@phdthesis{Spohn1999, author = {Spohn, Gunther}, title = {The transcriptional control of virulence gene expression in Helicobacter pylori}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-2334}, school = {Universit{\"a}t W{\"u}rzburg}, year = {1999}, abstract = {The Gram-negative, spiral-shaped, microaerophilic bacterium Helicobacter pylori is the causative agent of various disorders of the upper gastrointestinal tract, such as chronic superficial gastritis, chronic active gastritis, peptic ulceration and adenocarcinoma. Although many of the bacterial factors associated with disease development have been analysed in some detail in the recent years, very few studies have focused so far on the mechanisms that regulate expression of these factors at the molecular level. In an attempt to obtain an overview of the basic mechanisms of virulence gene expression in H. pylori, three important virulence factors of this pathogen, representative of different pathogenic mechanisms and different phases of the infectious process, are investigated in detail in the present thesis regarding their transcriptional regulation. As an essential factor for the early phase of infection, including the colonisation of the gastric mucosa, the flagella are analysed; the chaperones including the putative adhesion factors GroEL and DnaK are investigated as representatives of the phase of adherence to the gastric epithelium and persistence in the mucus layer; and finally the cytotoxin associated antigen CagA is analysed as representative of the cag pathogenicity island, which is supposed to account for the phenomena of chronic inflammation and tissue damage observed in the later phases of infection. RNA analyses and in vitro transcription demonstrate that a single promoter regulates expression of cagA, while two promoters are responsible for expression of the upstream divergently transcribed cagB gene. All three promoters are shown to be recognised by RNA polymerase containing the vegetative sigma factor sigma 80. Promoter deletion analyses establish that full activation of the cagA promoter requires sequences up to -70 and binding of the C-terminal portion of the alpha subunit of RNA polymerase to an UP-like element located between -40 and -60, while full activation of the major cagB promoter requires sequences upstream of -96 which overlap with the cagA promoter. These data suggest that the promoters of the pathogenicity island represent a class of minimum promoters, that ensure a basic level of transcription, while full activation requires regulatory elements or structural DNA binding proteins that provide a suitable DNA context. Regarding flagellar biosynthesis, a master transcriptional factor is identified that regulates expression of a series of flagellar basal body and hook genes in concert with the alternative sigma factor sigma 54. Evidence is provided that this regulator, designated FlgR (for flagellar regulatory protein), is necessary for motility and transcription of five promoters for seven basal body and hook genes. In addition, FlgR is shown to act as a repressor of transcription of the sigma 28-regulated promoter of the flaA gene, while changes in DNA topology are shown to affect transcription of the sigma 54-regulated flaB promoter. These data indicate that the regulatory network that governs flagellar gene expression in H. pylori shows similarities to the systems of both Salmonella spp. and Caulobacter crescentus. In contrast to the flagellar genes which are regulated by three different sigma factors, the three operons encoding the major chaperones of H. pylori are shown to be transcribed by RNA polymerase containing the vegetative sigma factor sigma 80. Expression of these operons is shown to be regulated negatively by the transcriptional repressor HspR, a homologue of a repressor protein of Streptomyces spp., known to be involved in negative regulation of heat shock genes. In vitro studies with purified recombinant HspR establish that the protein represses transcription by binding to large DNA regions centered around the transcription initiation site in the case of one promoter, and around -85 and -120 in the case of the the other two promoters. In contrast to the situation in Streptomyces, where transcription of HspR-regulated genes is induced in response to heat shock, transcription of the HspR-dependent genes in H. pylori is not inducible with thermal stimuli. Transcription of two of the three chaperone encoding operons is induced by osmotic shock, while transcription of the third operon, although HspR-dependent, is not affected by salt treatment. Taken together, the analyses carried out indicate that H. pylori has reduced its repertoire of specific regulatory proteins to a basic level that may ensure coordinate regulation of those factors that are necessary during the initial phase of infection including the passage through the gastric lumen and the colonisation of the gastric mucosa. The importance of DNA topology and/or context for transcription of many virulence gene promoters may on the other hand indicate, that a sophisticated global regulatory network is present in H. pylori, which influences transcription of specific subsets of virulence genes in response to changes in the microenvironment.}, subject = {Helicobacter-pylori-Infektion}, language = {en} } @phdthesis{Blaettner2016, author = {Bl{\"a}ttner, Sebastian}, title = {The role of the non-ribosomal peptide synthetase AusAB and its product phevalin in intracellular virulence of Staphylococcus aureus}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-146662}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2016}, abstract = {Staphylococcus aureus is a prevalent commensal bacterium which represents one of the leading causes in health care-associated bacterial infections worldwide and can cause a variety of different diseases ranging from simple abscesses to severe and life threatening infections including pneumonia, osteomyelitis and sepsis. In recent times multi-resistant strains have emerged, causing severe problems in nosocomial as well as community-acquired (CA) infection settings, especially in the United States (USA). Therefore S. aureus has been termed as a superbug by the WHO, underlining the severe health risk originating from it. Today, infections in the USA are dominated by S. aureus genotypes which are classified as USA300 and USA400, respectively. Strains of genotype USA300 are responsible for about 70\% of the CA infections. The molecular mechanisms which render S. aureus such an effective pathogen are still not understood in its entirety. For decades S. aureus was thought to be a strictly extracellular pathogen relying on pore-forming toxins like α-hemolysin to damage human cells and tissue. Only recently it has been shown that S. aureus can enter non-professional phagocytes, using adhesins like the fibronectin-binding proteins which mediate an endocytotic uptake into the host cells. The bacteria are consequently localized to endosomes, where the degradation of enclosed bacterial cells through phagosome maturation would eventually occur. S. aureus can avoid degradation, and translocate to the cellular cytoplasm, where it can replicate. The ability to cause this so-called phagosomal escape has mainly been attributed to a family of amphiphilic peptides called phenol soluble modulins (PSMs), but as studies have shown, they are not sufficient. In this work I used a transposon mutant library in combination with automated fluorescence microscopy to screen for genes involved in the phagosomal escape process and intracellular survival of S. aureus. I thereby identified a number of genes, including a non-ribosomal peptide synthetase (NRPS). The NRPS, encoded by the genes ausA and ausB, produces two types of small peptides, phevalin and tyrvalin. Mutations in the ausAB genes lead to a drastic decrease in phagosomal escape rates in epithelial cells, which were readily restored by genetic complementation in trans as well as by supplementation of synthetic phevalin. In leukocytes, phevalin interferes with calcium fluxes and activation of neutrophils and promotes cytotoxicity of intracellular bacteria in both, macrophages and neutrophils. Further ausAB is involved in survival and virulence of the bacterium during mouse lung pneumoniae. The here presented data demonstrates the contribution of the bacterial cyclic dipeptide phevalin to S. aureus virulence and suggests, that phevalin directly acts on a host cell target to promote cytotoxicity of intracellular bacteria.}, subject = {Staphylococcus aureus}, language = {en} } @phdthesis{Dunkel2013, author = {Dunkel, Nico}, title = {Regulation of virulence-associated traits of the human fungal pathogen Candida albicans by nitrogen availability}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-83076}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2013}, abstract = {Nitrogen-regulated pathogenesis describes the expression of virulence attributes as direct response to the quantity and quality of an available nitrogen source. As consequence of nitrogen availability, the opportunistic human fungal pathogen Candida albicans changes its morphology and secretes aspartic proteases [SAPs], both well characterized virulence attributes. C. albicans, contrarily to its normally non-pathogenic relative Saccharomyces cerevisiae, is able to utilize proteins, which are considered as abundant and important nitrogen source within the human host. To assimilate complex proteinaceous matter, extracellular proteolysis is followed by uptake of the degradation products through dedicated peptide transporters (di-/tripeptide transporters [PTRs] and oligopeptide transporters [OPTs]). The expression of both traits is transcriptionally controlled by Stp1 - the global regulator of protein utilization - in C. albicans. The aim of the present study was to elucidate the regulation of virulence attributes of the pathogenic fungus C. albicans by nitrogen availability in more detail. Within a genome wide binding profile of Stp1, during growth with proteins, more than 600 Stp1 target genes were identified, thereby confirming its role in the usage of proteins, but also other nitrogenous compounds as nitrogen source. Moreover, the revealed targets suggest an involvement of Stp1 in the general adaption to nutrient availability as well as in the environmental stress response. With the focus on protein utilization and nitrogen-regulated pathogenesis, the regulation of the major secreted aspartic protease Sap2 - additionally one of the prime examples of allelic heterogeneity in C. albicans - was investigated in detail. Thereby, the heterogezygous SAP2 promoter helped to identify an unintended genomic alteration as the true cause of a growth defect of a C. albicans mutant. Additionally, the promoter region, which was responsible for the differential activation of the SAP2 alleles, was delimited. Furthermore, general Sap2 induction was demonstrated to be mediated by distinct cis-acting elements that are required for a high or a low activity of SAP2 expression. For the utilization of proteins as nitrogen source it is also crucial to take up the peptides that are produced by extracellular proteolysis. Therefore, the function and importance of specific peptide transporters was investigated in C. albicans mutants, unable to use peptides as nitrogen source (opt1Δ/Δ opt2Δ/Δ opt3Δ/Δ opt4Δ/Δ opt5Δ/Δ ptr2Δ/Δ ptr22Δ/Δ septuple null mutants). The overexpression of individual transporters in these mutants revealed differential substrate specificities and expanded the specificity of the OPTs to dipeptides, a completely new facet of these transporters. The peptide-uptake deficient mutants were further used to elucidate, whether indeed proteins and peptides are an important in vivo nitrogen source for C. albicans. It was found that during competitive colonization of the mouse intestine these mutants exhibited wild-type fitness, indicating that neither proteins nor peptides are primary nitrogen sources required to efficiently support growth of C. albicans in the mouse gut. Adequate availability of the preferred nitrogen source ammonium represses the utilization of proteins and other alternative nitrogen sources, but also the expression of virulence attributes, like Sap secretion and nitrogen-starvation induced filamentation. In order to discriminate, whether ammonium availability is externally sensed or determined inside the cell by C. albicans, the response to exterior ammonium concentrations of ammonium-uptake deficient mutants (mep1Δ/Δ mep2Δ/Δ null mutants) was investigated. This study showed that presence of an otherwise suppressing ammonium concentration did not inhibit Sap2 proteases secretion and arginine-induced filamentation in these mutants. Conclusively, ammonium availability is primarily determined inside the cell in order to control the expression of virulence traits. In sum, the present work contributes to the current understanding of how C. albicans regulates expression of virulence-associated traits in response to the presence of available nitrogen sources - especially proteins and peptides - in order to adapt its lifestyle within a human host.}, subject = {Candida albicans}, language = {en} } @phdthesis{Raffelsbauer2001, author = {Raffelsbauer, Diana}, title = {Identification and characterization of the inlGHE gene cluster of Listeria monocytogenes}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-1180595}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2001}, abstract = {In the present study, a new gene cluster of Listeria monocytogenes EGD containing three internalin genes was identified and characterized. These genes, termed inlG, inlH and inlE, encode proteins of 490, 548 and 499 amino acids, respectively, which belong to the class of large, surface-bound internalins. Each of these proteins contains a signal peptide, two regions of repeats (Leucine-rich repeats and B repeats), an inter-repeat region and a putative cell wall anchor sequence containing the sorting motiv LPXTG. PCR analysis revealed the presence of the inlGHE gene cluster in most L. monocytogenes serotypes. A similar gene cluster termed inlC2DE localised to the same position on the chromosome was described in a different L. monocytogenes EGD isolate. Sequence comparison of the two clusters indicates that inlG is a new internalin gene, while inlH was generated by a site-specific recombination leading to an in-frame deletion which removed the 3'-terminal end of inlC2 and a 5'-portion of inlD. The genes inlG, inlH and inlE seem to be transcribed extracellularly and independent of PrfA. To study the function of the inlGHE gene cluster several in-frame deletion mutants were constructed which lack the genes of the inlGHE cluster individually or in combination with other inl genes. When tested in the mouse model, the inlGHE mutant showed a significant reduction of bacterial counts in liver and spleen in comparison to the wild type strain, indicating that the inlGHE gene cluster plays an important role in virulence of L. monocytogenes. The ability of this mutant to invade non-phagocytic cells in vitro was however two- to three-fold higher than that of the parental strain. To examine whether deletion of the single genes from the cluster has the same stimulatory effect on invasiveness as deletion of the complete gene cluster, the single in-frame deletion mutants inlG, inlH and inlE were constructed. These mutants were subsequently reverted to the wild type by introducing a copy of the corresponding intact gene into the chromosome by homologous recombination using knock-in plasmids. To determine a putative contribution of InlG, InlH and InlE in combination with other internalins to the entry of L. monocytogenes into mammalian cells, the combination mutants inlA/GHE, inlB/GHE, inlC/GHE, inlA/B/GHE, inlB/C/GHE, inlA/C and inlA/C/GHE were constructed. Transcription of the genes inlA, inlB and inlC in these mutants was studied by RT-PCR. Deletion of inlGHE enhances transcription of inlA and inlB, but not of inlC. This enhancement is not transient but can be observed at different time-points of the bacterial growth curve. Deletion of inlA also increases transcription of inlB and vice-versa. In contrast, the amounts of inlA and inlB transcripts in the single deletion mutants inlG, inlH and inlE were similar to those from the wild type.}, subject = {Listeria monocytogenes}, language = {en} } @phdthesis{Ng2001, author = {Ng, Eva Yee Wah}, title = {How did Listeria monocytogenes become pathogenic?}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-1752}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2001}, abstract = {Listeriae are Gram positive, facultative, saprophytic bacteria capable of causing opportunistic infections in humans and animals. This thesis presents three separate lines of inquiries that can lead to the eventual convergence of a global view of Listeria as pathogen in the light of evolution, genomics, and function. First, we undertook to resolve the phylogeny of the genus Listeria with the goal of ascertaining insights into the evolution of pathogenic capability of its members. The phylogeny of Listeriae had not yet been clearly resolved due to a scarcity of phylogenetically informative characters within the 16S and 23S rRNA molecules. The genus Listeria contains six species: L. monocytogenes, L. ivanovii, L. innocua, L. seeligeri, L. welshimeri, and L. grayi; of these, L. monocytogenes and L. ivanovii are pathogenic. Pathogenicity is enabled by a 10-15Kb virulence gene cluster found in L. seeligeri, L. monocytogenes and L. ivanovii. The genetic contents of the virulence gene cluster loci, as well as some virulence-associated internalin loci were compared among the six species. Phylogenetic analysis based on a data set of nucleic acid sequences from prs, ldh, vclA, vclB, iap, 16S and 23S rRNA genes identified L. grayi as the ancestral branch of the genus. This is consistent with previous 16S and 23S rRNA findings. The remainder 5 species formed two groupings. One lineage represents L. monocytogenes and L. innocua, while the other contains L. welshimeri, L. ivanovii and L. seeligeri, with L. welshimeri forming the deepest branch within this group. Deletion breakpoints of the virulence gene cluster within L. innocua and L. welshimeri support the proposed tree. This implies that the virulence gene cluster was present in the common ancestor of L. monocytogenes, L. innocua, L. ivanovii, L. seeligeri and L. welshimeri; and that pathogenic capability has been lost in two separate events represented by L. innocua and L. welshimeri. Second, we attempted to reconstitute L. innocua of its deleted virulence gene cluster, in its original chromosomal location, from the L. monocytogenes 12 Kb virulence gene cluster. This turned out particularly difficult because of the limits of genetic tools presently available for the organism. The reconstitution was partially successful. The methods and approaches are presented, and all the components necessary to complete the constructs are at hand for both L. innocua and the parallel, positive control of L. monocytogenes mutant deleted of its virulence gene cluster. Third, the sequencing of the entire genome of L. monocytogenes EGDe was undertaken as part of an EU Consortium. Our lab was responsible for 10 per cent of the labor intensive gap-closure and annotation efforts, which I helped coordinate. General information and comparisons with sister species L. innocua and a close Gram positive relative Bacillus subtilis are presented in context. The areas I personally investigated, namely, sigma factors and stationary phase functions, are also presented. L. monocytogenes and L. innocua both possess surprisingly few sigma factors: SigA, SigB, SigH, SigL, and an extra-cytoplasmic function type sigma factor (SigECF). The stationary phase genes of L. monocytogenes is compared to the well-studied, complex, stationary phase networks of B. subtilis. This showed that while genetic competence functions may be operative in unknown circumstances, non-sporulating Listeria opted for very different approaches of regulation from B. subtilis. There is virtually no overlap of known, stationary phase genes between Listeria and Gram negative model organism E. coli.}, subject = {Listeria monocytogenes}, language = {en} } @phdthesis{Luo2004, author = {Luo, Qin}, title = {Essential features of a PrfA-dependent : promoter of Listeria monocytogenes}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-10341}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2004}, abstract = {The gram-positive, facultative intracellular pathogen Listeria monocytogenes is the causal agent of listeriosis. Most of well-known virulence genes are controlled by PrfA that belongs to the Crp-Fnr family of transcriptional activators. A PrfA-mediated transcription initiating at a virulence gene promoter, inlC promoter (PinlC) that regulates the expression of the small, secreted internalin C, was in-depth characterized by an in vitro transcription system to unravel the essential features of a PrfA-dependent promoter in this study. The obtained results indicate a dual promoter for inlC that leads to PrfA-dependent and -independent transcription in vitro and in vivo. The PrfA-dependent transcription requires, as expected, the PrfA-box, a conserved 14 bp sequence of dyad symmetry located about 40 bp upstream of the transcriptional start site of each PrfA-regulated gene. Another important structural feature for this PrfA-dependent promoter is the distance between the 3´-end of the PrfA-box and the 5´-end of the SigA-recognized -10 box fixed to 22 or 23 bp, which is observed in the interspace regions of the other known PrfA-dependent promoters, e.g. PactA, PplcA, Phly and Pmpl. The -35 box of PinlC is not necessary for PrfA-dependent transcription. The -10 box of PinlC and also that of the other PrfA-dependent promoters of L. monocytogenes closely resemble SigA-recognized -10 promoter sequences of the well-characterized gram-positive bacterium B. subtilis. Even the extended -10 motif (5´-TRTG-3´) considered to be a basic element for many SigA-recognized promoters in B. subtilis is present in PinlC. Primer extension studies reveal that both the PrfA-dependent and the independent promoter share the same -10 box. The PrfA-independent transcription of inlC depends on a -35 box located directly downstream of the PrfA-box, and the close proximity of the two sites inhibits strongly the transcription activity of the PrfA-independent promoter when the PrfA-RNA polymerase complex binds to the PrfA-box. Deletion of the PrfA-box results in PrfA-independent transcription from PinlC, which is no longer inhibited by PrfA. High concentration of GTP appears to be necessary for PrfA-dependent transcription initiated at the inlC promoter and at other PrfA-dependent promoters. Based on transcriptome analysis, Milohanic and his co-workers identified three groups of genes that were regulated differently by PrfA. Some of these genes containing putative PrfA-boxes in their 5´-upstream regulatory regions were selected for analysis of their transcriptional dependency on PrfA using again the in vitro transcription system. The data show that among these "PrfA-regulated" promoters tested, only the promoter of the hpt gene belonging to group I is clearly activated by PrfA. This promoter is also the only one that exhibited all essential features of a typical PrfA-dependent promoter as described above. In vitro transcription starting at most of the other promoters was neither positively nor negatively affected by PrfA. Transcription initiated at some of the promoters of group III genes (lmo0596 and lmo2067) is rather inefficient with SigA-loaded RNA polymerase, but is highly activated with RNA polymerase loaded with purified SigB. Addition of purified PrfA protein has no effect on the SigB-dependent transcription. These in vitro transcription results indicate that the in vivo observed PrfA effect on the expression of most of the new genes is either indirect or PrfA-mediated transcription of these genes requires - in contrast to the PrfA-dependent transcription of the known virulence genes (including hpt) - additional factors not present in the in vitro transcription assay. In addition to these new genes described by Milohanic, the promoters of two genes (lmo2420 and lmo2840) that contain putative PrfA-boxes with only a single mismatch in their upstream regulatory regions were analyzed in this study. However, transcription of none of these genes is regulated by PrfA, suggesting that these genes are either not truly regulated by PrfA or regulated by other global transcription activators that interact with PrfA by yet unknown mechanisms. By exchanging corresponding sequences between a functionally inactive promoter ParoAP2 and a typical PrfA-dependent promoter PplcA, it is found that PrfA-dependent in vitro transcription can be initiated from the hybrid promoter containing the putative PrfA-box and the SigA-recognized -10 box (TTTAAT) from the putative PrfA-dependent aroAP2 promoter, but it is inhibited strongly by the interspace sequence between these two sites apparently due to an additional RNA polymerase binding site [the -10 box (TAATAT) for the PrfA-independent transcription of ParoAP1)] within this region. Furthermore, a symmetric sequence downstream of the -10 box (TTTAAT) is also shown to be a strongly inhibitory for PrfA-dependent transcription from the putative PrfA-dependent aroAP2 promoter.}, subject = {Listeria monocytogenes}, language = {en} } @phdthesis{Zude2014, author = {Zude, Ingmar}, title = {Characterization of virulence-associated traits of Escherichia coli bovine mastitis isolates}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-100934}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2014}, abstract = {Bacterial mastitis is caused by invasion of the udder, bacterial multiplication and induction of inflammatory responses in the bovine mammary gland. Disease severity and the cause of disease are influenced by environmental factors, the cow's immune response as well as bacterial traits. Escherichia coli (E. coli) is one of the main causes of acute bovine mastitis, but although pathogenic E. coli strains can be classified into different pathotypes, E. coli causing mastitis cannot unambiguously be distinguished from commensal E. coli nor has a common set of virulence factors been described for mastitis isolates. This project focussed on the characterization of virulence- associated traits of E. coli mastitis isolates in comprehensive analyses under conditions either mimicking initial pathogenesis or conditions that E. coli mastitis isolates should encounter while entering the udder. Virulence-associated traits as well as fitness traits of selected bovine mastitis or faecal E. coli strains were identified and analyzed in comparative phenotypic assays. Raw milk whey was introduced to test bacterial fitness in native mammary secretion known to confer antimicrobial effects. Accordingly, E. coli isolates from bovine faeces represented a heterogeneous group of which some isolates showed reduced ability to survive in milk whey whereas others phenotypically resembled mastitis isolates that represented a homogeneous group in that they showed similar survival and growth characteristics in milk whey. In contrast, mastitis isolates did not exhibit such a uniform phenotype when challenged with iron shortage, lactose as sole carbon source and lingual antimicrobial peptide (LAP) as a main defensin of milk. Reduced bacterial fitness could be related to LAP suggesting that bacterial adaptation to an intramammary lifestyle requires resistance to host defensins present in mammary secretions, at least LAP. E. coli strain 1303 and ECC-1470 lack particular virulence genes associated to mastitis isolates. To find out whether differences in gene expression may contribute to the ability of E. coli variants to cause mastitis, the transcriptome of E. coli model mastitis isolates 1303 and ECC-1470 were analyzed to identify candidate genes involved in bacterium-host interaction, fitness or even pathogenicity during bovine mastitis. DNA microarray analysis was employed to assess the transcriptional response of E. coli 1303 and ECC-1470 upon cocultivation with MAC-T immortalized bovine mammary gland epithelial cells to identify candidate genes involved in bacterium-host interaction. Additionally, the cell adhesion and invasion ability of E. coli strain 1303 and ECC-1470 was investigated. The transcriptonal response to the presence of host cells rather suggested competition for nutrients and oxygen between E. coli and MAC-T cells than marked signs of adhesion and invasion. Accordingly, mostly fitness traits that may also contribute to efficient colonization of the E. coli primary habitat, the gut, have been utilized by the mastitis isolates under these conditions. In this study, RNA-Seq was employed to assess the bacterial transcriptional response to milk whey. According to our transcriptome data, the lack of positively deregulated and also of true virulence-associated determinants in both of the mastitis isolates indicated that E. coli might have adapted by other means to the udder (or at least mammary secretion) as an inflammatory site. We identified traits that promote bacterial growth and survival in milk whey. The ability to utilize citrate promotes fitness and survival of E. coli that are thriving in mammary secretions. According to our results, lactoferrin has only weak impact on E. coli in mammary secretions. At the same time bacterial determinants involved in iron assimilation were negatively regulated, suggesting that, at least during the first hours, iron assimilation is not a challenge to E. coli colonizing the mammary gland. It has been hypothesized that cellular iron stores cause temporary independency to extracellular accessible iron. According to our transcriptome data, this hypothesis was supported and places iron uptake systems beyond the speculative importance that has been suggested before, at least during early phases of infection. It has also been shown that the ability to resist extracytoplasmic stress, by oxidative conditions as well as host defensins, is of substantial importance for bacterial survival in mammary secretions. In summary, the presented thesis addresses important aspects of host-pathogen interaction and bacterial conversion to hostile conditions during colonization of the mastitis inflammatory site, the mammary gland.}, subject = {Escherichia coli}, language = {en} } @phdthesis{Salvador2011, author = {Salvador, Ellaine Riciel P.}, title = {Characterization of Asymptomatic Bacteriuria (ABU) Escherichia coli Isolates: virulence traits and host-pathogen interactions}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-71283}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2011}, abstract = {Urinary tract infection (UTI) is one of the most serious health problems worldwide. It accounts for a million hospital visits annually in the United States. Among the many uropathogenic bacteria, uropathogenic Escherichia coli (UPEC) is the most common causative agent of UTI. However, not all E. coli that inhabit the urinary tract can cause UTI. Some of them thrive for long periods of time in the urinary bladder without causing overt symptoms of infection. This carrier state is called asymptomatic bacteriuria (ABU). E. coli ABU isolates can live in the host without inducing host response due to deletions, insertions and point mutations in the genome leading to the attenuation of virulence genes. They therefore behave in the same way as commensals. Since bacteria that inhabit the urinary tract are said to originate from the lower intestinal tract and ABU behave in a similar way as commensals, this study compared various phenotypic and genotypic characteristics of ABU and commensal E. coli fecal isolates. The two groups did not show a strict clustering with regards to phylogenetic lineage since there appears to be overlaps in their distribution in some clonal complexes. In addition, it was observed that the UPEC virulence genes were more frequently inactivated in ABU than in fecal isolates. Hence, ABU tend to have less functional virulence traits compared to the fecal isolates. The ABU model organism E. coli 83972 which is known not only for its commensal behavior in the urinary bladder but its ability to outcompete other bacteria in the urinary tract is currently being used as prophylactic treatment in patients who have recurrent episodes of UTI at the University Hospital in Lund, Sweden. The pilot studies showed that upon deliberate long-term colonization of the patients with E. coli 83972, they become protected from symptomatic UTI. In this study, the phenotypic and genotypic characteristics of eight re-isolates taken from initially asymptomatically colonized patients enrolled in the deliberate colonization study who reported an episode of symptoms during the colonization period were investigated. Two out of the eight re-isolates were proven to be a result of super infection by another uropathogen. Six re-isolates, on the other hand, were E. coli 83972. The urine re-isolates confirmed to be E. coli 83972 were phenotypically heterogeneous in that they varied in colony size as well as in swarming motility. Four of these re-isolates were morphologically homogenous and similar to the parent isolate E. coli 83972 whereas one of them appeared phenotypically heterogenous as a mixture of smaller and normal-sized colonies. Still another re-isolate phenotypically resembled small colony variants. Meanwhile, three of the six re-isolates did not differ from the parent isolate with regards to motility. On the other hand, three exhibited a markedly increased motility compared to the parent isolate. Transcriptome analysis demonstrated the upregulation of a cascade of genes involved in flagellar expression and biosynthesis in one of the three motile re-isolates. However, upon further investigation, it was found out that the expression of flagella had no effect on bacterial adhesion to host cells in vitro as well as to the induction of host inflammatory markers. Thus, this implies that the increased motility in the re-isolates is used by the bacteria as a fitness factor for its benefit and not as a virulence factor. In addition, among the various deregulated genes, it was observed that gene regulation tends to be host-specific in that there is no common pattern as to which genes are deregulated in the re-isolates. Taken together, results of this study therefore suggest that the use of E. coli 83972 for prophylactic treatment of symptomatic UTI remains to be very promising.}, subject = {Escherichia coli}, language = {en} } @phdthesis{Zdziarski2008, author = {Zdziarski, Jaroslaw Maciej}, title = {Bacterial Genome Plasticity and its Role for Adaptation and Evolution of Asymptomatic Bacteriuria (ABU) Escherichia coli Strains}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-32879}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2008}, abstract = {Asymptomatic bacteriuria (ABU) represents the long term bacterial colonization of the urinary tract, frequently caused by Escherichia coli (E. coli), without typical symptoms of a urinary tract infection (UTI). To investigate characteristics of ABU E. coli isolates in more detail, the geno- and phenotypes of eleven ABU isolates have been compared. Moreover, consecutive in vivo re-isolates of the model ABU strain 83972 were characterized with regard to transcriptomic, proteomic and genomic alterations upon long term in vivo persistence in the human bladder. Finally, the effect of the human host on bacterial adaptation/evolution was assessed by comparison of in vitro and in vivo-propagated strain 83972. ABU isolates represent a heterologous group of organisms. The comparative analysis of different ABU isolates elucidated the remarkable genetic and phenotypic flexibility of E. coli isolates. These isolates could be allocated to all four major E. coli phylogenetic lineages as well as to different clonal groups. Accordingly, they differed markedly in genome content, i.e., the genome size as well as the presence of typical UPEC virulence-associated genes. Multi locus sequence typing suggested that certain ABU strains evolved from UPEC variants that are able to cause symptomatic UTI by genome reduction. Consequently, the high E. coli genome plasticity does not allow a generalized view on geno- and phenotypes of individual isolates within a clone. Reductive evolution by point mutations, DNA rearrangements and deletions resulted in inactivation of genes coding for several UPEC virulence factors, thus supporting the idea that a reduced bacterial activation of host mucosal inflammation promotes the ABU lifestyle of these E. coli isolates. Gene regulation and genetic diversity are strategies which enable bacteria to live and survive under continuously changing environmental conditions. To study adaptational changes upon long term growth in the bladder, consecutive re-isolates of model ABU strain 83972 derived from a human colonisation study and from an in vitro long term cultivation experiment were analysed with regard to transcriptional changes and genome rearrangements. In this context, it could be demonstrated that E. coli, when exposed to different host backgrounds, is able to adapt its metabolic networks resulting in an individual bacterial colonisation strategy. Transcriptome and proteome analyses demonstrated distinct metabolic strategies of nutrients acquisition and energy production of tested in vivo re-isolates of strain 83972 that enabled them to colonise their host. Utilisation of D-serine, deoxy- and ribonucleosides, pentose and glucuronate interconversions were main up-regulated pathways providing in vivo re-isolates with extra energy for efficient growth in the urinary bladder. Moreover, this study explored bacterial response networks to host defence mechanisms: The class III alcohol dehydrogenase AdhC, already proven to be involved in nitric oxide detoxification in pathogens like Haemophilus influenzae, was shown for the first time to be employed in defending E. coli against the host response during asymptomatic bacteriuria. Consecutive in vivo and in vitro re-isolates of strain 83972 were also analysed regarding their genome structure. Several changes in the genome structure of consecutive re-isolates derived from the human colonisation study implied the importance of bacterial interactions with the host during bacterial microevolution. In contrast, the genome structure of re-isolates from the in vitro long term cultivation experiment, where strain 83972 has been propagated without host contact, was not affected. This suggests that exposure to the immune response promotes genome plasticity thus being a driving force for the development of the ABU lifestyle and evolution within the urinary tract.}, subject = {Escherichia coli}, language = {en} }