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Posttranslationale Proteinmodifikationen beeinflussen Proteinaktivitäten und Signalwege innerhalb einer Zelle und haben somit vielfältige Auswirkungen auf den Stoffwechsel von Bakterien. Um die genauen Mechanismen besser verstehen zu können, wurde in dieser Arbeit das Phosphoproteom von Streptococcus pneumoniae D39 untersucht. Der Schwerpunkt lag dabei in der Entwicklung besserer Auswertestrategien und der damit einhergehenden verbesserten Identifizierung von Phosphoproteinen. Um dies zu bewerkstelligen, wurden die Proteinextrakte durch gelfreie und gelbasierte Methoden aufgetrennt. Die Auswertung der Experimente erfolgte zunächst durch klassische Proteinidentifizierung mit Hilfe von Proteindatenbanken. Zusätzlich wurden Spektrenbibliotheken von S. pneumoniae D39 aufgebaut und diese für eine bessere Proteinidentifizierung sowie Phosphoproteinidentifizierung genutzt. Anschließend wurden zur Quantifizierung des Phosphoproteoms dieses Pathogens verschiedene Quantifizierungsmethoden getestet und modifiziert. Hierbei wurde zum einen das Phosphoproteom einer Kinasedeletionsmutante von S. pneumoniae D39 über die Spotintensitäten von 2D Gelen mit dem Wildtyp verglichen. Zusätzlich wurden die Auswirkungen dieser Kinase auf das globale S. pneumoniae D39 Proteom mittels SILAC sowie der neu erstellten Spektrenbibliothek aufgezeigt. Eine weitere etablierte Quantifizierungsmethode für Phosphoproteine in der Arbeit war die Kombination von metabolischer Markierung und 2D Gelen. Die Veränderung des Phosphoproteoms wurde an dem industriell bedeutsamen Bakterium Bacillus pumilus anhand von oxidativem Stress aufgezeigt.
Numerous signalling pathways orchestrate the development, the functions, and the survival of cells, mostly in response to external stimuli. An overwhelming amount of data supports the concept of specific, spatio-temporal redox signalling pathways that affect the redox state of protein cysteinyl side chains and thus the biological function of these proteins. Glutaredoxins (Grxs) and thioredoxins (Trxs) catalyse reversible thiol-disulphide exchange reactions. The cytosolic Grx2 isoform Grx2c is essential for brain development and axonal outgrowth. A reversible dithiol-disulphide switch of CRMP2 has been identified as one of the major targets regulated by Grx2c. This CRMP2 redox switch is toggled in neuronal differentiation. Reduction of CRMP2 thiols induces profound conformational changes, modifying interactions and downstream elements of this redox switch. In [article I] and [manuscript V], we identified the Cys504 of CRMP2 to be the redox regulated residue. We used various in vitro assays with recombinant protein and molecular dynamics simulations to characterise the conformational change. The changes involve the solvent accessible surface area of at least one known phosphorylation site at the C-terminus of the protein. In [article III], we analysed the function of Grx2 and Trx1 in a model for perinatal asphyxia. Trx family proteins exhibit a very complex, cell-type and tissue specific expression pattern following hypoxia/ischemia and reoxygenation, especially Trx1 and Grx2. The results imply the clinical relevance for both proteins in perinatal asphyxia as well as many other neurological disorders. In agreement with the results presented in [articleI], Grx2 may be required for the re-establishment of neuronal integrity and connectivity. Cell shape, all forms of intracellular transport, and cell movement depend on the cytoskeleton, particularly on the fine tuned complex regulation of the dynamic re-arrangement of actin filaments and microtubules. In [article IV], we discuss the redox regulation of this dynamic cytoskeletal remodelling. Taking recent discoveries into account, we focus on redox signalling mechanisms, e.g. reversible thiol and methionyl switches. These switches are specifically controlled by enzymes such as Trx1 and Grx2c, for instance, and not the result of random modification by unspecific oxidants. Methionyl sulphoxidation of actin can be reversed by methionyl sulphoxide reductase (MsrA), promoting actin polymerisation. Human cells express two different Msr enzymes (MsrA and MsrB), that can reduce S- and R-methionyl sulphoxide, respectively. In the gram-positive Streptococcus pneumoniae, on the other hand, both Msr genes and thus enzymes were fused during evolution. In [article II], we characterised the surface-exposed thioredoxin family lipoproteins Etrx1 and 2 and regulators of this Msr (SpMsrAB). A loss of function of both Etrx proteins or SpMsrAB dramatically reduced pneumococcal virulence, enhanced the bacterial uptake by macrophages, and accelerated pneumococcal killing by H2O2 or free methionine sulphoxide. Identification and characterisation of components of this redox regulated system may contribute to the design of new antimicrobials. In [manuscript VI], we investigated the effects of Grx2c expression on cell morphology, migration, and invasion behaviour of cancer cells. Grx2c expressing cancer cells developed dramatic changes in phenotype, including alterations in cytoskeletal dynamics and significantly increased motility and invasiveness. We used quantitative proteomics and phopshoproteomic approaches to characterise the underlying mechanisms. Proteins and pathways regulating cytoskeletal dynamics, cell adhesion, and receptor-mediated signal transduction were detected to be specifically altered. We started a clinical pilot study with patients suffering from clear cell renal cell carcinoma (ccRCC). Grx2c was expressed with significantly higher frequency in ccRCC compared to healthy kidney tissue, associated with a strong trend for locally more advanced tumour stages and a clear tendency for a decreased cancer-specific survival, compared to patients without detectable Grx2c. These results were supported by data from "The Cancer Genome Atlas". In synopsis, the results presented and discussed in these articles and manuscripts, support the concept of specific redox signalling in different models and model organisms. They also demonstrate the importance of the specific redox control of signalling pathways that, in the case of errors or misinterpretations, contribute to pathophysiological alterations. The regulation of the CRMP2 redox switch by Grx2c, for instance, is physiologically essential for brain development, but might lead to cancer progression, if "switched on" in adult tissue. Identification of further interaction partners as well as the development of compounds modulating this redox switch and CRMP2s conformations, will be part of our future research.
Transfusion-related acute lung injury (TRALI) is an adverse transfusion reaction and the major cause of transfusion-related mortality. The syndrome occurs within six hours after transfusion and is characterized by acute respiratory distress and the occurrence of a non-cardiogenic, bilateral lung edema. TRALI is almost entirely induced by leukocyte-reactive substances which are present in the blood product and get transferred to the recipient during transfusion. The majority of cases (~80%) is caused by leukocyte-reactive immunoglobulins and is accordingly classified as immune-mediated TRALI. The responsible antibodies are generated via alloimmunization and are directed against human leukocyte antigens of class I and II or human neutrophil alloantigens (HNA). Within the HNA class, HNA-3a antibodies have an exceptional clinical relevance as they are most frequently involved in severe and fatal TRALI cases. The high mortality was associated with their characteristic ability to induce a strong neutrophil aggregation response. The described clinical relevance of HNA-3a antibody-mediated TRALI motivates the screening for new strategies for preventive or acute pharmacologic intervention. Knowledge of the molecular pathomechanisms is a crucial prerequisite and thus, respective investigations are required. In order to achieve this goal, HNA-3a antibody-induced cytotoxicity and aggregation were assessed on the molecular level by usage of flow cytometry, the granulocyte agglutination test and by phosphoproteome analysis. The current study provides insight into molecular processes during HNA-3a antibody-induced neutrophil responses and is the first to assess neutrophils using global, gel-free phosphoproteome analyses. Accordingly, it is the first to provide neutrophil phosphoproteome data in the context of TRALI. Gel-free phosphoproteome analyses of primary neutrophils required the highly selective and sensitive phosphopeptide enrichment from stable and sufficiently large protein extracts. However, an appropriate workflow did not exist and was hence developed by sequential protocol optimization steps. The developed workflow was finally proven suitable for comparative gel-free phosphoproteomics when detecting the formyl-methionyl-leucyl-phenylalanine-induced activation of extracellular signal-regulated kinase 1/2 (ERK1/2) signaling in a proof-of-principle experiment. The following single parameter analyses were conducted to investigate neutrophils for their responses to HNA-3a antibodies in absence and presence of proinflammatory priming conditions. Results revealed that the direct stimulation of neutrophils with HNA-3a antibodies will likely not cause the induction of cytotoxic effector functions. In contrast, neutrophils react predominantly by aggregation, a process which is potentially mediated by integrins and causes a secondary, subthreshold activation of solely ERK2. Accordingly, only the neutrophil aggregation response could also be enhanced by an appropriate priming. Taken together, the single parameter analyses proved neutrophil aggregation as the main pathomechanism in HNA-3a antibody-mediated TRALI and thus, the underlying signaling pathways were investigated by global, gel-free phosphoproteomics. The following phosphoproteome analyses indicated the induction of a biphasic signaling during 30 minutes of HNA-3a antibody treatment and signaling pathways of Rho family GTPases could be associated with the first and the second phase. Additionally, the involvement of ERK signaling was indicated in the second phase and this result corroborated thus the data of the previous single parameter analyses. The comprehensive analysis of the identified signaling pathways revealed Rho, Rac and Cdc42 as central regulators and the specific inhibition of Rho in the following validating experiments led very intriguingly to a significant enhancement of HNA-3a antibody-mediated neutrophil aggregation. Hence, this result indicated a potential inhibitory effect of HNA-3a antibodies on Rho activity. Therefore, Rho inhibition was suggested to occur in parallel to an adhesion-inducing signaling pathway and might hence be involved in the stabilization of neutrophil aggregates in HNA-3a antibody-induced TRALI. The results from this doctoral thesis contributed to the generation of a new pathogenesis model for HNA-3a antibody-mediated TRALI. In this model, neutrophils respond to direct HNA-3a antibody exposure predominantly by homotypic aggregation. These potentially very stable and primed aggregates accumulate in the lung and are susceptible to parallel, proinflammatory stimulation. Subsequently, this cascade leads to full neutrophil activation and finally to TRALI induction.