The selC-associated SHI-2 pathogenicity island of Shigella flexneri

Pathogenicity islands are chromosomal gene clusters, often located adjacent to tRNA genes, that encode virulence factors present in pathogenic organisms but absent or sporadically found in related non-pathogenic species. The selC tRNA locus is the site of integration of different pathogenicity islands in uropathogenic Escherichia coli, enterohaemorrhagic E. coli and Salmonella enterica. We show here that the selC locus of Shigella flexneri, the aetiological agent of bacterial dysentery, also contains a pathogenicity island. This pathogenicity island, designated SHI-2 (Shigella island 2), occupies 23.8 kb downstream of selC and contains genes encoding the aerobactin iron acquisition siderophore system, colicin V immunity and several novel proteins. Remnants of multiple mobile genetic elements are present in SHI-2. SHI-2-hybridizing sequences were detected in all S. flexneri strains tested and parts of the island were also found in other Shigella species. SHI-2 may allow Shigella survival in stressful environments, such as those encountered during infection.     

Genome-wide identification of novel genomic islands that contribute to Salmonella virulence in mouse systemic infection

Salmonella pathogenicity islands are inserted into the genome by horizontal gene transfer and are required for expression of full virulence. Here, we performed tRNA scanning of the genome of Salmonella enterica serovar Typhimurium and compared it with that of nonpathogenic Escherichia coli in order to identify genomic islands that contribute to Salmonella virulence. Using deletion analysis, we identified four genomic islands that are required for virulence in the mouse infection model. One of the newly identified pathogenicity islands was the pheV- tRNA-located genomic island, which is comprised of 26 126 bp, and encodes 22 putative genes, including STM3117–STM3138. We also showed that the pheV tRNA-located genomic island is widely distributed among different nontyphoid Salmonella serovars. Furthermore, genes including STM3118–STM3121 were identified as novel virulence-associated genes within the pheV- tRNA-located genomic island. These results indicate that a Salmonella -specific pheV- tRNA genomic island is involved in Salmonella pathogenesis among the nontyphoid Salmonella serovars.     

Acquisition and evolution of the exoU locus in Pseudomonas aeruginosa

ExoU is a potent Pseudomonas aeruginosa cytotoxin translocated into host cells by the type III secretion system. A comparison of genomes of various P. aeruginosa strains showed that that the ExoU determinant is found in the same polymorphic region of the chromosome near a tRNA(Lys) gene, suggesting that exoU is a horizontally acquired virulence determinant. We used yeast recombinational cloning to characterize four distinct ExoU-encoding DNA segments. We then sequenced and annotated three of these four genomic regions. The sequence of the largest DNA segment, named ExoU island A, revealed many plasmid- and genomic island-associated genes, most of which have been conserved across a broad set of beta- and gamma-Proteobacteria. Comparison of the sequenced ExoU-encoding genomic islands to the corresponding PAO1 tRNA(Lys)-linked genomic island, the pathogenicity islands of strain PA14, and pKLC102 of clone C strains allowed us to propose a mechanism for the origin and transmission of the ExoU determinant. The evolutionary history very likely involved transposition of the ExoU determinant onto a transmissible plasmid, followed by transfer of the plasmid into different P. aeruginosa strains. The plasmid subsequently integrated into a tRNA(Lys) gene in the chromosome of each recipient, where it acquired insertion sequences and underwent deletions and rearrangements. We have also applied yeast recombinational cloning to facilitate a targeted mutagenesis of ExoU island A, further demonstrating the utility of the specific features of the yeast capture vector for functional analyses of genes on large horizontally acquired genetic elements.     

EilA, a HilA-like regulator in enteroaggregative Escherichia coli

Enteroaggregative Escherichia coli (EAEC) is increasingly recognized as a diarrhoeal pathogen in developing and industrialized countries. Most EAEC virulence factors thus far described are encoded on virulence plasmid pAA, yet recent completion of the EAEC genome has suggested the presence of additional factors encoded on chromosomal islands. Previous reports have recognized the presence of a type III secretion system (T3SS), designated ETT2, at the glyU locus of prototype EAEC strain 042, along with possible T3SS effectors at the selC locus. The selC locus was also noted to harbour homologues of Salmonella enterica regulator HilA and of invasin from Yersinia spp., yet previous publications suggested that these loci may be silent. Here, we show that the genes of the selC locus are present inconsistently among a collection of well-characterized EAEC strains. Notably, however, there was perfect correlation between the presence of hilA-homologue eilA and predicted Yersinia invasin homologue gene eaeX. We hypothesized that if expressed, the putative gene product EilA would contribute to EAEC virulence in part by activation of the T3SS and its effectors. An eilA mutant was constructed in EAEC strain 042, and complementation was achieved by cloning the eilA gene under control of an arabinose-dependent promoter. In this system, we observed expression of at least seven genes to be affected by expression of eilA, either directly or indirectly: selC locus genes eipB, eipC, eipD, eicA and eaeX (renamed here air), as well as glyU ETT2 genes eivF and eivA. Notably, the eilA mutant was shown to be less adherent to epithelial cells in culture and to form less abundant biofilms than the isogenic parent. These effects were recapitulated in the air mutant, suggesting that the predicted outer membrane protein product of the air gene is involved as an accessory adhesin and aggregin of EAEC, coexpressed with the T3SS. Our data suggest that the T3SS of EAEC and presumed effectors located on different chromosomal islands may be coordinately activated by EilA, which also activates the genetically linked high molecular weight bacterial surface protein Air. Contributions of this new putative virulence-related regulon in EAEC may include adherence, aggregation, and as yet uncharacterized roles for the T3SS.     

PIPS: pathogenicity island prediction software

The adaptability of pathogenic bacteria to hosts is influenced by the genomic plasticity of the bacteria, which can be increased by such mechanisms as horizontal gene transfer. Pathogenicity islands play a major role in this type of gene transfer because they are large, horizontally acquired regions that harbor clusters of virulence genes that mediate the adhesion, colonization, invasion, immune system evasion, and toxigenic properties of the acceptor organism. Currently, pathogenicity islands are mainly identified in silico based on various characteristic features: (1) deviations in codon usage, G+C content or dinucleotide frequency and (2) insertion sequences and/or tRNA genetic flanking regions together with transposase coding genes. Several computational techniques for identifying pathogenicity islands exist. However, most of these techniques are only directed at the detection of horizontally transferred genes and/or the absence of certain genomic regions of the pathogenic bacterium in closely related non-pathogenic species. Here, we present a novel software suite designed for the prediction of pathogenicity islands (pathogenicity island prediction software, or PIPS). In contrast to other existing tools, our approach is capable of utilizing multiple features for pathogenicity island detection in an integrative manner. We show that PIPS provides better accuracy than other available software packages. As an example, we used PIPS to study the veterinary pathogen Corynebacterium pseudotuberculosis, in which we identified seven putative pathogenicity islands.     

Multiple insertions of fimbrial operons correlate with the evolution of Salmonella serovars responsible for human disease

On centisome 7, Salmonella spp. contain a large region not present in the corresponding region of Escherichia coli. This region is flanked by sequences with significant homology to the E. coli tRNA gene aspV and the hypothetical E. coli open reading frame yafV. The locus consists of a mosaic of differentially acquired inserts forming a dynamic cs7 region of horizontally transferred inserts. Salmonella enterica subspecies I, responsible for most Salmonella infections in warm-blooded animals, carries a fimbrial gene cluster (saf) in this region as well as a regulatory gene (sinR). These genes are flanked by inverted repeats and are inserted in another laterally transferred region present in most members of Salmonella spp. encoding a putative invasin (pagN ). S. enterica subspecies I serovar Typhi, the Salmonella serovar that causes the most severe form of human salmonellosis, contains an additional insert of at least 8 kb in the sinR-pagN intergenic region harbouring a novel fimbrial operon (tcf ) similar to the coo operon encoding the CS1 fimbrial adhesin expressed by human-specific enterotoxigenic E. coli. It is suggested that the multiple insertions of fimbrial genes that have occurred in the cs7 region have contributed to phylogenetic diversity and host adaptation of Salmonella spp.     

致病性大肠埃希菌和沙门菌毒力岛基因的双重PCR检测方法的建立

目的实现对致病性大肠埃希菌（E．coli）、沙门菌（Salmonella）的同时检测,建立快速灵敏的双重PCR检测方法。方法以致病性大肠埃希菌和沙门菌毒力岛基因为研究对象,根据GenBank发表的大肠埃希菌和沙门菌毒力岛基因序列,分别设计合成了大肠埃希菌毒力岛irpl、irl）2和fyuA,沙门菌毒力岛mgtC、sseL和sopB等6对引物,以禽致病性大肠埃希菌（CVCC1565）菌株和沙门菌（ATCC9150）菌株的核酸混合物为模板,经引物特异性试验,引物组合,成功建立了快速鉴别检测致病性大肠埃希菌和沙门菌的双重PCR方法。结果特异性试验结果显示,引物irpl、irp2和fyuA仅能扩增出大肠埃希菌（CVCC1565）的特异性片段,大小分别是799、414和948bp;引物mgtC、sseL和sopB仅能扩增出沙门菌（ATCC9150）的特异性片段,大小分别是500、269和1000bp。敏感性试验结果表明大肠埃希菌和沙门菌的最低检测限分别为2．2×101CFU／mL和2．0×101CFU／mL。结论本研究建立的双重PCR方法具有特异性强、敏感性高、快速简便等特点,可用于致病性大肠埃希菌和沙门菌的联合检测与鉴别诊断。     

A parallel intraphagosomal survival strategy shared by mycobacterium tuberculosis and Salmonella enterica

Mycobacterium tuberculosis and Salmonella enterica cause very different diseases and are only distantly related. However, growth within macrophages is crucial for virulence in both of these intracellular pathogens. Here, we demonstrate that in spite of the phylogenetic distance, M. tuberculosis and Salmonella employ a parallel survival strategy for growth within macrophage phagosomes. Previous studies established that the Salmonella mgtC gene is required for growth within macrophages and for virulence in vivo. M. tuberculosis contains an open reading frame exhibiting 38% amino acid identity with the Salmonella MgtC protein. Upon inactivation of mgtC, the resulting M. tuberculosis mutant was attenuated for virulence in cultured human macrophages and impaired for growth in the lungs and spleens of mice. Replication of the mgtC mutant was inhibited in vitro by a combination of low magnesium and mildly acidic pH suggesting that the M. tuberculosis-containing phagosome has these characteristics. The similar phenotypes displayed by the mgtC mutants of M. tuberculosis and Salmonella suggest that the ability to acquire magnesium is essential for virulence in intracellular pathogens that proliferate within macrophage phagosomes.     

Salmonella pathogenicity islands: big virulence in small packages

Reflecting a complex set of interactions with its host, Salmonella spp. require multiple genes for full virulence. Many of these genes are found in 'pathogenicity islands' in the chromosome. Salmonella typhimurium possesses at least five such pathogenicity islands (SPI), which confer specific virulence traits and may have been acquired by horizontal transfer from other organisms. We highlight recent progress in characterizing these SPIs and the function of some of their genes. The role of virulence genes found on a highly conserved plasmid is also discussed. Collectively, these packages of virulence cassettes are essential for Salmonella pathogenesis.     

Occurrence and functional compatibility within Enterobacteriaceae of a tRNA species which inserts selenocysteine into protein.

The selC gene from E. coli codes for a tRNA species (tRNA(UCASer] which is aminoacylated with L-serine and which cotranslationally inserts selenocysteine into selenoproteins. By means of Southern hybridization it was demonstrated that this gene occurs in all enterobacteria tested. To assess whether the unique primary and secondary structural features of the E. coli selC gene product are conserved in that of other organisms, the selC homologue from Proteus vulgaris was cloned and sequenced. It was found that the Proteus selC gene differs from the E. coli counterpart in only six nucleotides, that it displays the same unique properties and that it is expressed and functions in E. coli. This indicates that the unique mechanism of selenocysteine incorporation is not restricted to E. coli but has been conserved as a uniform biochemical process.     

Genes coding for the selenocysteine-inserting tRNA species from Desulfomicrobium baculatum and Clostridium thermoaceticum: structural and evolutionary implications.

The genes (selC) coding for the selenocysteine-inserting tRNA species (tRNA(Sec)) from Clostridium thermoaceticum and Desulfomicrobium baculatum were cloned and sequenced. Although they differ in numerous positions from the sequence of the Escherichia coli selC gene, they were able to complement the selC lesion of an E. coli mutant and to promote selenoprotein formation in the heterologous host. The tRNA(Sec) species from both organisms possess all of the unique primary, secondary, and tertiary structural features exhibited by E. coli tRNA(Sec) (C. Baron, E. Westhof, A. Böck, and R. Giegé, J. Mol. Biol. 231:274-292, 1993). The structural and functional properties of the tRNA(Sec) species from prokaryotes analyzed thus far support the notion that tRNA(Sec) may be an evolutionarily conserved structure whose function in the primordial genetic code was to decode UGA with selenocysteine.     

Role of antigens and virulence factors of Salmonella enterica serovar Typhi in its pathogenesis

Salmonella enterica serovar Typhi (S. Typhi), the aetiologic agent of typhoid fever, is a human restricted pathogen. The molecular mechanism of Salmonella pathogenicity is complex. The investigations of the molecular mechanisms of Salmonella virulence factors have shown that pathogenic Salmonella spp. are distinguished from their non-pathogenic relatives by the presence of specific pathogenicity genes, often organized in so-called pathogenicity islands (PIs). The type III secretion system (T3SS) proteins encoded by two Salmonella PIs (SPIs) are associated with the pathogenicity at molecular level. The identification of T3SS has provided new insight into the molecular factors and mechanisms underlying bacterial pathogenesis. The T3SS encoded by SPI-1 contains invasion genes; while SPI-2 is responsible for intracellular pathogenesis and has a crucial role for systemic S. enterica infections. These studies reveal a complex set of pathogenic interferences between intracellular Salmonella and its host cells. The understanding of the mechanisms by which Salmonella evade the host defense system and establish pathogenesis will be important for proper disease management.     

LeuX tRNA-dependent and -independent mechanisms of Escherichia coli pathogenesis in acute cystitis

Uropathogenic Escherichia coli (UPEC) contain multiple horizontally acquired pathogenicity-associated islands (PAI) implicated in the pathogenesis of urinary tract infection. In a murine model of cystitis, type 1 pili-mediated bladder epithelial invasion and intracellular proliferation are key events associated with UPEC virulence. In this study, we examined the mechanisms by which a conserved PAI contributes to UPEC pathogenesis in acute cystitis. In the human UPEC strain UTI89, spontaneous excision of PAI II(UTI89) disrupts the adjacent leuX tRNA locus. Loss of wild-type leuX-encoded tRNA(5)(Leu) significantly delayed, but did not eliminate, FimB recombinase-mediated phase variation of type 1 pili. FimX, an additional FimB-like, leuX-independent recombinase, was also found to mediate type 1 pili phase variation. However, whereas FimX activity is relatively slow in vitro, it is rapid in vivo as a non-piliated strain lacking the other fim recombinases rapidly expressed type 1 pili upon experimental infection. Finally, we found that disruption of leuX, but not loss of PAI II(UTI89) genes, reduced bladder epithelial invasion and intracellular proliferation, independent of type 1 piliation. These findings indicate that the predominant mechanism for preservation of PAI II(UTI89) during the establishment of acute cystitis is maintenance of wild-type leuX, and not PAI II(UTI89) gene content.     

Composition,acquisition, and distribution of the Vi exopolysaccharide-encoding Salmonella enterica pathogenicity island SPI-7

Vi capsular polysaccharide production is encoded by the viaB locus, which has a limited distribution in Salmonella enterica serovars. In S. enterica serovar Typhi, viaB is encoded on a 134-kb pathogenicity island known as SPI-7 that is located between partially duplicated tRNA(pheU) sites. Functional and bioinformatic analysis suggests that SPI-7 has a mosaic structure and may have evolved as a consequence of several independent insertion events. Analysis of viaB-associated DNA in Vi-positive S. enterica serovar Paratyphi C and S. enterica serovar Dublin isolates revealed the presence of similar SPI-7 islands. In S. enterica serovars Paratyphi C and Dublin, the SopE bacteriophage and a 15-kb fragment adjacent to the intact tRNA(pheU) site were absent. In S. enterica serovar Paratyphi C only, a region encoding a type IV pilus involved in the adherence of S. enterica serovar Typhi to host cells was missing. The remainder of the SPI-7 islands investigated exhibited over 99% DNA sequence identity in the three serovars. Of 30 other Salmonella serovars examined, 24 contained no insertions at the equivalent tRNA(pheU) site, 2 had a 3.7-kb insertion, and 4 showed sequence variation at the tRNA(pheU)-phoN junction, which was not analyzed further. Sequence analysis of the SPI-7 region from S. enterica serovar Typhi strain CT18 revealed significant synteny with clusters of genes from a variety of saprophytic bacteria and phytobacteria, including Pseudomonas aeruginosa and Xanthomonas axonopodis pv. citri. This analysis suggested that SPI-7 may be a mobile element, such as a conjugative transposon or an integrated plasmid remnant.     

Occurrence in vivo of selenocysteyl-tRNA(SERUCA) in Escherichia coli. Effect of sel mutations

The selC gene of Escherichia coli codes for a novel tRNA species which is aminoacylated by L-serine and is required for the insertion of selenocysteine into proteins (Leinfelder, W., Zehelein, E., Mandrand-Berthelot, M.-A., and B?ck, A. (1988) Nature 331, 723-725). As a first step toward the elucidation of the postulated pathway for selenocysteine formation from an L-serine residue esterified to tRNA, we have examined whether an increase in the selC gene dosage allows the demonstration of selenocysteyl-tRNA formation in vivo. To this end, cells of an E. coli strain carrying selC on a multicopy plasmid were labeled with [75Se]selenite, their tRNA was isolated and deacylated, and the hydrolysate was analyzed by thin layer chromatography and ion exchange chromatography. Both methods unequivocally demonstrated that the increase in the selC gene product concentration correlated with an augmented level of selenocysteine bound to tRNA. The formation of selenocysteine depended on the presence of functional products of the selA and selD genes but not of the selB gene. The selB gene product, therefore, may have a function in the decoding step itself.