@phdthesis{Winkler2015, author = {Winkler, Ann-Cathrin Nicole}, title = {Identification of human host cell factors involved in \(Staphylococcus\) \(aureus\) 6850 infection}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-114300}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2015}, abstract = {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.}, subject = {Staphylococcus aureus}, language = {en} } @phdthesis{Wermser2019, author = {Wermser, Charlotte}, title = {Morphology, regulation and interstrain interactions in a new macrocolony biofilm model of the human pathogen \(Staphylococcus\) \(aureus\)}, doi = {10.25972/OPUS-16593}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-165931}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2019}, abstract = {The role of multicellularity as the predominant microbial lifestyle has been affirmed by studies on the genetic regulation of biofilms and the conditions driving their formation. Biofilms are of prime importance for the pathology of chronic infections of the opportunistic human pathogen Staphylococcus aureus. The recent development of a macrocolony biofilm model in S. aureus opened new opportunities to study evolution and physiological specialization in biofilm communities in this organism. In the macrocolony biofilm model, bacteria form complex aggregates with a sophisticated spatial organization on the micro- and macroscale. The central positive and negative regulators of this organization in S. aureus are the alternative sigma factor σB and the quorum sensing system Agr, respectively. Nevertheless, nothing is known on additional factors controlling the macrocolony morphogenesis. In this work, the genome of S. aureus was screened for novel factors that are required for the development of the macrocolony architecture. A central role for basic metabolic pathways was demonstrated in this context as the macrocolony architecture was strongly altered by the disruption of nucleotide and carbohydrate synthesis. Environmental signals further modulate macrocolony morphogenesis as illustrated by the role of an oxygen-sensitive gene regulator, which is required for the formation of complex surface structures. A further application of the macrocolony biofilm model was demonstrated in the study of interstrain interactions. The integrity of macrocolony communities was macroscopically visibly disturbed by competitive interactions between clinical isolates of S. aureus. The results of this work contribute to the characterization of the macrocolony biofilm model and improve our understanding of developmental processes relevant in staphylococcal infections. The identification of anti-biofilm effects exercised through competitive interactions could lead to the design of novel antimicrobial strategies targeting multicellular bacterial communities.}, subject = {Staphylococcus aureus}, language = {en} } @phdthesis{Wencker2022, author = {Wencker, Freya Dorothea Ruth}, title = {The methionine biosynthesis operon in \(Staphylococcus\) \(aureus\): Role of concerted RNA decay in transcript stability and T-box riboswitch turnover}, doi = {10.25972/OPUS-20712}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-207124}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2022}, abstract = {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 W{\"u}rzburg). 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.}, subject = {Staphylococcus aureus}, language = {en} } @article{StelznerWinklerLiangetal.2020, author = {Stelzner, Kathrin and Winkler, Ann-Cathrin and Liang, Chunguang and Boyny, Aziza and Ade, Carsten P. and Dandekar, Thomas and Fraunholz, Martin J. and Rudel, Thomas}, title = {Intracellular Staphylococcus aureus Perturbs the Host Cell Ca\(^{2+}\) Homeostasis To Promote Cell Death}, series = {mBio}, volume = {11}, journal = {mBio}, doi = {10.1128/mBio.02250-20}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-231448}, year = {2020}, abstract = {The opportunistic human pathogen Staphylococcus aureus causes serious infectious diseases that range from superficial skin and soft tissue infections to necrotizing pneumonia and sepsis. While classically regarded as an extracellular pathogen, S. aureus is able to invade and survive within human cells. Host cell exit is associated with cell death, tissue destruction, and the spread of infection. The exact molecular mechanism employed by S. aureus to escape the host cell is still unclear. In this study, we performed a genome-wide small hairpin RNA (shRNA) screen and identified the calcium signaling pathway as being involved in intracellular infection. S. aureus induced a massive cytosolic Ca\(^{2+}\) increase in epithelial host cells after invasion and intracellular replication of the pathogen. This was paralleled by a decrease in endoplasmic reticulum Ca\(^{2+}\) concentration. Additionally, calcium ions from the extracellular space contributed to the cytosolic Ca2+ increase. As a consequence, we observed that the cytoplasmic Ca\(^{2+}\) rise led to an increase in mitochondrial Ca\(^{2+}\) concentration, the activation of calpains and caspases, and eventually to cell lysis of S. aureus-infected cells. Our study therefore suggests that intracellular S. aureus disturbs the host cell Ca\(^{2+}\) homeostasis and induces cytoplasmic Ca\(^{2+}\) overload, which results in both apoptotic and necrotic cell death in parallel or succession. IMPORTANCE Despite being regarded as an extracellular bacterium, the pathogen Staphylococcus aureus can invade and survive within human cells. The intracellular niche is considered a hideout from the host immune system and antibiotic treatment and allows bacterial proliferation. Subsequently, the intracellular bacterium induces host cell death, which may facilitate the spread of infection and tissue destruction. So far, host cell factors exploited by intracellular S. aureus to promote cell death are only poorly characterized. We performed a genome-wide screen and found the calcium signaling pathway to play a role in S. aureus invasion and cytotoxicity. The intracellular bacterium induces a cytoplasmic and mitochondrial Ca\(^{2+}\) overload, which results in host cell death. Thus, this study first showed how an intracellular bacterium perturbs the host cell Ca\(^{2+}\) homeostasis."}, language = {en} } @article{StelznerBoynyHertleinetal.2021, author = {Stelzner, Kathrin and Boyny, Aziza and Hertlein, Tobias and Sroka, Aneta and Moldovan, Adriana and Paprotka, Kerstin and Kessie, David and Mehling, Helene and Potempa, Jan and Ohlsen, Knut and Fraunholz, Martin J. and Rudel, Thomas}, title = {Intracellular Staphylococcus aureus employs the cysteine protease staphopain A to induce host cell death in epithelial cells}, series = {PLoS Pathogens}, volume = {17}, journal = {PLoS Pathogens}, number = {9}, doi = {10.1371/journal.ppat.1009874}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-263908}, year = {2021}, abstract = {Staphylococcus aureus is a major human pathogen, which can invade and survive in non-professional and professional phagocytes. Uptake by host cells is thought to contribute to pathogenicity and persistence of the bacterium. Upon internalization by epithelial cells, cytotoxic S. aureus strains can escape from the phagosome, replicate in the cytosol and induce host cell death. Here, we identified a staphylococcal cysteine protease to induce cell death after translocation of intracellular S. aureus into the host cell cytoplasm. We demonstrated that loss of staphopain A function leads to delayed onset of host cell death and prolonged intracellular replication of S. aureus in epithelial cells. Overexpression of staphopain A in a non-cytotoxic strain facilitated intracellular killing of the host cell even in the absence of detectable intracellular replication. Moreover, staphopain A contributed to efficient colonization of the lung in a mouse pneumonia model. In phagocytic cells, where intracellular S. aureus is exclusively localized in the phagosome, staphopain A did not contribute to cytotoxicity. Our study suggests that staphopain A is utilized by S. aureus to exit the epithelial host cell and thus contributes to tissue destruction and dissemination of infection. Author summary Staphylococcus aureus is an antibiotic-resistant pathogen that emerges in hospital and community settings and can cause a variety of diseases ranging from skin abscesses to lung inflammation and blood poisoning. The bacterium can asymptomatically colonize the upper respiratory tract and skin of humans and take advantage of opportune conditions, like immunodeficiency or breached barriers, to cause infection. Although S. aureus was not regarded as intracellular bacterium, it can be internalized by human cells and subsequently exit the host cells by induction of cell death, which is considered to cause tissue destruction and spread of infection. The bacterial virulence factors and underlying molecular mechanisms involved in the intracellular lifestyle of S. aureus remain largely unknown. We identified a bacterial cysteine protease to contribute to host cell death of epithelial cells mediated by intracellular S. aureus. Staphopain A induced killing of the host cell after translocation of the pathogen into the cell cytosol, while bacterial proliferation was not required. Further, the protease enhanced survival of the pathogen during lung infection. These findings reveal a novel, intracellular role for the bacterial protease staphopain A.}, language = {en} } @phdthesis{Stelzner2020, author = {Stelzner, Kathrin}, title = {Identification of factors involved in Staphylococcus aureus- induced host cell death}, doi = {10.25972/OPUS-18899}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-188991}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2020}, abstract = {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.}, subject = {Staphylococcus aureus}, language = {en} } @article{SelleHertleinOesterreichetal.2016, author = {Selle, Martina and Hertlein, Tobias and Oesterreich, Babett and Klemm, Theresa and Kloppot, Peggy and M{\"u}ller, Elke and Ehricht, Ralf and Stentzel, Sebastian and Br{\"o}ker, Barbara M. and Engelmann, Susanne and Ohlsen, Knut}, title = {Global antibody response to Staphylococcus aureus live-cell vaccination}, series = {Scientific Reports}, volume = {6}, journal = {Scientific Reports}, doi = {10.1038/srep24754}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-181245}, year = {2016}, abstract = {The pathogen Staphylococcus aureus causes a broad range of severe diseases and is feared for its ability to rapidly develop resistance to antibiotic substances. The increasing number of highly resistant S. aureus infections has accelerated the search for alternative treatment options to close the widening gap in anti-S. aureus therapy. This study analyses the humoral immune response to vaccination of Balb/c mice with sublethal doses of live S. aureus. The elicited antibody pattern in the sera of intravenously and intramuscularly vaccinated mice was determined using of a recently developed protein array. We observed a specific antibody response against a broad set of S. aureus antigens which was stronger following i.v. than i.m. vaccination. Intravenous but not intramuscular vaccination protected mice against an intramuscular challenge infection with a high bacterial dose. Vaccine protection was correlated with the strength of the anti-S. aureus antibody response. This study identified novel vaccine candidates by using protein microarrays as an effective tool and showed that successful vaccination against S. aureus relies on the optimal route of administration.}, language = {en} } @phdthesis{Schiebel2013, author = {Schiebel, Johannes}, title = {Structure-Based Drug Design on Enzymes of the Fatty Acid Biosynthesis Pathway}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-69239}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2013}, abstract = {W{\"a}hrend die Wirkung der meisten gebr{\"a}uchlichen Antibiotika auf einer Beeintr{\"a}chtigung wichtiger bakterieller Prozesse beruht, wirken manche Substanzen durch die St{\"o}rung der Zellmembran-Struktur. Da Fetts{\"a}uren ein essentieller Bestandteil von Membran-Phospholipiden sind, stellt die bakterielle Fetts{\"a}urebiosynthese II (FAS-II) einen relativ wenig erforschten, aber dennoch vielversprechenden Angriffspunkt f{\"u}r die Entwicklung neuer Antibiotika dar. Das wichtige Antituberkulotikum Isoniazid blockiert die mykobakterielle Fetts{\"a}urebiosynthese und ruft dadurch morphologische {\"A}nderungen sowie letztlich die Lyse des Bakteriums hervor. Eine wichtige Erkenntnis war, dass Isoniazid den letzten Schritt des FAS-II Elongationszyklus inhibiert, der durch die Enoyl-ACP Reduktase katalysiert wird. Darauf aufbauend wurden mehrere Programme ins Leben gerufen, die sich zum Ziel gesetzt hatten, neue Molek{\"u}le zu entwickeln, welche dieses Protein verschiedener Pathogene hemmen. Die S. aureus Enoyl-ACP Reduktase (saFabI) ist von besonders großem Interesse, da drei vielversprechende Inhibitoren dieses Proteins entwickelt werden konnten, die momentan in klinischen Studien eingehend untersucht werden. Trotz dieser Erfolgsaussichten waren zum Zeitpunkt, als die vorliegenden Arbeiten aufgenommen wurden, keine Kristallstrukturen von saFabI {\"o}ffentlich verf{\"u}gbar. Daher war es eines der Hauptziele dieser Doktorarbeit, auf der Basis von kristallographischen Experimenten atomar aufgel{\"o}ste Modelle f{\"u}r dieses wichtige Protein zu erzeugen. Durch die Entwicklung einer verl{\"a}sslichen Methode zur Kristallisation von saFabI im Komplex mit NADP+ und Diphenylether-Inhibitoren konnten Kristallstrukturen von 17 verschiedenen tern{\"a}ren Komplexen gel{\"o}st werden. Weitere kristallographische Experimente ergaben zwei apo-Strukturen sowie zwei Strukturen von saFabI im Komplex mit NADPH und 2-Pyridon-Inhibitoren. Basierend auf der nun bekannten saFabI-Struktur konnten Molekulardynamik-Simulationen durchgef{\"u}hrt werden, um zus{\"a}tzliche Erkenntnisse {\"u}ber die Flexibilit{\"a}t dieses Proteins zu erhalten. Die so gewonnenen Informationen {\"u}ber die Struktur und Beweglichkeit des Enzyms dienten in Folge als ideale Grundlage daf{\"u}r, den Erkennungsprozess von Substrat und Inhibitor zu verstehen. Besonders bemerkenswert dabei ist, dass die verschiedenen saFabI Kristallstrukturen Momentaufnahmen entlang der Reaktionskoordinate der Ligandenbindung und des Hydrid-Transfers repr{\"a}sentieren. Dabei verschließt der so genannte Substratbindungsloop das aktive Zentrum des Enzyms allm{\"a}hlich. Die außergew{\"o}hnlich hohe Mobilit{\"a}t von saFabI konnte durch molekulardynamische Simulationen best{\"a}tigt werden. Dies legt nahe, dass die beobachteten {\"A}nderungen der Konformation tats{\"a}chlich an der Aufnahme und Umsetzung des Substrates beteiligt sind. Eine Kette von Wassermolek{\"u}len zwischen dem aktiven Zentrum und einer wassergef{\"u}llten Kavit{\"a}t im Inneren des Tetramers scheint f{\"u}r die Beweglichkeit des Substratbindungsloops und somit f{\"u}r die katalysierte Reaktion von entscheidender Bedeutung zu sein. Außerdem wurde die erstaunliche Beobachtung gemacht, dass der adaptive Substratbindungsprozess mit einem Dimer-Tetramer {\"U}bergang gekoppelt ist, welcher die beobachtete positive Kooperativit{\"a}t der Ligandenbindung erkl{\"a}ren kann. Alles in allem weist saFabI im Vergleich zu FabI Proteinen aus anderen Organismen mehrere außergew{\"o}hnliche Eigenschaften auf, die f{\"u}r die Synthese von verzweigten Fetts{\"a}uren n{\"o}tig sein k{\"o}nnten, welche wiederum f{\"u}r die {\"U}berlebensf{\"a}higkeit von S. aureus im Wirt von Bedeutung sind. Diese Erkenntnis k{\"o}nnte erkl{\"a}ren, warum S. aureus selbst bei Anwesenheit von exogenen Fetts{\"a}uren von FAS-II Inhibitoren abget{\"o}tet werden kann. Somit k{\"o}nnen die gewonnenen atomaren saFabI Modelle einen entscheidenden Beitrag zur Entwicklung neuer Hemmstoffe dieses validierten Angriffszieles leisten. Tats{\"a}chlich konnten die neuen Strukturen genutzt werden, um die Bindungsst{\"a}rken sowie die Verweilzeiten verschiedener saFabI Inhibitoren molekular zu erkl{\"a}ren. Die Struktur von saFabI im Komplex mit dem 2-Pyridon Inhibitor CG400549 hingegen enth{\"u}llte spezifische Wechselwirkungen in der geweiteten Bindetasche des S. aureus Enzyms, welche das geringe Aktivit{\"a}tsspektrum dieses derzeit klinisch erprobten Inhibitors erkl{\"a}ren. Diese Studien schaffen somit eine ideale Voraussetzung f{\"u}r die Entwicklung neuer wirksamer saFabI Inhibitoren, was am Beispiel des 4-Pyridons PT166 belegt werden kann. Im Rahmen der vorliegenden Dissertation konnten außerdem die Strukturen des Enzyms KasA im Komplex mit mehreren Derivaten des Naturstoffs Thiolactomycin gel{\"o}st werden.}, subject = {Staphylococcus aureus}, language = {en} } @phdthesis{Mishra2013, author = {Mishra, Shambhavi}, title = {Structural and Functional Characterization of the Enzymes Involved in the Menaquinone Biosynthesis and Benzoate Degradation}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-90848}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2013}, abstract = {The present work illustrates the structural and biochemical characterization of two diverse proteins, BadI and MenD from Rhodopseudomonas palustris and Staphylococcus aureus, respectively. BadI or 2-ketocyclohexanecarboxyl-CoA is one of the key enzymes involved in the anaerobic degradation of aromatic compounds. The degradation of aromatic compounds is a vital process for the maintenance of the biogeochemical carbon cycle and bioremediation of xenobiotic compounds, which if present at higher concentrations can cause potential hazards to humans. Due to the relatively inert nature of aromatic compounds, enzymes catalyzing their degradation are of special interest for industrial applications. BadI is one of the key enzymes involved in the anaerobic degradation of aromatic compounds into an aliphatic moiety. The major focus of this study was to provide mechanistic insights into the reaction catalyzed by BadI. BadI belongs to the crotonase superfamily and shares high sequence homology with the family members of MenB or dihydroxynaphthoate synthase. BadI is known to catalyze the cleavage of the cyclic ring of 2-ketocyclohexane carboxyl-CoA by hydrolyzing the C-C bond leading to the formation of the aliphatic compound pimelyl CoA. On the other hand MenB catalyzes the condensation reaction of o-succinylbenzoyl-CoA to dihydroxylnaphthoyl-CoA. A comprehensive amino acid sequence analysis between BadI and MenB showed that the active site residues of MenB from Mycobacterium tuberculosis (mtMenB) are conserved in BadI from Rhodopseudomonas palustris. MenB is involved in the menaquinone biosynthesis pathway and is a potential drug target against Mycobacterium tuberculosis as it has no known human homologs. Due to the high homology between MenB and BadI and the inability to obtain MenB-inhibitor complex structures we extended our interest to BadI to explore a potential substitute model for mtMenB as a drug target. In addition, BadI possesses some unique mechanistic characteristics. As mentioned before, it hydrolyzes the substrate via a retro Dieckmann's reaction contrasting its closest homolog MenB that catalyzes a ring closing reaction through a Dieckmann's reaction. Nevertheless the active site residues in both enzymes seem to be highly conserved. We therefore decided to pursue the structural characterization of BadI to shed light on the similarities and differences between BadI and MenB and thereby provide some insights how they accomplish the contrasting reactions described above. We determined the first structures of BadI, in its apo and a substrate mimic bound form. The crystal structures revealed that the overall fold of BadI is similar to other crotonase superfamily members. However, there is no indication of domain swapping in BadI as observed for MenB. The absence of domain swapping is quite remarkable because the domain swapped C-terminal helical domain in MenB provides a tyrosine that is imperative for catalysis and is also conserved in the BadI sequence. Comparison of the active sites revealed that the C-terminus of BadI folds onto its core in such a way that the conserved tyrosine is located in the same position as in MenB and can form interactions with the ligand molecule. The structure of BadI also confirms the role of a serine and an aspartate in ligand interaction, thus validating that the conserved active site triad participates in the enzymatic reaction. The structures also reveal a noteworthy movement of the active site aspartate that adopts two major conformations. Structural studies further illuminated close proximity of the active site serine to a water and chlorine molecule and to the carbon atom at which the carbonyl group of the true substrate would reside. Biochemical characterization of BadI using enzyme kinetics validated that the suggested active site residues are involved in substrate interaction. However, the role of these residues is very distinct, with the serine assuming a major role. Thus, the present work ascertain the participation of putative active site residues and demonstrates that the active site residues of BadI adopt very distinctive roles compared to their closest homolog MenB. The MenD protein also referred to as SEPHCHC (2-succinyl-5-enolpyruvyl-6- hydroxy-3-cyclohexene-1-carboxylic acid) synthase is one of the enzymes involved in menaquinone biosynthesis in Staphylococcous aureus. Though S. aureus is usually considered as a commensal it can act as a remarkable pathogen when it crosses the epithelium, causing a wide spectrum of disorders ranging from skin infection to life threatening diseases. Small colony variants (SCVs), a slow growing, small sized subpopulation of the bacteria has been associated with persistent, recurrent and antibiotic resistant infections. These variants show autotrophy for thiamine, menaquinone or hemin. Menaquinone is an essential component in the electron transport pathway in gram-positive organisms. Therefore, enzymes partaking in this pathway are attractive drug targets against pathogens such as Mycobacterium tuberculosis and Bacillus subtilis. MenD, an enzyme catalyzing the first irreversible step in the menaquinone biosynthetic pathway has been implicated in the SCV phenotype of S. aureus. In the present work we explored biochemical and structural properties of this important enzyme. Our structural analysis revealed that despite its low sequence identity of 28\%, the overall fold of staphylococcal MenD (saMenD) is similar to Escherichia coli MenD (ecMenD) albeit with some significant disparities. Major structural differences can be observed near the active site region of the protein and are profound in the C-terminal helix and a loop near the active site. The loop contains critical residues for cofactor binding and is well ordered only in the ecMenD-ThDP structure, while in the apo and substrate bound structures of ecMenD the loop is primarily disordered. In our saMenD structure the loop is for the first time completely ordered in the apo form and displays a novel conformation of the cofactor-binding loop. The loop adopts an unusual open conformation and the conserved residues, which are responsible for cofactor binding are located too far away to form a productive complex with the cofactor in this conformation. Additionally, biochemical studies in conjugation with the structural data aided in the identification of the substrate-binding pocket and delineated residues contributing to its binding and catalysis. Thus the present work successfully divulged the unique biochemical and structural characteristics of saMenD.}, subject = {Benzoate}, language = {en} } @phdthesis{Mietrach2020, author = {Mietrach, Nicole Aline}, title = {Structural and functional elucidation of the Type VIIb secretion system from Staphylococcus aureus}, doi = {10.25972/OPUS-21482}, url = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-214824}, school = {Universit{\"a}t W{\"u}rzburg}, year = {2020}, abstract = {The Type VII secretion system (T7SS) is linked to virulence and long-term pathogenesis in a broad range of Gram-positive bacteria, including the human commensal and pathogen Staphylococcus aureus. The Type VIIb secretion system (T7SSb) is responsible for the export of small toxic proteins, which induce antibacterial immune responses and mediate bacterial persistence in the host. In addition, it is also involved in bacterial competition. The T7SSb requires several proteins to build up the secretion machinery. This work focuses on the structural and functional investigation of the motor ATPase EssC and the putative pore forming, multi-pass membrane component EsaA. Both proteins are indispensable for substrate secretion. EssC belongs to the FtsK/SpoIIIE ATPase family and is conserved among the T7SSs. It contains three C-terminal, cytosolic ATPase domains, designated as EssC- D1, -D2 and -D3, whereby EssC-D3 is the most distal one. In this thesis, I am presenting the crystal structure of the EssC-D3 at 1.7 {\AA} resolution. As the deletion of EssC-D3 abrogates substrate export, I have demonstrated that this domain comprises a hydrophobic, surface-exposed pocket, which is required for substrate secretion. More specifically, I have identified two amino acids involved in the secretion process. In addition, my results indicate that not only EssC-D3 is important for substrate interaction but also EssC-D2 and/or EssC-D1. Unlike in the related Yuk T7SSb of Bacillus subtilis, the ATPase activity of D3 domain contributes to substrate secretion. Mutation of the modified Walker B motif in EssC-D3 diminishes substrate secretion completely. The membrane protein EsaA encompasses an extracellular segment spanning through the cell wall of S. aureus. I was able to reveal that this part folds into a stable domain, which was crystallized and diffracted up to 4 {\AA}. The first attempts to dissolve the structure failed due to a lack of homologues structures. Therefore, crystals for single-wavelength anomalous dispersion, containing selenomethionyl-substitutes, were produced and the structure solution is still in progress. Preliminary experiments addressing the function of the extracellular domain indicate an important role in substrate secretion and bacterial competition.}, subject = {Secretion}, language = {en} }