Characterization of an Acid-Inducible Sulfatase in Salmonella enterica Serovar Typhimurium

Sulfatases of enteric bacteria can provide access to heavily sulfated mucosal glycans. In this study, we show that aslA (STM0084) of Salmonella enterica serovar Typhimurium LT2 encodes a sulfatase that requires mildly acidic pH for its expression and activity. AslA is not regulated by sulfur compounds or tyramine but requires the EnvZ-OmpR and PhoPQ regulatory systems, which play an important role in pathogenesis.     

Curcumin Increases the Pathogenicity of Salmonella enterica Serovar Typhimurium in Murine Model

Curcumin has gained immense importance for its vast therapeutic and prophylactic applications. Contrary to this, our study reveals that it regulates the defense pathways of Salmonella enterica serovar Typhimurium (S. Typhimurium) to enhance its pathogenicity. In a murine model of typhoid fever, we observed higher bacterial load in Peyer''s patches, mesenteric lymph node, spleen and liver, when infected with curcumin-treated Salmonella. Curcumin increased the resistance of S. Typhimurium against antimicrobial agents like antimicrobial peptides, reactive oxygen and nitrogen species. This increased tolerance might be attributed to the up-regulation of genes involved in resistance against antimicrobial peptides - pmrD and pmrHFIJKLM and genes with antioxidant function - mntH, sodA and sitA. We implicate that iron chelation property of curcumin have a role in regulating mntH and sitA. Interestingly, we see that the curcumin-mediated modulation of pmr genes is through the PhoPQ regulatory system. Curcumin downregulates SPI1 genes, required for entry into epithelial cells and upregulates SPI2 genes required to intracellular survival. Since it is known that the SPI1 and SPI2 system can be regulated by the PhoPQ system, this common regulator could explain curcumin''s mode of action. This data urges us to rethink the indiscriminate use of curcumin especially during Salmonella outbreaks.     

Characteristics of Salmonella enterica Serovar 4,[5],12:i:- as a Monophasic Variant of Serovar Typhimurium

Salmonella enterica subspecies enterica serovar 4,[5],12:i:- (S. 4,[5]12:i:-) is believed to be a monophasic variant of S. enterica serovar Typhimurium (S. Typhimurium). This study was conducted to corroborate this hypothesis and to identify the molecular and phenotypic characteristics of the S. 4,[5]12:i:- isolates in Japan. A total of 51 S. 4,[5]12:i:- isolates derived from humans, cattle, swine, chickens, birds, meat (pork), and river water in 15 prefectures in Japan between 2000 and 2010 were analyzed. All the S. 4,[5],12:i:- isolates were identified as S. Typhimurium by two different polymerase chain reactions (PCR) for identification of S. Typhimurium. Of the 51 S. 4,[5],12:i:- isolates, 39 (76.5%) harbored a 94-kb virulence plasmid, which is known to be specific for S. Typhimurium. These data suggest that the S. 4,[5],12:i:- isolates are monophasic variants of S. Typhimurium. The flagellar phase variation is induced by three adjacent genes (fljA, fljB, and hin) in the chromosome. The results of PCR mapping of this region and comparative genomic hybridization analysis suggested that the deletion of the fljAB operon and its flanking region was the major genetic basis of the monophasic phenotype of S. 4,[5],12:i:-. The fljAB operon and hin gene were detectable in eight of the S. 4,[5],12:i:- isolates with common amino acid substitutions of A46T in FljA and R140L in Hin. The introduction of these mutations into S. Typhimurium isolates led to the loss of selectability of isolates expressing the phase 2 H antigen. These data suggested that a point mutation was the genetic basis, at least in part, of the S. 4,[5],12:i:- isolates. The results of phenotypic analysis suggested that the S. 4,[5],12:i:- isolates in Japan consist of multiple distinct clones. This is the first detailed characterization of the S. 4,[5],12:i:- isolates derived from various sources across Japan.     

Reporters for Single-Cell Analysis of Colicin Ib Expression in Salmonella enterica Serovar Typhimurium

Colicins are toxins that mediate interference competition in microbial ecosystems. They serve as a “common good” for the entire producer population but are synthesized by only few members which pay the costs of colicin production. We have previously shown that production of colicin Ib (cib), a group B colicin, confers a competitive advantage to Salmonella enterica serovar Typhimurium (S. Tm) over commensal E. coli strains. Here, we studied regulation of S. Tm cib expression at the single cell level. Comparative analysis of a single- and a multicopy gfp-reporter for the colicin Ib promoter (Pcib) revealed that the latter yielded optimal signal intensity for a diverse range of applications. We further validated this reporter and showed that gfp expression correlated well with colicin Ib (ColIb) protein levels in individual cells. Pcib is negatively controlled by two repressors, LexA and Fur. Only a small fraction of S. Tm expressed cib under non-inducing conditions. We studied Pcib activity in response to mitomycin C mediated DNA damage and iron limitation. Both conditions, if applied individually, lead to an increase in the fraction of GFP⁺ S. Tm, albeit an overall low fluorescence intensity. When both conditions were applied simultaneously, the majority of S. Tm turned GFP⁺ and displayed high fluorescence intensity. Thus, both repressors individually confine cib expression to a subset of the population. Taken together, we provide the first thorough characterization of a conventional gfp-reporter to study regulation of a group B colicin at the single cell level. This reporter will be useful to further investigate the costs and benefits of ColIb production in human pathogenic S. Tm and analyze cib expression under environmental conditions encountered in the mammalian gut.     

Low-Shear Modeled Microgravity Alters the Salmonella enterica Serovar Typhimurium Stress Response in an RpoS-Independent Manner

We have previously demonstrated that low-shear modeled microgravity (low-shear MMG) serves to enhance the virulence of a bacterial pathogen, Salmonella enterica serovar Typhimurium. The Salmonella response to low-shear MMG involves a signaling pathway that we have termed the low-shear MMG stimulon, though the identities of the low-shear MMG stimulon genes and regulatory factors are not known. RpoS is the primary sigma factor required for the expression of genes that are induced upon exposure to different environmental-stress signals and is essential for virulence in mice. Since low-shear MMG induces a Salmonella acid stress response and enhances Salmonella virulence, we reasoned that RpoS would be a likely regulator of the Salmonella low-shear MMG response. Our results demonstrate that low-shear MMG provides cross-resistance to several environmental stresses in both wild-type and isogenic rpoS mutant strains. Growth under low-shear MMG decreased the generation time of both strains in minimal medium and increased the ability of both strains to survive in J774 macrophages. Using DNA microarray analysis, we found no evidence of induction of the RpoS regulon by low-shear MMG but did find that other genes were altered in expression under these conditions in both the wild-type and rpoS mutant strains. Our results indicate that, under the conditions of these studies, RpoS is not required for transmission of the signal that induces the low-shear MMG stimulon. Moreover, our studies also indicate that low-shear MMG can be added to a short list of growth conditions that can serve to preadapt an rpoS mutant for resistance to multiple environmental stresses.     

Short-Term Signatures of Evolutionary Change in the Salmonella enterica Serovar Typhimurium 14028 Genome

Salmonella enterica serovar Typhimurium is a Gram-negative pathogen that causes gastroenteritis in humans and a typhoid-like disease in mice and is often used as a model for the disease promoted by the human-adapted S. enterica serovar Typhi. Despite its health importance, the only S. Typhimurium strain for which the complete genomic sequence has been determined is the avirulent LT2 strain, which is extensively used in genetic and physiologic studies. Here, we report the complete genomic sequence of the S. Typhimurium strain 14028s, as well as those of its progenitor and two additional derivatives. Comparison of these S. Typhimurium genomes revealed differences in the patterns of sequence evolution and the complete inventory of genetic alterations incurred in virulent and avirulent strains, as well as the sequence changes accumulated during laboratory passage of pathogenic organisms.The genomes of related bacteria can differ in three ways: (i) gene content, where one bacterial species or strain harbors genes absent from the other organism; (ii) nucleotide substitutions within largely conserved DNA sequences, which can result in amino acid changes in orthologous proteins, form pseudogenes, and promote distinct expression patterns of genes present in the two organisms; and (iii) changes in gene arrangement, caused by inversions and translocations. These differences have been observed not only across bacterial species but also among strains belonging to the same species. Recent genomic analyses have revealed that many bacterial pathogens of humans are virtually monomorphic (1) and exhibit very limited sequence diversity, raising questions about the nature of the genetic changes governing distinct behaviors. Furthermore, several bacterial pathogens that have been subjected to extensive passage in the laboratory display altered virulence characteristics, but the genetic basis for these alterations remains largely unknown. Here, we address both of these questions by determining and analyzing the genome sequences of closely related isolates of Salmonella enterica serovar Typhimurium, a Gram-negative pathogen that has been used as a preeminent model to investigate basic genetic mechanisms (2, 8, 46, 59), as well as the interaction between bacterial pathogens and mammalian hosts (11, 41).The genus Salmonella is divided into two species: Salmonella bongori and Salmonella enterica, which together comprise over 2,300 serovars differing in host specificity and the disease conditions they promote in various hosts. For example, S. enterica serovar Typhi is human restricted and causes typhoid fever, whereas serovar Typhimurium is a broad-host-range organism that causes gastroenteritis in humans and a typhoid-like disease in mice. Although the complete genome sequences of 15 Salmonella enterica strains are available, there is only a single representative of S. Typhimurium—strain LT2 (31). Despite its wide application in genetic analysis, strain LT2 is highly attenuated for virulence in both in vitro and in vivo assays (52, 56), leading many investigators to use other S. Typhimurium isolates to examine the genetic basis for bacterial pathogenesis (11, 14, 16).Over 300 virulence genes (3, 5, 47) have already been identified in Salmonella enterica serovar Typhimurium 14028 (now termed S. enterica subsp. enterica serovar Typhimurium ATCC 14028), which is a descendant of CDC 60-6516, a strain isolated in 1960 from pools of hearts and livers of 4-week-old chickens (P. Fields, personal communication). Whereas strain 14028 has been typed as LT2, a designation based on phage sensitivity (27), the two strains were isolated from distinct sources decades apart, which makes their genealogy and exact relationship obscure. A derivative of the original 14028 strain with a rough colony morphology (due to changes in O-antigen expression) was designated 14028r to distinguish it from the original smooth strain, renamed 14028s, and was used in a genetic screen for Salmonella virulence genes because it retained lethality for mice and the ability to survive within murine macrophages. Strain 14028 was also used for the identification of Salmonella genes that were specifically expressed during infection of a mammalian host (30). Both 14028 and LT2 possess a 90-kb virulence plasmid promoting intracellular replication and systemic disease (14), but they differ in their prophage contents, as is often the case among S. Typhimurium strains (12, 13).To identify the individual changes that differentiate S. Typhimurium strains and to assess the nature of variation that arises during laboratory storage and passage, we determined the genome sequence of strain 14028s. This genome was then used as a reference for sequencing its progenitors, including the original source strain CDC 60-6516 and the earliest smooth and rough variants. Our analysis uncovered the genomic differences that arose during the past decades of laboratory cultivation and showed that derivatives with different virulence potentials can follow distinct patterns of sequence evolution.     

Evaluation of Salmonella enterica Serovar Typhimurium TTSS-2 Deficient fur Mutant as Safe Live-Attenuated Vaccine Candidate for Immunocompromised Mice

Salmonella enterica serovar Typhimurium has been extensively exploited as live attenuated vaccines (LAV) which generally confers better protection than killed or subunit vaccines. However, many LAV are limited by their inherent ability to access systemic organs in many of the vaccinated hosts, especially those which are immunocompromised. We evaluated the efficacy of a live-attenuated SPI2-deficient (ΔssaV) S. Typhimurium vaccine candidate (MT13) that additionally devoids the ferric uptake regulator (fur). We used specific pathogen free (SPF) streptomycin-pretreated mouse colitis model that included healthy C57BL/6 and immunocompromised iNos ^−/−, IL10^−/− and CD40L^−/− in the background of C57BL/6 mice to assess the efficacy of developed vaccine candidate. In our study, the S. Typhimurium MT13 strain was established as a safe vaccine candidate to be administered in immunocompromised mice as it was found to be systemically attenuated without conferring significant pathological signs and growth defect within the host. In bacterial challenge experiment, the MT13-vaccinated C57BL/6 mice were protected from subsequent wild-type S. Typhimurium infection by inducing proficient mucosal immunity. The MT13 strain elicited efficient O-antigen specific mucosal secretory IgA associated protective response which was comparable with its parental ssaV mutant. Vaccination with MT13 also showed proficient T-cell activation in host mice; which has direct relation with pathogen clearance from host tissues. Collectively, these data implicate the possible application of SPI-2 deficient fur mutant (MT13) as a novel live attenuated vaccine strain with adept immunogenicity and improved safety, even in immunocompromised hosts. Further, this vaccine candidate can be employed to express heterologous antigens targeted against several other diseases, especially related to enterocolitic pathogens.     

Survival and Transmission of Salmonella enterica Serovar Typhimurium in an Outdoor Organic Pig Farming Environment

It was investigated how organic rearing conditions influence the Salmonella enterica infection dynamics in pigs and whether Salmonella persists in the paddock environment. Pigs inoculated with S. enterica serovar Typhimurium were grouped with Salmonella-negative tracer pigs. Bacteriological and serological testing indicated that organic pigs were susceptible to Salmonella infections, as 26 of 46 (56%) tracer pigs turned culture positive. An intermittent and mainly low-level excretion of Salmonella (<100 cells g⁻¹) partly explains why the bacteriological prevalence appeared lower than the seroprevalence. Salmonella persisted in the paddock environment, as Salmonella was isolated from 46% of soil and water samples (n = 294). After removal of pigs, Salmonella was found in soil samples for up to 5 weeks and in shelter huts during the entire test period (7 weeks). Subsequent introduction of Salmonella-negative pigs into four naturally Salmonella-contaminated paddocks caused Salmonella infections of pigs in two paddocks. In one of these paddocks, all tracer pigs (n = 10) became infected, coinciding with a previous high Salmonella infection rate and high Salmonella excretion level. Our results showed that pigs reared under organic conditions were susceptible to Salmonella infections (just like conventional pigs) and that Salmonella persisting in the paddock environment could pose an infection risk. A driving force for these infections seemed to be pigs with a high Salmonella excretion level, which caused substantial contamination of the environment. This suggests that isolation of animals as soon as a Salmonella infection is indicated by clinical symptoms of diarrhea could be a means of reducing and controlling the spread and persistence of Salmonella in outdoor organic pig production environments.     

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.     

Role of the Hya Hydrogenase in Recycling of Anaerobically Produced H2 in Salmonella enterica Serovar Typhimurium

Double and triple uptake-type hydrogenase mutants were used to determine which hydrogenase recycles fermentatively produced hydrogen. The Δhyb Δhya and Δhyd Δhya double mutants evolved H₂ at rates similar to that of the triple mutant strain, so Hya alone oxidizes the bulk of H₂ produced during fermentation. When only Hya was present, no hydrogen production was observed in nutrient-limited medium. H₂ uptake assays showed that Hya can oxidize both exogenously added H₂ and formate hydrogen lyase-evolved H₂ anaerobically. Even after anaerobic growth, all three uptake-type hydrogenases could function in the presence of oxygen, including using O₂ as a terminal acceptor.Due to the anticipated scarcity of fossil fuels, there has been a surge of interest in H₂ production for alternative energy means. Numerous studies have attempted to engineer H₂-producing organisms, such as photosynthetic bacteria, cyanobacteria, and Escherichia coli, to produce maximal amounts of H₂ while minimizing the H₂-oxidizing capability of the organism (4, 5, 9, 10, 19). Hydrogenase expression and activity are controlled by multiple regulatory pathways and respond to fluctuations in pH, oxygen levels, and availability of metabolites and metal cofactors (17). In addition, the presence of hydrogen uptake hydrogenases decreases the net H₂ yield even under conditions that favor H₂ production. It is therefore important to understand the interactions between H₂-oxidizing enzymes (i.e., respiratory hydrogenases) and H₂-producing enzymes.Gene sequence analysis has revealed that many enteric bacteria contain the genes necessary for hydrogen production and oxidation. The E. coli hydrogenases have been studied extensively, while Salmonella enterica serovar Typhimurium hydrogenases have been studied to a lesser extent. Both E. coli and Salmonella serovar Typhimurium contain the hydrogen-oxidizing hydrogenases Hya and Hyb. Salmonella serovar Typhimurium also contains Hyd, which is another hydrogen-oxidizing hydrogenase (2, 13, 15). Hyc and Hyf are hydrogen-evolving hydrogenases that are present in both E. coli and Salmonella serovar Typhimurium, although it is unknown whether Hyf is functional (1).The Salmonella serovar Typhimurium hydrogenases are important for cellular metabolism. Hyc produces H₂ in order to remove excess reductant generated during mixed-acid fermentation. Hyc and formate dehydrogenase constitute the formate hydrogen lyase (FHL) complex (16), which oxidizes formate to produce CO₂ and H₂ (12). The hyb genes in E. coli and Salmonella serovar Typhimurium are expressed at high levels under anaerobic respiration conditions, and Hyb probably contributes to energy conservation (11, 15, 20). Hyb oxidizes H₂ and generates electrons, which are passed through the electron transport chain to terminal acceptors such as fumarate. The protons generated contribute to the proton-motive force. The role of Hya is not as well characterized. Hya may be used to recycle Hyc-produced H₂, since the hya operon is expressed at high levels during fermentative growth, or it may play a role in acid stress resistance (6, 14, 20, 21). The hyb genes are expressed at high levels under aerobic conditions in Salmonella serovar Typhimurium, and Hyb may couple H₂ oxidation to O₂ reduction (20).Redwood et al. recently examined the roles of uptake-type hydrogenases on net hydrogen production in E. coli (10). Cells were pregrown aerobically or anaerobically with formate and then allowed to ferment in anaerobic bottles. H₂ gas was collected, and other fermentation products were measured. They found that H₂ production increased by 37% in an hya hyb double mutant (compared to that in the wild type) that was grown overnight aerobically with formate. This increase in production was associated with the loss of hyb and not hya. Therefore, in E. coli, Hyb may be responsible for recycling fermentatively produced H₂.In this study, we measured the effect of uptake-type hydrogenase mutations on H₂ production in Salmonella serovar Typhimurium. We found that the majority of H₂-recycling activity in fermenting cells was dependent on the presence of hya, and having only Hya was sufficient to prevent any detectable H₂ evolution. These results demonstrate yet another difference between H₂ metabolism in E. coli and H₂ metabolism in Salmonella serovar Typhimurium.     

Respective Roles of Culturable and Viable-but-Nonculturable Cells in the Heterogeneity of Salmonella enterica Serovar Typhimurium Invasiveness

The existence of Salmonella enterica serovar Typhimurium viable-but-nonculturable (VBNC) cells is a public health concern since they could constitute unrecognized sources of infection if they retain their pathogenicity. To date, many studies have addressed the ability of S. Typhimurium VBNC cells to remain infectious, but their conclusions are conflicting. An assumption could explain these conflicting results. It has been proposed that infectivity could be retained only temporarily after entry into the VBNC state and that most VBNC cells generated under intense stress could exceed the stage where they are still infectious. Using a Radioselectan density gradient centrifugation technique makes it possible to increase the VBNC-cell/culturable-cell ratio without increasing the exposure to stress and, consequently, to work with a larger proportion of newly VBNC cells. Here, we observed that (i) in the stationary phase, the S. Typhimurium population comprised three distinct subpopulations at 10, 24, or 48 h of culture; (ii) the VBNC cells were detected at 24 and 48 h; (iii) measurement of invasion gene (hilA, invF, and orgA) expression demonstrated that cells are highly heterogeneous within a culturable population; and (iv) invasion assays of HeLa cells showed that culturable cells from the different subpopulations do not display the same invasiveness. The results also suggest that newly formed VBNC cells are either weakly able or not able to successfully initiate epithelial cell invasion. Finally, we propose that at entry into the stationary phase, invasiveness may be one way for populations of S. Typhimurium to escape stochastic alteration leading to cell death.Like several readily culturable pathogenic bacterial species, Salmonella enterica has been shown to enter into a viable-but-nonculturable (VBNC) state in response to environmental stresses (25, 33). In this state, cells display integrity and activities but escape detection by conventional culture-based monitoring (24). The physiological significance of this phenotype is unclear: some authors have proposed that it is part of an adaptive response aimed at long-term survival under adverse conditions (22, 32); others argue that it is a consequence of stochastic cellular deterioration and that VBNC cells are on their way to death (4, 10, 12, 23). In any case, the existence of VBNC pathogens is a public health concern since they may constitute unrecognized sources of infection if they retain their pathogenicity.To date, many studies have addressed the ability of VBNC pathogens to remain infectious, but the conclusions of some investigators are conflicting (15, 36). In vitro experiments have shown that VBNC cells of Salmonella enterica serovar Typhimurium and Salmonella enterica serovar Oranienburg can recover their culturability (13, 27, 30, 31). This phenomenon, called resuscitation, confirms that at least some VBNC cells ultimately remain able to multiply and are therefore potentially infectious. On the other hand, most in vivo studies ruled out the ability of S. Typhimurium VBNC cells to initiate infection in mice and chicken or to resuscitate during their passage in the animal gut (6, 17, 34, 35). However, one study reported evidence of the maintenance of pathogenicity by VBNC cells of S. Oranienburg in a model of morphine-immunosuppressed mice (1). An assumption could explain these apparently opposite results. It has been proposed that infectivity could be retained only temporarily after entry into the VBNC state (8, 19, 26). Experiments intended for testing the ability of VBNC cells to retain their pathogenicity cannot be fully conclusive if the inocula still contain culturable cells. Therefore, all previously published animal experiments with S. Typhimurium were conducted on populations with VBNC-cell/culturable-cell ratios around 10,000:1. Such populations were obtained after strong exposure to stress, either under intense stressing factors for a short period (e.g., germicidal UV-C for 2 min [6]) or under mild stressing factors for a long period (e.g., starvation for a minimum of 1 week [35]). In such populations, most VBNC cells could exceed the stage where they are still infectious, and the negative outcomes of infection studies could actually reflect their inability to specifically address the fraction of recent VBNC cells.A Radioselectan density gradient centrifugation technique was shown to fractionate stationary-phase populations of Escherichia coli into two subpopulations (10, 12, 18). Interestingly, the VBNC cells formed during a 48-h E. coli culture were specifically recovered in the high-density (HD) subpopulation (12). This technique thus gives the opportunity to increase the VBNC-cell/culturable-cell ratio without increasing exposure to stress and, consequently, to work with a larger proportion of cells having recently entered the VBNC state.Here, this technique was used to discriminate different stationary-phase S. Typhimurium subpopulations. We further investigated the invasiveness of these cell subpopulations by using both gene expression assays of invasion genes and in vitro invasion tests. Thus, the aim of this study was to assess the invasiveness of the cell subpopulations in accordance with their cellular states.     

Thioredoxin 1 Participates in the Activity of the Salmonella enterica Serovar Typhimurium Pathogenicity Island 2 Type III Secretion System

The facultative intracellular pathogen Salmonella enterica serovar Typhimurium relies on its Salmonella pathogenicity island 2 (SPI2) type III secretion system (T3SS) for intracellular replication and virulence. We report that the oxidoreductase thioredoxin 1 (TrxA) and SPI2 are coinduced for expression under in vitro conditions that mimic an intravacuolar environment, that TrxA is needed for proper SPI2 activity under these conditions, and that TrxA is indispensable for SPI2 activity in both phagocytic and epithelial cells. Infection experiments in mice demonstrated that SPI2 strongly contributed to virulence in a TrxA-proficient background whereas SPI2 did not affect virulence in a trxA mutant. Complementation analyses using wild-type trxA or a genetically engineered trxA coding for noncatalytic TrxA showed that the catalytic activity of TrxA is essential for SPI2 activity in phagocytic cells whereas a noncatalytic variant of TrxA partially sustained SPI2 activity in epithelial cells and virulence in mice. These results show that TrxA is needed for the intracellular induction of SPI2 and provide new insights into the functional integration between catalytic and noncatalytic activities of TrxA and a bacterial T3SS in different settings of intracellular infections.In Escherichia coli, thioredoxin 1 (TrxA, encoded by trxA) is an evolutionary conserved 11-kDa cytosolic highly potent reductase that supports the activities of various oxidoreductases and ribonucleotide reductases (1, 29) and interacts with a number of additional cytoplasmic proteins through the formation of temporary covalent intermolecular disulphide bonds (32). Consequently, as trxA mutants of E. coli (51), Helicobacter pylori (13), and Rhodobacter sphaeroides (34) show increased sensitivity to hydrogen peroxide, TrxA has been defined as a significant oxidoprotectant. In addition, TrxA possess a protein chaperone function that is disconnected from cysteine interactions (30, 32).Salmonella enterica serovar Typhimurium is closely related to E. coli. During divergent evolution, the Salmonella genome acquired a number of virulence-associated genes (20). Many of these genes are clustered on genetic regions termed Salmonella pathogenicity islands (or SPIs). Of these, SPI1 and SPI2 code for separate type III secretion systems (T3SSs). T3SSs are supramolecular virulence-associated machineries that, in several pathogenic gram-negative bacterial species, enable injection of effector proteins from the bacteria into host cells (22, 57). The effector proteins, in turn, manipulate intrinsic host cell functions to facilitate the infection.The SPI1 T3SS of S. serovar Typhimurium is activated for expression in the intestine in response to increased osmolarity and decreased oxygen tension (22, 57). SPI1 effector proteins are primarily secreted into cells that constitute the epithelial layer and interfere with host cell Cdc42 and Rac-1 signaling and actin polymerization. This enables the bacteria to orchestrate their own actin-dependent uptake into nonphagocytic cells (57). SPI1 effector proteins also induce inflammatory signaling and release of interleukin-1β from infected cells (25, 26).Subsequent systemic progression of S. serovar Typhimurium from the intestinal tissue relies heavily on an ability to survive and replicate in phagocytic cells (18, 46, 53, 54). S. serovar Typhimurium uses an additional set of effector proteins secreted by the SPI2 T3SS for replication inside host cells and for coping with phagocyte innate responses to the infection (10, 11, 54). The functions of SPI2 effectors include diversion of vesicular trafficking, induction of apoptotic responses, and manipulation of ubiquitination of host proteins (28, 40, 45, 53). Hence, SPI2 effector proteins create a vacuolar environment that sustains intracellular replication of S. serovar Typhimurium (28).In addition to pathogenicity islands, the in vivo fitness of Salmonella spp. relies on selected functions shared with other enterobacteria. Thus, many virulence genes are integrated into “housekeeping” gene regulatory networks, coded for by a core genome, which steer bacterial stress responses (12, 17, 27, 55). Selected anabolic pathways also contribute to virulence of S. serovar Typhimurium (18, 27), evidently by providing biochemical building blocks for bacterial replication (36).In S. serovar Typhimurium, TrxA is a housekeeping protein that strongly contributes to virulence in cell culture and mouse infection models (8). However, the mechanism by which TrxA activity adds to virulence has not been defined. Here we show that the contribution of TrxA to virulence of S. serovar Typhimurium associates with its functional integration with the SPI2 T3SS under conditions that prevail in the intracellular vacuolar compartment of the host cell. These findings ascribe a novel role to TrxA in bridging environmental adaptations with virulence gene expression and illuminate a new aspect of the interaction between evolutionary conserved and horizontally acquired gene functions in bacteria.     

Length Control of the Flagellar Hook in a Temperature-Sensitive flgE Mutant of Salmonella enterica Serovar Typhimurium

The flagellar hook is a short, curved, extracellular structure located between the basal body and the filament. The hook is composed of the FlgE protein. In this study, we analyzed flagellum assembly in a temperature-sensitive flgE mutant of Salmonella enterica serovar Typhimurium. When the mutant cells were grown at 30°C, they produced flagella of a normal length (71% of the population) and short hooks without filaments (26%). At 37°C, 70% of the basal bodies lacked hooks, and intact flagella made up only 6% of the population. Mutant cells secreted monomeric FlgE in abundance at 37°C, suggesting that the mutant FlgE protein might be defective in polymerization at higher temperatures. The average length of the hooks in intact filaments was 55 nm, whereas after acid treatment, it was 45 nm. SDS-PAGE analysis of the hook-basal body showed that HAP1 was missing in the mutant but not in the wild type. We concluded that hook length in the mutant is controlled in the same way as in the wild type, but the hook appeared short after acid treatment due to the lack of HAP1. We also learned that the true length of the hook is possibly 45 nm, not 55 nm, as has been believed.     

Genetic Mechanisms Underlying the Pathogenicity of Cold-Stressed Salmonella enterica Serovar Typhimurium in Cultured Intestinal Epithelial Cells

Salmonella encounters various stresses in the environment and in the host during infection. The effects of cold (5°C, 48 h), peroxide (5 mM H₂O₂, 5 h) and acid stress (pH 4.0, 90 min) were tested on pathogenicity of Salmonella. Prior exposure of Salmonella to cold stress significantly (P < 0.05) increased adhesion and invasion of cultured intestinal epithelial (Caco-2) cells. This increased Salmonella-host cell association was also correlated with significant induction of several virulence-associated genes, implying an increased potential of cold-stressed Salmonella to cause an infection. In Caco-2 cells infected with cold-stressed Salmonella, genes involved in the electron transfer chain were significantly induced, but no simultaneous significant increase in expression of antioxidant genes that neutralize the effect of superoxide radicals or reactive oxygen species was observed. Increased production of caspase 9 and caspase 3/7 was confirmed during host cell infection with cold-stressed Salmonella. Further, a prophage gene, STM2699, induced in cold-stressed Salmonella and a spectrin gene, SPTAN1, induced in Salmonella-infected intestinal epithelial cells were found to have a significant contribution in increased adhesion and invasion of cold-stressed Salmonella in epithelial cells.