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Emerging zoonotic viruses are a constant threat to human and animal health. Therefore, knowledge about the host factors influencing viral pathogenicity is highly welcome as a basis for developing treatment or vaccine strategies. In order to identify host factors that potentially determine the
pathogenicity of three highly pathogenic (’high consequence’) zoonotic viruses, the interactomes of
selected viral proteins were analysed in parallel with the interactomes of the homologous proteins from closely related viruses which lack high pathogenicity. For this purpose, affinity purification mass spectrometry (AP-MS) was performed with the virus proteins as baits and lists of candidate proteins were generated that may determine the pathotype and warrant follow-up studies to characterise their function concerning the viral life cycles. In detail, the interactomes of virus pairs from the arenaviruses, filoviruses and henipaviruses were studied. The following protein homologues were selected: for filoviruses, the transcription factor VP30, the co-transcription factor VP35 and matrix protein VP40 of the non-pathogenic Reston virus
(RESTV, species Reston ebolavirus), the pathogenic Ebola virus (EBOV, species Zaire ebolavirus),
and, in addition, the Lloviu virus (LLOV, species Lloviu cuevavirus); in case of the arenaviruses
the nucleoprotein (NP), matrix protein (Z) and glycoprotein (GP) of the pathogenic Junín virus (JUNV, species Argentine mammarenavirus) and the non-pathogenic Tacaribe virus (TCRV, species Tacaribe mammarenavirus); and for the henipaviruses, the fusion protein F of the apathogenic Cedar virus (CedV, species Cedar henipavirus) and the pathogenic Nipah virus (NiV, species Nipah henipavirus). The experimental approach was to express the tagged bait proteins in human cells by transfection with appropriate constructs, purify the interactomes by affinity enrichment and analyse their protein content by MS. Quantitation was performed by labelling with stable isotopes or by label-free quantification (LFQ). High-confidence interactions for the LFQ approach were identified using the Mass Spectrometry interaction STatistics (MiST) scoring tool. Qualitative and quantitative data were used to identify a limited number of candidates for follow-up research. Additionally,
the interactomes were analysed with bioinformatical tools like term enrichment analysis and network analysis to identify cellular pathways which are possibly impacted by the expression of viral proteins. A novel specific interactor of EBOV VP30 was identified, ubiquitin carboxyl-terminal hydrolase7
(USP7, also known as HAUSP), and the interaction was partially characterised. The interaction was confirmed by reverse-pull-down experiments, and the Kd value (determined by Microscale Thermophoresis, MST) was found to be lower than for the interaction of USP7 with the RESTV VP30.
This work adds insight into virus protein interactomes, especially for the often neglected low pathogenic virus species. Furthermore, the pathogenicity of the viruses was refl ected to some degree
in the interactomes of their proteins. The generated interactome data for the different virus species
create a basis in the search for interactions that determine pathogenicity.
The anaerobic, gastrointestinal pathogen Clostridioides difficile can cause severe forms of enterocolitis which is mainly mediated by the toxins it produces. The RNA polymerase inhibitor Fidaxomicin is the current gold standard for the therapy of C. difficile infections due to several beneficial features including its ability to suppress toxin synthesis in C. difficile. In contrast to the Rifamycins, Fidaxomicin binds to the RNA polymerase switch region, which is also the binding site for Myxopyronin B. Here, serial broth dilution assays were performed to test the susceptibility of C. difficile and other anaerobes to Myxopyronin B, proving that the natural product is considerably active against C. difficile and that there is no cross-resistance between Fidaxomicin and Myxopyronin B in a Fidaxomicin-resistant C. difficile strain. Moreover, mass spectrometry analysis indicated that Myxopyronin B is able to suppress early phase toxin synthesis in C. difficile to the same degree as Fidaxomicin. Conclusively, Myxopyronin B is proposed as a new lead structure for the design of novel antibiotics for the therapy of C. difficile infections.
The relevance of cold atmospheric plasmas (CAPs) in biomedicine has recently grown. The potential of CAPs has been discussed in multiple scientific works, highlighting its effectiveness in promoting wound healing, limiting cancer progression, and for sterilization of surfaces. Main bioactive molecules, such as reactive oxygen and nitrogen species (RONS), are proposed as key candidates in these processes. Indeed, the generation of cold plasma induces noble gas ionization which, reacting with atmospheric air molecules, generates species such as singlet oxygen, atomic oxygen radicals, nitric oxide radicals. Although molecular simulations have been conducted, the mechanism of action on biological molecules, as well as the possibility to tune plasmas to produce specific species cocktails (e.g., with different degree of oxidation power) has been not fully unleashed. In this dissertation, presented in form of 5 published scientific articles, focus has been placed on the interaction of plasmas with peptides and proteins, which are main biological effectors in cellular compartments. Precisely, through the development of liquid chromatography coupled mass spectrometry (LC-MS) methods, the effects of plasmas on peptides and proteins in form of oxidative post-translational modifications (oxPTMs) has been investigated. The characterization of these oxPTMs has been performed by treating peptide or protein aqueous solutions and on porcine skin tissues. It has been found that, introducing small amounts of different gases (oxygen, nitrogen, or both) or even water molecules, can made CAPs tunable tools to produce oxygen-species dominating effects versus nitrogen-species dominating effects. In addition to this, it was found that the amino acid position in a peptide or protein influences the quality and quantity of the resulting oxPTMs. Besides this, other important parameters like driven gases, admixture gases or treatment duration were identified as relevant factors for the modification of amino acids in the peptide structure. By comparing the effects between peptide solutions and complex matrices such as porcine skin, water has been identified as a valid vehicle to transport and amplify the plasma chemistry. In an experimental study, the inactivation of a protein (PLA2) was observed after CAP treatment and together with simulation studies, the specific dioxidation of tryptophane W128 was detected as a potential explanation for this inactivation, indicating the strong impact of plasma on biological targets. In summary, oxidative modifications found in peptide solutions were observed also in complex protein structures and sample matrices. In conclusion, this work provides a starting point for future studies of oxidative modifications in complex models and may thus be helpful for further investigations in the fields of plasma medicine and redox chemistry.
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.
Microbial cell factories have been largely exploited for the controlled production of recombinant proteins, including industrial enzymes and biopharmaceuticals. The advent of high-throughput ‘-omics’ techniques have boosted the design of these production systems due to their valuable contribution to the field of systems metabolic engineering, a discipline integrating metabolic engineering with systems and synthetic biology. In order to thrive, the field of systems metabolic engineering needs absolute proteomics data to be generated, as proteins are the central players in the complex metabolic and adaptational networks. Due to advent of mass spectrometry-based proteomics, a substantial amount of absolute proteomic data became available in the past decade. However, membrane proteins remained inaccessible to these efforts.
Nonetheless, comparative studies targeting the membrane proteome have been quite successful in characterizing physiological processes. Hence, label-free proteomics was used in a study (Quesada-Ganuza et al, 2019 – Article I) to identify and optimize PrsA in Bacillus subtilis, for improved yield of amylase. Amylase is one of the most relevant enzymes in the biotechnological sector. By employing a label-free mass spectrometry approach targeting the membrane proteome of this bacterium, relative changes in heterologous and native levels of PrsA could be quantified. The results of this study evidenced that each PrsA shows different relative abundancies, but with no relevant impact in the yield of amylase.
Even though relative protein quantification can already provide a good visualization of the physiological changes occurring between different conditions, they are not sufficient to understand how resources are allocated in the cell under certain physiological conditions. Therefore, a global method for absolute membrane protein quantification remains the biggest requirement for systems metabolic engineering.
Hence, with this work, we successfully developed a mass spectrometry-based approach enabling the absolute quantification of membrane proteins (Antelo-Varela et al, 2019 – Article II). This study was also performed in the Gram-positive model organism Bacillus subtilis, regarded as a prolific microbial cell factory. The method developed in this work combines the comprehensiveness of shotgun proteomics with the sensitivity and accuracy of targeted mass spectrometry. Fundamental to the method is that it relies on the application of a correction and an enrichment factor to calibrate absolute membrane protein abundances derived from shotgun mass spectrometry. This has permitted, for the first time reported, the calculation of absolute membrane protein abundances in a living organism.
The newly developed approach enabled to accurately quantify ~40% of the predicted proteome of this bacterium, offering a clear visualization of the physiological rearrangements occurring upon the onset of osmotic stress. In addition, this work also provides evidence for new membrane protein stoichiometries.
Overall, this study enabled the development of a straightforward methodology long-needed in the scientific and biotechnological community and, for the first time reported, providing absolute abundances of one of the most puzzling fractions of the cell – the membrane proteome.
The next step of the work summarized here was to implement the afore described method to a biotechnological relevant strain, as absolute membrane protein abundances are essential to understand the fundamental principles of protein secretion and production stress. Hence, this work was applied in a genome-reduced B. subtilis strain, ‘midiBacillus’, expressing the major staphylococcal antigen IsaA (Antelo-Varela et al, submitted – Article III). The employed absolute membrane protein quantification methodology enabled the analysis of physiological rearrangements occurring upon the induction of heterologous protein production. This work showed that, even though IsaA was successfully secreted into the growth medium, one of the main requirements for the biotechnological sector, it was still partly accumulated in the cell membrane of this bacterium. This led to an exacerbated physiological response where membrane proteins involved in the management of secretion stress were activated. In addition, this study also showed that a rearrangement of the cell’s translocation machinery occurs upon induction of production, where a ‘game’ of in- and decrease of transporters takes place.
Anticipating the impact of genetic and environmental insults, such as the ones caused by production stress, is essential for the field of systems metabolic engineering. Thus, the highly accurate and comprehensive dataset generated during this work can be implemented in predictive mathematical models, thereby contributing in the rational design of next-generation secretion systems.
This work describes the recent scientific and technical achievements obtained at the high-precision Penning trap mass spectrometer SHIPTRAP. The scientific focus of the SHIPTRAP experiment are mass measurements of short-lived nuclides with proton number larger than 100. The masses of these isotopes are usually determined via extrapolations, systematic trends, predictions based on theoretical models or alpha-decay spectroscopy. In several experiments the masses of the isotopes 252-255No and 255,256Lr have been measured directly. With the obtained results the region of enhanced nuclear stability at the deformed shell closure at the neutron number 152 was investigated. Furthermore, the masses have been used to benchmark theoretical mass models. The measured masses were compared selected mass models which revealed differences between few keV/c² up to several MeV/c² depending on the investigated nuclide and model. In order to perform mass measurements on superheavy nuclei with lower production rates, the efficiency of the SHIPTRAP setup needs to be increased. Currently, the efficiency is 2% and mainly limited by the stopping- and extraction efficiency of the buffer gas cell. The stopping and extraction efficiency of the current buffer gas cell is 12%. To this end, a modified version of the buffer gas cell was developed and characterized with 223Ra ion source. Besides a larger stopping volume and a coaxial injection the new buffer gas cell is operated at a temperature of 40K. The operation at cryogenic temperatures increases the cleanliness of the buffer gas. From extraction measurements and simulations an overall efficiency of 62(3)% was determined which results in an increase by a factor of 5 in comparison to the current buffer gas cell. Aside from high-precision mass measurements of heavy radionuclides the mass differences of metastable isobars was measured to identify candidates for the neutrinoless double-electron capture. Neutrinoless double-electron capture can only occur if the neutrino is its own antiparticle and a physics beyond the standard model exists since the neutrinoless double-electron capture violates the conservation of the lepton number. Due to its expected long half-life this decay has not yet been observed. However, the decay rate is resonantly enhanced if mother and daughter nuclide are degenerate in energy. Suitable candidates for the search of the neutrinoless double-electron capture have been identified with mass difference measurements uncertainties of about 100eV/c². In this work the results of the mass difference measurements of 12 possible candidates are presented.