Multiple factors independently regulate hilA and invasion gene expression in Salmonella enterica serovar typhimurium.

HilA activates the expression of Salmonella enterica serovar Typhimurium invasion genes. To learn more about regulation of hilA, we isolated Tn5 mutants exhibiting reduced hilA and/or invasion gene expression. In addition to expected mutations, we identified Tn5 insertions in pstS, fadD, flhD, flhC, and fliA. Analysis of the pstS mutant indicates that hilA and invasion genes are repressed by the response regulator PhoB in the absence of the Pst high-affinity inorganic phosphate uptake system. This system is required for negative control of the PhoR-PhoB two-component regulatory system, suggesting that hilA expression may be repressed by PhoR-PhoB under low extracellular inorganic phosphate conditions. FadD is required for uptake and degradation of long-chain fatty acids, and our analysis of the fadD mutant indicates that hilA is regulated by a FadD-dependent, FadR-independent mechanism. Thus, fatty acid derivatives may act as intracellular signals to regulate hilA expression. flhDC and fliA encode transcription factors required for flagellum production, motility, and chemotaxis. Complementation studies with flhC and fliA mutants indicate that FliZ, which is encoded in an operon with fliA, activates expression of hilA, linking regulation of hilA with motility. Finally, epistasis tests showed that PhoB, FadD, FliZ, SirA, and EnvZ act independently to regulate hilA expression and invasion. In summary, our screen has identified several distinct pathways that can modulate S. enterica serovar Typhimurium's ability to express hilA and invade host cells. Integration of signals from these different pathways may help restrict invasion gene expression during infection.

The starvation-stress response (SSR) of Salmonella.

Salmonella serovars are common etiologic agents of intestinal-based disease of animals and humans. As a result of their lifestyle, salmonellae occupy and survive in a wide range of niches where they can encounter an even broader range of environmental stresses. One of the most common stresses is starvation for an essential nutrient such as a carbon/energy (C)-source. The genetic and physiologic changes that the bacterium undergoes in response to starvation-stress are referred to as the starvation-stress response or SSR. The genetic loci whose expression increases in response to the starvation-stress compose the SSR stimulon. Several loci of the SSR stimulon have been identified in Salmonella typhimurium and grouped, based on putative or known functions or products, into transport systems, C-compound catabolic enzymes, known protective enzymes, respiratory enzyme systems, regulatory proteins, virulence loci and unclassified products. The majority of loci identified are under positive control by the rpoS-encoded sigma factor, sigma S. However, a few are under (indirect) negative control by sigma S, but only during starvation-induced stationary phase. Most of the loci identified are also under either positive or negative control by the cAMP:CRP complex. For many, additional regulatory proteins (e.g. FadR, OxyR, and RelA and others) play a role in their regulation as well. Furthermore, most of the SSR loci identified are induced during other stresses or environmental conditions. For example, some are induced during P- or N-starvation, in addition to C-starvation; some are induced by extremes in pH or osmolarity; and some are induced in the intracellular environment of epithelial cells, and/or macrophages, and/or medium designed to mimic the intracellular milieu of mammalian cells (ISM). Several SSR loci are required for long-term starvation-survival (core SSR loci), e.g. narZ, dadA, stiC and rpoS. In addition, a few of the core SSR loci are also required for stress-specific-inducible and/or C-starvation-inducible resistance to H2O2 (e.g. stiC), thermal (e.g. stiC), and/or acid pH (e.g. narZ), challenge. Interestingly, C-starved cells are resistant to challenge with the antimicrobial peptide, polymyxin B. However, this resistance mechanism(s) is different from the resistance mechanisms for H2O2 and other environmental stresses. Furthermore, a link between the SSR and Salmonella virulence can be hypothesized since the two major regulators of the SSR, sigma s and cAMP:CRP, are required for full virulence of Salmonella. Moreover, the spv (Salmonella plasmid-associated virulence) genes, required for Salmonella to cause systemic disease, are C (and P- and N-)-starvation-inducible. However, a direct link between starvation-stress and virulence has not been established conclusively.

Starvation- and Stationary-phase-induced resistance to the antimicrobial peptide polymyxin B in Salmonella typhimurium is RpoS (sigma(S)) independent and occurs through both phoP-dependent and -independent pathways.

A common stress encountered by Salmonella serovars involves exposure to membrane-permeabilizing antimicrobial peptides and proteins such as defensins, cationic antibacterial proteins, and polymyxins. We wanted to determine if starvation induces cross-resistance to the membrane-permeabilizing antimicrobial peptide polymyxin B (PmB). We report here that starved and stationary-phase (Luria-Bertani [LB] medium) cells exhibited ca. 200- to 1,500-fold-higher (cross-)resistance to a 60-min PmB challenge than log-phase cells. Genetic analysis indicates that this PmB resistance involves both phoP-dependent and -independent pathways. Furthermore, both pathways were sigma(S) independent, indicating that they are different from other known sigma(S) -dependent cross-resistance mechanisms. Additionally, both pathways were important for PmB resistance early during C starvation and for cells in stationary phase in LB medium. However, only the phoP-independent pathway was important for P-starvation-induced PmB resistance and the sustained PmB resistance seen in 24-h-C-starved (and N-starved) or stationary-phase cells in LB medium. The results indicate the presence of an rpoS- and phoP-independent pathway important to starvation- and stationary-phase-induced resistance to membrane-permeabilizing antimicrobial agents.

Essential roles of core starvation-stress response loci in carbon-starvation-inducible cross-resistance and hydrogen peroxide-inducible adaptive resistance to oxidative challenge in Salmonella typhimurium.

The starvation-stress response (SSR) of Salmonella typhimurium encompasses the physiological changes that occur upon starvation for an essential nutrient, e.g. C-source. A subset of SSR genes, known as core SSR genes, are required for the long-term starvation survival of the bacteria. Four core SSR loci have been identified in S. typhimurium: rpoS, stiA, stiB, and stiC. Here we report that in S. typhimurium C-starvation induced a greater and more sustainable cross-resistance to oxidative challenge (15 mM hydrogen peroxide (H2O2) for 40 min) than either N- or P-starvation. Of the four core SSR loci, only rpoS and stiC mutants exhibited a defective C-starvation-inducible cross-resistance to H2O2 challenge. Interestingly, (unadapted) log-phase S. typhimurium rpoS and stiA mutants were very sensitive to oxidative challenge. Based on this, we determined if these core SSR loci were important for H2O2 resistance developed during a 60 min adaptive exposure to 60 microM H2O2 (adapted cells). Both unadapted and adapted rpoS and stiA mutants were hypersensitive to a H2O2 challenge. In addition, a stiB mutant exhibited normal adaptive resistance for the first 20 mins of H2O2 challenge but then rapidly lost viability, declining to a level of about 1.5% of the wild-type strain. The results of these experiments indicate that: (i) the rpoS and stiC loci are essential for the development of C-starvation-inducible cross-resistance to oxidative challenge, and (ii) the rpoS, stiA, and, in a delayed effect, stiB loci are needed for H2O2-inducible adaptive resistance to oxidative challenge. Moreover, we found that both stiA and stiB are induced by a 60 microM H2O2 exposure, but only stiA was regulated (repressed) by (reduced form) OxyR.

How Salmonella survive against the odds.

The enteric pathogen Salmonella typhimurium faces daunting odds during its voyages in the natural environment and through an infected host. It must manage stresses ranging from feast to famine, acid to base, and high to low osmolarity, among others, as well as counter various types of oxidative stress and a variety of antimicrobial peptides. The defenses used to survive these encounters can be specific or can provide cross protection to a variety of hostile conditions. Once inside a host, Salmonella spp. escape the extracellular environment and thus humoral immunity by invading professional and nonprofessional phagocytes in which a new set of challenges await. Some of these stresses are similar to those encountered in the natural environment (e.g. acid, starvation) but the bacterial response is complicated by the simultaneous occurrence of multiple stresses. S. typhimurium appears to sense various in vivo cues and responds by seducing the host signal-transduction pathways that are required to phagocytize the bacterial cell. The pathogen then calls upon components of its stress-response arsenal to survive the intracellular environment. These survival strategies enable the organism to persist in nature, where conditions are usually suboptimal, and equip the bacterium with pathogenic properties that, if successful, will provide it with a very rich and stress-free growth environment, a dead host.

RpoS is necessary for both the positive and negative regulation of starvation survival genes during phosphate, carbon, and nitrogen starvation in Salmonella typhimurium.

The starvation stress response of Salmonella typhimurium encompasses the genetic and physiologic changes that occur when this bacterium is starved for an essential nutrient such as phosphate (P), carbon (C), or nitrogen (N). The responses to the limitation of each of these nutrients involve both unique and overlapping sets of proteins important for starvation survival and virulence. The role of the alternative sigma factor RpoS in the regulation of the starvation survival loci, stiA, stiB, and stiC, has been characterized. RpoS (sigma S) was found to be required for the P, C, and N starvation induction of stiA and stiC. In contrast, RpoS was found to be required for the negative regulation of stiB during P and C starvation-induced stationary phase but not during logarithmic phase. This role was independent of the relA gene (previously found to be needed for stiB induction). The role of RpoS alone and in combination with one or more sti mutations in the starvation survival of the organism was also investigated. The results clearly demonstrate that RpoS is an integral component of the complex interconnected regulatory systems involved in S. typhimurium's response to nutrient deprivation. However, differential responses of various sti genes indicate that additional signals and regulatory proteins are also involved.

Starvation-inducible loci of Salmonella typhimurium: regulation and roles in starvation-survival.

Four starvation-inducible loci (stiA, stiB, stiC, and stiE) of Salmonella typhimurium have been extensively characterized as to their genetic and physiologic regulation, and their roles in survival during prolonged simultaneous phosphate (P)-, carbon (C)- and nitrogen (N)-starvation (PCN-starvation). Strains of S. typhimurium LT-2, isogenic with the exception of lacking either the stiA, stiB or stiC locus, died off more quickly and survived at much reduced levels compared with their wild-type parent. When certain sti mutations were combined in the same strain, we found that viability of these cultures declined even more rapidly, and starvation-survival was affected to levels over-and-above the additive effects of each individual mutation, indicating an epistatic relationship between these loci. All four sti loci were, directly or indirectly, under negative control by the crp gene product (cAMP receptor protein, CRP). With the exception of stiB, all were similarly regulated by the cya gene product (i.e., cAMP). This suggests that CRP acts alone, or with a signal molecule other than cAMP, to cause repression of the stiB locus. In addition, all four loci are under positive regulation by the relA gene product (i.e., ppGpp) during C- or N-starvation, but not P-starvation. Since not all relA-dependent sti loci are induced during both C- and N-starvation, we propose that two separate ppGpp-dependent pathways function during C-starvation and N-starvation, respectively. Possible models for separate P-, C- and N-starvation-induction pathways are discussed.

Regulation of NAD metabolism in Salmonella typhimurium: molecular sequence analysis of the bifunctional nadR regulator and the nadA-pnuC operon.

In Salmonella typhimurium, de novo synthesis of NAD is regulated through the transcriptional control of the nadA and nadB loci. Likewise, the pyridine nucleotide salvage pathway is controlled at pncB. The transcriptional expression of these three loci is coordinately regulated by the product of nadR. However, there is genetic evidence suggesting that NadR is bifunctional, serving in both regulatory and transport capacities. One class of mutations in the nadR locus imparts a transport-defective PnuA- phenotype. These mutants retain regulation properties but are unable to transport nicotinamide mononucleotide (NMN) intact across the cell membrane. Other nadR mutants lose both regulatory and transport capabilities, while a third class loses only regulatory ability. The unusual NMN transport activity requires both the PnuC and NadR proteins, with the pnuC locus residing in an operon with nadA. To prove that nadR encoded a single protein and to gain insight into a regulatory target locus, the nadR and nadA pnuC loci were cloned and sequenced. A DNA fragment which complemented both regulatory and transport mutations was found to contain a single open reading frame capable of encoding a 409-amino-acid protein (47,022 daltons), indicating that NadR is indeed bifunctional. Confirmation of the operon arrangement for nadA and pnuC was obtained through the sequence analysis of a 2.4-kilobase DNA fragment which complemented both NadA and PnuC mutant phenotypes. The nadA product, confirmed in maxicells, was a 365-amino-acid protein (40,759 daltons), while pnuC encoded a 322-amino-acid protein (36,930 daltons). The extremely hydrophobic (71%) nature of the PnuC protein indicated that it was an integral membrane protein, consistent with its central role in the transport of NMN across the cytoplasmic membrane. The results presented here and in previous studies suggest a hypothetical model in which NadR interacts with PnuC at low internal NAD levels, permitting transport of NMN intact into the cell. As NAD levels increase within the cell, the affinity of NadR for the operator regions of nadA, nadB, and pncB increases, repressing the transcription of these target genes.

Identification and characterization of starvation-regulated genetic loci in Salmonella typhimurium by using Mu d-directed lacZ operon fusions.

We used the technique of Mu d-directed lac operon fusion formation in an effort to identify loci in Salmonella typhimurium which are transcriptionally regulated by nutrient starvation conditions. We identified lacZ operon fusions in eight genetic loci, all of which exhibited increased transcription when starved for two or more of the following nutrients: nicotinate, phosphate, ammonium, glucose, and sulfate. The loci have been designated stiA to stiH for starvation-inducible loci. Mutations in two sti loci (stiC and stiD) significantly decreased cell viability during prolonged periods of nicotinate starvation, stiA and stiD are linked and map at 30 min. The stiC, stiE, stiG, and stiH loci mapped at approximately 77, 43, 88, and 56 min, respectively, on the S. typhimurium linkage map.

The pyridine nucleotide cycle of Salmonella typhimurium: genetic characterization of the pncXA operon.

A series of Mud1 and Tn10 insertions were identified in the pncA chromosome region of Salmonella typhimurium which is responsible for the production of nicotinamide deamidase. Both pncA (resulting in no nicotinamide deamidase activity) and pncX (resulting in lowered nicotinamide deamidase activity) insertions were constructed. In addition, mutants which could utilize nicotinamide as a sole source of nitrogen were isolated. These mutants, designated pncH, hyperproduce nicotinamide deamidase. Genetic studies utilizing pncX--lacZ and pncA--lacZ operon fusions indicate that pncX::Tn10 insertions reduce transcription of pncA--lac while pncH mutations increase the expression of both pncA--lacZ and pncX-lacZ. The gene order was determined as purB--pncA--pncX--gdh with transcription of both pncA and pncX occurring in the counterclockwise direction. Merodiploid studies suggest a model whereby pncX and pncA form an operon with the major promoter occurring upstream from pncX. A second, weaker promoter for pncA must be situated between pncX and pncA. The pncH mutations appear to occur in the pncX promoter (pncXp) increasing promoter activity.

Global control in Salmonella typhimurium: two-dimensional electrophoretic analysis of starvation-, anaerobiosis-, and heat shock-inducible proteins.

The response of Salmonella typhimurium to various forms of environmental stress was examined by using O'Farrell two-dimensional gel electrophoresis. Polypeptides (a total of 110) which quantitatively increased during various starvations, anaerobiosis, or heat shock were identified and cataloged in reference to a standard polypeptide map. Although significant overlap was noted during comparison of proteins induced by different starvations, only a few proteins produced during heat shock or anaerobiosis were also identified as starvation inducible.

Genetics of NAD metabolism in Salmonella typhimurium and cloning of the nadA and pnuC loci.

The nadA and pnuC loci of S. typhimurium were cloned and found to reside within a 2.2-kilobase region. Two-dimensional O'Farrell gel electrophoresis of the proteins produced after chloramphenicol amplification and subsequent release from chloramphenicol inhibition revealed NadA and PnuC to be 43,000- and 25,000-molecular-weight proteins, respectively. The data indicated that nadA and pnuC represent two distinct genes.

Phosphate starvation regulon of Salmonella typhimurium.

Several phosphate-starvation-inducible (psi) genetic loci in Salmonella typhimurium were identified by fusing the lacZ gene to psi promoters by using the Mu d1 and Mu d1-8 bacteriophages. Although several different starvation conditions were examined, the psi loci responded solely to phosphate deprivation. A regulatory locus, psiR, was identified as controlling the psiC locus. The psiR locus did not affect the expression of the Escherichia coli phoA locus or any of the other psi loci described.

Regulation of NAD biosynthesis in Salmonella typhimurium: expression of nad-lac gene fusions and identification of a nad regulatory locus.

Regulation of NAD biosynthesis was examined through the construction of nad-lac fusions in Salmonella typhimurium. The nadA (17 unit map position) and nadB (55 units) genetic loci involved with quinolinic acid biosynthesis were both found to be regulated by the product of a nadR locus (99 units) in a repression/derepression manner while nadC (3 units) expression appeared constitutive at the transcriptional level. Increases in nadAB transcription directly correlated with decreases in intracellular NAD(P) levels, and kinetic studies indicated that the NAD analogue 6-amino NAD was ineffective in repressing either nadA or nadB. The presence of cAMP + cAMP receptor protein was essential for the complete derepression of nadA while no effect was evident upon nadB. Transfer of cultures from aerobic to anaerobic conditions, however, resulted in the partial derepression of both nadA and nadB. Thus, there appears to be a very complex set of controls regulating NAD biosynthesis.

Genetic characterization of pyridine nucleotide uptake mutants of Salmonella typhimurium.

Two classes of pyridine nucleotide uptake mutants isolated previously in a strain of Salmonella typhimurium defective in both de novo NAD biosynthesis (nad) and pyridine nucleotide recycling (pncA) were analysed in terms of their genetic relationship to each other and their roles in the transport of nicotinamide mononucleotide as a precursor to NAD. The first class of uptake mutants, pnuA (99 units), failed to grow on nicotinamide mononucleotide (NMN) as a precursor for NAD. The second class, pnuB, grew on lower than normal levels of NMN and suppressed pnuA mutations. A third class of uptake mutant, pnuC, isolated in a nadB pncA pnuB background, also failed to grow on NMN. Transport studies and enzyme analyses confirmed these strains as defective in NMN uptake. A fourth locus, designated pnuD, was found to diminish NMN utilization in a nad pncA+ background. Tn10 insertions near pnuA, pnuC and pnuD were isolated and utilized in mapping studies. pnuA was found to map between thr and serB near trpR. The pnuC locus was cotransducible with nadA at 17 units while pnuD mapped at approximately 60 units. The biochemical and genetic data suggest that the pnuA and pnuC gene products cooperate in the utilization of NMN under normal conditions. A pnuB mutant, however, does not require the pnuA gene product for NMN uptake but does rely on the pnuC product. Fusion studies indicate that pnuC is regulated by internal NAD concentrations.