Internal pH crisis, lysine decarboxylase and the acid tolerance response of Salmonella typhimurium

Salmonella typhimurium possesses an adaptive response to acid that increases survival during exposure to extremely low pH values. The acid tolerance response (ATR) includes both log-phase and stationary-phase systems. The log-phase ATR appears to require two components for maximum acid tolerance, namely an inducible pH homeostasis system, and a series of acid-shock proteins. We have discovered one of what appears to be a series of inducible exigency pH homeostasis systems that contribute to acid tolerance in extreme acid environments. The low pH-inducible lysine decarboxylase was shown to contribute significantly to pH homeostasis in environments as low as pH 3.0. Under the conditions tested, both lysine decarboxylase and σ^s-dependent acid-shock proteins were required for acid tolerance but only lysine decarboxylase contributed to pH homeostasis. The cadBA operon encoding lysine decarboxylase and a lysine/cadaverine antiporter were cloned from S. typhimurium and were found to be 79% homologous to the cadBA operon from Escherichia coli . The results suggest that S. typhimurium has a variety of means of fulfilling the pH homeostasis requirement of the ATR in the form of inducible amino acid decarboxylases.     

The acid tolerance response of Salmonella typhimurium involves transient synthesis of key acid shock proteins.

Although Salmonella typhimurium prefers neutral-pH environments, it can adapt to survive conditions of severe low-pH stress (pH 3.3). The process, termed the acid tolerance response (ATR), includes two distinct stages. The first stage, called pre-acid shock, is induced at pH 5.8 and involves the production of an inducible pH homeostasis system functional at external pH values below 4.0. The second stage occurs following an acid shock shift to pH 4.5 or below and is called the post-acid shock stage. During this stage of the ATR, 43 acid shock proteins (ASPs) are synthesized. The present data reveal that several ASPs important for pH 3.3 acid tolerance are only transiently produced. Their disappearance after 30 to 40 min of pH 4.4 acid shock coincides with an inability to survive subsequent pH 3.3 acid challenge. Clearly, an essential feature of inducible acid tolerance is an ability to synthesize these key ASPs. The pre-acid shock stage, with its inducible pH homeostasis system, offers the cell an enhanced ability to synthesize ASPs following rapid shifts to conditions below pH 4.0, an external pH that normally prevents ASP synthesis. The data also address possible signals for ASP synthesis. The inducing signal for 22 ASPs appears to be internal acidification, while external pH serves to induce 13 others. Of the 14 transient ASPs, 10 are induced in response to changes in internal pH. Mutations in the fur (ferric uptake regulator) locus that produce an Atr- acid-sensitive phenotype also eliminate induction of six transiently induced ASPs.     

Salmonella acid shock proteins are required for the adaptive acid tolerance response.

Salmonella typhimurium, as well as other enteric bacteria, experiences significant fluctuations in H+ ion concentrations during growth in diverse ecological niches. In fact, some pH conditions which should kill cells rapidly, such as stomach acidity, are nevertheless tolerated. The complete mechanism for this tolerance is unknown. However, I have recently demonstrated that S. typhimurium has the ability to survive extreme low pH (pH 3.0 to 4.0) if first adapted to mild pH (pH 5.5 to 6.0). This phenomenon has been referred to as the acidification tolerance response (ATR). The exposure to mild acid is referred to as preshock, and the proteins involved are called preshock ATR proteins. A second type of encounter with acid, called acid shock, involves shifting cells directly from alkaline conditions (pH 7.7) to acid conditions (pH 4.5 or below). During acid shock, the organism immediately ceases reproduction and dramatically changes the expression of at least 52 proteins. All but four are distinct from the preshock ATR proteins. Surprisingly, acid shock alone did not afford significant protection against strong acid challenge in minimal medium. Furthermore, inhibiting protein synthesis prior to acid shock revealed that the acid shock proteins do not appear to contribute to acid survival in minimal medium even at pH 4.3. Constitutive cellular pH homeostatic mechanisms seem sufficient to protect cells at this pH. The data suggest that the induction of acid shock and preshock ATR proteins are separate processes requiring separate signals. However, for S. typhimurium to survive extreme acid conditions, it must induce both the preshock and acid shock systems. Preventing the expression of one or the other eliminates acid tolerance. I propose a two-stage process that allows S. typhimurium to phase in acid tolerance as the environmental pH becomes progressively more acidic.     

Identification of Salmonella enterica serovar Typhimurium genes important for survival in the swine gastric environment

Since the stomach is a first line of defense for the host against ingested microorganisms, an ex vivo swine stomach contents (SSC) assay was developed to search for genes important for Salmonella enterica serovar Typhimurium survival in the hostile gastric environment. Initial characterization of the SSC assay (pH 3.87) using previously identified, acid-sensitive serovar Typhimurium mutants revealed a 10-fold decrease in survival for a phoP mutant following 20 min of challenge and no survival for mutants of rpoS or fur. To identify additional genes, a signature-tagged mutagenesis bank was constructed and screened in the SSC assay. Nineteen mutants were identified and individually analyzed in the SSC and acid tolerance response assays; 13 mutants exhibited a 10-fold or greater sensitivity in the SSC assay compared to the wild-type strain, but only 3 mutants displayed a 10-fold or greater decrease in survival following pH 3.0 acidic challenge. Further examination determined that the lethal effects of the SSC are pH dependent but that low pH is not the sole killing mechanism(s). Gas chromatography analysis of the SSC revealed lactic acid levels of 126 mM. Upon investigating the effects of lactic acid on serovar Typhimurium survival in a synthetic gastric fluid, not only was a concentration- and time-dependent lethal effect observed, but the phoP, rpoS, fur, and pnp genes were identified as involved in protection against lactic acid exposure. These studies indicate a role in gastric survival for several serovar Typhimurium genes and imply that the stomach environment is defined by more than low pH.     

Low-pH-induced effects on patterns of protein synthesis and on internal pH in Escherichia coli and Salmonella typhimurium

Escherichia coli and Salmonella typhimurium were grown in a supplemented minimal medium (SMM) at a pH of 7.0 or 5.0 or were shifted from pH 7.0 to 5.0. Two-dimensional gel electrophoretic analysis of proteins labeled with H2(35)SO4 for 20 min during the shift showed that in E. coli, 13 polypeptides were elevated 1.5- to 4-fold, whereas in S. typhimurium, 19 polypeptides were increased 2- to 14-fold over the pH 7.0 control. Upon long-term growth at pH 5.0, almost double the number of polypeptides were elevated twofold or more in S. typhimurium compared with E. coli. In E. coli, there was no apparent induction of heat shock proteins upon growth at pH 5.0 in SMM. However, growth of E. coli in a complex broth to pH 5.0, or subsequent growth of fresh E. coli cells in the filtrate from this culture, showed that a subset of five polypeptides is uniquely induced by low pH. Two of these polypeptides, D60.5, the inducible lysyl-tRNA synthetase, and C62.5, are known heat shock proteins. Measurements of the internal pH (pHi) and growth rates of both organisms were made during growth in SMM at pH 7.0, pH 5.0, and upon the pH shift. The data show that the pHi of E. coli decreases more severely than that of S. typhimurium at an external pH of 5.0; the growth rate of E. coli is about one-half that of S. typhimurium at this pH, whereas the two organisms have the same growth rate at pH 7.0. The two-dimensional gel, growth, and pHi experiments collectively suggest that, at least in SMM, S. typhimurium is more adaptive to low-pH stress than is E. coli.     

Low-pH-induced effects on patterns of protein synthesis and on internal pH in Escherichia coli and Salmonella typhimurium.

Escherichia coli and Salmonella typhimurium were grown in a supplemented minimal medium (SMM) at a pH of 7.0 or 5.0 or were shifted from pH 7.0 to 5.0. Two-dimensional gel electrophoretic analysis of proteins labeled with H2(35)SO4 for 20 min during the shift showed that in E. coli, 13 polypeptides were elevated 1.5- to 4-fold, whereas in S. typhimurium, 19 polypeptides were increased 2- to 14-fold over the pH 7.0 control. Upon long-term growth at pH 5.0, almost double the number of polypeptides were elevated twofold or more in S. typhimurium compared with E. coli. In E. coli, there was no apparent induction of heat shock proteins upon growth at pH 5.0 in SMM. However, growth of E. coli in a complex broth to pH 5.0, or subsequent growth of fresh E. coli cells in the filtrate from this culture, showed that a subset of five polypeptides is uniquely induced by low pH. Two of these polypeptides, D60.5, the inducible lysyl-tRNA synthetase, and C62.5, are known heat shock proteins. Measurements of the internal pH (pHi) and growth rates of both organisms were made during growth in SMM at pH 7.0, pH 5.0, and upon the pH shift. The data show that the pHi of E. coli decreases more severely than that of S. typhimurium at an external pH of 5.0; the growth rate of E. coli is about one-half that of S. typhimurium at this pH, whereas the two organisms have the same growth rate at pH 7.0. The two-dimensional gel, growth, and pHi experiments collectively suggest that, at least in SMM, S. typhimurium is more adaptive to low-pH stress than is E. coli.     

Molecular genetic analysis of the Escherichia coli phoP locus.

We have cloned the Escherichia coli phoP gene, a member of the family of environmentally responsive two-component systems, and found its deduced amino acid sequence to be 93% identical to that of the Salmonella typhimurium homolog, which encodes a major virulence regulator necessary for intramacrophage survival and resistance to cationic peptides of phagocytic cells. The phoP gene was mapped to kilobase 1202 on the Kohara map (25-min region) of the E. coli genome (Y. Kohara, K. Akiyama, and K. Isono, Cell 50:495-508, 1987) and found to be transcribed in a counterclockwise direction. Both E. coli and S. typhimurium phoP mutants were more sensitive than their isogenic wild-type strains to the frog-derived antibacterial peptide magainin 2, suggesting a role for PhoP in the response to various stresses in both enteric species.     

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.     

Acid-sensitive mutants of Salmonella typhimurium identified through a dinitrophenol lethal screening strategy.

Salmonella typhimurium exhibits a low-pH-inducible acid tolerance response (ATR) that can protect the adapted cell from severe acid challenge (pH 3.3). It is a two-stage system, with some proteins induced at pH 5.8 (pre-acid shock) and others induced below pH 4.5 (acid shock). The genetics of acid resistance was investigated through the use of a new screening medium. The medium contained 200 microM dinitrophenol (DNP) and was adjusted to pH 4.7 to 4.8. The medium will lower the internal pH of cells to a lethal level. However, cells capable of mounting an ATR will survive longer on this medium than acid-intolerant cells. Using this DNP lethal screening strategy, we isolated several acid-sensitive insertion mutants. Some mutants were defective in the pre-acid shock ATR stage but exhibited a normal or nearly normal post-acid shock-induced acid tolerance (atrB and atrC). Others could not induce acid tolerance by using either pre- or post-acid shock strategies (atrD, atrF, and atrG). The atrB locus was found to be part of a regulon under the control of a trans-acting regulator, atbR. An insertion in atbR caused constitutive acid tolerance because of overexpression of the regulon. Mutations in atrD and atrF affected iron metabolism and, in a manner analogous to ferric uptake regulator (fur) mutations, diminished acid resistance. The atrF mutation mapped within the ent cluster, probably in a fep uptake locus. The atrD locus mapped near metC and may represent an insertion into the S. typhimurium homolog of the Escherichia coli exbB or exbD locus. The mutation in atrC caused extreme UV light sensitivity and proved to occur within the polA (DNA polymerase I) locus. The results support the concept of overlapping acid protection systems in S. typhimurium.     

Inducible pH homeostasis and the acid tolerance response of Salmonella typhimurium.

The acid tolerance response (ATR) is an adaptive system triggered at external pH (pHo) values of 5.5 to 6.0 that will protect cells from more severe acid stress (J. Foster and H. Hall, J. Bacteriol. 172:771-778, 1990). Correlations between the internal pH (pHi) of adapted versus unadapted cells at pHo of 3.3 indicate that the ATR system produces an inducible pH-homeostatic function. This function serves to maintain the pHi above 5 to 5.5. Below this range, cells rapidly lose viability. Development of this pH homeostasis mechanism was sensitive to protein synthesis inhibitors and operated only to augment the pHi at pHo values below 4. In contrast, classical constitutive pH homeostasis was insensitive to protein synthesis inhibitors and was efficient only at pHo values above 4. Physiological studies indicated an important role for the Mg(2+)-dependent proton-translocating ATPase in affording ATR-associated survival during exposure to severe acid challenges. Along with being acid intolerant, cells deficient in this ATPase did not exhibit inducible pH homeostasis. We speculate that adaptive acid tolerance is important to Salmonella species in surviving acid encounters in both the environment and the infected host.     

Regulation of nonspecific acid phosphatase in Salmonella: phoN and phoP genes.

Mutations in Salmonella typhimurium strains lacking nonspecific acid phosphatase mapped in two unlinked loci. One of these, phoP, was cotransducible by phage P22 with purB, whereas the second, phoN, was cotransducible by phage P1 with purA. Mutants with temperature-sensitive nonspecific acid phosphatase activity (measured in whole cells) were also isolated. A phoN mutant with thermolabile whole-cell activity was isolated directly from wild-type LT-2. Several other mutants with temperature-sensitive enzyme activity were also isolated as revertants of phoN mutants. These data suggest that phoN might be a structural locus for nonspecific acid phosphatase. The observation that a mutation resulting in high level of nonspecific acid phosphatase mapped in phoP suggests a possible regulatory role for this locus.     

Molecular analysis of the Salmonella typhimurium phoN gene, which encodes nonspecific acid phosphatase.

The phoN gene of Salmonella typhimurium encodes nonspecific acid phosphatase (EC 3.1.3.2), which is regulated by a two-component regulatory system consisting of the phoP and phoQ genes. We cloned the phoN region into a plasmid vector by complementation of a phoN mutant strain and determined the nucleotide sequence of the phoN gene and its flanking regions. The phoN gene could encode a 26-kDa protein, which was identified by the maxicell method as the product of phoN. Results of the enzyme assay and Southern hybridization with chromosomal DNA of Escherichia coli K-12 suggests that there is no phoN gene in E. coli. The regulatory pattern of phoN in E. coli and Southern hybridization analysis of the E. coli chromosome with the S. typhimurium phoP gene suggest that E. coli K-12 also harbors the phoP and phoQ genes.     

The quantitative genetic basis of adaptive divergence in the moor frog (Rana arvalis) and its implications for gene flow

Knowledge on the relative contribution of direct genetic, maternal and environmental effects to adaptive divergence is important for understanding the drivers of biological diversification. The moor frog (Rana arvalis) shows adaptive divergence in embryonic and larval fitness traits along an acidification gradient in south-western Sweden. To understand the quantitative genetic basis of this divergence, we performed reciprocal crosses between three divergent population pairs and reared embryos and larvae at acid and neutral pH in the laboratory. Divergence in embryonic acid tolerance (survival) was mainly determined by maternal effects, whereas the relative contributions of maternal, additive and nonadditive genetic effects in larval life-history traits differed between traits, population pairs and rearing environments. These results emphasize the need to investigate the quantitative genetic basis of adaptive divergence in multiple populations and traits, as well as different environments. We discuss the implications of our findings for maintenance of local adaptation in the context of migrant and hybrid fitness.     

The PhoP-PhoQ two-component regulatory system of Photorhabdus luminescens is essential for virulence in insects

Photorhabdus luminescens is a symbiont of entomopathogenic nematodes. Analysis of the genome sequence of this organism revealed a homologue of PhoP-PhoQ, a two-component system associated with virulence in intracellular bacterial pathogens. This organism was shown to respond to the availability of environmental magnesium. A mutant with a knockout mutation in the regulatory component of this system (phoP) had no obvious growth defect. It was, however, more motile and more sensitive to antimicrobial peptides than its wild-type parent. Remarkably, the mutation eliminated virulence in an insect model. No insect mortality was observed after injection of a large number of the phoP bacteria, while very small amounts of parental cells killed insect larvae in less than 48 h. At the molecular level, the PhoPQ system mediated Mg(2+)-dependent modifications in lipopolysaccharides and controlled a locus (pbgPE) required for incorporation of 4-aminoarabinose into lipid A. Mg(2+)-regulated gene expression of pbgP1 was absent in the mutant and was restored when phoPQ was complemented in trans. This finding highlights the essential role played by PhoPQ in the virulence of an entomopathogen.     

Unshelled abalone and corrupted urchins: development of marine calcifiers in a changing ocean

The most fragile skeletons produced by benthic marine calcifiers are those that larvae and juveniles make to support their bodies. Ocean warming, acidification, decreased carbonate saturation and their interactive effects are likely to impair skeletogenesis. Failure to produce skeleton in a changing ocean has negative implications for a diversity of marine species. We examined the interactive effects of warming and acidification on an abalone (Haliotis coccoradiata) and a sea urchin (Heliocidaris erythrogramma) reared from fertilization in temperature and pH/pCO(2) treatments in a climatically and regionally relevant setting. Exposure of ectodermal (abalone) and mesodermal (echinoid) calcifying systems to warming (+2°C to 4°C) and acidification (pH 7.6-7.8) resulted in unshelled larvae and abnormal juveniles. Haliotis development was most sensitive with no interaction between stressors. For Heliocidaris, the percentage of normal juveniles decreased in response to both stressors, although a +2°C warming diminished the negative effect of low pH. The number of spines produced decreased with increasing acidification/pCO(2), and the interactive effect between stressors indicated that a +2°C warming reduced the negative effects of low pH. At +4°C, the developmental thermal tolerance was breached. Our results show that projected near-future climate change will have deleterious effects on development with differences in vulnerability in the two species.     

Vasoactive intestinal peptide (VIP) prevents killing of virulent and phoP mutant Salmonella typhimurium by inhibiting IFN-gamma stimulated NADPH oxidative pathways in murine macrophages

Vasoactive intestinal peptide is an immunomodulator with great potential in the treatment of inflammatory pathology. In this study, we have examined the effect of VIP on the growth dynamics of virulent Salmonella enterica. Serovar typhimurium (S. typhimurium) 14028 and 4/74 and an avirulent mutant (14028 phoP) in a murine, macrophage cell line (J774.2). In contrast to standard growth dynamics, in which phoP mutants do not survive in macrophages, we show that VIP (10(-10) M) significantly enhances phoP growth over a 24 h post-infection period even when the cells are co-cultured with IFN-gamma. We examined the effect of VIP on the generation of NADPH-induced reactive oxygen species (ROS) in Salmonella-infected/IFN-gamma cultured J774 cells. VIP inhibited gp91 mRNA levels, gp91 protein and subsequent ROS. The importance of ROS in killing of Salmonella by J774 cells was highlighted by experiments in which ROS production by J774 cells was inhibited using a conventional inhibitor, N-acetyl-L-cysteine captopril (ACC) and in which Salmonella growth significantly increased. Our findings suggest that although VIP inhibits inflammatory pathways in myeloid cells it also promotes the growth of avirulent (phoP) mutants.     

A low-pH-inducible, stationary-phase acid tolerance response in Salmonella typhimurium.

Acid is an important environmental condition encountered by Salmonella typhimurium during its pathogenesis. Our studies have shown that the organism can actively adapt to survive potentially lethal acid exposures by way of at least three possibly overlapping systems. The first is a two-stage system induced in response to low pH by logarithmic-phase cells called the log-phase acid tolerance response (ATR). It involves a major molecular realignment of the cell including the induction of over 40 proteins. The present data reveal that two additional systems of acid resistance occur in stationary-phase cells. One is a pH-dependent system distinct from log-phase ATR called stationary-phase ATR. It was shown to provide a higher level of acid resistance than log-phase ATR but involved the synthesis of fewer proteins. Maximum induction of stationary-phase ATR occurred at pH 4.3. A third system of acid resistance is not induced by low pH but appears to be part of a general stress resistance induced by stationary phase. This last system requires the alternative sigma factor, RpoS. Regulation of log-phase ATR and stationary-phase ATR remains RpoS independent. Although the three systems are for the most part distinct from each other, together they afford maximum acid resistance for S. typhimurium.