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Coagulase-negative staphylococci, particularly Staphylococcus epidermidis, have been recognised as an important cause of health care-associated infections due to catheterisation, and livestock-associated infections. The colonisation of indwelling medical devices is achieved by the formation of biofilms, which are large cell-clusters surrounded by an extracellular matrix. This extracellular matrix consists mainly of PIA (polysaccharide intercellular adhesin), which is encoded by the icaADBC-operon. The importance of icaADBC in clinical strains provoking severe infections initiated numerous investigations of this operon and its regulation within the last two decades. The discovery of a long transcript being located next to icaADBC, downstream of the regulator gene icaR, led to the hypothesis of a possible involvement of this transcript in the regulation of biofilm formation (Eckart, 2006). Goal of this work was to characterise this transcript, named ncRNA IcaZ, in molecular detail and to uncover its functional role in S. epidermidis.
The ~400 nt long IcaZ is specific for ica-positive S. epidermidis and is transcribed in early- and mid-exponential growth phase as primary transcript. The promotor sequence and the first nucleotides of icaZ overlap with the 3' UTR of the preceding icaR gene, whereas the terminator sequence is shared by tRNAThr-4, being located convergently to icaZ. Deletion of icaZ resulted in a macroscopic biofilm-negative phenotype with highly diminished PIA-biofilm. Biofilm composition was analysed in vitro by classical crystal violet assays and in vivo by confocal laser scanning microscopy under flow conditions to display biofilm formation in real-time. The mutant showed clear defects in initial adherence and decreased cell-cell adherence, and was therefore not able to form a proper biofilm under flow in contrast to the wildtype. Restoration of PIA upon providing icaZ complementation from plasmids revealed inconsistent results in the various mutant backgrounds.
To uncover the functional role of IcaZ, transcriptomic and proteomic analysis was carried out, providing some hints on candidate targets, but the varying biofilm phenotypes of wildtype and icaZ mutants made it difficult to identify direct IcaZ mRNA targets. Pulse expression of icaZ was then used as direct fishing method and computational target predictions were executed with candidate mRNAs from aforesaid approaches. The combined data of these analyses suggested an involvement of icaR in IcaZ-mediated biofilm control. Therefore, RNA binding assays were established for IcaZ and icaR mRNA. A positive gel shift was maintained with icaR 3' UTR and with 5'/3' icaR mRNA fusion product, whereas no gel shift was obtained with icaA mRNA. From these assays, it was assumed that IcaZ regulates icaR mRNA expression in S. epidermidis. S. aureus instead lacks ncRNA IcaZ and its icaR mRNA was shown to undergo autoregulation under so far unknown circumstances by intra- or intermolecular binding of 5' UTR and 3' UTR (Ruiz de los Mozos et al., 2013). Here, the Shine-Dalgarno sequence is blocked through 5'/3' UTR base pairing and RNase III, an endoribonuclease, degrades icaR mRNA, leading to translational blockade. In this work, icaR mRNA autoregulation was therefore analysed experimentally in S. epidermidis and results showed that this specific autoregulation does not take place in this organism. An involvement of RNase III in the degradation process could not be verified here. GFP-reporter plasmids were generated to visualise the interaction, but have to be improved for further investigations.
In conclusion, IcaZ was found to interact with icaR mRNA, thereby conceivably interfering with translation initiation of repressor IcaR, and thus to promote PIA synthesis and biofilm formation. In addition, the environmental factor ethanol was found to induce icaZ expression, while only weak or no effects were obtained with NaCl and glucose. Ethanol, actually is an ingredient of disinfectants in hospital settings and known as efficient effector for biofilm induction. As biofilm formation on medical devices is a critical factor hampering treatment of S. epidermidis infections in clinical care, the results of this thesis do not only contribute to better understanding of the complex network of biofilm regulation in staphylococci, but may also have practical relevance in the future.
Staphylococcus aureus is a versatile human pathogen that normally develops acute or chronic infections. The broad range of diseases caused by this bacterium facilitates the escape from the host's immune response as well as from target-specific antimicrobial therapies. Nevertheless, the underlying cellular and molecular mechanisms that enable S. aureus to cause these disparate types of infections are largely unknown. In this work, we depicted a novel genetic program involved in the development of cell-fate decision, which promotes the differentiation of the staphylococcal cells into two genetically identical but differently heritable cell lines capable of defining the course of an infection, by simultaneously progressing to (i) a biofilm-associated chronic infection or (ii) a disperse acute bacteremia. Here, S. aureus growing in architecturally complex multicellular communities harbored different cell types that followed an exclusive developmental plan, resulting in a clonal heterogeneous population. We found that these cell types are physiologically specialized and that, this specialization impacts the collective behavior within the multicellular aggregates. Whereas one cell line that we named BRcells, promotes biofilm formation that engenders chronic infections, the second cell line, which we termed DRcells is planktonic and synthetizes virulence factors, such as toxins that can drive acute bacteremia. We identified that the positive feedback loop present in Agr quorum sensing system of S. aureus acts a bimodal switch able to antagonistically control the divergence of these two physiologically distinct, heritable cell lines. Also, we found that this bimodal switch was triggered in response to environmental signals particularly extracellular Mg2+, affecting the size of the subpopulations in specific colonization environments. Specifically, Mg2+-enriched environments enhanced the binding of this cation to the staphylococcal teichoic acids, increasing the rigidity of the cell wall and triggering a genetic program involving the alternative sigma factor σB that downregulated the Agr bimodal switch, favoring the enrichment of the BRcells type. Therefore, colonization environments with different Mg2+ content favored different outcomes in the bimodal system, defining distinct ratio in the BRcells/DRcells subpopulations and the S. aureus outcome in our in vitro model of development of multicellular aggregates and, the infection outcome in an in vivo mice infection model. In this prime human pathogen cell-fate decision-making generates a conserved pattern of heritable, physiological heterogeneity that actively contributes to determine the course of an infection through the emergence and spatio-temporal dynamics of distinct and specialized cell types. In conclusion, this work demonstrates that cell differentiation in pathogenic bacteria is a fundamental phenomenon and its understanding, is central to understand nosocomial infections and to designing new anti-infective strategies
Staphylococcus aureus asymptomatically colonises one third of the healthy human population, finding its niche in the nose and on skin. Apart from being a commensal, it is also an important opportunistic human pathogen capable of destructing tissue, invading host cells and killing them from within. This eventually contributes to severe hospital- and community-acquired infections. Methicillin-resistant Staphylococcus aureus (MRSA), resistant to commonly used antibiotics are protected when residing within the host cell.
This doctoral thesis is focused on the investigation of staphylococcal factors governing intracellular virulence and subsequent host cell death. To initiate an unbiased approach to conduct this study, complex S. aureus mutant pools were generated using transposon insertional mutagenesis. Genome-wide infection screens were performed using these S. aureus transposon mutant pools in vitro and in vivo, followed by analysis using Transposon insertion site deep sequencing (Tn-seq) technology.
Amongst several other factors, this study identified a novel regulatory system in S. aureus that controls pathogen-induced host cytotoxicity and intra-host survival. The primary components of this system are an AraC-family transcription regulator called Repressor of surface proteins (Rsp) and a virulence associated non-coding RNA, SSR42. Mutants within rsp exhibit enhanced intra-host survival in human epithelial cells and delayed host cytotoxicity. Global gene-expression profiling by RNA-seq demonstrated that Rsp controls the expression of SSR42, several cytotoxins and other bacterial factors directed against the host immune system. Rsp enhances S. aureus toxin response when triggered by hydrogen peroxide, an antimicrobial substance employed by neutrophils to destroy pathogens. Absence of rsp reduces S. aureus-induced neutrophil damage and early lethality during mouse pneumonia, but still permits blood stream infection. Intriguingly, S. aureus lacking rsp exhibited enhanced survival in human macrophages, which hints towards a Trojan horse-like phenomenon and could facilitate dissemination within the host.
Hence, Rsp emerged as a global regulator of bacterial virulence, which has an impact on disease progression with prolonged intra-cellular survival, delayed-lethality but allows disseminated manifestation of disease. Moreover, this study exemplifies the use of genome-wide approaches as useful resources for identifying bacterial factors and deduction of its pathogenesis.
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.
Neisseria gonorrhoeae is a human-specific pathogen that causes gonorrhea. It is defined as a super bacterium by the WHO due to the emergence of gonococci that are resistant to a variety of antibiotics and a rapidly increasing infection incidence. Genome-wide investigation of neisserial gene essentiality and novel virulence factors is urgently required in order to identify new targets for anti-neisserial therapeutics. To identify essential genes and new virulence factors, a high-density mutant library in N. gonorrhoeae MS11 was generated by in vitro transposon mutagenesis. The transposon library harbors more than 100,000 individual mutants, a density that is unprecedented in gonococcal research. Essential genes in N. gonorrhoeae were determined by enumerating frequencies of transposon insertion sites (TIS) with Illumina deep sequencing (Tn-seq). Tn-seq indicated an average distance between adjacent TIS of 25 bp. Statistical analysis unequivocally demonstrated 781 genes that were significantly depleted in TIS and thus are essential for Neisseria survival. A subset of the genes was experimentally verified to comprise essential genes and thus support the outcome of the study. The hereby identified candidate essential genes thus may constitute excellent targets for the development of new antibiotics or vaccines.
In a second study, the transposon mutant library was applied in a genome-scale “negative-selection strategy” to identify genes that are involved in low phosphate-dependent invasion (LPDI). LPDI is dependent on the Neisseria porin subtype PorBIA which acts as an epithelial cell invasin in absence of phosphate and is associated with severe pathogenicity in disseminated gonococcal infections (DGI). Tn-seq demonstrated 98 genes, which were involved in adherence to host cells and 43 genes involved in host cell invasion. E.g. the hypothetical protein NGFG_00506, an ABC transporter ATP-binding protein NGFG_01643, as well as NGFG_04218 encoding a homolog of mafI in N. gonorrhoeae FA1090 were experimentally verified as new invasive factors in LPDI. NGFG_01605, a predicted protease, was identified to be a common factor involved in PorBIA, Opa50 and Opa57-mediated neisserial engulfment by the epithelial cells. Thus, this first systematic Tn-seq application in N. gonorrhoeae identified a set of previously unknown N. gonorrhoeae invasive factors which demonstrate molecular mechanisms of DGI.
Staphylococcus aureus is a Gram-positive commensal bacterium, that asymptomatically colonizes human skin and mucosal surfaces. Upon opportune conditions, such as immunodeficiency or breached barriers of the host, it can cause a plethora of infections ranging from local, superficial infections to life-threatening diseases. Despite being regarded as an extracellular pathogen, S. aureus can invade and survive within non-phagocytic and phagocytic cells. Eventually, the pathogen escapes from the host cell resulting in killing of the host cell, which is associated with tissue destruction and spread of infection. However, the exact molecular mechanisms underlying S. aureus-induced host cell death remain to be elucidated.
In the present work, a genome-wide haploid genetic screen was performed to identify host cell genes crucial for S. aureus intracellular cytotoxicity. A mutant library of the haploid cell line HAP1 was infected with the pathogen and cells surviving the infection were selected. Twelve genes were identified, which were significantly enriched when compared to an infection with a non-cytotoxic S. aureus strain.
Additionally, characteristics of regulated cell death pathways and the role of Ca2+ signaling in S. aureus-infected cells were investigated. Live cell imaging of Ca2+ reporter cell lines was used to analyze single cells. S. aureus-induced host cell death exhibited morphological features of apoptosis and activation of caspases was detected. Cellular H2O2 levels were elevated during S. aureus intracellular infection. Further, intracellular S. aureus provoked cytosolic Ca2+ overload in epithelial cells. This resulted from Ca2+ release from endoplasmic reticulum and Ca2+ influx via the plasma membrane and led to mitochondrial Ca2+ overload. The final step of S. aureus-induced cell death was plasma membrane permeabilization, a typical feature of necrotic cell death.
In order to identify bacterial virulence factors implicated in S. aureus-induced host cell killing, the cytotoxicity of selected mutants was investigated. Intracellular S. aureus employs the bacterial cysteine protease staphopain A to activate an apoptosis-like cell death characterized by cell contraction and membrane bleb formation. Phagosomal escape represents a prerequisite staphopain A-induced cell death, whereas bacterial intracellular replication is dispensable. Moreover, staphopain A contributed to efficient colonization of the lung in a murine pneumonia model.
In conclusion, this work identified at least two independent cell death pathways activated by intracellular S. aureus. While initially staphopain A mediates S. aureus-induced host cell killing, cytosolic Ca2+-overload follows later and leads to the final demise of the host cell.
Identification of human host cell factors involved in \(Staphylococcus\) \(aureus\) 6850 infection
(2015)
Staphylococcus aureus is both a human commensal and a pathogen. 20%-30% of all individuals are permanently or occasionally carriers of S. aureus without any symptoms. In contrast to this, S. aureus can cause life-threatening diseases e.g. endocarditis, osteomyelitis or sepsis. Here, the increase in antibiotic resistances makes it more and more difficult to treat these infections and hence the number of fatalities rises constantly. Since the pharmaceutical industry has no fundamentally new antibiotics in their pipeline, it is essential to better understand the interplay between S. aureus and the human host cell in order to find new, innovative treatment options.
In this study, a RNA interference based whole genome pool screen was performed to identify human proteins, which play a role during S. aureus infections. Since 1,600 invasion and 2,271 cell death linked factors were enriched at least 2 fold, the big challenge was to filter out the important ones. Here, a STRING pathway analysis proved to be the best option. Subsequently, the identified hits were validated with the help of inhibitors and a second, individualised small interfering RNA-based screen.
In the course of this work two important steps were identified, that are critical for host cell death: the first is bacterial invasion, the second phagosomal escape. The second step is obligatory for intracellular bacterial replication and subsequent host cell death. Invasion in turn is determining for all following events. Accordingly, the effect of the identified factors towards these two crucial steps was determined. Under screening conditions, escape was indirectly measured via intracellular replication. Three inhibitors (JNKII, Methyl-beta-cyclodeytrin, 9-Phenantrol) could be identified for the invasion process. In addition, siRNAs targeted against 16 different genes (including CAPN2, CAPN4 and PIK3CG), could significantly reduce bacterial invasion. Seven siRNAs (FPR2, CAPN4, JUN, LYN, HRAS, AKT1, ITGAM) were able to inhibit intracellular replication significantly. Further studies showed that the IP3 receptor inhibitor 2-APB, the calpain inhibitor calpeptin and the proteasome inhibitor MG-132 are able to prevent phagosomal escape and as a consequence intracellular replication and host cell death.
In this context the role of calpains, calcium, the proteasome and the mitochondrial membrane potential was further investigated in cell culture. Here, an antagonistic behaviour of calpain 1 and 2 during bacterial invasion was observed. Intracellular calcium signalling plays a major role, since its inhibition protects host cells from death. Beside this, the loss of mitochondrial membrane potential is characteristic for S. aureus infection but not responsible for host cell death. The reduction of membrane potential can be significantly diminished by the inhibition of the mitochondrial Na+/Ca2+ exchanger.
All together, this work shows that human host cells massively contribute to different steps in S. aureus infection rather than being simply killed by bacterial pore-forming toxins. Various individual host cell factors were identified, which contribute either to invasion or to phagosomal escape and therefore to S. aureus induced cytotoxicity. Finally, several inhibitors of S. aureus infection were identified. One of them, 2-APB, was already tested in a sepsis mouse model and reduced bacterial load of kidneys.
Thus, this study shows valuable evidence for novel treatment options against S. aureus infections, based on the manipulation of host cell signalling cascades.
Staphylococcus aureus ist ein grampositives Bakterium, welches häufig als kommensaler Besiedler auf der Nasen- und Rachenschleimhaut von Säugetieren vorkommt. Darüber hinaus besitzt dieser fakultativ pathogene Mikroorganismus die Fähigkeit schwer zu behandelnde Krankenhausinfektionen auszulösen. Aufgrund der weiten Verbreitung von Antibiotikaresistenzen und dem Mangel an effektiven Therapien, verursachen S. aureus Infektionen jährlich enorme Kosten für das Gesundheitssystem. S. aureus wird meist von der Nase zum primären Infektionsort übertragen, wodurch zunächst sehr häufig Wund- und Weichteilinfektionen hervor gerufen werden. Von diesem primären Infektionsort ausgehend, kann der Erreger tiefer liegende Gewebsschichten infizieren oder sich über den Blutstrom im gesamten Organismus ausbreiten. Das Spektrum an Krankheitsbildern reicht von leichten Abszessen der Haut bis zu schweren, lebensbedrohlichen Erkrankungen wie Pneumonien und akuter Sepsis.
Für die erfolgreiche Kolonisierung und Infektion des Wirtes exprimiert S. aureus eine Vielzahl unterschiedlicher Virulenzfaktoren. Die wohl größte Gruppe an Virulenzfaktoren umfasst die Proteine, die an der Immunevasion und der Umgehung von verschiedenen Abwehrstrategien des Immunsystems beteiligt sind. Das bisherige Wissen über die Interaktion von S. aureus mit dem Immunsystem des Wirtes und die zugrunde liegenden Pathogenitätsmechanismen ist bisher limitiert.
Um neue Erkenntnisse über die Interaktion von Wirt und Pathogen zu erlangen, wurden im Rahmen dieser Arbeit bislang unbekannte sekretierte und Oberflächen-assoziierte Proteine von S. aureus funktionell charakterisiert. Die Funktion der ausgewählten Proteine wurde in vitro hinsichtlich Einfluss auf Komponenten des Immunsystems, Adhäsion an Wirtsfaktoren und Invasion in eukaryotische Zellen untersucht.
Mit Hilfe der vorangegangenen in-vitro-Charakterisierung der putativen Virulenzfaktoren, konnte für die cytoplasmatische Adenylosuccinat-Synthase PurA eine neuartige Funktion identifiziert werden. PurA ist bekannt als essentielles Enzym der de novo Purin-Synthese. In dieser Arbeit wurde nun gezeigt, dass PurA zudem an der Immunevasion beteiligt ist. Durch die Bindung des humanen Faktor H des Komplementsystems schützt PurA S. aureus vor der lytischen Aktivität des Komplementsystems und verhindert die Opsonisierung des Pathogens. Basierend auf diesen Ergebnissen wurde PurA detailliert charakterisiert. In Bindungsstudien mit rekombinantem Faktor H und PurA wurde eine direkte Interaktion beider Proteine nachgewiesen, wobei Faktor H mit dem N-terminalen Bereich von PurA interagiert. Weiterhin konnte PurA durch Immunfluoreszenz und FACS-Analysen auf der Zelloberfläche nachgewiesen werden, wo es wahrscheinlich mit der Zellwand assoziiert vorliegt. Dort rekrutiert es Faktor H an die bakterielle Oberfläche und verhindert das Fortschreiten der Komplement-Kaskade und damit die Lyse des Pathogens. Aufgrund der Multifunktionalität zählt PurA somit zur Gruppe der Moonlighting Proteine.
Des Weiteren wurde die Rolle von PurA im Infektionsgeschehen in zwei unabhängigen Tiermodellen untersucht. In beiden Modellen wurde ein signifikant reduziertes Virulenzpotential der ΔpurA-Mutante beobachtet. Zukünftig soll geklärt werden, ob die verminderte Virulenz in der fehlenden Komplementevasion oder im Defekt in der Purin-Synthese begründet ist. Aufgrund der sehr starken Attenuation in allen untersuchten Infektionsmodellen sollte PurA als potentielles Target für eine Therapie von S. aureus Infektionen weiter charakterisiert werden. Im Ergebnis dieser Arbeit wurde demnach mit PurA ein neues Moonlighting Protein identifiziert, das als Inhibitor des Komplementsystems wesentlich zur Immunevasion von S. aureus beiträgt.
Für das bessere Verständnis der humoralen S. aureus-spezifischen Immunantwort, Unterschieden in der Antikörperantwort und der gebildeten Antikörperspezifitäten wurde weiterhin das während der Kolonisierung und Infektion gebildete S. aureus-spezifische Antikörperprofil untersucht. Dazu wurden Plasmen von humanen nasalen Trägern und Nicht-Trägern sowie murine Seren von infizierten Tieren untersucht. Insbesondere wurde das Pathogen-spezifische Antikörperprofil in unterschiedlichen Infektionsmodellen mit Hilfe eines Proteinarrays analysiert, der im Rahmen dieser Arbeit in einer Kooperation mit der Firma Alere Technologies (Jena, Deutschland) und universitären Forschergruppen der Universitäten Greifswald, Münster und Jena mitentwickelt wurde. Die Antikörperprofile von intramuskulär und intravenös infizierten Tieren resultierten in jeweils spezifischen Antikörperprofilen. Diese Ergebnisse deuten auf einen Zusammenhang zwischen der Art der Infektion und der gebildeten Antikörperspezifitäten hin. Wahrscheinlich beruht dies auf einer gewebespezifischen Genexpression als Anpassung an die individuellen Bedürfnisse im Wirtsorganismus. Das ausgebildete Antikörperprofil gibt somit einen Einblick in das Expressionsmuster von Virulenzfaktoren von S. aureus unter in vivo Bedingungen und trägt damit zum Verständnis der komplexen Interaktion von Pathogen und Wirt bei. Diese Untersuchungen ergänzen zudem die bisherigen Kenntnisse über die Anpassung der humoralen Immunantwort an eine asymptomatische Kolonisierung im Gegensatz zu einer akuten Infektion durch S. aureus. Darüber hinaus können die gewonnenen Ergebnisse für diagnostische Zwecke und zur Identifikation von neuen Zielstrukturen für eine Vakzin-Entwicklung genutzt werden.
Shiga toxin producing E. coli strains (STEC) are a great concern to human health. Upon an infection with as few as 100 bacteria, humans can develop disease symptoms ranging from watery to bloody diarrhea or even develop the hemolytic uremic syndrome (HUS). The major factor contributing to the disease symptoms is Shiga toxin (Stx) which can bind to the eukaryotic cells in the intestine of the human and induce cell death via apoptosis. Based, among other things, on the microbiota composition, the impact of STEC can vary. Some bacteria of the microbiota can interfere with the colonization of STEC strains in the first place. Others cannot impair the colonization but interfere with the toxin production and there are still others which are even infected by stx encoding phages, being released from STEC strains. Those previously harmless bacteria subsequently contribute to the toxin increase and worsen the disease progression. Since the genetic information of Stx is encoded on a prophage, antibiotic treatment of patients can lead to an increased toxin and stx-phage release and is therefore not recommended. Several STEC epidemics in different countries, which even resulted in the death of some patients, demonstrated that there is an urgent need for alternative treatment strategies.
The E. coli strain Nissle 1917 (EcN) has been used as a probiotic to treat gastrointestinal infections for more than 100 years. It harbors several fitness factors which contribute to the establishment of an intact intestinal barrier in the human gut. Moreover, studies with EcN unraveled that the probiotic E. coli can interfere with the colonization of STEC strains and their toxin production. This study aimed to investigate if EcN could be a possible alternative or supplementary treatment strategy for STEC infected patients, or a preventive treatment for the patient’s close contact persons.
Therefore, EcN was firstly investigated for a possible stx-prophage integration into its’s genome which would eliminate it from being a potential treatment due to the possibility of disease worsening. Despite the presence of the stx-phage surface receptor YaeT, EcN demonstrated a complete resistance towards the lysis and the lysogeny by stx-phages, which was proven by PCR, phage-plaque assays and phage enrichment approaches. Transcriptome data could unravel that a lambdoid prophage in the genome of EcN is involved in the resistance towards the phage infection. Other commensal E. coli tested presented a stx-phage resistance as well and in silico analysis revealed that all of them harbor a complete lambdoid prophage besides the stx-phage susceptible K-12 strain MG1655. We assume that the resistance of EcN towards a stx-phage infection is connected to the presence of an intact lambdoid prophage which interferes with superinfection.
Further experiments regarding the impact of the microcin negative EcN mutant SK22D towards STEC strains depicted that SK22D did not only interfere with the toxin production but also negatively regulated the transcription of the entire stx-prophage in coculture with all STEC strains tested (O157:H7, O26:H11, O145:H25, O103:H2, O111:H- and two O104:H4 isolates from the 2011 outbreak in Germany). This influence on the pathogenic factor production was evinced to be cell contact independent as SK22D could even interfere with the pathogenic factor production when being separated from the STEC strain EDL933 by a Transwell membrane with the pore size of 0.4 µm. From this data we concluded, that factor(s) released by SK22D interfere with the lysis of STEC strains by stabilizing the lysogenic state.
Another positive aspect of EcN towards the pathogenicity of STEC strains was encountered when EcN was incubated with isolated stx-phages. The probiotic strain could reduce the infectivity of the phages towards a MG1655 lysis from ~ 1e7 pfus/ml to 0 after 44 h of incubation. Various approaches to determine the characteristics of the factor(s) of EcN which are involved in the phage inactivation depicted it to be a heat resistant stationary phase protein on the surface of EcN, which could be a component of its biofilm.
Regarding the protective role of EcN we could further evince that SK22D was capable of interfering with the lysogenic K 12 mediated increase of Stx and stx phages. Lysogenic K-12 strains were characterized by a huge increase of Stx and stx-phage production. The presence of SK22D anyhow, could interfere with this K-12 mediated pathogenic factor increase. Transwell and stx phage infection kinetics led to the proposal that SK22D interfered with the stx-phage infection of K-12 strains in the first place rather than disturbing the lysis of lysogenic K 12. The protection from the phage infection could be due to the growth of K 12 strains within the SK22D culture, whereby the phage susceptible strains are masked from phage detection.
Summarizing, this work could underline the beneficial attributes of EcN towards the STEC pathogenicity in vitro. These results should be considered as pioneers for future in vivo studies to enable EcN medication as a supportive STEC infection treatment strategy.
Staphylococcus aureus ist ein Kommensale, der die menschliche Haut und Schleimhaut der Nase und des Rachens besiedelt. Der Keim verursacht aufgrund zahlreicher Virulenzfaktoren leichte aber auch schwere Infektionen wie Pneumonie, Endokarditis oder Sepsis. Die Behandlung von S. aureus-Infektionen gestaltet sich heutzutage schwierig, da der Keim Resistenzen gegen verschiedenste Antibiotika ausgebildet hat. Zur Bekämpfung dieser Resistenzen werden neue Antibiotika benötigt, die u.a. mit der Zellphysiologie und der Zellwandwandsynthese der Bakterien interferieren.
Die Zellphysiologie und Zellwandsynthese wird abhängig von der Wachstumsphase und Umwelt-einflüssen in den Bakterien streng reguliert. Neben den Zweikomponentensystemen sind Serin/Threonin-Proteinkinasen und -Phosphatasen wesentliche Sensoren und Regulatoren der Bakterien. Durch Phosphorylierung und Dephosphorylierung bewirken diese beiden Systeme eine Hemmung oder Aktivierung der entsprechenden Zielproteine. Dadurch kann sich die Bakterienzelle an innere und äußere Reize anpassen. In dieser Arbeit wurde die konservierte Serin/Threonin-Proteinkinase Stk und die Serin/Threonin-Phosphatase Stp von S. aureus untersucht. Die beiden Proteine Stk und Stp haben einen großen Einfluss auf die Signalweiterleitung, den zentralen Metabolismus, die Stressantwort, die Antibiotikaresistenz und die Virulenz von S. aureus.
Im ersten Teil dieser Arbeit wird dargelegt, dass Stk und Stp in der bakteriellen Membran lokalisiert sind, dort miteinander interagieren und antagonistisch Zielproteine phosphorylieren bzw. dephospho-rylieren. Die Deletion der Phosphatase Stp bewirkt, dass zahlreiche Proteine in der Zelle permanent phosphoryliert und daher vermutlich nur noch eingeschränkt funktionstüchtig sind. Die ausbleibende Dephosphorylierung der Proteine in der stp-Mutante hat einen dramatischen Effekt auf die Zellwand-synthese und die Virulenz von S. aureus. So hat die stp-Mutante eine verdickte Zellwand und ist weniger virulent als die stk-Mutante und der Wildtypstamm. Im Rahmen dieser Arbeit wird erstmals eine Erklärung präsentiert, die die strukturellen Besonderheiten von Stk und deren Auswirkung auf die Zellwandsynthese zusammenführt: In der stp-Mutante akkumulieren Zellwandvorläufer in der Zelle, da vermutlich die entsprechenden Zellwandsyntheseproteine durch Stk-vermittelte Phosphorylierung gehemmt werden. Die Proteine FemXAB nehmen eine zentrale Rolle in der Zellwandsynthese ein, indem sie die Pentaglycin-Interpeptidbrücke des Zellwandvorläufers Pentaglycin-Lipid II syntheti-sieren. Stk wird durch die Bindung seiner extrazellulären Domänen an Pentaglycin-Lipid II aktiviert. In der vorliegenden Arbeit konnte FemX als in vitro Substrat von Stk und Stp identifiziert werden. Die permanente Phosphorylierung von FemX in der stp-Mutante führt zur verminderten Synthese der Pentaglycin-Brücken am Lipid II und infolgedessen zum Einbau von unvollständigen Muropeptiden in den neuen Peptidoglycanstrang. Diese strukturelle Veränderung führt zur Verdickung der Zellwand und folglich zur verminderten Empfindlichkeit gegenüber der Glycyl-Glycinpeptidase Lysostaphin. Neben FemX interagiert Stk mit weiteren Zellwandsyntheseproteinen wie FemAB und einigen Zellteilungsproteinen. Diese Ergebnisse verdeutlichen, dass Stk das Vorkommen seines extrazellulären Liganden Lipid II detektiert und dementsprechend die Zellwandsynthese über FemX reguliert.
Im zweiten Teil der Arbeit wurde anhand verschiedener Omics-Techniken die stk-, stp- und stk/stp-Mutante im Vergleich zum S. aureus NewmanHG Wildtyp charakterisiert. Dabei zeigten sich teilweise große Unterschiede zwischen der stp-Mutante und den anderen Stämmen. Mit diesen Unter-suchungen konnten Ergebnisse aus anderen Studien bestätigt und mit weiteren Daten untermauert werden. So lässt sich die verminderte Virulenz der stp-Mutante mit der reduzierten Expression und Sekretion von Toxinen wie Hämolysinen und Leukozidinen erklären. Dies führt zu einer verminderten Hämolyse von Erythrozyten und einer verminderten Immunantwort gegen diese Toxine im Infektions-versuch. Stk und Stp phosphorylieren bzw. dephosphorylieren Transkriptionsfaktoren und Antwort-regulatoren von Zweikomponentensystemen, was zu der veränderten Expression und Sekretion der Virulenzfaktoren führt. Die Analyse der Mutanten offenbart, dass Stk ein negativer und Stp ein positiver Regulator der Virulenz in S. aureus ist. Außerdem regulieren Stk und Stp zentrale Aspekte des Metabolismus in S. aureus. So ist die Konzentration an Nukleotidtriphosphaten in der stp-Mutante reduziert, was auf eine verminderte Expression der Gene der Pyrimidinsynthese zurückzuführen ist. Anhand dieser Ergebnisse wird deutlich, dass Stk und Stp wesentliche Aspekte der Zellphysiologie wie die Zellwandsynthese, den zentralen Metabolismus und die Virulenz von S. aureus regulieren.