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- Helmholtz Institute for RNA-based Infection Research (HIRI) (7)
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- CAPES - Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - the development agency of the Brazilian Federal Government (1)
- CBIO, University of Cape Town, South Africa (1)
- Carl-Ludwig-Institut für Physiologie, Universität Leipzig (1)
- Chair of Experimental Biomedicine I (1)
Aging is known to be a risk factor for structural abnormalities and functional decline in the nervous system. Characterizing age-related changes is important to identify putative pathways to overcome deleterious effects and improve life quality for the elderly. In this study, the peripheral nervous system of 24-month-old aged C57BL/6 mice has been investigated and compared to 12-month-old adult mice. Aged mice showed pathological alterations in their peripheral nerves similar to nerve biopsies from elderly human individuals, with nerve fibers showing demyelination and axonal damage. Such changes were lacking in nerves of adult 12-month-old mice and adult, non-aged humans. Moreover, neuromuscular junctions of 24-month-old mice showed increased denervation compared to adult mice. These alterations were accompanied by elevated numbers of macrophages in the peripheral nerves of aged mice. The neuroinflammatory conditions were associated with impaired myelin integrity and with a decline of nerve conduction properties and muscle strength in aged mice.
To determine the pathological impact of macrophages in the aging mice, macrophage depletion was performed in mice by oral administration of CSF-1R specific kinase (c-FMS) inhibitor PLX5622 (300 mg/kg body weight), which reduced the number of macrophages in the peripheral nerves by 70%. The treated mice showed attenuated demyelination, less muscle denervation and preserved muscle strength. This indicates that macrophage-driven inflammation in the peripheral nerves is partially responsible for the age-related neuropathy in mice.
Based on previous observations that systemic inflammation can accelerate disease progression in mouse models of neurodegenerative diseases, it was hypothesized that systemic inflammation can exacerbate the peripheral neuropathy found in aged mice. To investigate this hypothesis, aged C57BL/6 mice were intraperitoneally injected with a single dose of lipopolysaccharide (LPS; 500 μg/kg body weight) to induce systemic inflammation by mimicking bacterial infection, mostly via activation of Toll-like receptors (TLRs). Altered endoneurial macrophage activation, highlighted by Trem2 downregulation, was found in LPS injected aged mice one month after injection. This was accompanied by a so far rarely observed form of axonal perturbation, i.e., the occurrence of “dark axons” characterized by a damaged cytoskeleton and an increased overall electron density of the axoplasm. At the same time, however, LPS injection reduced demyelination and muscle denervation in aged mice. Interestingly, TREM2 deficiency in aged mice led to similar changes to LPS injection. This suggests that LPS injection likely mitigates aging-related demyelination and muscle denervation via Trem2 downregulation.
Taken together, this study reveals the role of macrophage-driven inflammation as a pathogenic mediator in age-related peripheral neuropathy, and that targeting macrophages might be an option to mitigate peripheral neuropathies in aging individuals. Furthermore, this study shows that systemic inflammation may be an ambivalent modifier of age-related nerve damage, leading to a distinct type of axonal perturbation, but in addition to functionally counteracting, dampened demyelination and muscle denervation. Translationally, it is plausible to assume that tipping the balance of macrophage polarization to one direction or the other may determine the functional outcome in the aging peripheral nervous system of the elderly.
Among the defense strategies developed in microbes over millions of years, the innate adaptive CRISPR-Cas immune systems have spread across most of bacteria and archaea. The flexibility, simplicity, and specificity of CRISPR-Cas systems have laid the foundation for CRISPR-based genetic tools. Yet, the efficient administration of CRISPR-based tools demands rational designs to maximize the on-target efficiency and off-target specificity. Specifically, the selection of guide RNAs (gRNAs), which play a crucial role in the target recognition of CRISPR-Cas systems, is non-trivial. Despite the fact that the emerging machine learning techniques provide a solution to aid in gRNA design with prediction algorithms, design rules for many CRISPR-Cas systems are ill-defined, hindering their broader applications.
CRISPR interference (CRISPRi), an alternative gene silencing technique using a catalytically dead Cas protein to interfere with transcription, is a leading technique in bacteria for functional interrogation, pathway manipulation, and genome-wide screens. Although the application is promising, it also is hindered by under-investigated design rules. Therefore, in this work, I develop a state-of-art predictive machine learning model for guide silencing efficiency in bacteria leveraging the advantages of feature engineering, data integration, interpretable AI, and automated machine learning. I first systematically investigate the influential factors that attribute to the extent of depletion in multiple CRISPRi genome-wide essentiality screens in Escherichia coli and demonstrate the surprising dominant contribution of gene-specific effects, such as gene expression level. These observations allowed me to segregate the confounding gene-specific effects using a mixed-effect random forest (MERF) model to provide a better estimate of guide efficiency, together with the improvement led by integrating multiple screens. The MERF model outperformed existing tools in an independent high-throughput saturating screen. I next interpret the predictive model to extract the design rules for robust gene silencing, such as the preference for cytosine and disfavoring for guanine and thymine within and around the protospacer adjacent motif (PAM) sequence. I further incorporated the MERF model in a web-based tool that is freely accessible at www.ciao.helmholtz-hiri.de.
When comparing the MERF model with existing tools, the performance of the alternative gRNA design tool optimized for CRISPRi in eukaryotes when applied to bacteria was far from satisfying, questioning the robustness of prediction algorithms across organisms. In addition, the CRISPR-Cas systems exhibit diverse mechanisms albeit with some similarities. The captured predictive patterns from one dataset thereby are at risk of poor generalization when applied across organisms and CRISPR-Cas techniques. To fill the gap, the machine learning approach I present here for CRISPRi could serve as a blueprint for the effective development of prediction algorithms for specific organisms or CRISPR-Cas systems of interest. The explicit workflow includes three principle steps: 1) accommodating the feature set for the CRISPR-Cas system or technique; 2) optimizing a machine learning model using automated machine learning; 3) explaining the model using interpretable AI. To illustrate the applicability of the workflow and diversity of results when applied across different bacteria and CRISPR-Cas systems, I have applied this workflow to analyze three distinct CRISPR-Cas genome-wide screens. From the CRISPR base editor essentiality screen in E. coli, I have determined the PAM preference and sequence context in the editing window for efficient editing, such as A at the 2nd position of PAM, A/TT/TG downstream of PAM, and TC at the 4th to 5th position of gRNAs. From the CRISPR-Cas13a screen in E. coli, in addition to the strong correlation with the guide depletion, the target expression level is the strongest predictor in the model, supporting it as a main determinant of the activation of Cas13-induced immunity and better characterizing the CRISPR-Cas13 system. From the CRISPR-Cas12a screen in Klebsiella pneumoniae, I have extracted the design rules for robust antimicrobial activity across K. pneumoniae strains and provided a predictive algorithm for gRNA design, facilitating CRISPR-Cas12a as an alternative technique to tackle antibiotic resistance.
Overall, this thesis presents an accurate prediction algorithm for CRISPRi guide efficiency in bacteria, providing insights into the determinants of efficient silencing and guide designs. The systematic exploration has led to a robust machine learning approach for effective model development in other bacteria and CRISPR-Cas systems. Applying the approach in the analysis of independent CRISPR-Cas screens not only sheds light on the design rules but also the mechanisms of the CRISPR-Cas systems. Together, I demonstrate that applied machine learning paves the way to a deeper understanding and a broader application of CRISPR-Cas systems.
Development and application of computational tools for RNA-Seq based transcriptome annotations
(2019)
In order to understand the regulation of gene expression in organisms, precise genome annotation is essential. In recent years, RNA-Seq has become a potent method for generating and improving genome annotations. However, this Approach is time consuming and often inconsistently performed when done manually. In particular, the discovery of non-coding RNAs benefits strongly from the application of RNA-Seq data but requires significant amounts of expert knowledge and is labor-intensive. As a part of my doctoral study, I developed a modular tool called ANNOgesic that can detect numerous transcribed genomic features, including non-coding RNAs, based on RNA-Seq data in a precise and automatic fashion with a focus on bacterial and achaeal species. The software performs numerous analyses and generates several visualizations. It can generate annotations of high-Resolution that are hard to produce using traditional annotation tools that are based only on genome sequences. ANNOgesic can detect numerous novel genomic Features like UTR-derived small non-coding RNAs for which no other tool has been developed before. ANNOgesic is available under an open source license (ISCL) at https://github.com/Sung-Huan/ANNOgesic.
My doctoral work not only includes the development of ANNOgesic but also its application to annotate the transcriptome of Staphylococcus aureus HG003 - a strain which has been a insightful model in infection biology. Despite its potential as a model, a complete genome sequence and annotations have been lacking for HG003. In order to fill this gap, the annotations of this strain, including sRNAs and their functions, were generated using ANNOgesic by analyzing differential RNA-Seq data from 14 different samples (two media conditions with seven time points), as well as RNA-Seq data generated after transcript fragmentation. ANNOgesic was
also applied to annotate several bacterial and archaeal genomes, and as part of this its high performance was demonstrated. In summary, ANNOgesic is a powerful computational tool for RNA-Seq based annotations and has been successfully applied to several species.
Thermoplastic polymers have a history of decades of safe and effective use in the clinic as implantable medical devices. In recent years additive manufacturing (AM) saw increased clinical interest for the fabrication of customizable and implantable medical devices and training models using the patients’ own radiological data. However, approval from the various regulatory bodies remains a significant hurdle. A possible solution is to fabricate the AM scaffolds using materials and techniques with a clinical safety record, e.g. melt processing of polymers. Melt Electrowriting (MEW) is a novel, high resolution AM technique which uses thermoplastic polymers. MEW produces scaffolds with microscale fibers and precise fiber placement, allowing the control of the scaffold microarchitecture. Additionally, MEW can process medical-grade thermoplastic polymers, without the use of solvents paving the way for the production of medical devices for clinical applications. This pathway is investigated in this thesis, where the layout is designed to resemble the journey of a medical device produced via MEW from conception to early in vivo experiments. To do so, first, a brief history of the development of medical implants and the regenerative capability of the human body is given in Chapter 1. In Chapter 2, a review of the use of thermoplastic polymers in medicine, with a focus on poly(ε-caprolactone) (PCL), is illustrated, as this is the polymer used in the rest of the thesis. This review is followed by a comparison of the state of the art, regarding in vivo and clinical experiments, of three polymer melt AM technologies: melt-extrusion, selective laser sintering and MEW. The first two techniques already saw successful translation to the bedside, producing patient-specific, regulatory-approved AM implants. To follow in the footsteps of these two technologies, the MEW device parameters need to be optimized. The MEW process parameters and their interplay are further discussed in Chapter 3 focusing on the importance of a steady mass flow rate of the polymer during printing. MEW reaches a balance between polymer flow, the stabilizing electric field and moving collector to produce reproducible, high-resolution scaffolds. An imbalance creates phenomena like fiber pulsing or arcing which result in defective scaffolds and potential printer damage. Chapter 4 shows the use of X-ray microtomography (µCT) as a non-destructive method to characterize the pore-related features: total porosity and the pore size distribution. MEW scaffolds are three-dimensional (3D) constructs but have long been treated in the literature as two-dimensional (2D) ones and characterized mainly by microscopy, including stereo- and scanning electron microscopy, where pore size was simply reported as the distance between the fibers in a single layer. These methods, together with the trend of producing scaffolds with symmetrical pores in the 0/90° and 0/60/120° laydown patterns, disregarded the lateral connections between pores and the potential of MEW to be used for more complex 3D structures, mimicking the extracellular matrix. Here we characterized scaffolds in the aforementioned symmetrical laydown patterns, along with the more complex 0/45/90/135° and 0/30/60/90/120/150° ones. A 2D pore size estimation was done first using stereomicroscopy, followed by and compared to µCT scanning. The scaffolds with symmetrical laydown patterns resulted in the predominance of one pore size, while those with more complex patterns had a broader distribution, which could be better shown by µCT scans. Moreover, in the symmetrical scaffolds, the size of 3D pores was not able to reach the value of the fiber spacing due to a flattening effect of the scaffold, where the thickness of the scaffold was less than the fiber spacing, further restricting the pore size distribution in such scaffolds. This method could be used for quality assurance of fabricated scaffolds prior to use in in vitro or in vivo experiments and would be important for a clinical translation. Chapter 5 illustrates a proof of principle subcutaneous implantation in vivo experiment. MEW scaffolds were already featured in small animal in vivo experiments, but to date, no analysis of the foreign body reaction (FBR) to such implants was performed. FBR is an immune reaction to implanted foreign materials, including medical devices, aimed at protecting the host from potential adverse effects and can interfere with the function of some medical implants. Medical-grade PCL was used to melt electrowrite scaffolds with 50 and 60 µm fiber spacing for the 0/90° and 0/60/120° laydown patterns, respectively. These implants were implanted subcutaneously in immunocompetent, outbred mice, with appropriate controls, and explanted after 2, 4, 7 and 14 days. A thorough characterization of the scaffolds before implantation was done, followed by a full histopathological analysis of the FBR to the implants after excision. The scaffolds, irrespective of their pore geometry, induced an extensive FBR in the form of accumulation of foreign body giant cells around the fiber walls, in a manner that almost occluded available pore spaces with little to no neovascularization. This reaction was not induced by the material itself, as the same reaction failed to develop in the PCL solid film controls. A discussion of the results was given with special regard to the literature available on flat surgical meshes, as well as other hydrogel-based porous scaffolds with similar pore sizes. Finally, a general summary of the thesis in Chapter 6 recapitulates the most important points with a focus on future directions for MEW.
Myocardial infarction (MI) is a leading cause of death worldwide. Timely restoration of coronary blood flow to ischemic myocardium significantly reduces acute infarct mortality and attenuates ventricular remodeling. However, surviving MI patients frequently develop heart failure, which is associated with reduced quality of life, high mortality rate (10% annually), as well as high healthcare expenditures. The main processes involved in the evolution of heart failure post-MI are the great loss of contractile cardiomyocytes during ischemia-reperfusion and the subsequent complex structural and functional alterations, which are rooted in modifications at molecular and cellular levels in both the infarcted and non-infarcted myocardium. However, we still lack efficient treatments to prevent the development and progression of left ventricular remodeling. The improved survival rate of acute MI patients combined with the lack of effective therapy for post-MI remodeling contributes to the high prevalence of heart failure. Cardiac Magnetic Resonance Imaging (MRI) is an important tool for diagnosis and assessment of MI. With the advancement of this technology, the frontier of MRI has been extended to probing molecular and cellular events in vivo and non-invasively. In combination with assessment of morphology and function, the visualization of essential molecular and cellular markers in vivo could provide comprehensive, multifaceted views of the healing process in infarcted hearts, which might give new insight for the treatment of acute MI. In this thesis, molecular and cellular cardiac MRI methods were established to visualize and investigate inflammation and calcium flux in the healing process of acute MI in vivo, in a clinically relevant rat model.
RNA is one of the most abundant macromolecules and plays essential roles in numerous biological processes. This doctoral thesis consists of two projects focusing on RNA structure and RNA-RNA interactions in viral genome packaging. In the first project I developed a method called Functional Analysis of RNA Structure (FARS-seq) to investigate structural features regulating genome dimerization within the HIV-1 5’UTR. Genome dimerization is a conserved feature of retroviral replication and is thought to be a prerequisite for binding to the viral structural protein Pr55Gag during genome packaging. It also plays a role in genome integrity and evolution through recombination, and is linked to a structural switch that may regulate genome packaging and translation within cells. Despite its importance for HIV-1 replication, the RNA signals regulating genome dimerization, and the molecular mechanism leading to the selection of the genome dimer over the monomer for packaging are incompletely understood. The FARS-seq method combines RNA structural information obtained by chemical probing with single nucleotide resolution profiles of RNA function obtained by mutational interference. In this way, we found nucleotides that were critical for dimerization, especially within the well-characterized dimerization motif within stem-loop 1 (SL1). We also found stretches of nucleotides that enhanced genome dimerization upon mutation, suggesting their role in negatively regulating dimerization. A structural analysis identified distinct structural signatures within monomeric and dimeric RNA. The dimeric conformation displayed the canonical transactivation response (TAR), PolyA, primer binding site (PBS), and SL1-SL3 stem-loops, and contained a long range U5-AUG interaction. Unexpectedly, in monomeric RNA, SL1 was reconfigured into long- and short-range base-pairings with PolyA and PBS, respectively. Intriguingly, these base pairings concealed the palindromic sequence needed for dimerization and disrupted the internal loop in SL1 previously shown to contain the major packaging motif for Pr55Gag. We therefore rationally introduced mutations into PolyA and PBS, and showed how these regions regulate genome dimerization, and the binding of Pr55Gag in vitro, as well as genome packaging into virions. These findings give insights into late stages of the HIV-1 life cycle and a mechanistic explanation for the link between RNA dimerization and packaging.
In the second project, I developed a proximity ligation and high-throughput sequencing-based method, RNA-RNA seq, which can measure direct (RNA-RNA) and indirect (protein-mediated) interactions. In contrast to existing methods, RNA-RNA seq is not limited by specific protein or RNA baits, nor to a particular crosslinking reagent. The genome of influenza A virus contains eight segments, which assemble into a “7+1” supramolecular complex. However, the molecular details of genome assembly are poorly understood. Our goal is to use RNA-RNA seq to identify the sites of interaction between the eight genomic RNAs of influenza, and to use this information to define the quaternary RNA architecture of the genome. We showed that RNA-RNA seq worked on model substrates, like the HIV-1 Dimerization Initiation Site (DIS) RNA and purified ribosome, as well as influenza A virus infected cells.
The learned helplessness phenomenon is a specific animal behavior induced by prior exposure to uncontrollable aversive stimuli. It was first found by Seligman and Maier (1967) in dogs and then has been reported in many other species, e.g. in rats (Vollmayr and Henn, 2001), in goldfishes (Padilla, 1970), in cockroaches (Brown, 1988) and also in fruit flies (Brown, 1996; Bertolucci, 2008). However, the learned helplessness effect in fruit flies (Drosophila melanogaster) has not been studied in detail. Thus, in this doctoral study, we investigated systematically learned helplessness behavior of Drosophila for the first time.
Three groups of flies were tested in heatbox. Control group was in the chambers experiencing constant, mild temperature. Second group, master flies were punished in their chambers by being heated if they stopped walking for 0.9s. The heat pulses ended as soon as they resumed walking again. A third group, the yoked fly, was in their chambers at the same time. However, their behavior didn’t affect anything: yoked flies were heated whenever master flies did, with same timing and durations. After certain amount of heating events, yoked flies associated their own behavior with the uncontrollability of the environment. They suppressed their innate responses such as reducing their walking time and walking speed; making longer escape latencies and less turning around behavior under heat pulses. Even after the conditioning phase, yoked flies showed lower activity level than master and control flies. Interestingly, we have also observed sex dimorphisms in flies. Male flies expressed learned helplessness not like female flies. Differences between master and yoked flies were smaller in male than in female flies. Another interesting finding was that prolonged or even repetition of training phases didn’t enhance learned helplessness effect in flies.
Furthermore, we investigated serotonergic and dopaminergic nervous systems in learned helplessness. Using genetic and pharmacological manipulations, we altered the levels of serotonin and dopamine in flies’ central nervous system. Female flies with reduced serotonin concentration didn’t show helpless behavior, while the learned helplessness effect in male flies seems not to be affected by a reduction of serotonin. Flies with lower dopamine level do not display the learned helplessness effect in the test phase, suggesting that with low dopamine the motivational change in learned helplessness in Drosophila may decline faster than with a normal dopamine level.
Neisseria gonorrhoeae (GC) is a human specific pathogenic bacterium. Currently, N. gonorrhoeae developed resistance to virtually all the available antibiotics used for treatment. N. gonorrhoeae starts infection by colonizing the cell surface, followed by invasion of the host cell, intracellular persistence, transcytosis and exit into the subepithelial space. Subepithelial bacteria can reach the bloodstream and disseminate to other tissues causing systemic infections, which leads to serious conditions such as arthritis and pneumonia. A number of studies have well established the host-pathogen interactions during the initial adherence and invasion steps. However, the mechanism of intracellular survival and traversal is poorly understood so far. Hence, identification of novel bacterial virulence factors and host factors involved in the host-pathogen interaction is a crucial step in understanding disease development and uncovering novel therapeutic approaches. Besides, most of the previous studies about N. gonorrhoeae were performed in the conventional cell culture. Although they have provided insights into host-pathogen interactions, much information about the native infection microenvironment, such as cell polarization and barrier function, is still missing.
This work focused on determining the function of novel bacterial virulence factor NGFG_01605 and host factor (FLCN) in gonococcal infection. NGFG_01605 was identified by Tn5 transposon library screening. It is a putative U32 protease. Unlike other proteins in this family, it is not secreted and has no ex vivo protease activity. NGFG_01605 knockout decreases gonococcal survival in the epithelial cell. 3D models based on T84 cell was developed for the bacterial transmigration assay. NGFG_01605 knockout does not affect gonococcal transmigration.
The novel host factor FLCN was identified by shRNA library screening in search for factors that affected gonococcal adherence and/or internalization. We discovered that FLCN did not affect N. gonorrhoeae adherence and invasion but was essential for bacterial survival. Since programmed cell death is a host defence mechanism against intracellular pathogens, we further explored apoptosis and autophagy upon gonococcal infection and determined that FLCN did not affect apoptosis but inhibited autophagy. Moreover, we found that FLCN inhibited the expression of E-cadherin. Knockdown of E- cadherin decreased the autophagy flux and supported N. gonorrhoeae survival. Both non-polarized and polarized cells are present in the cervix, and additionally, E-cadherin represents different polarization properties on these different cells. Therefore, we established 3-D models to better understand the functions of FLCN. We discovered that FLCN was critical for N. gonorrhoeae survival in the 3-D environment as well, but not through inhibiting autophagy. Furthermore, FLCN inhibits the E-cadherin expression and disturbs its polarization in the 3-D models. Since N. gonorrhoeae can cross the epithelial cell barriers through both cell-cell junctions and transcellular migration, we further explored the roles FLCN and E-cadherin played in transmigration. FLCN delayed N. gonorrhoeae transmigration, whereas the knockdown of E-cadherin increased N. gonorrhoeae transmigration.
In summary, we revealed roles of the NGFG_01605 and FLCN-E-cadherin axis play in N. gonorrhoeae infection, particularly in relation to intracellular survival and transmigration. This is also the first study that connects FLCN and human-specific pathogen infection.
Chlamydia trachomatis (Ct) is an obligate intracellular human pathogen. It causes blinding trachoma and sexually transmitted disease such as chlamydia, pelvic inflammatory disease and lymphogranuloma venereum. Ct has a unique biphasic development cycle and replicates in an intracellular vacuole called inclusion. Normally it has two forms: the infectious form, elementary body (EB); and the non-infectious form, reticulate body (RB). Ct is not easily amenable to genetic manipulation. Hence, to understand the infection process, it is crucial to study how the metabolic activity of Ct exactly evolves in the host cell and what roles of EB and RB play differentially in Ct metabolism during infection. In addition, Ct was found regularly coinfected with other pathogens in patients who got sexually transmitted diseases (STDs). A lack of powerful methods to culture Ct outside of the host cell makes the detailed molecular mechanisms of coinfection difficult to study.
In this work, a genome-scale metabolic model with 321 metabolites and 277 reactions was first reconstructed by me to study Ct metabolic adaptation in the host cell during infection. This model was calculated to yield 84 extreme pathways, and metabolic flux strength was then modelled regarding 20hpi, 40hpi and later based on a published proteomics dataset. Activities of key enzymes involved in target pathways were further validated by RT-qPCR in both HeLa229 and HUVEC cell lines. This study suggests that Ct's major active pathways involve glycolysis, gluconeogenesis, glycerolphospholipid biosynthesis and pentose phosphate pathway, while Ct's incomplete tricarboxylic acid cycle and fatty acid biosynthesis are less active. EB is more activated in almost all these carbohydrate pathways than RB. Result suggests the survival of Ct generally requires a lot of acetyl-CoA from the host. Besides, both EB and RB can utilize folate biosynthesis to generate NAD(P)H but may use different pathways depending on the demands of ATP. When more ATP is available from both host cell and Ct itself, RB is more activated by utilizing energy providing chemicals generated by enzymes associated in the nucleic acid metabolism. The forming of folate also suggests large glutamate consumption, which is supposed to be converted from glutamine by the glutamine-fructose-6-phosphate transaminase (glmS) and CTP synthase (pyrG).
Then, RNA sequencing (RNA-seq) data analysis was performed by me in a coinfection study. Metatranscriptome from patient RNA-seq data provides a realistic overview. Thirteen patient samples were collected and sequenced by our collaborators. Six male samples were obtained by urethral swab, and seven female samples were collected by cervicovaginal lavage. All the samples were Neisseria gonorrhoeae (GC) positive, and half of them had coinfection with Ct. HISAT2 and Stringtie were used for transcriptomic mapping and assembly respectively, and differential expression analysis by DESeq2, Ballgown and Cuffdiff2 are parallelly processed for comparison. Although the measured transcripts were not sufficient to assemble Ct's transcriptome, the differential expression of genes in both the host and GC were analyzed by comparing Ct positive group (Ct+) against Ct-uninfected group. The results show that in the Ct+ group, the host MHC class II immune response was highly induced. Ct infection is associated with the regulation of DNA methylation, DNA double-strand damage and ubiquitination. The analysis also shows Ct infection enhances host fatty acid beta oxidation, thereby inducing mROS, and the host responds to reduce ceramide production and glycolysis. The coinfection upregulates GC's own ion transporters and amino acid uptake, while it downregulates GC's restriction and modification systems. Meanwhile, GC has the nitrosative and oxidative stress response and also increases the ability for ferric uptake especially in the Ct+ group compared to Ct-uninfected group.
In conclusion, methods in bioinformatics were used here in analyzing the metabolism of Ct itself, and the responses of the host and GC respectively in a coinfection study with and without Ct. These methods provide metabolic and metatranscriptomic details to study Ct metabolism during infection and Ct associated coinfection in the human microbiota.
Amyotrophic lateral sclerosis and spinal muscular atrophy are the two most common motoneuron diseases. Both are characterized by destabilization of axon terminals, axon degeneration and alterations in neuronal cytoskeleton. Accumulation of neurofilaments has been observed in several neurodegenerative diseases but the mechanisms how elevated neurofilament levels destabilize axons are unknown so far. Here, I show that increased neurofilament expression in motor nerves of pmn mutant mice causes disturbed microtubule dynamics. Depletion of neurofilament by Nefl knockout increases the number and regrowth of microtubules in pmn mutant motoneurons and restores axon elongation. This effect is mediated by interaction of neurofilament with the stathmin complex. Depletion of neurofilament increases stathmin-Stat3 interaction and stabilizes the microtubules. Consequently, the axonal maintenance is improved and the pmn mutant mice survive longer. We propose that this mechanism could also be relevant for other neurodegenerative diseases in which neurofilament accumulation is a prominent feature.
Next, using Smn-/-;SMN2 mouse as a model, the molecular mechanism behind synapse loss in SMA is studied. SMA is characterized by degeneration of lower α-motoneurons in spinal cord; however, how reduction of ubiquitously expressed SMN leads to MN-specific degeneration remains unclear. SMN is involved in pre-mRNA splicing (Pellizzoni, Kataoka et al. 1998) and its deficiency in SMA affects the splicing machinery. Neuromuscular junction denervation precedes neurodegeneration in SMA. However, there is no evidence of a link between aberrant splicing of transcripts downstream of Smn and reduced presynaptic axon excitability observed in SMA. In this study, we observed that expression and splicing of Nrxn2, that encodes a presynaptic protein is affected in the SMA mouse and that Nrxn2 could be a candidate that relates aberrant splicing to synaptic motoneuron defects in SMA.
DNA damage occurs frequently during normal cellular progresses or by environmental factors. To preserve the genome integrity, DNA damage response (DDR) has evolved to repair DNA and the non-properly repaired DNA induces human diseases like immune deficiency and cancer. Since a large number of proteins involved in DDR are enzymes of ubiquitin system, it is critical to investigate how the ubiquitin system regulates cellular response to DNA damage. Hereby, we reveal a novel mechanism for DDR regulation via activation of SCF ubiquitin ligase upon DNA damage.
As an essential step for DNA damage-induced inhibition of DNA replication, Cdc25A degradation by the E3 ligase β-TrCP upon DNA damage requires the deubiquitinase Usp28. Usp28 deubiquitinates β-TrCP in response to DNA damage, thereby promotes its dimerization, which is required for its activity in substrate ubiquitination and degradation. Particularly, ubiquitination at a specific lysine on β-TrCP suppresses dimerization.
The key mediator protein of DDR, 53BP1, forms oligomers and associates with β-TrCP to inhibit its activity in unstressed cells. Upon DNA damage, 53BP1 is degraded in the nucleoplasm, which requires oligomerization and is promoted by Usp28 in a β-TrCP-dependent manner. Consequently, 53BP1 destruction releases and activates β-TrCP during DNA damage response.
Moreover, 53BP1 deletion and DNA damage promote β-TrCP dimerization and recruitment to chromatin sites that locate in the vicinity of putative replication origins. Subsequently, the chromatin-associated Cdc25A is degraded by β-TrCP at the origins. The stimulation of β-TrCP binding to the origins upon DNA damage is accompanied by unloading of Cdc45, a crucial component of pre-initiation complexes for replication. Loading of Cdc45 to origins is a key Cdk2-dependent step for DNA replication initiation, indicating that localized Cdc25A degradation by β-TrCP at origins inactivates Cdk2, thereby inhibits the initiation of DNA replication.
Collectively, this study suggests a novel mechanism for the regulation of DNA replication upon DNA damage, which involves 53BP1- and Usp28-dependent activation of the SCF(β-TrCP) ligase in Cdc25A degradation.
SUMOylation, as a post-translational modification, plays a crucial role in several biological processes. Small ubiquitin-like modifier (SUMO) proteins can be reversibly linked to the lysine residues located within specific motifs on numerous target proteins, leading to the change of stability, localization, activity of target proteins, mostly by promoting or interfering with the interaction with other molecules. Consequently, it can regulate gene transcription, migration, cell cycle progression, cellular responses to stress, and tumorigenesis.
NFATc1 belongs to the Nuclear Factor of Activated T-cells (NFAT) transcription factor family, which is dephosphorylated and translocates to the nucleus upon cell stimulation, which provokes Ca2+ signalling. NFAT plays a crucial role in the development and function of the immune system. NFATc1 has three SUMOylation sites at the position of aa 349, 702, and 914. In our previous study, we demonstrated that point mutations performed on the SUMOylation sites on all three or only at the lysine residues K702 and K914 lead to enhanced expression of IL-2 in vitro. To evaluate the function of SUMOylation of NFATc1 on T cell-mediated immunity in vivo, we not only generated a transgenic mouse strain (NFATc1/ΔS+ mouse) by point mutations from Lysine to Arginine on the two SUMOylation sites within exon 10 of Nfatc1 to prevent their SUMOylation, but in combination created another mouse strain (NFATc1/ΔBC+ mouse) that is completely Nfatc1 exon 10-ablated by using the LoxP/Cre system. In NFATc1/ΔS+ T cells, we observed enhanced IL-2 production and less IL-17A and IFN-γ expression. In line with exon 10 bearing the relevant SUMO sites, NFATc1/ΔBC+ CD4+ T cells behaved similarly as NFATc1/ΔS+ ones. The mechanism is that elevated IL-2 secretion can counteract the expression of IL-17A and IFN-γ via STAT5 and Blimp-1 induction. Afterwards, Blimp-1 suppressed IL-2 itself as well as Bcl2A1. Next, we performed two disease models with our NFATc1/ΔS+ mice. In a major mismatch model for acute graft-versus-host disease, we found that the mice transplanted with NFATc1/ΔS+ CD3+ T cells developed less severe disease, and T cells proliferated less due to increased Tregs. Moreover, when transferring 2D2.NFATc1/ΔS+ Th1 plus Th17 cells to Rag1-/- mice to induce experimental autoimmune encephalitis, we also observed ameliorated disease compared to animals with transferred WT T cells as well as increased Tregs.
Taking all data together, the deficiency in SUMOylation of NFATc1 leads to an elevated IL-2 secretion in T cells and subsequent activation of STAT5, which competes with STAT3 to inhibit IL-17A production and promotes Treg expansion, as well as to an enforcement of Blimp-1 expression, which suppresses IFN-γ and IL-2 expression. Consequently and despite a short phase of enhanced IL-2 secretion, the deficiency of SUMOylation on NFATc1 can protect from autoreactive and alloreactive diseases.
Moreover, to further understand the function of SUMOylation of NFATc1 in humans, we started by establishing an in vitro 3D culture system for tonsil organoids, which was successful in the presence of feeder cells, along with IL-4 and IL-7 cytokines. To confirm that our 3D tonsil organoids can respond to real antigens, we used CMV peptides and peptides of spike proteins from Covid-19 as real antigens, and co-cultured with tonsil organoids, which indeed can generate memory cells and plasmablasts. In the end, we also compared 3D to 2D cultures. Although the total numbers of all B cell subsets were much less in 3D culture than that in 2D culture, still, it indicates that this in-vitro culture system has its limitation, while being usable to produce the similar results as 2D did. Therefore, this 3D culture system can be used as a platform to investigate NFATc1/ΔS+ or NFATc1/ΔBC+ TFH and TFR cells in the dynamic of human GC responses.
Ecophysiological adaptations of the cuticular water permeability within the Solanaceae family
(2024)
The cuticle, a complex lipidic layer synthesized by epidermal cells, covers and protects primary organs of all land plants. Its main function is to avoid plant desiccation by limiting non-stomatal water loss. The cuticular properties vary widely among plant species. So far, most of the cuticle-related studies have focused on a limited number of species, and studies addressing phylogenetically related plant species are rare. Moreover, comparative studies among organs from the same plant species are still scarce.
Thus, this study focus on organ-specificities of the cuticle within and between plant species of the Solanaceae family. Twenty-seven plant species of ten genera, including cultivated and non- cultivated species, were investigated to identify potential cuticular similarities. Structural, chemical and functional traits of fully expanded leaves, inflated fruiting calyces, and ripe fruits were analyzed.
The surface morphology was investigated by scanning electron microscopy. Leaves were mainly amphistomatic and covered by an epicuticular wax film. The diversity and distribution of trichomes varied among species. Only the leaves of S. grandiflora were glabrous. Plant species of the Leptostemonum subgenus had numerous prickles and non-glandular stellate trichomes. Fruits were stomata-free, except for S. muricatum, and a wax film covered their surface. Last, lenticel- like structures and remaining scars of broken trichomes were found on the surface of some Solanum fruits.
Cuticular water permeability was used as indicators of the cuticular transpiration barrier efficiency. The water permeability differed among plant species, organs and fruit types with values ranging up to one hundred-fold. The minimum leaf conductance ranged from 0.35 × 10-5 m s-1 in S. grandiflora to 31.54 × 10-5 m s-1 in S. muricatum. Cuticular permeability of fruits ranged from 0.64 × 10-5 m s-1 in S. dulcamara (fleshy berry) to 34.98 × 10-5 m s-1 in N. tabacum (capsule). Generally, the cuticular water loss of dry fruits was about to 5-fold higher than that of fleshy fruits.
Interestingly, comparisons between cultivated and non-cultivated species showed that wild species have the most efficient cuticular transpiration barrier in leaves and fruits. The average permeability of leaves and fruits of wild plant species was up to three-fold lower in comparison to the cultivated ones. Moreover, ripe fruits of P. ixocarpa and P. peruviana showed two-times lower cuticular transpiration when enclosed by the inflated fruiting calyx.
The cuticular chemical composition was examined using gas chromatography. Very-long-chain aliphatic compounds primarily composed the cuticular waxes, being mostly dominated by n- alkanes (up to 80% of the total wax load). Primary alkanols, alkanoic acids, alkyl esters and branched iso- and anteiso-alkanes were also frequently found. Although in minor amounts, sterols, pentacyclic triterpenoids, phenylmethyl esters, coumaric acid esters, and tocopherols were identified in the cuticular waxes. Cuticular wax coverages highly varied in solanaceous (62- fold variation). The cuticular wax load of fruits ranged from 0.55 μg cm−2 (Nicandra physalodes) to 33.99 μg cm−2 (S. pennellii), whereas the wax amount of leaves varied from 0.90 μg cm−2 (N. physalodes) to 28.42 μg cm−2 (S. burchellii). Finally, the wax load of inflated fruiting calyces ranged from 0.56 μg cm−2 in P. peruviana to 2.00 μg cm−2 in N. physalodes.
For the first time, a comparative study on the efficiency of the cuticular transpiration barrier in different plant organs of closely related plant species was conducted. Altogether, the cuticular chemical variability found in solanaceous species highlight species-, and organ-specific wax biosynthesis. These chemical variabilities might relate to the waterproofing properties of the plant cuticle, thereby influencing leaf and fruit performances. Additionally, the high cuticular water permeabilities of cultivated plant species suggest a potential existence of a trade-off between fruit organoleptic properties and the efficiency of the cuticular transpiration barrier. Last, the high cuticular water loss of the solanaceous dry fruits might be a physiological adaptation favouring seed dispersion.
Das maligne Melanom, eine der seltensten, aber gleichzeitig auch die tödlichste dermatologische Malignität, gekennzeichnet durch die Neigung zu einer frühen Metastasierung sowie die rasche Entwicklung von Therapieresistenzen, zählt zu den Tumorentitäten mit dem höchsten Anstieg der Inzidenz weltweit. Mausmodelle werden häufig verwendet, um die Melanomagenese zu erforschen und neue effektive therapeutische Strategien zu entwickeln, spiegeln die menschliche Physiologie allerdings nur unzureichend wider. In zweidimensionalen (2D) Zellkulturen mangelt es dagegen an wichtigen Komponenten der Mikroumgebung des Tumors und dem dreidimensionalen Gewebekontext. Um dieses Manko zu beheben und die Entwicklung von auf den Menschen übertragbaren Tumormodellen in der onkologischen Forschung voranzutreiben, wurde als Alternative zu Zellkulturen und Tierversuchen humane organotypische dreidimensionale (3D) Melanom-Modelle als in vitro Testsystem für die Bewertung der Wirksamkeit von anti-Tumor Therapeutika entwickelt.
Im Zuge dieser Arbeit konnte das in vitro Melanom-Modell entscheidend weiterentwickelt werden. So konnten Modelle unterschiedlichster Komplexität etabliert werden, wobei abhängig von der Fragestellung einfachere epidermale bis hin zu unterschiedlich komplexen Vollhautmodellen Anwendung finden. Durch Simulation der Tumor-Mikroumgebung eignen sich diese zur präklinischen Validierung neuer Tumor-Therapeutika, sowie der Erforschung pathologischer Vorgänge, von der Tumor-Formierung bis zur Metastasierung. Zudem konnten erfolgreich unterschiedlichste humane Melanomzelllinien ins Modell integriert werden; dadurch, dass sich diese durch ihre Treibermutationen, die zur Krankheitsentstehung beitragen, unterscheiden, stellen sie unterschiedliche Ansprüche an potentielle therapeutische Angriffspunkte und ermöglichen das Widerspiegeln vieler Melanom-Subtypen im Modell. Ferner ist es möglich, verschiedene Stadien der Tumor-Entwicklung über die Zugabe von Melanomzellen in Einzelsuspension bzw. von Melanom-Sphäroiden widerzuspiegeln. Es konnte für bestimmte Therapie-Ansätze, wie zielgerichtete Therapien, z.B. die Gabe von sich in der Klinik im Einsatz befindlicher BRAF-/MEK-Inhibitoren, gezeigt werden, dass sich die etablierten Modelle hervorragend als präklinische Testsysteme zur Wirksamkeitsbewertung eignen. Zudem bieten sich einzigartige Möglichkeiten, um die Interaktion humaner Tumorzellen und gesunder Zellen in einem Gewebeverband zu untersuchen. Ferner konnten drei neue technische Analyse-Verfahren zur nicht-invasiven Detektion der Tumor- Pro- und Regression, Beurteilung der Wirksamkeit von potenziellen Anti-Tumor-Therapien sowie der Evaluierung des Tumor-Metabolismusses implementiert werden. Perspektivisch ermöglichen immun-kompetente Melanom-Modelle die Austestung neuer Immun- und Zelltherapien in einem voll humanen System; gleichzeitig leisten die etablierten Modelle einen signifikanten Beitrag zur Reduktion von Tierexperimenten.
Depressionen und Angststörungen sind die beiden häufigsten psychischen Erkrankungen. Für Angststörungen wurde in zahlreichen Untersuchungen die Bedeutung veränderter Muster in den basalen emotional-assoziativen Lernprozessen für die Ätiologie und Aufrechterhaltung der Erkrankung gezeigt. Hierzu zählen eine verstärkte Akquisitionsreaktion auf den konditionierten Stimulus, Defizite in der Inhibition der Furchtreaktion auf den Sicherheit signalisierenden Stimulus, Übergeneralisierung und Beeinträchtigungen in der Extinktion konditionierter Reaktionen.
Aufgrund der hohen Prävalenzen einer Komorbidität mit Depressionen rückte in den letzten Jahren zunehmend die Untersuchung der genannten Prozesse bei Depressionen in den Fokus. Hierfür konnten bisher keine einheitlichen Ergebnisse gezeigt werden.
Weiterhin wird der Subtyp der ängstlichen Depression einerseits mit hohen Prävalenzen beschrieben, andererseits zeigen Untersuchungen eine schlechtere Prognose, stärkere Einschränkungen in der Funktionalität und ein schlechteres Ansprechen auf die Therapie im Vergleich zu depressiven Patienten ohne hohes Ängstlichkeitsniveau.
In dieser Arbeit wurden die Akquisition, Generalisierung und Extinktion in einem differentiellen Konditionierungsparadigma bei schwer depressiven ängstlichen und nicht ängstlich-depressiven Patienten sowie einer gesunden Kontrollgruppe untersucht. Ängstliche und nicht ängstlich-depressive Patienten zeigten ein beeinträchtigtes Sicherheitslernen in der Akquisition und Beeinträchtigungen in der Extinktion der konditionierten Furcht. Es ergaben sich keine Unterschiede hinsichtlich der Stärke der Generalisierung zwischen Patienten und den gesunden Kontrollen und es konnten keine differenzierenden Muster zwischen den ängstlich- und den nicht ängstlich-depressiven Patienten gezeigt werden.
Zusammenfassend weisen die Ergebnisse auf Veränderungen im Furchtlernen bei Patienten mit Depressionen hin. Es konnten keine Belege für unterschiedliche Mechanismen im Furchtlernen von ängstlich- und nicht ängstlich-depressiven Patienten gefunden werden. Unsere Ergebnisse stützen somit die Klassifikation der ängstlichen Depression als Subtyp der Depression. Weiterhin weisen die Ergebnisse der beeinträchtigten Extinktion bei Patienten mit Depressionen darauf hin, dass Expositionselemente, welche bei der Therapie von Angststörungen als Verfahren der Wahl eingesetzt werden, auch bei der Behandlung von Depressionen integriert werden sollten, um so den Therapieerfolg zu verbessern.
Bei der Multiplen Sklerose (MS) handelt es sich um eine Autoimmunerkrankung des zentralen Nervensystems (ZNS). Abhängig von der betroffenen ZNS-Region kann es zu vielfältigen Symptomen kommen. Neben neurologischen Symptomen verursacht durch ZNS-Läsionen leidet ein Großteil der MS-Patienten auch unter gastrointestinalen Funktionsstörungen. Diese gastrointestinalen Symptome wurden bisher eher auf Läsionen im Rückenmark zurückgeführt und nicht direkt in Verbindung mit der autoimmunen Ätiologie der Erkrankung gebracht.
In dieser Studie wurde das enterische Nervensystem (ENS) in einem B-Zell- und Antikörper-abhängigen Mausmodell der MS untersucht. Dafür wurde der Autoimmunprozess durch Immunisierung mit MP4, einem Fusionsprotein aus dem Myelin-Basischen-Protein (MBP) und dem Proteolipid-Protein (PLP), ausgelöst. Das ZNS und ENS wurden in den unterschiedlichen Erkrankungsstadien immunhistochemisch und elektronenmikroskopisch analysiert. Neben der Immunpathologie des ZNS konnte dabei eine Degeneration des ENS schon vor dem Einsetzen der ersten neurologischen Defizite nachgewiesen werden. Die ENS-Pathologie war antikörper-mediiert und ging einher mit einer verringerten gastrointestinalen Motilität sowie mit einer Gliose und Neurodegeneration des ENS.
Mithilfe von Immunpräzipitation und Massenspektrometrie konnten im ENS vier mögliche Zielstrukturen des Autoimmunprozesses identifiziert werden, was auf sog. epitope spreading hindeutet. Auch im Plasma von MS-Patienten konnten Antikörper gegen drei dieser Antigene nachgewiesen werden. Des Weiteren zeigten sich in Kolon-Resektaten von MS-Patienten erste Ansätze einer Neurodegeneration und Gliose des ENS.
In dieser Studie wurde zum ersten Mal ein direkter Zusammenhang zwischen der Autoimmunreaktion gegen das ZNS und einer simultanen Reaktion gegen das ENS gezeigt. Dies kann einen Paradigmenwechsel im Verständnis der Immunpathogenese der MS anstoßen und neue therapeutische und diagnostische Ansätze initiieren.
Background: Nicotine addiction is the most prevalent type of drug addiction that has been described as a cycle of spiraling dysregulation of the brain reward systems. Imaging studies have shown that nicotine addiction is associated with abnormal function in prefrontal brain regions that are important for cognitive emotion regulation. It was assumed that addicts may perform less well than healthy nonsmokers in cognitive emotion regulation tasks. The primary aims of this thesis were to investigate emotional responses to natural rewards among smokers and nonsmokers and to determine whether smokers differ from nonsmokers in cognitive regulation of positive and negative emotions. To address these aims, two forms of appraisal paradigms (i.e., appraisal frame and reappraisal) were applied to compare changes in emotional responses of smokers with that of nonsmokers as a function of appraisal strategies. Experiment 1: The aim of the first experiment was to evaluate whether and how appraisal frames preceding positive and negative picture stimuli affect emotional experience and facial expression of individuals. Twenty participants were exposed to 125 pairs of auditory appraisal frames (either neutral or emotional) followed by picture stimuli reflecting five conditions: unpleasant-negative, unpleasant-neutral, pleasant-positive, pleasant-neutral and neutral-neutral. Ratings of valence and arousal as well as facial EMG activity over the corrugator supercilii and the zygomaticus major were measured simultaneously. The results indicated that appraisal frames could alter both subjective emotional experience and facial expressions, irrespective of the valence of the pictorial stimuli. These results suggest and support that appraisal frame is an efficient paradigm in regulation of multi-level emotional responses. 8 Experiment 2: The second experiment applied the appraisal frame paradigm to investigate how smokers differ from nonsmokers on cognitive emotion regulation. Sixty participants (22 nonsmokers, 19 nondeprived smokers and 19 12-h deprived smokers) completed emotion regulation tasks as described in Experiment 1 while emotional responses were concurrently recorded as reflected by self-ratings and psychophysiological measures (i.e., facial EMG and EEG). The results indicated that there was no group difference on emotional responses to natural rewards. Moreover, nondeprived smokers and deprived smokers performed as well as nonsmokers on the emotion regulation task. The lack of group differences in multiple emotional responses (i.e., self-reports, facial EMG activity and brain EEG activity) suggests that nicotine addicts have no deficit in cognitive emotion regulation of natural rewards via appraisal frames. Experiment 3: The third experiment aimed to further evaluate smokers’ emotion regulation ability by comparing performances of smokers and nonsmokers in a more challenging cognitive task (i.e., reappraisal task). Sixty-five participants (23 nonsmokers, 22 nondeprived smokers and 20 12-h deprived smokers) were instructed to regulate emotions by imagining that the depicted negative or positive scenario would become less negative or less positive over time, respectively. The results showed that nondeprived smokers and deprived smokers responded similarly to emotional pictures and performed as well as nonsmokers in down-regulating positive and negative emotions via the reappraisal strategy. These results indicated that nicotine addicts do not have deficit in emotion regulation using cognitive appraisal strategies. In sum, the three studies consistently revealed that addicted smokers were capable to regulate emotions via appraisal strategies. This thesis establishes the groundwork for therapeutic use of appraisal instructions to cope with potential self-regulation failures in nicotine addicts.
The recently discovered human DREAM complex (for DP, RB-like, E2F and MuvB complex) is a chromatin-associated pocket protein complex involved in cell cycle- dependent gene expression. DREAM consists of five core subunits and forms a complex either with the pocket protein p130 and the transcription factor E2F4 to repress gene expression or with the transcription factors B-MYB and FOXM1 to promote gene expression.
Gas2l3 was recently identified by our group as a novel DREAM target gene. Subsequent characterization in human cell lines revealed that GAS2L3 is a microtubule and F-actin cross-linking protein, expressed in G2/M, plays a role in cytokinesis, and is important for chromosomal stability.
The aim of the first part of the study was to analyze how expression of GAS2L3 is regulated by DREAM and to provide a better understanding of the function of GAS2L3 in mitosis and cytokinesis.
ChIP assays revealed that the repressive and the activating form of DREAM bind to the GAS2L3 promoter. RNA interference (RNAi) mediated GAS2L3 depletion demonstrated the requirement of GAS2L3 for proper cleavage furrow ingression in cytokinesis. Immunofluorescence-based localization studies showed a localization of GAS2L3 at the mitotic spindle in mitosis and at the midbody in cytokinesis. Additional experiments demonstrated that the GAS2L3 GAR domain, a putative microtubule- binding domain, is responsible for GAS2L3 localization to the constriction zones in cytokinesis suggesting a function for GAS2L3 in the abscission process.
DREAM is known to promote G2/M gene expression. DREAM target genes include several mitotic kinesins and mitotic microtubule-associated proteins (mitotic MAPs). However, it is not clear to what extent DREAM regulates mitotic kinesins and MAPs, so far. Furthermore, a comprehensive study of mitotic kinesin expression in cancer cell lines is still missing.
Therefore, the second major aim of the thesis was to characterize the regulation of mitotic kinesins and MAPs by DREAM, to investigate the expression of mitotic kinesins in cancer cell line panels and to evaluate them as possible anti-cancer targets.
ChIP assays together with RNAi mediated DREAM subunit depletion experiments demonstrated that DREAM is a master regulator of mitotic kinesins. Furthermore, expression analyses in a panel of breast and lung cancer cell lines revealed that mitotic kinesins are up-regulated in the majority of cancer cell lines in contrast to non-transformed controls. Finally, an inducible lentiviral-based shRNA system was developed to effectively deplete mitotic kinesins. Depletion of selected mitotic kinesins resulted in cytokinesis failures and strong anti-proliferative effects in several human cancer cell lines.
Thus, this system will provide a robust tool for future investigation of mitotic kinesin function in cancer cells.
XPD is a 5‘-3‘ helicase of the superfamily 2. As part of the transcription factor IIH it functions in transcription initiation and nucleotide excision repair. This work focus on the role of XPD in nucleotide excision repair. NER is a DNA repair pathway unique for its broad substrate range. In placental mammals NER is the only repair mechanism able to remove lesions induced by UV-light. NER can be divided into four different steps that are conserved between pro- and eukaryotes. Step 1 consists of the initial damage recognition, during step 2 the putative damage is verified, in step 3 the verified damage is excised and in the 4th and final step the resulting gap in the DNA is refilled. XPD was shown to be involved in the damage verification step. It was possible to solve the first apo XPD structure by a MAD approach using only the endogenous iron from the iron sulfur cluster. Based on the apo XPD structure several questions arise: where is DNA bound? Where is DNA separated? How is damage verification achieved? What is the role of the FeS cluster? These questions were addressed in this work. Hypothesis driven structure based functional mutagenesis was employed and combined with detailed biochemical characterization of the variants. The variants were analyzed by thermal unfolding studies to exclude the possibility that the overall stability could be affected by the point mutation. DNA binding assays, ATPase assays and helicase assays were performed to delineate amino acid residues important for DNA binding, helicase activity and damage recognition. A structure of XPD containing a four base pair DNA fragment was solved by molecular replacement. This structure displays the polarity of the translocated strand with respect to the helicase framework. Moreover the properties of the FeS cluster were studied by electron paramagnetic resonance to get insights into the role of the FeS cluster. Furthermore XPD from Ferroplasma acidarmanus was investigated since it was shown that it is stalled at CPD containing lesions. The data provide the first detailed insight into the translocation mechanism of a SF2B helicase and reveal how polarity is achieved. This provides a basis for further anlayses understanding the combined action of the helicase and the 4Fe4S cluster to accomplish damage verification within the NER cascade.
Phospholamban (PLN) reguliert in der Herzmuskelzelle die Aktivität der Kalzium-ATPase SERCA2a und damit maßgeblich die Kinetik des myozytären Kalzium-Kreislaufs. PLN liegt im Herz in Form von Monomeren und Pentameren vor, wobei angenommen wird, dass nur die Monomere die Aktivität der SERCA2a durch direkte Interaktion hemmen. Die Funktion der Pentamere ist noch immer unklar. In der vorliegenden Arbeit sollte untersucht werden, ob PLN-Pentamere für die PKA-abhängige Phosphorylierung des PLN und damit für die Regulation der PLN-Aktivität von Bedeutung sein können.
Mit Hilfe transfizierter HEK293AD-Zellen und verschiedener PLN-Mutanten wurde gezeigt, dass sowohl PLN-Monomere als auch -Pentamere durch die PKA phosphoryliert werden, wobei die Phosphorylierung der Monomere in Anwesenheit von Pentameren geringer ist und verzögert abläuft. Ohne Pentamer war die Phosphorylierung der Monomere dagegen bereits basal und nach moderater PKA-Stimulation stärker. Ursache dafür schien eine höhere Affinität der PKA für PLN-Pentamere als für Monomere zu sein. Darüber hinaus konnte gezeigt werden, dass nicht nur PLN-Monomere sondern auch das PLN-Pentamer mit der SERCA2a interagieren und das Oligomer im Gegensatz zum PLN-Monomer nach PLN-Phosphorylierung zu einem kleinen Anteil an die SERCA2a gebunden bleibt. Auch spiegelten sich die unterschiedlichen Phosphorylierungsmuster von PLN-Pentamer und Monomer in den SERCA2a-Aktivitäten wieder. Messungen der SERCA2a-Aktivität in Mäuseherzen mit (Wildtyp und TgPLN) und ohne (TgAFA-PLN) PLN-Pentamere zeigten, dass Wildtyp-PLN und TgPLN die SERCA2a stärker inhibieren als TgAFA-PLN, was auf die stärkere basale Phosphorylierung des TgAFA-PLN zurückzuführen war. Nach PKA-Stimulation war der Anstieg der Enzymaktivität in Anwesenheit von TgPLN fast dreimal höher als in TgAFA-PLN. Analog zeigte TgPLN eine deutlichere Steigerung der Phosphorylierung der PLN-Monomere als TgAFA-PLN.
Zusammenfassend konnte gezeigt werden, dass PLN-Pentamere durch Hemmung der Monomer-Phosphorylierung deren Aktivität erhöhen mit der Folge einer verstärkten Inhibition der SERCA2a. Da die inhibitorische Wirkung durch PKA-Stimulation vollständig aufgehoben werden kann, erhöhen die Pentamere die Regulationsmöglichkeiten der SERCA2a-Aktivität.
Streptococcus pneumoniae (Pneumococcus) is one of the leading causes of childhood meningitis,pneumonia and sepsis. Despite the availability of childhood vaccination programs and antimicrobial agents, childhood pneumococcal meningitis is still a devastating illness with mortality rates among the highest of any cause of bacterial meningitis. Especially in low-income countries, where medical care is less accessible, mortality rates up to 50 % have been reported. In surviving patients, neurological sequelae, including hearing loss, focal neurological deficits and cognitive impairment, is reported in 30 to 50 %. Growing resistance of pneumococci towards conventional antibiotics emphasize the need for effective therapies and development of effective vaccines against Streptococcus pneumoniae. One major virulence factor of Streptococcus pneumoniae is the protein toxin Pneumolysin (PLY). PLY belongs to a family of structurally related toxins, the so-called cholesterol-dependent cytolysins (CDCs). Pneumolysin is produced by almost all clinical isolates of the bacterium. It is expressed during the late log phase of bacterial growth and gets released mainly through spontaneous autolysis of the bacterial cell. After binding to cholesterol in the host cell membranes, oligomerization of up to 50 toxin monomers and rearrangement of the protein structure, PLY forms large pores, leading to cell lysis in higher toxin concentrations. At sub-lytic concentrations, however, PLY mediates several other effects, such as activation of the classic complement pathway and the induction of apoptosis. First experiments with pneumococcal strains, deficient in pneumolysin, showed a reduced virulence of the organism, which emphasizes the contribution of this toxin to the course of bacterial meningitis and the urgent need for the understanding of the multiple mechanisms leading to invasive pneumococcal disease. The aim of this thesis was to shed light on the contribution of pneumolysin to the course of the disease as well as to the mental illness patients are suffering from after recovery from pneumococcal meningitis. Therefore, we firstly investigated the effects of sub-lytic pneumolysin concentrations onto primary mouse neurons, transfected with a GFP construct and imaged with the help of laser scanning confocal microscopy. We discovered two major morphological changes in the dendrites of primary mouse neurons: The formation of focal swellings along the dendrites (so-called varicosities) and the reduction of dendritic spines. To study these effects in a more complex system, closer to the in vivo situation, we established a reproducible method for acute brain slice culturing. With the help of this culturing method, we were able to discover the same morphological changes in dendrites upon challenge with sub-lytic concentrations of pneumolysin. We were able to reverse the seen alterations in dendritic structure with the help of two antagonists of the NMDA receptor, connecting the toxin´s mode of action to a non-physiological stimulation of this subtype of glutamate receptors. The loss of dendritic spines (representing the postsynapse) in our brain slice model could be verified with the help of brain slices from adult mice, suffering from pneumococcal meningitis. By immunohistochemical staining with an antibody against synapsin I, serving as a presynaptic marker, we were able to identify a reduction of synapsin I in the cortex of mice, infected with a pneumococcal strain which is capable of producing pneumolysin. The reduction of synapsin I was higher in these brain slices compared to mice infected with a pneumococcal strain which is not capable of producing pneumolysin, illustrating a clear role for the toxin in the reduction of dendritic spines. The fact that the seen effects weren´t abolished under calcium free conditions clarifies that not only the influx of calcium through the pneumolysin-pore is responsible for the alterations. These findings were further supported by calcium imaging experiments, where an inhibitor of the NMDA receptor was capable of delaying the time point, when the maximum of calcium influx upon PLY challenge was reached. Additionally, we were able to observe the dendritic beadings with the help of immunohistochemistry with an antibody against MAP2, a neuron-specific cytoskeletal protein. These observations also connect pneumolysin´s mode of action to excitotoxicity, as several studies mention the aggregation of MAP2 in dendritic beadings in response to excitotoxic stimuli. All in all, this is the first study connecting pneumolysin to excitotoxic events, which might be a novel chance to tie in other options of treatment for patients suffering from pneumococcal meningitis.
CRISPR-Cas systems are highly diverse and canonically function as prokaryotic adaptive immune systems. The canonical resistance mechanism relies on spacers that are complementary to the invaders' nucleic acids. By accidental incorporation or other mechanisms, prokaryotes can also acquire self-targeting spacers that are complementary to their own genome. As self-targeting commonly leads to lethal autoimmunity, the existence of self-targeting spacers poses a paradox. In Chapter 1, we provide an overview of the prevalence of self-targeting spacers, summarize how they can be incorporated, and which means can be employed by the host to evade lethal self-targeting. In addition, we outline alternative functions of CRISPR-Cas systems that are associated with self-targeting spacers. Whether CRISPR-Cas systems can efficiently target their own genome depends heavily on the presence of protospacer adjacent motifs (PAMs) next to the target region. In Chapter 2, we developed a method to determine PAM requirements. Thereby, we specifically focused on type I systems that engage multi-protein complexes, which are challenging to assess. Using the cell-free transcription-translation (TXTL) system, we developed an enrichment-based binding assay and validated its reliability by examining the well-known PAM requirements of the E. coli type I-E system. In Chapter 3, we applied the TXTL-based PAM assay to assess 16 additional CRISPR-Cas systems. These 16 systems included three CRISPR-Cas associated transposons (CASTs). CASTs are recently discovered transposons that employ CRISPR-Cas systems in a non-canonical function for the directed integration of the transposon. To further characterize CASTs in TXTL outside their PAM requirements, we reconstituted the transposition of CASTs in TXTL. In Chapter 4, we turned to non-canonical self-targeting CRISPR-Cas systems, which were already discussed in Chapter 1. While investigating how the plant pathogen Xanthomonas albilineans survives self-targeting by its two endogenous CRISPR-Cas systems, we identified multiple putative anti-CRISPR proteins (Acrs) in the genome of X. albilineans. Two of the Acrs, named AcrIC11 and AcrIF12Xal, inhibited degradation by their respective CRISPR-Cas systems but still retained Cascade-binding ability, and appear responsible for the lack of autoimmunity in X. albilineans. In summary, we developed new technologies that eased the investigation of non-canonical multi-component systems and, if applied to additional systems, might reveal unique properties that could be implemented in new CRISPR-Cas based tools.
Die Rolle von Chronophin bei Schlaganfall-induziertem Funktionsverlust der Blut-Hirn-Schranke
(2018)
Der ischämische Schlaganfall ist mit einer jährlichen Inzidenz von 200/100 000 Einwohnern die häufigste Gefäßerkrankung in Deutschland. Atherothrombose, arterielle Hypertonie und Embolien unterschiedlichen Ursprungs sind die wesentlichen Ursachen des ischämischen Schlaganfalls. Die neurologischen Defizite nach einem Schlaganfall resultieren aus einem gestörten zerebralen Blutfluss und somit einer insuffizienten Sauerstoffversorgung. Zusätzlich ist die Ödembildung, welche von einer gesteigerten Permeabilität der Blut-Hirn-Schranke verursacht wird, am neuronalen Zelltod beteiligt.
Chronophin ist eine Aktinzytoskelett-regulierende Serin-Phosphatase. In einem ischämischen Schlaganfall-Modell konnte im Rahmen dieser Arbeit gezeigt werden, dass der globale Verlust von Chronophin zu einer vermehrten Ödembildung und einem aggravierten neurologischen Zustand der Mäuse im Vergleich zu wildtypischen Kontrollen führte. Hirnlysate von wildtypischen Mäusen zeigten verringerte Chronophin-Level in der vom Schlaganfall betroffenen Hemisphäre. Jedoch konnten initiale immunhistochemische und zellbiologische Untersuchungen weder Chronophin-abhängige Veränderungen der Blut-Hirn-Schranke feststellen noch einen zerebralen Zelltyp identifizieren, der für den schützenden Effekt von Chronophin verantwortlich ist.
Diese Ergebnisse weisen auf einen komplexen, vielzelligen Mechanismus hin, dem die schützende Rolle von Chronophin im ischämischen Schlaganfall unterliegt. Die Entschlüsselung dieses Mechanismus ist Aufgabe künftiger Untersuchungen.
In reconstructive and plastic surgery, there exists a growing demand of adequate tissue implants, since currently available strategies for autologous transplantation are limited by complications including transplant failure and donor site morbidity. By developing in vitro and in vivo autologous substitutes for defective tissue sites, adipose tissue engineering can address these challenges, although there are several obstacles to overcome. One of the major limitations is the sufficient vascularization of in vitro engineered large constructs that remains crucial and demanding for functional tissues. Decellularized jejunal segments may represent a suitable scaffolding system with preexisting capillary structures that can be repopulated with human microvascular endothelial cells (hMVECs), and a luminal matrix applicable for the adipogenic differentiation of human adipose-derived stem cells (hASCs). Hence, co-culture of these cells in jejunal segments, utilizing a custom-made bioreactor system, was characterized in terms of vascularization and adipose tissue development. Substantial adipogenesis of hASCs was demonstrated within the jejunal lumen in contrast to non-induced controls, and the increase of key adipogenic markers was verified over time upon induction. The development of major extracellular matrix components of mature adipose tissue, such as laminin and collagen IV, was shown within the scaffold in induced samples. Successful reseeding of the vascular network with hMVECs was demonstrated in long-term culture and co-localization of vascular structures and adipogenically differentiated hASCs was observed. Therefore, these results represent a novel approach for in vitro engineering of vascularized adipose tissue constructs that warrants further investigations in preclinical studies.
Another still existing obstacle in adipose tissue engineering is the insufficient knowledge about the applied cells, for instance the understanding of how cells can be optimally expanded and differentiated for successful engineering of tissue transplants. Even though hASCs can be easily isolated from liposuction of abdominal fat depots, yielding low donor site morbidity, huge numbers of cells are required to entirely seed complex and large 3D matrices or scaffolds. Thus, cells need to be large-scale expanded in vitro on the premise of not losing their differentiation capacity caused by replicative aging. Accordingly, an improved differentiation of hASCs in adipose tissue engineering approaches remains still desirable since most engineered constructs exhibit an inhomogeneous differentiation pattern. For mesenchymal stem cells (MSCs), it has been shown that growth factor application can lead to a significant improvement of both proliferation and differentiation capacity. Especially basic fibroblast growth factor (bFGF) represents a potent mitogen for MSCs, while maintaining or even promoting their osteogenic, chondrogenic and adipogenic differentiation potential. As there are currently different contradictory information present in literature about the applied bFGF concentration and the explicit effect of bFGF on ASC differentiation, here, the effect of bFGF on hASC proliferation and differentiation capacity was investigated at different concentrations and time points in 2D culture. Preculture of hASCs with bFGF prior to adipogenic induction showed a remarkable effect, whereas administration of bFGF during culture did not improve adipogenic differentiation capacity. Furthermore, the observations indicated as mode of action an impact of this preculture on cell proliferation capacity, resulting in increased cellular density at the time of adipogenic induction. The difference in cell density at this time point appeared to be pivotal for increased adipogenic capacity of the cells, which was confirmed in a further experiment employing different seeding densities. Interestingly, furthermore, the obtained results suggested a cell-cell contact-mediated mechanism positively influencing adipogenic differentiation. As a consequence, subsequently, studies were conducted focusing on intercellular communication of these cells, which has hardly been investigated to date.
Despite the multitude of literature on the differentiation capacity of ASCs, little is reported about the physiological properties contributing to and controlling the process of lineage differentiation. Direct intercellular communication between adjacent cells via gap junctions has been shown to modulate differentiation processes in other cell types, with connexin 43 (Cx43) being the most abundant isoform of the gap junction-forming connexins. Thus, in the present study we focused on the expression of Cx43 and gap junctional intercellular communication (GJIC) in hASCs, and its significance for adipogenic differentiation of these cells. Cx43 expression in hASCs was demonstrated histologically and on the gene and protein expression level and was shown to be greatly positively influenced by cell seeding density. Functionality of gap junctions was proven by dye transfer analysis in growth medium. Adipogenic differentiation of hASCs was shown to be also distinctly elevated at higher cell seeding densities. Inhibition of GJIC by 18α-glycyrrhetinic acid significantly compromised adipogenic differentiation, as demonstrated by histology, triglyceride quantification, and adipogenic marker gene expression. Flow cytometry analysis showed a lower proportion of cells undergoing adipogenesis when GJIC was inhibited, further indicating the importance of GJIC in the differentiation process. Altogether, these results demonstrate the impact of direct cell-cell communication via gap junctions on the adipogenic differentiation process of hASCs and may contribute to further integrate direct intercellular crosstalk in rationales for tissue engineering approaches.
Lack of acid sphingomyelinase (ASM) activity, either through genetic deficiency or through pharmacological inhibition, is linked with increased activity and frequency of Foxp3+ regulatory T cells (Treg) among cluster of differentiation (CD) 4+ T cells in mice in vivo and in vitro1. Thus, pharmacological blockade of ASM activity, which catalyzes the cleavage of sphingomyelin to ceramide and phosphocholine, might be used as a new therapeutic mechanism to correct numeric and/ or functional Treg de-ficiencies in diseases like multiple sclerosis or major depression.
In the present study, the effect of pharmacological inhibition of ASM in humans, in vitro and in vivo, was analyzed. In the in vitro experiments, peripheral blood mono-nuclear cells (PBMC) of healthy human blood donors were treated with two widely prescribed antidepressants with high (sertraline, Ser) or low (citalopram, Cit) capaci-ty to inhibit ASM activity. Similar to the findings in mice an increase in the frequency of Treg among human CD4+ T cells upon inhibition of ASM activity was observed. For the analysis in vivo, a prospective study of the composition of the CD4+ T cell com-partment of patients treated for major depression was done. The data show that pharmacological inhibition of ASM activity was superior to antidepressants with little or no ASM-inhibitory activity in increasing CD45RA- CD25high effector Treg (efTreg) frequencies among CD4+ T cells to normal levels. Independently of ASM inhibition, correlating the data with the clinical response, i.e. improvement of the Hamilton rat-ing scale for depression (HAMD) by at least 50 per cent (%) after four weeks of treatment, it was found that an increase in efTreg frequencies among CD4+ cells dur-ing the first week of treatment identified patients with a clinical response.
Regarding the underlying mechanism, it could be found that the positive effect of ASM inhibition on Treg required CD28 co-stimulation suggesting that enhanced CD28 co-stimulation was the driver of the observed increase in the frequency of Treg among human CD4+ T cells. Inhibition of ASM activity was further associated with changes in the expression and shuttling of CTLA-4, a key inhibitory molecule ex-pressed by Treg, between cellular compartments but the suppressive activity of CTLA-4 through its transendocytosis activity was unaffected by the inhibition of ASM activity.
In summary, the frequency of (effector) Treg among CD4+ T cells in mice and in hu-mans is increased after inhibition of ASM activity suggesting that ASM blockade might beneficially modulate autoimmune diseases and depression-promoting in-flammation.
Deregulated MYC expression contributes to cellular transformation as well as progression and
maintenance of human tumours. Interestingly, in the absence of additional genetic alterations,
potentially oncogenic levels of MYC sensitise cells to a variety of apoptotic stimuli. Hence, MYC-induced
apoptosis has long been recognised as a major barrier against cancer development.
However, it is largely unknown how cells discriminate physiological from supraphysiological levels
of MYC in order to execute an appropriate biological response.
The experiments described in this thesis demonstrate that induction of apoptosis in mammary
epithelial cells depends on the repressive actions of MYC/MIZ1 complexes. Analysis of gene
expression profiles and ChIP-sequencing experiments reveals that high levels of MYC are required
to invade low-affinity binding sites and repress target genes of the serum response factor SRF.
These genes are involved in cytoskeletal dynamics as well as cell adhesion processes and are likely
needed to transmit survival signals to the AKT kinase. Restoration of SRF activity rescues MIZ1-
dependent gene repression and increases AKT phosphorylation and downstream function.
Collectively, these results indicate that association with MIZ1 leads to an expansion of MYC’s
transcriptional response that allows sensing of oncogenic levels, which points towards a tumour-suppressive
role for the MYC/MIZ1 complex in epithelial cells.
Das Cochlea-Implantat (CI) ermöglichte bereits >300 000 hochgradig hörgeschädigten Menschen
weltweit eine grundsätzlich wiederhergestellte Hörfunktion. Es wird angenommen, dass sich das
Sprachverständnis von CI-Trägern verbessert, wenn die funktionale Trennung der CI-Kanäle erhöht
wird. Neben verschiedenen auf die auditorische Peripherie beschränkten Ansätzen gibt es Überlegungen, eine verbesserte Kanaltrennung durch die Rehabilitation taubheitsinduzierter Degenerationen in der spektralen Verarbeitung im zentralen auditorischen System zu erreichen. Es konnte in ertaubten Tieren bislang allerdings kein adäquates CI-Stimulationsmuster beschrieben werden, dass es erlaubte, eine gezielte neuronale Plastizität in der spektralen Verarbeitung zu induzieren.
Die Arbeitsgruppe um M.P. Kilgard (UT Dallas, USA) zeigte in mehreren Studien in hörenden Tieren,
dass auditorische Stimulation gepaart mit elektrischer Vagusnerv-Stimulation (VNS) zu einer gezielten kortikalen Plastizität führt. Diese gepaarte Stimulation konnte die spektrale Verarbeitung von Signalen im auditorischen Kortex (AC) gezielt beeinflussen und so z.B. pathologisch verbreiterte Repräsentationen von Tönen wieder verfeinern. Dieses hochgradige Potential für gezielte Plastizität im AC durch die gepaarte VNS scheint eine vielversprechende Lösung darzustellen, um die durch verbreiterte Repräsentation im ertaubten AC verminderte CI-Kanaltrennung zu verbessern. Vor diesem Hintergrund sollte in der vorliegenden Promotion die Übertragbarkeit dieses hochgradigen Potentials auf das ertaubte und CI-stimulierte auditorische System evaluiert werden.
Um die CI-Kanaltrennung zu untersuchen, wurde ein Multikanal-CI für die Mongolische Wüstenrennmaus (Gerbil) entwickelt. Trotz der kleinen Ausmaße von Cochlea und AC im Gerbil und der generell breiten neuronalen Erregung durch intracochleäre elektrische Stimulation konnte eine tonotop organisierte und selektive Repräsentation der neuronalen Antworten für mehrere CI-Kanäle im AC nachgewiesen werden. Für die gepaarte CI/VN-Stimulation wurden die Tiere zusätzlich mit einer Manschettenelektrode um den linken zervikalen Nervus vagus (VN) implantiert. Die chronischen Implantate erlaubten über mehrere Wochen hinweg eine stabile und zuverlässige elektrische Stimulation im frei-beweglichen Gerbil. Damit kombiniert das in dieser Promotion entwickelte Multikanal-CI-VNS-Modell die Vorteile einer tonotop selektiven und stabilen neuronalen Aktivierung mit den ethischen, kostenrelevanten und entwicklungsbezogenen Vorteilen, die der Einsatz von Kleinnagern bietet.
Als nächster Schritt wurde das grundsätzliche Potential der gepaarten CI/VN-Stimulation für gezielte plastische Veränderungen im AC des Gerbils getestet. Engineer et al. (2011) hatten bereits in akustischen Studien in hörenden Ratten die kortikale Überrepräsentation eines einzelnen chronisch mit VNS gepaarten Tones gezeigt. In der vorliegenden Promotion wurde versucht, die Ergebnisse aus der akustischen Studie in hörenden Ratten in zwei verschiedenen Studien im Gerbil zu reproduzieren. Analog zur gepaarten Ton/VN-Stimulation in der Ratte untersuchten wir zuerst in ertaubten Gerbils die Auswirkungen einkanaliger CI-Stimulation gepaart mit VNS. Im AC des Gerbils konnten keine Veränderung der zentralen Repräsentation des VNS gepaarten CI-Kanals festgestellt werden. Um speziesspezifische (Ratte vs. Gerbil) und stimulusspezifische (akustisch vs. elektrisch) Unterschiede zwischen den Studien als mögliche Gründe für das Ausbleiben der VNS induzierten Plastizität auszuschließen, wurde nun die gepaarte Ton/VN-Stimulation (Engineer et al., 2011) im hörenden Gerbil wiederholt. Eine kortikale Überrepräsentation des VNS gepaarten Signals konnte aber auch im hörenden Gerbil nicht reproduziert werden.
Mögliche Gründe für die Diskrepanz zwischen unseren Ergebnissen im Gerbil und den publizierten
Ergebnissen in der Ratte werden diskutiert. Die generelle Funktionsfähigkeit der VNS in den chronisch stimulierten Tieren wurde durch die Ableitung VNS evozierter Potentiale (VNEP) kontrolliert. Ein speziesspezifischer Unterschied erscheint bei der biologischen Nähe von Ratte und mongolischer Wüstenrennmaus unwahrscheinlich, kann allerdings durch die vorliegenden Studien nicht vollständig ausgeschlossen werden. Eine Abhängigkeit des plastischen Potentials der gepaarten VNS von der Stimulationsintensität ist bekannt. Da Ratten und Gerbils ähnliche VNEP-Schwellen zeigten und mit identischen VNS-Amplituden stimuliert wurden, gehen wir davon aus, dass Unterschiede im plastischen Potential gepaarter VNS zwischen beiden Spezies nicht auf die verwendete Stimulationsintensität zurückzuführen sind.
Die beschriebene Diskrepanz im Potential für kortikale Plastizität durch gepaarte VNS weckt Zweifel an der Übertragbarkeit des für die Ratte publizierten Potentials auf andere Spezies, einschließlich des Menschen.
Untersucht wurde der Einfluss mehrerer Chemotherapeutika auf den Chemokinrezeptor CXCR4 in
Myelomzelllinien auf Ebene des Promotors, der mRNA und der Rezeptorverteilung, wobei drei
Substanzen (Etoposid, Bortezomib und Dexamethason) als potenzielle Suppressoren des Promotors ausgemacht werden konnten. Abhängig vom Myelom-Zelltyp und der Dosierung können so evtl.
Rückschlüsse auf die beobachtete Suppression von CXCR4 bei erkrankten Patienten mit hoher CXCR4-Aktivität (hier: Malignes Myelom) durch die begleitende Chemotherapie gezogen werden, welche eine Diagnostik und Therapie bei diesen Patienten erschwert.
Hintergrund: Hintergrund für diese Arbeit waren Beobachtungen in klinischen Fallstudien von Lapa et al. am Universitätsklinikum Würzburg, die sich auf CXCR4 bezogen, welches u.a. bei Patienten mit
Multiplem Myelom überexprimiert wird und dadurch bereits als Target für Diagnostik und Therapie in der Klinik Anwendung findet. Dabei konnte bei PET-CT Untersuchungen in der Nuklearmedizin beobachtet werden, dass es durch die begleitende Chemotherapie der Patienten zu einer Suppression des markierten CXCR4-Signals kam, so dass es nicht mehr zur Verlaufsbeobachtung und
vor allem nicht mehr zur Radiotherapie und Therapiekontrolle verwendet werden konnte.
Um den Einfluss und mögliche Interaktionen der Chemotherapeutika auf CXCR4 zu untersuchen, war es Ziel dieser Arbeit, ein vergleichbares Szenario in-vitro nachzustellen und Einflüsse messbar zu
machen, um so mögliche Ansätze und Verbesserungsvorschläge für die klinische Anwendung zu
liefern.
Methoden/Ergebnisse: Hierfür wurden im ersten Teil INA-6 (Myelomzellen) und Mesenchymale
Stammzellen (MSC) kultiviert, in Ko-Kultur gebracht und nach einer bestimmten Zeit wieder getrennt, um anschließend den gegenseitigen Einfluss in Bezug auf CXCR4 zu messen. Zudem wurde der Einfluss von Dexamethason untersucht. Es zeigte sich eine enge Bindung zwischen INA-6 und MSC
sowie eine hohe CXCR4-Aktivität bei INA-6, jedoch konnte keine Induktion der CXCR4-Aktivität in MSC durch INA-6-Kontakt oder Dexamethason quantifiziert werden. Die Immunzytologie erwies sich aufgrund einer schweren Anfärbbarkeit von CXCR4 – auch mit verschiedensten Antikörpern und sogar Liganden-gekoppeltem Farbstoff– als kaum auswertbar, wobei eine Darstellung von CXCR4
generell aber gelang.
Der CXCR4-Promotor wurde mittels Software genauer analysiert, wobei einige relevante Bindestellen, u.a. für Glukokortikoide und NFkB gefunden wurden. Die Herstellung eines CXCR4-
pGl4.14-Promotor-Konstrukts war erfolgreich, ebenso dessen Einschleusung in Myelomzellen. Auch gelang die Herstellung stabiler transfizierter INA-6, sodass mit diesen anschließend konstantere Ergebnisse erzielt werden konnten.
Im größten Teil der Arbeit wurden geeignete Chemotherapeutika-Konzentrationen ermittelt und in Viabilitäts- und Apoptose-Versuchen überprüft. Die Stimulationsversuche mit diesen zeigten variable
Effekte abhängig vom Zelltyp (INA-6, MM1S), jedoch konnten Bortezomib, Etoposid und
Dexamethason konzentrationsabhängig als starke Suppressoren der CXCR4-Aktivität ausgemacht
werden, was sich v.a. auf Ebene der Promotoraktivität – gemessen mittels Luciferase - zeigte. Interpretation: In-vitro konnten somit drei potenzielle Suppressoren der CXCR4-Aktivität ausgemacht
werden: Etoposid, Bortezomib und Dexamethason. Zumindest beim INA-6-Zelltyp fiel dieser Effekt deutlich aus, wobei in der Klinik der entsprechende Zelltyp sowie die Dosierung der Medikamente berücksichtigt werden müssen. Hinzu kommen weitere Einflussfaktoren des menschlichen Körpers,
die nicht berücksichtig werden konnten. Die genauen Mechanismen der Suppression könnten sich aus den Bindestellen des Promotors erklären, die von uns analysiert wurden, aber auf die in weiteren Arbeiten noch näher eingegangen werden muss.
Der Meniskus, ein scheibenförmiger Faserknorpel, spielt im Kniegelenk eine bedeutende Rolle, weil er Kräfte und Druck im Kniegelenk gleichmäßig verteilt, Stöße dämpft sowie der Kraftübertragung und Stabilisierung dient. Durch die Entfernung des Gewebes, der sogenannten Totalmeniskektomie, nach einer Meniskusverletzung oder einem Riss, verändern sich die mechanischen Eigenschaften des Gelenks stark und verursachen durch die erhöhte Belastung der Gelenkflächen Arthrose. Arthrose ist weltweit die Häufigste aller Gelenkerkrankungen. Der Erhalt der körperlichen Leistungsfähigkeit und Mobilität bis ins hohe Alter sowie die Bewahrung der Gesundheit von Herz-Kreislauf- und Stoffwechselorganen zählen aufgrund des demografischen Wandels zu den großen medizinischen Herausforderungen. Die Erkrankung des muskuloskelettalen Systems stellte 2010 im Bundesgebiet die am häufigsten vorkommende Krankheitsart dar.
Während Risse in den äußeren Teilen des Meniskus aufgrund des Anschlusses an das Blutgefäßsystem spontan heilen können, können sie dies in tieferen Zonen nicht. Durch die begrenzte Heilungsfähigkeit des Knorpels bleibt langfristig der Einsatz eines Ersatzgewebes die einzige therapeutische Alternative.
In der vorliegenden Arbeit wurde als therapeutische Alternative erfolgreich ein vaskularisiertes Meniskusersatzgewebe mit Methoden des Tissue Engineering entwickelt. Es soll in Zukunft als Implantat Verwendung finden. Tissue Engineering ist ein interdisziplinäres Forschungsfeld, in dem Gewebe außerhalb des Körpers generiert werden. Schlüsselkomponenten sind Zellen, die aus einem Organismus isoliert werden, und Trägerstrukturen, die mit Zellen besiedelt werden. Die Biomaterialien geben den Zellen eine geeignete Umgebung, die die Extrazelluläre Matrix (EZM) ersetzen soll, um die Funktion der Zellen beizubehalten, eigene Matrix zu bilden. Zum Erhalt eines funktionelles Gewebes werden oftmals dynamische Kultursysteme, sogenannte Bioreaktoren, verwendet, die natürliche Stimuli wie beispielsweise den Blutfluss oder mechanische Kompressionskräfte während der in vitro Reifungsphase des Gewebes, zur Verfügung stellen. Das Gewebekonstrukt wurde auf Basis natürlicher Biomaterialien aufgebaut, unter Verwendung ausschließlich primärer Zellen, die später direkt vom Patienten gewonnen werden können und damit Abstoßungsreaktionen auszuschließen sind. Da der Meniskus teilvaskularisiert ist und die in vivo Situation des Gewebes bestmöglich nachgebaut werden sollte, wurden Konstrukte mit mehreren Zelltypen, sogenannte Ko-Kulturen aufgebaut. Neben mikrovaskulären Endothelzellen (mvEZ) und Meniskuszellen (MZ) erfolgten Versuche mit mesenchymalen Stammzellen (MSZ).
Zur Bereitstellung einer zelltypspezifischen Matrixumgebung, diente den mvEZ ein Stück Schweinedarm mit azellularisierten Gefäßstrukturen (BioVaSc®) und den MZ diente eine geeig- nete Kollagenmatrix (Kollagen Typ I Hydrogel). Die Validierung und Charakterisierung des aufgebauten 3D Meniskuskonstrukts, welches in einem dynamischen Perfusions-Bioreaktorsystem kultiviert wurde, erfolgte mit knorpeltypischen Matrixmarkern wie Aggrekan, Kollagen Typ I, II und X sowie mit den Transkriptionsfaktoren RunX2 und Sox9, die in der Knorpelentstehung von großer Bedeutung sind. Zusätzlich erfolgten Auswertungen mit endothelzellspezifischen Markern wie vWF, CD31 und VEGF, um die Vaskularisierung im Konstrukt nachzuweisen. Analysiert wurden auch die Zellvitalitäten in den Konstrukten.
Aufgrund einer nur geringen Verfügbarkeit von MZ wurden Kulturansätze mit alternativen Zellquellen, den MSZ, durchgeführt. Dafür erfolgte zunächst deren Isolation und Charakterisierung und die Auswahl einer geeigneten 3D Kollagenmatrix. Die beste Zellintegration der MSZ konnte auf einer eigens hergestellten elektrogesponnenen Matrix beobachtet werden. Die Matrix besteht aus zwei unterschiedlichen Kollagentypen, die auf insgesamt fünf Schichten verteilt sind. Die Fasern besitzen weiter unterschiedliche Ausrichtungen. Während die Kollagen Typ I Fasern in den äußeren Schichten keiner Ausrichtung zugehören, liegen die Kollagen Typ II Fasern in der mittleren Schicht parallel zueinander. Der native Meniskus war für den Aufbau einer solchen Kollagen-Trägerstruktur das natürliche Vorbild, das imitiert werden sollte. Nach der Besiedelung der Matrix mit MSZ, konnte eine Integration der Zellen bereits nach vier Tagen bis in die Mittelschicht sowie eine spontane chondrogene Differenzierung nach einer insgesamt dreiwöchigen Kultivierung gezeigt werden. Das Biomaterial stellt in Hinblick auf die Differenzierung der Zellen ohne die Zugabe von Wachstumsfaktoren eine relevante Bedeutung für klinische Studien dar.
Zur Kultivierung des 3D Meniskuskonstrukts wurde ein Bioreaktor entwickelt. Mit diesem können neben Perfusion der Gefäßsysteme zusätzlich Kompressionskräfte sowie Scherspannungen auf das Ersatzgewebe appliziert und die Differenzierung von MZ bzw. MSZ während der in vitro Kultur über mechanische Reize stimuliert werden. Ein anderes Anwendungsfeld für den neuartigen Bioreaktor ist seine Verwendung als Prüftestsystem für die Optimierung und Qualitätssicherung von Gewebekonstrukten.
During development of the nervous system, spontaneous Ca2+ transients are observed that regulate the axon growth of motoneurons. This form of spontaneous neuronal activity is reduced in motoneurons from a mouse model of spinal muscular atrophy and this defect correlates with reduced axon elongation. Experiments from our group demonstrated that voltage-gated sodium channel pore blockers decrease spontaneous neuronal activity and
axon growth in cultured motoneurons, too. In these experiments, saxitoxin was more potent than tetrodotoxin. We identified the saxitoxin-sensitive/tetrodotoxin-insensitive voltage-gated sodium channel NaV1.9 as trigger for the opening of voltage-gated calcium channels. In motoneurons, expression of NaV1.9 was verified via quantitative RT-PCR. Immuno labelling
experiments revealed enrichment of the channel in axonal growth cones and at the nodes of Ranvier of isolated nerve fibres from wild type mice. Motoneurons from NaV1.9 knock-out mice show decreased spontaneous activity and reduced axonal elongation. This growth defect can be rescued by NaV1.9 overexpression. In motoneurons from Smn-deficient mice, NaV1.9 distribution appeared to be normal.
Recently, patients carrying a missense mutation in the NaV1.9-encoding gene SCN11A were identified. These patients are not able to feel pain and suffer from muscular weakness and a delayed motor development. Molecular biological work during this dissertation supported the analysis of this mutation in a mouse model carrying the orthologous alteration in the Scn11a
locus. The cooperation study confirmed that a gain-of-function mechanism underlies the NaV1.9-mediated channelopathy, thus suggesting a functional role of NaV1.9 in human motoneurons.
An earlier study showed in hippocampal neurons that the receptor tyrosine kinase tropomyosin receptor kinase B (TrkB) can open the NaV1.9 channel. TrkB is localized in
growth cones of motoneurons and subsequently found in close proximity to NaV1.9. In order to proof whether TrkB is involved in spontaneous excitability in motoneurons, TrkB knock-out mice were analysed. Isolated motoneurons from TrkB knock-out mice show a reduced spontaneous activity and axon elongation. It remains to be studied whether TrkB and NaV1.9 are functionally connected.
The infection of a eukaryotic host cell by a bacterial pathogen is one of the most intimate examples of cross-kingdom interactions in biology. Infection processes are highly relevant from both a basic research as well as a clinical point of view. Sophisticated mechanisms have evolved in the pathogen to manipulate the host response and vice versa host cells have developed a wide range of anti-microbial defense strategies to combat bacterial invasion and clear infections. However, it is this diversity and complexity that makes infection research so challenging to technically address as common approaches have either been optimized for bacterial or eukaryotic organisms. Instead, methods are required that are able to deal with the often dramatic discrepancy between host and pathogen with respect to various cellular properties and processes. One class of cellular macromolecules that exemplify this host-pathogen heterogeneity is given by their transcriptomes: Bacterial transcripts differ from their eukaryotic counterparts in many aspects that involve both quantitative and qualitative traits. The entity of RNA transcripts present in a cell is of paramount interest as it reflects the cell’s physiological state under the given condition. Genome-wide transcriptomic techniques such as RNA-seq have therefore been used for single-organism analyses for several years, but their applicability has been limited for infection studies.
The present work describes the establishment of a novel transcriptomic approach for infection biology which we have termed “Dual RNA-seq”. Using this technology, it was intended to shed light particularly on the contribution of non-protein-encoding transcripts to virulence, as these classes have mostly evaded previous infection studies due to the lack of suitable methods. The performance of Dual RNA-seq was evaluated in an in vitro infection model based on the important facultative intracellular pathogen Salmonella enterica serovar Typhimurium and different human cell lines. Dual RNA-seq was found to be capable of capturing all major bacterial and human transcript classes and proved reproducible. During the course of these experiments, a previously largely uncharacterized bacterial small non-coding RNA (sRNA), referred to as STnc440, was identified as one of the most strongly induced genes in intracellular Salmonella. Interestingly, while inhibition of STnc440 expression has been previously shown to cause a virulence defect in different animal models of Salmonellosis, the underlying molecular mechanisms have remained obscure. Here, classical genetics, transcriptomics and biochemical assays proposed a complex model of Salmonella gene expression control that is orchestrated by this sRNA. In particular, STnc440 was found to be involved in the regulation of multiple bacterial target mRNAs by direct base pair interaction with consequences for Salmonella virulence and implications for the host’s immune response. These findings exemplify the scope of Dual RNA-seq for the identification and characterization of novel bacterial virulence factors during host infection.
Das Endothel bildet eine einschichtige Zellbarriere zwischen Blut und interstitiellem Gewebe, deren Durchlässigkeit entscheidend durch die sekundären Botenstoffe Ca2+ und cAMP reguliert wird. Während Ca2+ durch eine verstärkte Kontraktion der Endothelzellen die Permeabilität erhöht, fördert cAMP die Adhäsion der Zellen und unterstützt somit die Barrierefunktion. Es ist bekannt, dass Thrombin durch einen Anstieg der intrazellulären Ca2+-Konzentration und vermutlich auch durch eine Hemmung der cAMP-Konzentration zu einer Permeabilitätserhöhung führt. Ziel dieser Arbeit war es, Thrombin-induzierte Änderungen der cAMP-Konzentration in Echtzeit in lebenden Endothelzellen mittels Fluorescence-Resonance-Energy-Transfer (FRET) zu untersuchen. Hierfür wurden Human-Umbilical-Vein-Endothelial-Cells (HUVECs) mit dem FRET-basierten cAMP-Sensor Epac1-camps transfiziert. Die Bindung von cAMP an Epac1-camps führt zu einer Konformationsänderung des Sensors und damit zu einer Abschwächung des FRET. Mit Hilfe dieses Sensors kann die cAMP-Konzentration mit hoher zeitlicher Auflösung in einzelnen lebenden Zellen gemessen werden. Untersucht wurde der Effekt von Thrombin auf die cAMP-Konzentration in Endothelzellen, deren cAMP-Konzentration durch Stimulierung endogener β-Rezeptoren erhöht war. Thrombin erniedrigte Ca2+-abhängig die cAMP-Konzentration um ca. 30 %. Dieser Abfall der cAMP-Konzentration folgte zeitlich verzögert dem Thrombin-induzierten Ca2+-Signal. Die cAMP-Konzentration erreichte ca. 30 s nach der Thrombinzugabe ein Minimum und stieg danach wieder an. Durch die Herunterregulierung der durch Ca2+ direkt inhibierten Adenylatzyklase 6 (AC6) mittels siRNA wurde die Thrombin-induzierte Abnahme der cAMP-Konzentration vollständig aufgehoben. Dies bestätigte, dass Thrombin durch die Ca2+-vermittelte Inhibierung der AC6 eine Abnahme der cAMP-Konzentration verursacht. Ohne β-adrenerge Stimulation führte die Applikation von Thrombin zu einem langsamen Anstieg der cAMP-Konzentration, der mehrere Minuten anhielt. Dieser cAMP-Konzentrationsanstieg beruhte auf der Ca2+-abhängigen Aktivierung der Phospholipase A2 (PLA2). Diese setzt Arachidonsäure aus Membranphospholipiden frei, die als Substrat für die Synthese verschiedener Prostaglandine dient. Durch die pharmakologische Beeinflussung von Zyklooxygenasen und Prostazyklinrezeptoren konnte gezeigt werden, dass die Synthese von Prostazyklin und die anschließende Stimulation Gs-gekoppelter Prostazyklinrezeptoren zum Thrombin-induzierten Anstieg der cAMP-Konzentration führte. Da die Physiologie der Endothelzellen im Gefäß stark von Faktoren aus der unmittelbaren Umgebung beeinflusst wird, ist die Messung der Änderungen der cAMP-Konzentration in Endothelzellen, die sich innerhalb eines Gewebes befinden, von sehr großer Bedeutung. Deshalb war die Generierung transgener Mäuse mit einer gewebespezifischen Expression des FRET-Sensors Epac1-camps in Endothelzellen ein weiteres Ziel dieser Arbeit. Durch Anwendung eines Cre-Rekombinase/loxP-Ansatzes konnten transgene Mäuse generiert werden, die Epac1-camps spezifisch in Endothelzellen exprimierten. An isolierten pulmonären Endothelzellen konnte die Funktionalität des transgen exprimierten Sensors Epac1-camps nachgewiesen werden. Die Echtzeitmessung der Thrombin-induzierten Änderungen der cAMP-Konzentration verdeutlichte ein zeitlich sehr komplexes Wechselspiel zwischen Ca2+- und cAMP-Signalen, das die Barrierefunktion des Endothels maßgeblich beeinflussen wird. Die transgene Expression von Epac1-camps in Endothelzellen ermöglicht in Zukunft die Untersuchung der Thrombin-verursachten Änderungen der cAMP-Konzentration und der Permeabilität innerhalb eines intakten Gefäßes.
The number of newly detected autoantibodies (AB) targeting synaptic proteins in neurological disorders of the central nervous system (CNS) is steadily increasing. Direct interactions of AB with their target antigens have been shown in first studies but the exact pathomecha-nisms for most of the already discovered AB are still unclear. The present study investigates pathophysiological mechanisms of AB-fractions that are associated with the enigmatic CNS disease Stiff person syndrome (SPS) and target the synaptically located proteins amphiphysin or glutamate decarboxylase 65 (GAD65).
In the first part of the project, effects of AB to the presynaptic endocytic protein amphiphysin were investigated. Ultrastructural investigations of spinal cord presynaptic boutons in an es-tablished in-vivo passive-transfer model after intrathecal application of human anti-amphiphysin AB showed a defect of endocytosis. This defect was apparent at high synaptic activity and was characterized by reduction of the synaptic vesicle pool, clathrin coated vesi-cles (CCVs), and endosome like structures (ELS) in comparison to controls. Molecular inves-tigation of presynaptic boutons in cultured murine hippocampal neurons with dSTORM microscopy after pretreatment with AB to amphiphysin revealed that marker proteins involved in vesicle exocytosis (synaptobrevin 2 and synaptobrevin 7) had an altered expression in GA-BAergic presynapses. Endophilin, a direct binding partner of amphiphysin also displayed a disturbed expression pattern. Together, these results point towards an anti-amphiphysin AB-induced defective organization in GABAergic synapses and a presumably compensatory rearrangement of proteins responsible for CME.
In the second part, functional consequences of SPS patient derived IgG fractions containing AB to GAD65, the rate limiting enzyme for GABA synthesis, were investigated by patch clamp electrophysiology and immunohistology. GABAergic neurotransmission at low and high activity as well as short term plasticity appeared normal but miniature synaptic potentials showed an enhanced frequency with constant amplitudes. SPS patient IgG after preabsorption of GAD65-AB using recombinant GAD65 still showed specific synaptic binding to neu-rons and brain slices supporting the hypothesis that additional, not yet characterized AB are present in patient IgG responsible for the exclusive effect on frequency of miniature potentials.
In conclusion, the present thesis uncovered basal pathophysiological mechanisms underlying paraneoplastic SPS induced by AB to amphiphysin leading to disturbed presynaptic architec-ture. In idiopathic SPS, the hypothesis of a direct pathophysiological role of AB to GAD65 was not supported and additional IgG AB are suspected to induce distinct synaptic malfunction.
The role of multicellularity as the predominant microbial lifestyle has been affirmed by studies on the genetic regulation of biofilms and the conditions driving their formation. Biofilms are of prime importance for the pathology of chronic infections of the opportunistic human pathogen Staphylococcus aureus.
The recent development of a macrocolony biofilm model in S. aureus opened new opportunities to study evolution and physiological specialization in biofilm communities in this organism. In the macrocolony biofilm model, bacteria form complex aggregates with a sophisticated spatial organization on the micro- and macroscale. The central positive and negative regulators of this organization in S. aureus are the alternative sigma factor σB and the quorum sensing system Agr, respectively. Nevertheless, nothing is known on additional factors controlling the macrocolony morphogenesis.
In this work, the genome of S. aureus was screened for novel factors that are required for the development of the macrocolony architecture. A central role for basic metabolic pathways was demonstrated in this context as the macrocolony architecture was strongly altered by the disruption of nucleotide and carbohydrate synthesis. Environmental signals further modulate macrocolony morphogenesis as illustrated by the role of an oxygen-sensitive gene regulator, which is required for the formation of complex surface structures. A further application of the macrocolony biofilm model was demonstrated in the study of interstrain interactions. The integrity of macrocolony communities was macroscopically visibly disturbed by competitive interactions between clinical isolates of S. aureus.
The results of this work contribute to the characterization of the macrocolony biofilm model and improve our understanding of developmental processes relevant in staphylococcal infections. The identification of anti-biofilm effects exercised through competitive interactions could lead to the design of novel antimicrobial strategies targeting multicellular bacterial communities.
Despite accounting for only a small proportion of all skin cancers, malignant melanoma
displays a serious health risk with increasing incidence and high mortality rate. Fortunately,
advances in the treatment of malignant melanoma now prolong survival and enhance response
and treatment efficacy. Established biomarkers help evaluate disease progression and
facilitate choosing appropriate and individual treatment options. However, the need for easily
accessible and reliable biomarkers is rising to predict patient-specific clinical outcome.
Eosinophil infiltration into the tumor and high peripheral eosinophil counts prior and during
treatment have been associated with better response in patients for various cancer entities,
including melanoma. An analysis of a heterogeneous study cohort reported high serum ECP
levels in non-responders. Hence, eosinophil frequency and serum ECP as a soluble
eosinophil-secreted mediator were suggested as prognostic biomarkers in melanoma. We
examined whether melanoma patients treated with first-line targeted therapy could also benefit
from the effects of eosinophils. In total, 243 blood and serum samples from patients with
advanced melanoma were prospectively and retrospectively collected before and after drug
initiation. To link eosinophil function to improved clinical outcome, soluble serum markers and
peripheral blood counts were used for correlative studies using a homogeneous study cohort.
In addition, functional and phenotypical characterizations provided insights into the expression
profile and activity of freshly isolated eosinophils, including comparisons between patients and
healthy donors.
Our data showed a significant correlation between high pre-treatment blood eosinophil counts
and improved response to targeted therapy and by trend to combinatorial immunotherapy in
patients with metastatic melanoma. In accordance with previous studies our results links
eosinophil blood counts to better response in melanoma patients. High pre-treatment ECP
serum concentration correlated with response to immunotherapy but not to targeted therapy.
Eosinophils from healthy donors and patients showed functional and phenotypical similarities.
Functional assays revealed a strong cytotoxic potential of blood eosinophils towards
melanoma cells in vitro, inducing apoptosis and necrosis. In addition, in vitro cytotoxicity was
an active process of peripheral eosinophils and melanoma cells with bidirectional features and
required close cell-cell interaction. The extent of cytotoxicity was dose-dependent and showed
susceptibility to changes in physical factors like adherence. Importantly, we provide evidence
of an additive tumoricidal function of eosinophils and combinatorial targeted therapy in vitro. In
summary, we give valuable insights into the complex and treatment-dependent role of
eosinophils in melanoma. As a result, our data support the suggestion of eosinophils and their
secreted mediators as potential prognostic biomarkers. It will take additional studies to
examine the molecular mechanisms that underlie our findings.
Methionine is the first amino acid of every newly synthesised protein. In combination with its role as precursor for the vital methyl-group donor S-adenosylmethionine, methionine is essential for every living cell. The opportunistic human pathogen Staphylococcus aureus is capable of synthesising methionine de novo, when it becomes scarce in the environment. All genes required for the de novo biosynthesis are encoded by the metICFE-mdh operon, except for metX. Expression is controlled by a hierarchical network with a methionyl-tRNA-specific T-box riboswitch (MET-TBRS) as centrepiece, that is also referred to as met leader (RNA). T-box riboswitches (TBRS) are regulatory RNA elements located in the 5’-untranslated region (5’-UTR) of genes. The effector molecule of T-box riboswitches is uncharged cognate tRNA. The prevailing mechanism of action is premature termination of transcription of the nascent RNA in the absence of the effector (i.e. uncharged cognate tRNA) due to formation of a hairpin structure, the Terminator stem. In presence of the effector, a transient stabilisation of the alternative structure, the Antiterminator, enables transcription of the downstream genes (‘read-through’). Albeit, after the read-through the thermodynamically more stable Terminator eventually forms. The Terminator and the Antiterminator are two mutually exclusive structures. Previous work of the research group showed that in staphylococci the MET-TBRS ensures strictly methionine-dependent control of met operon expression. Uncharged methionyl-tRNA that activates the system is only present in sufficient amounts under methionine-deprived conditions. In contrast to other bacterial TBRS, the staphylococcal MET-TBRS has some characteristic features regarding its length and predicted secondary structure whose relevance for the function are yet unkown.
Aim of the present thesis was to experimentally determine the structure of the met leader RNA and to investigate the stability of the met operon-specific transcripts in the context of methionine biosynthesis control. Furthermore, the yet unknown function of the mdh gene within the met operon was to be determined.
In the context of this thesis, the secondary structure of the met leader was determined employing in-line probing. The structural analysis revealed the presence of almost all highly conserved T-box riboswitch structural characteristics. Furthermore, three additional stems, absent in all T-box riboswitches analysed to date, could be identified. Particularly remarkable is the above average length of the Terminator stem which renders it a potential target of the double-strand-specific endoribonuclease III (RNase III). The RNase III-dependent cleavage of the met leader could be experimentally verified by the use of suitable mutants. Moreover, the exact cleavage site within the Terminator was determined.
The unusual immediate separation of the met leader from the met operon mRNA via the RNase III cleavage within the Terminator stem induces the rapid degradation of the met leader RNA and, most likely, that of the 5’-region of the met mRNA. The met mRNA is degraded from its 5’-end by the exoribonuclease RNase J. The stability of the met mRNA was found to vary over the length of the transcript with an instable 5’-end (metI and metC) and a longer half-life towards the 3’-end (metE and mdh). The varying transcript stability is reflected by differences in the available cellular protein levels. The obtained data suggest that programmed mRNA degradation is another level of regulation in the complex network of staphylococcal de novo methionine biosynthesis control.
In addition, the MET-TBRS was studied with regard to a future use as a drug target for novel antimicrobial agents. To this end, effects of a dysregulated methionine biosynthesis on bacterial growth and survival were investigated in met leader mutants that either caused permanent transcription of the met operon (‘ON’) or prevented operon transcription (‘OFF’), irrespective of the methionine status in the cell. Methionine deprivation turned out to be a strong selection pressure, as ‘OFF’ mutants acquired adaptive mutations within the met leader to restore met operon expression that subsequently re-enabled growth.
The second part of the thesis was dedicated to the characterisation of the Mdh protein that is encoded by the last gene of the met operon and whose function is unknown yet. At first, co-transcription and -expression with the met operon could be demonstrated. Next, the Mdh protein was overexpressed and purified and the crystal structure of Mdh was solved to high resolution by the Kisker research group (Rudolf-Virchow-Zentrum Würzburg). Analysis of the structure revealed the amino acid residues crucial for catalytic activity, and zinc was identified as a co-factor of Mdh. Also, Mdh was shown to exist as a dimer. However, identification of the Mdh substrate was, in the context of this thesis, (still) unsuccessful. Nevertheless, interactions of Mdh with enzymes of the met operon could be demonstrated by employing the bacterial two-hybrid system. This fact and the high conservation of mdh/Mdh on nucleotide and amino acid level among numerous staphylococcal species suggests an important role of Mdh within the methionine metabolism that should be a worthwhile subject of future research.
Attention-deficit/hyperactivity disorder (ADHD) is a genetically complex childhood onset neurodevelopmental disorder which is highly persistent into adulthood. Several chromo-somal regions associated with this disorder were identified previously in genome-wide linkage scans, association (GWA) and copy number variation (CNV) studies. In this work the results of case-control and family-based association studies using a can-didate gene approach are presented. For this purpose, possible candidate genes for ADHD have been finemapped using mass array-based SNP genotyping. The genes KCNIP4, CDH13 and DIRAS2 have been found to be associated with ADHD and, in addition, with cluster B and cluster C personality disorders (PD) which are known to be related to ADHD. Most of the associations found in this work would not withstand correction for multiple testing. However, a replication in several independent populations has been achieved and in conjunction with previous evidence from linkage, GWA and CNV studies, it is assumed that there are true associations between those genes and ADHD. Further investigation of DIRAS2 by quantitative real-time PCR (qPCR) revealed expression in the hippocampus, cerebral cortex and cerebellum of the human brain and a significant increase in Diras2 expression in the mouse brain during early development. In situ hybrid-izations on murine brain slices confirmed the results gained by qPCR in the human brain. Moreover, Diras2 is expressed in the basolateral amygdala, structures of the olfactory system and several other brain regions which have been implicated in the psychopatholo-gy of ADHD. In conclusion, the results of this work provide further support to the existence of a strong genetic component in the pathophysiology of ADHD and related disorders. KCNIP4, CDH13 and DIRAS2 are promising candidates and need to be further examined to get more knowledge about the neurobiological basis of this common disease. This knowledge is essential for understanding the molecular mechanisms underlying the emergence of this disorder and for the development of new treatment strategies.
In dieser Dissertation wird der MEK5/ERK5- Signalweg als möglicher Angriffspunkt in der zielgerichteten Melanomtherapie identifiziert. Die Adressierung von ERK5 bietet eine Alternative, um einer Resistenzentwicklung gegenüber Inhibitoren des MAPK- Signalwegs entgegenzuwirken. Das maligne Melanom ist ein hochaggressiver Tumor mit steigender Inzidenz. Zunehmende Sonnenstunden im Rahmen des Klimawandels mit erhöhter Belastung der Haut durch UV-Strahlung werden die Problematik des malignen Melanoms für den Menschen in den nächsten Jahren weiter zunehmen lassen.
Die Aktivierung des MEK5/ERK5- Signalwegs scheint eine Reaktion von Tumorzellen auf Therapiestress zu sein. Diese Aktivierung liefert den Melanomzellen einen Überlebensvorteil und verhindert ein langfristiges Therapieansprechen. ERK5 beeinflusst den Zellzyklus von Melanomzellen und ist somit möglicherweise von wichtiger Bedeutung in der Tumorgenese des malignen Melanoms.
Patienten mit NRAS- Mutation profitieren auffallend weniger von einer gezielten MEKi-Therapie als solche mit BRAF Mutation. Für ersteres Patientenkollektiv steht aktuell lediglich die Immuntherapie zur Verfügung, wodurch oft nur ein kurzes, progressionsfreies Intervall erreicht werden kann und die Patienten häufig unter schweren Nebenwirkungen leiden. Grund für die problematische Behandlung könnte das häufige Auftreten einer basalen ERK5- Aktivierung in NRAS- mutierten Melanomen sein. Diese Arbeit liefert eine positive Prognose über den Nutzen einer ERK5- Inhibition als Erweiterung des Therapieschemas. Diese These gilt auch für Melanompatienten mit einer BRAF- Mutation. Patienten, die an einem malignen Melanom erkrankt sind, weisen zu 80% eine Mutation in einem dieser beschriebenen Onkogene auf. Die Arbeit lässt darauf schließen, dass eine ERK5- Inhibition in der Therapie von beiden Gruppen erfolgreich sein könnte und somit das Leben nahezu aller Melanompatienten betrifft.
The present dissertation aims to shed light on different mechanisms of socio-emotional feedback in social decision-making situations. The objective is to evaluate emotional facial expressions as feedback stimuli, i.e., responses of interaction partners to certain social decisions. In addition to human faces, artificial emojis are also examined due to their relevance for modern digital communication. Previous research on the influence of emotional feedback suggests that a person's behavior can be effectively reinforced by rewarding stimuli. In the context of this dissertation, the differences in the feedback processing of human photographs and emojis, but also the evaluation of socially expected versus socially unexpected feedback were examined in detail in four studies. In addition to behavioral data, we used the electroencephalogram (EEG) in all studies to investigate neural correlates of social decision-making and emotional feedback.
As the central paradigm, all studies were based on a modified ultimatum game. The game is structured as follows: there is a so-called proposer who holds a specific amount of money (e.g., 10 cents) and offers the responder a certain amount (e.g., 3 cents). The responder then decides whether to accept or reject the offer. In the version of the ultimatum game presented here, different types of proposers are introduced. After the participants have accepted or rejected in the role of the responder, the different proposers react to the participant’s decision with specific emotional facial expressions. Different feedback patterns are used for the individual experiments conducted in the course of this dissertation.
In the first study, we investigated the influence of emotional feedback on decision-making in the modified version of the ultimatum game. We were able to show that a proposer who responds to the acceptance of an offer with a smiling face achieves more accepted offers overall than a control proposer who responds to both accepted and rejected offers with a neutral facial expression. Consequently, the smile served as a positive reinforcement. Similarly, a sad expression in response to a rejected offer also resulted in higher acceptance rates as compared to the control identity, which could be considered an expression of compassion for that proposer. On a neuronal level, we could show that there are differences between simply looking at negative emotional stimuli (i.e., sad and angry faces) and their appearance as feedback stimuli after rejected offers in the modified ultimatum game. The so-called feedback-related negativity was reduced (i.e., more positive) when negative emotions appeared as feedback from the proposers. We argued that these findings might show that the participants wanted to punish the proposers by rejecting an offer for its unfairness and therefore the negative feedback met their expectations. The altered processing of negative emotional facial expressions in the ultimatum game could therefore indicate that the punishment is interpreted as successful. This includes the expectation that the interaction partner will change his behavior in the future and eventually make fairer offers.
In the second study we wanted to show that smiling and sad emojis as feedback stimuli in the modified ultimatum game can also lead to increased acceptance rates. Contrary to our assumptions, this effect could not be observed. At the neural level as well, the findings did not correspond to our assumptions and differed strongly from those of the first study. One finding, however, was that the neural P3 component showed how the use of emojis as feedback stimuli particularly characterizes certain types of proposers. This is supported by the fact that the P3 is increased for the proposer who rewards an acceptance with a smile as well as for the proposer who reacts to rejection with a sad emoji compared to the neutral control proposer.
The third study examined the discrepancy between the findings of the first and second study. Accordingly, both humans and emojis representing the different proposers were presented in the ultimatum game. In addition, emojis were selected that showed a higher similarity to known emojis from common messenger services compared to the second study. We were able to replicate that the proposers in the ultimatum game, who reward an acceptance of the offer with a smile, led to an increased acceptance rate compared to the neutral control proposers. This difference is independent of whether the proposers are represented by emojis or human faces. With regard to the neural correlates, we were able to demonstrate that emojis and human faces differ strongly in their neural processing. Emojis showed stronger activation than human faces in the face-processing N170 component, the feedback-related negativity and the P3 component. We concluded that the results of the N170 and feedback-related negativity could indicate a signal for missing social information of emojis compared to faces. The increased P3 amplitude for emojis might imply that emojis appear unexpectedly as reward stimuli in a social decision task compared to human faces.
The last study of this project dealt with socially unexpected feedback. In comparison to the first three studies, new proposer identities were implemented. In particular, the focus was on a proposer who reacted to the rejection of an offer unexpectedly with a smile and to the acceptance with a neutral facial expression. According to the results, participants approach this unexpected smile through increased rejection, although it is accompanied by financial loss. In addition, as reported in studies one and three, we were able to show that proposers who respond to the acceptance of an offer with a smiling face and thus meet the expectations of the participants have higher offer acceptance rates than the control proposer. At the neuronal level, especially the feedback from the socially unexpected proposer led to an increased P3 amplitude, which indicates that smiling after rejection is attributed a special subjective importance.
The experiments provide new insights into the social influence through emotional feedback and the processing of relevant social cues. Due to the conceptual similarity of the studies, it was possible to differentiate between stable findings and potentially stimulus-dependent deviations, thus creating a well-founded contribution to the current research. Therefore, the novel paradigm presented here, and the knowledge gained from it could also play an important role in the future for clinical questions dealing with limited social competencies.
Sepsis ist eine dysregulierte Reaktion des Organismus auf eine Infektion. Bei Sepsis werden oft Blutungs- und Thromboseereignisse beobachtet, welche in einer Disseminierten Intravasalen Gerinnung (DIG) gipfeln können. Thrombozyten sind die Schlüsselzellen von Thrombose und Hämostase. Bei Sepsis und DIG kommt es häufig zu einem Abfall der Thrombozytenzahl, doch Blutungs- und Thromboseereignisse können unabhängig von der Thrombozytenzahl auftreten, was zusätzlich eine Veränderung der Thrombozytenfunktion nahelegt.
In dieser Arbeit wurde deshalb die Thrombozytenfunktion bei 15 Patienten mit Sepsis zu drei Zeitpunkten im Krankheitsverlauf untersucht. Es konnte bei unauffälliger Rezeptorexpression keine Voraktivierung der Thrombozyten mittels Durchflusszytometrie festgestellt werden. Jedoch war die Aktivierung nach Stimulation mit multiplen Agonisten signifikant reduziert. Besonders ausgeprägt war die Hyporeaktivität bei Stimulation des Kollagen-Rezeptors GPVI mit dem Agonisten CRP-XL. Es wurde gezeigt, dass nach GPVI-Stimulation eine reduzierte Phosphorylierung der nachgeschalteten Proteine Syk und LAT im Vergleich zum Gesundspender induziert wird. In Kreuzinkubationsexperimenten hatte die (Co )Inkubation von Thrombozyten in Plasma von Sepsispatienten oder mit Bakterienisolaten aus Sepsis-Blutkulturen keinen Effekt auf die Thrombozytenreaktivität. Allerdings konnte durch Sepsis-Vollblut eine signifikante GPVI-Hyporeaktivität in Thrombozyten von gesunden Probanden induziert werden, was einen zellulären Mediator als Ursache des Defekts nahelegt. In dieser Arbeit wurde gezeigt, dass insbesondere die GPVI-Signalkaskade bei Sepsis massiv beeinträchtigt ist. Der Immunorezeptor GPVI ist ein vielversprechendes Zielmolekül, um die Pathogenese der Sepsis, des Capillary Leak und die immunregulatorische Rolle von Thrombozyten besser zu verstehen. Die GPVI-Hyporeaktivität könnte als zukünftiger Biomarker für die Sepsis-Frühdiagnose genutzt werden.
The human pathogen Aspergillus (A.) fumigatus is a fungal mold that can cause severe infections in immunocompromised hosts. Pathogen recognition and immune cell cross-talk are essential for clearing fungal infections efficiently. Immune cell interactions in particular may enhance individual cell activation and cytotoxicity towards invading pathogens.
This study analyzed the reciprocal cell activation of natural killer (NK) cells and monocyte-derived dendritic cells (moDCs) after stimulation with A. fumigatus cell wall fractions and whole-cell lysates. Furthermore, the impact of the on moDCs expressed fungal receptors Dectin-1 and TLR-2 on NK cell activation was analyzed. Stimulation of moDCs with ligands for Dectin-1 and TLR-2 and transfer of soluble factors on autologous NK cells showed that moDCs could induce NK cell activation solely by secreting factors. In summary, both cell types could induce reciprocal cell activation if the stimulated cell type recognized fungal morphologies and ligands. However, moDCs displayed a broader set of A. fumigatus receptors and, therefore, could induce NK cell activation when those were not activated by the stimulus directly.
Consequently, new fungal receptors should be identified on NK cells. The NK cell characterization marker CD56 was reduced detected in flow cytometry after fungal co-culture. Notably, this decreased detection was not associated with NK cell apoptosis, protein degradation, internalization, or secretion of CD56 molecules. CD56 was shown to tightly attach to hyphal structures, followed by its concentration at the NK-A. fumigatus interaction site. Actin polymerization was necessary for CD56 relocalization, as pre-treatment of NK cells with actin-inhibitory reagents abolished CD56 binding to the fungus. Blocking of CD56 suppressed fungal mediated NK cell activation and secretion of the immune-recruiting chemokines MIP-1α, MIP-1β, and RANTES, concluding that CD56 is functionally involved in fungal recognition by NK cells.
CD56 binding to fungal hyphae was inhibited in NK cells obtained from patients during immune-suppressing therapy after allogeneic stem cell transplantation (alloSCT). Additionally, reduced binding of CD56 correlated with decreased actin polymerization of reconstituting NK cells challenged with the fungus. The immune-suppressing therapy with corticosteroids negatively influenced the secretion of MIP-1α, MIP-1β, and RANTES in NK cells after fungal stimulation ex vivo. Similar results were obtained when NK cells from healthy donors were treated with corticosteroids prior to fungal co-culture. Thus, corticosteroids were identified to have detrimental effects on NK cell function during infection with A. fumigatus.
The unicellular pathogen Trypanosoma brucei is the causative agent of African
trypanosomiasis, an endemic disease prevalent in sub-Saharan Africa. Trypanosoma brucei alternates between a mammalian host and the tsetse fly vector. The extracellular parasite survives in the mammalian bloodstream by periodically exchanging their ˈvariant surface glycoproteinˈ (VSG) coat to evade the host immune response. This antigenic variation is achieved through monoallelic expression of one VSG variant from subtelomeric ˈbloodstream
form expression sitesˈ (BES) at a given timepoint. During the differentiation from the bloodstream form (BSF) to the procyclic form (PCF) in the tsetse fly midgut, the stage specific surface protein is transcriptionally silenced and replaced by procyclins. Due to their subtelomeric localization on the chromosomes, VSG transcription and silencing is partly regulated by homologues of the mammalian telomere complex such as TbTRF, TbTIF2 and TbRAP1 as well as by ˈtelomere-associated proteinsˈ (TelAPs) like TelAP1. To gain more insights into transcription regulation of VSG genes, the identification and characterization of other TelAPs is critical and has not yet been achieved. In a previous study, two biochemical approaches were used to identify other novel TelAPs. By using ˈco-immunoprecipitationˈ (co-IP) to enrich possible interaction partners of TbTRF and by affinity chromatography using telomeric repeat oligonucleotides, a listing of TelAP candidates has been conducted. With this approach TelAP1 was identified as a novel component of the telomere complex, involved in the kinetics of transcriptional BES silencing during BSF to PCF differentiation. To gain further insights into the telomere complex composition, other previously enriched proteins were characterized through a screening process using RNA interference to deplete potential candidates. VSG expression profile changes and overall proteomic changes after depletion were analyzed by mass spectrometry. With this method, one can gain insights into the functions of the proteins and their involvement in VSG expression site regulation. To validate the interaction of proteins enriched by co-IP with TbTRF and TelAP1 and to identify novel interaction proteins, I performed reciprocal affinity purifications of the four most promising candidates (TelAP2, TelAP3, PPL2 and PolIE) and additionally confirmed colocalization of two candidates with TbTRF via immunofluorescence (TelAP2, TelAP3). TelAP3 colocalizes with TbTRF and potentially interacts with TbTRF, TbTIF2, TelAP1 and TelAP2, as well as with two translesion polymerases PPL2 and PolIE in BSF. PPL2 and PolIE seem to be in close contact to each other at the telomeric ends and fulfill different roles as only PolIE is involved in VSG regulation while PPL2 is not. TelAP2 was previously characterized to be associated with telomeres by partially colocalizing with TbTRF and cells show a VSG derepression phenotype when the protein was depleted. Here I show that TelAP2 interacts with the telomere-binding proteins TbTRF and TbTIF2 as well as with the telomere-associated protein TelAP1 in BSF and that TelAP2 depletion results in a loss of TelAP1 colocalization with TbTRF in BSF.
In conclusion, this study demonstrates that characterizing potential TelAPs is effective in gaining insights into the telomeric complex's composition and its role in VSG regulation in Trypanosoma brucei. Understanding these interactions could potentially lead to new therapeutic targets for combatting African trypanosomiasis.
Cardiac healing after myocardial infarction (MI) represents the cardinal prerequisite for proper replacement of the irreversibly injured myocardium. In contrast to innate immunity, the functional role of adaptive immunity in postinfarction healing has not been systematically addressed. The present study focused on the influence of CD4+ T lymphocytes on wound healing and cardiac remodeling after experimental myocardial infarction in mice. Both conventional and Foxp3+ regulatory CD4+ T cells (Treg cells) became activated in heart draining lymph nodes after MI and accumulated in the infarcted myocardium. T cell activation was strictly antigen-dependant as T cell receptor-transgenic OT-II mice in which CD4+ T cells exhibit a highly limited T cell
receptor repertoire did not expand in heart-draining lymph nodes post-MI. Both OT-II and major histocompatibility complex class II-deficient mice lacking a CD4+ T cell compartment showed a fatal clinical postinfarction outcome characterized by disturbed scar tissue construction that resulted in impaired survival due to a prevalence of left-ventricular ruptures. To assess the contribution of anti-inflammatory Treg cells on wound healing after MI, the Treg cell compartment was depleted using DEREG mice that specifically express the human diphtheria toxin receptor in Foxp3-positive cells, resulting in Treg cell ablation after diphtheria toxin administration. In a parallel line of experiments, a second model of anti-CD25 antibody-mediated Treg cell immuno-depletion was used. Treg cell ablation prior to MI resulted in adverse postinfarction left-ventricular dilatation associated with cardiac deterioration. Mechanistically, Treg cell depletion resulted in an increased recruitment of pro-inflammatory neutrophils and Ly-6Chigh monocytes into the healing myocardium. Furthermore, Treg cell-ablated mice exhibited an adverse activation of conventional non-regulatory CD4+ and CD8+ T cells that
showed a reinforced infiltration into the infarct zone. Increased synthesis of TNFα and IFNγ by conventional CD4+ and CD8+ T cells in hearts of Treg cell-depleted mice provoked an M1-like macrophage polarization characterized by heightened expression of healing-compromising induced NO synthase, in line with a reduced synthesis of healing-promoting transglutaminase factor XIII (FXIII), osteopontin (OPN) and transforming growth factor beta 1 (TGFβ1).
Therapeutic Treg cell activation by a superagonistic anti-CD28 monoclonal antibody stimulated Treg cell accumulation in the infarct zone and led to an increased expression of mediators inducing an M2-like macrophage polarization state, i.e. interleukin-10, interleukin-13 and TGFβ1. M2-like macrophage differentiation in the healing infarct was associated with heightened expression of scar-forming procollagens as well as scar-stabilizing FXIII and OPN, resulting in improved survival due to a reduced incidence of left-ventricular ruptures. Therapeutic Treg cell activation and the induction of a beneficial M2-like macrophage polarization was further achieved by employing a treatment modality of high clinical potential, i.e. by therapeutic administration of IL-2/ anti-IL-2 monoclonal antibody complexes. The findings of the present study suggest that therapeutic Treg cell activation and the resulting improvement of healing may represent a suitable strategy to attenuate adverse infarct expansion, left-ventricular remodeling, or infarct ruptures in patients with MI.
The Myb-MuvB (MMB) multiprotein complex is a master regulator of cell cycle-dependent gene expression. Target genes of MMB are expressed at elevated levels in several different cancer types and are included in the chromosomal instability (CIN) signature of lung, brain, and breast tumors.
This doctoral thesis showed that the complete loss of the MMB core subunit LIN9 leads to strong proliferation defects and nuclear abnormalities in primary lung adenocarcinoma cells. Transcriptome profiling and genome-wide DNA-binding analyses of MMB in lung adenocarcinoma cells revealed that MMB drives the expression of genes linked to cell cycle progression, mitosis, and chromosome segregation by direct binding to promoters of these genes. Unexpectedly, a previously unknown overlap between MMB-dependent genes and several signatures of YAP-regulated genes was identified. YAP is a transcriptional co-activator acting downstream of the Hippo signaling pathway, which is deregulated in many tumor types. Here, MMB and YAP were found to physically interact and co-regulate a set of mitotic and cytokinetic target genes, which are important in cancer. Furthermore, the activation of mitotic genes and the induction of entry into mitosis by YAP were strongly dependent on MMB. By ChIP-seq and 4C-seq, the genome-wide binding of MMB upon YAP overexpression was analyzed and long-range chromatin interaction sites of selected MMB target gene promoters were identified. Strikingly, YAP strongly promoted chromatin-association of B-MYB through binding to distal enhancer elements that interact with MMB-regulated promoters through chromatin looping.
Together, the findings of this thesis provide a so far unknown molecular mechanism by which YAP and MMB cooperate to regulate mitotic gene expression and suggest a link between two cancer-relevant signaling pathways.
The aim of this project was to investigate whether reflex-like innate facial reactions to tastes and odors are altered in patients with eating disorders. Qualitatively different tastes and odors have been found to elicit specific facial expressions in newborns. This specificity in newborns is characterized by positive facial reactions in response to pleasant stimuli and by negative facial reactions in response to unpleasant stimuli. It is, however, unclear, whether these specific facial displays remain stable during ontogeny (1). Despite the fact that several studies had shown that taste-and odor-elicited facial reactions remain quite stable across a human’s life-span, the specificity of research questions, as well as different research methods, allow only limited comparisons between studies. Moreover, the gustofacial response patterns might be altered in pathological eating behavior (2). To date, however, the question of whether dysfunctional eating behavior might alter facial activity in response to tastes and odors has not been addressed. Furthermore, changes in facial activity might be linked to deficient inhibitory facial control (3). To investigate these three research questions, facial reactions in response to tastes and odors were assessed. Facial reactions were analyzed using the Facial Action Coding System (FACS, Ekman & Friesen, 1978; Ekman, Friesen, & Hager, 2002) and electromyography.
This thesis aimed the development of a correlated device which combines FluidFM® with Fluorescence Microscopy (FL) (FL-FluidFM®) and enables the simultaneous quantification of adhesion forces and fluorescent visualization of mature cells. The implementation of a PIFOC was crucial to achieve a high-resolution as well as a stable but dynamic focus level. The functionality of SCFS after hardware modification was verified by comparing two force-curves, both showing the typical force progression and measured with the optimized and conventional hardware, respectively. Then, the integration of FL was examined by detaching fluorescently labeled REF52 cells. The fluorescence illumination of the cytoskeleton showed the expected characteristic force profile and no evidence of interference effects. Afterwards a corresponding correlative data analysis was addressed including manual force step fitting, the identification of visualized cellular unbinding, and a time-dependent correlation. This procedure revealed a link between the area of cytoskeletal unbinding and force-jumps. This was followed by a comparison of the detachment characteristics of intercellular connected HUVECs and individual REF52 cells. HUVECs showed maximum detachment forces in the same order of magnitude as the ones of single REF52 cells. This contrasted with the expected strong cohesiveness of endothelial cells and indicated a lack of cell-cell contact formation. The latter was confirmed by a comparison of HUVECs, primary HBMVECs, and immortalized EA.hy926 cells fluorescently labeled for two marker proteins of intercellular junctions. This unveiled that both the previous cultivation duration and the cell type have a major impact on the development of intercellular junctions. In summary, the correlative FL FluidFM® represents a powerful novel approach, which enables a truly contemporaneous performance and, thus, has the potential to reveal new insights into the mechanobiological properties of cell adhesion.
Herzschrittmachersysteme sind eine weitverbreitete Möglichkeit Herz-Kreislauf-Erkrankungen zu behandeln. Wegen der natürlichen Reaktion des Immunsystems auf Fremdkörper, erfolgt aber eine fortschreitende Verkapselung der Herzschrittmacherelektrode. Die Folge ist eine ansteigende Verminderung der Stimulationseffizienz durch Erhöhung der Anregungsschwelle. Die Integration der Elektrode in das Gewebe ist dabei mangelhaft und wird bestimmt durch Implantateigenschaften wie Größe, Flexibilität und Dimensionalität. Um die Integration zu verbessern, stellen dreidimensionale (3D) bzw. gewebeartige Elektroden eine Alternative zu den derzeit verwendeten planaren Metallelektroden dar. Zur Entwicklung einer leitfähigen, 3D und faserförmigen Elektrode wurden in dieser Arbeit Kohlenstoff-Nanofaser-Scaffolds über Elektrospinnen hergestellt. Durch die Modifikation des Fasergerüstes mit Natriumchlorid (NaCl) während der Scaffoldherstellung, konnte das Fasernetzwerk aufgelockert und Poren generiert werden. Die Kohlenstofffaser-Elektroden zeigten einen effizienten Energieübertrag, welcher vergleichbar mit heutigen Titannitrid (TiN) -Elektroden ist. Die Auflockerung des Fasergewebes hatte eine verbesserte Flexibilität des Faserscaffolds zu Folge. Neben der Flexibilität, konnte auch die Infiltration von Zellen in das poröse Faserscaffold erheblich verbessert werden. Dabei konnten Fibroblasten durch das gesamte Scaffold migrieren. Die Kompatibilität mit kardialen Zellen, die Grundvoraussetzung von Herzschrittmacherelektroden, wurde in vitro nachgewiesen. Durch die Kombination aus dem 3D-Elektrodengerüst mit einer Co-Kultur aus humanen Kardiomyozyten, mesenchymalen Stammzellen und Fibroblasten, erfolgte eine Einbettung der Elektrode in funktionelles kardiales Gewebe. Dadurch konnte ein lebender Gewebe-Elektroden-Hybrid generiert werden, welcher möglicherweise die Elektrode vor Immunzellen in vivo abschirmen kann. Eine Zusammenführung der hybriden Elektrode mit einen Tissue-Engineerten humanen kardialen Patch in vitro, führte zu Bildung einer nahtlosen Elektronik-Gewebe-Schnittstelle. Die fusionierte Einheit wurde abschließend auf ihre mechanische Belastbarkeit getestet und konnte über einen Elektroden-Anschluss elektrisch stimuliert werden.
Sepsis ist ein häufiges und akut lebensbedrohliches Syndrom, das eine Organfunktionsstörung in Folge einer dysregulierten Immunantwort auf eine Infektion beschreibt. Eine frühzeitige Diagnosestellung und Therapieeinleitung sind von zentraler Bedeutung für das Überleben der Patient:innen. In einer Pilotstudie konnte unsere Forschungsgruppe mittels Durchflusszytometrie eine ausgeprägte Hyporeaktivität der Thrombozyten bei Sepsis nachweisen, die einen potenziell neuen Biomarker zur Sepsis-Früherkennung darstellt. Zur Evaluation des Ausmaßes und Entstehungszeitpunktes der detektierten Thrombozytenfunktionsstörung wurden im Rahmen der vorliegenden Arbeit zusätzlich zu Patient:innen mit Sepsis (SOFA-Score ≥ 2; n=13) auch hospitalisierte Patient:innen mit einer Infektion ohne Sepsis (SOFA-Score < 2; n=12) rekrutiert. Beide Kohorten wurden zu zwei Zeitpunkten (t1: <24h; t2: Tag 5-7) im Krankheitsverlauf mittels Durchflusszytometrie und PFA-200 untersucht und mit einer gesunden Kontrollgruppe (n=28) verglichen.
Phänotypische Auffälligkeiten der Thrombozyten bei Sepsis umfassten: (i) eine veränderte Expression verschiedener Untereinheiten des GPIb-IX-V-Rezeptorkomplexes, die auf ein verstärktes Rezeptor-Shedding hindeutet; (ii) ein ausgeprägtes Mepacrin-Beladungsdefizit, das auf eine zunehmend reduzierte Anzahl von δ-Granula entlang des Infektion-Sepsis Kontinuums hinweist; (iii) eine Reduktion endständig gebundener Sialinsäure im Sinne einer verstärkten Desialylierung. Die funktionelle Analyse der Thrombozyten bei Sepsis ergab bei durchflusszytometrischer Messung der Integrin αIIbβ3-Aktivierung (PAC-1-Bindung) eine ausgeprägte generalisierte Hyporeaktivität gegenüber multiplen Agonisten, die abgeschwächt bereits bei Infektion nachweisbar war und gemäß ROC-Analysen gut zwischen Infektion und Sepsis diskriminierte (AUC >0.80 für alle Agonisten). Im Gegensatz dazu zeigten Thrombozyten bei Sepsis und Analyse mittels PFA-200 unter Einfluss physiologischer Scherkräfte eine normale bis gar beschleunigte Aggregation.
Die Reaktivitätsmessung von Thrombozyten mittels Durchflusszytometrie stellt weiterhin einen vielversprechenden Biomarker für die Sepsis-Früherkennung dar. Für weitere Schlussfolgerungen ist jedoch eine größere Kohorte erforderlich. In nachfolgenden Untersuchungen sollten zudem mechanistische Ursachen der beschriebenen phänotypischen und funktionellen Auffälligkeiten von Thrombozyten bei Infektion und Sepsis z.B. mittels Koinkubationsexperimenten untersucht werden.
Mit jährlich circa 11 Millionen Fällen weltweit, stellen schwere Brandwunden bis heute einen großen Anteil an Verletzungen dar, die in Kliniken behandelt werden müssen. Während leichte Verbrennungen meist problemlos heilen, bedarf die Behandlung tieferer Verbrennungen medizinischer Intervention. Zellbasierte Therapeutika zeigen hier bereits große Erfolge, aufgrund der eingeschränkten Übertragbarkeit von Ergebnissen aus Tiermodellen ist jedoch sowohl die Testung neuer Produkte, als auch die Erforschung der Wundheilung bei Brandwunden noch immer schwierig.
Aufgrund dessen wurden in dieser Arbeit zwei Ziele verfolgt: Die Etablierung von Methoden, um ein zellbasiertes Therapeutikum produzieren zu können und die Entwicklung eines Modells zur Untersuchung von Verbrennungswunden. Zunächst wurden hierfür die Kulturbedingungen und -protokolle zur Isolation und Expansion von Keratinozyten so angepasst, dass sie gängigen Regularien zur Produktion medizinischer Produkte entsprechen. Hier zeigten die Zellen auch in anschließenden Analysen, dass charakteristische Merkmale nicht verloren hatten. Darüber hinaus gelang es, die Zellen mithilfe verschiedener protektiver Substanzen erfolgreich einzufrieren und zu konservieren.
Des Weiteren konnte ein Modell etabliert werden, das eine Verbrennung ersten Grades widerspiegelt. Über einen Zeitraum von zwei Wochen wurde seine Regeneration hinsichtlich verschiedener Aspekte, wie der Histomorphologie, dem Metabolismus und der Reepithelialisierungsrate, untersucht. Die Modelle zeigten hier viele Parallelen zur Wundheilung in vivo auf. Um die Eignung der Modelle zur Testung von Wirkstoffen zu ermitteln wurde außerdem eine Behandlung mit 5% Dexpanthenol getestet. Sie resultierte in einer verbesserten Histomorphologie und einer erhöhten Anzahl an proliferativen Zellen in den Modellen, beschleunigte jedoch die Reepithelialisierung nicht. Zusammengefasst konnten in dieser Arbeit zunächst Methoden etabliert werden, um ein medizinisches Produkt aus Keratinozyten herzustellen und zu charakterisieren. Außerdem wurde ein Modell entwickelt, anhand dessen die Wundheilung und Behandlung von Verbrennungen ersten Grades untersucht werden kann und welches als Basis zur Entwicklung von Modellen von tieferen Verbrennungen dienen kann.
Adrenal Cushing’s Syndrome (CS) is a rare but life-threatening disease and therefore it is of great importance to understand the pathogenesis leading to adrenal CS. It is well accepted that Protein Kinase A (PKA) signalling mediates steroid secretion in adrenocortical cells. PKA is an inactive heterotetramer, consisting of two catalytic and two regulatory subunits. Upon cAMP binding to the regulatory subunits, the catalytic subunits are released and are able to phosphorylate their target proteins. Recently, activating somatic mutations affecting the catalytic subunit a of PKA have been identified in a sub-population of cortisol-producing adenomas (CPAs) associated with overt CS. Interestingly, the PKA regulatory subunit IIb has long been known to have significantly lower protein levels in a sub-group of CPAs compared to other adrenocortical tumours. Yet, it is unknown, why these CPAs lack the regulatory subunit IIb, neither are any functional consequences nor are the underlying regulation mechanisms leading to reduced RIIb levels known. The results obtained in this thesis show a clear connection between Ca mutations and reduced RIIb protein levels in CPAs but not in other adrenocortical tumours. Furthermore, a specific pattern of PKA subunit expression in the different zones of the normal adrenal gland is demonstrated. In addition, a Ca L206R mutation-mediated degradation of RIIb was observed in adrenocortical cells in vitro. RIIb degradation was found to be mediated by caspases and by performing mutagenesis experiments of the regulatory subunits IIb and Ia, S114 phosphorylation of RIIb was identified to make RIIb susceptible for degradation. LC-MS/MS revealed RIIb interaction partners to differ in the presence of either Ca WT and Ca L206R. These newly identified interaction partners are possibly involved in targeting RIIb to subcellular compartments or bringing it into spatial proximity of degrading enzymes. Furthermore, reducing RIIb protein levels in an in vitro system were shown to correlate with increased cortisol secretion also in the absence of PRKACA mutations. The inhibiting role of RIIb in cortisol secretion demonstrates a new function of this regulatory PKA subunit, improving the understanding of the complex regulation of PKA as key regulator in many cells.