Interaction of uropathogenic Escherichia coli with host uroepithelium

Investigation into the pathogenesis of Escherichia coli urinary tract infection has provided numerous insights into the mechanisms by which bacteria adhere, grow and persist in association with host tissue. Many molecular details concerning the interaction of these bacteria with their host have been elucidated, and the murine model of cystitis has generated a new paradigm by which acute and recurrent urinary tract infections may proceed. These advances could potentially result in the development of novel vaccines and therapies for this very costly disease.     

Overproduction of Escherichia coli integration host factor, a protein with nonidentical subunits.

Integration host factor (IHF) is a small, basic protein that is needed for efficient recombination of bacteriophage lambda, as well as for other host and viral functions. We have constructed strains in which the two subunits of IHF, encoded by the himA and hip genes of Escherichia coli, are expressed under the control of the lambda rho L promoter. Separate overexpression of himA and hip led to the production of unstable and insoluble peptides, respectively. In contrast, the overexpression of both genes conjointly led to the accumulation of large amounts of active IHF. Extracts of such cells provided the starting material for a rapid purification procedure that results in milligram quantities of apparently homogeneous IHF.     

Interaction of cinnamyl-tRNAPhe with Escherichia coli elongation factor Tu

The products of nitrous acid mediated-deamination of Phe-tRNAPhe from E. coli were analyzed and their capability to interact with elongation factor Tu from E. coli was investigated. Thin-layer chromatography as well as HPLC analysis revealed the existence of at least two deamination products, 3-phenyl-lactyl-tRNAPhe and cinnamyl-tRNAPhe. It could be shown that the aminoacyl-tRNA analogues were active in the formation of the ternary complex with EF-Tu X GTP, although with a lower efficiency than native Phe-tRNAPhe. For both modified acyl-tRNAs the dissociation constant was determined to be 3 X 10(-5) M.     

Interaction of Escherichia coli translation-initiation factor IF-1 with ribosomes

The interaction between Escherichia coli translation-initiation factor IF-1 and ribosomes was studied in binding experiments by Airfuge centrifugation. IF-1 binds to the 30S, but not to the 50S, ribosomal subunit and its binding is strongly stimulated by IF-3 and IF-2, either alone or in combination. From the dependence of the Kd of the 30S-subunit--IF-1 complex on ionic strength, it can be concluded that IF-1 binds primarily via an ionic interaction, most likely with the 16S rRNA, with the minimum number of ion pairs involved being 2.7-3.6. The 30S-subunit--IF-1 interaction is unaffected by temperature changes between 11 degrees C and 44 degrees C and is thus accompanied by a negligible enthalpy change. It is concluded that the interaction is an entropy-driven process triggered mainly by the release of counter ions from the RNA phosphates. Titration of 30S-subunit--IF-1 complexes with 50S subunits causes the ejection of the factor indicating that IF-1 is released from the ribosomes during the subunit association step which marks the transition from a 30S-initiation-complex to a 70S initiation complex.     

Interaction of Escherichia coli RNA polymerase with eukaryotic TATA-binding protein

Interaction with eukaryotic TATA-binding protein (TBP) was analyzed for natural Escherichia coli RNA polymerase or the recombinant holoenzyme, minimal enzyme, or its sigma subunit. Upon preincubation of full-sized RNA polymerase with TBP and further incubation with a constant amount of 32P-labeled phosphamide derivative of a TATA-containing oligodeoxyribonucleotide, the yield of the holoenzyme-oligonucleotide covalent complex decreased with increasing TBP concentration. This was considered as indirect evidence for complexing of RNA polymerase with TBP. In gel retardation assays, the holoenzyme, but neither minimal enzyme nor the sigma subunit, interacted with TPB, since the labeled probe formed complexes with both proteins in the reaction mixture combining TBP with the minimal enzyme or the sigma subunit. It was assumed that E. coli RNA polymerase is functionally similar to eukaryotic RNA polymerase II, and that the complete ensemble of all subunits is essential for the specific function of the holoenzyme.     

Stabilization of bacteriophage Mu repressor-operator complexes by the Escherichia coli integration host factor protein

All of the previously described effects of integration host factor (IHF) on bacteriophage Mu development have supported the view that IHF favours transposition-replication over the alternative state of lysogenic phage growth. In this report we show that, consistent with a model in which Mu repressor binding to its operators requires a particular topology of the operator DNA, IHF stimulates repressor binding to the O1 and O2 operators and enhances Mu repression. IHF would thus be one of the keys, besides supercoiling and the H-NS protein, that lock the operator region into the appropriate topological conformation for high-affinity binding not only of the phage transposase but also of the phage repressor.     

Enteropathogenic Escherichia coli effector EspF interacts with host protein Abcf2

Enteropathogenic Escherichia coli (EPEC) is a major causative agent of infant diarrhoea in developing countries. The EspF effector protein is injected from EPEC into host cells via a type III secretion system and is involved in the disruption of host intestinal barrier function. In addition, EspF is sorted to mitochondria and has a role in initiating the mitochondrial death pathway. To clarify the manner in which EspF affects host cells, we sought to identify eukaryotic EspF-binding proteins using affinity purification. Abcf2, a protein of unknown function and member of the ABC-transporter family, bound EspF in this assay. An interaction between EspF and Abcf2 was confirmed in a yeast two-hybrid system, by colocalization and by co-immunoprecipitation from EPEC-infected cells. Levels of Abcf2 were decreased in cells infected with EPEC in an EspF dose-dependent manner. Knock-down of Abcf2 expression by RNA interference increased EspF-induced caspase 9 and caspase 3 cleavage. In addition, Abcf2-knocked down cells showed increased caspase 3 cleavage upon treatment with the apoptosis inducing agent staurosporine. These results indicate that EspF induces or facilitates host cell death by targeting and interfering with the putative protective function of Abcf2.     

Purification of the Gin recombination protein of Escherichia coli phage Mu and its host factor

Inversion of the G-segment of Escherichia coli phage Mu was studied in vitro. The reaction requires the Gin recombination protein, which was purified to near homogeneity from overproducing cells. Upon purification the protein lost activity, which was restored by addition of an extract from uninfected E. coli cells. The stimulatory host factor is a small heat-stable protein and was purified from E. coli cells. Full recombination required both proteins, but Gin alone promoted some recombination by itself, particularly at high concentrations. Relaxation of negative supercoils and recombination of a substrate with two recombination sites in an inverted orientation both have the same specificity for Gin and the host factor. The Gin-associated topoisomerase activity appears tightly coupled to its recombination activity.     

Interaction of the recA protein of Escherichia coli with single-stranded DNA

The interaction of recA protein with single-stranded (ss) phi X174 DNA has been examined by means of a nuclease protection assay. The stoichiometry of protection was found to be 1 recA monomer/approximately 4 nucleotides of ssDNA both in the absence of a nucleotide cofactor and in the presence of ATP. In contrast, in the presence of adenosine 5'-O-(thiotriphosphate) (ATP gamma S) the stoichiometry was 1 recA monomer/approximately 8 nucleotides. No protection was seen with ADP. In the absence of a nucleotide cofactor, the binding of recA protein to ssDNA was quite stable as judged by equilibration with a challenge DNA (t1/2 approximately 30 min). Addition of ATP stimulated this transfer (t1/2 approximately 3 min) as did ADP (t1/2 approximately 0.2 min). ATP gamma S greatly reduced the rate of equilibration (t1/2 greater than 12 h). Direct visualization of recA X ssDNA complexes at subsaturating recA protein concentrations using electron microscopy revealed individual ssDNA molecules partially covered with recA protein which were converted to highly condensed networks upon addition of ATP gamma S. These results have led to a general model for the interaction of recA protein with ssDNA.     

Interaction of integration host factor from Escherichia coli with the integration region of the Haemophilus influenzae bacteriophage HP1.

The specific DNA-binding protein integration host factor (IHF) of Escherichia coli stimulates the site-specific recombination reaction between the attP site of bacteriophage HP1 and the attB site of its host, Haemophilus influenzae, in vitro and also appears to regulate the expression of HP1 integrase. IHF interacts specifically with DNA segments containing the att sites and the integrase regulatory region, as judged by IHF-dependent retardation of relevant DNA fragments during gel electrophoresis. The locations of the protein-binding sites were identified by DNase I protection experiments. Three sites in the HP1 attP region bound IHF, two binding sites were present in the vicinity of the attB region, and one region containing three partially overlapping sites was present in the HP1 integrase regulatory segment. The binding sites defined in these experiments all contained sequences which matched the consensus IHF binding sequences first identified in the lambda attP region. An activity which stimulated the HP1 site-specific integration reaction was found in extracts of H. influenzae, suggesting that an IHF-like protein is present in this organism.     

Interaction of methionine-specific tRNAs from Escherichia coli with immobilized elongation factor Tu

The interaction of three different Met-tRNAsMet from E. coli with bacterial elongation factor (EF) Tu X GTP was investigated by affinity chromatography. Met-tRNAfMet which lacks the base pair at the end of the acceptor stem binds only weakly to EF-Tu X GTP, while Met-tRNAmMet has a high affinity for the elongation factor. A modified Met-tRNAfMet which has a C1-G72 base pair binds much more strongly to immobilized EF-Tu X GTP than the native aminoacyl(aa)-tRNA with non-base-paired C1A72 at this position, demonstrating that the base pair including the first nucleotide in the tRNA is one of the essential structural requirements for the aa-tRNA X EF-Tu X GTP ternary complex formation.     

Interaction of the maltose-binding protein with membrane vesicles of Escherichia coli.

The interaction of the radioactively labeled purified maltose-binding protein of Escherichia coli with membrane vesicles was studied. The maltose-binding protein bound specifically to the vesicles, in the presence of maltose, on few sites. Under conditions in which a potential was imposed across the membrane, the specific binding was (i) increased, (ii) dependent on maltose, and (iii) abolished in a mutant defective in the tar gene product, one of the methyl-accepting chemotaxis proteins. At least 1,300 binding sites were present in the membrane fraction of logarithmically growing cells.     

Interaction of the RecA protein of Escherichia coli with single-stranded oligodeoxyribonucleotides.

The RecA protein of Escherichia coli performs a number of ATP-dependent, in vitro reactions and is a DNA-dependent ATPase. Small oligodeoxyribonucleotides were used as DNA cofactors in a kinetic analysis of the ATPase reaction. Polymers of deoxythymidilic acid as well as oligonucleotides of mixed base composition stimulated the RecA ATPase activity in a length-dependent fashion. Both the initial rate and the extent of the reaction were affected by chain length. Full activity was seen with chain lengths > or = 30 nt. Partial activity was seen with chain lengths of 15-30 nt. The lower activity of shorter oligonucleotides was not simply due to a reduced affinity for DNA, since effects of chain length on KmATP and the Hill coefficient for ATP hydrolysis were also observed. The results also suggested that single-stranded DNA secondary structure frequently affects the ATPase activity of RecA protein with oligodeoxyribonucleotides.     

Interaction of the Bacillus subtilis DnaA-like protein with the Escherichia coli DnaA protein.

Plasmids carrying the intact Bacillus subtilis dnaA-like gene and two reciprocal hybrids between the B. subtilis and Escherichia coli dnaA genes were constructed. None of the plasmids could transform wild-type E. coli cells unless the cells contained surplus E. coli DnaA protein (DnaAEc). A dnaA (Ts) strain integratively suppressed by the plasmid R1 origin could be transformed by plasmids carrying either the B. subtilis gene (dnaABs) or a hybrid gene containing the amino terminus of the E. coli gene and the carboxyl terminus of the B. subtilis gene (dnaAEc/Bs). In cells with surplus E. coli DnaA protein, expression of the E. coli dnaA gene was derepressed by the B. subtilis DnaA protein and by the hybrid DnaAEc/Bs protein, whereas it was strongly repressed by the reciprocal hybrid protein DnaABs/Ec. The plasmids carrying the different dnaA genes probably all interfere with initiation of chromosome replication in E. coli by decreasing the E. coli DnaA protein concentration to a limiting level. The DnaABs and the DnaAEc/Bs proteins effect this decrease possibly by forming inactive oligomeric proteins, while the DnaABs/Ec protein may decrease dnaAEc gene expression.     

Interaction between DNA and an Escherichia coli protein omega

An E. coli protein, designated ω, has been purified at least 1000-fold. Treatment of a eovalently closed DNA duplex containing negative superhelical turns with ω results in the loss of most of the superhelical turns. The loss of superhelical turns follows a gradual course rather than a one-hit mechanism. This reaction does not require a cofactor. No other change in the physical properties of the DNA could be detected. The DNA remains covalently closed. Its ultraviolet absorption spectrum, circular dichroism, buoyant density in CsCl, sedimentation properties in neutral media containing varying amounts of ethidium and in an alkaline medium, and its susceptibility toward Neurospora endonuclease, are not significantly different from an untreated DNA containing the same number of superhelical turns. Thus it appears that ω is capable of introducing a “swivel” reversibly into a DNA. A plausible mechanism is postulated.     

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.     

Trigger factor retards protein export in Escherichia coli

Trigger factor (TF) is a ribosome-associated protein that interacts with a wide variety of nascent polypeptides in Escherichia coli. Previous studies have indicated that TF cooperates with DnaK to facilitate protein folding, but the basis of this cooperation is unclear. In this study we monitored protein export in E. coli that lack or overproduce TF to obtain further insights into its function. Whereas inactivation of genes encoding most molecular chaperones (including dnaK) impairs protein export, inactivation of the TF gene accelerated protein export and suppressed the need for targeting factors to maintain the translocation competence of presecretory proteins. Furthermore, overproduction of TF (but not DnaK) markedly retarded protein export. Manipulation of TF levels produced similar effects on the export of a cytosolic enzyme fused to a signal peptide. The data strongly suggest that TF has a unique ability to sequester nascent polypeptides for a relatively prolonged period. Based on our results, we propose that TF and DnaK promote protein folding by distinct (but complementary) mechanisms.