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Cardiovascular diseases are the most common cause of death in industrial nations. The basis of these diseases is a dysfunction in the interaction between the cells the heart is composed of. The main types of cells making up the human heart are cardiomyocytes that build the myocardium and provide the contraction properties, endothelial cells that delimit the blood flowing through the inner chambers and coronary arteries from the myocardial tissue, and fibroblasts, which build the connective tissue. A common process in the development of cardiovascular diseases is the formation of fibrosis due to injury of the endothelium and subsequent infiltration of the cardiac tissue by immune cells, and inflammatory agents like cytokines. Cytokines exert different functions in cardiac cells. Tumor necrosis factor α (TNFα) is an inducer of apoptosis. Transforming growth factor ß (TGFß) is known for activation of proliferation. Other cytokines like C-X-C motif chemokine 11 (CXCL11), interleukin-6 (IL-6), or brain-derived neurotrophic factor (BDNF) have not yet been investigated or their impact on such cells is unknown. Eventually, however, fibrotic scar tissue arises from the transition from fibroblasts to myofibroblasts leading to a stiffening of the cardiac muscle and impaired pump function. In order to prevent the occurrence of these events the balance of proliferation, migration, and differentiation of cardiac cells needs to be controlled very delicately.
The mechanisms controlling these interactions are still not well understood, which is why this work aimed at the elucidation of molecular mechanisms within the three main cell types that might play a role in the regulation of cardiac function. A proteomic approach using mass spectrometry was used to identify alterations in protein levels that could provide hints about the involved pathways and find new players as candidates for more detailed investigation. Initially, the proteomic composition of HL-1 cardiomyocytes, L929 fibroblasts, and human umbilical vein endothelial cells (HUVECs) that were cultivated in standard growth conditions without stress was investigated. Half of the total protein intensity was made up by only 42 to 53 proteins, depending on the cell type. More than a third of all proteins were identified in all three cell types, which may be proteins performing common cell functions. Indeed, the proteins displaying the highest abundance seem to be predominantly involved in such common cellular functions as the regulation of glucose metabolism or the cytoskeleton. More specific functions like heart development and muscle contraction were found enriched in cardiomyocytes as were mitochondrial proteins. The proportion of proteins with extracellular localization and function was higher in fibroblasts and endothelial cells.
Secondly, the impact of cytokines on the proliferative behavior and the proteomic composition of cardiomyocytes and fibroblasts was analyzed. HL-1 cardiomyocytes and L929 fibroblasts were treated with different concentrations of cytokines with a cytotoxic, proliferative, or yet unknown effect on these cells. While HL-1 cells exhibited no macroscopic reaction to any of the cytokines used, cytotoxic/growth inhibitory (TNFα, CXCL11) and proliferative (TGFß, IL6, BDNF) effects were observed for L929 cells. The latter also showed CXCL11-induced upregulated EIF2 signaling, pointing to a higher need of protein synthesis.
The third aim was the examination of proteome adaptations in endothelial cells due to different kinds of stress, as these cells are the first line of defense against inflammatory agents or injury and therefore prone to wounding. The role of the growth factors vascular endothelial growth factor (VEGF) and basic fibroblast growth factor (bFGF) in wounding and starvation was another object of this study as they are known for their angiogenic and cell survival supporting properties. Additionally, the impact of the cellular sex on the response to stress and growth factors was examined, because a person’s sex plays an important role in susceptibility, risk factors, and outcome of cardiovascular diseases. This has mainly been attributed to the different hormone levels, especially the higher levels of estrogen in premenopausal women, which exerts cardioprotective properties, but also genetic background was reported to play an important role. Only few studies that examined the molecular properties of HUVECs considered the cellular sex and if so, the genetic bias of unrelated samples was not taken into account. This is why Lorenz and colleagues at the Charité in Berlin collected HUVECs from newborn twins of opposite sex, cultivated them without stress in standard growth medium, exposed them to wounding and serum starvation, and investigated the impact of the growth factors and the sex on migrational behavior and metabolic issues. The current work focused on the alterations of not only the intra- but also the extracellular proteome, because paracrine signaling is crucial for intercellular communication in order to cope with stress. General differences between male and female cells were observed for proteins encoded on the X chromosome with higher levels in females (DDX3X, UBA1, EIF1AX, RPS4X, HDHD1), except for one protein with higher levels in male cells (G6PD). A Y-chromosomal protein was, for the first time, identified in endothelial cells (DDX3Y). Wounding, starvation, and growth factor treatment led to alterations and sex-specific different levels in an unexpectedly high number of proteins, with VEGF showing a stronger impact than bFGF. Many proteins with alterations observed without taking the sex into account, were actually only changed in male or female cells. Some proteins were regulated in opposite directions, or growth factors inhibited their secretion in a sex-specific way by unknown mechanisms. Tissue factor pathway inhibitor 2 (TFPI2) should be emphasized as a protein with sex-specific differences, especially in the extracellular space and with increased levels after starvation and VEGF treatment. These observations suggest a temporal lack in TFPI2 synthesis and secretion in male cells, which might explain the enhanced adaptation of females to wounding.
The results of this work lay the basis for future investigation by providing a database of intra- and extracellular proteome changes due to different environmental circumstances. It strongly suggests the investigation of male and female HUVECs, and other cells, separately to avoid the impact of the sex observed in this work. Essentially, the observations suggest a number of candidate proteins for more detailed investigations of endothelial and cardiovascular diseases.
Class I and class II glutaredoxins (Grxs) are glutathione (GSH)-dependent proteins, that function as oxidoreductases (class I) or mediate cellular iron trafficking (class II). Some members of class I Grxs like human Grx2 are able to complex a [2Fe-2S] cluster and form a dimeric holo complex, which renders them catalytically inactive and is the basis for their function as redox sensors. Class II Grxs like human Grx5 also complex [2Fe-2S] clusters, however these proteins transfer the clusters to other proteins. Both functionally distinct classes share a similar thioredoxin fold and conserved interaction sites for the non-covalently binding of GSH, which is required to complex the [2Fe-2S] cluster. Furthermore, the proteins from both classes contain a highly nucleophilic active site cysteine that would allow both classes to catalyze GSH-dependent oxidoreduction reactions. Despite of these similar features, only class I Grxs are able to form a mixed disulfide with GSH and to reversibly transfer it to protein thiols (de-/glutathionylation). Interestingly, neither class I Grxs nor class II Grxs can effectively compensate the loss of an essential member of the other class. Even though some structural differences were described earlier, the basis for their different functions remained unknown. In particular, the lack of catalytic activity of class II Grxs as oxidoreductases could not be explained. Here, we demonstrate that the different conformations of a conserved lysyl side chain are the molecular determinant of the oxidoreductase or Fe-S transfer activity of class I and II Grxs, respectively. A specific loop structure that is conserved in all class II Grxs determines one lysyl conformation that prevents the formation of a mixed disulfide of the active site cysteinyl thiol with GSH. Using engineered mutants of hGrx2 and hGrx5, we demonstrated that the exchange of the distinct loop between the classes results in a loss of oxidoreductase function of class I hGrx2 and the gain of oxidoreductase activity of class II hGrx5. The altered GSH binding mode also profoundly changes the [2Fe-2S] cluster binding of the engineered mutants and thereby also influences stability of the holo complexes, a pre-determinant for [Fe-S] cluster transfer activity. With the minor shift of 2 Å in a conserved lysyl side chain orientation we were not only able to modify the catalytic activity of two small human mitochondrial proteins, but on a much larger scale also provided evidence for the previously unknown structural basis that determines the function of all class I and class II Grxs.
The oxidoreductase activity of hGrx2 was also analyzed in vivo in a model of doxorubicin cell toxicity. Applying a mass spectrometrical approach, we identified various mitochondrial proteins as targets for redox regulation. Furthermore, our results gave reason to reconsider some common assumptions regarding doxorubicin-induced apoptosis and the protective function of mitochondrial Grx2.
Staphylococcus aureus is a commensal that colonizes the skin and mucosa of 20-30% of the human population without leading to symptoms of diseases. However, it is also the most important cause of nosocomial infections. Those range from minor skin infections to life-threatening diseases such as pneumonia, endocarditis or septicaemia. Development of strains with resistance against many antibiotics complicates the situation further. The variety of strains with their various properties is one reason why no successful vaccine has been introduced to the market, yet. Therefore, efficient strategies for prevention and therapy of these dangerous infections are urgently needed. To accomplish these goals, the understanding of molecular interactions between host and pathogen is indispensable. Within this dissertation, several internalization experiments were performed aiming to investigate the interaction of S. aureus HG001 and human cell lines upon infection on the protein level. In order to obtain sufficient amounts of proteins for comprehensive physiological interpretations, it is necessary to enrich bacteria, secreted bacterial proteins or infected host cells upon internalization. In the framework of this thesis, bacteria which continuously produce green fluorescent protein (GFP) were employed. With that it was possible to sort bacteria from lysed host cells by flow cytometry or to separate host cells carrying bacteria after contact from those which did not. Subsequently, the proteins were proteolytically digested and peptides were analyzed by mass spectrometry in a gel-free proteomics approach. To allow such analyses also for staphylococci which do not produce GFP, such as clinical isolates, an additional protocol was developed. Prior to the infection, bacteria were labeled with fluorescent or para-magnetic nanoparticles. Afterwards bacteria could be separated from host cell debris by fluorescence-based cell sorting or with the help of a strong magnet. In order to cover also important secreted virulence factors of S. aureus HG001, phagosomes and engulfed bacteria and secreted proteins were isolated from infected host cells. Further steps of protocol optimization included improved bacterial cell counting by fluorescence-based flow cytometry, enhanced data analysis by combination of different search algorithms, and comprehensive functional annotation of proteins of the applied strain by sequence comparison with other strains and organisms. First, the proteome adaptation of internalized S. aureus HG001 and the infected A549 host cells was investigated during the first hours of infection. It became clear, that the bacteria replicate inside the host during the first 6.5 h. After internalization the levels of bacterial enzymes involved in protein biosynthesis decreased. Furthermore, bacteria adapted their proteome to the harsh intracellular conditions such as oxygen limitation, cell wall stress, host defense in terms of oxidative stress, and nutrient limitation. After contact to S. aureus HG001, A549 cells produced increased amounts of cytokines (e.g. IL-8, IFN-γ) in comparison to non-treated A549 cells. In addition, activation of the immunoproteasome and hints of early apoptosis activity were observed. Afterwards, the response of S. aureus HG001 to internalization by A549, S9 or HEK 293 cells was compared on the proteome level. It was obvious, that the adaptation to stress and the reduced protein synthesis are conserved mechanisms. Host dependent differences were detected especially in the energy metabolism and the synthesis of some amino acids. Additionally, bacteria showed different intracellular replication patterns depending on the host cell line. A higher percentage of extracellular bacterial proteins was found in isolated phagosomes compared to the sorted samples. Selected low abundant virulence factors could be quantified at two points in time after infection with the help of the sensitive single reaction monitoring (SRM) method. Further, a heterogeneous mixture of several phagosomal maturation steps was present during the first 6.5 h after infection. Finally, the gel-free proteome analyses could be applied to investigate Bordetella pertussis, the cause of whooping cough, during iron limitation and after internalization, and the results were compared to the S. aureus HG001 data.
Mechanically ventilated patients are at risk of ventilator-associated pneumonia, a serious infection of the lungs. Not every ventilated patient develops pneumonia due to a combination of the protective layer of mucus in the airways, the immune system and prophylactic antibiotic therapy. To date, only little was known about the antimicrobial factors produced by humans that protect the lungs against infection. Research described in this thesis was therefore aimed at investigating to what extent the lungs of ventilated patients can inhibit the growth of bacteria, the major causative agent of pneumonia Streptococcus pneumoniae in particular. To this end, the accumulated mucus in the patients’ lungs, sputum, was investigated. The most important conclusion was that sputum can indeed possess antimicrobial activity, explained either by a combination of antibiotics and S. pneumoniae-specific antibodies, or by the innate immune defenses. Thus, sputum may serve as a valuable source of information to unravel the complex interactions between the human host, antimicrobial factors and the microbiome of the lower respiratory tract. A possible consequence of pneumonia is the dissemination of bacteria from the lungs to the bloodstream and the brain, which may lead to meningitis. This thesis describes how this process takes place, and how the so-called choline-binding protein CbpL contributes to invasive pneumococcal infections. In addition, possible future approaches to prevent meningitis caused by this bacterium are proposed.
Clostridium (C.) difficile ist beim Menschen ein bedeutender Erreger von Krankenhaus-assoziierten Durchfallerkrankungen. Die vorliegende Dissertation umfasst die Erhebung und Analyse der ersten epidemiologischen Daten zu C. difficile in deutschen Heim- und Nutztierbeständen und die Entwicklung eines neuartigen DNA-Microarrays, der eine einfache Ribotypisierung von C. difficile ermöglicht. In drei Studien wurden Kotproben von Hunden, Katzen, Ferkeln und Kälbern kulturell auf C. difficile untersucht. Das Bakterium wurde aus 5 von 135 Katzenkot- (3,7%), 9 von 165 Hundekot- (5,4%), 176 von 999 Kälberkot- (17,6%) und 147 von 201 Schweinekotproben (73,1%) isoliert. Neugeborene Ferkel und Kälber waren in den ersten 2 bzw. 3 Lebenswochen signifikant häufiger kulturpositiv für C. difficile als ältere Tiere. Die in den Studien isolierten Stämme wurden 25 Ribotypen zugeordnet; darunter befanden sich 6 bisher nicht beschriebene Varianten. Bei den Ferkelproben dominierten die einander sehr ähnlichen Ribotypen 078 (55% der Isolate) und 126 (20%). Die Ribotypen 033 (57% der Isolate) und 078 (17%) wurden bei Kälbern am häufigsten vorgefunden. Basierend auf ihren Typisierungsprofilen wurden die Ribotypen in einer UPGMA-Analyse (Unweighted Pair Group Method with Arithmetic mean) untereinander verglichen. Von den 25 bei den untersuchten Tieren gefundenen Ribotypen formten 11 einen Cluster, zu dem auch die Ribotypen 033, 078 und 126 gehörten und in dem sich 90% aller in den beiden Nutztierstudien isolierten Stämme wiederfanden. Alle Isolate dieses Clusters waren zudem PCR-positiv für ein binäres Toxin und, im Gegensatz zu allen nicht zu dem Cluster gehörenden Ribotypen, PCR-negativ für den MLVA-Lokus A6Cd. Hierdurch, aber auch durch frühere Studien, in denen gezeigt werden konnte, dass die dem Cluster zugeordneten Ribotypen 033, 045, 078 und 126 den gleichen MLST-Typ (ST-11, Multilocus Sequence Typing) und eine charakteristische Deletion (delta 39 bp) im Toxinregulatorgen tcdC aufweisen, wird die These einer genetische Verwandtschaft unterstützt. In allen untersuchten Tierpopulationen wurden Ribotypen gefunden, die mit C.-difficile-Infektionen des Menschen assoziiert werden. Da Stämme des Ribotyps 078 in deutschen und europäischen Krankenhäusern zunehmend häufiger als Ursache von Durchfallerkrankungen auftreten, wurden alle ermittelten MLVA-Daten von Ribotyp-078-Stämmen humanen und tierischen Ursprungs mit entsprechenden Daten anderer Studien aus 5 europäischen Ländern verglichen. In einer hierbei durchgeführten Minimum-Spanning-Tree-Analyse mit 294 Datensätzen wurde die genetische Abgrenzung von MLVA-Typen unterschiedlicher geographischer Herkunft verdeutlicht und belegt, dass einige aus Tieren und Menschen isolierte C.-difficile-Stämme sehr ähnlichen oder sogar identischen MLVA-Typen entsprechen. Die in den Haus- und Nutztierstudien isolierten C. difficile wurden anschließend mit dem neu entwickelten DNA-Microarray ribotypisiert. Das Sondendesign des Microarrays basiert auf der bei C. difficile modular aufgebauten Intergenic Spacer Region (ISR), welche auch Zielstruktur der herkömmlichen Ribotypisierungsmethoden ist. Die Sonden wurden von in der GenBank-Datenbank publizierten ISR-Modulsequenzen und theoretisch möglichen Modulsequenzkombinationen abgeleitet. Nachdem die Eignung des Arrays in theoretisch und praktisch durchgeführten Experimenten belegt werden konnte, wurde mit 142 repräsentativ ausgewählten C.-difficile-Stämmen eine 48 Ribotypen umfassende Datenbank aus Referenzhybridisierungsmustern erstellt. Diese Referenzmuster wurden anschließend in einer Ähnlichkeitsmatrix-Analyse untereinander verglichen, wobei 27 Referenzmuster eindeutig differenziert werden konnten. Zu den gut unterscheidbaren Ribotypen gehörten u.a. die häufig mit humanen C.-difficile-Infektionen assoziierten Ribotypen 001, 014/020, 027 und 078/126. Nicht unterscheidbar hingegen waren die 11 Ribotypen des oben beschriebenen Clusters, wodurch sich die These ihrer molekularen Verwandtschaft weiter erhärtet. Die Praxistauglichkeit des DNA-Microarrays wurde abschließend in einer Anwendungsstudie überprüft. Hierbei wurden 50 C.-difficile-Stämme, die im Rahmen eines anderen Projektes aus Kotproben von Haustieren und deren Besitzern isoliert wurden, mit herkömmlicher und DNA-Microarray-basierter Ribotypisierung vergleichend untersucht. Berücksichtig man, dass durch den Microarray einige sehr ähnliche Ribotypen derzeit noch nicht unterschieden werden können, wurden alle Isolate dem richtigen Ribotypen bzw. der richtigen Ribotypengruppe zugeordnet. Darüber hinaus wurden 6 für das Microarray unbekannte Ribotypen korrekt als „neu“ und klar voneinander unterscheidbar erkannt. Zusammenfassend trägt das Dissertationsprojekt zum Verständnis über das Vorkommen von C.-difficile-Genotypen in Heim- und Nutztierbeständen bei und präsentiert einen neuartigen DNA-Microarray zur einfachen Ribotypisierung von C. difficile.
Staphylococcus aureus is one of the commonly encountered bacteria of the human microbiome. Although mostly a seemingly harmless commensal microbe, S. aureus can act as an invasive pathogen with seriously devastating effects on its host’s health and wellbeing. A wide range of infections caused by this bacterium has been reported to affect diverse parts of the human body, including the skin, soft tissues and bones, as well as important organs like the heart, kidneys and lungs. Particularly, S. aureus is infamous for being a major causative agent of respiratory tract infections that may escalate up to necrotizing pneumonia. Due to its clinical relevance, this pathogen has been intensively studied for many years. Nonetheless, further research in this field is still needed, because of the high capacity of S. aureus to evolve drug resistance, its high genomic plasticity and adaptability and, not in the last place, the plethora of niches within the human body where it can thrive and survive. In this regard, there are still many uncertainties concerning the specific adaptations carried out by S. aureus during colonization and infection of the human body, the transition between both stages, and upon the invasion of different types of host cells. To shed more light on some of these adaptations, the research described in this thesis has employed in vitro models of infection that mimic particular conditions during the infectious process with special focus on the lung epithelium. The adaptations displayed by S. aureus were monitored using advanced proteomics. Furthermore, the analyses documented in this thesis included S. aureus strains with diverse backgrounds and epidemiology to take into account the genetic diversity encountered in this species.
Bacteria are an integral part of modern biotechnology. They are used to make a variety of products, such as foods, drugs, as well as a multitude of chemicals. In order to increase their production rates molecular biotechnology offers many tuning points, starting from the selection of an applicable host, over its geno- and phenotypical characterization, followed by genetic manipulations for an optimized metabolism and stabilisation of production processes. This work comprises the optimization of Bacillus subtilis as an expression system. It describes the steps taken for selection and genomic characterization of the B. subtilis wild type strain ATCC 6051, the subsequent optimizations of the strain in respect to growth and productivity, as well as the characterization of its behaviour in a variety of cultivation conditions. The B. subtilis strain most commonly found in laboratories around the world is the first sequenced Gram-positive organism B. subtilis 168. Zeigler et al. showed that strain 168 is not a real wild type. Instead it was created through random mutagenesis with X-rays and selected for transformability. This strain has been used as the basis for popular B. subtilis strains in heterologous gene expression such as the extracellular protease deficient WB strains. Growth experiments showed the real wild type strain ATCC 6051 to be superior to its mutated ancestor 168, making it a solid basis for the construction of an optimized B. subtilis expression system. In order to gain a full understanding of the genomic and corresponding physiological differences between the two systems, B. subtilis ATCC 6051 was sequenced and compared to the genome of B. Subtilis 168. Several variations on geno- and phenotypic level could be revealed, that resulted in particular from genes involved in natural competency, the metabolism of amino acids and chemotaxis. This genomically well characterized B. subtilis ATCC 6051 was improved in respect to its application as an expression host. Improvements were achieved through the inactivation of both sporulation and reduction of autolysis, leading to a more robust behaviour during the overproduction and secretion of a reporter enzyme. A positive effect on the activity of an acetoin induced promoter by the addition of second copies for its transcription factors SigmaL and AcoR could be observed. Anaerobic zones and areas with excess glucose caused by insufficient mixing are common conditions in large scale bioprocesses and lead to oscillating conditions for the cells. In turn, this oscillation provokes an excretion of so called overflow metabolites, which can negatively affect the bacterial productivity. Detailed scientific characterizations of industrial scale processes under such oscillating conditions are scarce due to the high costs and logistics involved. A B. Subtilis sporulation mutant was thus examined in respect to its extra- and intracellular metabolites in a scale-down, two-compartment reactor giving hints about conditions the host is exposed to and how it reacts. To improve tolerance thresholds and utilization capacity for such metabolites in B. subtilis, the glyoxylate cycle was transferred from its close relative Bacillus licheniformis into the genome of B. subtilis. This feature enabled our B. subtilis ACE mutant to grow on acetate. The improved strain showed higher tolerance towards excess glucose in a fed-batch as well as higher productivity during the expression of a reporter enzyme in comparison to the wild type. The ACE strain and B. licheniformis showed an increased formation of glycolate during growth with the glyoxylate cycle. This with regard to bacteria undescribed metabolite seems to play a role as a by-product of the glyoxylate cycle. Summarizing, this thesis deals with the characterization and optimization of B. subtilis for growth on overflow metabolites, enhancements of the acoA-expression system and the influence of sporulation and lysis mutants on its activity. Complementary, the host was begun to be characterized in respect to its behaviour in industrial scale processes.
Symbiotic interactions are a key element of biological systems. One powerful strategy to gain insight into these interactions, and into biological systems in general, is the analysis of proteins expressed in situ using metaproteomics. In this thesis, host-microbe interactions in two mutualistic associations between chemosynthetic sulfur-oxidizing endosymbionts and marine invertebrates, the deep-sea tubeworm Riftia pachyptila and the shallow-water clam Codakia orbicularis, were studied by adapted and optimized metaproteomics methods.
The Riftia symbiosis, which inhabits hydrothermal vents in the deep sea, and in which the host completely depends on its symbiont for nutrition, has fascinated researchers for about four decades. Yet, the interaction mechanisms between both partners have been understudied so far. Additionally, while different aspects of the host’s biology have been described, a comprehensive analysis has been lacking. Moreover, although only one symbiont 16S rRNA phylotype is present in Riftia, the symbiont population of the same host expresses proteins of various redundant or opposed metabolic pathways at the same time. As the symbionts also exhibit a wide variety in size and shape, symbionts of different size might have dissimilar physiological functions, which remained as of now to be elucidated. In this thesis, we addressed both, the host-symbiont interaction mechanisms, and physiological roles of symbiont subpopulations. A comprehensive Riftia host and symbiont protein database was generated as prerequisite for metaproteomics studies by de novo sequencing the host’s transcriptome and combining it with existing symbiont protein databases. This database was then used for metaproteomics comparisons of symbiont-containing and symbiont-free Riftia tissues, to gain insights into host-symbiont interactions on the protein level. The impact of energy availability on host-symbiont interactions was studied by comparing specimens with stored sulfur (i.e., high energy availability) with specimens in which sulfur storages were depleted. We employed optimized liquid chromatography peptide separation to increase metaproteome coverage. With this analysis, we identified proteins and mechanisms likely involved in maintaining the symbiosis, under varying environmental conditions. We unraveled key interaction mechanisms, i.e.: (i) the host likely digests its symbionts using abundant digestive enzymes, and, at the same time, (ii) a considerable part of the worm’s proteome is involved in creating stable internal conditions, thus maintaining the symbiont population. Furthermore, (iii) the symbionts probably employ eukaryote-like proteins to communicate with the host. (iv) Under conditions of restricted energy availability, the host apparently increases digestion pressure on the symbiotic population to sustain itself.
Riftia symbionts of different size apparently have dissimilar metabolic roles, as revealed in this thesis. We enriched symbionts of different sizes using gradient centrifugation. These enrichments were subjected to protein extraction using a protocol optimized for the small sample amount available. Metaproteomics analysis included a gel-based workflow and evaluation of the complex dataset with machine learning techniques. Based on our metaproteomics study, we propose that Riftia symbionts of different cell size correspond to dissimilar physiological differentiation stages. Smaller cells are apparently engaged in cell differentiation and host interactions. Larger cells, on the other hand, seem to be more involved in synthesis of various organic compounds. Supposedly, in large symbionts endoreduplication cycles lead to polyploidy. Our results indicate that the Riftia symbiont employs a large part of its metabolic repertoire at the same time in the stable host environment.
The symbiont of the shallow-water clam Codakia orbicularis, which, like the Riftia symbiont, relies on reduced sulfur compounds as energy source and fixes inorganic carbon, is, unexpectedly, also able to fix atmospheric nitrogen, as shown by metaproteomic, genomic and biochemical analysis. Potentially, this benefits the host, as Codakia digests its symbiont and might thus supplement its diet with organic nitrogen fixed by the symbionts in addition to organic carbon in its nitrogen-poor seagrass habitat.
Lipoproteins of Staphylococcus aureus represent a major class of surface proteins, which are anchored to the outer leaflet of the cell membrane. Although they play a key role in the immune response and virulence, the majority of lipoproteins in this organism is still of unknown function. The aim of our study was to investigate the function of so far poorly or uncharacterized lipoproteins in S. aureus strain Newman. To this end, an integrated bioinformatical approach was applied to define the pan-lipoproteome of 123 completely sequenced S. aureus strains. In total, this analysis predicted 192 different potential lipoproteins, with a core lipoproteome of 39 and a variable lipoproteome of 153 lipoproteins. Out of those 192 lipoproteins, 141 are so far functionally uncharacterized. Primarily focusing on members of the core-lipoproteome with unknown or poorly characterized function, 24 lipoproteins or co-encoded neighbor proteins were selected for further characterization. Of those 24 proteins, 20 S. aureus markerless deletion mutants were constructed (S. aureus delta l01 - delta l20) and screened for an altered growth behavior under various conditions. Here, three mutants showed a temperature-sensitive phenotype, two mutants formed aggregates in the TSB of the manufacturer Merck (TSBMerck), and four mutants showed reduced growth under osmotic stress with 8% NaCl. An altered aggregation behavior was observed for four mutants in the presence of Triton X-100 and for eleven mutants in the presence of SDS. Furthermore, ten mutants revealed an impaired biofilm formation capacity as well as reduced hemolytic activity. Interestingly, S. aureus deletion mutants delta l14 (delta NWMN_1435) and delta l16 (delta NWMN_0646) showed an altered phenotype under nearly all tested growth and stress conditions. Most strikingly, both deletion mutants demonstrated dramatic defects in cell morphology and cell division during the transient growth phase in TSBMerck and were therefore selected for further detailed characterization. Electron microscopy imaging of the two mutants revealed an irregular cell shape, increased cell size, multiple displaced division septa, and incomplete separation of daughter cells resulting in the formation of cell aggregates in TSBMerck. Complementarily, microarray-based transcriptome analysis and whole-genome sequencing of S. aureus delta l14 and delta l16 suppressor mutants strongly point to a functional association of both lipoproteins with cell envelope- or cell division-related processes. Specifically, multiple hints suggest a functional connection of both lipoproteins with lipo- or wall teichoic acids. Of note, the phenotypes of S. aureus delta l14 and delta l16 are conditional and appear under some, but not all growth conditions. Thus, it is conceivable that the function of L14 and L16 is modulated by metabolic processes, or that the proteins might be part of a “backup system” becoming important only under certain conditions. Collectively, we propose that L14 and L16 fulfill a basic role in cell envelope- or cell division-related processes under specific growth conditions. Particularly, the activity of L14 and L16 might be necessary for the function or localization of lipo- or wall teichoic acids, and thus, might be linked to the regulation of autolysins. In conclusion, this study reveals important insights into the function of two so far uncharacterized but highly conserved lipoproteins in S. aureus.