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Background
Increasing bacterial resistance to antibiotics is a serious problem worldwide. We sought to record the acquisition of antibiotic-resistant Escherichia coli (E. coli) in healthy infants in Northern Thailand and investigated potential determinants.
Methods
Stool samples from 142 infants after birth, at ages 2wk, 2mo, 4 to 6mo, and 1y, and parent stool samples were screened for E. coli resistance to tetracycline, ampicillin, co-trimoxazole, and cefazoline by culture, and isolates were further investigated for multiresistance by disc diffusion method. Pulsed-field gel electrophoresis was performed to identify persistent and transmitted strains. Genetic comparison of resistant and transmitted strains was done by multilocus sequence typing (MLST) and strains were further investigated for extra- and intra-intestinal virulence factors by multiplex PCR.
Results
Forty-seven (33%) neonatal meconium samples contained resistant E. coli. Prevalence increased continuously: After 1y, resistance proportion (tetracycline 80%, ampicillin 72%, co-trimoxazole 66%, cefazoline 35%) almost matched those in parents. In 8 infants (6%), identical E. coli strains were found in at least 3 sampling time points (suggesting persistence). Transmission of resistant E. coli from parents to child was observed in only 8 families. MLST showed high diversity. We could not identify any virulence genes or factors associated with persistence, or transmission of resistant E. coli. Full-term, vaginal birth and birth in rural hospital were identified as risk factors for early childhood colonization with resistant E. coli.
Conclusion
One third of healthy Thai neonates harboured antibiotic-resistant E. coli in meconium. The proportion of resistant E. coli increased during the first year of life almost reaching the value in adults. We hypothesize that enhancement of infection control measures and cautious use of antibiotics may help to control further increase of resistance.
The search for new antibiotics against multidrug-resistant (MDR), Gram-negative bacteria is crucial with respect to filling the antibiotics development pipeline, which is subject to a critical shortage of novel molecules. Screening of natural products is a promising approach for identifying antimicrobial compounds hosting a higher degree of novelty. Here, we report the isolation and characterization of four galloylglucoses active against different MDR strains of Escherichia coli and Klebsiella pneumoniae. A crude acetone extract was prepared from Paeonia officinalis Linnaeus leaves, and bioautography-guided isolation of active compounds from the extract was performed by liquid–liquid extraction, as well as open column, flash, and preparative chromatographic methods. Isolated active compounds were characterized and elucidated by a combination of spectroscopic and spectrometric techniques. In vitro antimicrobial susceptibility testing was carried out on E. coli and K. pneumoniae using 2 reference strains and 13 strains hosting a wide range of MDR phenotypes. Furthermore, in vivo antibacterial activities were assessed using Galleria mellonella larvae, and compounds 1,2,3,4,6-penta-O-galloyl-β-d-glucose, 3-O-digalloyl-1,2,4,6-tetra-O-galloyl-β-d-glucose, 6-O-digalloyl-1,2,3,4-tetra-O-galloyl-β-d-glucose, and 3,6-bis-O-digalloyl-1,2,4-tri-O-galloyl-β-d-glucose were isolated and characterized. They showed minimum inhibitory concentration (MIC) values in the range of 2–256 µg/mL across tested bacterial strains. These findings have added to the number of known galloylglucoses from P. officinalis and highlight their potential against MDR Gram-negative bacteria.
The reversibility of bacterial resistance to antibiotics is poorly understood. Therefore, the aim of this study was to determine, over a period of five years, the effect of fluoroquinolone (FQ) use in primary care on the development and gradual decay of Escherichia coli resistance to FQ. In this matched case–control study, we linked three sources of secondary data of the Health Service of the Autonomous Province of Bolzano, Italy. Cases were all those with an FQ-resistant E. coli (QREC)-positive culture from any site during a 2016 hospital stay. Data were analyzed using conditional logistic regression. A total of 409 cases were matched to 993 controls (FQ-sensitive E. coli) by the date of the first isolate. Patients taking one or more courses of FQ were at higher risk of QREC colonization/infection. The risk was highest during the first year after FQ was taken (OR 2.67, 95%CI 1.92–3.70, p < 0.0001), decreased during the second year (OR 1.54, 95%CI 1.09–2.17, p = 0.015) and became undetectable afterwards (OR 1.09, 95%CI 0.80–1.48, p = 0.997). In the first year, the risk of resistance was highest after greater cumulative exposure to FQs. Moreover, older age, male sex, longer hospital stays, chronic obstructive pulmonary disease (COPD) and diabetes mellitus were independent risk factors for QREC colonization/infection. A single FQ course significantly increases the risk of QREC colonization/infection for no less than two years. This risk is higher in cases of multiple courses, longer hospital stays, COPD and diabetes; in males; and in older patients. These findings may inform public campaigns and courses directed to prescribers to promote rational antibiotic use.
FinO-domain proteins represent an emerging family of RNA-binding proteins (RBPs) with diverse roles in bacterial post-transcriptional control and physiology. They exhibit an intriguing targeting spectrum, ranging from an assumed single RNA pair (FinP/traJ) for the plasmid-encoded FinO protein, to transcriptome-wide activity as documented for chromosomally encoded ProQ proteins. Thus, the shared FinO domain might bear an unusual plasticity enabling it to act either selectively or promiscuously on the same cellular RNA pool. One caveat to this model is that the full suite of in vivo targets of the assumedly highly selective FinO protein is unknown. Here, we have extensively profiled cellular transcripts associated with the virulence plasmid-encoded FinO in Salmonella enterica. While our analysis confirms the FinP sRNA of plasmid pSLT as the primary FinO target, we identify a second major ligand: the RepX sRNA of the unrelated antibiotic resistance plasmid pRSF1010. FinP and RepX are strikingly similar in length and structure, but not in primary sequence, and so may provide clues to understanding the high selectivity of FinO-RNA interactions. Moreover, we observe that the FinO RBP encoded on the Salmonella virulence plasmid controls the replication of a cohabitating antibiotic resistance plasmid, suggesting cross-regulation of plasmids on the RNA level.
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.
Two lineages of Salmonella enterica serovar Typhimurium (S. Typhimurium) of multi-locus sequence type ST313 have been linked with the emergence of invasive Salmonella disease across sub-Saharan Africa. The expansion of these lineages has a temporal association with the HIV pandemic and antibiotic usage. We analysed the whole genome sequence of 129 ST313 isolates representative of the two lineages and found evidence of lineage-specific genome degradation, with some similarities to that observed in S. Typhi. Individual ST313 S. Typhimurium isolates exhibit a distinct metabolic signature and modified enteropathogenesis in both a murine and cattle model of colitis, compared to S. Typhimurium outside of the ST313 lineages. These data define phenotypes that distinguish ST313 isolates from other S. Typhimurium and may represent adaptation to a distinct pathogenesis and lifestyle linked to an-immuno-compromised human population.
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.
E. coli Nissle 1917 (EcN) zählt durch seine fast hundertjährige Nutzung als Arzneimittel und aufgrund der weitreichenden Forschung während der letzten Jahrzehnte mittlerweile zu einem der am besten untersuchten Probiotika. EcN wird als Medikament zur Remissionserhaltung von Patienten mit Kolitis, bei chronischer Verstopfung und bei Durchfall von Kleinkindern eingesetzt.
Der enteroaggregative – hämorrhagische - E. coli (EAHEC) mit dem Serotyp O104:H4 war 2011 in Deutschland für den bisher größten EHEC-Ausbruch seit Beginn der Aufzeichnungen verantwortlich. Es fehlt bis zum heutigen Tage immer noch an effektiven Möglichkeiten einer Infektionsprophylaxe oder einer Behandlung der Erkrankung. Ein alternatives Therapeutikum wird daher dringend benötigt. In dieser Arbeit wurden die antagonistischen Effekte von EcN auf pathogene E. coli Stämme wie dem EHEC Stamm EDL933 oder klinischen EAHEC O104:H4 Isolaten untersucht. Es wurden die Auswirkungen von EcN auf die Adhäsion an humane Epithelzellen, das Wachstum und die Shiga Toxin Produktion der pathogenen Stämme untersucht. Zusätzlich wurde die Resistenz von EcN gegenüber Shiga Toxin Phagen nachgewiesen.
Zunächst wurde die Adhäsionseffizienz der verschiedenen E. coli Stämme bestimmt. Der am schlechtesten an die humanen Epithelzelllinien Caco-2 und LS-174T adhärierende Stamm war EcN. Dies ist insofern überraschend, da von Probiotika erwartet wird, besser als Pathogene an Epithelzellen zu adhärieren. Dem ungeachtet konnte jedoch gezeigt werden, dass EcN die Adhäsion von zwei EAHEC O104:H4 Isolaten, des nahe verwandten enteroaggregativen E. coli (EAEC) Stammes 55989 und des enterohämorrhagischen (EHEC) E. coli Stammes O157:H7 EDL933 an beide Zelllinen hemmt. Die von EcN produzierten Mikrozine M und H47 konnten hier für einen Teil des beobachteten anti-adhäsiven Effektes von EcN auf die pathogenen E. coli Stämme verantwortlich gemacht werden. Die Mikrozine wurden hier als einzige Substanz, die das Wachstum der pathogenen E. coli Stämme beeinflusst, identifiziert.
Einer der wichtigsten Virulenzfaktoren von EAHEC und EHEC Stämmen ist das Shiga Toxin. In dieser Arbeit konnte gezeigt werden, dass EcN die Shiga Toxin Produktion der am häufigsten auftretenden EHEC Stämme (´Big Five´: O157:H7, O26:H11, O103:H2, O111:H-, O145:H25) und der klinischen Isolate von EAHEC O104:H4 im Zellkulturmedium DMEM hemmt.
Auffällig war, dass die Stx1 Produktion von EHEC O103:H2 und O111:H- nicht nur von EcN, sondern auch von E. coli K-12 Stamm MG1655, gehemmt wurde, im Gegensatz zur EcN-spezifischen Blockierung der Stx2-Produktion in den Serotypen O104:H4, O26:H11, O145:H25. Die Reduktion der Stx-Produktion in EAHEC O104:H4 TY3730 und TY3456, sowie EHEC O26:H11 war zum Teil von der Mikrozinproduktion abhängig. Diese hatte jedoch keinen Einfluss auf die Stx-Produktion in EHEC O157:H7 EDL933 und EHEC O145:H25. Bei Verwendung von LB-Medium zeigte sich im Gegensatz zum DMEM-Medium keine Mikrozin-Abhängigkeit der Toxinproduktion bei den EAHEC Isolaten TY3730 und TY3456. Die Toxinproduktion von EHEC EDL933 wurde ebenfalls nicht durch die Deletion der Mikrozin-Gene in EcN beeinflusst. Studien der Toxinproduktion in SCEM-Medium zeigten ebenfalls eine EcN-Dosisabhängige Reduktion der Stx-Produktion in Co-Kultur. Um den Mechanismus der Hemmung der Stx-Produktion zu untersuchen, wurden Versuche mit der EcN-Mutante EcN::luxS durchgeführt. Diese Deletion des AI-2 ´Quorum sensing´ Moleküls in EcN hatte allerdings keinen Einfluss auf die Hemmung der Stx-Produktion. Der Einsatz von Acetat führte, im Gegensatz zu publizierten Ergebnissen, nicht zu einer Reduktion der Stx-Produktion. Auch eine Beeinflussung der Lyse der EHEC-Bakterien, oder der Verminderung der Sekretion von Shiga Toxin durch EcN, konnte widerlegt werden. Zur Untersuchung der Stx-Expression wurde ein Assay mit einem biolumineszenten C-P (Chromosom-Plasmid) Reporter System etabliert. Damit konnte die Shiga Toxin Expression im Stammhintergrund EHEC EDL933 in Echtzeit untersucht werden. Hier wurde wiederum eine Reduktion der Shiga Toxin Expression in Co-Kultur mit EcN erfolgreich nachgewiesen.
In weiteren Versuchen konnte gezeigt werden, dass EcN nicht nur die Shiga Toxin Produktion von nicht-induzierten EAHEC Bakterien, sondern auch in mit Mitomycin C induzierten Bakterien hemmt.
Als wichtiger Sicherheitsaspekt einer Behandlung mit EcN wurde die Resistenz von EcN gegenüber Shiga Toxin Phagen untersucht. Die Infektion der Bakterien wurde hierbei mit stx-spezifischer PCR, Phagen-Plaque-Assay, Stx-ELISA und K+-Efflux Assay untersucht. Es konnte durch diese verschiedenen Methoden erfolgreich gezeigt werden, dass EcN nicht durch Shiga Toxin Phagen infiziert wird. Als möglicher Resistenzmechanismus kommt hier eine Mutation vom Phagenrezeptor LamB in Frage, was jedoch noch bestätigt werden muss.
Zusammenfassend wurden in dieser Arbeit wichtige antagonistische Effekte von EcN auf pathogene E. coli Stämme untersucht, die als Grundlage von neuen und dringend benötigten Behandlungen von EHEC-Infektionen dienen können.
Die Forschungsergebnisse der letzten Jahre liefern immer mehr Hinweise darauf, dass eine klare Unterscheidung von Fitness- und Virulenzfaktoren in vielen Fällen, insbesondere bei extraintestinal pathogenen Escherichia coli, nicht möglich ist. So lässt sich auch bei Harnwegsinfektionen verursachenden E. coli den bakteriellen und teils stammspezifischen Faktoren oftmals nicht eindeutig eine typische Virulenz- oder Fitness-assoziierte Funktion zuordnen. Zudem werden in neueren Studien immer häufiger atypische uropathogene Isolate von E. coli beschrieben, die in ihrem „Virulenzrepertoire“ deutlich von typischen uropathogenen E. coli (UPEC) abweichen, da sie keine klassischen UPEC-Virulenzfaktoren aufweisen. In dieser Arbeit wurden daher Virulenzeigenschaften typischer als auch atypischer UPEC untersucht.
Der Effekt eines bestimmten bakteriellen Faktors auf den Wirtsorganismus wird teilweise indirekt durch sekundäre Modifikation bedingt. Dies offenbart sich beispielsweise am Autotransporterprotein AIDA-I, dessen Konformation durch posttranslationale Glykosylierung stabilisiert wird, wodurch es seine Funktionalität als Adhäsin erhält. Da bisherige Studien zum AIDA-I homologen Autotransporterprotein Antigen 43 (Ag43) auf der Analyse von künstlich glykosyliertem Protein basieren, lag ein Schwerpunkt dieser Arbeit auf der Untersuchung der natürlichen Glykosylierung von Ag43 in UPEC Stamm 536. Es zeigte sich, dass beide Ag43-Varianten von E. coli Stamm 536 natürlicherweise glykosyliert vorliegen, der Grad der Glykosylierung jedoch wesentlich geringer ausfällt als bei natürlich glykosyliertem AIDA-I. Inwieweit die natürliche Glykosylierung von Ag43 zu dessen Funktionalität beiträgt, kann erst durch die Identifizierung der für die Ag43-Glykosylierung verantwortlichen Glykosyltransferase geklärt werden.
Die in silico-Analyse des Genoms von UPEC Stamm 536 für potentielle Glykosyltransferasen von Ag43 lieferte neun Kandidatengene. Die Gene wurde teils im Wildtyp-Hintergrund, teils im rfaH-negativen Hintergrund von E. coli Stamm 536 deletiert und die Mutanten im Anschluss phänotypisch charakterisiert. Die Deletion der Kandidatengene waaF, waaG und waaQ, die für Glykosyltransferasen des LPS-Biosynthesesystems kodieren, führte zu den deutlichsten Unterschieden in Bezug auf Motilität, Curli/Zellulose-Produktion, Hämolyseaktivität und Expression von Typ 1 Fimbrien. Der Einfluss des „knock-out“ der Kandidatengene auf die Glykosylierung von Ag43 muss in weiterführenden Studien untersucht werden.
Zur Charakterisierung des uropathogenen Virulenzpotentials verschiedener E. coli Stämme in vivo hat sich in den letzten Jahren das murine Modell der aufsteigenden Harnwegsinfektion etabliert. Mit Hilfe dieses Modells wurden in der vorliegenden Arbeit sowohl spezifische Deletionsmutanten prototypischer UPEC als auch atypische E. coli Harnwegsisolate bezüglich ihrer Urovirulenz getestet und verglichen. Bei der Untersuchung der klassischen UPEC lag der Fokus auf der möglichen Urovirulenzmodulation durch die folgenden spezifischen Faktoren: dem Autotransporterprotein Ag43, dem „Response regulator“ UvrY, dem Polyketid Colibactin sowie dem Exopolysaccharid poly-β-1,6-N-Acetylglucosamin (PGA). Für Ag43 war bei der Etablierung einer Harnwegsinfektion keine eindeutige Funktion feststellbar. Es ist jedoch denkbar, dass Ag43 zur Langzeitpersistenz im Harnwegstrakt beitragen kann, was in weiteren Studien belegt werden sollte. Die Expression von UvrY in der natürlichen uvrY-Deletionsmutante UPEC Stamm 536 ließ keine Erhöhung des Urovirulenzpotentials im Mausmodell erkennen. In diesem Zusammenhang konnte allerdings gezeigt werden, dass die Expression des Genotoxins Colibactin in UPEC Stamm 536 dessen Virulenz signifikant herabsetzte. Die Untersuchungen zur Relevanz des Exopolysaccharids PGA belegen deutlich, dass PGA für die Langzeitpersistenz von E. coli im murinen Harnwegstrakt benötigt wird. Für die initiale Kolonisierung scheint PGA hingegen keine Bedeutung zu haben. Für atypische UPEC Isolate, die Charakteristika von STEC und EAEC zeigen und sich in ihrem Virulenzmuster deutlich von prototypischen UPEC unterscheiden, ließ sich im murinen Modell der aufsteigenden Harnwegsinfektion, verglichen mit dem UPEC Modellorganismus 536, ein ähnliches, teils sogar erhöhtes uropathogenes Virulenzpotential nachweisen.
Die Ergebnisse der Arbeit untermauern somit die heutige Vorstellung bezüglich der Entwicklung und Etablierung einer Harnwegsinfektion, dass verschiedene E. coli Stämme unterschiedliche (Kontroll-) Mechanismen entwickelt haben, um erfolgreich den Harnwegstrakt kolonisieren und eine Infektion auslösen zu können. Zudem weisen sie darauf hin, dass diese Fähigkeit nicht auf Isolate typischer phylogenetischer UPEC Entwicklungslinien beschränkt und auf das Vorhandensein charakteristischer UPEC Virulenzfaktoren angewiesen ist.
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.