The role of fur in the acid tolerance response of Salmonella typhimurium is physiologically and genetically separable from its role in iron acquisition

Interaction of the RNA chaperone Hfq with mRNAs: direct and indirect roles of Hfq in iron metabolism of Escherichia coli

The Escherichia coli Sm-like host factor I (Hfq) is thought to play direct and indirect roles in post-transcriptional regulation by targeting small regulatory RNAs and mRNAs. In this study, we have used proteomics to identify new mRNA targets of Hfq. We have identified 11 candidate proteins, synthesis of which was differentially affected in a hfq- background. The effect of Hfq on some of the corresponding mRNAs including fur, gapA, metF, ppiB and sodB mRNA was assessed, using different in vitro and in vivo methods. This allowed us to distinguish between direct and indirect effects of Hfq in modulating the translational activities of these mRNAs. From the collection of mRNAs tested, only fur and sodB mRNA, encoding the master regulator of iron metabolism and the iron superoxide dismutase, respectively, were found to be regulated by Hfq. Fur is known to be a negative regulator of transcription of the small RNA RyhB. Mutations in the sodB leader and compensating mutations in RyhB revealed that RyhB in turn represses translation of sodB mRNA, explaining the previously reported positive control of sodB by Fur. These data assign a role to Hfq in regulation of iron uptake and in switching off of iron scavenger genes.

An anti-repression Fur operator upstream of the promoter is required for iron-mediated transcriptional autoregulation in Helicobacter pylori

The Fur protein acts as a regulator of iron-dependent gene transcription in bacteria. In Helicobacter pylori, Fur regulates iron-activated and iron-repressed promoters. It also acts as an autoregulatory rheostat of transcription to fine-tune its own expression in response to iron by binding to three operators at its own promoter Pfur. Using biochemical and genetic analyses, here we show that the distal upstream operator III (centred at -110) is essential for iron regulation of Pfur and functions as an anti-repression site that is bound by the iron-free form of Fur to induce transcription. Furthermore, operator I (centred at -50) may have a dual role both as a high-affinity binding site for Fur and as an UP element. We propose that its role is ensuring that Fur expression is not repressed below a minimum threshold level. Our data supports a novel promoter architecture and mechanism of regulation by Fur.

A novel DNA-binding site for the ferric uptake regulator (Fur) protein from Bradyrhizobium japonicum

The Fur protein is a global regulator of iron metabolism and other processes in many bacterial species. A key feature of the model of Fur function is the recognition of a DNA element within target promoters with similarity to a 19-bp AT-rich palindromic sequence called a Fur box. The irr gene from Bradyrhizobium japonicum is under the control of Fur. Here, we provide evidence that B. japonicum Fur (BjFur) binds to the irr gene promoter with high affinity despite the absence of DNA sequence similarity to the Fur box consensus. Both Escherichia coli Fur and BjFur bound a synthetic Fur box consensus DNA element in electrophoretic gel mobility shift assays, but only BjFur bound the irr promoter. BjFur maximally protected a 30-bp region in DNase I footprinting analysis that includes three imperfect direct repeat hexamers. BjFur formed a high mobility complex and a low mobility complex with DNA in electrophoretic gel mobility shift assays corresponding to occupancy by a single dimer and two dimers or a tetramer, respectively. A mutation in the downstream direct repeat DNA sequence allowed high mobility complex formation only. In vitro transcription from the wild type irr promoter or from a mutated promoter that allowed only dimer occupancy was repressed by Fur, indicating that the dimer can be a functional repressor unit. Our findings identify a novel DNA-binding element for Fur and suggest that the Fur box consensus may not completely represent the target sequences for bacterial Fur proteins as a whole. In addition, Fur binding to a target promoter is sufficient to repress transcription in vitro.

Mycobacterium tuberculosis FurA autoregulates its own expression

The furA-katG region of Mycobacterium tuberculosis, encoding a Fur-like protein and the catalase-peroxidase, is highly conserved among mycobacteria. Both genes are induced upon oxidative stress. In this work we analyzed the M. tuberculosis furA promoter region. DNA fragments were cloned upstream of the luciferase reporter gene, and promoter activity in Mycobacterium smegmatis was measured in both the presence and absence of oxidative stress. The shortest fragment containing an inducible promoter extends 45 bp upstream of furA. In this region, -35 and -10 promoter consensus sequences can be identified, as well as a 23-bp AT-rich sequence that is conserved in the nonpathogenic but closely related M. smegmatis. M. tuberculosis FurA was purified and found to bind upstream of furA by gel shift analysis. A ca. 30-bp DNA sequence, centered on the AT-rich region, was essential for FurA binding and protected by FurA in footprinting analysis. Peroxide treatment of FurA abolished DNA binding. Three different AT-rich sequences mutagenized by site-directed mutagenesis were constructed. In each mutant, both M. tuberculosis FurA binding in vitro and pfurA regulation upon oxidative-stress in M. smegmatis were abolished. Thus, pfurA is an oxidative stress-responsive promoter controlled by the FurA protein.

Emerging themes in manganese transport, biochemistry and pathogenesis in bacteria

Though an essential trace element, manganese is generally accorded little importance in biology other than as a cofactor for some free radical detoxifying enzymes and in the photosynthetic photosystem II. Only a handful of other Mn2+-dependent enzymes are known. Recent data, primarily in bacteria, suggest that Mn2+-dependent processes may have significantly greater physiological importance. Two major classes of prokaryotic Mn2+ uptake systems have now been described, one homologous to eukaryotic Nramp transporters and one a member of the ABC-type ATPase superfamily. Each is highly selective for Mn2+ over Fe2+ or other transition metal divalent cations, and each can accumulate millimolar amounts of intracellular Mn2+ even when environmental Mn2+ is scarce. In Salmonella enterica serovar Typhimurium, simultaneous mutation of both types of transporter results in avirulence, implying that one or more Mn2+-dependent enzymes is essential for pathogenesis. This review summarizes current literature on Mn2+ transport, primarily in the Bacteria but with relevant comparisons to the Archaea and Eukaryota. Mn2+-dependent enzymes are then discussed along with some speculations as to their role(s) in cellular physiology, again primarily in Bacteria. It is of particular interest that most of the enzymes which interconvert phosphoglycerate, pyruvate, and oxaloacetate intermediates are either strictly Mn2+-dependent or highly stimulated by Mn2+. This suggests that Mn2+ may play an important role in central carbon metabolism. Further studies will be required, however, to determine whether these or other actions of Mn2+ within the cell are the relevant factors in pathogenesis.

Comparative analysis of acid resistance between susceptible and multi-antimicrobial-resistant Salmonella strains cultured under stationary-phase acid tolerance-inducing and noninducing conditions

This study compared acid resistance levels among five antimicrobial-susceptible strains of Salmonella and five strains that were simultaneously resistant to a minimum of six antimicrobial agents. The induction of a stationary-phase acid tolerance response (ATR) was attempted by both transient low-pH acid shock and acid adaptation. For acid shock induction, strains were grown for 18 h in minimal E medium containing 0.4% glucose (EG medium) and exposed to sublethal acid stress (pH 4.3) for 2 h, and subsequently, both shocked and nonshocked cultures were acid challenged (pH 3.0) for 4 h. Acid adaptation was achieved by growing strains for 18 h in tryptic soy broth containing 1.0% glucose (TSB+G), while nonadapted cultures were grown for 18 h in glucose-free tryptic soy broth (TSB-G). Acid-adapted and nonadapted inocula were acid challenged (pH 2.3) for 4 h. Initial (0 h) mean populations of nonchallenged Salmonella were 8.5 to 8.7, 8.4 to 8.8, and 8.2 to 8.3 log CFU/ml for strains grown in EG medium, TSB-G, and TSB+G, respectively. After 4 h of acid challenge, mean populations were 3.0 to 4.8 and 2.5 to 3.7 log CFU/ml for previously acid-shocked susceptible and resistant strains, respectively, while corresponding counts for nonshocked strains were 4.3 to 5.5 log CFU/ml and 3.9 to 4.9 log CFU/ml. Following 4 h of acid exposure, acid-adapted cultures of susceptible and resistant strains had mean populations of 6.1 to 6.4 log CFU/ml and 6.4 to 6.6 log CFU/ml, respectively, while corresponding counts for nonadapted cultures were 1.9 to 2.1 log CFU/ml and 1.8 to 2.0 log CFU/ml, respectively. A low-pH-inducible ATR was not achieved through transient acid shock, while an ATR was evident following acid adaptation, as adapted populations were 4.2 to 4.8 log units larger than nonadapted populations following acid exposure. Although some strain-dependent variations in acid resistance were observed, results from this study suggest no association between susceptibility to antimicrobial agents and the ability of the Salmonella strains evaluated to survive low-pH stress.

Molecular characterization of the acid-inducible asr gene of Escherichia coli and its role in acid stress response

Enterobacteria have developed numerous constitutive and inducible strategies to sense and adapt to an external acidity. These molecular responses require dozens of specific acid shock proteins (ASPs), as shown by genomic and proteomic analysis. Most of the ASPs remain poorly characterized, and their role in the acid response and survival is unknown. We recently identified an Escherichia coli gene, asr (acid shock RNA), encoding a protein of unknown function, which is strongly induced by high environmental acidity (pH < 5.0). We show here that Asr is required for growth at moderate acidity (pH 4.5) as well as for the induction of acid tolerance at moderate acidity, as shown by its ability to survive subsequent transfer to extreme acidity (pH 2.0). Sodium dodecyl sulfate-polyacrylamide gel electrophoresis and Western analysis of acid-shocked E. coli cells harboring a plasmid-borne asr gene demonstrated that the Asr protein is synthesized as a precursor with an apparent molecular mass of 18 kDa. Mutational studies of the asr gene also demonstrated the Asr preprotein contains 102 amino acids. This protein is subjected to an N-terminal cleavage of the signal peptide and a second processing event, yielding 15- and 8-kDa products, respectively. Only the 8-kDa polypeptide was detected in acid-shocked cells containing only the chromosomal copy of the asr gene. N-terminal sequencing and site-directed mutagenesis revealed the two processing sites in the Asr protein precursor. Deletion of amino acids encompassing the processing site required for release of the 8-kDa protein resulted in an acid-sensitive phenotype similar to that observed for the asr null mutant, suggesting that the 8-kDa product plays an important role in the adaptation to acid shock. Analysis of Asr:PhoA fusions demonstrated a periplasmic location for the Asr protein after removal of the signal peptide. Homologues of the asr gene from other Enterobacteriaceae were cloned and shown to be induced in E. coli under acid shock conditions.

Architecture of a protein central to iron homeostasis: crystal structure and spectroscopic analysis of the ferric uptake regulator

Iron is an essential element for almost all organisms, although an overload of this element results in toxicity because of the formation of hydroxyl radicals. Consequently, most living entities have developed sophisticated mechanisms to control their intracellular iron concentration. In many bacteria, including the opportunistic pathogen Pseudomonas aeruginosa, this task is performed by the ferric uptake regulator (Fur). Fur controls a wide variety of basic physiological processes including iron uptake systems and the expression of exotoxin A. Here, we present the first crystal structure of Fur from P. aeruginosa in complex with Zn2+ determined at a resolution of 1.8 A. Furthermore, X-ray absorption spectroscopic measurements and microPIXE analysis were performed in order to characterize the distinct zinc and iron binding sites in solution. The combination of these complementary techniques enables us to present a model for the activation and DNA binding of the Fur protein.

Autoregulation of Helicobacter pylori Fur revealed by functional analysis of the iron-binding site

The ferric uptake regulator protein Fur regulates iron-dependent gene expression in bacteria. In Helicobacter pylori it has been shown to regulate iron-activated and iron-repressed genes. In this study, we show that H. pylori Fur protein regulates transcription from its own sigma 80 promoter P fur in response to iron. Footprinting analysis shows that Fur binds at three distinct operators at P fur overlapping and proximal to the promoter elements. Site-directed mutagenesis of the proposed iron-binding site of the protein results in derepression of P fur and the loss of iron regulation. In vivo oligomerization assays reveals that the C-terminus of Fur is necessary for multimerization of the protein and that the mutations do not affect this activity. Molecular and phenotypic analysis of the mutant proteins provides evidence that the iron-binding site controls the specific affinity of Fur for the operators at P fur and hence its repressive ability. In summary, the data presented are consistent with a model in which Fur acts as a rheostat of transcription to autoregulate its own expression in response to iron, which in turn controls expression of iron-induced and iron-repressed genes, providing maintenance of homeostasis.

Microarray analysis identifies Salmonella genes belonging to the low-shear modeled microgravity regulon

The low-shear environment of optimized rotation suspension culture allows both eukaryotic and prokaryotic cells to assume physiologically relevant phenotypes that have led to significant advances in fundamental investigations of medical and biological importance. This culture environment has also been used to model microgravity for ground-based studies regarding the impact of space flight on eukaryotic and prokaryotic physiology. We have previously demonstrated that low-shear modeled microgravity (LSMMG) under optimized rotation suspension culture is a novel environmental signal that regulates the virulence, stress resistance, and protein expression levels of Salmonella enterica serovar Typhimurium. However, the mechanisms used by the cells of any species, including Salmonella, to sense and respond to LSMMG and identities of the genes involved are unknown. In this study, we used DNA microarrays to elucidate the global transcriptional response of Salmonella to LSMMG. When compared with identical growth conditions under normal gravity (1 x g), LSMMG differentially regulated the expression of 163 genes distributed throughout the chromosome, representing functionally diverse groups including transcriptional regulators, virulence factors, lipopolysaccharide biosynthetic enzymes, iron-utilization enzymes, and proteins of unknown function. Many of the LSMMG-regulated genes were organized in clusters or operons. The microarray results were further validated by RT-PCR and phenotypic analyses, and they indicate that the ferric uptake regulator is involved in the LSMMG response. The results provide important insight about the Salmonella LSMMG response and could provide clues for the functioning of known Salmonella virulence systems or the identification of uncharacterized bacterial virulence strategies.

Fur-DNA interactions at the bidirectional fepDGC-entS promoter region in Escherichia coli

The transcriptional repressor Fur binds to a 19-bp consensus sequence, 5'-GATAATGATAATCATTATC-3', under high iron conditions. The fepDGC-entS promoter of Escherichia coli contains two Fur-binding sites (FBS) offset by 6bp. Genetic studies of this promoter region revealed two mutations that exhibited a loss of iron regulation in vivo. One mutation altered the upstream portion of FBS 1, whereas the other, originally created to improve entS promoter strength, inadvertently altered the downstream portion of FBS 2. In both cases, there remains a 19-bp sequence that by current models should be sufficient for Fur binding. The effect of these mutations on Fur binding was examined using in vitro gel retardation assays and DNase I footprinting experiments. Though Fur bound wild-type DNA with high affinity, its affinity for the mutants was reduced, suggesting that both sites are required. In addition, gel shift studies demonstrated that the Fur-promoter complexes exhibit a unique hierarchy of binding, with distinct species forming at increasing concentrations of Fur. The DNA sequences bound in each gel-shifted species were determined using a coupled gel shift/footprint technique. The data presented here, with previously published data, suggest a new model for Fur-DNA interactions similar to that seen with the transcriptional repressor, DtxR. The model predicts that the 19-bp consensus Fur operator is configured as overlapping 13-mer sequences, and that two Fur dimers interact with these sequences from opposite faces of the helix.

The role of the Ferric Uptake Regulator (Fur) in regulation of Helicobacter pylori iron uptake

BACKGROUND

Availability of the essential nutrient iron is thought to vary greatly in the gastric mucosa, and thus the human gastric pathogen Helicobacter pylori requires regulatory responses to these environmental changes. Bacterial iron-responsive regulation is often mediated by Ferric Uptake Regulator (Fur) homologs, and in this study we have determined the role of H. pylori Fur in regulation of H. pylori iron uptake.

METHODS

Wild-type H. pylori and fur mutant derivatives were compared after growth in iron-restricted and iron-replete conditions. Iron-uptake was measured using 55Fe-labeled iron, whereas gene expression was monitored at the transcriptional level using Northern hybridization and lacZ reporter gene fusions.

RESULTS

Iron-uptake and total cellular iron content were approximately five-fold increased in the fur mutant compared with the wild-type strain, which indicated that in the fur mutant iron-uptake is not repressed by excess iron. A comprehensive screening of all H. pylori genes encoding putative iron-uptake proteins indicated that some of these H. pylori genes are constitutively expressed, while others are iron- and Fur-regulated.

CONCLUSIONS

Iron uptake in H. pylori is in part differently regulated compared with other bacteria, since in H. pylori some iron-uptake systems are constitutively expressed. However, other iron uptake systems of H. pylori display the iron- and Fur-mediated repression that is common in bacteria. Taken together, this Fur-mediated modulation of iron-uptake capacity may be a specific adaptation to the conditions in the human stomach, where iron starvation and iron overload can be encountered in relatively short time intervals.

The ferric uptake regulator of Pseudomonas aeruginosa has no essential cysteine residues and does not contain a structural zinc ion

The ferric uptake regulator (Fur) of Pseudomonas aeruginosa was expressed in Escherichia coli in its native form and as a fusion to the maltose-binding protein (MBP). Fur from the MBP fusion bound to MBP after proteolytic cleavage, and the two could only be separated by partial unfolding. The refolded protein was in the same conformation as native protein (as judged by circular dichroism and fluorescence spectroscopies) and was fully active in DNA-binding assays. As-prepared native Fur contained small amounts of Zn(2+) that were easily removed by treatment with EDTA, and apo-protein could be reconstituted with approximately one Zn(2+) ion per monomer. Thus, the P. aeruginosa Fur can probably accommodate a single Zn(2+) ion bound to the metal-sensing site. The single cysteine residue of P. aeruginosa Fur aligns with a cysteine in other members of the Fur family that is essential for activity of the E. coli protein, and is believed to provide one of the ligands to a structural Zn(2+) ion. This cysteine residue was shown to be dispensable for the in vivo activity of P. aeruginosa Fur, which is consistent with the suggestion that the P. aeruginosa protein does not contain a structural Zn(2+) ion. Members of the Fur family contain a highly conserved His-His-Asp-His motif. Alanine substitutions of residues in this motif showed His-87 and His-89 of P. aeruginosa Fur to be essential for activity, whilst His-86 and Asp-88 are partially dispensable.

Acid stress response in Helicobacter pylori

To determine the existence of an acid stress response in Helicobacter pylori the global changes in the proteins synthesized by the bacterium when subjected to an acid stress were studied. H. pylori ATCC43504 previously adapted to pH 7 did not show an acid stress response as detected by the two-dimensional electrophoretic pattern of 35S-labeled proteins when incubated at pH 3. This was probably due to the neutralization of the external medium by the action of urease. However, H. pylori DW504UreI-negative, a mutant strain unable to transport urea into the cell, showed a large number of proteins changed, as is typical in an acid stress response. Some of these proteins were identified by N-terminal sequencing.

The gonococcal fur regulon: identification of additional genes involved in major catabolic, recombination, and secretory pathways

In this study, we have characterized the in vitro binding of Neisseria gonorrhoeae Fur to several well-defined iron transport genes, as well as to additional genes involved in major catabolic, secretory, and recombination pathways of gonococci. The gonococcal Fur protein was recombinantly expressed in Escherichia coli HBMV119. Fur was isolated from inclusion bodies and partially purified by ion-exchange chromatography. Gonococcal Fur was found to bind to the promoter/operator region of a gene encoding the previously identified Fur-regulated periplasmic binding protein (FbpA) in a metal ion-dependent fashion, demonstrating that purified Fur is functional. In silico analysis of the partially completed gonococcal genome (FA1090) identified Fur boxes in the promoters of several genes, including tonB, fur, recN, secY, sodB, hemO, hmbR, fumC, a hypothetical gene (Fe-S homolog), and the opa family of genes. By using purified gonococcal Fur, we demonstrate binding to the operator regions of tonB, fur, recN, secY, sodB, hemO, hmbR, fumC, the Fe-S homolog gene, and the opa gene family as determined by an electrophoretic mobility shift assay. While gonococcal Fur was demonstrated to bind to the promoter regions of all 11 opa genes (opaA through -K), we did not detect binding of purified E. coli Fur with 8 of the 11 opa members, indicating that target DNA sequence specificities between these two closely related proteins exist. Furthermore, we observed differences in the relative strengths of binding of gonococcal Fur for these different genes, which most likely reflect a difference in affinity between gonococcal Fur and its DNA targets. This is the first report that definitively demonstrates the binding of gonococcal Fur to its own promoter/operator region, as well as to the opa family of genes that encode surface proteins. Our results demonstrate that the gonococcal Fur protein binds to the regulatory regions of a broad array of genes and indicates that the gonococcal Fur regulon is larger than originally proposed.

Autoinduction of the ompR response regulator by acid shock and control of the Salmonella enterica acid tolerance response

Salmonella enterica serovar Typhimurium periodically experiences acid stress in a variety of host and non-host environments. An encounter with non-lethal acid stress (pH > 4) induces an assortment of physiological changes, called the acid tolerance response (ATR), that helps the cell to tolerate extreme low pH (pH 3). These physiological changes differ in log phase and stationary phase cells and are controlled by different regulatory proteins. OmpR is an acid-induced response regulator critical to the stationary phase ATR but not to the log phase ATR. As OmpR also controls the expression of the acid-induced virulence operon ssrAB, acid shock induction of ompR was examined to gain insight into how Salmonella links virulence with survival at extreme acid pH. The results indicate that acid pH induces ompR from a promoter different from that used for basal expression. Transcription from this promoter is repressed by the histone-like protein H-NS and requires OmpR-P for induction. The classic sensor kinase EnvZ and acetyl phosphate collaborate to produce the optimum level of OmpR-P needed for autoinduction. Although OmpR-P is required for acid-induced expression of ompR in wild-type cells, OmpR is not needed for ompR transcription in the absence of H-NS. Thus, the role of OmpR-P in autoinduction is to help to counteract repression by H-NS. This evidence, combined with the finding that relaxing DNA supercoiling with novobiocin also increased ompR transcription, suggests that acid stress induces ompR by altering local DNA topology, not by changing the phosphorylation status of OmpR.

Effect of fur mutation on acid-tolerance response and in vivo virulence of avian septicemic Escherichia coli

The Fur (ferric uptake regulator) protein is a master regulator of iron metabolism in gram-negative bacteria. In the present study, the effect of a partial deletion of the fur gene on the acid-tolerance response and in vivo virulence of avian Escherichia coli was examined. The fur mutant was unable to trigger the acid-tolerance response as observed in the wild-type parent strain. However, the mutant was as virulent as the wild-type parent strain when tested in 1-day-old chickens by subcutaneous inoculation. These data indicate that the fur gene is involved in the acid-tolerance response but not involved in the virulence of E. coli, as detected by the ability to cause septicemia in our experimental infection.

Intracellular cyclic AMP concentration is decreased in Salmonella typhimurium fur mutants

It is known that the Fur protein negatively regulates iron-uptake systems in different bacterial species, including Salmonella typhimurium. In this study it has been shown that the intracellular concentration of cyclic AMP (cAMP) is lower in a knockout S. typhimurium fur mutant than in the wild-type strain. According to this, the expression of two cAMP-regulated genes, such as pepE (encoding an alpha-aspartyl dipeptidase) and the Escherichia coli lac operon, is decreased in S. typhimurium fur cells in comparison with wild-type cells. Introduction of an additional mutation in cpdA, encoding a cyclic 3',5'-cAMP phosphodiesterase, recovers wild-type intracellular cAMP concentration in the S. typhimurium fur mutant. Likewise, expression of pepE and the E. coli lac operon was the same in the S. typhimurium fur cpdA double mutant and the wild-type strain. Moreover, these results also demonstrate that the S. typhimurium Fur protein positively regulates the expression of the flhD master operon governing the flagellar regulon. This positive control must be mediated by binding of the S. typhimurium Fur protein to the flhD promoter as indicated by the fact that this promoter tests positive in a Fur titration assay.

Urease of enterohemorrhagic Escherichia coli: evidence for regulation by fur and a trans-acting factor

Recent genomic analyses of Escherichia coli O157:H7 strain EDL933 revealed two loci encoding urease gene homologues (ureDABCEFG), which are absent in nonpathogenic E. coli strain K-12. This report demonstrates that the cloned EDL933 ure gene cluster is capable of synthesizing urease in an E. coli DH5alpha background. However, when the gene fragment is transformed back into the native EDL933 background, the enzymatic activity of the cloned determinants is undetectable. We speculate that an unidentified trans-acting factor in enterohemorrhagic E. coli (EHEC) is responsible for this regulation of ure expression. In addition, Fur-like recognition sites are present in three independent O157:H7 isolates upstream of ureD and ureA. Enzymatic assays confirmed a difference in urease expression of cloned EHEC ure clusters in E. coli MC3100Deltafur. Likewise, interruption of fur in O157:H7 isolate IN1 significantly diminished urease activity. We propose that, similar to the function of Fur in regulating the acid response of Salmonella enterica serovar Typhimurium, it modulates urease expression in EHEC, perhaps contributing to the acid tolerance of the organism.

The Helicobacter pylori homologue of the ferric uptake regulator is involved in acid resistance

The only known niche of the human pathogen Helicobacter pylori is the gastric mucosa, where large fluctuations of pH occur, indicating that the bacterial response and resistance to acid are important for successful colonization. One of the few regulatory proteins in the H. pylori genome is a homologue of the ferric uptake regulator (Fur). In most bacteria, the main function of Fur is the regulation of iron homeostasis. However, in Salmonella enterica serovar Typhimurium, Fur also plays an important role in acid resistance. In this study, we determined the role of the H. pylori Fur homologue in acid resistance. Isogenic fur mutants were generated in three H. pylori strains (1061, 26695, and NCTC 11638). At pH 7 there was no difference between the growth rates of mutants and the parent strains. Under acidic conditions, growth of the fur mutants was severely impaired. No differences were observed between the survival of the fur mutant and parent strain 1061 after acid shock. Addition of extra iron or removal of iron from the growth medium did not improve the growth of the fur mutant at acidic pH. This indicates that the phenotype of the fur mutant at low pH was not due to increased iron sensitivity. Transcription of fur was repressed in response to low pH. From this we conclude that Fur is involved in the growth at acidic pH of H. pylori; as such, it is the first regulatory protein implicated in the acid resistance of this important human pathogen.

Fur-mediated transcriptional and post-transcriptional regulation of FeSOD expression in Escherichia coli

Fur (ferric uptake regulation protein) activates sodB expression, increasing expression levels by a factor of seven and sodB transcript stability by a factor of three. Post-transcriptional regulation of sodB was investigated by searching for endoribonucleases that might be involved in sodB mRNA degradation. The activation of sodB expression was significantly reduced if both the RNaseE and RNaseIII genes were mutated. This correlated with cleavage at a palindromic sequence located in the 5' untranslated region of the sodB transcript. An RNA-binding assay showed that Fur did not directly protect the sodB transcript. It was hypothesized that the persistence of Fur-mediated activation of sodB expression in the RNase double mutant was probably due to an effect at the transcriptional level. Therefore, it was investigated whether Fur had a direct transcriptional effect in vitro. Fur bound the sodB promoter region with low affinity, but it was not able to increase sodB transcription. H-NS-mediated repression of sodB expression, which has been shown to be Fur-dependent, was characterized. No DNA-bending region was identified in the sodB promoter region. H-NS did not interfere with the post-transcriptional effect of Fur. Fur-dependent H-NS and the Fur post-transcriptional effect were not additive. This suggests that Fur and H-NS effects are indirect and may be mediated by a common intermediate.

The Fur repressor controls transcription of iron-activated and -repressed genes in Helicobacter pylori

The ferric uptake regulator (Fur) protein is known to act as a Fe2+-dependent transcriptional repressor of bacterial promoters. Here, we show that, in Helicobacter pylori, Fur can mediate the regulation of iron-activated genes in contrast to classical Fur regulation, in which iron acts as a co-repressor. Inactivation of the fur gene in the chromosome of H. pylori resulted in the derepression of a 19 kDa protein that was identified by N-terminal sequencing as the non-haem-containing ferritin (Pfr). Growth of the wild-type H. pylori strain on media treated with increasing concentrations of FeSO4 resulted in induction of transcription from the Ppfr promoter and, conversely, depletion of iron resulted in repression of Ppfr, indicating that this promoter is iron activated. In the fur mutant, the Ppfr promoter is constitutively highly expressed and no longer responds to iron, indicating that the Fur protein mediates this type of iron regulation. Footprinting analysis revealed that Fur binds to the Ppfr promoter region and that Fe2+ decreases the efficiency of binding. In contrast, Fe2+ increased the affinity of Fur for a classical Fur-regulated promoter, the iron-repressed frpB gene promoter. To our knowledge, this is the first evidence of direct interaction between the Fur protein and the promoter of an iron-activated (-derepressed) gene. Our results support a model in which the iron status of the Fur protein differentially alters its affinity for operators in either iron-repressed or iron-activated genes.

Iron-dependent transcription of the frpB gene of Helicobacter pylori is controlled by the Fur repressor protein

We have overexpressed and purified the Helicobacter pylori Fur protein and analyzed its interaction with the intergenic regions of divergent genes involved in iron uptake (frpB and ceuE) and oxygen radical detoxification (katA and tsaA). DNase I footprint analysis showed that Fur binds specifically to a high-affinity site overlapping the P(frpB) promoter and to low-affinity sites located upstream from promoters within both the frpB-katA and ceuE-tsaA intergenic regions. Construction of an isogenic fur mutant indicated that Fur regulates transcription from the P(frpB) promoter in response to iron. In contrast, no effect by either Fur or iron was observed for the other promoters.

Identifying regulators of transcription in an obligate intracellular pathogen: a metal-dependent repressor in Chlamydia trachomatis

A prominent feature exhibited by Chlamydia trachomatis growing in an iron-limiting environment is a differential pattern of protein expression. In many bacteria, iron-responsive proteins are regulated at the level of transcription by a family of repressors resembling the Escherichia coli ferric uptake regulator (Fur) protein. Although the chlamydial genome sequencing project did not unveil an obvious Fur homologue, a detailed examination indicated five unassigned open reading frames (ORFs) that would encode products with limited sequence homology to Fur. In this report, each chlamydial ORF was engineered in E. coli, and recombinant proteins were examined for functional characteristics resembling Fur. A Fur-specific polyclonal antiserum revealed that the protein encoded by ORF CT296 shares antigenic cross-recognition. Moreover, this protein forms dimers in solution in a fashion analogous to E. coli Fur. Further studies confirmed that the product of ORF CT296 is able to (i) complement Fur activity in a mutant strain of E. coli; and (ii) specifically bind to a 19 bp consensus sequence found in promoters of iron-regulated genes in E. coli. We propose a designation of dcrA (divalent cation-dependent regulator A) for ORF CT296, which encodes a protein distantly related to E. coli Fur. DcrA represents the first repressor described for this obligate intracellular bacterium.

Breaking through the acid barrier: an orchestrated response to proton stress by enteric bacteria

The ability of enteropathogens such as Salmonella and Escherichia coli to adapt and survive acid stress is fundamental to their pathogenesis. Once inside the host, these organisms encounter life-threatening levels of inorganic acid (H+) in the stomach and a combination of inorganic and organic acids (volatile fatty acids) in the small intestine. To combat these stresses, enteric bacteria have evolved elegant, overlapping strategies that involve both constitutive and inducible defense systems. This article reviews the recent progress made in understanding the pH 3 acid tolerance systems of Salmonella and the even more effective pH 2 acid resistance systems of E. coli. Focus is placed on how Salmonella orchestrates acid tolerance by modulating the activities or levels of diverse regulatory proteins in response to pH stress. The result is induction of overlapping arrays of acid shock proteins that protect the cell against acid and other environmental stresses. Most notable among these pH-response regulators are RpoS, Fur, PhoP and OmpR. In addition, we will review three dedicated acid resistance systems of E. coli, not present in Salmonella, that allow this organism to survive extreme (pH 2) acid challenge.

Virulence gene regulation in Salmonella enterica

In order to infect a host, a microbe must be equipped with special properties known as virulence factors. Bacterial virulence factors are required to facilitate colonization, to survive under host defenses, and to permit multiplication inside the host. However, the possession of genes encoding virulence factors does not guarantee effective infection. There is considerable evidence that tight regulation of a given virulence factor is as important as the possession of the virulence factors themselves. Thus, an understanding of the regulation of virulence expression is fundamental to our comprehension of any infection process and can identify potential targets for disease prevention and therapy. We have summarized the lessons learned from experimental salmonellosis in terms of virulence regulation and hope to illustrate the differing requirements for gene and virulence expression.

Cloning, overexpression and interaction of recombinant Fur from the cyanobacterium Anabaena PCC 7119 with isiB and its own promoter

A gene coding for a Fur (ferric uptake regulation) protein from the cyanobacterium Anabaena PCC 7119 has been cloned and overexpressed in Escherichia coli. DNA sequence analysis confirmed the presence of a 151-amino-acid open reading frame that showed homology with the Fur proteins reported for the unicellular cyanobacteria Synechococcus 7942 and Synechocystis PCC 6803. Two putative Fur-binding sites were detected in the promoter regions of the fur gene from Anabaena. Partially purified recombinant Fur binds to the flavodoxin promoter as well as its own promoter. This suggests that the Fur gene is autoregulated in Anabaena.

Caenorhabditis elegans is a model host for Salmonella typhimurium

The idea of using simple, genetically tractable host organisms to study the virulence mechanisms of pathogens dates back at least to the work of Darmon and Depraitère [1]. They proposed using the predatory amoeba Dictyostelium discoideum as a model host, an approach that has proved to be valid in the case of the intracellular pathogen Legionella pneumophila [2]. Research from the Ausubel laboratory has clearly established the nematode Caenorhabditis elegans as an attractive model host for the study of Pseudomonas aeruginosa pathogenesis [3]. P. aeruginosa is a bacterium that is capable of infecting plants, insects and mammals. Other pathogens with a similarly broad host range have also been shown to infect C. elegans [3,4]. Nevertheless, the need to determine the universality of C. elegans as a model host, especially with regards pathogens that have a naturally restricted host specificity, has rightly been expressed [5]. We report here that the enterobacterium Salmonella typhimurium, generally considered to be a highly adapted pathogen with a narrow range of target hosts [6], is capable of infecting and killing C. elegans. Furthermore, mutant strains that exhibit a reduced virulence in mammals were also attenuated for their virulence in C. elegans, showing that the nematode may constitute a useful model system for the study of this important human pathogen.

A serine protease-encoding gene (aprII) of Alteromonas sp. Strain O-7 is regulated by the iron uptake regulator (Fur) protein

The ferric uptake regulator (Fur) box-like sequence was located upstream of the serine protease-encoding gene (aprII) from a marine bacterium, Alteromonas sp. strain O-7. To clarify whether the production of AprII (the gene product of aprII) is regulated by the environmental iron concentrations, this strain was cultured under iron-depleted or iron-rich conditions and the level of AprII in the culture supernatant was analyzed by Western blotting. The production of AprII was significantly repressed under iron-rich conditions. Northern hybridization analysis demonstrated that AprII biosynthesis was regulated by iron through the control of transcription. These results indicate that aprII is a new member of the iron regulon and plays an important role in the iron acquisition system of the strain. Furthermore, the gene encoding Fur was cloned and sequenced. The deduced amino acid sequence of the cloned Fur showed high sequence similarity with that from gram-negative bacteria.

Evidence of an unusually long operator for the fur repressor in the aerobactin promoter of Escherichia coli

Production of the siderophore aerobactin in Escherichia coli is transcriptionally metalloregulated through the iron-dependent binding of the Fur (ferric uptake regulator) to a large region (>100 base pairs) within the cognate promoter in the pColV-K30 plasmid. We show in this article that such an unusually long operator results from the specific addition of degenerate repeats 5'-NAT(A/T)AT-3' and not from a fortuitous occupation of the DNA adjacent to the primary binding sites by an excess of the repressor. Furthermore, the protection pattern revealed by DNase I and hydroxyl radical footprinting reflected a side-by-side oligomerization of the protein along an extended DNA stretch. This type of DNA-protein interactions is more like those observed in some eukaryotic factors and nucleoid-associated proteins than typical of specific prokaryotic regulators.

OmpR regulates the stationary-phase acid tolerance response of Salmonella enterica serovar typhimurium

Tolerance to acidic environments is an important property of free-living and pathogenic enteric bacteria. Salmonella enterica serovar Typhimurium possesses two general forms of inducible acid tolerance. One is evident in exponentially growing cells exposed to a sudden acid shock. The other is induced when stationary-phase cells are subjected to a similar shock. These log-phase and stationary-phase acid tolerance responses (ATRs) are distinct in that genes identified as participating in log-phase ATR have little to no effect on the stationary-phase ATR (I. S. Lee, J. L. Slouczewski, and J. W. Foster, J. Bacteriol. 176:1422-1426, 1994). An insertion mutagenesis strategy designed to reveal genes associated with acid-inducible stationary-phase acid tolerance (stationary-phase ATR) yielded two insertions in the response regulator gene ompR. The ompR mutants were defective in stationary-phase ATR but not log-phase ATR. EnvZ, the known cognate sensor kinase, and the porin genes known to be controlled by OmpR, ompC and ompF, were not required for stationary-phase ATR. However, the alternate phosphodonor acetyl phosphate appears to play a crucial role in OmpR-mediated stationary-phase ATR and in the OmpR-dependent acid induction of ompC. This conclusion was based on finding that a mutant form of OmpR, which is active even though it cannot be phosphorylated, was able to suppress the acid-sensitive phenotype of an ack pta mutant lacking acetyl phosphate. The data also revealed that acid shock increases the level of ompR message and protein in stationary-phase cells. Thus, it appears that acid shock induces the production of OmpR, which in its phosphorylated state can trigger expression of genes needed for acid-induced stationary-phase acid tolerance.

Molecular characterization of the ferric-uptake regulator, fur, from Staphylococcus aureus

Iron is an essential nutrient for the survival and pathogenesis of bacteria, but relatively little is known regarding its transport and regulation in staphylococci. Based on the known sequences of ferric-uptake regulatory (fur) genes from several Gram-positive and Gram-negative bacteria, a fragment containing the fur homologue was cloned from a genomic library of Staphylococcus aureus RN450. Nucleotide sequence analysis of this fragment revealed the presence of a 447 bp ORF that encodes a putative 149 aa polypeptide with an apparent molecular mass of 17 kDa. A putative ferrichrome-uptake (fhu) operon, containing the conserved Fur-binding sequences (Fur box) in the promoter region, was also cloned from the same S. aureus library. To characterize the impact of Fur on the fhu operon, fur was cloned, overexpressed as a His-tagged protein and purified by Ni2+-affinity column chromatography. The recombinant protein was digested with enterokinase to remove the His tag. Electrophoretic mobility-shift assays indicated that Fur binds to the promoter region of the fhu operon in the presence of divalent cations. Fur also interacted with the promoter region of the recently reported sir operon that has been proposed to constitute a siderophore-transport system in S. aureus. The DNase I-protection assay revealed that Fur specifically binds to the Fur box located in the promoter region of the fhu operon. The primer-extension reaction indicated that the transcription-start site of the fhu operon was located inside the Fur box. S. aureus fur partially complemented a fur- mutation in Bacillus subtilis. The data suggest that Fur regulates iron-transport processes in S. aureus.

Characterization of a ferric uptake regulator (fur) gene from Xanthomonas campestris pv. phaseoli with unusual primary structure, genome organization, and expression patterns

A 1.5kb DNA fragment from Xanthomonas campestris pv. phaseoli containing fur was characterized. fur is a single copy gene that is transcribed as a monocistronic mRNA. The predicted amino acid sequence of Xp Fur showed extensive identity to other Fur proteins. However, Xp Fur has many distinct features, particularly a lack of cysteine residues in the conserved metal-binding motifs and unusual modifications in the carboxy-terminus region. The nucleotide sequences of fur genes from four other Xanthomonas spp. were determined. Deduced amino acid sequences all showed the distinct features of Xp Fur. Functionally, Xp Fur partially repressed a Fur-regulated promoter in E. coli. Expression analysis of fur showed increased fur mRNA levels in response to a low iron growth condition. The fur transcription start site was identified by primer extension.

Interaction of Bacillus subtilis Fur (ferric uptake repressor) with the dhb operator in vitro and in vivo

Bacillus subtilis contains three metalloregulatory proteins belonging to the ferric uptake repressor (Fur) family: Fur, Zur, and PerR. We have overproduced and purified Fur protein and analyzed its interaction with the operator region controlling the expression of the dihydroxybenzoate siderophore biosynthesis (dhb) operon. The purified protein binds with high affinity and selectivity to the dhb regulatory region. DNA binding does not require added iron, nor is binding reduced by dialysis of Fur against EDTA or treatment with Chelex. Fur selectively inhibits transcription from the dhb promoter by sigmaA RNA polymerase, even if Fur is added after RNA polymerase holoenzyme. Since neither DNA binding nor inhibition of transcription requires the addition of ferrous ion in vitro, the mechanism by which iron regulates Fur function in vivo is not obvious. Mutagenesis of the fur gene reveals that in vivo repression of the dhb operon by iron requires His97, a residue thought to be involved in iron sensing in other Fur homologs. Moreover, we identify His96 as a second likely iron ligand, since a His96Ala mutant mediates repression at 50 microM but not at 5 microM iron. Our data lead us to suggest that Fur is able to bind DNA independently of bound iron and that the in vivo role of iron is to counteract the effect of an inhibitory factor, perhaps another metal ion, that antagonizes this DNA-binding activity.

Inducible acid tolerance mechanisms in enteric bacteria

Enteric micro-organisms have developed several inducible mechanisms for surviving transient periods of extreme acid stress. Salmonella typhimurium possesses an acid tolerance response (ATR) induced in minimal medium by short exposures to mild acid stress. More than 50 acid shock proteins (ASPs) are induced during adaptation. Eight ASPs are regulated by the major iron regulatory protein, Fur, in an unusual iron-independent manner. The two-component regulator, PhoP, is an autoinduced ASP that controls the induction of three additional ASPs. The stress sigma factor sigma S is an ASP that regulates induction of eight ASPs. Acid induction of sigma S is due to its decreased proteolytic turnover via the ClpXP protease in conjunction with the two-component-type response regulator MviA (RssB in Escherichia coli). Mutations in any of these three regulators leads to a defective ATR. Repair of pH stress-induced DNA damage appears to require the Ada protein (O6-methylguanine methyltransferase) since an ada mutant is both acid and alkaline sensitive. In contrast to S. typhimurium, E. coli and Shigella have acid resistance systems induced in complex media that include a glucose-repressed system protective at pH 2.5 without amino acid supplementation, a glutamate decarboxylase system that requires glutamate and an arginine decarboxylase system unique to E. coli.

Salmonella typhimurium encodes a putative iron transport system within the centisome 63 pathogenicity island

Upon entry into the host, Salmonella enterica strains are presumed to encounter an iron-restricted environment. Consequently, these bacteria have evolved a variety of often-redundant high-affinity acquisition systems to obtain iron in this restricted environment. We have identified an iron transport system that is encoded within the centisome 63 pathogenicity island of Salmonella typhimurium. The nucleotide composition of this locus is significantly different from that of the rest of this pathogenicity island, suggesting a different ancestry and a mosaic structure for this region of the S. typhimurium chromosome. This locus, designated sit, consists of four open reading frames which encode polypeptides with extensive homology to the yfe ABC iron transport system of Yersinia pestis, as well as other ABC transporters. The sitA gene encodes a putative periplasmic binding protein, sitB encodes an ATP-binding protein, and sitC and sitD encode two putative permeases (integral membrane proteins). This operon is capable of complementing the growth defect of the enterobactin-deficient Escherichia coli strain SAB11 in iron-restricted minimal medium. Transcription of the sit operon is repressed under iron-rich growth conditions in a fur-dependent manner. Introduction of a sitBCD deletion into wild-type S. typhimurium resulted in no apparent growth defect in either nutrient-rich or minimal medium and no measurable virulence phenotype. These results further support the existence of redundant iron uptake systems in S. enterica.

Iron regulation and pathogenicity in Erwinia chrysanthemi 3937: role of the Fur repressor protein

Low iron availability is a triggering signal for coordinated expression of the genes encoding pectate lyases PelB, PelC, PelD, and PelE, and chrysobactin iron transport functions, which are two main determinants of phytopathogenicity of the Erwinia chrysanthemi strain 3937. The possible implication of the ferric uptake regulation (Fur) protein in this process was investigated. The E. chrysanthemi fur gene was cloned by functional complementation of an Escherichia coli fur mutant and sequenced. The 444-bp open reading frame identified was found to code for a protein highly similar to the E. coli Fur regulator. An E. chrysanthemi fur null mutant was constructed by reverse genetics. This mutant showed altered growth capacity and reduced pathogenicity on African violets. In a fur background, transcriptional lacZ fusions to genes belonging to the E. chrysanthemi high affinity iron transport systems were constitutively expressed. Transcription of the pelA, pelD, and pelE genes was analyzed, using fusions to the uidA reporter gene. Iron availability and a fur mutation did not influence the expression of pelA. In the presence of iron, pelD and pelE transcription levels were higher in the fur mutant than in the parental strain. Furthermore, iron deficiency stimulated the expression of both fusions in the fur mutant. These findings indicate that, in E. chrysanthemi 3937, (i) Fur negatively controls iron transport and genes encoding PelD and PelE, and (ii) additional factor(s) mediate iron regulation of the pel genes.

Coordinate intracellular expression of Salmonella genes induced during infection

Salmonella typhimurium in vivo-induced (ivi) genes were grouped by their coordinate behavior in response to a wide variety of environmental and genetic signals, including pH, Mg2+, Fe2+, and PhoPQ. All of the seven ivi fusions that are induced by both low pH and low Mg2+ (e.g., iviVI-A) are activated by the PhoPQ regulatory system. Iron-responsive ivi fusions include those induced under iron limitation (e.g., entF) as well as one induced by iron excess but only in the absence of PhoP (pdu). Intracellular expression studies showed that each of the pH- and Mg2+-responsive fusions is induced upon entry into and growth within three distinct mammalian cell lines: RAW 264.7 murine macrophages and two cultured human epithelial cell lines: HEp-2 and Henle-407. Each ivi fusion has a characteristic level of induction consistent within all three cell types, suggesting that this class of coordinately expressed ivi genes responds to general intracellular signals that are present both in initial and in progressive stages of infection and may reflect their responses to similar vacuolar microenvironments in these cell types. Investigation of ivi expression patterns reveals not only the inherent versatility of pathogens to express a given gene(s) at various host sites but also the ability to modify their expression within the context of different animal hosts, tissues, cell types, or subcellular compartments.

Cyclic AMP receptor protein and TyrR are required for acid pH and anaerobic induction of hyaB and aniC in Salmonella typhimurium

Two acid-inducible genes, aniC and aciK, that require anaerobiosis and tyrosine for expression were identified as orf326a encoding a potential amino acid/polyamine antiporter and hyaB encoding hydrogenase I, respectively. Cyclic AMP (cAMP) receptor protein, cAMP, and TyrR, regulator of aromatic amino acid metabolism, were strong positive regulators of both genes.

Characterization of the Acinetobacter baumannii Fur regulator: cloning and sequencing of the fur homolog gene

Growth kinetics, siderophore activity and iron-regulated bacterial proteins of Acinetobacter baumannii BM2580 were studied in iron-restricted and iron-supplemented chemically defined media. Iron-regulated outer membrane proteins of 75 kDa and 80 kDa were expressed under iron-restricted conditions. Cloning and sequencing of the complete iron-uptake regulatory (fur) gene from A. baumannii BM2580 is reported for the first time. This gene is preceded by a single autoregulated promoter whose -10 region overlaps the Fur binding site. The open reading frame identified encodes a polypeptide consisting of 145 amino acids. The fur gene is followed by a divergent open reading frame coding for the C-terminus of a putative PilU protein. Sequence analysis indicates that the Fur protein of A. baumannii was 63% identical to the Escherichia coli Fur protein.

Binding of the fur (ferric uptake regulator) repressor of Escherichia coli to arrays of the GATAAT sequence

The mode of DNA binding of the Fur (ferric uptake regulator) repressor which controls transcription of iron-responsive genes in Escherichia coli, has been re-examined. Using as a reference the known sites at the promoter of the aerobactin operon of Escherichia coli, we have compared in detail the patterns of interaction between the purified Fur protein and natural or synthetic DNA targets. DNase I and hydroxyl radical footprinting, as well as missing-T assays, consistently revealed that functional Fur sites are composed of a minimum of three repeats of the hexameric motif GATAAT rather than by a palindromic 19 bp target sequence. Extended binding sites, constructed by stepwise addition of one or two direct repeats of the same sequence, were occupied co-operatively by Fur with the same pattern of interactions as those observed with the core of three repeats. This indicated that functional sites with a range of affinities can be formed by the addition of discrete GATAAT extensions to a minimal recognition sequence. The fashion in which Fur binds its target, virtually unknown in prokaryotic transcriptional regulators, accounts for the observed helical wrapping of the protein around the DNA helix.

Effect of mild acid treatment on the survival, enteropathogenicity, and protein production in vibrio parahaemolyticus

Vibrio parahaemolyticus is an important food-borne enteropathogen that encounters various adverse conditions in its native environment or during infection. Effects of mild acid treatment on survival under stress conditions, enteropathogenicity, and protein production in this pathogen were investigated. Logarithmically grown cells, at pH 7.5 shifted to pH 5.0 for 30 min, were more resistant to subsequent acid challenge at pH 4.4. A two-phase adaptive procedure (pH 5.8 for 30 min; pH 5.0 for 30 min) was better than a single-phase procedure for enhancing the acid tolerance of this pathogen. The acid-adapted cells were cross-protected against the challenges of low salinity and thermal inactivation. One-dimensional polyacrylamide gel electrophoresis revealed that proteins with molecular masses of 6.4, 9.0, 13.6, 16.3, 18.9, 22.9, 24.4, 28.3, 33. 9, 36.9, 41.2, 47.6, 58.1, 65.6, 80.5, 88.2, and 96.9 kDa were induced or significantly enhanced, while proteins of 25.3, 30.1, 30. 7, and 91.7 kDa were significantly inhibited. Two-dimensional polyacrylamide gel electrophoresis revealed that 20 species of proteins were induced or significantly enhanced, while 26 species were inhibited. In assays conducted using the suckling mouse model, enteropathogenicity of the acid-adapted cells was significantly enhanced in terms of intestine/body weight ratio and in vivo recovery of infected cells.

Biooxidation capacity of the extremely thermoacidophilic archaeon metallosphaera sedula under bioenergetic challenge

The biooxidation capacity of an extremely thermoacidophilic archaeon Metallosphaera sedula (DSMZ 5348) was examined under bioenergetic challenges imparted by thermal or chemical stress in regard to its potential use in microbial bioleaching processes. Within the normal growth temperature range of M. sedula (70-79 degrees C) at pH 2.0, upward temperature shifts resulted in bioleaching rates that followed an Arrhenius-like dependence. When the cells were subjected to supraoptimal temperatures through gradual thermal acclimation at 81 degrees C (Han et al., 1997), cell densities were reduced but 3 to 5 times faster specific leaching rates (Fe3+ released from iron pyrite/cell/h) could be achieved by the stressed cells compared to cells at 79 degrees C and 73 degrees C, respectively. The respiration capacity of M. sedula growing at 74 degrees C was challenged by poisoning the cells with uncouplers to generate chemical stress. When the protonophore 2,4-dinitrophenol (5-10 μM) was added to a growing culture of M. sedula on iron pyrite, there was little effect on specific leaching rates compared to a culture with no protonophore at 74 degrees C; 25 μM levels proved to be toxic to M. sedula. However, a significant stimulation in specific rate was observed when the cells were subjected to 1 μM nigericin (+135%) and 2 μM (+63%); 5 μM levels of the ionophore completely arrested cell growth. The ionophore effect was further investigated in continuous culture growing on ferrous sulfate at 74 degrees C. When 1 μM nigericin was added as a pulse to a continuous culture, a 30% increase in specific iron oxidation rate was observed for short intervals, indicating a potential positive impact on leaching when periodic chemical stress is applied. This study suggests that biooxidation rates can be increased by strategic exposure of extreme thermoacidophiles to chemical or thermal stress, and this approach should be considered for improving process performance. Copyright 1998 John Wiley & Sons, Inc.

The ZnuABC high-affinity zinc uptake system and its regulator Zur in Escherichia coli

In Escherichia coli, lacZ operon fusions were isolated that were derepressed under iron repletion and repressed under iron depletion. Two fusions were localized in genes that formed an operon whose gene products had characteristics of a binding protein-dependent transport system. The growth defect of these mutants on TY medium containing 5mM EGTA was compensated for by the addition of Zn2+. In the presence of 0.5mM EGTA, only the parental strain was able to take up 65Zn2+. This high-affinity transport was energized by ATP. The genes were named znuACB (for zinc uptake; former name yebLMI) and localized at 42 min on the genetic map of E. coli. At high Zn2+ concentrations, the znu mutants took up more 65Zn2+ than the parental strain. The high-affinity 65Zn2+ uptake was repressed by growth in the presence of 10 microM Zn2+. A znuA-lacZ operon fusion was repressed by 5 microM Zn2+ and showed a more than 20-fold increase in beta-galactosidase activity when Zn2+ was bound to 1.5 microM TPEN [tetrakis-(2-pyridylmethyl) ethylenediamine]. To identify the Zn2+-dependent regulator, constitutive mutants were isolated and tested for complementation by a gene bank of E. coli. A complementing gene, yjbK of the E. coli genome, was identified and named zur (for zinc uptake regulation). The Zur protein showed 27% sequence identity with the iron regulator Fur. High-affinity 65Zn2+ transport of the constitutive zur mutant was 10-fold higher than that of the uninduced parental strain. An in vivo titration assay suggested that Zur binds to the bidirectional promoter region of znuA and znuCB.

A low pH-inducible, PhoPQ-dependent acid tolerance response protects Salmonella typhimurium against inorganic acid stress

The acid tolerance response enables Salmonella typhimurium to survive exposures to potentially lethal acidic environments. The acid stress imposed in a typical assay for acid tolerance (log-phase cells in minimal glucose medium) was shown to comprise both inorganic (i.e., low pH) and organic acid components. A gene previously determined to affect acid tolerance, atbR, was identified as pgi, the gene encoding phosphoglucoisomerase. Mutations in pgi were shown to increase acid tolerance by preventing the synthesis of organic acids. Protocols designed to separate the stresses of inorganic from organic acids revealed that the regulators sigma38 (RpoS), Fur, and Ada have major effects on tolerance to organic acid stress but only minor effects on inorganic acid stress. In contrast, the two-component regulatory system PhoP (identified as acid shock protein ASP29) and PhoQ proved to be important for tolerance to inorganic [corrected] acid stress but had little effect against organic acid stress. PhoP mutants also failed to induce four ASPs, confirming a role for this regulator in acid tolerance. Acid shock induction of PhoP appears to occur at the transcriptional level and requires the PhoPQ system. Furthermore, induction by acid occurs even in the presence of high concentrations of magnesium, the ion known to be sensed by PhoQ. These results suggest that PhoQ can sense both Mg2+ and pH. Since phoP mutants are avirulent, the low pH activation of this system has important implications concerning the pathogenesis of S. typhimurium. The involvement of four regulators, two of which are implicated in virulence, underscores the complexity of the acid tolerance stress response and further suggests that features of acid tolerance and virulence are interwoven.

Coordinated repression in vitro of the divergent fepA-fes promoters of Escherichia coli by the iron uptake regulation (Fur) protein

The mechanism involved in transcriptional repression of the fepA-fes divergent promoters of Escherichia coli by the Fur (ferric uptake regulation) protein has been examined in vitro. This DNA region includes a suboptimal and single Fur-binding site with two divergent and overlapped -35/-10 hexamers. Comparison of transcription patterns generated with runoff experiments in either the presence or the absence of heparin showed that access of the RNA polymerase to the principal -35/-10 hexamers was fully prevented by Fur-Mn2+ bound to its target site within the divergent promoter region. Neither RNA polymerase bound to the fes and fepA promoters could be displaced by Fur-Mn2+, nor could the bound repressor be outcompeted by an excess of the enzyme. However, the repressor blocked reinitiation as soon as the polymerase moved away from the fes promoter during transcription. The spatial distribution of regulatory elements within the DNA region allowed the simultaneous binding of the RNA polymerase to the fes and fepA promoters and their coordinate regulation regardless of their different transcriptional activities. Comparisons with other iron-regulated systems support a general mechanism for Fur-controlled promoters that implies a direct competition between the polymerase and the regulator for overlapping target sites in the DNA.

A competitive microflora increases the resistance of Salmonella typhimurium to inimical processes: evidence for a suicide response

The presence of a viable competitive microflora at cell densities of 10(8) CFU ml-1 protects an underlying population of 10(5) CFU of Salmonella typhimurium ml-1 against freeze injury. The mechanism of enhanced resistance was initially postulated to be via an RpoS-mediated adaptive response. By using an spvRA:: luxCDABE reporter we have shown that although the onset of RpoS-mediated gene expression was brought forward by the addition of a competitive microflora, the time taken for induction was measured in hours. Since the protective effect of a competitive microflora is essentially instantaneous, the stationary-phase adaptive response is excluded as the physiological mechanism. The only instantaneous effect of the competitive microflora was a reduction in the percent saturation of oxygen from 100% to less than 10%. For both mild heat treatment (55 degrees C) and freeze injury this change in oxygen tension affords Salmonella a substantive (2 orders of magnitude) enhancement in survival. By reducing the levels of dissolved oxygen through active respiration, a competitive microflora reduces oxidative damage to exponential-phase cells irrespective of the inimical treatment. These results have led us to propose a suicide hypothesis for the destruction of rapidly growing cells by inimical processes. In essence, the suicide hypothesis proposes that a mild inimical process leads to the growth arrest of exponential-phase cells and to the decoupling of anabolic and catabolic metabolism. The result of this is a free radical burst which is lethal to unadapted cells.

Signal transduction and transcriptional and posttranscriptional control of iron-regulated genes in bacteria

Iron is an essential element for nearly all living cells. Thus, the ability of bacteria to utilize iron is a crucial survival mechanism independent of the ecological niche in which the microorganism lives, because iron is scarce both in potential biological hosts, where it is bound by high-affinity iron-binding proteins, and in the environment, where it is present as part of insoluble complex hydroxides. Therefore, pathogens attempting to establish an infection and environmental microorganisms must all be able to utilize the otherwise unavailable iron. One of the strategies to perform this task is the possession of siderophore-mediated iron uptake systems that are capable of scavenging the hoarded iron. This metal is, however, a double-edged sword for the cell because it can catalyze the production of deadly free hydroxyl radicals, which are harmful to the cells. It is therefore imperative for the cell to control the concentration of iron at levels that permit key metabolic steps to occur without becoming a messenger of cell death. Early work identified a repressor, Fur, which as a complex with iron repressed the expression of most iron uptake systems as well as other iron-regulated genes when the iron concentration reached a certain level. However, later work demonstrated that this regulation by Fur was not the only answer under low-iron conditions, there was a need for activation of iron uptake genes as well as siderophore biosynthetic genes. Furthermore, it was also realized that in some instances the actual ferric iron-siderophore complex induced the transcription of the cognate receptor and transport genes. It became evident that control of the expression of iron-regulated genes was more complex than originally envisioned. In this review, I analyze the processes of signal transduction, transcriptional control, and posttranscriptional control of iron-regulated genes as reported for the ferric dicitrate system in Escherichia coli; the pyochelin, pyoverdin, and enterobactin systems in Pseudomonas species; the irgB system in Vibrio cholerae; and the plasmid-mediated anguibactin system in Vibrio anguillarum. I hope that by using these diverse paradigms, I will be able to convey a unifying picture of these mechanism and their importance in the maintenance and prosperity of bacteria within their ecological niches.