Open Access

Humanity is plagued by many diseases. Beside environmental influences, many --- if not all --- diseases are also subject to genetic predisposition and then display molecular alterations such as proteomic or metabolic aberrations. The elucidation of the molecular principles underlying human diseases is one of the prime goals of biomedical research. To this end, there has been an advent of large-scale omics profiling studies. While the field of molecular biology has experienced tremendous development, data analysis remains a bottleneck. In the context of this thesis, we developed a number of analysis strategies for different types of omics data resulting from different experimental settings. These include approaches for associations studies for plasma miRNAs and time-resolved plasma omics data. Furthermore, we devised analyses of different RNA-Seq transcriptome profiling studies coping with problems such as lack of replicates or multifactorial experimental design. We also designed machine learning frameworks for the identification of discriminatory biomolecular signatures analysing case-control or time-to-event data. All of the strategies mentioned above were developed and applied in the contexts of multi-disciplinary endeavours. They aided in the identification of plasma miRNAs associated with age, sex, and BMI as well as plasma miRNAs bearing potential as diagnostic biomarkers for non-alcoholic fatty liver disease (NAFLD). This thesis significantly contributed to a study demonstrating the utility of plasma miRNAs as prognostic biomarkers for major cardiovascular events such as ST-elevation myocardial infarction. Our approaches for analysing RNA-Seq data aided in the characterisation of murine models for Alzheimers disease and the transcriptional response of human gingiva fibroblasts to ionizing radiation exposure. Furthermore, the developed approaches were applied for studying a human model for thyrotoxicosis and for the successful identification of a multi-omics plasma biomarker signature of thyroid status. We are only beginning to understand the molecular principles underlying human diseases. The approaches and results presented in this thesis will contribute to improved understanding of biomolecular processes involved in common diseases such as Alzheimers disease, NAFLD, and cardiovascular diseases.

In der vorliegenden Arbeit wurde das Proteom von Seminomen mit dem von nicht-neoplastischem Hodengewebe von 6 Patienten vergleichend analysiert. Ziel der Arbeit war die Ermittlung von Expressionsunterschieden zwischen Tumorgewebe und gesundem Gewebe auf Protein-Ebene. Zur Auftrennung der Proteine und Darstellung des Proteoms wurde die zweidimensionale Gelelektrophorese angewandt. Diese erlaubt eine Trennung der Proteine nach ihrem Molekulargewicht und ihrem isoelektrischen Punkt. Mit den hier verwendeten Gelen wurden Proteine im Molekulargewichtsbereich von ca. 10-200 kDa und einem isoelektrischen Punkt zwischen 4 und 7 erfasst. Die Darstellung der Proteine erfolgte durch Silber- und Fluoreszenzfärbung. Die Bearbeitung und Auswertung der Proteinmuster erfolgte mit der Software Delta 2D (Decodon). Bei 5 von 6 Patienten fand sich ein Protein, welches im Seminomgewebe geringer exprimiert war als im gesunden Hodengewebe. Das Protein wurde massenspektroskopisch mittels MALDI-MS analysiert und als GSTM3, Glutathion-S-Transferase der Mu-Klasse, identifiziert. Glutathion-S-Transferasen sind multifunktionelle Enzyme des Phase-Il-Stoffwechsels und spielen eine wichtige Rolle bei der Eliminierung von Karzinogenen und Xenobiotika. Eine verminderte Expression von GST-Isoformen der Mu-Klasse in Seminomen wurde in der Literatur bereits beschrieben, jedoch ohne Angabe der GST-Isoformen. Diese Arbeit berichtet erstmalig von einer verminderten Expression der GSTM3-Isoform in Seminomgeweben. Auch die Menge an GSTM3-mRNA korrelierte mit den Proteindaten. Durch semiquantitative RT- PCR konnte das Ergebnis somit auf Transkriptionsebene bestätigt werden.

Microbial infections can be either caused by a single species or complex multi-species consortia. One of the most prominent opportunistic human pathogens leading to mono- or mixed-species infections is the Gram-negative bacterium Pseudomonas aeruginosa. Understanding the molecular basis of its adaptation to infection-related stresses is an essential prerequisite for the prevention and treatment of P. aeruginosa infections. We therefore employed state-of-the-art proteomics approaches to elucidate the molecular adaptation mechanisms of P. aeruginosa to infection-related conditions. Moreover, structure, function and interaction of complex microbial consortia containing P. aeruginosa and causing catheter-associated urinary tract infections were investigated by metaproteomics analyses. Our investigations revealed that the adaptation of P. aeruginosa during infection is either based on gene expression changes caused by environmental signal integration or by gene mutations leading to a selective advantage in a particular host environment. In study I, investigating the proteome response of P. aeruginosa biofilms to the clinical relevant antibiotic ciprofloxacin, global changes in the protein profile were observed. Ciprofloxacin induced the expression of proteins involved in the Lex-induced SOS-response, drug efflux pumps and gene products of the ciprofloxacin-responsive prophage cluster and repressed the expression of porins and DNA-binding proteins. In study II the transcriptome and proteome of two clonal P. aeruginosa lineages during long-term colonization of cystic fibrosis (CF) patient’s lungs were analyzed. Point mutations in global regulator genes, i.e. retS, gacS, and gacA, were identified by genomic sequencing. Inactivation of RetS, found two years after the initial colonization, induced the expression of genes involved in chronic infections and coding for the type 6-secretion system (T6SS). Additional mutations in the GacS/GacA two-component regulatory system (TCS) were found to repress the expression of T6SS proteins and to induce the expression of proteins belonging to the type 3-secretion system (T3SS). In study III we elucidated the niche-specific adaptation of P. aeruginosa isolates from different infection sites by investigating their protein expression patterns and glucose metabolic fluxes. We could show that isolates from the urinary tract express a higher amount of proteins involved in the acquisition of micronutrients (i.e. iron) and carbohydrates compared to isolates from the CF lung. In study IV 16S rDNA sequencing and metaproteomics were employed to demonstrate that the investigated CAUTI-related biofilms consisted of two to five different species with one or two species dominating the mixed community. Following this line of research, we investigated in study V structure and function of a biofilm of a long-term catheterized patient, which was predominantly composed of P. aeruginosa and Morganella morganii, but also contained a minor proportion of the obligate anaerobe Bacteroides sp.. The comparison of in vivo and in vitro protein expression profiles of P. aeruginosa and M. morganii indicated that iron and carbohydrates are the major growth-limiting factors in the bladder. These results indicate different nutritional strategies of the two pathogens in the bladder environment. A comparison of urinary protein profiles of healthy persons and catheterized patients suggested that the human innate immune system is induced by CAUTIs. Moreover, numerous proteins involved in nutritional immunity, e.g. iron-, calcium- and magnesium-binding proteins, were found to be more abundant in the urine of catheterized patients. A follow-up (meta)proteomics study (study VI) aiming at the elucidation of interspecies interactions during multi-species infections indicated that the urease-positive uropathogen Proteus mirabilis induces the precipitation of metal ions by urine alkalization and thereby limits the availability of these important micronutrients for other co-infecting bacteria. This limitation seems to be sensed by the P. aeruginosa PhoP-PhoQ two-component system (TCS) leading to an increased resistance to antimicrobial peptides and biofilm-forming capacity of the pathogen. Also during co-cultivation of P. aeruginosa with Staphylococcus aureus a slight increase in the expression of the PhoP-PhoQ TCS and the alkaline protease could be observed (study VII). In study VIII a combined metagenomics and metaproteomics approach was employed to investigate structure and function of the lichen Lobaria pulmonaria, a complex consortium consisting of a fungus, an algal partner, cyanobacteria, and a highly diverse bacterial microbiome. The results presented in this work contribute to a better understanding of the manifold and complex bacterial adaptation mechanisms to infection-related and environmental stress and thereby foster the development of novel treatment and prevention strategies.

Hintergrund: Die Phototherapie hat sich bereits in den Leitlinien zur Therapie entzündlicher und immunvermittelter dermatologischer Erkrankungen wie Psoriasis oder dem atopischen Ekzem etabliert. Eine neuere Anwendung ist die intranasale Phototherapie mit mUV/VIS (70 % sichtbares Licht, 25 % UVA, 5 % UVB) zur Behandlung der allergischen Rhinitis. Verschiedene Arbeiten zeigen eine Reduktion der Symptome der allergischen Rhinitis durch mUV/VIS. In der vorliegenden Arbeit wurden die zugrundeliegenden molekularen Mechanismen und Veränderungen auf Proteomebene in humanen respiratorische S9-Epithelzellen untersucht. Methoden: Respiratorische S9-Epithelzellen wurden mit mUV/VIS für 4 min bestrahlt und nach 0, 30 und 60 min (Kurzzeitbereich) sowie nach 24, 48 und 72 h (Langzeitbereich) geerntet. Zum Vergleich unterschiedlicher Dosen wurden zusätzlich Zellen für 2 und 6 min bestrahlt und nach 24, 48 und 72 h geerntet. Die Proteine der Proben wurden extrahiert und mittels 2D-DIGE aufgetrennt. Die resultierenden Gel-Bilder wurden mittels Delta2D-Software analysiert, die detektierten Spots ausgestanzt und mit Trypsin proteolytisch verdaut. Anschließend konnten sie mittels Massenspektrometrie (MALDI-TOF-MS) und dem Datenbankvergleich mit virtuell verdauten Proteinen identifiziert werden. Ergebnisse: Von 1665 detektierten Spots wurden 897 identifiziert und weiter statistisch analysiert. Für die weiteren Analysen wurden nur die im Vergleich zur Kontrolle signifikant veränderten Proteine berücksichtigt (p ≤ 0,05 und Fold Change ≥ 1,5). Die Ergebnisse zeigen eine deutliche Induktion von oxidativem Stress nach mUV/VIS. Dies konnte dosisabhängig mit der Induktion des Nrf2-Pathways, der Hitzeschockproteine und der Induktion der Thioredoxinreduktase 1 nachgewiesen werden. Proteinschäden und Proteinreparatur konnten anhand der Induktion von Hitzeschockproteinen und der Induktion von Proteinen, die mit der Ubiquitin-vermittelten proteasomalen Degradation fehlgefalteter Proteine assoziiert sind, gezeigt werden. Dosisabhängig werden direkt und indirekt durch oxidativen Stress DNA-Schäden induziert. Dies bestätigte sich anhand der dosisabhängigen Induktion von DNA-Reparaturmechanismen (NER). Die Induktion der Apoptose bei massiven Schäden wurde mittels Ingenuity Pathway Analyse (IPA) nachgewiesen. Die Induktion der Tumorgenese ist anhand der dosisabhängig induzierten Anzahl der Tumor-assoziierten Proteine und der induzierten Protoonkogene wie CRK oder des Tumorantigens p53 nachweisbar. In IPA zeigt sich eine dosisabhängige Beeinflussung immunologischer/inflammatorischer Prozesse wie der Psoriasis oder des atopischen Ekzems. Im Zeitverlauf kommt es zum Anstieg der Proteine, die mit solchen Erkrankungen assoziiert sind. Es zeigte sich auch eine dosisabhängige Induktion von Proteinen, die mit Mechanismen der Virusfreisetzung aus der Wirtszelle assoziiert sind. Dies könnte einige klinische Berichte über eine Herpes simplex Virusreaktivierung nach einer mUV/VIS-Bestrahlung erklären. Fazit: Eine Beeinflussung immunologisch/inflammatorischer Prozesse konnte bestätigt werden. Somit ist mUV/VIS zur Therapie der allergischen Rhinitis einsetzbar. Nach aktueller Literatur scheint die Rhinophototherapie nicht für die Karzinogenese zu prädisponieren. Aber es fehlen bisher Langzeit-Studien, die dies bestätigen. Aufgrund der genannten Veränderungen sollte eine mUV/VIS-Behandlung nur nach sorgfältiger Nutzen- und Risikoanalyse erfolgen.

Dilated Cardiomyopathy is a chronic myocardial disease characterized by progressive depression of contractile function and ventricular dilatation. It is the leading cause of heart failure and the most common reason for heart transplantation. Besides genetic causes, viral infection and autoimmune response are considered to play a major role in the etiology of the disease. Among different viruses that cause the disease, Coxsackievirus B3 (CVB3) is predominantly associated with the development and progression of the disease. Moreover, Coxsackievirus induced myocarditis in the mouse mimics human myocarditis and dilated cardiomyopathy. In the murine model, the disease progresses over a period of 90 days from acute myocarditis to chronic myocarditis and further develops into dilated cardiomyopathy and congestive heart failure. Though much is known about the progression of the disease, the molecular events occurring after infection with CVB3 are not completely understood. In the current study, comparative proteomic analysis of A.BY/SnJ mouse hearts 84 days post infection (84 d p.i.) with CVB3 and age-matched non-infected mouse hearts was performed. 2D-DIGE and gel-free LC-MS/MS were used to characterize the changes occurring at the molecular level and Western Blot analysis as well as immunohistochemical staining was carried out for validation of results. A total of 101 distinct proteins were identified as displaying dilated cardiomyopathy-associated changes in A.BY/SnJ mouse hearts 84 d p.i. compared to age matched controls. Comprehensive analysis by both DIGE and gel-free proteomics revealed proteins related to lipid metabolism (18%), carbohydrate metabolism (14%), cell morphogenesis (14%) and respiratory electron transport chain (9%) to display significantly altered levels in diseased mouse hearts. The significant increase in extracellular matrix proteins observed in mouse hearts 84 d p.i. indicated extensive fibrosis. On the other hand, proteins related to energy metabolism were identified at lower levels in infected mouse hearts than in controls. These proteomics data and the decrease in activities measured for complexes I-IV of the respiratory electron transport chain in A.BY/SnJ mouse hearts 84 d p.i compared to age matched controls, indicate a diminished energy supply in the dilated hearts of CVB3 infected mice. Furthermore, proteins associated with muscle contraction were identified at lower levels in mouse hearts 84 d p.i. compared to age matched controls indicating compromised myocardial contractility due to virus induced dilated cardiomyopathy. While extracellular matrix proteins and contractile proteins were identified in the DIGE analysis, proteins of lipid metabolism which are mostly mitochondrial in origin and have a pI > 7 were identified by gel-free proteomics indicating the advantages of both methods. Gel based analysis also aided in the identification of protein isoforms/ species which allows conclusions on post translational modifications and protein processing. Thus, the current study also identified infection related changes in the phosphorylation of selected proteins. Phosphospecific staining of the gels demonstrated increased phosphorylation of myosin regulatory light chain - ventricular isoform, actin - aortic smooth muscle isoform, heat shock protein 90B, and heat shock protein beta-1 in infected mouse hearts. Extensive degradation of proteins was not observed in the dilated heart. As described earlier, virus induced dilated cardiomyopathy develops over a period of 90 days in the murine model during which the mice also grow and undergo aging. Since aging is one of the factors influencing the susceptibility of animals to disease, age dependent changes in the proteome of mouse hearts were also studied by comparing 4 months old (84d) A.BY/SnJ mice with 1 month old mice as controls. Complementary analyses by 2D-DIGE and gel-free LC-MS/MS analysis revealed 96 distinct proteins displaying age associated differences in intensity. These proteins are related to lipid metabolism (19%), protein transport (17%) and electron transport chain (12%). Mitochondrial proteins such as carnitine-o-palmitoyltranferase 1, carnitine-o-palmitoyltranferase 2, and carnitine-O-acetyltransferase involved in lipid metabolism and transport were identified at significantly higher levels indicating higher energy demand in 4 months old mice compared to controls. This conclusion is complemented by observation of decreases in the levels of respiratory electron transport chain proteins especially of subunits of ATP synthase as a member of complex V. Furthermore, an increase in intracellular transport proteins was also observed in 4 months old mouse hearts compared to one month old controls. An increase in the level of vesicular transport proteins likely constitutes a secondary effect leading to endoplasmic reticulum associated protein degradation. In the two studies described above, altered mitochondrial functioning and thereby decreased energy/ATP production was very prominent indicating the role of mitochondria in health and disease. The exchange of ADP/ATP across the mitochondrial membrane is carried out by the carrier protein adenine nucleotide translocase1 (ANT1). To improve understanding of the influence of ANT1 in the heart, comparative proteomic analysis using gel-free LC-MS/MS was performed with hearts of 3 months old rats over-expressing ANT1 using hearts from age-matched wild type animals as controls. A total of four hundred and thirty three proteins were identified with at least two peptides, of which eighty seven proteins displayed small but significant (p<0.05) changes in intensity. Proteins related to integrin linked kinase signalling and myocardial contraction displayed increased levels whereas proteins of the mitochondrial respiratory electron transport chain displayed decreased levels in ANT1 overexpressing hearts compared to wild type animals. Oxyblot analysis performed to study changes in the protein oxidation did not reveal any significant difference in the oxidative state of the proteins between the wild type and transgenic animals. To understand the influence of ANT1 overexpression in virus induced dilated cardiomyopathy, comparative proteomic analyses was performed for the mitochondrial fractions from the hearts of 8 months old rats of the wild type and ANT1 transgenic animals infected with CVB3. Of a total of 370 identified proteins, 83 proteins displayed altered levels in ANT1 overexpressing animals compared to controls. Proteins related to mitochondrial electron transport chain, fatty acid metabolism, contractility and cell structure displayed decreased levels in the infected transgenic animals compared to controls indicating decreased energy metabolism and myocardial contractility besides compromised cell structure. Besides viral causes of dilated cardiomyopathy, autoimmunity also plays a major role in the development of myocarditis and dilated cardiomyopathy. Therefore proteomic analyses of experimental models of autoimmune myocarditis generated by active immunization of rats with peptides of FcγIIa receptor -CEPPWIQVLKEDTVTL (peptide 1) designated as FcR animals and CRCRMEETGISEPI (peptide 2) designated as FcR2 animals- was performed. Of the 303 proteins identified with at least two peptides by gel-free LC-MS/MS analysis. 43 proteins displayed intensities greater than 1.2 fold in FcR rat hearts and 49 proteins displayed intensities greater than 1.2 fold in FcR2 rat hearts compared to animals injected with KLH adjuvant treated as controls. The majority of the alterations (>70%) were observed in both autoimmune models. Thus, immunization leading to an induction of the acute phase response signalling was observed in both experimental setups. Furthermore, the increased amount of proteins such as lumican or procollagen alpha 1, type 1 indicated the presence of fibrosis after immunization independent of the peptide used. In summary, using proteomics the current thesis addresses the changes in protein profiles of two models of dilated cardiomyopathy, namely, virus induced dilated cardiomyopathy and autoimmunity induced dilated cardiomyopathy in mouse and rat models of disease. 2D-DIGE and gel-free LC-MS/MS analysis are complementary techniques which provided a comprehensive view of the changes in the protein profile of hearts of the different animal models. Altered mitochondrial function resulting in decreased energy metabolism and compromised myocardial contractility were prominent in viral models of cardiomyopathy whereas intense acute phase response signalling was observed as a characteristic feature of autoimmune dilated cardiomyopathy. Altered mitochondrial function was also prominent in age associated changes in the heart of A.BY/SnJ mice indicating the role and influence of mitochondria in health and in disease.