Nuclear factor kappa B-dependent persistence of Salmonella Typhi and Paratyphi in human macrophages

Salmonella serovars Typhi and Paratyphi cause a prolonged illness known as enteric fever, whereas other serovars cause acute gastroenteritis. Mechanisms responsible for the divergent clinical manifestations of nontyphoidal and enteric fever Salmonella infections have remained elusive. Here, we show that S. Typhi and S. Paratyphi A can persist within human macrophages, whereas S. Typhimurium rapidly induces apoptotic macrophage cell death that is dependent on Salmonella pathogenicity island 2 (SPI2). S. Typhi and S. Paratyphi A lack 12 specific SPI2 effectors with pro-apoptotic functions, including nine that target nuclear factor κB (NF-κB). Pharmacologic inhibition of NF-κB or heterologous expression of the SPI2 effectors GogA or GtgA restores apoptosis of S. Typhi-infected macrophages. In addition, the absence of the SPI2 effector SarA results in deficient signal transducer and activator of transcription 1 (STAT1) activation and interleukin 12 production, leading to impaired TH1 responses in macrophages and humanized mice. The absence of specific nontyphoidal SPI2 effectors may allow S. Typhi and S. Paratyphi A to cause chronic infections.

IMPORTANCE

Salmonella enterica is a common cause of gastrointestinal infections worldwide. The serovars Salmonella Typhi and Salmonella Paratyphi A cause a distinctive systemic illness called enteric fever, whose pathogenesis is incompletely understood. Here, we show that enteric fever Salmonella serovars lack 12 specific virulence factors possessed by nontyphoidal Salmonella serovars, which allow the enteric fever serovars to persist within human macrophages. We propose that this fundamental difference in the interaction of Salmonella with human macrophages is responsible for the chronicity of typhoid and paratyphoid fever, suggesting that targeting the nuclear factor κB (NF-κB) complex responsible for macrophage survival could facilitate the clearance of persistent bacterial infections.

Analysis of Salmonella Typhi Pathogenesis in a Humanized Mouse Model

Efforts to understand molecular mechanisms of pathogenesis of the human-restricted pathogen Salmonella enterica serovar Typhi, the causative agent of typhoid fever, have been hampered by the lack of a tractable small animal model. This obstacle has been surmounted by a humanized mouse model in which genetically modified mice are engrafted with purified CD34+ stem cells from human umbilical cord blood, designated CD34+ Hu-NSG (formerly hu-SRC-SCID) mice. We have shown that these mice develop a lethal systemic infection with S. Typhi that is dependent on the presence of engrafted human hematopoietic cells. Immunological and pathological features of human typhoid are recapitulated in this model, which has been successfully employed for the identification of bacterial genetic determinants of S. Typhi virulence. Here we describe the methods used to infect CD34+ Hu-NSG mice with S. Typhi in humanized mice and to construct and analyze a transposon-directed insertion site sequencing S. Typhi library, and provide general considerations for the use of humanized mice for the study of a human-restricted pathogen.

Manganese import protects Salmonella enterica serovar Typhimurium against nitrosative stress

Nitric oxide (NO˙) is a radical molecule produced by mammalian phagocytic cells as part of the innate immune response to bacterial pathogens. It exerts its antimicrobial activity in part by impairing the function of metalloproteins, particularly those containing iron and zinc cofactors. The pathogenic Gram-negative bacterium Salmonella enterica serovar typhimurium undergoes dynamic changes in its cellular content of the four most common metal cofactors following exposure to NO˙ stress. Zinc, iron and magnesium all decrease in response to NO˙ while cellular manganese increases significantly. Manganese acquisition is driven primarily by increased expression of the mntH and sitABCD transporters following derepression of MntR and Fur. ZupT also contributes to manganese acquisition in response to nitrosative stress. S. Typhimurium mutants lacking manganese importers are more sensitive to NO˙, indicating that manganese is important for resistance to nitrosative stress.

Genome-wide Analysis of Salmonella enterica serovar Typhi in Humanized Mice Reveals Key Virulence Features

Salmonella enterica serovar Typhi causes typhoid fever only in humans. Murine infection with S. Typhimurium is used as a typhoid model, but its relevance to human typhoid is limited. Non-obese diabetic-scid IL2rγnull mice engrafted with human hematopoietic stem cells (hu-SRC-SCID) are susceptible to lethal S. Typhi infection. In this study, we use a high-density S. Typhi transposon library in hu-SRC-SCID mice to identify virulence loci using transposon-directed insertion site sequencing (TraDIS). Vi capsule, lipopolysaccharide (LPS), and aromatic amino acid biosynthesis were essential for virulence, along with the siderophore salmochelin. However, in contrast to the murine S. Typhimurium model, neither the PhoPQ two-component system nor the SPI-2 pathogenicity island was required for lethal S. Typhi infection, nor was the CdtB typhoid toxin. These observations highlight major differences in the pathogenesis of typhoid and non-typhoidal Salmonella infections and demonstrate the utility of humanized mice for understanding the pathogenesis of a human-specific pathogen.

The Evolution of SlyA/RovA Transcription Factors from Repressors to Countersilencers in Enterobacteriaceae

Gene duplication and subsequent evolutionary divergence have allowed conserved proteins to develop unique roles. The MarR family of transcription factors (TFs) has undergone extensive duplication and diversification in bacteria, where they act as environmentally responsive repressors of genes encoding efflux pumps that confer resistance to xenobiotics, including many antimicrobial agents. We have performed structural, functional, and genetic analyses of representative members of the SlyA/RovA lineage of MarR TFs, which retain some ancestral functions, including repression of their own expression and that of divergently transcribed multidrug efflux pumps, as well as allosteric inhibition by aromatic carboxylate compounds. However, SlyA and RovA have acquired the ability to countersilence horizontally acquired genes, which has greatly facilitated the evolution of Enterobacteriaceae by horizontal gene transfer. SlyA/RovA TFs in different species have independently evolved novel regulatory circuits to provide the enhanced levels of expression required for their new role. Moreover, in contrast to MarR, SlyA is not responsive to copper. These observations demonstrate the ability of TFs to acquire new functions as a result of evolutionary divergence of both cis-regulatory sequences and in trans interactions with modulatory ligands.IMPORTANCE Bacteria primarily evolve via horizontal gene transfer, acquiring new traits such as virulence and antibiotic resistance in single transfer events. However, newly acquired genes must be integrated into existing regulatory networks to allow appropriate expression in new hosts. This is accommodated in part by the opposing mechanisms of xenogeneic silencing and countersilencing. An understanding of these mechanisms is necessary to understand the relationship between gene regulation and bacterial evolution. Here we examine the functional evolution of an important lineage of countersilencers belonging to the ancient MarR family of classical transcriptional repressors. We show that although members of the SlyA lineage retain some ancestral features associated with the MarR family, their cis-regulatory sequences have evolved significantly to support their new function. Understanding the mechanistic requirements for countersilencing is critical to understanding the pathoadaptation of emerging pathogens and also has practical applications in synthetic biology.

The NsrR regulon in nitrosative stress resistance of Salmonella enterica serovar Typhimurium

Nitric oxide (NO·) is an important mediator of innate immunity. The facultative intracellular pathogen Salmonella has evolved mechanisms to detoxify and evade the antimicrobial actions of host-derived NO· produced during infection. Expression of the NO·-detoxifying flavohaemoglobin Hmp is controlled by the NO·-sensing transcriptional repressor NsrR and is required for Salmonella virulence. In this study we show that NsrR responds to very low NO· concentrations, suggesting that it plays a primary role in the nitrosative stress response. Additionally, we have defined the NsrR regulon in Salmonella enterica sv. Typhimurium 14028s using transcriptional microarray, qRT-PCR and in silico methods. A novel NsrR-regulated gene designated STM1808 has been identified, along with hmp, hcp-hcr, yeaR-yoaG, ygbA and ytfE. STM1808 and ygbA are important for S. Typhimurium growth during nitrosative stress, and the hcp-hcr locus plays a supportive role in NO· detoxification. ICP-MS analysis of purified STM1808 suggests that it is a zinc metalloprotein, with histidine residues H32 and H82 required for NO· resistance and zinc binding. Moreover, STM1808 and ytfE promote Salmonella growth during systemic infection of mice. Collectively, these findings demonstrate that NsrR-regulated genes in addition to hmp are important for NO· detoxification, nitrosative stress resistance and Salmonella virulence.

Evolution of Salmonella enterica virulence via point mutations in the fimbrial adhesin

Whereas the majority of pathogenic Salmonella serovars are capable of infecting many different animal species, typically producing a self-limited gastroenteritis, serovars with narrow host-specificity exhibit increased virulence and their infections frequently result in fatal systemic diseases. In our study, a genetic and functional analysis of the mannose-specific type 1 fimbrial adhesin FimH from a variety of serovars of Salmonella enterica revealed that specific mutant variants of FimH are common in host-adapted (systemically invasive) serovars. We have found that while the low-binding shear-dependent phenotype of the adhesin is preserved in broad host-range (usually systemically non-invasive) Salmonella, the majority of host-adapted serovars express FimH variants with one of two alternative phenotypes: a significantly increased binding to mannose (as in S. Typhi, S. Paratyphi C, S. Dublin and some isolates of S. Choleraesuis), or complete loss of the mannose-binding activity (as in S. Paratyphi B, S. Choleraesuis and S. Gallinarum). The functional diversification of FimH in host-adapted Salmonella results from recently acquired structural mutations. Many of the mutations are of a convergent nature indicative of strong positive selection. The high-binding phenotype of FimH that leads to increased bacterial adhesiveness to and invasiveness of epithelial cells and macrophages usually precedes acquisition of the non-binding phenotype. Collectively these observations suggest that activation or inactivation of mannose-specific adhesive properties in different systemically invasive serovars of Salmonella reflects their dynamic trajectories of adaptation to a life style in specific hosts. In conclusion, our study demonstrates that point mutations are the target of positive selection and, in addition to horizontal gene transfer and genome degradation events, can contribute to the differential pathoadaptive evolution of Salmonella.

Multiple targets of nitric oxide in the tricarboxylic acid cycle of Salmonella enterica serovar typhimurium

Host nitric oxide (NO⋅) production is important for controlling intracellular bacterial pathogens, including Salmonella enterica serovar Typhimurium, but the underlying mechanisms are incompletely understood. S. Typhmurium 14028s is prototrophic for all amino acids but cannot synthesize methionine (M) or lysine (K) during nitrosative stress. Here, we show that NO⋅-induced MK auxotrophy results from reduced succinyl-CoA availability as a consequence of NO⋅ targeting of lipoamide-dependent lipoamide dehydrogenase (LpdA) activity. LpdA is an essential component of the pyruvate and α-ketoglutarate dehydrogenase complexes. Additional effects of NO⋅ on gene regulation prevent compensatory pathways of succinyl-CoA production. Microarray analysis indicates that over 50% of the transcriptional response of S. Typhimurium to nitrosative stress is attributable to LpdA inhibition. Bacterial methionine transport is essential for virulence in NO⋅-producing mice, demonstrating that NO⋅-induced MK auxotrophy occurs in vivo. These observations underscore the importance of metabolic targets for antimicrobial actions of NO⋅.

The phage shock protein PspA facilitates divalent metal transport and is required for virulence of Salmonella enterica sv. Typhimurium

The phage shock protein (Psp) system is induced by extracytoplasmic stress and thought to be important for the maintenance of proton motive force. We investigated the contribution of PspA to Salmonella virulence. A pspA deletion mutation significantly attenuates the virulence of Salmonella enterica serovar Typhimurium following intraperitoneal inoculation of C3H/HeN (Ity(r) ) mice. PspA was found to be specifically required for virulence in mice expressing the natural resistance-associated macrophage protein 1 (Nramp1) (Slc11a1) divalent metal transporter, which restricts microbial growth by limiting the availability of essential divalent metals within the phagosome. Salmonella competes with Nramp1 by expressing multiple metal uptake systems including the Nramp-homologue MntH, the ABC transporter SitABCD and the ZIP family transporter ZupT. PspA was found to facilitate Mn(2+) transport by MntH and SitABCD, as well as Zn(2+) and Mn(2+) transport by ZupT. In vitro uptake of (54) Mn(2+) by MntH and ZupT was reduced in the absence of PspA. Transport-deficient mutants exhibit reduced viability in the absence of PspA when grown under metal-limited conditions. Moreover, the ZupT transporter is required for Salmonella enterica serovar Typhimurium virulence in Nramp1-expressing mice. We propose that PspA promotes Salmonella virulence by maintaining proton motive force, which is required for the function of multiple transporters mediating bacterial divalent metal acquisition during infection.

Biosynthesis and IroC-dependent export of the siderophore salmochelin are essential for virulence of Salmonella enterica serovar Typhimurium

In response to iron deprivation, Salmonella enterica serovar Typhimurium secretes two catecholate-type siderophores, enterobactin and its glucosylated derivative salmochelin. Although the systems responsible for enterobactin synthesis and acquisition are well characterized, the mechanisms of salmochelin secretion and acquisition, as well as its role in Salmonella virulence, are incompletely understood. Herein we show by liquid chromatography-mass spectrometry analysis of culture supernatants from wild type and isogenic mutant bacterial strains that the Major Facilitator Superfamily pump EntS is the major exporter of enterobactin and the ABC transporter IroC exports both salmochelin and enterobactin. Growth promotion experiments demonstrate that IroC is not required for utilization of Fe-enterobactin or Fe-salmochelin, as had been previously suggested, but the ABC transporter protein FepD is required for utilization of both siderophores. Salmonella mutants deficient in salmochelin synthesis or secretion exhibit reduced virulence during systemic infection of mice.

The mechanism of outer membrane penetration by the eubacterial flagellum and implications for spirochete evolution

The rod component of the bacterial flagellum polymerizes from the inner membrane across the periplasmic space and stops at a length of 25 nm at the outer membrane. Bushing structures, the P- and L-rings, polymerize around the distal rod and form a pore in the outer membrane. The flagellar hook structure is then added to the distal rod growing outside the cell. Hook polymerization stops after the rod-hook structure reaches approximately 80 nm in length. This study describes mutants in the distal rod protein FlgG that fail to terminate rod growth. The mutant FlgG subunits continue to polymerize close to the length of the normal rod-hook structure of 80 nm. These filamentous rod structures have multiple P-rings and fail to form the L-ring pore at the outer membrane. The flagella grow within the periplasm similar to spirochete flagella. This provides a simple method to evolve intracellular flagella as in spirochetes. The mechanism that couples rod growth termination to the ring assembly and outer membrane penetration exemplifies the importance of stopping points in the construction of a complex macromolecular machine that facilitate efficient coupling to the next step in the assembly pathway.

FliK regulates flagellar hook length as an internal ruler

The mechanism of length control of the flagellar hook is under debate between two theories. One claims that the FliK directly measures the hook length as a molecular ruler, while the other claims that the cytoplasmic substructure measures the amount of hook subunits to determine the hook length. Both agree that the FliK C-terminal domain catalyses the substrate-specificity switch to terminate hook elongation. In this study, we systematically created fliK mutants with deletions and insertions at various sites within the FliK N-terminal domain and analysed their effects on the final hook length. Insertions of peptide fragments from the Yersinia YscP into FliK gave rise to hooks with defined lengths, which was proportional to the molecular size of the FliK-YscP chimeras. Among fliK deletion mutants, only those with small truncations in three specific sites of FliK produced hooks of a defined, shortened length. For the majority of deletion mutants, FliK was secreted, but hook length was not controlled. On the other hand, for some deletion mutants FliK was not secreted, but the hook length was controlled, indicating that FliK secretion is not necessary for hook-length control. We conclude that FliK regulates hook length as an internal molecular ruler.

Genomic screening for regulatory genes using the T-POP transposon

The identification of a gene that activates or regulates a gene or regulon of interest often requires the artificial induction of the regulatory gene. The properties of the Tn10-derived transposon T-POP allow a simple chromosomal survey of genes that, when artificially induced from an adjacent T-POP transposon by the addition of tetracycline, can activate or inhibit the expression of virtually any gene of interest. Procedures for genome-wide screening for T-POP inducible regulatory genes are described in detail. T-POP is a derivative of transposon Tn10dTc. It encodes resistance to tetracycline, but unlike Tn10dTc, the tet(A) and tet(R) promoters do not terminate within the transposon. Instead they continue out into adjacent chromosomal DNA. When this element inserts in a gene, three things will result: (1) the target gene is disrupted by the addition of a large block of DNA (approximately 3000 bases); (2) a drug-resistance gene (tetracycline resistance) included in the inserted material is now 100% linked to the insertion mutant phenotype; and (3) the mRNA transcripts initiated at either the tet(A) or tet(R) promoters (or both) will continue out into the adjacent chromosomal DNA. Despite the fancy aspects, insertion mutants are easy to isolate and can be assayed for effects on gene regulation using simple plate tests.

lambda-Red genetic engineering in Salmonella enterica serovar Typhimurium

The use of the recombination system from bacteriophage lambda, lambda-Red, allows for PCR-generated fragments to be targeted to specific chromosomal locations in sequenced genomes. A minimal region of homology of 30 to 50 bases flanking the fragment to be inserted is all that is required for targeted mutagenesis. Procedures for creating specific insertions, deletions, and site-directed changes are described.

The flagellar-specific transcription factor, sigma28, is the Type III secretion chaperone for the flagellar-specific anti-sigma28 factor FlgM

The sigma(28) protein is a member of the bacterial sigma(70)-family of transcription factors that directs RNA polymerase to flagellar late (class 3) promoters. The sigma(28) protein is regulated in response to flagellar assembly by the anti-sigma(28) factor FlgM. FlgM inhibits sigma(28)-dependent transcription of genes whose products are needed late in assembly until the flagellar basal motor structure, the hook-basal body (HBB), is constructed. A second function for the sigma(28) transcription factor has been discovered: sigma(28) facilitates the secretion of FlgM through the HBB, acting as the FlgM Type III secretion chaperone. Transcription-specific mutants in sigma(28) were isolated that remained competent for FlgM-facilitated secretion separating the transcription and secretion-facilitation activities of sigma (28). Conversely, we also describe the isolation of mutants in sigma(28) that are specific for FlgM-facilitated secretion. The data demonstrate that sigma(28) is the Type III secretion chaperone for its own anti-sigma factor FlgM. Thus, a novel role for a sigma(70)-family transcription factor is described.

Regulatory protein that inhibits both synthesis and use of the target protein controls flagellar phase variation in Salmonella enterica

Flagellin is a major surface antigen for many bacterial species. The pathogen Salmonella enterica switches between two alternative, antigenic forms of its flagellin filament protein, either type B or C. This switching (flagellar phase variation) is achieved by stochastic inversion of a promoter that produces both type B flagellin (FljB) and an inhibitor (FljA) of type C flagellin formation. When the fljB-fljA operon is expressed, only type B flagella are produced; when the operon is not transcribed, the gene for type C flagellin (fliC) is released from inhibition and forms type C flagella. Long thought to be a transcription repressor, the FljA inhibitor is shown here to block both translation and use of the FliC protein by binding to an mRNA region upstream from the translation start codon. Bypass mutants resistant to this inhibition alter this mRNA region, and some prevent FljA-RNA binding. Other bypass mutations are duplications within the leader mRNA that make FljA essential for FliC assembly. Certain bypass mutations allow FljA to block FliC-dependent motility without blocking production of the FliC protein, per se. Other mutations in the FliC mRNA leader block expression of the unlinked fljB gene. Results suggest that mRNAs for types B and C flagellin compete for occupancy of a site that directs the product toward assembly and that FljA influences this competition. This mechanism may serve to prevent assembly of flagella with a mixture of subunit types, especially during periods of switching from one type to the other.

Translation inhibition of the Salmonella fliC gene by the fliC 5' untranslated region, fliC coding sequences, and FlgM

The 5'-untranslated region (5'UTR) of the fliC flagellin gene of Salmonella contains sequences critical for efficient fliC mRNA translation coupled to assembly. In a previous study we used targeted mutagenesis of the 5' end of the fliC gene to isolate single base changes defective in fliC gene translation. This identified a predicted stem-loop structure, SL2, as an effector of normal fliC mRNA translation. A single base change (-38C:U) in the fliC 5'UTR resulted in a mutant that is defective in fliC mRNA translation and was chosen for this study. Motile (Mot+) revertants of the -38C:T mutant were isolated and characterized, yielding several unexpected results. Second-site suppressors that restored fliC translation and motility included mutations that disrupt a RNA duplex stem formed between RNA sequences in the fliC 5'UTR SL2 region (including a precise deletion of SL2) and bases early within the fliC-coding region. A stop codon mutation at position 80 of flgM also suppressed the -38C:T motility defect, while flgM mutants defective in anti-sigma28 activity had no effect on fliC translation. One remarkable mutation in the fliC 5'UTR (-15G:A) results in a translation defect by itself but, in combination with the -38C:U mutation, restores normal translation. These results suggests signals intrinsic to the fliC mRNA that have both positive and negative effects on fliC translation involving both RNA structure and interacting proteins.

Transcriptional and translational control of the Salmonella fliC gene

The flagellin gene fliC encodes the major component of the flagellum in Salmonella enterica serovar Typhimurium. This study reports the identification of a signal within the 5' untranslated region (5'UTR) of the fliC transcript required for the efficient expression and assembly of FliC into the growing flagellar structure. Primer extension mapping determined the transcription start site of the fliC flagellin gene to be 62 bases upstream of the AUG start codon. Using tetA-fliC operon fusions, we show that the entire 62-base 5'UTR region of fliC was required for sufficient fliC mRNA translation to allow normal FliC flagellin assembly, suggesting that translation might be coupled to assembly. To identify sequence that might couple fliC mRNA translation to FliC secretion, the 5' end of the chromosomal fliC gene was mutagenized by PCR-directed mutagenesis. Single base sequences important for fliC-dependent transcription, translation, and motility were identified by using fliC-lacZ transcriptional and translational reporter constructs. Transcription-specific mutants identified the -10 and -35 regions of the consensus flagellar class 3 gene promoter. Single base changes defective in translation were located in three regions: the AUG start codon, the presumed ribosomal binding site region, and a region near the very 5' end of the fliC mRNA that corresponded to a potential stem-loop structure in the 5'UTR. Motility-specific mutants resulted from base substitutions only in the fliC-coding region. The results suggest that fliC mRNA translation is not coupled to FliC secretion by the flagellar type III secretion system.

Flk prevents premature secretion of the anti-sigma factor FlgM into the periplasm

The flk locus of Salmonella typhimurium was identified as a regulator of flagellar gene expression in strains defective in P- and l-ring formation. Flk acts as a regulator of flagellar gene expression by modulating the protein levels of the anti-sigma28 factor FlgM. Evidence is presented which suggests that Flk is a cytoplasmic-facing protein anchored to the inner membrane by a single, C-terminal transmembrane-spanning domain (TMS). The specific amino acid sequence of the TMS is not essential for Flk activity, but membrane anchoring is essential. Membrane fractionation and visualization of protein fusions of green fluorescent protein derivatives to Flk suggested that the Flk protein is present in the membrane as punctate spots in number that are much greater than the number of flagellar basal structures. The turnover of the anti-sigma28 factor FlgM was increased in flk mutant strains. Using FlgM-beta-lactamase fusions we show the increased turnover of FlgM in flk null mutations is due to FlgM secretion into the periplasm where it is degraded. Our data suggest that Flk inhibits FlgM secretion by acting as a braking system for the flagellar-associated type III secretion system. A model is presented to explain a role for Flk in flagellar assembly and gene regulatory processes.

Identification of new flagellar genes of Salmonella enterica serovar Typhimurium

RNA levels of flagellar genes in eight different genetic backgrounds were compared to that of the wild type by DNA microarray analysis. Cluster analysis identified new, potential flagellar genes, three putative methyl-accepting chemotaxis proteins, STM3138 (McpA), STM3152 (McpB), and STM3216(McpC), and a CheV homolog, STM2314, in Salmonella, that are not found in Escherichia coli. Isolation and characterization of Mud-lac insertions in cheV, mcpB, mcpC, and the previously uncharacterized aer locus of S. enterica serovar Typhimurium revealed them to be controlled by sigma28-dependent flagellar class 3 promoters. In addition, the srfABC operon previously isolated as an SsrB-regulated operon clustered with the flagellar class 2 operon and was determined to be under FlhDC control. The previously unclassified fliB gene, encoding flagellin methylase, clustered as a class 2 gene, which was verified using reporter fusions, and the fliB transcriptional start site was identified by primer extension analysis. RNA levels of all flagellar genes were elevated in flgM or fliT null strains. RNA levels of class 3 flagellar genes were elevated in a fliS null strain, while deletion of the fliY, fliZ, or flk gene did not affect flagellar RNA levels relative to those of the wild type. The cafA (RNase G) and yhjH genes clustered with flagellar class 3 transcribed genes. Null alleles in cheV, mcpA, mcpB, mcpC, and srfB did not affect motility, while deletion of yhjH did result in reduced motility compared to that of the wild type.

Genetic transplantation: Salmonella enterica serovar Typhimurium as a host to study sigma factor and anti-sigma factor interactions in genetically intractable systems

In Salmonella enterica serovar Typhimurium, sigma(28) and anti-sigma factor FlgM are regulatory proteins crucial for flagellar biogenesis and motility. In this study, we used S. enterica serovar Typhimurium as an in vivo heterologous system to study sigma(28) and anti-sigma(28) interactions in organisms where genetic manipulation poses a significant challenge due to special growth requirements. The chromosomal copy of the S. enterica serovar Typhimurium sigma(28) structural gene fliA was exchanged with homologs of Aquifex aeolicus (an extreme thermophile) and Chlamydia trachomatis (an obligate intracellular pathogen) by targeted replacement of a tetRA element in the fliA gene location using lambda-Red-mediated recombination. The S. enterica serovar Typhimurium hybrid strains showed sigma(28)-dependent gene expression, suggesting that sigma(28) activities from diverse species are preserved in the heterologous host system. A. aeolicus mutants defective for sigma(28)/FlgM interactions were also isolated in S. enterica serovar Typhimurium. These studies highlight a general strategy for analysis of protein function in species that are otherwise genetically intractable and a straightforward method of chromosome restructuring using lambda-Red-mediated recombination.

A little gene with big effects: a serT mutant is defective in flgM gene translation

A conditional-lethal mutant was isolated as having a flagellar regulatory phenotype at 30 degrees C and being unable to grow at 42 degrees C. Chromosomal mapping localized the mutation to the serT gene, which encodes an essential serine tRNA species (tRNA((cmo)5UGA)(Ser)). DNA sequence analysis revealed the mutation to be a single base change in G:A at position 10 of the serT gene that lies within the D-stem of the essential tRNA((cmo)5)UGA(Ser) species. tRNA((cmo)5)UGA(Ser) recognizes UCA, UCG, and UCU codons, but UCU is also recognized by tRNA(GGA)(Ser) and UCG by tRNA(CGA)(Ser). No other tRNAs are known to read the UCA codon. Thus, the UCA codon is specifically recognized by tRNA((cmo)5)UGA(Ser). We show that the anti-sigma(28) activity of FlgM is defective in the serT mutant strain. The serT allele causes a 10-fold increase in sigma(28)-dependent fliC promoter transcription, indicating a defect in FlgM anti-sigma(28) activity in the presence of the serT mutation. The flgM gene contains only one UCA codon. Changing the UCA of flgM to ACG reversed the effect of the serT allele. Implications for context effects in regulation of gene expression are discussed.

Completion of the hook-basal body complex of the Salmonella typhimurium flagellum is coupled to FlgM secretion and fliC transcription

The flhDC operon of Salmonella typhimurium is the master control operon required for the expression of the entire flagellar regulon. The flagellar master operon was placed under the tetracycline-inducible promoter PtetA using the T-POP transposon. Cells containing this construct are motile in the presence of tetracycline and non-motile without inducer present. No flagella were visible under the electron microscope when cells were grown without inducer. The class 1, class 2 and class 3 promoters of the flagellar regulon are temporally regulated. After addition of tetracycline, the class 1 flhDC operon was transcribed immediately. Transcription of flgM (which is transcribed from both class 2 and class 3 promoters) began 15 min after induction. At 20 min after induction, the class 2 fliA promoter became active and intracellular FliA protein levels increased; at 30 min after induction, the class 3 fliC promoter was activated. Induction of fliC gene expression coincides with the appearance of FlgM anti-sigma factor in the growth medium. This also coincides with the completion of hook-basal body structures. Rolling cells first appeared 35 min after induction, and excess hook protein (FlgE) was also found in the growth medium at this time. At 45 min after induction, nascent flagellar filaments became visible in electron micrographs and over 40% of the cells exhibited some swimming behaviour. Multiple flagella assemble and grow on individual cells after induction of the master operon. These results confirm that the flagellar regulatory hierarchy of S. typhimurium is temporally regulated after induction. Both FlgM secretion and class 3 gene expression occur upon completion of the hook-basal body structure.

Translation/secretion coupling by type III secretion systems

Type III secretion systems mediate export of virulence proteins and flagellar assembly subunits in Gram-negative bacteria. Chaperones specific to each class of secreted protein are believed to prevent degradation of the secreted substrates. We show that an additional role of chaperones may be to regulate translation of secreted proteins. We show that the chaperone FIgN is required for translation of the flgM gene transcribed from one mRNA transcript (a flagellar class 3 transcript), but not from another (a flagellar class 2 transcript). FIgM translated from the class 3 transcript is primarily secreted whereas FIgM translated from the class 2 transcript is primarily retained in the cytoplasm. These results suggest FIgM and other type III secretion substrates possess both mRNA and amino acid secretion signals, and supports a new role for type III chaperones in translation/secretion coupling.

The flagellar anti-sigma factor FlgM actively dissociates Salmonella typhimurium sigma28 RNA polymerase holoenzyme

The anti-sigma factor FlgM of Salmonella typhimurium inhibits transcription of class 3 flagellar genes through a direct interaction with the flagellar-specific sigma factor, sigma28. FlgM is believed to prevent RNA polymerase (RNAP) holoenzyme formation by sequestering free sigma28. We have analyzed FlgM-mediated inhibition of sigma28 activity in vitro. FlgM is able to inhibit sigma28 activity even when sigma28 is first allowed to associate with core RNAP. Surface plasmon resonance (SPR) was used to evaluate the interaction between FlgM and both sigma28 and sigma28 holoenzyme (Esigma28). The Kd of the sigma28-FlgM complex is approximately 2 x 10(-10) M; missense mutations in FlgM that cause a defect in sigma28 inhibition in vivo increase the Kd of this interaction by 4- to 10-fold. SPR measurements of Esigma28 dissociation in the presence of FlgM indicate that FlgM destabilizes Esigma28, presumably via an interaction with the sigma subunit. Our data provide the first direct evidence of an interaction between FlgM and Esigma28. We propose that this secondary activity of FlgM, which we term holoenzyme destabilization, enhances the sensitivity of the cell to changes in FlgM levels during flagellar biogenesis.

Flk couples flgM translation to flagellar ring assembly in Salmonella typhimurium

The hook-basal body (HBB) is a key intermediate structure in the flagellar assembly pathway in Salmonella typhimurium. The FlgM protein inhibits the flagellum-specific transcription factor sigma28 in the absence of the intact HBB structure and is secreted out of the cell following HBB completion. The flk gene encodes a positive regulator of the activity of FlgM at an assembly step just prior to HBB completion: at the point of assembly of the P- and L-rings. FlgM inhibition of sigma28-dependent class 3 flagellar gene transcription was relieved in P- and L-ring assembly mutants (flgA, flgH, and flgI) by introduction of a null mutation in the flk gene (J. E. Karlinsey et al., J. Bacteriol. 179:2389-2400, 1997). In P- and L-ring mutant strains, recessive mutations in flk resulted in a reduction in intracellular FlgM levels to those seen in wild-type (Fla+) strains. The reduction in intracellular FlgM levels by mutations in the flk gene was concomitant with a 10-fold increase in transcription of the flgMN operon compared to that of the isogenic flk+ strain, while transcription of the flgAMN operon was unaffected. This was true for both direct measurement of the flgAMN and flgMN mRNA transcripts by RNase T2 protection assays and for lac operon fusions to either the flgAMN or flgMN promoter. Loss of Flk did not allow secretion of FlgM through basal-body structures lacking the P- and L-rings. Intracellular FlgM was stable to proteolysis, and turnover occurred primarily after export out of the cell. Loss of Flk did not result in increased FlgM turnover in either P- or L-ring mutant strains. With lacZ translational fusions to flgM, a null mutation in flk resulted in a significant reduction of flgM-lacZ mRNA translation, expressed from the class 3 flgMN promoter, in P- and L-ring mutant strains. No reduction in either flgAMN or flgMN mRNA stability was measured in the absence of Flk in Fla+, ring mutant, or HBB deletion strains. We conclude that the reduction in the intracellular FlgM levels by mutation in the flk gene is only at the level of flgM mRNA translation.

The flk gene of Salmonella typhimurium couples flagellar P- and L-ring assembly to flagellar morphogenesis

The flagellum of Salmonella typhimurium is assembled in stages, and the negative regulatory protein, FlgM, is able to sense the completion of an intermediate stage of assembly, the basal body-hook (BBH) structure. Mutations in steps leading to the formation of the BBH structure do not express the flagellar filament structural genes, fliC and fljB, due to negative regulation by FlgM (K. L. Gillen and K. T. Hughes, J. Bacteriol. 173:6453-6459, 1991). We have discovered another novel regulatory gene, flk, which appears to sense the completion of another assembly stage in the flagellar morphogenic pathway just prior to BBH formation: the completion of the P- and L-rings. Cells that are unable to assemble the L- or P-rings do not express the flagellin structural genes. Mutations by insertional inactivation in either the flk or flgM locus allow expression of the fljB flagellin structural gene in strains defective in flagellar P- and L-ring assembly. Mutations in the flgM gene, but not mutations in the flk gene, allow expression of the fljB gene in strains defective in all of the steps leading to BBH formation. The flk gene was mapped to min 52 of the S. typhimurium linkage map between the pdxB and fabB loci. A null allele of flk was complemented in trans by a flk+ allele present in a multicopy pBR-based plasmid. DNA sequence analysis of the flk gene has revealed it to be identical to a gene of Escherichia coli of unknown function which has an overlapping, divergent promoter with the pdxB gene promoter (P. A. Schoenlein, B. B. Roa, and M. E. Winkler, J. Bacteriol. 174:6256-6263, 1992). An open reading frame of 333 amino acids corresponding to the flk gene product of S. typhimurium and 331 amino acids from the E. coli sequence was identified. The transcriptional start site of the S. typhimurium flk gene was determined and transcription of the flk gene was independent of the FlhDC and sigma28 flagellar transcription factors. The Flk protein observed in a T7 RNA polymerase-mediated expression system showed an apparent molecular mass of 35 kDa, slightly smaller than the predicted size of 37 kDa. The predicted structure of Flk is a mostly hydrophilic protein with a very C-terminal membrane-spanning segment preceded by positively charged amino acids. This finding predicts Flk to be inserted into the cytoplasmic membrane facing inside the cytoplasm.

The C-terminal half of the anti-sigma factor, FlgM, becomes structured when bound to its target, sigma 28

The interaction between the flagellum specific sigma factor, sigma 28, and its inhibitor, FlgM, was examined using multidimensional heteronuclear NMR. Here we observe that free FlgM is mostly unfolded, but about 50% of the residues become structured when bound to sigma 28. Our analysis suggests that the sigma 28 binding domain of FlgM is contained within the last 57 amino acids of the protein while the first 40 amino acids are unstructured in both the free and bound states. Genetic analysis of flgM mutants that fail to inhibit sigma 28 activity reveal amino acid changes that are also isolated to the C-terminal 57 residues of FlgM. We postulate that the lack of structure in free and bound FlgM is important to its role as an exported protein.

Analysis of the developmental and transcriptional potentiation functions of 5'HS2 of the murine beta-globin locus control region in transgenic mice

We analyze the role of 5'HS2 of the mouse beta-globin LCR in the transcriptional and developmental regulation of beta-globin gene expression. Previous studies have shown that the human beta-globin gene behaves as an adult gene in transgenic mice, being expressed in fetal liver and bone marrow-derived erythroblasts but not in yolk sac-derived embryonic erythroid cells. We show that linkage of mLCR5'HS2 to a human beta-globin gene alters this pattern of expression during ontogeny, resulting in expression of the linked beta-globin gene at all stages of murine erythroid development. Expression was independent of integration position and correlated with transgene copy number. Our results provide the first test of a phylogenetically homologous LCR in transgenic mice and demonstrate evolutionary conservation of both developmental and transcriptional potentiation functions between mammalian beta-globin LCRs.

Sensing structural intermediates in bacterial flagellar assembly by export of a negative regulator

The ability of a regulatory protein to sense the integrity of the bacterial flagellar structure was investigated. In response to a defective hook-basal body complex, the anti-sigma 28 FlgM protein inhibits flagellin transcription. In cells with a functional hook-basal body complex, the flagellin genes are transcribed normally and the FlgM protein is expelled into the growth medium. In strains with a defective hook-basal body structure, FlgM is absent from the media. The presence of flagellin protein in the media is substantially reduced in strains carrying a FlgM-LacZ protein fusion, suggesting that the fusion is blocking the flagellar export apparatus. These results suggest that the FlgM protein assesses the integrity of the flagellar hook-basal body complex by itself being a substrate for export by the flagellar-specific export apparatus.

Sequence-specific interaction of the Salmonella Hin recombinase in both major and minor grooves of DNA

The Hin recombinase of Salmonella catalyzes a site-specific recombination event which leads to flagellar phase variation. Starting with a fully symmetrical recombination site, hixC, a set of 40 recombination sites which vary by pairs of single base substitutions was constructed. This set was incorporated into the Salmonella-specific bacteriophage P22 based challenge phage selection and used to define the DNA sequence determinants for the binding of Hin to DNA in vivo. The critical sequence-specific contacts between a Hin monomer and a 13 bp hix half-site are at two T:A base pairs in the major groove of the DNA which are separated by one base pair, and two consecutive A:T contacts in the minor groove. The base substitutions in the major groove recognition portion which were defective in binding Hin still retained residual binding capability in vivo, while the base pair substitutions affecting the minor groove recognition region lost all in vivo binding. Using in vitro binding assays, Hin was found to bind to hix symmetrical sites with A:T base pairs or I:C base pairs in the minor groove recognition sequences, but not to G:C base pairs. In separate in vitro binding assays, Hin was equally defective in binding to either a G:C or a I:C contact in a major groove recognition sequence. Results from in vitro binding assays to hix sites in which 3-deazaadenine was substituted for adenine are consistent with Hin making a specific contact to either the N3 of adenine or O2 of thymine in the minor groove within the hix recombination site on each symmetric half-site. These results taken with the results of previous studies on the DNA binding domain of Hin suggest a sequence-specific minor groove DNA binding motif.

Agrobacterium tumefaciens virulence locus pscA is related to the Rhizobium meliloti exoC locus

Agrobacterium tumefaciens and Rhizobium meliloti carry related genetic loci which have important roles in virulence and symbiosis. Previously, it was shown that two virulence loci of A. tumefaciens, chvA and chvB, are related to two R. meliloti symbiosis loci, ndvA and ndvB, respectively (T. Dylan, L. Ielpi, S. Stanfield, L. Kashyap, C. Douglas, M. Yanofsky, E. Nester, D. R. Helinski, and G. Ditta, Proc. Natl. Acad. Sci. USA 83:4403-4407, 1986). Here we show that these two phytobacteria possess additional related virulence/symbiosis genes. Results of genetic complementation and DNA hybridization experiments indicate that the pscA virulence locus of A. tumefaciens is structurally and functionally related to the exoC symbiosis locus of R. meliloti. Thus, A. tumefaciens and R. meliloti bear at least three related genetic loci that have crucial roles in establishing the interactions that each bacterium has with its respective host plants.

Identification of a new virulence locus in Agrobacterium tumefaciens that affects polysaccharide composition and plant cell attachment

We have identified a new virulence locus in Agrobacterium tumefaciens. Strains carrying Tn5 inserts at this locus could not incite tumors on Kalanchoe daigremontiana, Nicotiana rustica, tobacco, or sunflower and had severely attenuated virulence on carrot disks. We termed the locus pscA, because the mutants that defined the locus were initially isolated as having an altered polysaccharide composition; they were nonfluorescent on media containing Leucophor or Calcofluor, indicating a defect in the production of cellulose fibrils. Further analysis showed that the pscA mutants produced little, if any, of the four species of exopolysaccharide synthesized by the wild-type strain. DNA hybridization analysis and genetic complementation experiments indicated that the pscA locus is not encoded by the Ti plasmid and that it is distinct from the previously described chromosomal virulence loci chvA and chvB. However, like chvA and chvB mutants, the inability of the pscA mutants to form tumors is apparently due to a defect in plant cell attachment. Whereas we could demonstrate binding of the wild-type strain to tobacco suspension cells, attachment of the pscA mutants was drastically reduced or completely absent.

Antibacterial hemolymph proteins of Manduca sexta

Exclusion column fractionated immune hemolymph of the M. sexta larva contains five peaks of anti-E. coli activity with molecular weights of greater than 140 kD and approximately 91, 54, 14 and 4 kD, plus one peak of lysozyme activity with a molecular weight of 17 kD. Purification of the 54 kD peak showed that this peak consists of the previously described M18 proteins which have monomeric weights of approximately 20 kD and had antibacterial activity against certain gram negative bacteria. Approximately 80% of the total hemolymph antibacterial activity was detected in the 14 and 4 kD peaks. These proteins, which kill both gram negative and gram positive bacteria, appeared to be directly analogous to the cecropins of H. cecropia. The greater than 140 and 91 kD peaks constituted only a minor part of the total antibacterial activity.