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Notes: EspG, a secreted effector of enteropathogenic Escherichia coli (EPEC), as well as its homologue Orf3, has been shown to disrupt microtubules (MTs) in fibroblasts and non-polarized epithelial cells. The roles of MTs and the effects of MT disruption in these cell types differ significantly. The aim of this study was to investigate the effects of EspG on polarized, host target intestinal epithelial cells. Immunofluorescent labelling of tubulin showed that EPEC caused progressive fragmentation and loss of the MT network in cells harbouring attached organisms. Immunoblots of proteins extracted from EPEC-infected cells showed a corresponding loss of α-tubulin. Type III secretion system (TTSS)-deficient strains had no effect on MT suggesting TTSS dependence. Mutation of espG, but not espF or map, ablated EPEC's effects on MTs for up to 6 h. Ectopic expression of EspG in HeLa cells caused MT disruption. While deletion of espG alone had no effect on the EPEC-induced decrease in transepithelial electrical resistance (TER), mutation of both espG and orf3 significantly delayed the kinetics of this response. Complementation of the double mutant with espG alone restored the kinetics of TER drop to that of wild type. Herein, we describe a previously unrecognized phenotype for the EPEC effectors EspG and Orf3.

Notes: Enteropathogenic Escherichia coli (EPEC) uses a type III secretion system to translocate into host cells several effector molecules that are required for virulence. One of these, the translocated intimin receptor, Tir, inserts into the host cell cytoplasmic membrane, where it functions as the receptor for intimin, an outer membrane adhesin expressed by EPEC. A chaperone for Tir, called CesT, is required for stability of Tir in the EPEC cytoplasm. In this study, the cyaA gene reporter system was used to identify domains in Tir that mediate secretion into the culture supernatant and translocation into host cells. A Tir–CyaA fusion containing the first 15 N-terminal residues of Tir was secreted and translocated into HeLa cells by a ΔtirΔcesT mutant; however, maximal secretion and translocation was observed with the first 26 N-terminal residues of Tir. Fusions containing progressively larger N-terminal sequences of Tir were also efficiently secreted and translocated into HeLa cells by the ΔtirΔcesT strain. However, in a Δtir mutant that expresses CesT, Tir26–CyaA and an additional fusion containing the first 69 N-terminal residues of Tir were not secreted or translocated, but fusions containing larger N-terminal Tir sequences were secreted and translocated by the Δtir mutant. Wild-type EPEC secreted and translocated the Tir15–CyaA fusion, whereas longer fusions, such as Tir26–CyaA and Tir69–CyaA, were translocated to higher levels, similar to what was observed with the ΔtirΔcesT mutant. A Tir–CyaA fusion containing the CesT binding domain was translocated into HeLa cells more rapidly in the presence of CesT compared with translocation in the absence of CesT. Collectively, these results suggest that an N-terminal domain of 26 amino acids functions as a CesT-independent signal that is capable of delivering Tir into both the culture supernatant and the cytosol of host cells. Furthermore, in addition to its role in the stability of Tir, CesT may function in translocation by mediating rapid delivery of Tir into host cells.

Notes: Abstract Virulence factors of pathogenic bacteria (adhesins, toxins, invasins, protein secretion systems, iron uptake systems, and others) may be encoded by particular regions of the prokaryotic genome termed pathogenicity islands. Pathogenicity islands were first described in human pathogens of the species Escherichia coli, but have recently been found in the genomes of various pathogens of humans, animals, and plants. Pathogenicity islands comprise large genomic regions [10-200 kilobases (kb) in size] that are present on the genomes of pathogenic strains but absent from the genomes of nonpathogenic members of the same or related species. The finding that the G+C content of pathogenicity islands often differs from that of the rest of the genome, the presence of direct repeats at their ends, the association of pathogenicity islands with transfer RNA genes, the presence of integrase determinants and other mobility loci, and their genetic instability argue for the generation of pathogenicity islands by horizontal gene transfer, a process that is well known to contribute to microbial evolution. In this article we review these and other aspects of pathogenicity islands and discuss the concept that they represent a subclass of genomic islands. Genomic islands are present in the majority of genomes of pathogenic as well as nonpathogenic bacteria and may encode accessory functions which have been previously spread among bacterial populations.

Notes: Quorum sensing is a cell-to-cell signalling mechanism in which bacteria secrete hormone-like compounds called autoinducers. When these auto-inducers reach a certain threshold concentration, they interact with bacterial transcriptional regulators, thereby regulating gene expression. Enterohaemorrhagic Escherichia coli (EHEC) O157:H7 as well as E. coli K-12 produces the autoinducer-2 (AI-2), which is synthesized by the product of the luxS gene, and previous work from our laboratory has shown that genes encoding the EHEC type III secretion system were activated by quorum sensing. Recently, by hybridizing an E. coli K-12 gene array with cDNA synthesized from RNA extracted from EHEC strain 86-24 and its isogenic luxS mutant, we observed that other potential virulence-associated factors, such as genes encoding the expression and assembly of flagella, motility and chemotaxis, were also activated by quorum sensing. The array data also indicated that several genes encoding putative E. coli regulators were controlled by quorum sensing. In this report, we describe a two-component system regulated by quorum sensing that shares homology with Salmonella typhimurium PmrAB, which we have named quorum sensing E. coli regulator B and C (QseBC). The qseBC genes, previously identified only as open reading frames b3025 and b3026, are organized in an operon in the E. coli chromosome, with qseB encoding the response regulator and qseC the sensor kinase. We confirmed the regulation of qseBC by quorum sensing using qseB::lacZ transcriptional fusions and characterized the phenotypes of an isogenic qseC mutation in EHEC. This mutant expressed less flagellin and had reduced motility compared with the wild-type and complemented strains. Transcription of flhD, fliA, motA and fliC::lacZ fusions was decreased in the qseC mutant, suggesting that qseBC is a transcriptional regulator of flagella genes. A qseC mutant was also generated in E. coli K-12 strain MC1000 that showed the same phenotypes as the EHEC mutant, indicating that qseBC regulates flagella and motility by quorum sensing in both EHEC and K-12. QseBC activates transcription of flhDC, which is the master regulator for the flagella and motility genes and, in the absence of flhD, QseBC failed to activate the transcription of fliA. Motility of a luxS, but not of a qseC, mutant can be restored by providing AI-2 exogenously as preconditioned media, suggesting that the qseC mutant is unable to respond to AI-2. However, QseC has no effect on the expression of other quorum sensing-controlled genes such as those encoding for the type III secretion system. These data indicate that QseBC is one component of the quorum-sensing regulatory cascade in both EHEC and K-12 that is involved in the regulation of flagella and motility genes, but that additional regulators in this cascade remain to be characterized.

Notes: Enteropathogenic Escherichia coli (EPEC) utilizes a type III protein secretion system to target effector molecules into the host cell leading to effacement of the intestinal mucosa. This secretion apparatus shares many structural features of the flagellar type III export system involved in flagella assembly and motility. We report here that fliC insertional mutants constructed in two wild-type EPEC strains were markedly impaired in adherence and microcolony formation on cultured cells. An E. coli K-12 strain harbouring the EPEC H6 fliC gene on a plasmid showed discrete adhering clusters on HeLa cells, albeit to less extent than the wild-type EPEC strain. Flagella purified from EPEC bound to cultured epithelial cells and antiflagella antibodies blocked adherence of several EPEC serotypes. We determined that eukaryotic cells in culture stimulate expression of flagella by motile and non-motile EPEC. Isogenic strains mutated in perA (a transcriptional activator), bfpA (a type IV pilin), luxS (a quorum-sensing autoinducer gene) and in the type III secretion genes were reduced for motility in Dulbecco’s modified Eagle medium (DMEM) motility agar and produced none or few flagella when associated with epithelial cells. Growth of these mutants in preconditioned tissue culture medium restored motility and their ability to produce flagella, suggesting the influence of a signal provided by mammalian cells that triggers flagella production. This study shows for the first time that the flagella of EPEC are directly involved in the adherence of these bacteria and supports the existence of a molecular relationship between the two existing type III secretion pathways of EPEC, the EPEC adherence factor (EAF) plasmid-encoded regulator, quorum sensing and epithelial cells.

Notes: In many Gram-negative bacteria, a key indicator of pathogenic potential is the possession of a specialized type III secretion system, which is utilized to deliver virulence effector proteins directly into the host cell cytosol. Many of the proteins secreted from such systems require small cytosolic chaperones to maintain the secreted substrates in a secretion-competent state. One such protein, CesT, serves a chaperone function for the enteropathogenic Escherichia coli (EPEC) translocated intimin receptor (Tir) protein, which confers upon EPEC the ability to alter host cell morphology following intimate bacterial attachment. Using a combination of complementary biochemical approaches, functional domains of CesT that mediate intermolecular interactions, involved in both chaperone–chaperone and chaperone–substrate associations, were determined. The CesT N-terminal is implicated in chaperone dimerization, whereas the amphipathic α-helical region of the C-terminal, is intimately involved in substrate binding. By functional complementation of chaperone domains using the Salmonella SicA chaperone to generate chaperone chimeras, we show that CesT–Tir interaction proceeds by a mechanism potentially common to other type III secretion system chaperones.

Notes: A second region containing five genes homologous to the long polar fimbrial operon of Salmonella enterica serovar Typhimurium is located in the chromosome of enterohemorrhagic Escherichia coli (EHEC) O157:H7. A non-fimbriated E. coli K-12 strain carrying the cloned EHEC lpf (lpf2) genes expressed thin fibrillae-like structures on its surface and displayed reduced adherence to tissue culture cells. Neither mutation in the lpfA2 gene in either the parent or lpfA1 mutant strains showed an effect in adherence or in the formation of A/E lesions on HeLa cells. lpfA2 isogenic mutant strains adhere to Caco-2 cells almost as well as the wild-type at 5 h, but they were deficient in adherence at early time points. A collection of diarrheagenic E. coli strains were investigated for the presence of lpfA1 and lpfA2 and results showed that these genes are present in specific serogroups which are phylogenetically related. Our results suggest that LP fimbriae 2 may contribute to the early stages of EHEC adhesion and that genes encoding the major LP fimbrial subunits are present in a small group of EHEC and EPEC serotypes.

Notes: The locus of enterocyte effacement pathogenicity island confers the attaching and effacing histopathology on epithelial cells infected with enteropathogenic and enterohemorrhagic Escherichia coli. We investigated the site of insertion of the locus of enterocyte effacement in E. coli strains in relation to their evolution based on conservation of housekeeping proteins in these strains. The results indicate that the insertion site of the locus of enterocyte effacement varies according to the evolutionary lineage, suggesting that it has inserted at multiple times and sites during the evolution of these pathogens.

Notes: All proteins involved in the attachment and effacement lesion produced by enteropathogenic Escherichia coli (EPEC) and Shiga-toxin producing E. coli (STEC) are encoded by the locus of enterocyte effacement (LEE). We studied the presence and insertion site of the LEE in different EPEC and STEC strains. In serotypes O119:H6/H−, O55:H6, O55:H7, O142:H6, O111ac:H9/H−, O111ab:H9/H− LEE is inserted downstream of selC as previously described for EPEC O127:H6 and STEC O157:H7. In serotypes O111ac:H8/H− and O26:H11/H− the LEE is inserted in pheU as previously described for STEC O26:H−. However in EPEC from serotype O111ab:H25 the LEE is not inserted in either site suggesting a third insertion site in the K12 chromosome. We also cloned fragments of 2.3 kb and 1.0 kb from the right and left hand sides of the LEE of a O111ac:H− strain and identified additional insertion sequences on these LEE fragments, suggesting that the LEE may be larger and may have undergone more recombination events in these serotypes.

Notes: We describe a locus of enterocyte effacement (LEE) which is part of a new pathogenicity island (PAI) detected in the bovine Shiga toxin-producing Escherichia coli strain RW1374 (O103:H2). This PAI is at least 80 kb in size and inserted in the vicinity of the pheV tRNA gene at 67 min of the E. coli chromosome. Furthermore, the PAI differs from the previously described LEEs by unique flanking regions at both sides, which harbor one copy each of an insertion element in an inverted orientation that is 96% identical to insertion site (IS)629. In addition, a 5-kb PAI-specific sequence downstream of the LEE core region and adjacent to the E. coli K12 region is duplicated upstream of the LEE core region as well. The duplicated sequences are more than 80% identical to each other and consist partially of prophage sequences.