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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.
Heart Failure is currently the most common cardiac disorder and a major public health concern worldwide. The adult mammalian heart harbors a subpopulation of cardiac progenitor cells (CPC) that are capable of improving cardiac function. The scope of this study was to delineate the molecular phenotype of a subpopulation of CPCs characterized by the expression of the stem cells antigen-1 surface marker (Sca-1+) and to further identify molecular alterations occurring under heart failure conditions. In order to understand the underlying cellular mechanisms an integrated approach of proteomics and transcriptomics-based techniques were employed. The first step towards achieving this goal was to unravel the native Sca-1+ cell characteristics of freshly isolated progenitor cells derived from healthy adult murine hearts. The proteome map of Sca-1 cells was established using a gel-based mass-spectrometry (gel LC-MS/MS) approach. For better interpretation, a comparison with the protein profiles of cardiomyocytes and Sca-1- cells obtained under similar experimental conditions was performed. All three cell-types were morphologically different in size and structure, which was also evident from their protein expression profiles. We observed that Sca-1+ cells lack endothelial-like and cardiac contractile phenotypes, unlike Sca-1- cells and cardiomyocytes, respectively. Functional assessment of both protein and gene expression profiles revealed a possible role of Sca-1+ cells in cell adhesion, migration, and proliferation. CPC remain in a dormant state under physiological condition unless challenged by myocardial injury. Previous studies revealed that resident Sca-1+ cells home to the injured myocardium but not to the healthy heart and further differentiate into functional cardiomyocytes. We investigated the molecular background of this behavior of adult Sca-1+ cells under heart failure condition which might provide a better insight into their cardiogenic potential in a pathological milieu. The double transgenic α-myosin heavy chain (MHC)-cyclin T1/Gαq overexpressing mouse was chosen as a model for heart failure. Using the comparative gene expression profiling we could detect the differential regulation of 197 genes with at least a 2-fold difference. Among these BDNF mRNA levels were 5-fold higher in the Sca-1+ cells derived from transgenic mice (Cyc+) in comparison to that of wild-type controls (Wt+). This difference was also observed at protein level. The substantially higher expression of BDNF during heart failure prompted us to investigate its regulatory effect on Sca1+ cells. In this current study we were able to show that small amounts of exogenous BDNF stimulated the migratory potential of Cyc+ cells. This effect was not seen in treated Wt+ cells. Furthermore, pulsed SILAC was employed to monitor BDNF mediated changes following treatment. After BDNF treatment, 58 proteins were differentially regulated of which proteins related to cell proliferation were reduced in level in Cyc+ cells while they displayed increased levels in Wt+ cells. Findings from bromodeoxyuridine (BrdU) assays and immunoblotting indicated that BDNF might initiate a differentiation program by repressing cell proliferation in Cyc+ cells. Taken together, it could be shown that the BDNF effect on protein synthesis of Cyc+ and Wt+ cells varied considerably, suggesting an improvement of the cardiogenic potential of Sca-1+ cells under pathological conditions. Aldosterone levels are known to be elevated during heart failure. In this part of study it was hypothesized that endocrine factors associated with heart failure might influence the migration of CPC, thereby possibly restoring the cardiac function of diseased hearts. It could be shown that high concentrations of aldosterone, similar to those found in the plasma of heart failure patients, induced the migration of Sca-1+ cells by up to 60% when compared to control, while physiological levels had no significant influence. In addition, it could be demonstrated that the aldosterone stimulus led to the activation of the mineralocorticoid receptor (MR) expressed on Sca1+ cells, which in turn facilitated migration. This was supported by application of MR antagonist eplerenone, which significantly reduced the aldosterone-induced increase in cell migration while a glucocorticoid antagonist exhibited no inhibitory effect. Hence, the results support the potential role of aldosterone in the mobilization of CPC. It is currently believed that the beneficial effects of cell-based therapies on cardiac repair are imparted to a large degree via paracrine mechanisms. We therefore focused on understanding the influence of pathophysiological levels of aldosterone on the extracellular environment of Sca-1+ cells. MS-based secretome profiling of cells treated for 24h with aldosterone treatment revealed higher levels of proteins associated with extracellular matrix remodeling and IGF signaling. Additionally, galectin-1 and gelsolin were significantly increased in level under pathological conditions indicating a possible paracrine tissue repair of Sca-1+ cells. To conclude, the global proteome and transcriptome profiles generated here revealed the molecular phenotype of Sca-1+ cells which may be used for future reference. The comparative microarray study provided deeper insight into the endogenous changes in mRNA expression during heart failure and delineated the cardiogenic characteristics of Sca-1+ cells. Moreover, the data presented here shed new light on the potential role of BDNF in regulating the mobilization and proliferation of CPCs. Our study on the influence of aldosterone on the migration and the extracellular proteome of CPCs provided new insights on the beneficial effects of this mineralocorticoid on cardiac cells.
Staphylococcus aureus can be a harmless colonizer of the human body, which colonizes about 20-30% of the population. If S. aureus overcomes the outer physical barrier of the body, comprised of the skin and mucous surfaces, it can also cause severe diseases such as endocarditis, pneumonia, or sepsis. S. aureus possesses a variety of secreted and surface bound virulence factors to mediate attachment and invasion into the host, to disseminate an infection and to modulate and evade the immune system. But not only the huge amount of virulence factors turn S. aureus into a dangerous human pathogen, also its resistances to a broad spectrum of commonly used antibiotics make infections hard to treat. During the last years it became apparent that S. aureus can be internalized by as well as replicate and persist in professional and non-professional phagocytic cells. It is suggested that the intracellular compartment protects S. aureus from antibiotic treatment and the immune system. To accomplish the adaptation to the intracellular compartment, S. aureus needs to regulate its gene expression by regulatory systems. One of these regulators is the alternative sigma factor SigB, which directly and indirectly regulates the expression of about 200 genes in vitro. However, the stimuli leading to the activation of SigB in S. aureus are barely known and also its role during an infection varies, depending on the S. aureus strain and infection model used. Therefore, the importance of SigB during the early adaption of S. aureus to the intracellular environment should be elucidated using a cell culture infection model. First, the existing cell culture infection workflow had to be modified to improve the data analysis and to increase the yield of identified proteins to comparatively monitor the adaption reaction of S. aureus HG001 and its isogenic ΔsigB mutant to the intracellular milieu of S9 human bronchial epithelial cells. The proteome analysis in conjunction with RT-qPCR analysis of the wild type and the ΔsigB mutant revealed a fast and transient activation of SigB directly after internalization. Quantitative analysis of the intracellular bacterial titer demonstrated a requirement of SigB for intracellular replication. Differences in the proteome composition of the ΔsigB mutant in comparison to the wild type after internalization reflected the different growth rates, resistance to antibiotics and toxic compounds, adaptation to oxidative stress, and protein quality control mechanisms. The accessory gene regulator (Agr) is like SigB also a global regulator of gene expression in S. aureus. To elucidate possible benefits in the intracellular survival of the co-occurrence of S. aureus wild type and Δagr mutant cells, like it can be found in sites of an infection, a co-infection assay was established. With the co-infection assay the simultaneous and competitive intracellular survival in comparison to the individual intracellular survival was followed for three days post-infection (p.i.). The single and the co-infection revealed that the wild type was able to replicate more efficiently during the first hours p.i. than the Δagr mutant, but the mutant was able to survive more efficiently. The extracellular proteome of S. aureus represents the key compartment for virulence factors. Virulence factors are secreted or bound to the surface of the S. aureus cell. With the infection workflow applied in this study, secreted proteins are lost during the enrichment of the intracellular bacteria for proteome analysis. Therefore, no information about the levels or the regulation of virulence factor expression can be acquired in the cell culture infection model using cell sorting approaches. Hence, the extracellular proteome of S. aureus was analyzed in vitro from shake flask experiments. To get a comprehensive overview of the regulatory impact of different global regulators onto the secretome, S. aureus LS1 mutants lacking the global regulators Agr, SarA and SigB were compared to the respective wild type. Additionally the protein level of the secretome of the well characterized and frequently used S. aureus strains 6850, CowanI, HG001, LS1, SH1000, and USA300 was comparatively analyzed. This project was performed in collaboration with the group of Prof. Löffler from the Institute of Medical Microbiology in Jena. The data of the extracellular proteome generated in this thesis were combined with phenotypic and toxicity data to explain strain differences in invasiveness, cytotoxicity, phagosomal escape, and intracellular persistence in infection experiments.
Microalgae are aquatic, unicellular, eukaryotic organisms, which perform photosynthesis. They have gained interest within the last decades not only for biofuel production due to their high amount of lipids, but also for pharmaceutical and for nutraceutical purposes. Interesting compounds are proteins, carbohydrates, or pigments, such as carotenoids. However, microalgae possess strong and rigid cell walls, which hinder a sufficient and yet, gentle extraction of those valuable compounds. Although standard extraction techniques are available, several shortcomings occur, e.g. high energy demand, use of environmentally harmful solvents or alteration of compounds due to heat or chemicals. Therefore, an alternative method is needed, which is able to address these disadvantages. Physical plasmas were thus studied to answer the question whether they are able to disintegrate the cell walls of microalgae effectively and yet, without degradation of the extractives.
First step of the thesis was to find a suitable plasma source that has an effect on the cell walls because plasma effects, such as electric fields, shockwaves, UV light emission, and the generation of reactive species can be tailored with the respective setup. It was found that spark discharges are most effective for the extraction of Chlorella vulgaris, which was chosen as model organism. All extraction yields were compared to reference methods, whereat microwave radiation was found to be the most effective reference method and were hence, applied for comparative studies.
For the next step, proteins were selected as targets to answer the question, which differences can be determined between plasms-treated and microwave-radiated proteins are observable although the extraction yields were equal. Furthermore, plasma effects, especially the effects of reactive species on the extracted proteins had to be studied. Findings indicate that heat sensitive proteins, such as photosystem-related proteins, or histones are better extractable with spark discharges than with microwave exposure and the effect of reactive species is only minor.
The last step was to determine, which plasma effect is responsible for the observed cell wall disintegration. Therefore, the tensile strength of Chlorella vulgaris was determined and compared to the shockwave pressure, which is generated from the spark channel. It was proven that the shockwave pressure exceeds by far the tensile strength of the microalgae an can be thus held responsible for mechanism for cell wall rupture.
In this thesis, it was found that spark discharges are a promising alternative for the extraction of valuable compounds from microalgae. The discharges are not only effective, but also gentle enough for sensitive compounds, such as proteins or pigments.
In the post genomic era, novel “Omics” technologies like genomics and proteomics can be used in powerful screening approaches to provide unbiased lists of candidate genes and proteins and thus facilitate a comprehensive analysis of complex diseases such as cancer, which would not have been possible applying traditional genetic and biochemical approaches alone. During my PhD tenure I applied functional genomics screening technologies including proteomics in combination with traditional biochemical and cell biology approaches in two disease oriented projects: 1. Characterization of the role of BCL11b in Human T cell lymphomas (and) 2. Elucidation of the mechanism of pathophysiology of Johanson Blizzard Syndrome using UBR1 knockout mice and JBS patients’ lymphoblasts cell lines.
1.Characterization of the role of BCL11b in Human T cell lymphomas
: The Bcl11b protein belongs to the C2H2-family of Krueppel-like zinc finger proteins and thus is a member of the largest family of transcription factors in eukaryotes. It was shown to be important for a variety of functions such as T cell differentiation, normal development of central nervous system and DNA damage response. Malignant T cells undergo apoptotic cell death upon BCL11B down-regulation. However, the detailed mechanism of this cell death is not fully understood. Two dimensional difference in-gel electrophoresis (2D-DIGE), mass spectrometry and cell biological experiments were employed to investigate the functional impact of knock down of BCL11B in malignant T cell lines such as Jurkat and huT78. To further confirm the findings of these experiments, changes in protein patterns were also recorded after down-regulation of BCL11B expression in Jurkat cells over expressing BcL-xL and in Jurkat cells over expressing BCL11B. These experiments provide evidence for the involvement of the mitochondrial apoptotic pathway and increased levels of cleavage fragments of known caspase targets such as myosin, spectrin and vimentin were observed after BCL11B knockdown. The findings suggest an involvement of ERM proteins, which were up-regulated and phosphorylated upon BCL11B down-regulation. Besides ERM proteins, PDCD5, a key regulator of apoptosis, was also found at increased levels upon down regulation of BCL11B. Moreover, the levels of several proteins implicated in cell cycle entry, including DUT-N, UCK2, MAT1, CDK6, MCM4 and MCM6 were elevated, which might lead to uncontrolled cell cycle progression, uracil misincorporation and cell death. Interestingly, an inverse regulation pattern, i.e. decreased levels of ERM proteins, DUT-N, UCK2 and PDCD5 was seen upon over expression of BCL11B in Jurkat cells. In summary, proteome analyses revealed several previously unidentified mechanisms which could significantly contribute to the cell death following BCL11B knockdown.
2.Elucidation of the mechanism of pathophysiology of Johanson Blizzard Syndrome using UBR1 knockout mice and JBS patients’ lymphoblasts cell lines
: Johanson-Blizzard syndrome (JBS; OMIM 243,800), which was first described in 1971, is a rare autosomal recessively inherited genetic disorder with a unique combination of congenital abnormalities. The most constant clinical feature of JBS is the loss of exocrine pancreatic function due to progressive destruction of pancreatic acini. Genome wide linkage analysis identified the disease associated locus in the 15q14-q21 chromosome region and high-throughput sequencing of this region revealed several truncated and some missense mutations in the UBR1 gene. UBR1 gene contains 47 exons and spans over 161 kilobases. The UBR1 protein belongs to the E3 ubiquitin ligase family and is an important component of the N-end rule pathway of ubiquitous protein degradation. It was hypothesized that stabilization of direct and unique substrates of UBR1 could be the main cause of the JBS pathophysiology. So far sequencing of the UBR1 gene is the only available diagnostic procedure. However, sequencing might not always allow precise prediction of residual UBR1 activity. Hence, this study was started to develop a protein based diagnostic assay for the detection of subclinical cases of JBS and to identify signalling pathways contributing to the pathophysiology of this complex disorder using a murine UBR1 knockout model. 2D-DIGE proteome analysis was carried out for a comparative evaluation of lymphoblast samples of 14 patients and 11 controls. Principal component Analysis (PCA) clearly discriminated JBS patients from controls. However, 4 JBS patients differed from the rest and resembled controls more closely. Western-blot analysis revealed residual UBR1 levels in these patients, which were linked to a milder phenotype. Hierarchical clustering of the three groups (controls, patients with residual UBR1 levels and patients without UBR1) showed group-specific characteristic differences in the abundance of differentially regulated proteins. Quantification of a panel of five selected protein spots encompassing Interferon-induced GTP binding protein, HLA class II histocompatibility antigen, Annexin A6, FK506-binding protein 4 and GRP78 permitted discrimination of controls and JBS patients with mild phenotypes. Of note, the molecular chaperones GRP78 (BiP) and FK506BP were consistently altered in level in JBS patients and probably constitute UBR1 dependent substrates. This suggested JBS as an ER-stress related disease also indicating a possible way of therapeutic intervention. Comparative proteome analysis of UBR1 knockout and wild type animals after caerulein treatment revealed a significant accumulation of pancreatic proteases such as chymotrypsin B, anionic trypsin and pancreatic elastase in animals lacking UBR1. Furthermore, an up-regulation of ER-stress proteins and inflammation related proteins was observed. Phenotypic characterisation revealed in UBR1 knockout animals significantly increased lipase levels, a significantly increased histological score and significantly increased elastase activity 8h after the onset of pancreatitis. In isolated pancreatic acini of UBR1 knockout animals we found a significant increase in intracellular elastase activation upon supramaximal CCK stimulation, which was associated with a significant rise in the rate of necrosis explaining the more severe phenotype in the UBR1 knock-out animals. A TUNEL assay showed that there was more apoptosis in wild type compared to UBR1 knockout mice. Another set of experiments was designed to identify physiologically important substrates of UBR1. Inhibition of such substrates might then in turn allow reversion or prevention of the severe form of pancreatitis in UBR1 knockout mice. However, using the trypsin specific and reversible inhibitor S-124 it was shown that impaired trypsin degradation and thereby prolonged activation of this protease did not critically influence the phenotype. Calcium analysis after physiological stimulation revealed an increase of pathological Ca2+ signalling events, i.e. significant decrease of spike number and significant increase of spike duration. Of the candidates potentially influencing Ca2+ signalling RGS4 turned out to be of particular importance. Pre-incubation of pancreatic acini of UBR1 knockout animals with a specific RGS4 inhibitor (CCG-4986, 10 µM) normalized Ca2+ patterns, did not affect trypsin activity itself but prevented Ca2+-triggered premature trypsin activation and thus acinar disintegration. In summary, using lymphoblasts samples of JBS patients we were able to deduce a protein panel which could be developed as a possible diagnostic tool for confirmation of JBS syndrome. Furthermore, using UBR1 knockout mice in an experimental model we were able to elucidate the vital function of UBR1 and its direct substrate RGS4 in the defense against pathologic pancreatic damage thereby manifesting JBS as an inflammatory disorder due to an inadequate UBR1 mediated defense.
Streptococcus pneumoniae is one of the leading human pathogen causing morbidity and mortality worldwide. The pneumococcus can cause a variety of different diseases ranging from mild illnesses like otitis media and sinusitis to life-threatening diseases such as pneumonia, meningitis and sepsis. Mostly affected are infants, elderly and immune-suppressed patients. Although, there are vaccines against pneumococci available, still hundreds of thousands of people got infected each year. These vaccines are targeting the pneumococcal polysaccharide capsule. Because of the high number of different serotypes, it is not possible to generate a vaccine against all present serotypes. In the last years a shift to non-vaccine serotypes was noticed. This strengthens the need for the development of vaccines which do not target polysaccharides. Thus, proteins came into focus as potential new vaccine candidates or targets for drug treatment, because several proteins are highly conserved among different strains or even genera. Proteome analyses can give insights into the protein composition in a certain state of a bacterium. So, targets can be identified, which are especially expressed under infection-relevant conditions. Iron limitation is one of these conditions and the knowledge on iron acquisition in pneumococci is still limited. Iron is an essential trace element and as redox-active catalyst or as cofactor involved in various key metabolic pathway in nearly all living organisms and thus also in bacteria. For instance, iron is necessary during biosynthesis of amino acids and in electron transport as well as in DNA replication. Within the human host iron is extremely limited due to its high insolubility under physiological conditions, which is part of the nutritional immunity of its human host. Hence, bacteria had to evolve mechanism to overcome iron starvation. In this thesis the adaptation process triggered by iron limitation in the S. pneumoniae serotype 2 strain D39 was investigated in a global mass spectrometry-based proteome analysis.
In preceding growth experiments the pneumococcal growth was adapted to the needs of proteomic workflows. In order to investigate the pneumococcal response to iron limitation, the organic iron-chelating agent 2,2’-bipyridine (BIP) was applied. For the quantification of changes in protein abundances comparing stress to control conditions the very reliable and robust metabolic labeling technique Stable Isotope Labeling with Amino Acids in Cell Culture (SILAC) was used. This method requires the bacterial cultivation in a chemically defined medium, for which reason modified RPMI 1640 medium was chosen. A pooled protein extract with heavy labeled amino acids was applied as an internal standard, which included proteins expressed under control and stress condition, to control, BIP and BIP-iron-complex (BIP control experiment) samples. Samples were analyzed by liquid chromatography coupled directly to a tandem mass spectrometer. It is described that under iron-restricted conditions proteins associated to pathogenesis are higher abundant in pathogenic bacteria like Staphylococcus aureus. Hence, similar observations were expected also for the proteomic adaptation of S. pneumoniae, but the first results showed a reduction in protein abundance of virulence factors. In order to explain these results inductively-coupled-plasma mass spectrometry was executed to determine the iron concentration of chemically defined medium (CDM) used in this experiment. The analysis revealed a relatively low iron concentration of approximately 190 µg l-1. Therefore, the iron concentration of the complex medium THY, in which pneumococci are usually grown, was investigated. THY contains four-fold (740 µg l-1) more iron than the CDM. Subsequently, an additional iron limitation approach was carried out in THY. As SILAC is not applicable in complex media like THY, MaxLFQ was applied as quantification method in this case. Because two different media were used, an additional comparative proteome analysis with regard to the two investigated media was executed.
Comparing the protein composition in both cultivation media it became clear that pneumococci exhibit a totally different proteome depending on the medium. Major differences were found in metabolisms of amino acids, vitamins and cofactors as well as in pathogenesis-associated proteins. These differences have to be taken into account during the analyses of both iron limitation approaches. Overall, more proteins were identified and quantified in CDM samples. The pneumococcal adaptation to iron limitation in both media was different; especially, the alterations in protein abundances of virulence factors. In contrast to the iron limitation in CDM, proteins involved in pathogenesis were higher abundant under iron limitation in THY, which was the expected result. Because of proteomic changes of cell division and lipid metabolism involved proteins in iron-limited pneumococci in CDM, electron microscopic pictures were taken in order to proof cell morphology. The pictures showed an impaired cell division in iron-limited CDM, but not in THY medium. However, both datasets have similarities as well. Thus, the iron uptake protein PiuA is strongly increased in iron-restricted conditions and the abundance of the iron storage protein Dpr is significantly decreased in both datasets. Notably, PiuA and Dpr seem to have important roles during the pneumococcal adaptation to iron-restricted environments.
One the basis of these results, it could be shown that the proteomic response of pneumococci to iron limitation is strongly dependent to the initial iron concentration of the environment. Hence, pneumococci will adapt differently to varying niches and thus potential vaccine candidates should be expressed independently of the localization within the human host.
Rich knowledge about global nutrient cycles and functional interactions can be gained from the perspective of complex microbial proteomes. In this thesis, the application of environmental proteomics allowed for a direct in situ analysis of habitat-specific proteomes expressed by respective microbial communities from two different marine ecosystems. In the first part of this thesis, unculturable symbiont populations from tubeworms that colonize hydrothermal vents of the Pacific deep sea became accessible by use of community proteomics. This branch of environmental proteomics is generally employed to ascertain simple microbial assemblages derived from in situ samples. The proteome study was aimed at analyzing adaptations of seemingly monospecific symbionts to different hosts, the tubeworms Tevnia jerichonana und Riftia pachyptila. A comparison of the newly sequenced genomes of symbiont populations from both hosts confirmed that both symbioses involve the same bacterial species. Also the proteome analysis by 2D-PAGE showed a high physiological homogeneity for symbionts from both worm species, although the hosts are exposed to different geochemical conditions. Thus, the hosts provide their symbionts with a relatively stable internal environment by attenuation of external influences. Only minor variations in the symbionts proteomes reflected the differential environmental conditions outside the worms. Hence, the symbionts were able to fine-tune major metabolic pathways and oxidative stress in response to only minor chemical changes within their hosts. Moreover, new components of important physiological processes of the bacterial symbionts, like the sulfide oxidation and carbon fixation, were identified by in-depth proteomics of the Riftia symbiosis model system. The in situ protein samples showed as well that, in contrast to an earlier hypothesis, nitrate is used as an alternative electron acceptor. In the second part of this thesis, another branch of environmental proteomics called metaproteomics was applied to investigate the response of a bacterioplankton community to a spring phytoplankton bloom in the North Sea. Recurrent plankton blooms are a common phenomen of coastal areas, which however has only been investigated with limited resolution in biodiversity. Based on large-scale proteomic data sets it was found that specialized populations of Bacteroidetes, Gammaproteobacteria and Alphaproteobacteria exhibited differential protein expression patterns. These involved oligomer transporters, glycoside hydrolases and phosphate acquisition proteins. A successive utilization of algal organic matter by microbes indicated a series of ecological niches occupied by the heterotrophic picoplankton. Key proteins, identified by metaproteomics, were further investigated by studying a model bacterium to define their specificities regarding the utilization of algal glycans. By isotope labeling of proteins, quantitative proteomics of the North Sea isolate Gramella forsetii KT0803, a Bacteroidetes representative could be conducted. The adaptation to the algal polysaccharides alginate and laminarin in comparison with glucose was analyzed. G. forsetii proved to be a specialist for the chosen algal polymers, in particular for glucans like laminarin. Primarily comprehensive clusters, the so-called polysaccharide utilization loci (PULs) were activated. The results of this model study complemented the basic concepts obtained by the metaproteomic approach about carbon cycling in coastal systems. The accessibility of numerous unculturable marine microbes by environmental proteomics allows to improve our understanding of interactions that drive symbioses or complex communities. Adaptations to environmental parameters, such as the abundance of substrates, can be analyzed and associated with respective populations. Thus statements can be made for functional groups of microorganisms, their ability for the creation of niches and their flexibility to respond to varying environmental impacts. The increasing number of marine model bacteria enables targeted analysis of specificities and adaptations and hence to support the environmental proteomics approach.
Posttranslational modifications are involved in the regulation of virtually all cellular processes, including immune response, nevertheless, they are also targets manipulated by invading pathogens. The first investigated example is protein citrullination which is an important posttranslational modification that acts on a multitude of processes like supervision of cell pluripotency and rheumatoid arthritis. Citrullination of targeted arginine residues is performed by the Peptidylarginine deiminase. Within the first published manuscript, being part of this thesis, it was possible to show the use of this posttranslational modification by the human pathogen Porphyromonas gingivalis to facilitate innate immune evasion at three distinct level. P. gingivalis was demonstrated to citrullinate proteins by Porphyromonas peptidylarginine deiminase resulting in diminished phagocytosis and subsequent killing by neutrophils. Furthermore, it was shown that citrullination of histone H3 enables P. gingivalis to survive in neutrophil extracellular traps and incapacitate the lysozyme-derived peptide LP9.
The second investigated posttranslational modification is ubiquitination and its role in respiratory tract infections. Ubiquitination is the covalent attachment of a small protein that consisting of only 76 amino acids to the ε-amino group of lysine residues to posttranslational modify proteins. Acute infections of the lower respiratory tract such as viral and bacterial co-infections are among the most prevalent reasons of fatal casualties worldwide. Therefore, the interactions between host and pathogens resulting in the impairment of the hosts immune response and immune evasion of the pathogens, need to be elucidated. To get new insights in the infection driven changes in protein polyubiquitination and alterations in the abundance of ubiquitin E3 ligases involved in ubiquitination, cellular proteomes were monitored in detail by high resolution mass spectrometry. Therefore, the epithelial cell lines 16HBE14o- (Manuscript II) and A549 (Manuscript III) were co-infected with influenza A virus H1N1 and Streptococcus pyogenes or Staphylococcus aureus or with influenza A virus H1N1 and Streptococcus pneumoniae, respectively. Here, it could be shown in 16HBE14o- cells that co-infection of epithelial cells is not characterized by decreased cell survival and that observable effects on the proteome and ubiquitinome are mostly additive rather than synergistic. S. pyogenes infection affected the mitochondrial function, cell-cell adhesion, endocytosis and actin organization. Viral infection affected mRNA processing and Rho signaling. Viral and bacterial co-infection was detected to affect processes that were already affected by both of the corresponding single infections. No further pathways were strongly affected by the co-infection. A similar result has been observed in A549 cells co-infected IAV and S. pneumoniae. Overrepresented gene ontology terms depict the sum of those observed in the viral and bacterial single infection. Moreover, no significant change in cell survival upon co-infection compared to single bacterial infection was noticed for A549 cells either. This led to the suggestion that co-infection of investigated epithelial cells under examined conditions possesses additive rather than synergistic effect and thus, may not worsen the outcome of the infection within the studied conditions. Infections in other systems, may provide varying results and thus should be examined in future studies.
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.
Clostridioides difficile is the leading cause of antibiotic-associated diarrhea referring to infections of the gastrointestinal tract in the course of (broad-spectrum)antibiotic therapy. While antibiotic therapy, preferentially with fidaxomicin or vancomycin, often stops the acute infection, recurrence events due to remaining spores and biofilm-associated cells are observed in up to 20% of cases. Therefore, new antibiotics, which spare the intestinal microbiota and eventually clear infections with C. difficile are urgently required. In this light, the presented work aimed at the evaluation and characterization of three natural product classes, namely chlorotonils, myxopyronins and chelocardins, with respect to their antimicrobial activity spectrum under anaerobic conditions and their potential for the therapy of C. difficile infections. Briefly, compounds of all three classes were screened for their activity against a panel of anaerobic bacteria. Subsequently, the systemic effects of selected derivatives of each compound class were analyzed in C. difficile using a proteomics approach. Finally, appropriate downstream experiments were performed to follow up on hypotheses drawn from the proteomics datasets. Thereby, all three compound classes demonstrated significant activity against C. difficile. However, chelocardins similarly inhibited the growth of other anaerobes excluding chelocardins as antibiotic candidates for C. difficile infection therapy. In contrast, chlorotonils demonstrated significantly higher in vitro activity against C. difficile and close relatives compared to a small panel of other anaerobes. In addition, it could be shown that chlorotonils affect intracellular metal homeostasis as demonstrated in a multi-omics approach. The data led to speculate that chlorotonils eventually affect cobalt and selenate availability in particular. Moreover, a metaproteomics approach verified that oral chlorotonil treatment only marginally affected the intestinal microbiota of piglets on taxonomic and functional level. Furthermore, the proteome stress response of C. difficile 630 to myxopyronin B, which similarly showed elevated activity against C. difficile compared to a few other anaerobes, indicated that the antibiotic inhibited early toxin synthesis comparatively to fidaxomicin. Finally, evidence is provided that C. difficile 630 responds to dissipation of its membrane potential by production and accumulation of aromatic metabolites.