Acid tolerance of Streptococcus macedonicus as assessed by flow cytometry and single-cell sorting

An in situ flow cytometric viability assay employing carboxyfluorescein diacetate and propidium iodide was used to identify Streptococcus macedonicus acid tolerance phenotypes. The logarithmic-phase acid tolerance response (L-ATR) was evident when cells were (i) left to autoacidify unbuffered medium, (ii) transiently exposed to nonlethal acidic pH, or (iii) systematically grown under suboptimal acidic conditions (acid habituation). Stationary-phase ATR was also detected; this phenotype was gradually degenerated while cells resided at this phase. Single-cell analysis of S. macedonicus during induction of L-ATR revealed heterogeneity in both the ability and the rate of tolerance acquisition within clonal populations. L-ATR was found to be partially dependent on de novo protein synthesis and compositional changes of the cell envelope. Interestingly, acid-habituated cells were interlaced in lengthier chains and exhibited an irregular pattern of active peptidoglycan biosynthesis sites when probed with BODIPY FL vancomycin. L-ATR caused cells to retain their membrane potential after lethal challenge, as judged by ratiometric analysis with oxonol [DiBAC(4)(3)]. Furthermore, F-ATPase was important during the induction of L-ATR, but in the case of a fully launched response, inhibition of F-ATPase affected acid resistance only partially. Activities of both F-ATPase and the glucose-specific phosphoenolpyruvate-dependent phosphotransferase system were increased after L-ATR induction, distinguishing S. macedonicus from oral streptococci. Finally, the in situ viability assessment was compared to medium-based recovery after single-cell sorting, revealing that the culturability of subpopulations with identical fluorescence characteristics is dependent on the treatments imposed to the cells prior to acid challenge.     

Acid adaptation and biocontrol efficacy of antagonistic marine yeast Rhodosporidium paludigenum

The objectives of this work were to assess the optimum conditions for induction of acid tolerance in the marine yeast Rhodosporidium paludigenum and evaluate the biocontrol activity of non-adapted and acid-adapted yeasts in controlling apple blue mold caused by Penicillium expansum. R. paludigenum grown in malic and lactic acid treatments were stimulated after 12 h incubation. Moreover, medium modified with malic and lactic acid significantly enhanced the acid tolerance of R. paludigenum (p?<?0.05). In acid tolerance response test, the highest viability of R. paludigenum was obtained at initial pH of 5.5 in the NYDB medium modified with malic acid (91.6 %). In addition, all R. paludigenum treatments significantly reduced the disease incidences and lesion diameters of blue mold in apples. Furthermore, there was no significant difference between acid-adapted and unadapted yeasts in the apple wounds after 48 h dynamics. Acid stress improved R. paludigenum viability under acidic conditions. However, there was no significant difference between acid-adapted and unadapted yeasts in controlling P. expansum on apple fruit (p?<?0.05). These results indicate the potential for maintaining the survival level of biocontrol agents by physiological inducement strategy.     

Abscisic Acid-induced chilling tolerance in maize suspension-cultured cells

The induction of chilling tolerance by abscisic acid (ABA) in maize (Zea mays L. cv Black Mexican Sweet) suspension cultured cells was examined. Cell viability during exposure to chilling was estimated by triphenyl tetrazolium chloride reduction immediately after chilling and a filter paper growth assay. Both methods yielded comparable results. Chilling tolerance was induced by transferring 5-day-old cultures (late log phase) to a fresh medium containing ABA (10 to 100 micromolar). The greatest chilling tolerance was achieved with ABA at 100 micromolar. Growth of cells was inhibited at this concentration. After a 7-day exposure to 4°C in the dark, the survival of ABA-treated cells (100 micromolar ABA, 28°C for 24 h in the dark) was sevenfold greater than untreated cells. Effective induction of chilling tolerance was first observed when cells were held at 28°C for 6 hours after adding ABA. No tolerance was induced if the culture was chilled at the inception of ABA treatment. Induction of chilling tolerance was inhibited by cycloheximide. These results indicate that ABA is capable of inducing chilling tolerance when ABA-treated cells are incubated at a warm temperature before exposure to chilling, and this induction requires de novo synthesis of proteins.     

Acid Tolerance of Biofilm Cells of Streptococcus mutans

Streptococcus mutans, a member of the dental plaque community, has been shown to be involved in the carious process. Cells of S. mutans induce an acid tolerance response (ATR) when exposed to sublethal pH values that enhances their survival at a lower pH. Mature biofilm cells are more resistant to acid stress than planktonic cells. We were interested in studying the acid tolerance and ATR-inducing ability of newly adhered biofilm cells of S. mutans. All experiments were carried out using flow-cell systems, with acid tolerance tested by exposing 3-h biofilm cells to pH 3.0 for 2 h and counting the number of survivors by plating on blood agar. Acid adaptability experiments were conducted by exposing biofilm cells to pH 5.5 for 3 h and then lowering the pH to 3.5 for 30 min. The viability of the cells was assessed by staining the cells with LIVE/DEAD BacLight viability stain. Three-hour biofilm cells of three different strains of S. mutans were between 820- and 70,000-fold more acid tolerant than corresponding planktonic cells. These strains also induced an ATR that enhanced the viability at pH 3.5. The presence of fluoride (0.5 M) inhibited the induction of an ATR, with 77% fewer viable cells at pH 3.5 as a consequence. Our data suggest that adhesion to a surface is an important step in the development of acid tolerance in biofilm cells and that different strains of S. mutans possess different degrees of acid tolerance and ability to induce an ATR.     

Understanding the acid tolerance response of bifidobacteria

Aims: To investigate the effect of pH on the viability and the acid tolerance response (ATR) of bifidobacteria. Methods and Results: The impact of low pH on the viability of five species of bifidobacteria was examined under conditions of strict anaerobiosis. Although differences in the ability to resist the lethal effects of low pH were apparent among the species, cell viability could be improved by the provision of fermentable substrate during an acidic pH stress or through the use of stationary phase cells. While a stationary phase ATR was found to occur in two species of bifidobacteria, there was no adaptive response in exponential phase cells. Proteomic analysis of exponential phase Bifidobacterium longum subjected to a mild acid pre‐exposure (pH 4·5, 2 h) prior to an acid challenge revealed a substantial loss in the total number of cellular proteins. In contrast, proteomic analysis of stationary phase cells revealed an increased abundance of proteins associated with the general stress response as well as the β‐subunit of the F₀F₁‐ATPase, known to be important in bifidobacteria acid tolerance. Conclusion: Neither Bif. longum or Bifidobacterium breve possesses an inducible exponential phase ATR. Significance and Impact of the Study: These findings provide further insights into the impact of pH on the viability of bifidobacteria and may partially explain the loss in viability associated with their storage in acid foods.     

Abscisic acid is involved in brassinosteroids-induced chilling tolerance in the suspension cultured cells from Chorispora bungeana

The objective of this study was to investigate whether abscisic acid (ABA), a second messenger in chilling stress responses, is involved in brassinosteroids (BRs)-induced chilling tolerance in suspension cultured cells from Chorispora bungeana. The suspension cells were treated with 24-epibrassinolide (EBR), ABA, ABA biosynthesis inhibitor fluridone (Flu) and EBR in combination with Flu. Their effects on chilling tolerance, reactive oxygen species (ROS) levels and antioxidant defense system were analyzed. The results showed that EBR treatment markedly alleviated the decrease of cell viability and the increases of ion leakage and lipid peroxidation induced by chilling stress, suggesting that application of EBR could improve the chilling tolerance of C. bungeana suspension cultures. In addition, similar results were observed when exogenous ABA was applied. Treatment with Flu alone and in combination with EBR significantly suppressed cell viability and increased ion leakage and lipid peroxidation under low temperature conditions, indicating that the inhibition of ABA biosynthesis could decrease the chilling tolerance of C. bungeana suspension cultures and the EBR-enhanced chilling tolerance. Further analyses showed that EBR and ABA enhanced antioxidant defense and slowed down the accumulation of ROS caused by chilling. However, Flu application differentially blocked these protective effects of EBR. Moreover, EBR was able to mimic the effect of ABA by markedly increasing ABA content in the suspension cells under chilling conditions, whereas the EBR-induced ABA accumulation was inhibited by the addition of Flu. Taken together, these results demonstrate that EBR may confer chilling tolerance to C. bungeana suspension cultured cells by enhancing the antioxidant defense system, which is partially mediated by ABA, resulting in preventing the overproduction of ROS to alleviate oxidative injury induced by chilling.     

Dry artificial seeds and desiccation tolerance induction in microspore-derived embryos of broccoli

Desiccation tolerance of broccoli microspore-derived embryos was induced by exogenous application of abscisic acid (ABA). Embryos, which were desiccated to about 10% water content, were estimated for viability after rehydration. Survival was dependent on the ABA concentration and the development stage of embryo, but not on the length of exposure period to ABA or genotype. Cotyledonary stage embryos acquired the highest desiccation tolerance when treated with 1×10^-4M ABA. Under this condition, on average 27–48% of the desiccated embryos could convert into plants. Embryos treated with 1×10^-6M ABA or no ABA or earlier development-staged embryos, such as globular and heart stages, lost viability after desiccation. A one day exposure to ABA had the similar effect on the induction of desiccation tolerance as a 7-day treatment. The dried embryos maintained their ability of plant conversion after three months of storage under room conditions. The plants derived from the desiccated embryos were not different in the morphology or ploidy level from those from non-desiccated ones.Abbreviations ABA abscisic acid - RH relative humidity     

Hypervirulent-Host-Associated Citrobacter rodentium Cells Have Poor Acid Tolerance

Enhanced virulence or infectivity after passage through a mammalian host has been reported for a number of enteric food-borne pathogens. Citrobacter rodentium is a mouse pathogen that mimics many aspects of enterohemorrhagic Escherichia coli infection of humans and serves as a useful model for studying virulence mechanisms. Emergence of a hyperinfectious state after passage through mouse gastrointestinal tract was reported for C. rodentium. We wanted to investigate if increased acid tolerance could explain hypervirulence status of C. rodentium. Although we were able to observe hyperinfectious state of C. rodentium upon host passage, the cells were extremely acid sensitive. Growth under mildly acidic conditions (LB-MES, pH 5.5) induced acid tolerance of C. rodentium, but did not improve the organism’s ability to establish infection. Growth under anaerobic environment on fecal components also did not induce hyperinfectious state. Thus, contrary to conventional anticipation, hypervirulent C. rodentium cells were found to be acid sensitive thereby revealing limitations of the role of mouse gastric acidity by itself in elucidating the hypervirulent phenotype.     

The induction of hapten-specific immunological tolerance and immunity in B lymphocytes. V. Evidence for b-cell deletion in vitro with serum from tolerant mice.

The serum from mice that had been rendered specifically tolerant (TolS) to the trinitrophenyl (TNP) hapten by the injection of trinitrobenzenesulfonic acid (TNBS) is effective in the in vitro induction of immunological unresponsiveness in murine spleen cells. This tolerance system was investigated with particular emphasis upon the mode of induction. The observed inhibition by TolS of responses to the thymic-independent (TI) antigen TNP-lipopolysaccharide (TNP-LPS) was stable following adoptive transfer to lethally irradiated recipients and was due neither to the delay of in vitro responsiveness nor to effector cell blockade at the level of the antibody-forming cell. Neither suppressor cells nor cell-bound tolerogen carry-over were responsible for the tolerance induced by TolS. TNP-LPS doses, including a wide range of polyclonal activating concentrations, were ineffective in reversing the unresponsive state induced by cocultivation with TolS. Additionally, unconjugated LPS in either fetal calf serum (FCS)-containing or FCS-free cultures did not break tolerance. This failure of polyclonal activating substances to reverse the unresponsive state suggests that blockade of TNP-specific receptors is not the mechanism of tolerogenesis, since such compounds trigger cells polyclonally through nonimmunoglobulin receptors. Tolerance induced by incubation of spleen cells with TolS for 24 hr followed by extensive washing was stable whether the immunogenic stimulus was the TI antigen TNP-LPS or the thymic-dependent (TD) form of the hapten, TNP-sheep erythrocytes (TNP-SRC). Washing spleen cells at elevated temperatures after preculturing with TolS to avoid possible reassociation of surface Ig (sIg)-bound TNP conjugates did not lead to escape from tolerance. Antigen-free incubation for 24 hr following cultivation with TolS was equally unsuccessful in reversing the unresponsive state. Thus, extensive washing following tolerance induction and antigen-free cultivation where unblocking or turnover and resynthesis of sIg receptors should have taken place provided no support for receptor blockade as the mode of in vitro induction and maintenance of tolerance by TolS. Treatment with the proteolytic enzyme pronase with the intention of removing potential tolerogen from the cell surface revealed a stable tolerant state. Incubation with anti-Ig or anti-TNP antisera under conditions designed to allow capping and removal of sIg-bound tolerogen or surface-bound TNP conjugates also failed to reverse the tolerance induced by incubation with TolS. The results presented here and previously lend no support to active or passive suppression or blockade of reactive cells as the mechanism of tolerance induction in vitro by TolS. The data are consistent with the hypothesis that TolS-induced unresponsiveness is due to a functional deletion of TNP-specific B lymphocytes. Furthermore, the similarities observed between the induction of tolerance by TNBS injection and TolS-induced unresponsiveness are consistent with the suggestion that TNBS-induced tolerance in vivo is mediated by a component of TolS which is active as a tolerogen in vitro.     

Trinitrobenzene sulfonic acid effects in two amphibian model systems

The induction of hapten-specific tolerance was investigated in two amphibia, Notophthalmus viridescens and Xenopus laevis. Responses to trinitrophenylated (TNP)-Ficoll and TNP-lipopolysaccharide (LPS), as well as to horse erythrocytes (HRBC) were examined in both species, following an intraperitoneal injection of 2,4,6-trinitrobenzenesulfonic acid (TNBS). The less evolutionarily advanced newt, Notophthalmus, failed to respond to all three immunogens after TNBS administration. While Xenopus became completely tolerant upon challenge with TNP-Ficoll and partially tolerant with TNP-LPS, full capacity to respond to HRBC was retained. Therefore, specific tolerance was induced in Xenopus, but not in Notophthalmus. The tolerance with TNP-Ficoll in the toad, Xenopus, was short lived and return to responsiveness appeared to be related inversely to levels of TNP protein in the sera of TNBS-treated animals. The thymic dependence of this tolerance could not be determined, because adult thymectomy (ATx) abrogated the response to TNP-Ficoll in control nontolerized animals. Responses to TNP-LPS and HRBC were unaffected by ATx. These data, in conjunction with TNBS-induced differential tolerance to the TNP moiety, suggest carrier-dependent hapten-specific B-cell heterogeneity in the toad which differs in certain ways from that recently described for murine systems.     

Anaerobic Killing of Oral Streptococci by Reduced, Transition Metal Cations

Reduced, transition metal cations commonly enhance oxidative damage to cells caused by hydroperoxides formed as a result of oxygen metabolism or added externally. As expected, the cations Fe²⁺ and Cu⁺ enhanced killing of Streptococcus mutans GS-5 by hydroperoxides. However, unexpectedly, they also induced lethal damage under fully anaerobic conditions in a glove box with no exposure to O₂ or hydroperoxides from initial treatment with the cations. Sensitivities to anaerobic killing by Fe²⁺ varied among the organisms tested. The oral streptococci Streptococcus gordonii ATCC 10558, Streptococcus rattus FA-1, and Streptococcus sanguis NCTC 10904 were approximately as sensitive as S. mutans GS-5. Enterococcus hirae ATCC 9790, Actinomyces viscosus OMZ105E, and Actinomyces naeslundii WVU45 had intermediate sensitivity, while Lactobacillus casei ATCC 4646 and Escherichia coli B were insensitive. Killing of S. mutans GS-5 in response to millimolar levels of added Fe²⁺ occurred over a wide range of temperatures and pH. The organism was able to take up ferrous iron, but ferric reductase activity could not be detected. Chelators, uric acid, and thiocyanate were not effective inhibitors of the lethal damage. Sulfhydryl compounds, ferricyanide, and ferrocyanide were protective if added prior to Fe²⁺ exposure. Fe²⁺, but not Fe³⁺, acted to reduce the acid tolerance of glycolysis by intact cells of S. mutans. The reduction in acid tolerance appeared to be related directly to Fe²⁺ inhibition of F-ATPase, which could be assayed with permeabilized cells, isolated membranes, or F₁ enzyme separated from membranes. Cu⁺ and Cu²⁺ also inhibited F-ATPase and sensitized glycolysis by intact cells to acid. All of these damaging actions occurred anaerobically and thus did not appear to involve reactive oxygen species.     

Alteration of Gene Expression during the Induction of Freezing Tolerance in Brassica napus Suspension Cultures

Brassica napus suspension-cultured cells can be hardened to a lethal temperature for 50% of the sample of −20°C in eight days at room temperature with abscisic acid. During the induction of freezing tolerance, changes were observed in the electrophoretic pattern of [³⁵S]methionine labeled polypeptides. In hardening cells, a 20 kilodalton polypeptide was induced on day 2 and its level increased during hardening. The induction of freezing tolerance with nonmaximal hardening regimens also resulted in increases in the 20 kilodalton polypeptide. The 20 kilodalton polypeptide was associated with a membrane fraction enriched in endoplasmic reticulum and was resolved as a single spot by two-dimensional electrophoresis. In vitro translation of mRNA indicate alteration of gene expression during abscisic acid induction of freezing tolerance. The new mRNA encodes a 20 kilodalton polypeptide associated with increased freezing tolerance induced by either abscisic acid or high sucrose. A 20 kilodalton polypeptide was also translated by mRNA isolated from cold-hardened B. napus plants.     

Prenylation Inhibition-Induced Cell Death in Melanoma: Reduced Sensitivity in BRAF Mutant/PTEN Wild-Type Melanoma Cells

While targeted therapy brought a new era in the treatment of BRAF mutant melanoma, therapeutic options for non-BRAF mutant cases are still limited. In order to explore the antitumor activity of prenylation inhibition we investigated the response to zoledronic acid treatment in thirteen human melanoma cell lines with known BRAF, NRAS and PTEN mutational status. Effect of zoledronic acid on proliferation, clonogenic potential, apoptosis and migration of melanoma cells as well as the activation of downstream elements of the RAS/RAF pathway were investigated in vitro with SRB, TUNEL and PARP cleavage assays and videomicroscopy and immunoblot measurements, respectively. Subcutaneous and spleen-to-liver colonization xenograft mouse models were used to evaluate the influence of zoledronic acid treatment on primary and disseminated tumor growth of melanoma cells in vivo. Zoledronic acid more efficiently decreased short-term in vitro viability in NRAS mutant cells when compared to BRAF mutant and BRAF/NRAS wild-type cells. In line with this finding, following treatment decreased activation of ribosomal protein S6 was found in NRAS mutant cells. Zoledronic acid demonstrated no significant synergism in cell viability inhibition or apoptosis induction with cisplatin or DTIC treatment in vitro. Importantly, zoledronic acid could inhibit clonogenic growth in the majority of melanoma cell lines except in the three BRAF mutant but PTEN wild-type melanoma lines. A similar pattern was observed in apoptosis induction experiments. In vivo zoledronic acid did not inhibit the subcutaneous growth or spleen-to-liver colonization of melanoma cells. Altogether our data demonstrates that prenylation inhibition may be a novel therapeutic approach in NRAS mutant melanoma. Nevertheless, we also demonstrated that therapeutic sensitivity might be influenced by the PTEN status of BRAF mutant melanoma cells. However, further investigations are needed to identify drugs that have appropriate pharmacological properties to efficiently target prenylation in melanoma cells.     

Survival of Low-pH Stress by Escherichia coli O157:H7: Correlation between Alterations in the Cell Envelope and Increased Acid Tolerance

Survival of a nontoxigenic isolate of Escherichia coli O157:H7 at low pH (pH 3.0) was examined over prolonged time periods for each of three population types: exponential-phase cells, stationary-phase cells, and acid-adapted exponential-phase cells. In each population, approximately 5 × 10⁴ CFU ml⁻¹ were detected after a 24-h incubation at pH 3.0. Even after 3 days at pH 3.0, significant numbers of survivors from each of the three populations could be detected. The high level of acid tolerance exhibited by these survivors was found to be quickly lost once they were transferred to conditions which permitted growth to resume, indicating that they were not mutants. Proton flux measurements on the three populations of cells revealed that the initial rates of viability loss at pH 3.0 correlated well with net proton accumulation. Cells showing a high initial rate of viability loss (exponential-phase cells) accumulated protons at the highest rate, whereas resistant populations (adapted or stationary-phase cells) accumulated protons only slowly. Differences in the protein composition of the cell envelope between the three populations were studied by two-dimensional polyacrylamide gel electrophoresis. Complex differences in the pattern of proteins expressed by each population were uncovered. The implications of these findings are discussed in the context of a possible model accounting for acid tolerance in this important food-borne pathogen.     

Glucosylceramide Contained in Koji Mold-Cultured Cereal Confers Membrane and Flavor Modification and Stress Tolerance to Saccharomyces cerevisiae during Coculture Fermentation

In nature, different microorganisms create communities through their physiochemical and metabolic interactions. Many fermenting microbes, such as yeasts, lactic acid bacteria, and acetic acid bacteria, secrete acidic substances and grow faster at acidic pH values. However, on the surface of cereals, the pH is neutral to alkaline. Therefore, in order to grow on cereals, microbes must adapt to the alkaline environment at the initial stage of colonization; such adaptations are also crucial for industrial fermentation. Here, we show that the yeast Saccharomyces cerevisiae, which is incapable of synthesizing glucosylceramide (GlcCer), adapted to alkaline conditions after exposure to GlcCer from koji cereal cultured with Aspergillus kawachii. We also show that various species of GlcCer derived from different plants and fungi similarly conferred alkali tolerance to yeast. Although exogenous ceramide also enhanced the alkali tolerance of yeast, no discernible degradation of GlcCer to ceramide was observed in the yeast culture, suggesting that exogenous GlcCer itself exerted the activity. Exogenous GlcCer also increased ethanol tolerance and modified the flavor profile of the yeast cells by altering the membrane properties. These results indicate that GlcCer from A. kawachii modifies the physiology of the yeast S. cerevisiae and demonstrate a new mechanism for cooperation between microbes in food fermentation.     

F-ATPase of Drosophila melanogaster Forms 53-Picosiemen (53-pS) Channels Responsible for Mitochondrial Ca2+-induced Ca2+ Release

Mitochondria of Drosophila melanogaster undergo Ca²⁺-induced Ca²⁺ release through a putative channel (mCrC) that has several regulatory features of the permeability transition pore (PTP). The PTP is an inner membrane channel that forms from F-ATPase, possessing a conductance of 500 picosiemens (pS) in mammals and of 300 pS in yeast. In contrast to the PTP, the mCrC of Drosophila is not permeable to sucrose and appears to be selective for Ca²⁺ and H⁺. We show (i) that like the PTP, the mCrC is affected by the sense of rotation of F-ATPase, by Bz-423, and by Mg²⁺/ADP; (ii) that expression of human cyclophilin D in mitochondria of Drosophila S₂R⁺ cells sensitizes the mCrC to Ca²⁺ but does not increase its apparent size; and (iii) that purified dimers of D. melanogaster F-ATPase reconstituted into lipid bilayers form 53-pS channels activated by Ca²⁺ and thiol oxidants and inhibited by Mg²⁺/γ-imino ATP. These findings indicate that the mCrC is the PTP of D. melanogaster and that the signature conductance of F-ATPase channels depends on unique structural features that may underscore specific roles in different species.     

Spermine Is a Salicylate-Independent Endogenous Inducer for Both Tobacco Acidic Pathogenesis-Related Proteins and Resistance against Tobacco Mosaic Virus Infection

Intercellular spaces are often the first sites invaded by pathogens. In the spaces of tobacco mosaic virus (TMV)-infected and necrotic lesion-forming tobacco (Nicotiana tabacum L.) leaves, we found that an inducer for acidic pathogenesis-related (PR) proteins was accumulated. The induction activity was recovered in gel-filtrated fractions of low molecular mass with a basic nature, into which authentic spermine (Spm) was eluted. We quantified polyamines in the intercellular spaces of the necrotic lesion-forming leaves and found 20-fold higher levels of free Spm than in healthy leaves. Among several polyamines tested, exogenously supplied Spm induced acidic PR-1 gene expression. Immunoblot analysis showed that Spm treatment increased not only acidic PR-1 but also acidic PR-2, PR-3, and PR-5 protein accumulation. Treatment of healthy tobacco leaves with salicylic acid (SA) caused no significant increase in the level of endogenous Spm, and Spm did not increase the level of endogenous SA, suggesting that induction of acidic PR proteins by Spm is independent of SA. The size of TMV-induced local lesions was reduced by Spm treatment. These results indicate that Spm accumulates outside of cells after lesion formation and induces both acidic PR proteins and resistance against TMV via a SA-independent signaling pathway.     

The adaptive acid response in Mesorhizobium sp.

Mesorhizobium huakuii strain LL56 and Mesorhizobium sp. strain LL22, which nodulate Lotus glaber, developed an adaptive acid response during exponential growth upon exposure to sublethal acid conditions. The adaptive acid response was found to be dependent on the sublethal pH and the strain intrinsic acid tolerance: the lowest adaptation pH was 4.0 for strain LL56 and 5.7 for strain LL22, and the lowest pH values tolerated after adaptation were 3.0 and 4.0, respectively. Both complex and minimal medium allowed the development of the adaptive acid response, although in complex medium this response was more effective. Three low molecular weight polypeptides (LMWPs) showed increased expression in strain LL56 during the adaptation to pH 4.0. However, the adaptive acid tolerance was only partially dependent on de novo protein synthesis, and constitutive systems may play a significant role on the acid tolerance of Mesorhizobium huakuii strain LL56.     

Very Low Ethanol Concentrations Affect the Viability and Growth Recovery in Post-Stationary-Phase Staphylococcus aureus Populations

Pharmaceuticals, culture media used for in vitro diagnostics and research, human body fluids, and environments can retain very low ethanol concentrations (VLEC) (≤0.1%, vol/vol). In contrast to the well-established effects of elevated ethanol concentrations on bacteria, little is known about the consequences of exposure to VLEC. We supplemented growth media for Staphylococcus aureus strain DSM20231 with VLEC (VLEC⁺ conditions) and determined ultramorphology, growth, and viability compared to those with unsupplemented media (VLEC⁻ conditions) for prolonged culture times (up to 8 days). VLEC⁺-grown late-stationary-phase S. aureus displayed extensive alterations of cell integrity as shown by scanning electron microscopy. Surprisingly, while ethanol in the medium was completely metabolized during exponential phase, a profound delay of S. aureus post-stationary-phase recovery (>48 h) was observed. Concomitantly, under VLEC⁺ conditions, the concentration of acetate in the culture medium remained elevated while that of ammonia was reduced, contributing to an acidic culture medium and suggesting decreased amino acid catabolism. Interestingly, amino acid depletion was not uniformly affected: under VLEC⁺ conditions, glutamic acid, ornithine, and proline remained in the culture medium while the uptake of other amino acids was not affected. Supplementation with arginine, but not with other amino acids, was able to restore post-stationary-phase growth and viability. Taken together, these data demonstrate that VLEC have profound effects on the recovery of S. aureus even after ethanol depletion and delay the transition from primary to secondary metabolite catabolism. These data also suggest that the concentration of ethanol needed for bacteriostatic control of S. aureus is lower than that previously reported.