SOS regulation of the type III secretion system of enteropathogenic Escherichia coli

Genomes of bacterial pathogens contain and coordinately regulate virulence-associated genes in order to cause disease. Enteropathogenic Escherichia coli (EPEC), a major cause of watery diarrhea in infants and a model gram-negative pathogen, expresses a type III secretion system (TTSS) that is encoded by the locus of enterocyte effacement (LEE) and is necessary for causing attaching and effacing intestinal lesions. Effector proteins encoded by the LEE and in cryptic prophage are injected into the host cell cytoplasm by the TTTS apparatus, ultimately leading to diarrhea. The LEE is comprised of multiple polycistronic operons, most of which are controlled by the global, positive regulator Ler. Here we demonstrated that the LEE2 and LEE3 operons also responded to SOS signaling and that this regulation was LexA dependent. As determined by a DNase I protection assay, purified LexA protein bound in vitro to a predicted SOS box located in the divergent, overlapping LEE2/LEE3 promoters. Expression of the lexA1 allele, encoding an uncleavable LexA protein in EPEC, resulted in reduced secretion, particularly in the absence of the Ler regulator. Finally, we obtained evidence that the cryptic phage-located nleA gene encoding an effector molecule is SOS regulated. Thus, we demonstrated, for the first time to our knowledge, that genes encoding components of a TTSS are regulated by the SOS response, and our data might explain how a subset of EPEC effector proteins, encoded in cryptic prophages, are coordinately regulated with the LEE-encoded TTSS necessary for their translocation into host cells.     

EspC translocation into epithelial cells by enteropathogenic Escherichia coli requires a concerted participation of type V and III secretion systems

EspC is a non-locus of enterocyte effacement (LEE)-encoded autotransporter protein secreted by enteropathogenic Escherichia coli (EPEC) that causes a cytopathic effect on epithelial cells, including cytoskeletal damage. EspC cytotoxicity depends on its internalization and functional serine protease motif. Here we show that during EPEC infection, EspC is secreted from the bacteria by the type V secretion system (T5SS) and then it is efficiently translocated into the epithelial cells through the type III secretion system (T3SS) translocon. By dissecting this mechanism, we found that EspC internalization during EPEC-host cell interaction occurs after 1 h, unlike purified EspC (8 h). LEE pathogenicity island is involved in specific EspC translocation as three espC-transformed attaching and effacing (AE) pathogens translocated EspC into the cells. A role for effectors and other factors involved in the intimate adherence encoded in LEE were discarded by using an exogenous EspC internalization model. In this model, an isogenic EPEC DeltaespC strain allows the efficient internalization of purified EspC. Moreover, isogenic mutants in T3SS were unable to translocate endogenous and exogenous EspC into epithelial cells, as EspC-EspA interaction is required. These data show for the first time the efficient delivery of an autotransporter protein inside the epithelial cells by EPEC, through cooperation between T5SS and T3SS.     

Targeting of an enteropathogenic Escherichia coli (EPEC) effector protein to host mitochondria

Many Gram-negative pathogens use a type III secretion apparatus to deliver effector molecules into host cells to subvert cellular processes in favour of the pathogen. Enteropathogenic Escherichia coli (EPEC) uses such a system to deliver the Tir effector molecule into host cells. In this paper, we show that the gene upstream of tir , orf 19, encodes an additional type III secreted effector protein. Orf19 is delivered into host cells by a mechanism independent of endocytosis, but dependent on EspB. Orf19 is targeted to host mitochondria, where it appears to interfere with the ability to maintain membrane potential. Although the precise role of Orf19 remains to be elucidated, its interaction with mitochondria suggests a possible role in the subversion of key functions of these organelles, such as energy production or control of cell death. This is the first example of a type III secreted protein targeted to mitochondria; it is probable that homologues (present in EPEC and Shigella species) and other bacterial effectors will also target this organelle.     

EscE and EscG Are Cochaperones for the Type III Needle Protein EscF of Enteropathogenic Escherichia coli

Type III secretion systems (T3SSs) are central virulence mechanisms used by a variety of Gram-negative bacteria to inject effector proteins into host cells. The needle polymer is an essential part of the T3SS that provides the effector proteins a continuous channel into the host cytoplasm. It has been shown for a few T3SSs that two chaperones stabilize the needle protein within the bacterial cytosol to prevent its premature polymerization. In this study, we characterized the chaperones of the enteropathogenic Escherichia coli (EPEC) needle protein EscF. We found that Orf2 and Orf29, two poorly characterized proteins encoded within the EPEC locus of enterocyte effacement (LEE), function as the needle protein cochaperones. Our finding demonstrated that both Orf2 and Orf29 are essential for type III secretion (T3S). In addition, we found that Orf2 and Orf29 associate with the bacterial membrane and form a complex with EscF. Orf2 and Orf29 were also shown to disrupt the polymerization of EscF in vitro. Prediction of the tertiary structures of Orf2 and Orf29 showed high structural homology to chaperones of other T3SS needle proteins. Overall, our data suggest that Orf2 and Orf29 function as the chaperones of the needle protein, and therefore, they have been renamed EscE and EscG.     

EscA is a crucial component of the type III secretion system of enteropathogenic Escherichia coli

The virulence of many Gram-negative pathogens is associated with type III secretion systems (T3SSs), which deliver virulence effector proteins into the cytoplasm of host cells. Components of enteropathogenic Escherichia coli (EPEC) T3SS are encoded within the locus of enterocyte effacement (LEE). While most LEE-encoded T3SS proteins in EPEC have assigned names and functions, a few of them remain poorly characterized. Here, we studied a small LEE-encoded protein, Orf15, that shows no homology to other T3SS/flagellar proteins and is only present in attaching and effacing pathogens, including enterohemorrhagic E. coli and Citrobacter rodentium. Our findings demonstrated that it is essential for type III secretion (T3S) and that it is localized to the periplasm and associated with the inner membrane. Membrane association was driven by the N-terminal 19 amino acid residues, which were also shown to be essential for T3S. Consistent with its localization, Orf15 was found to interact with the EPEC T3SS outer membrane ring component, EscC, which was previously shown to be embedded within the outer membrane and protruding into the periplasmic space. Interestingly, we found that the predicted coiled-coil structure of Orf15 is critical for the protein's function. Overall, our findings suggest that Orf15 is a structural protein that contributes to the structural integrity of the T3S complex, and therefore we propose to rename it EscA.     

Improved system for construction and analysis of single-copy beta-galactosidase operon fusions in Yersinia enterocolitica

We report a significantly improved system for studying single-copy lacZ operon fusions in Yersinia enterocolitica: a simple procedure for the stable integration of lacZ operon fusions into the ara locus and a strain with a deletion mutation that abolishes the low level of endogenous beta-galactosidase activity.     

PerC and GrlA independently regulate Ler expression in enteropathogenic Escherichia coli

Ler, encoded by the locus of enterocyte effacement (LEE) of attaching and effacing (A/E) pathogens, induces the expression of LEE genes by counteracting the silencing exerted by H-NS. Ler expression is modulated by several global regulators, and is activated by GrlA, which is also LEE-encoded. Typical enteropathogenic Escherichia coli (EPEC) strains contain the EAF plasmid, which carries the perABC locus encoding PerC. The precise role of PerC in EPEC virulence gene regulation has remained unclear, mainly because EPEC strains lacking the pEAF still express the LEE genes and because PerC is not present in other A/E pathogens such as Citrobacter rodentium. Here, we describe that either PerC or GrlA can independently activate ler expression and, in consequence, of LEE genes depending on the growth conditions. Both PerC and GrlA, with the aid of IHF, counteract the repression exerted by H-NS on ler and can also further increase its activity. Our results substantiate the role of PerC and GrlA in EPEC virulence gene regulation and suggest that these convergent regulatory mechanisms may have represented an evolutionary adaptation in EPEC to co-ordinate the expression of plasmid- and chromosome-encoded virulence factors needed to successfully colonize its intestinal niche.     

Interaction of enteropathogenicEscherichia coli with host epithelial cells

EnteropathogenicEscherichia coli (EPEC) causes severe diarrhea in young children. Upon infection, EPEC induces the assembly of highly organized pedestal-like actin structures in host epithelial cells. All the EPEC genes that are involved in inducing formation of actin pedestals are located in a unique 35 kbp chromosomal pathogenicity island, termed LEE. These genes include thesep genes that encode components of type III protein secretion system, and genes that encode proteins secreted by this system, theesp genes. This protein secretion system is activated upon contact with the host cell, resulting in increased secretion of Esp proteins. Some of these Esp proteins form the translocation apparatus while others are translocated into the cytoplasm of the host cell. Concerted activity of the LEE genes including theeae, esp and thesep genes is needed to trigger signal transduction in the host cell which results in formation of an actin pedestal. Presented at the1st International Minisymposium on Cellular Microbiology: Cell Biology and Signalization in Host-Pathogen Interactions, Prague, October 6, 1997.     

trp repressor interactions with the trp aroH and trpR operators. Comparison of repressor binding in vitro and repression in vivo

Interaction of the Escherichia coli trp repressor with the promoter-operator regions of the trp, aroH and trpR operons was studied in vivo and in vitro. The three operators have similar, but non-identical, sequences; each operator is located in a different segment of its respective promoter. In vivo repression of the three operons was measured using single-copy gene fusions to lacZ. The extent of repression varied from 300-fold for the trp operon, to sixfold for the aroH operon and threefold for the trpR operon. To determine whether differential binding of repressor to the three operators was responsible for the differences in repression observed in vivo, three in vitro binding assays were employed. Restriction-site protection, gel retardation and DNase footprinting analyses revealed that repressor binds to the three operators with almost equal affinity. It was also shown in an in vivo competition assay that repressor binds approximately equally well to each of the three operators. It is proposed that the differential regulation observed in vivo may be due to the different relative locations of the three operators within their respective promoters.