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The infection of a eukaryotic host cell by a bacterial pathogen is one of the most intimate examples of cross-kingdom interactions in biology. Infection processes are highly relevant from both a basic research as well as a clinical point of view. Sophisticated mechanisms have evolved in the pathogen to manipulate the host response and vice versa host cells have developed a wide range of anti-microbial defense strategies to combat bacterial invasion and clear infections. However, it is this diversity and complexity that makes infection research so challenging to technically address as common approaches have either been optimized for bacterial or eukaryotic organisms. Instead, methods are required that are able to deal with the often dramatic discrepancy between host and pathogen with respect to various cellular properties and processes. One class of cellular macromolecules that exemplify this host-pathogen heterogeneity is given by their transcriptomes: Bacterial transcripts differ from their eukaryotic counterparts in many aspects that involve both quantitative and qualitative traits. The entity of RNA transcripts present in a cell is of paramount interest as it reflects the cell’s physiological state under the given condition. Genome-wide transcriptomic techniques such as RNA-seq have therefore been used for single-organism analyses for several years, but their applicability has been limited for infection studies.
The present work describes the establishment of a novel transcriptomic approach for infection biology which we have termed “Dual RNA-seq”. Using this technology, it was intended to shed light particularly on the contribution of non-protein-encoding transcripts to virulence, as these classes have mostly evaded previous infection studies due to the lack of suitable methods. The performance of Dual RNA-seq was evaluated in an in vitro infection model based on the important facultative intracellular pathogen Salmonella enterica serovar Typhimurium and different human cell lines. Dual RNA-seq was found to be capable of capturing all major bacterial and human transcript classes and proved reproducible. During the course of these experiments, a previously largely uncharacterized bacterial small non-coding RNA (sRNA), referred to as STnc440, was identified as one of the most strongly induced genes in intracellular Salmonella. Interestingly, while inhibition of STnc440 expression has been previously shown to cause a virulence defect in different animal models of Salmonellosis, the underlying molecular mechanisms have remained obscure. Here, classical genetics, transcriptomics and biochemical assays proposed a complex model of Salmonella gene expression control that is orchestrated by this sRNA. In particular, STnc440 was found to be involved in the regulation of multiple bacterial target mRNAs by direct base pair interaction with consequences for Salmonella virulence and implications for the host’s immune response. These findings exemplify the scope of Dual RNA-seq for the identification and characterization of novel bacterial virulence factors during host infection.
Methionine is the first amino acid of every newly synthesised protein. In combination with its role as precursor for the vital methyl-group donor S-adenosylmethionine, methionine is essential for every living cell. The opportunistic human pathogen Staphylococcus aureus is capable of synthesising methionine de novo, when it becomes scarce in the environment. All genes required for the de novo biosynthesis are encoded by the metICFE-mdh operon, except for metX. Expression is controlled by a hierarchical network with a methionyl-tRNA-specific T-box riboswitch (MET-TBRS) as centrepiece, that is also referred to as met leader (RNA). T-box riboswitches (TBRS) are regulatory RNA elements located in the 5’-untranslated region (5’-UTR) of genes. The effector molecule of T-box riboswitches is uncharged cognate tRNA. The prevailing mechanism of action is premature termination of transcription of the nascent RNA in the absence of the effector (i.e. uncharged cognate tRNA) due to formation of a hairpin structure, the Terminator stem. In presence of the effector, a transient stabilisation of the alternative structure, the Antiterminator, enables transcription of the downstream genes (‘read-through’). Albeit, after the read-through the thermodynamically more stable Terminator eventually forms. The Terminator and the Antiterminator are two mutually exclusive structures. Previous work of the research group showed that in staphylococci the MET-TBRS ensures strictly methionine-dependent control of met operon expression. Uncharged methionyl-tRNA that activates the system is only present in sufficient amounts under methionine-deprived conditions. In contrast to other bacterial TBRS, the staphylococcal MET-TBRS has some characteristic features regarding its length and predicted secondary structure whose relevance for the function are yet unkown.
Aim of the present thesis was to experimentally determine the structure of the met leader RNA and to investigate the stability of the met operon-specific transcripts in the context of methionine biosynthesis control. Furthermore, the yet unknown function of the mdh gene within the met operon was to be determined.
In the context of this thesis, the secondary structure of the met leader was determined employing in-line probing. The structural analysis revealed the presence of almost all highly conserved T-box riboswitch structural characteristics. Furthermore, three additional stems, absent in all T-box riboswitches analysed to date, could be identified. Particularly remarkable is the above average length of the Terminator stem which renders it a potential target of the double-strand-specific endoribonuclease III (RNase III). The RNase III-dependent cleavage of the met leader could be experimentally verified by the use of suitable mutants. Moreover, the exact cleavage site within the Terminator was determined.
The unusual immediate separation of the met leader from the met operon mRNA via the RNase III cleavage within the Terminator stem induces the rapid degradation of the met leader RNA and, most likely, that of the 5’-region of the met mRNA. The met mRNA is degraded from its 5’-end by the exoribonuclease RNase J. The stability of the met mRNA was found to vary over the length of the transcript with an instable 5’-end (metI and metC) and a longer half-life towards the 3’-end (metE and mdh). The varying transcript stability is reflected by differences in the available cellular protein levels. The obtained data suggest that programmed mRNA degradation is another level of regulation in the complex network of staphylococcal de novo methionine biosynthesis control.
In addition, the MET-TBRS was studied with regard to a future use as a drug target for novel antimicrobial agents. To this end, effects of a dysregulated methionine biosynthesis on bacterial growth and survival were investigated in met leader mutants that either caused permanent transcription of the met operon (‘ON’) or prevented operon transcription (‘OFF’), irrespective of the methionine status in the cell. Methionine deprivation turned out to be a strong selection pressure, as ‘OFF’ mutants acquired adaptive mutations within the met leader to restore met operon expression that subsequently re-enabled growth.
The second part of the thesis was dedicated to the characterisation of the Mdh protein that is encoded by the last gene of the met operon and whose function is unknown yet. At first, co-transcription and -expression with the met operon could be demonstrated. Next, the Mdh protein was overexpressed and purified and the crystal structure of Mdh was solved to high resolution by the Kisker research group (Rudolf-Virchow-Zentrum Würzburg). Analysis of the structure revealed the amino acid residues crucial for catalytic activity, and zinc was identified as a co-factor of Mdh. Also, Mdh was shown to exist as a dimer. However, identification of the Mdh substrate was, in the context of this thesis, (still) unsuccessful. Nevertheless, interactions of Mdh with enzymes of the met operon could be demonstrated by employing the bacterial two-hybrid system. This fact and the high conservation of mdh/Mdh on nucleotide and amino acid level among numerous staphylococcal species suggests an important role of Mdh within the methionine metabolism that should be a worthwhile subject of future research.
Small proteins, often defined as shorter than 50 amino acids, have been implicated
in fundamental cellular processes. Despite this, they have been largely understudied throughout all domains of life, since their size often makes their identification and characterization challenging.
This work addressed the knowledge gap surrounding small proteins with a focus
on the model bacterial pathogen Salmonella Typhimurium. In a first step,
new small proteins were identified with a combination of computational and experimental approaches. Infection-relevant datasets were then investigated with
the updated Salmonella annotation to prioritize promising candidates involved in virulence.
To implement the annotation of new small proteins, predictions from the algorithm
sPepFinder were merged with those derived from Ribo-seq. These were added to the Salmonella annotation and used to (re)analyse different datasets. Information
regarding expression during infection (dual RNA-seq) and requirement for virulence (TraDIS) was collected for each given coding sequence. In parallel,
Grad-seq data were mined to identify small proteins engaged in intermolecular
interactions.
The combination of dual RNA-seq and TraDIS lead to the identification of small
proteins with features of virulence factors, namely high intracellular induction
and a virulence phenotype upon transposon insertion. As a proof of principle of
the power of this approach in highlighting high confidence candidates, two small
proteins were characterized in the context of Salmonella infection.
MgrB, a known regulator of the PhoPQ two-component system, was shown to be essential for the infection of epithelial cells and macrophages, possibly via its stabilizing effect on flagella or by interacting with other sensor kinases of twocomponent
systems. YjiS, so far uncharacterized in Salmonella, had an opposite role in infection, with its deletion rendering Salmonella hypervirulent. The mechanism underlying this, though still obscure, likely relies on the interaction with
inner-membrane proteins.
Overall, this work provides a global description of Salmonella small proteins in
the context of infection with a combinatorial approach that expedites the identification
of interesting candidates. Different high-throughput datasets available for
a broad range of organisms can be analysed in a similar manner with a focus on small proteins. This will lead to the identification of key factors in the regulation
of various processes, thus for example providing targets for the treatment of bacterial
infections or, in the case of commensal bacteria, for the modulation of the microbiota composition.
Escherichia coli Nissle 1917 (EcN) gehört zu den am besten untersuchten und charakterisierten probiotischen Bakterienstämmen. Seit Beginn des letzten Jahrhunderts wird er als Medikament eingesetzt, um verschiedene Darmerkrankungen wie z.B. Diarrhöe, entzündliche Darmerkrankungen und Verstopfung zu behandeln. Die Flagelle des EcN vermittelt Beweglichkeit und kann die Produktion von humanem β-Defensin 2 (hBD2) durch Epithelzellen induzieren. Somit ist dieses Organell direkt in die probiotische Funktion des EcN involviert. Es konnte gezeigt werden, dass die Flagellen anderer Bakterien, wie z.B. dem probiotischen Stamm Bacillus cereus CH oder den pathogenen Stämmen Pseudomonas aeruginosa und Clostridium difficile, die Adhäsion an intestinalen Mucus, welcher von Epithelzellen sekretiert wird, vermitteln. Allerdings blieb unklar, welcher Teil der Flagelle an welche Mucuskomponente bindet. Die Fähigkeit effizient an Wirtgewebe zu adhärieren wird als wichtiges Attribut eines probiotischen Stammes angesehen. Ex vivo Adhäsionsstudien mit Kryoschnitten humaner Darmbiopsien haben gezeigt, dass die Flagelle des EcN in die effiziente Adhäsion an humanes Darmgewebe involviert sein muss. Aus diesem Grund wurde in dieser Arbeit die Funktion der Flagelle des EcN als Adhäsin untersucht. Zunächst wurde die hyperflagellierte Variante EcN ATHF isoliert und durch verschiedene Experimente, z.B. Schwärmagartests und Elektronenmikroskopie, charakterisiert. Weitere ex vivo Adhäsionsstudien mit EcN ATHF zeigten eine höhere Adhäsionseffizienz dieser hyperflagellierten Variante und bestätigten damit die Rolle der Flagelle bei der effizienten Adhäsion von EcN an die Kryoschnitte der humanen Darmbiopsien. Interessanterweise fungierte die Flagelle in in vitro Studien mit den humanen Epithelzellen Caco-2 und T24 nicht als Adhäsin. Diese Unterschiede zwischen den in vitro und ex vivo Studien führten zu der Annahme, dass die Flagelle des EcN in vivo die Adhäsion an Mucus vermittelt, welcher von den Caco-2- und T24-Zellen nicht produziert wird, aber in den Kryoschnitten der Darmbiopsien nachgewiesen wurde. Diese Vermutung wurde durch in vitro Adhäsionsstudien mit der Mucin-produzierenden Epithelzelllinie LS174-T bestätigt, da die Flagellen für eine effektive Adhäsion an diese Zellen essentiell waren. Zudem reduzierte die Präinkubation flagellierter EcN-Stämme mit Mucin2 ihre Adhäsionseffizienz an Kryoschnitte humaner Darmbiopsien. Um die direkte Interaktion zwischen Flagellen des EcN Wildtyps und Mucus zu zeigen, wurde ein ELISA etabliert. Es konnte eine direkte konzentrationsabhängige Interaktion zwischen isolierten Flagellen des EcN Wildtyps und Mucin2, bzw. humanem Mucus (Kolon) beobachtet werden. Interessanterweise konnte keine Interaktion zwischen isolierten Flagellen des EcN Wildtyps und murinem Mucus (Duodenum, Ileum, Caecum, Colon) festgestellt werden. Dies weist darauf hin, dass die Mucuszusammensetzung zwischen verschiedenen Spezies variiert. Verschiedene Kohlenhydrate, welche bekannte Mucusbestandteile sind, wurden auf ihre Interaktion mit der Flagelle von EcN getestet und Gluconat wurde als ein Rezeptor identifiziert. Die Präinkubation isolierter Flagellen mit Gluconat reduzierte ihre Interaktion mit Mucin2, bzw. humanem Mucus signifikant. Zudem wurde die oberflächenexponierte Domäne D3 des Flagellins, der Hauptuntereinheit der Flagelle, als möglicher Interaktionspartner von Mucin2, bzw. humanem Mucus ausgeschlossen. Flagellen, die aus einer Domäne D3 Deletionsmutante isoliert wurden, zeigten sogar eine effizientere Bindung an Mucin2, bzw. humanen Mucus. Weiterhin konnte gezeigt werden, dass Änderungen des pH-Wertes signifikante Effekte auf die Interaktion zwischen Mucus und isolierten Flagellen hatten, vermutlich aufgrund von Konformationsänderungen. Zusammenfassend wurde in dieser Arbeit die Flagelle als neues und scheinbar wichtigstes Adhäsin in vivo für den probiotischen Stamm EcN identifiziert. Hierfür wurden sowohl eine hyperflagellierte Variante, eine ΔfliC Mutante, sowie der dazugehörige komplementierte Stamm verwendet. EcN ist zudem der erste probiotische Stamm für den eine direkte Bindung der Flagellen an humanen Mucus nachgewiesen werden konnte. Die Mucuskomponente Gluconat konnte dabei als wichtiger Rezeptor identifiziert werden. Da einige pathogene Bakterien ihre Flagelle zur Adhäsion an Wirtsgewebe nutzen, könnte dieses Organell EcN dazu befähigen, mit Pathogenen um die erfolgreiche Kolonisierung des Darms zu konkurrieren, was als wichtige Eigenschaft eines Probiotikums betrachtet wird.
The sexual phase of Plasmodium falciparum begins with the differentiation of intraerythrocytic sexual stages, termed gametocytes, in the human host. Mature gametocytes circulate in the peripheral blood and are taken up by the mosquito during the blood meal. These stages are essential for the spread of the malaria disease and form gametes in the mosquito midgut within minutes. A highly conserved family of six secreted proteins has been identified in Plasmodium falciparum. They comprise multiple adhesive domains and are termed PfCCp1 through PfCCp5, and PfFNPA. It was revealed in this work that PfCCp multi-domain adhesion proteins form protein complexes in gametocytes and on the surface of newly emerged macrogametes by adhesion domain-mediated binding. Co-Immunoprecipitation assays with activated gametocyte lysates show interactions between PfCCp proteins and indicate surface association via Pfs230 and Pfs25. Pfs230 is connected with the plasma membrane of the parasite by its interaction partner Pfs48/45. This protein is linked to the plasma membrane by a GPI anchor and presumably retains the multi-protein complex on the surface of newly emerged macrogametes in the mosquito midgut. A WD40 domain containing protein was identified to be part of this protein complex. It might serve as platform for the assembly of the multi protein complex or mediate the interplay among proteins, as suggested from known functions of the WD40 domain repeats. During egress from the host erythrocyte, the emerging gametes become vulnerable to factors of the human complement, which is taken up with the blood meal. In this thesis it was found that the complement system is active for about one hour post feeding. Macrogametes defend against complement-mediated lysis by co-opting the human complement regulators Factor H and FHL-1 from the blood-meal. These serum proteins bind via its SCR domains 5-7 to the surface of macrogametes. Once bound, they trigger complement inactivation of the alternative pathway, which prevents induction of complement lysis on the surface of the malaria parasite. Antibodies against Factor H are able to impair the sexual development in vitro and are able to block transmission to the mosquito. Interaction studies on endogenous proteins and immobilized recombinant proteins revealed the PfGAP50 protein as binding partner of Factor H and FHL-1. This protein was hitherto described as a glideosome-associated protein in invasive parasite stages, but has not yet been characterized in gametes. First localization studies indicate a relocation of PfGAP50 from the inner membrane complex to the surface of macrogametes. Malaria still persists as one of the deadliest infectious diseases worldwide. Investigations on the essential transmissive stages, gametocytes and gametes of Plasmodium falciparum, stood in the background of research for a long time. This work deciphered details on protein interactions on the surface of the malaria parasite and provides first information about coactions between the parasite and the human complement in the mosquito midgut.
RNA-binding proteins (RBPs) have been extensively studied in eukaryotes, where they post-transcriptionally regulate many cellular events including RNA transport, translation, and stability. Experimental techniques, such as cross-linking and co-purification followed by either mass spectrometry or RNA sequencing has enabled the identification and characterization of RBPs, their conserved RNA-binding domains (RBDs), and the regulatory roles of these proteins on a genome-wide scale. These developments in quantitative, high-resolution, and high-throughput screening techniques have greatly expanded our understanding of RBPs in human and yeast cells. In contrast, our knowledge of number and potential diversity of RBPs in bacteria is comparatively poor, in part due to the technical challenges associated with existing global screening approaches developed in eukaryotes.
Genome- and proteome-wide screening approaches performed in silico may circumvent these technical issues to obtain a broad picture of the RNA interactome of bacteria and identify strong RBP candidates for more detailed experimental study. Here, I report APRICOT (“Analyzing Protein RNA Interaction by Combined Output Technique”), a computational pipeline for the sequence-based identification and characterization of candidate RNA-binding proteins encoded in the genomes of all domains of life using RBDs known from experimental studies. The pipeline identifies functional motifs in protein sequences of an input proteome using position-specific scoring matrices and hidden Markov models of all conserved domains available in the databases and then statistically score them based on a series of sequence-based features. Subsequently, APRICOT identifies putative RBPs and characterizes them according to functionally relevant structural properties. APRICOT performed better than other existing tools for the sequence-based prediction on the known RBP data sets. The applications and adaptability of the software was demonstrated on several large bacterial RBP data sets including the complete proteome of Salmonella Typhimurium strain SL1344. APRICOT reported 1068 Salmonella proteins as RBP candidates, which were subsequently categorized using the RBDs that have been reported in both eukaryotic and bacterial proteins. A set of 131 strong RBP candidates was selected for experimental confirmation and characterization of RNA-binding activity using RNA co-immunoprecipitation followed by high-throughput sequencing (RIP-Seq) experiments. Based on the relative abundance of transcripts across the RIP-Seq libraries, a catalogue of enriched genes was established for each candidate, which shows the RNA-binding potential of 90% of these proteins. Furthermore, the direct targets of few of these putative RBPs were validated by means of cross-linking and co-immunoprecipitation (CLIP) experiments.
This thesis presents the computational pipeline APRICOT for the global screening of protein primary sequences for potential RBPs in bacteria using RBD information from all kingdoms of life. Furthermore, it provides the first bio-computational resource of putative RBPs in Salmonella, which could now be further studied for their biological and regulatory roles. The command line tool and its documentation are available at https://malvikasharan.github.io/APRICOT/.
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.
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.
Der Hefepilz Candida albicans gehört zu den fakultativ pathogenen Infektionserregern und ist Teil der natürlichen Mikroflora der Schleimhäute des Verdauungs- und Urogenitaltraktes der meisten gesunden Menschen. Ist das Gleichgewicht der Flora gestört, kann es zu oberflächlichen Mykosen kommen, wie z.B. der oropharyngealen Candidiasis (Mundsoor), die in der Regel durch die Gabe eines Antimykotikums in wenigen Tagen zu behandeln sind. In seltenen Fällen kann es auch zu schwerwiegenden Infektionsverläufen bis hin zu lebensbedrohlichen systemischen Mykosen kommen. Hauptsächlich immunsupprimierte Patienten, wie z.B. AIDS-Patienten oder Personen, die kürzlich einer Organ- oder Knochenmarkstransplantation unterzogen wurden, leiden häufig an oberflächlichen C. albicans-Infektionen. Insbesondere bei wiederkehrenden Infektionen ist der Pilz in der Lage, gegen das häufig verabreichte Medikament Fluconazol eine Resistenz zu entwickeln. Ein wichtiger Mechanismus dieser Resistenzentwicklung ist die Überexpression von Effluxpumpen, die das Medikament aus der Zelle heraustransportieren. Zwei Arten von Effluxpumpen, die eine Rolle in der Resistenzentwicklung in C. albicans spielen, konnten bisher identifiziert werden, die ABC (ATP binding cassette)-Transporter Cdr1 und Cdr2 sowie der MFS (major facilitator superfamily)-Transporter Mdr1. Der Zinc-Cluster Transkriptionsfaktor Mrr1 spielt eine wichtige Rolle in der Regulation der MDR1-E¬ffluxpumpe. Er kontrolliert die MDR1-Expression in Anwesenheit induzierender Substanzen und sogenannte "gain-of-function" Mutationen in MRR1 konnten als die Ursache der konstitutiven MDR1-Hochregulierung und der "Multidrug-Resistance" in C. albicans identifiziert werden. In dieser Arbeit konnte ein Ortholog zu MRR1 aus C. albicans in Candida dubliniensis, einer zu C. albicans nahe verwandten Hefe, identifiziert werden. Es wurde gezeigt, dass in den untersuchten klinischen und in vitro generierten Fluconazol-resistenten C. dubliniensis-Stämmen ebenfalls gain-of-funcion Mutationen in MRR1 die MDR1-Überexpression und eine Resistenz bewirken. Die Ergebnisse demonstrieren, dass der Transkriptionsfaktor Mrr1 eine wichtige Rolle in der Entwicklung der Resistenz in diesen humanpathogenen Pilzen spielt. Bisher ist nicht bekannt, wie der Zinc-Cluster Transkriptionsfaktor MRR1 durch induzierende Substanzen oder gain-of-function Mutationen aktiviert wird. Um zu verstehen, wie die Mrr1- Aktivität reguliert wird, wurden in dieser Arbeit durch Deletionsstudien funktionelle Domänen des Transkriptionsfaktors identifiziert. Um einen besseren Einblick in die Regulation der MDR1-vermittelten Resistenz in C. albicans zu bekommen, wurde in dieser Arbeit die gegenseitige Abhängigkeit von Mrr1 und Cap1 bzw. Upc2 in Bezug auf die MDR1-Expression untersucht. Es wurden ChIP-on-chip Analysen und Transkriptionsprofile mit aktiviertem Mrr1 durchgeführt, um direkte Targets von Mrr1 zu identifizieren. Mit der vorliegenden Arbeit wurde ein wichtiger Beitrag zum Verständnis der Entwicklung der Multidrug-Resistenz in C. albicans geleistet. E¬ffluxpumpen und deren Regulatoren stellen in der Bekämpfung von C. albicans-Infektionen ein interessantes Angriffsziel für die Entwicklung neuer Medikamente und die Weiterentwicklung bereits vorhandender Antimykotika dar.
Dendritic cell-based vaccination is a well established technique for preventive and therapeutic instruction of the immune system where conservative vaccine formulations fail to cure or prevent diseases, respectively. Efficiency of this technique already was demonstrated in infectious diseases as well as for cancer in animal or human studies. Well controlled manipulation and antigen-loading of immature DC is most beneficial to this technique. But, time-consuming and cost-extensive procedures for preparation of DC precursors, expansion and stimulation of DC and inpatient administration are big disadvantages regarding vaccine development for pandemic infectious diseases that occur mainly in underdeveloped countries. Therefore vaccines are needed that are pathogen-tailored and able to induce equal immune responses as their DC-based vaccine models. For vaccination against Leishmania parasites such a DC-based vaccine is feasible and its efficacy to induce protective Th1-based immune responses was already demonstrated in several animal studies. But, one of our own studies indicated supportive activity of host cells exceeding the allocation of T cells to become activated by transferred DC. IL-12, an important cytokine for the induction of Th1-related immune responses, has to be produced by host cells. Therefore, the aim of this study was to investigate the mechanism of BMDC-based vaccination with regard to simplification of the vaccine formulation. Key questions that have been addressed are: Which cells process the information that is transferred by the injected DC and what are the key components of this information? Further more, it was looked at whether altered vaccine formulations are able to induce protective immunity and whether they share equal molecular mechanisms. The current paradigm of BMDC-based vaccination proposes direct interaction of transferred BMDC with host T cells. These BMDC have to be antigen-loaded for stimulation via antigen-peptide-MHC molecule-complexes and they have to be activated for proper co-stimulation of T cells. Here, this study demonstrates that neither activation for co-stimulation nor direct interaction with adequate MHC molecules is needed for the induction of protective immunity against infection with Leishmania-parasites. Disrupted antigen-loaded BMDC are able to induce protective immunity in BALB/c mice without pre-stimulation via CpG ODN. Beyond, if BMDC were used with a different MHC-background than recipient mice then the vaccine still would be efficient in terms of reduction of footpad swelling and parasite load in draining lymph nodes. Even more, DC-specific features are no key component that leads to protective immunity as vaccination with disrupted antigen-loaded MΦ shows equal properties than before mentioned vaccine formulations. Further more, it was found that host DC play a major role in transforming the incoming signal, received from transferred antigen-loaded DC, into Th1-related stimuli and Leishmania-antigen-specific T cell activation. Suspensions of disrupted antigen-loaded DC resemble a combination of laid off soluble molecules together with exosome-like vesicles that formed after disruption of membranes. Here it was shown that separation of the membranous and soluble fractions and subsequent transfer into BALB/c mice will lead to protection of these mice against infection with L. major promastigotes only if the membranous fraction is used as vaccine. More, this vaccine formulation takes advantage of easy storage at -80°C with no need of fresh production. This clearly demonstrates that the immunity-inducing principle of disrupted DC-based vaccination lies within the membrane enclosed fraction. On a molecular level, disrupted antigen-loaded DC induce Th1-related cytokines during vaccination and as response on pathogen encounter. In vivo assays revealed IL-12 production and antigen-specific T cell proliferation among splenocytes that were stimulated with disrupted antigen-loaded DC. Splenocytes of accordingly vaccinated mice produce tremendous amounts of IFNγ after stimulation with Leishmania parasites. In summary, disrupted antigen-loaded BMDC fulfil all characteristics of DC-based vaccination against Leishmania major. But, while purification of membranes of antigen-loaded DC and subsequent transfer to BALB/c mice leads to control of the disease in the animal model, only slight levels of Th1-related cytokines are seen in the in vivo assays. Whether this points towards a loss of vaccine activity on unseen levels or unknown sites where Th1-related immunity is induced by both, complete solution and purified membranes, still has to be determined.