@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{GarciaBetancur2018,
  author    = {Garcia Betancur, Juan Carlos},
  title     = {Divergence of cell-fates in multicellular aggregates of \(Staphylococcus\) \(aureus\) defines acute and chronic infection cell types},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-148059},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2018},
  abstract  = {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},
  subject      = {Staphylococcus aureus},
  language  = {en}
}
@phdthesis{MielichSuess2018,
  author    = {Mielich-S{\"u}ß, Benjamin},
  title     = {Elucidating structural and functional aspects of prokaryotic membrane microdomains},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-162037},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2018},
  abstract  = {Bacterial functional membrane microdomains (FMMs) are membrane platforms that resemble lipid rafts of eukaryotic cells in certain functional and structural aspects. Lipid rafts are nanometer-sized, dynamic clusters of proteins and lipids in eukaryotic cell membranes that serve as signaling hubs and assembling platforms. Yet, studying these structures can often be hampered by the complexity of a eukaryotic cell. Thus, the analogous structures of prokaryotes are an attractive model to study molecular traits of this type of membrane organization. Similar to eukaryotic lipid rafts, the bacterial FMMs are comprised of polyisoprenoid lipids, scaffold proteins and a distinct set of membrane proteins, involved in signaling or secretion. Investigating bacterial FMMs not only contributes to the understanding of the physiological importance of FMMs in bacteria, but also helps to elucidate general principles of rafts beyond prokaryotes. In this work, a bacterial model organism was used to investigate effects of synthetic overproduction of the raft scaffolding proteins on bacterial physiology. This overexpression causes an unusual stabilization of the FMM-harbored protease FtsH and therefore the proteolytic targets of FtsH are not correctly regulated. Developmental defects and aberrances in shape are the consequence, which in turn negatively affects cell physiology. These findings may be adapted to better understand lipid raft processes in humans, where flotillin upregulation is detected along with development of neurological diseases. Moreover, it was aimed at understanding the FMM-proteome of the human pathogen Staphylococcus aureus. An in-depth quantitative mass-spectrometry analysis reveals adaption of the protein cargo during different conditions, while maintaining a distinct set of core FMM proteins. As a case study, the assembly of the type VII secretion system was shown to be dependent on FMM integrity and more specifically on the activity of the FMM-scaffold flotillin. This secretion system is important for the virulence of this pathogen and its secretion efficiency can be targeted by small molecules that inhibit flotillin activity. This opens new venues for non-conventional antimicrobial compounds to treat staphylococcal infections.},
  subject      = {Staphylococcus aureus},
  language  = {en}
}
@phdthesis{Koziol2014,
  author    = {Koziol, Uriel},
  title     = {Molecular and developmental characterization of the Echinococcus multilocularis stem cell system},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-105040},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2014},
  abstract  = {The metacestode larva of Echinococcus multilocularis is the causative agent of alveolar echinococcosis (AE), one of the most dangerous zoonotic diseases in the Northern Hemisphere. Unlike "typical" metacestode larvae from other tapeworms, it grows as a mass of interconnected vesicles which infiltrates the liver of the intermediate host, continuously forming new vesicles in the periphery. From these vesicles, protoscoleces (the infective form for the definitive host) are generated by asexual budding. It is thought that in E. multilocularis, as in other flatworms, undifferentiated stem cells (so-called germinative cells in cestodes and neoblasts in free-living flatworms) are the sole source of new cells for growth and development. Therefore, this cell population should be of central importance for the progression of AE. In this work, I characterized the germinative cells of E. multilocularis, and demonstrate that they are indeed the only proliferating cells in metacestode vesicles. The germinative cells are a population of undifferentiated cells with similar morphology, and express high levels of transcripts of a novel non-autonomous retrotransposon family (ta-TRIMs). Experiments of recovery after hydroxyurea treatment suggest that individual germinative cells have extensive self-renewal capabilities. However, germinative cells also display heterogeneity at the molecular level, since only some of them express conserved homologs of fgfr, nanos and argonaute genes, suggesting the existence of several distinct sub-populations. Unlike free-living flatworms, cestode germinative cells lack chromatoid bodies. Furthermore, piwi and vasa orthologs are absent from the genomes of cestodes, and there is widespread expression of some conserved neoblast markers in E. multilocularis metacestode vesicles. All of these results suggest important differences between the stem cell systems of free-living flatworms and cestodes. Furthermore, I describe molecular markers for differentiated cell types, including the nervous system, which allow for the tracing of germinative cell differentiation. Using these molecular markers, a previously undescribed nerve net was discovered in metacestode vesicles. Because the metacestode vesicles are non-motile, and the nerve net of the vesicle is independent of the nervous system of the protoscolex, we propose that it could serve as a neuroendocrine system. By means of bioinformatic analyses, 22 neuropeptide genes were discovered in the E. multilocularis genome. Many of these genes are expressed in metacestode vesicles, as well as in primary cell preparations undergoing complete metacestode regeneration. This suggests a possible role for these genes in metacestode development. In line with this hypothesis, one putative neuropeptide (RGFI-amide) was able to stimulate the proliferation of primary cells at a concentration of 10-7 M, and the corresponding gene was upregulated during metacestode regeneration.},
  subject      = {Fuchsbandwurm},
  language  = {en}
}
@phdthesis{Schneider2015,
  author    = {Schneider, Johannes},
  title     = {Functional diversification of membrane microdomains in Bacillus subtilis},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-127569},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2015},
  abstract  = {Eukaryotic cells are considered as evolutionary complex organisms because they possess organelles that enable them to regulate the spatio-temporal organization of cellular processes. Spatio-temporal organization of signal transduction cascades occurs in eukaryotic cells via organization of membrane-associated microdomains or lipid rafts. Lipid rafts are nanoscale-sized domains in the plasma membrane that are constituted by a specific set of lipids and proteins and harbor a number of proteins related to signal transduction and trafficking. The integrity of lipid rafts is important for the assembly and functional coordination of a plethora of signaling networks and associated processes. This integrity is partially mediated by a chaperone protein called flotillin. Disruption of lipid raft integrity, for example via depletion or overproduction of flotillin, alters raft-associated signal transduction cascades and causes severe diseases like Alzheimer's, Parkinson's disease or cardiovascular disease. It was traditionally assumed that a sophisticated compartmentalization of cellular processes like the one exhibited in lipid rafts was exclusive to eukaryotic cells and therefore, lipid rafts have been considered as a hallmark in the evolution of cellular complexity, suggesting that prokaryotic cells were too simple organisms to organize such sophisticated membrane platforms. However, it was recently discovered that bacteria are also able to organize Functional Membrane Microdomains (FMMs) in their cellular membrane that are able to organize and catalyze the functionality of many diverse cellular processes. These FMMs of bacterial membranes contain flotillin-like proteins which play important roles in the organization of FMM-associated cellular processes. In this dissertation I describe the structural and biological significance of the existence of two distinct flotillin proteins, FloA and FloT, in the FMMs of the bacterial model Bacillus subtilis. Localization studies, proteomic data and transcriptomic analyses show that FloA and FloT are individual scaffold proteins that activate different regulatory programs during bacterial growth. Using the tractable bacterial model system, I show that the functionality of important regulatory proteins, like the protease FtsH or the signaling kinases KinC, PhoR and ResE, is linked to the activity of FMMs and that this is a direct consequence of the scaffold activity of the bacterial flotillins. FloA and FloT distribute heterogeneously along the FMMs of B. subtilis thereby generating a heterogeneous population of FMMs that compartmentalize different signal transduction cascades. Interestingly, diversification of FMMs does not occur randomly, but rather in a controlled spatio-temporal program to ensure the activation of given signaling networks at the right place and time during cell growth.},
  subject      = {Heubacillus},
  language  = {en}
}
@phdthesis{Wagner2021,
  author    = {Wagner, Rabea Marie},
  title     = {The Bacterial Exo- and Endo-Cytoskeleton Spatially Confines Functional Membrane Microdomain Dynamics in \(Bacillus\) \(subtilis\)},
  doi       = {10.25972/OPUS-21745},
  url       = {http://nbn-resolving.de/urn:nbn:de:bvb:20-opus-217458},
  school      = {Universit{\"a}t W{\"u}rzburg},
  year      = {2021},
  abstract  = {Cellular membranes form a boundary to shield the inside of a cell from the outside. This is of special importance for bacteria, unicellular organisms whose membranes are in direct contact with the environment. The membrane needs to allow the reception of information about beneficial and harmful environmental conditions for the cell to evoke an appropriate response. Information gathering is mediated by proteins that need to be correctly organized in the membrane to be able to transmit information. Several principles of membrane organization are known that show a heterogeneous distribution of membrane lipids and proteins. One of them is functional membrane microdomains (FMM) which are platforms with a distinct lipid and protein composition. FMM move within the membrane and their integrity is important for several cellular processes like signal transduction, membrane trafficking and cellular differentiation. FMM harbor the marker proteins flotillins which are scaffolding proteins that act as chaperones in tethering protein cargo to FMM. This enhances the efficiency of cargo protein oligomerization or complex formation which in turn is important for their functionality. The bacterium Bacillus subtilis contains two flotillin proteins, FloA and FloT. They form different FMM assemblies which are structurally similar, but differ in the protein cargo and thus in the specific function. In this work, the mobility of FloA and FloT assemblies in the membrane was dissected using live-cell fluorescence microscopy techniques coupled to genetic, biochemical and molecular biological methods. A characteristic mobility pattern was observed which revealed that the mobility of both flotillins was spatially restricted. Restrictions were bigger for FloT resulting in a decreased diffusion coefficient compared to FloA. Flotillin mobility depends on the interplay of several factors. Firstly, the intrinsic properties of flotillins determine the binding of different protein interaction partners. These proteins directly affect the mobility of flotillins. Additionally, binding of interaction partners determines the assembly size of FloA and FloT. This indirectly affects the mobility, as the endo-cytoskeleton spatially restricts flotillin mobility in a size-dependent manner. Furthermore, the extracellular cell wall plays a dual role in flotillin mobility: its synthesis stimulates flotillin mobility, while at the same time its presence restricts flotillin mobility. As the intracellular flotillins do not have spatial access to the exo-cytoskeleton, this connection is likely mediated indirectly by their cell wall-associated protein interaction partners. Together the exo- and the endo-cytoskeleton restrict the mobility of FloA and FloT. Similar structural restrictions of flotillin mobility have been reported for plant cells as well, where the actin cytoskeleton and the cell wall restrict flotillin mobility. These similarities between eukaryotic and prokaryotic cells indicate that the restriction of flotillin mobility might be a conserved mechanism.},
  subject      = {Heubacillus},
  language  = {en}
}