from oral lactic acid bacteria will be of use in future studies of the characteristics of the enzymes, especially in studies with liposomes.     

Lactose-Hydrolyzing Enzymes of Lactobacillus Species

beta-Galactosidase (beta-gal, EC 3.2.1.23) and beta-D-phosphogalactoside galactohydrolase (beta-Pgal) activities were observed in all of 13 Lactobacillus species studied except L. casei and L. buchneri. Only the latter enzyme was detected in nine strains of L. casei. The beta-gal from L. thermophilus and the beta-Pgal from L. casei were purified and characterized. In comparison with beta-gal, the beta-Pal was slightly less active (V(max) values were 28.9 and 50.0 mumoles per mg per min, respectively), but the substrate affinitives were similar (K(m) values were 1.69 x 10(-3) M and 1.59 x 10(-3) M, respectively). Although the two enzymes had similar amino acid compositions, the molecular weight of beta-gal was 5.4 x 10(5) and that of beta-Pgal was 1.3 x 10(5). The beta-gal from L. thermophilus and the beta-Pgal from L. casei had optimal temperature and pH activity values of 55 C at pH 6.2 and 37 C at pH 5.0, respectively. The complete absence of beta-gal from a homofermentative Lactobacillus species of industrial importance is further evidence of the heterogeneity of this genus.     

Phosphorus-31 nuclear magnetic resonance studies of bioenergetics in wild-type and adenosinetriphosphatase(1-) Escherichia coli cells

By use of 31P NMR, the transmembrane pH gradient (delta pH) and the intracellular levels of phosphorylated metabolites were measured in aerobic suspensions of wild-type Escherichia coli cells in the presence and absence of the adenosinetriphosphatase (ATPase) inhibitor dicyclohexylcarbodiimide (DCCD); the same parameters were also determined in E. coli mutants deficient in ATPase activity under both anaerobic and aerobic conditions. A method is described by which dense suspensions of E. coli cells (approximately 3 X 10(11) cells/mL) were oxygenated so that steady-state O2 levels in the suspensions were far greater than the Km for O2 consumption. Under these conditions, in wild-type MRE600 cells, the intracellular concentrations of PI, NTP, and NDP were measured to be 3.0 +/- 1.5, 8 +/- 1, and 1.2 +/- 1 mM, respectively, while the intracellular pH was approximately 7.5 over the external pH range studied (6 to approximately 7.0). Upon treatment with DCCD, the intracellular NTP level was drastically reduced and intracellular Pi concentration increased in respiring wild-type cells; in the same cells, however, DCCD did not affect the intracellular pH and the delta pH. During respiration in the presence of lactate, ATPase- cells established a delta pH but failed to synthesize any detectable levels of NTP. Conversely, ATPase- cells accumulated high levels of NTP but did not generate a delta pH during glycolysis under anaerobic conditions. These results are in complete agreement with the generally accepted chemiosmotic hypothesis. 31P NMR data on intact ATPase- NR70 cells were in agreement with the previously proposed [Rosen, B. P., Brey, R., & Hasan, S. (1978) J. Bacteriol. 134, 1030] existence of a proton leak in this strain which is sealed by DCCD or by spontaneous mutation into strain NR71. However, the NMR data also indicated that other major differences exist between NR71 and NR70 cells.     

交互保护对干酪乳杆菌ATCC 393~(TM)存活的影响

【目的】以干酪乳杆菌典型株ATCC 393TM(Lactobacillus casei ATCC 393TM)为实验菌株,研究其在多重胁迫环境下的交互保护应答机制。【方法】比较不同亚适应条件(热、H2O2、酸、胆盐)处理后菌体细胞在热致死条件(60℃)及氧致死条件H2O2(5mmol/L)下的存活率变化,并集中考察了最佳亚适应条件-酸适应的不同处理方式对细胞交互保护存活率、胞内pH以及脂肪酸含量的影响。【结果】交互保护对干酪乳杆菌ATCC393生理活性的影响因亚适应及致死条件而异:酸胁迫预适应能够显著提高细胞的交互胁迫抗性,其中,盐酸预适应的交互保护效果优于乳酸,其预适应引发的生理应答效应使细胞在应对热致死和氧致死胁迫时存活率分别提高了305倍和173倍;进一步的研究表明,酸预适应提高细胞存活率的作用机制可能与其能够显著改善胁迫环境下的胞内pH和细胞膜脂肪酸不饱和度相关。【结论】盐酸预适应对干酪乳杆菌典型株ATCC393的交互保护作用最为显著,并能够维持胁迫条件下细胞生理状态的相对稳定,本研究将有助于进一步解析干酪乳杆菌在对抗不同胁迫环境的过程中生理应答机制间的相互作用关系。     

Increasing Acidification of Nonreplicating Lactococcus lactis ΔthyA Mutants by Incorporating ATPase Activity

Lactococcus lactis MBP71 ΔthyA (thymidylate synthase) cannot synthesize dTTP de novo, and DNA replication is dependent on thymidine in the growth medium. In the nonreplicating state acidification by MBP71 was completely insensitive to bacteriophages (M. B. Pedersen, P. R. Jensen, T. Janzen, and D. Nilsson, Appl. Environ. Microbiol. 68:3010-3023, 2002). For nonreplicating MBP71 the biomass increased 3.3-fold over the first 3.5 h, and then the increase stopped. The rate of acidification increased 2.3-fold and then started to decrease. Shortly after inoculation the lactic acid flux was 60% of that of exponentially growing MBP71. However, when nonspecific ATPase activity was incorporated into MBP71, the lactic acid flux was restored to 100% but not above that point, indicating that control over the flux switched from ATP demand to ATP supply (i.e., to sugar transport and glycolysis). As determined by growing nonreplicating cells with high ATPase activity on various sugar sources, it appeared that glycolysis exerted the majority of the control. ATPase activity also stimulated the rate of acidification by nonreplicating MBP71 growing in milk, and pH 5.2 was reached 40% faster than it was without ATPase activity. We concluded that ATPase activity is a functional means of increasing acidification by nonreplicating L. lactis.     

Bioenergetic mechanism for nisin resistance, induced by the acid tolerance response of Listeria monocytogenes

This study examined the bioenergetics of Listeria monocytogenes, induced to an acid tolerance response (ATR). Changes in bioenergetic parameters were consistent with the increased resistance of ATR-induced (ATR(+)) cells to the antimicrobial peptide nisin. These changes may also explain the increased resistance of L. monocytogenes to other lethal factors. ATR(+) cells had lower transmembrane pH (DeltapH) and electric potential (Deltapsi) than the control (ATR(-)) cells. The decreased proton motive force (PMF) of ATR(+) cells increased their resistance to nisin, the action of which is enhanced by energized membranes. Paradoxically, the intracellular ATP levels of the PMF-depleted ATR(+) cells were approximately 7-fold higher than those in ATR(-) cells. This suggested a role for the F(o)F(1) ATPase enzyme complex, which converts the energy of ATP hydrolysis to PMF. Inhibition of the F(o)F(1) ATPase enzyme complex by N'-N'-1,3-dicyclohexylcarbodiimide increased ATP levels in ATR(-) but not in ATR(+) cells, where ATPase activity was already low. Spectrometric analyses (surface-enhanced laser desorption ionization-time of flight mass spectrometry) suggested that in ATR(+) listeriae, the downregulation of the proton-translocating c subunit of the F(o)F(1) ATPase was responsible for the decreased ATPase activity, thereby sparing vital ATP. These data suggest that regulation of F(o)F(1) ATPase plays an important role in the acid tolerance response of L. monocytogenes and in its induced resistance to nisin.     

Characteristics of subunit composition of H+-ATPase from the anaerobic bacterium Lactobacillus casei

In the presence of Mg2+ or Ca2+ the membranes of the anaerobic glycolytic bacterium Lactobacillus casei hydrolyze 0.1-0.2 mumole ATP/min/mg of protein with a pH optimum 6.4. This activity is inhibited by N,N'-dicyclohexylcarbodiimide and is insensitive to oligomycin, ouabain, vanadate and hydroxylamine. A soluble ATPase was isolated and purified from L. casei membranes. The specific activity of this ATPase is 3.0-4.0 mumole ATP/min/mg of protein. The enzyme homogeneity was established by analytical polyacrylamide gel disc electrophoresis and by analytical centrifugation (S20, omega = 12 +/- 0,5). The molecular weight of the enzyme is 270 000. Polyacrylamide gel electrophoresis of ATPase denaturated by 1% SDS and 8 M urea in the presence of SDS revealed one type of subunits with Mr = 43 000. These subunits could not be separated by isoelectrofocusing in polyacrylamide gel in the presence of 8 M urea and migrated as a single peptide with pI at 4.2. The experimental results suggest that the soluble ATPase from L. casei consists of six identical subunits with Mr of 43 000.