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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.
There is a growing interest in the application of non-thermal atmospheric pressure plasma for the treatment of wounds. Due to the generation of various ROS and RNS, UV radiation and electric fields plasma is a very promising tool which can stimulate skin and immune cells. However, not much is known about the mammalian cell responses after plasma treatments on a molecular level. The present work focusses on the impact of plasma on cell signaling in the human keratinocyte cell line HaCaT by using the methods DNA microarray, qPCR, ELISA and flow cytometry. Here, cell signaling mediators such as cytokines and growth factors which could promote wound healing by enhancing angiogenesis, reepithelization, migration and proliferation were of major interest. Additionally, the crosstalk between keratinocytes and monocytes was studied using a co-culture. For the first time extensive investigations on the impact of plasma on cell signaling in human keratinocytes were conducted. The most prominent cytokines and growth factors which were regulated by plasma at gene and protein level were VEGF-A, GM-CSF, HB-EGF, IL-8, and IL-6. The latter was not activated due to the JAK/STAT-pathway but probably by a combined activation of MAPK- and PI3K/Akt-pathways. By the use of conditioned medium it was found out that ROS and RNS generated directly after plasma treatment induced larger effects on cell signaling in keratinocytes than the subsequently secreted growth factors and cytokines. Furthermore, monocytes and keratinocytes hardly altered their secretion profiles in co-culture. From these results it is deduced that the plasma generated reactive species are the main actors during cell signaling. In order to differentiate the impact of ROS and RNS on the cellular response the ambience of the plasma effluent was controlled, varying the ambient gas composition from pure nitrogen to pure oxygen. Thereby a first step towards the attribution of the cellular response to specific plasma generated reactive species was achieved. While IL-6 expression correlated with ROS generated by the plasma source, the cell signaling mediators VEGF-A, GM-CSF and HB-EGF were significantly changed by RONS. Above all hydrogen peroxide was found to play a dominant role for observed cell responses. In summary, plasma activates wound healing related cell signaling mediators as cytokines and growth factors in keratinocytes. It was also shown that the generated reactive species mainly induced cell signaling. For the first time cell responses can be correlated to ROS and RONS in plasma treated cells. These results underline the potential of non-thermal atmospheric pressure plasma sources for their applications in wound treatment.
Protein quality control systems are essential for the viability and growth of all living organisms. They protect the cell from irreversible protein aggregation. Because the frequency of protein misfolding, which ultimately results in protein aggregation, varies with the environmental conditions, the amount and activity of protein quality systems have to be accurately adapted to the rate of protein misfolding. The main goal of this thesis was to gain detailed molecular insights into the transcriptional and post-translational regulation of these protein quality control networks in the ecologically, medically and industrially important phylum of low GC, Gram-positive bacteria. In these bacteria the core protein quality control systems are under the transcriptional control of the global repressor CtsR. In a first study it was demonstrated that the arginine kinase McsB is not responsible for the regulation of CtsR activity during heat stress, as was concluded by others on the basis of previous in vitro data. Rather, it was demonstrated that CtsR acts as an intrinsic thermosensor that adapts its activity to the surrounding temperature. CtsR displays a decreased DNA binding at higher temperatures, which leads to induction of transcription of the protein quality control systems under these conditions. This CtsR feature is conserved in all low GC, Gram-positive bacteria. However, the CtsR proteins of various low GC, Gram-positive species do not have the same temperature optima. CtsR responds to heat in a species-specific manner according to their corresponding growth temperature. Detailed analysis revealed that a highly conserved tetra-glycine loop within the winged helix-turn-helix domain of CtsR is responsible for thermosensing. Dual control of CtsR activity during different stresses was demonstrated for the first time in this work. In addition to heat-dependent de-repression, CtsR is inactivated by thiol-specific stress conditions. This latter de-repression depends on a molecular redox-switch that is independent of CtsR auto-regulation. In Bacillus subtilis and its closest relatives the McsA/McsB stress-sensing complex is responsible for CtsR de-repression during redox stress conditions. McsA is able to sense the redox state of the cell via its highly conserved cysteine residues. When these cysteines are reduced, McsA is able to bind and inhibit McsB. But when these cysteine residues are oxidized, McsB is released from McsA. Thereby, McsB is activated and removes CtsR from the DNA. However, the McsA/McsB complex is not present in all low GC, Gram-positive bacteria. In the species lacking this complex, ClpE is able to act as a redox-sensor probably via its highly conserved N-terminal zinc finger domain. When these cysteine residues are oxidized, ClpE is activated which results in CtsR de-repression. In addition to the transcriptional regulation of CtsR low GC, Gram-positive protein quality control systems are regulated post-transcriptionally. The expression of the McsA/McsB adaptor pair is regulated by CtsR. However, McsB activity is also tightly regulated by three different regulatory proteins (McsA/ClpC/YwlE). McsB is needed to target specific substrates to ClpC, either for refolding or degradation by the ClpCP protease. It was demonstrated that only the auto- phosphorylated form of McsB is able to bind to its substrates. This McsB function is inhibited in non-stressed cells by a direct interaction with ClpC. Consequently, McsB is activated by a release from ClpC during protein stress. In addition, McsB activation depends on the presence of its activator McsA. Accordingly, McsB cannot be activated as an adaptor protein during thiol-specific stress because McsA is no longer able to bind to McsB under these conditions. However, also active McsB is subject to post-translational control. Activated McsB is either de-phosphorylated by McaP or degraded by ClpCP ensuring an appropriate shut-down of the McsB adaptor. Both McaP and ClpC inhibit McsB activity with different intensities. ClpC possesses a stronger impact on McsB activity than McaP but both proteins are needed for an adequate silencing of McsB activity. In addition, it was shown for the first time that B. subtilis McsB is a global adaptor that influences the stability of multiple proteins. The B. subtilis ClpC protein is unlike most members of the Hsp100 family because it not only requires several adaptor proteins for substrate recognition but also for its general ATP- dependent activity. Biochemical analysis revealed how ClpC is activated by distinct adaptor proteins. McsB modulates ClpC activity by regulatory phosphorylation of arginine residues. Moreover, McaP (formerly YwlE) was identified as an arginine phosphatase that modulates the McsB mediated ClpC activity. MecA, another known adaptor protein for ClpC, activates ClpC independently of these arginine phosphorylations, which demonstrates the existence of multiple pathways for ClpC activation.