Refine
Has Fulltext
- yes (13)
Is part of the Bibliography
- yes (13)
Year of publication
Document Type
- Doctoral Thesis (13) (remove)
Language
- English (13) (remove)
Keywords
- Escherichia coli (13) (remove)
Institute
Sonstige beteiligte Institutionen
Complex formation between macromolecules constitutes the foundation of most cellular processes. Most known complexes are made up of two or more proteins interacting in order to build a functional entity and therefore enabling activities which
the single proteins could otherwise not fulfill. With the increasing knowledge about
noncoding RNAs (ncRNAs) it has become evident that, similar to proteins, many of
them also need to form a complex to be functional. This functionalization is usually executed by specific or global RNA-binding proteins (RBPs) that are specialized
binders of a certain class of ncRNAs. For instance, the enterobacterial global RBPs
Hfq and ProQ together bind >80 % of the known small regulatory RNAs (sRNAs),
a class of ncRNAs involved in post-transcriptional regulation of gene expression.
However, identification of RNA-protein interactions so far was performed individually by employing low-throughput biochemical methods and thereby hindered the discovery of such interactions, especially in less studied organisms such
as Gram-positive bacteria. Using gradient profiling by sequencing (Grad-seq), the
present thesis aimed to establish high-throughput, global RNA/protein complexome resources for Escherichia coli and Streptococcus pneumoniae in order to provide a
new way to investigate RNA-protein as well as protein-protein interactions in these
two important model organisms.
In E. coli, Grad-seq revealed the sedimentation profiles of 4,095 (∼85 % of
total) transcripts and 2,145 (∼49 % of total) proteins and with that reproduced
its major ribonucleoprotein particles. Detailed analysis of the in-gradient distribution of the RNA and protein content uncovered two functionally unknown
molecules—the ncRNA RyeG and the small protein YggL—to be ribosomeassociated. Characterization of RyeG revealed it to encode for a 48 aa long, toxic protein that drastically increases lag times when overexpressed. YggL was shown to
be bound by the 50S subunit of the 70S ribosome, possibly indicating involvement
of YggL in ribosome biogenesis or translation of specific mRNAs.
S. pneumoniae Grad-seq detected 2,240 (∼88 % of total) transcripts and 1,301
(∼62 % of total) proteins, whose gradient migration patterns were successfully reconstructed, and thereby represents the first RNA/protein complexome resource
of a Gram-positive organism. The dataset readily verified many conserved major
complexes for the first time in S. pneumoniae and led to the discovery of a specific
interaction between the 3’!5’ exonuclease Cbf1 and the competence-regulating ciadependent sRNAs (csRNAs). Unexpectedly, trimming of the csRNAs by Cbf1 stabilized the former, thereby promoting their inhibitory function. cbf1 was further shown
to be part of the late competence genes and as such to act as a negative regulator of
competence.
High-throughput sequencing (HTS) has revolutionized bacterial genomics. Its unparalleled sensitivity has opened the door to analyzing bacterial evolution and population genomics, dispersion of mobile genetic elements (MGEs), and within-host adaptation of pathogens, such as Escherichia coli.
One of the defining characteristics of intestinal pathogenic E. coli (IPEC) pathotypes is a specific repertoire of virulence factors (VFs). Many of these IPEC VFs are used as typing markers in public health laboratories to monitor outbreaks and guide treatment options. Instead, extraintestinal pathogenic E. coli (ExPEC) isolates are genotypically diverse and harbor a varied set of VFs -- the majority of which also function as fitness factors (FFs) for gastrointestinal colonization.
The aim of this thesis was the genomic characterization of pathogenic and commensal E. coli with respect to their virulence- and antibiotic resistance-associated gene content as well as phylogenetic background. In order to conduct the comparative analyses, I created a database of E. coli VFs, ecoli_VF_collection, with a focus on ExPEC virulence-associated proteins (Leimbach, 2016b). Furthermore, I wrote a suite of scripts and pipelines, bac-genomics-scripts, that are useful for bacterial genomics (Leimbach, 2016a). This compilation includes tools for assembly and annotation as well as comparative genomics analyses, like multi-locus sequence typing (MLST), assignment of Clusters of Orthologous Groups (COG) categories, searching for protein homologs, detection of genomic regions of difference (RODs), and calculating pan-genome-wide association statistics.
Using these tools we were able to determine the prevalence of 18 autotransporters (ATs) in a large, phylogenetically heterogeneous strain panel and demonstrate that many AT proteins are not associated with E. coli pathotypes. According to multivariate analyses and statistics the distribution of AT variants is instead significantly dependent on phylogenetic lineages. As a consequence, ATs are not suitable to serve as pathotype markers (Zude et al., 2014).
During the German Shiga toxin-producing E. coli (STEC) outbreak in 2011, the largest to date, we were one of the teams capable of analyzing the genomic features of two isolates. Based on MLST and detection of orthologous proteins to known E. coli reference genomes the close phylogenetic relationship and overall genome similarity to enteroaggregative E. coli (EAEC) 55989 was revealed. In particular, we identified VFs of both STEC and EAEC pathotypes, most importantly the prophage-encoded Shiga toxin (Stx) and the pAA-type plasmid harboring aggregative adherence fimbriae. As a result, we could show that the epidemic was caused by an unusual hybrid pathotype of the O104:H4 serotype. Moreover, we detected the basis of the antibiotic multi-resistant phenotype on an extended-spectrum beta-lactamase (ESBL) plasmid through comparisons to reference plasmids. With this information we proposed an evolutionary horizontal gene transfer (HGT) model for the possible emergence of the pathogen (Brzuszkiewicz et al., 2011).
Similarly to ExPEC, E. coli isolates of bovine mastitis are genotypically and phenotypically highly diverse and many studies struggled to determine a positive association of putative VFs. Instead the general E. coli pathogen-associated molecular pattern (PAMP), lipopolysaccharide (LPS), is implicated as a deciding factor for intramammary inflammation. Nevertheless, a mammary pathogenic E. coli (MPEC) pathotype was proposed presumably encompassing strains more adapted to elicit bovine mastitis with virulence traits differentiating them from commensals.
We sequenced eight E. coli isolates from udder serous exudate and six fecal commensals (Leimbach et al., 2016). Two mastitis isolate genomes were closed to a finished-grade quality (Leimbach et al., 2015). The genomic sequence of mastitis-associated E. coli (MAEC) strain 1303 was used to elucidate the biosynthesis gene cluster of its O70 LPS O-antigen. We analyzed the phylogenetic genealogy of our strain panel plus eleven bovine-associated E. coli reference strains and found that commensal or MAEC could not be unambiguously allocated to specific phylogroups within a core genome tree of reference E. coli. A thorough gene content analysis could not identify functional convergence of either commensal or MAEC, instead both have only very few gene families enriched in either pathotype. Most importantly, gene content and ecoli_VF_collection analyses showed that no virulence determinants are significantly associated with MAEC in comparison to bovine fecal commensals, disproving the MPEC hypothesis. The genetic repertoire of bovine-associated E. coli, again, is dominated by phylogenetic background. This is also mostly the case for large virulence-associated E. coli gene cluster previously associated with mastitis. Correspondingly, MAEC are facultative and opportunistic pathogens recruited from the bovine commensal gastrointestinal microbiota (Leimbach et al., 2017). Thus, E. coli mastitis should be prevented rather than treated, as antibiotics and vaccines have not proven effective.
Although traditional E. coli pathotypes serve a purpose for diagnostics and treatment, it is clear that the current typing system is an oversimplification of E. coli's genomic plasticity. Whole genome sequencing (WGS) revealed many nuances of pathogenic E. coli, including emerging hybrid or heteropathogenic pathotypes. Diagnostic and public health microbiology need to embrace the future by implementing HTS techniques to target patient care and infection control more efficiently.
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.
The probiotic Escherichia coli strain Nissle 1917 (EcN) is one of the few probiotics licensed as a medication in several countries. Best documented is its effectiveness in keeping patients suffering from ulcerative colitis (UC) in remission. This might be due to its ability to induce the production of human beta defensin 2 (HBD2) in a flagellin-dependent way in intestinal epithelial cells. In contrast to ulcerative colitis, for Crohn´s disease (CD) convincing evidence is lacking that EcN might be clinically effective, most likely due to the genetically based inability of sufficient defensin production in CD patients. As a first step in the development of an alternative approach for the treatment of CD patients, EcN strains were constructed which were able to produce human alpha-defensin 5 (HD5) or beta-defensin 2 (HBD2). For that purpose codon-optimized defensin genes encoding either the proform with the signal sequence or the mature form of human alpha defensin 5 (HD5) or the gene encoding HBD2 with or without the signal sequence were cloned in an expression vector plasmid under the control of the T7 promoter. Synthesis of the encoded defensins was shown by Western blots after induction of expression and lysis of the recombinant EcN strains. Recombinant mature HBD2 with an N-terminal His-tag could be purified by Ni-column chromatography and showed antimicrobial activity against E. coli, Salmonella enterica serovar Typhimurium and Listeria monocytogenes. In a second approach, that part of the HBD2-gene which encodes mature HBD2 was fused with yebF gene. The resulting fusion protein YebFMHBD2 was secreted from the encoding EcN mutant strain after induction of expression. Presence of YebFMHBD2 in the medium was not the result of leakage from the bacterial cells, as demonstrated in the spent culture supernatant by Western blots specific for ß-galactosidase and maltose-binding protein. The dialyzed and concentrated culture supernatant inhibited the growth of E. coli, Salmonella enterica serovar Typhimurium and Listeria monocytogenes in radial diffusion assays as well as in liquid coculture. This demonstrates EcN to be a suitable probiotic E. coli strain for the production of certain defensins.
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.
Avian pathogenic Escherichia coli (APEC) represent a subset of the so-called extraintestinal pathogenic Escherichia coli (ExPEC) pathotype that can cause various extraintestinal infections in humans and animals. APEC are the causative agent of localized colibacillosis or systemic infection in poultry. In this latter case, the syndrome starts as an infection of the upper respiratory tract and develops into a systemic infection. Generally, ExPEC are characterized by a broad variety of virulence-associated factors that may contribute to pathogenesis. Major virulence factors, however, that clearly define this pathotype, have not been identified. Instead, virulence-associated genes of ExPEC and thus also of APEC could be used in a mix-and-match-fashion. Both pathotypes could not be clearly distinguished by molecular epidemiology, and this suggested a hypothetical zoonotic risk caused by APEC. Accordingly, the main scientific question of this study was to characterize common traits as well as differences of APEC and human ExPEC variants that could either support the possible zoonotic risk posed by these pathogenic E. coli strains or indicate factors involved in host specificity. Comparative genomic analysis of selected APEC and human ExPEC isolates of the same serotype indicated that these variants could not be clearly distinguished on the basis of (i) general phenotypes, (ii) phylogeny, (iii) the presence of typical ExPEC virulence genes, and (iv) the presence of pathoadaptive mutations. Allelic variations in genes coding for adhesins such as MatB and CsgA or their regulators MatA and CsgD have been observed, but further studies are required to analyze their impact on pathogenicity. On this background, the second part of this thesis focused on the analysis of differences between human ExPEC and APEC isolates at the gene expression level. The analysis of gene expression of APEC and human ExPEC under growth conditions that mimick their hosts should answer the question whether these bacterial variants may express factors required for their host-specificity. The transcriptomes of APEC strain BEN374 and human ExPEC isolate IHE3034 were compared to decipher whether there was a specific or common behavior of APEC and human ExPEC, in response to the different body temperatures of man (37°C) or poultry (41°C). Only a few genes were induced at 41 °C in each strain relative to growth at 37 °C. The group of down-regulated genes in both strains was markedly bigger and mainly included motility and chemotaxis genes. The results obtained from the transcriptome, genomic as well as phenotypic comparison of human ExPEC and APEC, supports the idea of a potential zoonotic risk of APEC and certain human ExPEC variants. In the third part of the thesis, the focus was set on the characterization of Mat fimbriae, and their potential role during ExPEC infection. Comparison of the mat gene cluster in K-12 strain MG1655 and O18:K1 isolate IHE3034 led to the discovery of differences in (i) DNA sequence, (ii) the presence of transcriptional start and transcription factor binding sites as well as (iii) the structure of the matA upstream region that account for the different regulation of Mat fimbriae expression in these strains. A negative role of the H-NS protein on Mat fimbriae expression was also proven at 20 °C and 37 °C by real-time PCR. A major role of this fimbrial adhesin was demonstrated for biofilm formation, but a significant role of Mat fimbriae for APEC in vivo virulence could not yet be determined. Interestingly, the absence of either a functional matA gene or that of the structural genes matBCDEF independently resulted in upregulation of motility in E. coli strains MG1655 and IHE3034 by a so far unknown mechanism. In conclusion, the results of this thesis indicate a considerable overlap between human and animal ExPEC strains in terms of genome content and phenotypes. It becomes more and more apparent that the presence of a common set of virulence-associated genes among ExPEC strains as well as similar virulence gene expression patterns and phylogenetic backgrounds indicate a significant zoonotic risk of avian-derived E. coli isolates. In addition, new virulence factors identified in human ExPEC may also play a role in the pathogenesis of avian ExPEC.
Cysteines play important roles in the biochemistry of many proteins. The high reactivity, redox properties, and ability of the free thiol group to coordinate metal ions designate cysteines as the amino acids of choice to form key catalytic components of many enzymes. Also, cysteines readily react with reactive oxygen and nitrogen species to form reversible oxidative thiol modifications. Over the last few years, an increasing number of proteins have been identified that use redox-mediated thiol modifications to modulate their function, activity, or localization. These redox-regulated proteins are central players in numerous important cellular processes. First aim of this study was to discover nitric oxide (NO) sensitive proteins in E. coli, whose redox-mediated functional changes might explain the physiological alterations observed in E. coli cells suffering from NO-stress. To identify E. coli proteins that undergo reversible thiol modifications upon NO-treatment in vivo, I applied a differential thiol trapping technique combined with two-dimensional gel analysis. 10 proteins were found to contain thiol groups sensitive to NO-treatment. Subsequent genetic studies revealed that the oxidative modifications of AceF & IlvC are, in part, responsible for the observed NO-induced growth inhibition. Noteworthy, the majority of identified protein targets turned out to be specifically sensitive towards reactive nitrogen species. This oxidant specificity was tested on one NO-sensitive protein, the small subunit of glutamate synthase. In vivo and in vitro activity studies demonstrated that glutamate synthase rapidly inactivates upon nitric oxide treatment but is resistant towards other oxidative stressors. These results imply that reactive oxygen and nitrogen species affect distinct physiological processes in bacteria. The second aim of my study was to identify redox-sensitive proteins in S. cerevisiae and to use their redox state as in vivo read-out to assess the role of oxidative stress during the eukaryotic aging process. I first determined the precise in vivo thiol status of almost 300 yeast proteins located in the cytosol and sub-cellular compartments of yeast cells using a highly quantitative mass spectrometry based thiol trapping technique, called OxICAT. The identified proteins can be clustered in four groups: 1) proteins, whose cysteine residues are oxidation resistant; 2) proteins with structurally or functionally important cysteine modifications 3) proteins with highly oxidation-sensitive active site cysteines, which are partially oxidized in exponentially growing yeast cells due to their exquisite sensitivity towards low amounts of ROS; 4) proteins that are reduced in exponentially growing cells but harbor redox-sensitive cysteine(s) that affect the catalytic function of the protein during oxidative stress. These oxidative stress sensitive proteins were identified by exposure of yeast cells to sublethal concentrations of H2O2 or superoxide. It was shown that the major targets of peroxide- and superoxide-mediated stress in the cell are proteins involved in translation, glycolysis, TCA cycle and amino acid biosynthesis. These targets indicate that cells rapidly redirect the metabolic flux and energy towards the pentose phosphate pathway in an attempt to ensure the production of the reducing equivalent NADPH to counterattack oxidative stress. These results reveal that the quantitative assessment of a protein’s oxidation state is a valuable tool to identify catalytically active and redox-sensitive cysteine residues. The OxICAT technology was then used to precisely determine extent and onset of oxidative stress in chronologically aging S. cerevisiae cells by utilizing the redox status of proteins as physiological read-out. I found that chronological aging yeast cells undergo a global collapse of the cellular redox homeostasis, which precedes cell death. The onset of this collapse appears to correlate with the yeast life span, as caloric restriction increases the life span and delays the redox collapse. These results suggest that maintenance of the redox balance might contribute to the life expanding benefits of regulating the caloric intake of yeast. Clustering analysis of all oxidatively modified proteins in chronological aging yeast revealed a subset of proteins whose oxidative thiol modifications significantly precede the general redox collapse. Oxidation of these early target proteins, which most likely results in a loss of their activity, might contribute to or even cause the observed loss of redox homeostasis (i.e., thioredoxin reductase) in chronologically aging yeast. These studies in aging yeast expand our understanding how changes in redox homeostasis affect the life span of yeast cells and confirm the importance of oxidative thiol modifications as key posttranslational modifications in pro- and eukaryotic organisms.
Asymptomatische Bakteriurie (ABU) stellt eine bakterielle Infektion der Harnblase über einen langen Zeitraum dar, die häufig von Escherichia coli hervorgerufen wird, ohne dass typische Symptome einer Harnwegsinfektion auftreten. Um die Charakteristika von ABU E. coli Isolaten genauer zu untersuchen, wurden die Geno- und Phänotypen von 11 ABU-Isolaten verglichen. Außerdem wurden in mehreren aufeinanderfolgenden in vivo-Reisolaten des Modell-ABU Stammes 83972 die Veränderungen im Transkriptom, Proteom und Genom während einer langfristigen Persistenz in der menschlichen Blase charakterisiert. Schließlich wurde der Effekt des menschlichen Wirtes auf die bakterielle Adaptation durch einen Vergleich von in vitro- mit in vivo-kultivierten Stämmen abgeschätzt. ABU-Isolate stellt eine heterogene Gruppe von Organismen dar. Diese können den vier phylogenetischen Hauptgruppen von E. coli sowie unterschiedlichen klonalen Gruppen zugeordnet werden. Dementsprechend unterscheiden sie sich erheblich bezüglich der Zusammensetzung des Genomes, der Genomgröße und auch der Ausstattung mit UPEC-typischen Virulenz-assoziierten Genen. Multi-Lokus-Sequenz-Typisierung legt nahe, dass bestimmte ABU Stämme sich durch Genomreduktion aus UPEC Stämmen entwickelt haben, die eine Harnwegsinfektion mit charakteristischen Symptomen auslösen konnten. Folglich erlaubt die hohe Genomplastizität von E. coli keine generalisierte Betrachtung einzelner Isolate eines Klons. Genomreduktion über Punktmutationen, Genom-Reorganisation und Deletionen resultierte in der Inaktivierung einiger Gene, die für einige UPEC Virulenz-Faktoren kodieren. Dies stützt die Vorstellung, dass eine verminderte bakterielle Aktivierung der Entzündung der Wirtsschleimhaut den Lebensstil von ABU (bei diesen E. coli-)Isolaten fördert. Genregulation und genetische Diversität sind Strategien, die es Bakterien ermöglichen unter sich fortlaufend ändernden Bedingungen zu leben bzw. zu überleben. Um die anpassungsbedingten Veränderungen bei einem langfristigen Wachstum in der Blase zu untersuchen, wurden aufeinanderfolgende Reisolate, denen eine langfristige in vivo-Kolonisierung im menschlichen Wirt beziehungsweise eine in vitro-Kultivierung vorausgegangen ist, im Hinblick auf Veränderungen Genexpression und Genomorganisation analysiert. In diesem Zusammenhang konnte gezeigt werden, dass E. coli in der Lage ist, seine metabolischen Netzwerke verschiedenen Wachstumsbedingungen anzupassen und individuelle bakterielle Kolonisierungsstrategien entwickeln kann. Transkriptom- und Proteom-Analysen zeigten verschiedene metabolische Strategien zur Nährstoffbeschaffung und Energieproduktion bei untersuchten in vivo-Reisolaten vom Stamm 83972, die es ihnen ermöglichen, den Wirt zu kolonisieren. Das Zurückgreifen auf D-Serin, Deoxy- und Ribonucleoside sowie die bidirektionale Umwandlung zwischen Pentose und Glucuronat waren hoch-regulierte Stoffwechselwege, die die in vivo-Reisolate mit zusätzlicher Energie für ein effizientes Wachstum in der Blase versorgen. Zudem wurden in dieser Studie die Netzwerke für eine Reaktion auf Abwehrmechanismen des Wirtes erforscht: Erstmals wurde hier die Rolle der Klasse-III-Alkoholdehydrogenase AdhC, bekannt durch ihre Bedeutung bei der Entgiftung von Stickstoffmonoxid, bei der Wirtsantwort während einer asymptomatischen Bakteriurie gezeigt. Aufeinanderfolgende in vivo- und in vitro-Reisolate vom Stamm 83972 wurden ebenfalls bezüglich ihrer Genomstruktur analysiert. Einige Veränderungen in der Genomstruktur der aufeinanderfolgenden Reisolate, die von einer humanen Kolonisierungsstudie stammen, implizieren die Bedeutung einer Interaktion der Bakterien mit dem Wirt bei der Mikroevolution der Bakterien. Dagegen war die Genomstruktur von Reisolaten eines langfristigen in vitro-Kultivierungsexperiments, bei dem sich der Stamm 83972 ohne Wirtskontakt vermehrt hat, nicht von Veränderungen betroffen. Das legt nahe, dass die Immunantwort eine Genomplastizität fördert und somit eine treibende Kraft für den ABU Lebensstil und die Evolution im Harnwegstrakt ist.
In this study pore forming proteins of the gram-negative bacteria B. burgdorferi, B. duttonii and E.coli were investigated. Therefore the study is subdivided into three parts. In the first part outer membrane preparation of three relapsing fever Borrelia were investigated. In the second part the putative TolC homologue BB0124 of B. burgdorferi, the Lyme borreliosis agent, was studied. In the last part the influence of point mutants within the greasy slide of the maltose specific porin (LamB) of E. coli were shown. In the first part of this study outer membrane preparations of three Borrelia relapsing fever strains have been studied for pore-forming activity in the black lipid bilayer assay. Histograms of conductance fluctuations were obtained from single-channel experiments with outer membrane preparations of B. hermsii, B. recurentis and B. duttonii. All strains had a different conductance fluctuation pattern with a broad range of single-channel conductance values varying from 0.5 nS – 11 nS. Common for all three strains was a high pore-forming activity at around 0.5 nS. Furthermore the proteins of the outer membrane of B. duttonii were separated by chromatographic methods. Some eluate fractions contained a channel-forming protein, which was forming stable channels with a single-channel conductance of 80 pS in 1 M KCl. Characterization of this channel showed that it is slightly anionic selective and voltage independent. The small single-channel conductance suggests that it is a specific pore. However, a substrate specificity could not be determined. In the second part, for the B. burgdorferi HB19 and p66 knock out strain HB19/K02, their outer membrane preparations were characterized in the black lipid bilayer assay. Comparing the histograms of single-channel conductions fluctuations of both strains showed no single-channel activity at 11.5 nS for the p66 knock out strain. This verifies earlier studies that P66 is a pore-forming protein in B. burgdorferi. Furthermore, one fraction obtained by anion exchange chromatography of the p66 knock out outer membrane protein preparation showed a uniform channel-forming activity with a single channel conductance of 300 pS. The electrophysically characterization of the 300 pS channel showed that it is not ionselective or voltage dependent. By mass spectrometry using peptide mass finger prints, BB0142 could be identified as the sole channel forming candidate in the active fraction. A BLAST search and a conserved domain search showed that BB0142 is a putative TolC homologue in B. burgdorferi. Furthermore the location of the bb0142 gene within the chromosome is in an operon encoding a multidrug efflux pump. In this study the expression of an outer membrane component of a putative drug efflux system of B. burgdorferi was shown for the first time. In the third part functional studies of the maltooligosaccharide-specific LamB channel were performed. The 3D-structure of LamB suggests that a number of aromatic residues (Y6, Y41, W74, F229, W358 and W420) within the channel lumen is involved in carbohydrate and ion transport. All aromatic residues were replaced by alanine (A) scanning mutagenesis. Furthermore, LamB mutants were created in which one, two, three, four and five aromatic residues were replaced to study their effects on ion and maltopentaose transport through LamB. The purified mutant proteins were reconstituted into lipid bilayer membranes and the single-channel conductance was studied. The results suggest that all aromatic residues provide some steric hindrance for ion transport through LamB. Highest impact is provided by Y6 and Y41, which are localized opposite to Y118, which forms the central constriction of the LamB channel. Stability constants for binding of maltopentaose to the mutant channels were measured using titration experiments with the carbohydrate. The mutation of one or several aromatic amino acids led to a substantial decrease of the stability constant of binding. The highest effect was observed when all aromatic amino acids were replaced by alanine because no binding of maltopentaose could be detected in this case. However, binding was again possible when Y118 was replaced by tryptophane (W). The carbohydrate-induced block of the channel function could also be used for the study of current noise through the different mutant LamB-channels. The analysis of the power density spectra of some of the mutants allowed the evaluation of the on- and off-rate constants (k1 and k-1) of carbohydrate binding to the binding-site inside the channels. The results suggest that both on- and off-rate constants were affected by the mutations. For most mutants k1 decreased and k-1 increased.
Study of Omp85 Family Proteins YaeT and YtfM and Multidrug Export Machineries in Escherichia coli
(2006)
In this study the Omp85 family proteins YaeT and YtfM of Escherichia coli were investigated by using biochemical and electrophysiological methods as well as bioinformatical and structural analysis. In addition, knock-out strains were constructed to further study the relevance of these proteins in vivo. The prediction that Omp85 proteins are composed of two domains, a periplasmic amino-terminal POTRA (polypeptide translocation associated) domain and a carboxy-terminal domain anchoring these proteins in the outer membrane, was confirmed by the construction of mutants. It could be shown that the carboxy-terminal part of the proteins is able to insert into the outer bacterial membrane, even if the POTRA domain is removed. Furthermore, pore-forming activity in the black-lipid bilayer was observed for both full-length proteins as well as their carboxy-terminal membrane located parts. The channels formed by both proteins in the black lipid bilayer showed variable single channel conductance states rather than a defined value for conductance. In 1M KCl, e.g. YaeT forms pores with a channel conductance of 100 to 600 pS containing a most abundant value at 400 pS. This variability is at least reasonable for YaeT due to a prerequisite flexibility of its channel for OMP insertion. YaeT was identified to form a cation selective, YtfM an anion selective channel, which is less pH dependent than YaeT. Another feature of the YaeT channel is that its selectivity and conductance is influenced by charged detergent molecules indicating an accumulation of these molecules in hydrophobic pockets inside the compact channel. YaeT revealed heat-modifiable mobility in SDS-PAGE which is characteristic for β-barrel OMPs, whereas YtfM did not show this behaviour. This result could be explained by sequence alignment and structural comparison of YaeT and YtfM via CD and FTIR spectra displaying much higher β-strand content for the carboxy-terminal part of YaeT compared to YtfM. Since the carboxy-terminal parts were shown to have pore forming ability and are inserted in the OM in vivo, the substitution of the essential protein YaeT by its carboxy-terminal mutant was attempted in a yaeT knock-out strain. The carboxy-terminal half of YaeT was not sufficient to compensate depletion of the full-length protein indicating an important role of the amino-terminus for cell viability. In contrary, YtfM is shown to be a non-essential protein and lack of YtfM had no effects on the composition and integrity of the OM. However, chromosomal deletion of ytfM remarkably reduced the growth rate of cells. This study provides the first detailed investigation of the structure of YaeT and describes its electrophysiological behaviour, which could be a basis for further studies of YaeT and its substrate proteins. Furthermore, YtfM was characterised and its in vivo function was investigated revealing YtfM as the second Omp85 family protein of importance in E. coli. In a second part of this study assembly and function of multidrug efflux pumps were investigated. Drug efflux pumps are tripartite export machineries in the cell envelope of Gram-negative bacteria conferring multidrug resistance and therefore causing severe problems for medical treatment of diseases. Protein structures of all three efflux pump components are solved, but the exact interaction sites are still unknown. Assembly of a hybrid exporter system composed of the Pseudomonas aeruginosa channel tunnel OprM, the E. coli adaptor protein AcrA and its associated transporter AcrB could be shown by chemical cross-linking, even though this efflux pump is not functional. Exchange of the hairpin domain of AcrA by the corresponding hairpin from the adaptor protein MexA of P. aeruginosa restored functionality tested by antibiotic sensitivity assays. This shows the importance of the MexA hairpin domain for functional interaction with the OprM channel tunnel. Interestingly, the hybrid protein was also able to assemble with TolC as outer membrane component to form a functional efflux pump indicating a higher flexibility of TolC compared to OprM concerning interaction partners. Based on these results, an interaction model of the hairpin domain and the channel tunnel on molecular level for AcrA and TolC as well as MexA and OprM, respectively, is presented. This model provides a basis for directed mutagenesis to reveal the exact contact sites of the hairpin of the adapter protein and the outer membrane component