Refine
Has Fulltext
- yes (45)
Is part of the Bibliography
- yes (45)
Year of publication
- 2015 (45) (remove)
Document Type
- Doctoral Thesis (45) (remove)
Keywords
- Taufliege (5)
- Drosophila (4)
- Therapie (4)
- Myc (3)
- Regulation (3)
- T-Lymphozyt (3)
- Brain-computer interface (2)
- Chemotherapie (2)
- Cryptochrom (2)
- EEG (2)
- Entzündung (2)
- Ereigniskorreliertes Potenzial (2)
- Glucosetransportproteine (2)
- Konditionierung (2)
- Krebs <Medizin> (2)
- Molekularbiologie (2)
- Nozizeptor (2)
- P300 (2)
- Ratte (2)
- Rezeptor (2)
- Rhodopsin (2)
- Transkription <Genetik> (2)
- learning and memory (2)
- regulation (2)
- 3-D liver model (1)
- 53BP1 (1)
- AAC (1)
- ALS (1)
- Actin (1)
- Adenosine receptors (1)
- Adenosinrezeptor (1)
- Adipogenesis (1)
- Alpha Neurofeedback (1)
- Alzheimer`s disease (1)
- Alzheimerkrankheit (1)
- Amyotrophe Lateralsklerose (1)
- Angiogenese (1)
- Angst (1)
- Angststörung (1)
- Antigen CD8 (1)
- Anxiety Disorders (1)
- Apallisches Syndrom (1)
- Apoptose (1)
- Apoptosis (1)
- Arthrosis deformans (1)
- Aspergillus (1)
- Aurora-A (1)
- Aversive Konditionierung (1)
- B-Lymphozyt (1)
- B-MYB (1)
- BCI (1)
- BMS-5 (1)
- Bacillus subtilis (1)
- Bariatric surgery (1)
- Biene (1)
- Biochemie (1)
- Biologie / Zellbiologie (1)
- Biologische Uhr (1)
- Bone marrow stromal cell (BMSC) (1)
- CD1d (1)
- CD8 T cell (1)
- CD8 T-Zelle (1)
- ChIP-sequencing (1)
- Chirurgie (1)
- Chlamydia trachomatis (1)
- Chronophin (1)
- Circadian Rhythms (1)
- Cofilin (1)
- Compound eyes (1)
- DC/T-Zell-Konjugate (1)
- DNA Doppelstrangbrüche (1)
- DNA double strand breaks (1)
- DNA methylation (1)
- DNS-Doppelstrangbruch (1)
- DREAM (1)
- Darm (1)
- Dendritische Zelle (1)
- Dendritische Zellen (1)
- Depression (1)
- Diabetes mellitus (1)
- Differentiation (1)
- Dimension 3 (1)
- Diversifikation <Biologie> (1)
- Dosimetrie (1)
- Double Negative B cells (1)
- Drosophila melanogaster (1)
- Duodenal Jejunal Bypass (1)
- Echinococcus (1)
- Eierstocktumor (1)
- Elektroencephalographie (1)
- Elektronencephalographie (1)
- Elektrophysiologie (1)
- Elongation (Transkription) (1)
- Entzündungschmerz (1)
- Enzymaktivierung (1)
- EphA2 (1)
- Ephrin ligand (1)
- Ephrine (1)
- Epigenetic (1)
- Epigenetik (1)
- FMMs (1)
- FOXM1 (1)
- Fear (1)
- Fear Conditioning (1)
- Fear Extinction (1)
- Fettsucht (1)
- Fettzelle (1)
- Fibroblastenwachstumsfaktor (1)
- Flotillin (1)
- Fluoreszenz-Resonanz-Energie-Transfer (1)
- Fluoreszenzkorrelationsspektroskopie (1)
- Fluoreszenzmikroskopie (1)
- Foamyviren (1)
- Französische Feldwespe (1)
- Fuchsbandwurm (1)
- Furcht (1)
- G-Protein gekoppelte Rezeptoren (1)
- G-Protein-gekoppelte Rezeptoren (1)
- GABA(A) receptor (1)
- GABA-Rezeptor (1)
- GAS2L3 (1)
- GDF-15 (1)
- Gehirn-Computer Schnittstelle (1)
- Gehirn-Computer-Schnittstelle (1)
- Gelernte Hilflosigkeit (1)
- Genexpression (1)
- Gewebe (1)
- Glatter Krallenfrosch (1)
- Glioblastom (1)
- Glucosetransport (1)
- Growth (1)
- Growth-differentiation Factor 15 (1)
- HERV (1)
- HLA-G (1)
- Heubacillus (1)
- Hippocampus (1)
- IL-6 Inhibition (1)
- Ileal Trasposition (1)
- Immunology (1)
- Insulinresistenz (1)
- Interaction analysis (1)
- Interleukin 6 (1)
- Kaliumkanal (1)
- Kernspintomografie (1)
- Kognition (1)
- Kognitive Störung (1)
- Kommunikationshilfe (1)
- LASP1 (1)
- LIMK (1)
- LIS (1)
- Lebensqualität (1)
- Leberepithelzelle (1)
- Leishmaniose (1)
- Lernen (1)
- Licht (1)
- Lipid Rafts (1)
- Lokalanästhesie (1)
- Lysin-Oxidase (1)
- Lysyl oxidases (1)
- Lysyloxidasen (1)
- MRI (1)
- MYCN-amplified (1)
- Manisch-depressive Krankheit (1)
- Maus (1)
- Medizinphysik (1)
- Melanin (1)
- Melanin release (1)
- Melanom (1)
- Memory B cells (1)
- Mesenchymale Stammzelle (1)
- Mesenchymzelle (1)
- Microscopy (1)
- Miz1 (1)
- Monoklonaler Antikörper (1)
- Moonlight (1)
- Muskelin (1)
- Myatrophische Lateralsklerose (1)
- Myokarditis (1)
- N-Myc (1)
- N400 (1)
- Nanomedicine (1)
- Nanomedizin (1)
- Nanoparticles (1)
- Nestbau (1)
- Neuroblastom (1)
- Neuroblastoma (1)
- Neurofeedback (1)
- Nuklearmedizin (1)
- Oligomerisation (1)
- Oligomerization (1)
- Oozyte (1)
- Opioide (1)
- Osteogenesis (1)
- Osteoporose (1)
- PDXP (1)
- PHMB (1)
- PI3K (1)
- Plasmamembran (1)
- Polistes (1)
- Polo-like kinase 1 (1)
- Prefrontalt Cortex (1)
- Protease (1)
- Proteaseaktivität (1)
- Proteasen (1)
- Proteasomaler Abbau (1)
- Präfrontaler Cortex (1)
- Pränatale Entwicklung (1)
- RESTORE protocol (1)
- RNS-Polymerase II (1)
- RS1 (1)
- RS1 Peptides (1)
- RS1 derived peptides (1)
- Radionuklid (1)
- Radionuklidtherapie (1)
- Repression (1)
- Reverse Transkriptase (1)
- Rheumatoid arthritis (1)
- Rho-GTPasen (1)
- Rho-Proteine (1)
- Rhodopsin 7 (1)
- Ribosome (1)
- SGLT1 (1)
- Schmerz (1)
- Serotonin (1)
- Signalkette (1)
- Spumaviren (1)
- Stammzelle (1)
- Stress (1)
- Strukturanalyse (1)
- Synapse (1)
- Synapses (1)
- Syncytin (1)
- T-Lymphozyten-Rezeptor (1)
- T-Zelle (1)
- Tagesrhythmus (1)
- Therapeutical application (1)
- Therapy (1)
- Thermoregulation (1)
- Transcranial Magnetic Stimulation (1)
- Transcription (1)
- Tumor (1)
- Tumour (1)
- Twilight (1)
- Typ 2 (1)
- Ubiquitinierung (1)
- Untertyp (1)
- Zeitgeber (1)
- Zellkultur (1)
- Zellteilung (1)
- Zellzyklus (1)
- active zone (1)
- adipocytes (1)
- adult neurogenesis (1)
- antigen (1)
- bipolar disorder (1)
- bipolare Störung (1)
- cancer (1)
- cardiovascular (1)
- chlamydia (1)
- cognitive deficits (1)
- cognitive remediation (1)
- ctr (1)
- cytokinesis (1)
- dendritic cells (1)
- dendritische Zelle (1)
- depression (1)
- division of labor (1)
- dosimetry (1)
- drug development (1)
- electrophysiology (1)
- endocytosis (1)
- extracellular matrix (1)
- extrazelluläre Matrix (1)
- foamy viruses (1)
- gamma-H2AX (1)
- honeybee (1)
- immune escape (1)
- immunologische Synapse (1)
- inflammation (1)
- insulin resistance (1)
- invariant NKT cells (1)
- invariante NKT Zellen (1)
- kinesin (1)
- kognitive Defizite (1)
- kognitive Remediation (1)
- learned helplessness (1)
- medical physics (1)
- melanocytic nevi (1)
- melanoma cancer (1)
- mitosis (1)
- myocarditis (1)
- nesting behaviour (1)
- nociceptors (1)
- nuclear medicine (1)
- opioid receptors (1)
- ovarian cancer (1)
- ovarian carcinoma (1)
- polymer (1)
- protease (1)
- protease activity (1)
- psychophysiology (1)
- radionuclide therapy (1)
- regional analgesia (1)
- reverse Transkription (1)
- reverse transcription (1)
- sensitivity (1)
- signalling (1)
- single particle tracking (1)
- snoRNA (1)
- steady-state visually evoked potentials (1)
- streptozotocin (1)
- structure-function relationships (1)
- super-resolution microscopy (1)
- transfer (1)
- Übung (1)
Institute
- Graduate School of Life Sciences (45) (remove)
Sonstige beteiligte Institutionen
Use of polyhexanide and nanomedicine approach for effective treatments of cutaneous leishmaniasis
(2015)
Despite huge suffering caused by cutaneous leishmaniasis (CL), there is no effective and affordable treatment strategy against CL and no licensed vaccines. The current treatments show limited efficacy and high toxicity. Improved therapies through discovery of novel drugs and/or an alternative treatment approaches are/is urgently needed. We aimed at identifying a novel antileishmanial agent and developing an innovative nanoparticle (NP) based platform for safe and effective treatments against CL. We discovered that polyhexanide (PHMB), a widely used antimicrobial polymer and wound antisepsis, shows an inherent antileishmanial activity at submicromolar concentrations. PHMB appears to kill L. major parasites via a dual mechanism involving disruption of membrane integrity and selective chromosome condensation. However, host chromosomes binding appear to be limited by exclusion from mammalian cell nuclei. Moreover, we attempted to establish effective drug delivery systems that overcome the various shortcomings in the present treatment of CL. In this scenario, we initially studied the cellular interactions of NPs and their uptake mechanisms into mammalian cells before applying them in drug delivery system. We obtained clear evidence for the involvement of multiple endocytic routes to internalize NPs. Physicochemical properties of NPs, cell type, temperature and pathogenesis of the target diseases were shown to be determinant factors. Thereafter, a mechanism based host- and pathogen-directed combination therapy comprising PHMB and CpG ODN immunomodulator was established for overall synergistic effect against CL. It simultaneously targets the pathogen and the host immunity with effective delivery system. The results show that PHMB binds to CpG ODN and form stable nanopolyplexes for efficient cell entry and therapy. The nanopolyplexes displayed enhanced cellular uptake and antileishmanial potency while drastically reducing the toxicity against mammalian cells. In conclusion, our findings clearly indicate that PHMB can be used as effective candidate drug against CL and as non-viral delivery of immunomodulatorynucleic acids. Moreover, our proof-of concept study showed nanomedicine approaches are effective strategy to challenge CL and other human diseases.
Development Of Three-Dimensional Liver Models For Drug Development And Therapeutical Applications
(2015)
Primary human liver cells such as hepatocytes when isolated and cultured in 2D monolayers, de-differentiate and lose their phenotypic characteristics. In order to maintain the typical polygonal shape of the hepatocytes and their polarization with respect to the neighbouring cells and extra cellular matrix (ECM), it is essential to culture the cells in a three-dimensional (3D) environment. There are numerous culturing techniques available to retain the 3D organization including culturing hepatocytes between two layers of collagen and/or MatrigelTM (Moghe et al. 1997) or in 3D scaffolds (Burkard et al. 2012).
In this thesis, three different 3D hepatic models were investigated.
1. To reflect the in vivo situation, the hepatocytes were cultured in 3D synthetic scaffolds called Mimetix®. These were generated using an electrospinning technique using biodegradable polymers. The scaffolds were modified to increase the pore size to achieve an optimal cell function and penetration into the scaffolds, which is needed for good cell-cell contact and to retain long-term phenotypic functions. Different fibre diameters, and scaffold thicknesses were analyzed using upcyte® hepatocytes. The performance of upcyte® hepatocytes in 3D scaffolds was determined by measuring metabolic functions such as cytochrome P450 3A4 (CYP3A4) and MTS metabolism.
2. Apart from maintaining the hepatocytes in 3D orientation, co-culturing the hepatocytes with other non-parenchymal cell types, such as liver sinusoidal endothelial cells (LSECs) and mesenchymal stem cells (MSCs), better reflects the complexity of the liver. Three different upcyte® cell types namely, hepatocytes, LSECs and MSCs, were used to generated 3D liver organoids. The liver organoids were generated and cultured in static and dynamic conditions. Dynamic conditions using Quasi-vivo® chambers were used to reflect the in vivo blood flow. After culturing the cells for 10 days, the structural orientation of cells within the organoids was analyzed. Functional integrity was investigated by measuring CYP3A4 activities. The organoids were further characterized using in situ hybridization for the expression of functional genes, albumin and enzymes regulating glutamine and glucose levels.
3. An ex vivo bioreactor employing a decellularized organic scaffold called a “Biological Vascularized Scaffold” (BioVaSc) was established. Jejunum of the small intestine from pigs was chemically decellularized by retaining the vascular system. The vascular tree of the
BioVaSc was repopulated with upcyte® microvascular endothelial cells (mvECs). The lumen of the BioVaSc was then used to culture the liver organoids generated using upcyte® hepatocytes, LSECs and MSCs. The structural organisation of the cells within the organoids was visualized using cell-specific immunohistochemical stainings. The performance of liver organoids in the BioVaSc was determined according to metabolic functions (CYP3A4 activities).
This thesis also addresses how in vitro models can be optimized and then applied to drug development and therapy.
A comprehensive evaluation was conducted to investigate the application of second-generation upcyte® hepatocytes from 4 donors for inhibition and induction assays, using a selection of reference inhibitors and inducers, under optimized culture conditions. CYP1A2, CYP2B6, CYP2C9 and CYP3A4 were reproducibly inhibited in a concentration-dependent manner and the calculated IC50 values for each compound correctly classified them as potent inhibitors. Upcyte® hepatocytes were responsive to prototypical CYP1A2, CYP2B6, CYP2C9 and CYP3A4 inducers, confirming that they have functional AhR, CAR and PXR mediated CYP regulation. A panel of 11 inducers classified as potent, moderate or non-inducers of CYP3A4 and CYP2B6 were tested. Three different predictive models for CYP3A4 induction, namely the Relative Induction Score (RIS), AUCu/F2 and Cmax,u/Ind50 were analyzed. In addition, PXR (rifampicin) and CAR-selective (carbamazepine and phenytoin) inducers of CYP3A4 and CYP2B6 induction, respectively, were also demonstrated.
Haemophilia A occurs due to lack of functional Factor VIII (FVIII) protein in the blood. Different types of cells from hepatic and extrahepatic origin produce FVIII. Supernatants harvested from primary LSECs were evaluated for the presence of secreted functional FVIII. In order to increase the FVIII production, different upcyte® endothelial cells such as blood outgrowth endothelial cells (BOECs), LSECs and mvECs were transduced with lentiviral particles carrying a FVIII transgene. Also, to reflect a more native situation, primary mvECs were selected and modified by transducing them with FVIII lentivirus and investigated as a potential method for generating this coagulation factor.
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.
Wasps of the genus Polistes comprise over 200 species and are nearly cosmopolitan. They show a lack of physiological caste differentiation and are therefore considered as primitively eusocial. Furthermore, paper wasps are placed between the solitary living Eumenidae and the highly social organized Vespinae. Hence, they are often called a “key genus” for understanding the evolution of sociality. Particularly, Polistes dominula, with its small easy manageable nests and its frequent occurrence and wide distribution range is often the subject of studies.
In Europe, the invasion of this species into northern regions is on the rise. Since little was known about the nesting behaviour of P. dominula in Central Europe, the basic principles about nesting were investigated in Würzburg, Germany (latitude 49°) by conducting a comprehensive field-study spanning three consecutive years. Furthermore, the thermoregulation of individual wasps in their natural habitat had not yet been investigated in detail. Therefore, their ability to respond to external hazards with elevated thorax temperatures was tested. In addition, different types of nest thermoregulation were investigated using modern methods such as infrared thermography and temperature data logger.
In the present work, the investigation of basic nesting principles revealed that foundress groups (1-4 foundresses) and nests are smaller and that the nesting season is shorter in the Würzburg area than in other regions. The mean size of newly founded nests was 83 cells and the average nesting season was around 4.6 months. The queens neither preferred single (54%) nor multiple founding (46%) in this study. The major benefit of multiple founding is an increased rate of survival. During the three years of observation, only 47% of single-foundress colonies survived, whereas 100% of colonies that were built by more than two queens, survived. However, an influence of the number of foundresses on the productivity of colonies in terms of number of cells and pupae per nest has not shown up. However, the length of the nesting season as well as the nest sizes varied strongly depending on the climatic conditions of the preceding winter during the three consecutive years.
In order to investigate the thermoregulatory mechanisms of individual adult P. dominula wasps, I presented artificial threats by applying smoke or carbon dioxide simulating fire and predator attacks, respectively, and monitored the thorax temperature of wasps on the nest using infrared thermography. The results clearly revealed that P. dominula workers recognized smoke and CO2 and reacted almost instantaneously and simultaneously with an increase of their thorax temperature. The maximal thorax temperature was reached about 65 s after the application of both stressors, but subsequently the wasps showed a different behaviour pattern. They responded to a longer application of smoke with moving to the exit and fled, whereas in case of CO2 the wasps started flying and circling the nest without trying to escape. No rise of the thorax temperature was detectable after an air blast was applied or in wasps resting on the nest. Additionally, the thorax temperatures of queens were investigated during dominance battles. I found that the thorax temperature of the dominant queens rose up to 5°C compared to that of subordinate queens that attacked the former.
The study of active mechanisms for nest thermoregulation revealed no brood incubation or clustering behaviour of P. dominula. Furthermore, I found out that wing fanning for cooling the nest was almost undetectable (4 documented cases). However, I could convincingly record that water evaporation is most effective for nest cooling. By the direct comparison of active (with brood and adults) and non-active (without brood and adults) nests, the start of cooling by water evaporation was detected above maximum outside temperatures of 25°C or at nest temperatures above 35°C. The powerful role of water in nest cooling was manifested by an average decrease of temperature of a single cell of about 8°C and a mean duration of 7 min until the cell reached again its initial temperature. The investigation of passive thermoregulatory mechanisms revealed that the nest site choice as well as nest orientation appears to be essential for P. dominula wasps. Furthermore, I was able to show that the architecture of the nests plays an important role. Based on the presented results, it can be assumed that the vertical orientation of cells helps maintaining the warmth of nests during the night, whereas the pedicel assists in cooling the nest during the day.
Feedback efficiency and training effects during alpha band modulation over the sensorimotor cortex
(2015)
Neural oscillations can be measured by electroencephalography (EEG) and these oscillations can be characterized by their frequency, amplitude and phase. The mechanistic properties of neural oscillations and their synchronization are able to explain various aspects of many cognitive functions such as motor control, memory, attention, information transfer across brain regions, segmentation of the sensory input and perception (Arnal and Giraud, 2012). The alpha band frequency is the dominant oscillation in the human brain. This oscillatory activity is found in the scalp EEG at frequencies around 8-13 Hz in all healthy adults (Makeig et al., 2002) and considerable interest has been generated in exploring EEG alpha oscillations with regard to their role in cognitive (Klimesch et al., 1993; Hanselmayr et al., 2005), sensorimotor (Birbaumer, 2006; Sauseng et al., 2009) and physiological (Lehmann, 1971; Niedermeyer, 1997; Kiyatkin, 2010) aspects of human life. The ability to voluntarily regulate the alpha amplitude can be learned with neurofeedback training and offers the possibility to control a brain-computer interface (BCI), a muscle independent interaction channel. BCI research is predominantly focused on the signal processing, the classification and the algorithms necessary to translate brain signals into control commands than on the person interacting with the technical system. The end-user must be properly trained to be able to successfully use the BCI and factors such as task instructions, training, and especially feedback can therefore play an important role in learning to control a BCI (Neumann and Kübler, 2003; Pfurtscheller et al., 2006, 2007; Allison and Neuper, 2010; Friedrich et al., 2012; Kaufmann et al., 2013; Lotte et al., 2013).
The main purpose of this thesis was to investigate how end-users can efficiently be trained to perform alpha band modulation recorded over their sensorimotor cortex. The herein presented work comprises three studies with healthy participants and participants with schizophrenia focusing on the effects of feedback and training time on cortical activation patterns and performance. In the first study, the application of a realistic visual feedback to support end-users in developing a concrete feeling of kinesthetic motor imagery was tested in 2D and 3D visualization modality during a single training session. Participants were able to elicit the typical event-related desynchronisation responses over sensorimotor cortex in both conditions but the most significant decrease in the alpha band power was obtained following the three-dimensional realistic visualization. The second study strengthen the hypothesis that an enriched visual feedback with information about the quality of the input signal supports an easier approach for motor imagery based BCI control and can help to enhance performance. Significantly better performance levels were measurable during five online training sessions in the groups with enriched feedback as compared to a conventional simple visual feedback group, without significant differences in performance between the unimodal (visual) and multimodal (auditory–visual) feedback modality. Furthermore, the last study, in which people with schizophrenia participated in multiple sessions with simple feedback, demonstrated that these patients can learn to voluntarily regulate their alpha band. Compared to the healthy group they required longer training times and could not achieve performance levels as high as the control group. Nonetheless, alpha neurofeedback training lead to a constant increase of the alpha resting power across all 20 training session.
To date only little is known about the effects of feedback and training time on BCI performance and cortical activation patterns. The presented work contributes to the evidence that healthy individuals can benefit from enriched feedback: A realistic presentation can support participants in getting a concrete feeling of motor imagery and enriched feedback, which instructs participants about the quality of their input signal can give support while learning to control the BCI. This thesis demonstrates that people with schizophrenia can learn to gain control of their alpha oscillations recorded over the sensorimotor cortex when participating in sufficient training sessions. In conclusion, this thesis improved current motor imagery BCI feedback protocols and enhanced our understanding of the interplay between feedback and BCI performance.
Background
GDF-15 is a divergent member of the TGF-superfamily, which was first described as macrophage inhibitory cytokine-1 (MIC-1), revealing an immune modulatory function. GDF-15 is a soluble protein which is, under physiological conditions, highly expressed in the placenta and found in elevated levels in blood sera of pregnant women. Apart from the placenta, GDF-15 is expressed in healthy tissue, albeit to a lower extent and overexpressed in many solid tumors. A variety of different functions are attributed to GDF-15 in healthy as well as diseased humans. On the one hand, GDF-15 is required for successful pregnancy and low GDF-15 serum levels during pregnancy correlate with fetal abortion. On the other hand, overexpression of GDF-15, which can be observed in several malignancies is correlated with a poor prognosis. Furthermore, tumor derived GDF-15 leads to cancer associated anorexia-cachexia syndrome in mice. The aim of my PhD thesis was to further investigate the role of GDF-15 as an immune modulatory factor in cancer, in particular, by inhibiting the target molecule in vitro and in vivo. Therefore, the main focus was placed on the generation and characterization of monoclonal GDF-15 specific blocking antibodies, which were tested in vitro and in vivo, which represents a substantial part of my work.
Results
Here, GDF-15 was shown to be highly expressed in human gynecological cancer and brain tumors. We could then demonstrate that GDF-15 modulates effector immune cells in vitro. GDF-15 mediated a slight downregulation of the activating NKG2D receptor on NK and CD8+ T cells, which is crucial for proper anti-tumoral immune responses. Furthermore, we could demonstrate that GDF-15 reduces the adhesion of CD4+ and CD8+ T cells on endothelial cells in vitro. A negatively affected trans-endothelial migration of leukocytes into inflamed tissue could explain the low T cell infiltration in GDF-15 expressing tumors, which were observed in vivo, where mice bearing (shRNA mediated) GDF-15 deficient glioma cells revealed enhanced immune cell infiltrates in the tumor microenvironment, compared with the GDF-15 expressing control group. Those animals further exhibited a decreased tumor growth and prolonged survival. GDF-15 is a soluble protein, secreted by more than 50 % of solid tumors and associated with grade of malignancy. Therefore a neutralizing monoclonal antibody to GDF-15 was assumed to be an auspicious therapeutically anti-cancer tool. Such an antibody was thus generated in GDF-15 knock out mice against human GFD-15. Amongst many clones, the GDF-15 antibody clone B1-23 was found to be applicable in Western Blot as well as in ELISA techniques, detecting a three-dimensional epitope of the mature GDF-15 dimer with high affinity and specificity. To enable the humanization for a later administration in humans, the variable regions of antibody B1-23 were identified by a special PCR method using degenerate primers and cloned into a sequencing vector. The sequence obtained thereby enabled the generation of chimeric and humanized B1-23 variants. After further comprehensive characterization, the original mouse antibody B1-23 as well as the chimeric antibody (ChimB1-23) and the humanized B1-23 antibody (H1L5) were applied in a melanoma xenograft study in vivo. None of the antibodies could significantly inhibit tumor growth. .However of utmost importance, body weight loss mediated by tumor derived GDF-15 could be significantly prevented upon administration of all three GDF-15 specific antibodies, which confirmed the antagonizing functionality of the immunoglobulin.
Conclusion
GDF-15 is a promising cancer target, involved in tumor progression and cancer related cachexia. A monoclonal GDF-15 antibody was generated, which served on one hand as a tool for molecular biological applications (Western Blot, ELISA, etc.) and on the other hand was applied as an antagonizing antibody in vitro and in vivo. Even though tumor growth inhibition by GDF-15 depletion in T cell deficient athymic mice failed using B1-23, the same antibody and derivates thereof (chimeric and humanized) impressively prevented tumor associated cachexia in UACC-257 melanoma bearing nude mice. The missing anti-tumor effect in our own melanoma model in nude mice can only partially be explained by the missing secondary immunity, in particular cytotoxic T cells, in the athymic animals, since in a similar melanoma model, performed by an external company, a tumor reduction in immunocompromised animals was observed, when B1-23 was administered. These findings support the idea that T cells are substantial for an effective tumor immunity and are in line with the results of the syngeneic, T cell comprising, mouse glioma model, where silencing of tumor expressed GDF-15 led to an enhanced intratumoral T cell infiltration and a prolonged survival.
Taken together our data allow for the conclusion that tumor associated cachexia can be combatted with the GDF-15 antibody B1-23. Further, B1-23 might elicit direct anti-tumor effects in immune competent models, which contain T cells, rather than in an athymic, T cell deficient nude mouse model.
Bariatric surgery represents the first-line treatment for morbid obesity, resulting in weight loss and improved diabetes control. The positive effect of bariatric surgery on type-2 diabetes is unclear. Increased secretion of insulin regulating enterohormone glucagon-like-peptide 1 (GLP-1) has been observed in rats with experimental type 2-like diabetes following duodenal-jejunal bypass (DJB) and ileal transposition (IT). Sodium dependent glucose co-transporter (SGLT1) is involved in the secretion of GLP-1 that in turn regulates insulin secretion. In the present study, an attempt was made to elucidate the impact of DJB and IT on SGLT1 mediated glucose transport. Transport measurements using phlorizin inhibited uptake of SGLT1-specific glucose analogue [14C] α-Methyl-D-glucopyranoside (AMG) were performed to determine the changes in SGLT1 transport upon these surgical procedures. The data indicated that DJB decreased SGLT1-mediated glucose absorption in the small intestine which contributes to the body-weight independent improvement of type 2 diabetes. However, IT did not change the SGLT1-mediated glucose transport. Immunohistochemical analysis revealed that in IT, the transposed ileum showed increased diameter, increased villi length and increased number of GLP-1 secreting L-cells. The weight-independent improvement in glycemic control after IT is not related to SGLT1-mediated glucose absorption but may be linked to increased GLP-1 secretion.
Along with this, the study also focused on the regulation of SGLT1 by several RS1 derived tripeptides in mouse and human intestinal tissues (ex vivo). Phlorizin inhibited uptake of AMG was measured without and with tripeptides. QEP and thiophosphorylated QSP down-regulated SGLT1 activity in small intestine in a concentration-dependent manner. Among the tested tripeptides, QEP showed higher activity and further analysis in various species demonstrated its universal role in SGLT1 regulation. The data thus indicates that RS1 derived tripeptides QEP and thiophosphorylated QSP may be employed for the treatment of type 2 diabetes.
Opioids have been, since centuries, the gold standard for pain treatment and relief. They exert their effects after binding to opioid receptors (OP) that are expressed and functional in the central (CNS) and peripheral nervous system (PNS). As their systemic application has many side effects, including sedation and respiratory depression, a peripheral application of opioids and selective targeting of µ-OP (MOP) in nociceptive axons would be extremely beneficial. MOP presence and function has been conclusively demonstrated at nerve terminals; however it is still controversial whether functional MOPs are available on the membrane of peripheral nociceptive axons to mediate opioid-induced antinociception. While under pathologic conditions (i.e. nerve injury) exogenous as well as endogenous MOP agonists applied at the damaged nerve can elicit potent antinociception or anti-allodynia, under physiological conditions no antinociception was seen in rats. This could be caused by either a lack of functional opioid receptors in the axonal membranes or by the inability of injected opioids to cross the intact perineurial barrier and to reach nociceptors. Previous behavioral test results showed an antinociceptive effect (up to 5h) following perisciatic application of the hydrophilic DAMGO (MOP agonist) if coinjected with hypertonic saline solution (HTS; 10% NaCl), a treatment suited to open the perineural barrier. The effect was inhibited by naloxone, a MOP antagonist, documenting its specific action via MOP. Fentanyl, a lipophilic opioid, elicited an effect, which was enhanced by HTS treatment, indicating that HTS may act not only on the barrier but also directly on axonal MOP presence and/or functionality. To provide a basis for testing this hypothesis, the present work was designed to study the axonal localization of MOP in experimental animals under different conditions using molecular and morphological methods.
Initially four different commercial antibodies were tested for MOP detection. Immunoreactions with these antibodies specifically detected MOP in the hippocampus and in amygdala, while in the peripheral nervous system the reactions showed varying labeling patterns pointing towards less specificity with low signal-to-noise ratio. Double labelling with calcitonin gene related peptide (CGRP), a neuropeptide expressed in sensory fibers, with the non-compacted myelin marker S100 or with the neuronal marker PGP9.5 documented significant immunoreaction signals outside sensory nerve fibers. Therefore, none of these antibodies appeared suitable. Taking advantage of a new commercial monoclonal rabbit antibody (RabMAb) and of genetically modified mice in which the fluorescent protein mcherry was inserted in the C-tail of MOP (MOP-mcherry knock-in mice), MOP fusion protein expression in rat and mouse CGRP+ sciatic nerve fibers and fiber bundles was confirmed by immunofluorescence labeling. Immunoelectron microscopic analysis indicated MOP/MOP-mcherry-localization in the cytoplasm and the membranes of unmyelinated axons organized in Remak bundles. Both antibodies detected bands of appropriate size in Western Blot in the CNS and additional larger bands in the PNS. Quantitative analyses 60 min after HTS-treatment revealed no change in MOP mRNA in the sciatic nerve and DRG as well as no change in MOP immunoreactivity in the sciatic nerve. Thus, the opioid-induced long lasting antinociception enhanced by perisciatic injection of HTS were not due to a sustained increased MOP expression or content in sensory, putative nociceptive axons.
In summary, the current study succeeded to unequivocally document the presence of MOP protein in intact sensory axons of rat and mouse sciatic nerve. Thus, axonal MOPs may indeed mediate antinociceptive opioid effects observed in behavioral studies in naive animals possibly via activation of potassium or calcium channels. As HTS treatment does not lead to a sustained increase in axonal MOP protein or MOP mRNA expression, other mechanisms might enhance MOP function, including inhibition of MOP recycling or changes in functional coupling. Future studies should further explore the axonal mechanisms of antinociception by opioids and enhancing treatments.
Eukaryotic cells are considered as evolutionary complex organisms because they possess organelles that enable them to regulate the spatio-temporal organization of cellular processes. Spatio-temporal organization of signal transduction cascades occurs in eukaryotic cells via organization of membrane-associated microdomains or lipid rafts. Lipid rafts are nanoscale-sized domains in the plasma membrane that are constituted by a specific set of lipids and proteins and harbor a number of proteins related to signal transduction and trafficking. The integrity of lipid rafts is important for the assembly and functional coordination of a plethora of signaling networks and associated processes. This integrity is partially mediated by a chaperone protein called flotillin. Disruption of lipid raft integrity, for example via depletion or overproduction of flotillin, alters raft-associated signal transduction cascades and causes severe diseases like Alzheimer’s, Parkinson’s disease or cardiovascular disease.
It was traditionally assumed that a sophisticated compartmentalization of cellular processes like the one exhibited in lipid rafts was exclusive to eukaryotic cells and therefore, lipid rafts have been considered as a hallmark in the evolution of cellular complexity, suggesting that prokaryotic cells were too simple organisms to organize such sophisticated membrane platforms. However, it was recently discovered that bacteria are also able to organize Functional Membrane Microdomains (FMMs) in their cellular membrane that are able to organize and catalyze the functionality of many diverse cellular processes. These FMMs of bacterial membranes contain flotillin-like proteins which play important roles in the organization of FMM-associated cellular processes.
In this dissertation I describe the structural and biological significance of the existence of two distinct flotillin proteins, FloA and FloT, in the FMMs of the bacterial model Bacillus subtilis. Localization studies, proteomic data and transcriptomic analyses show that FloA and FloT are individual scaffold proteins that activate different regulatory programs during bacterial growth. Using the tractable bacterial model system, I show that the functionality of important regulatory proteins, like the protease FtsH or the signaling kinases KinC, PhoR and ResE, is linked to the activity of FMMs and that this is a direct consequence of the scaffold activity of the bacterial flotillins. FloA and FloT distribute heterogeneously along the FMMs of B. subtilis thereby generating a heterogeneous population of FMMs that compartmentalize different signal transduction cascades. Interestingly, diversification of FMMs does not occur randomly, but rather in a controlled spatio-temporal program to ensure the activation of given signaling networks at the right place and time during cell growth.
Der Natrium-D-Glukose Kotransporter 1 (SGLT1) spielt eine wichtige Rolle bei der Aufnahme von Glukose aus dem Darmlumen in die Enterozyten des Darms. Anhand von Untersuchungen an Xenopus laevis-Oozyten konnte in unserem Labor das Protein RS1 als posttranslationales Regulatorprotein für SGLT1 und diverse andere Transporter ermittelt werden. Es wurde eine regulatorische Domäne aus RS1 mit vielen potentiellen Phosphorylierungsstellen isoliert (RS1-Reg) und gezeigt dass RS1-Reg die Abschnürung von Transporter enthaltenen Vesikeln vom Transgolgi-Netzwerk hemmt. Neben SGLT1 reguliert RS1 auch die konzentrierenden Nukleosidtransporter (CNTs) am TGN. Die Regulation der Transporter ist vom Phosphorylierungszustand von RS1-Reg abhängig. So wurde durch Versuche an Oozyten von Xenopus laevis und Injektion von RS1-Reg Mutanten gezeigt, dass die Phosphorylierung von RS1-Reg an einigen Stellen zu einer Inhibition von SGLT1 führte, während der Nukleosidtransporter CNT1 durch die dephosphorylierte Mutante herunterreguliert wurden. Neben der phosphorylierungsabhängigen Regulation konnte für SGLT1 auch gezeigt werden, dass die Herunterregulation nur unter Niedrigzucker-Bedingungen erfolgte, nicht jedoch bei hohen Glukosekonzentrationen. Für die CNTs war eine derartige Zuckerabhängigkeit nicht zu beobachten.
Im Rahmen der vorliegenden Studie wurde untersucht, ob die Ergebnisse aus den Oozytenmessungen auch in vivo in einem Säugetier gezeigt werden können. Hierzu wurden Mutanten der regulatorischen Domäne (RS1-Reg) des Maus-Proteins, welche den phosphorylierten Zustand simulierten (RS1-Reg (S19E)), oder die Phosphorylierung verhinderten (RS1-Reg (S19A)) eingesetzt. Diese wurden an ein Nanohydrogel gekoppelt, um eine Aufnahme in die Enterozyten im Darm zu gewährleisten. Es wurde in der RS1KO-Mausohne funktionelles RS1 gezeigt, dass auch im in vivo-System eine Herunterregulation von SGLT1 durch mRS1-Reg (S19E), nicht jedoch durch mRS1-Reg (S19A) erfolgte, während die CNTs nur durch mRS1-Reg (S19A) inhibiert wurden. Des Weiteren führte mRS1-Reg (S19A) in der Wildtypmaus bei niedrigen Zuckerkonzentrationen zu einer Stimulation von SGLT1, was für eine Kompetition mit dem endogenen RS1-Proteins spricht. Es konnte indirekt der Beweis erbracht werden, dass über Nanohydrogele längere Proteine in die Zelle gebracht werden können und dort funktionell freigesetzt werden.
Das invasive Potential maligner Gliome beeinflusst maßgeblich die schlechte Prognose dieser Tumorentität. Migration und Invasion von Tumorzellen werden entscheidend durch die Cofilin-vermittelte Umstrukturierung des Aktin-Zytoskeletts geprägt, die durch die Aktivität antagonistischer Cofilin-Kinasen und -Phosphatasen reguliert wird.
Im Rahmen der vorliegenden Arbeit konnte ein progressiver Expressionsverlust der Cofilin-Phosphatase Chronophin mit ansteigendem Malignitätsgrad astrozytärer Gliome aufgezeigt werden, der mit einer Zunahme der Phosphorylierung von Cofilin einhergeht. In den entsprechenden Gewebeproben gelang gleichzeitig der Nachweis einer gesteigerten Expression der Cofilin-Kinase LIMK-2.
Genetische und epigenetische Analysen des Chronophin-Locus konnten eine Hypermethylierung im Bereich der Promotorregion der Phosphatase identifizieren, die möglicherweise dem Verlust von Chronophin in Glioblastom-Gewebeproben zugrunde liegt.
In Glioblastom-Zelllinien, die unterschiedliche Expressionsmuster von Chronophin aufwiesen, konnten hingegen keine molekularen Alterationen festgestellt werden.
Untersuchungen des Einflusses von ROCK- und LIMK-Inhibitoren auf Glioblastomzellen konnten ausgeprägte Veränderungen der Zellmorphologie dokumentieren, wobei erstmals die Induktion eines stellate cell-Phänotyps unter Einfluss des LIMK-Inhibitors BMS-5 beschrieben wird. Während ROCK- und LIMK-Inhibitoren keinen Einfluss auf die 2D-Motilität der Tumorzellen hatten, wiesen die Glioblastomzellen in Abhängigkeit ihrer basalen Cofilin-Aktivität eine verstärkte bzw. verminderte 3D-Invasivität auf.
Die Erkenntnisse dieser Arbeit unterstreichen die Bedeutung des Cofilin-Signalweges für die Migration und Invasion von Gliomzellen, zeigen neue Angriffspunkte in der Therapie maligner Gliome auf und warnen zugleich vor einem unkritischen Einsatz neuer Wirkstoffe.
Abstract
Background
HLA-G is a non-classical MHC class I molecule which exerts strong immunosuppressive effects on various immune cells. Several membrane-bound and soluble isoforms are known. Physiologically, HLA-G is predominantly expressed in the placenta, where it contributes to protecting the semi-allogeneic embryo from rejection by the maternal immune system. However, HLA-G is also often upregulated during tumourigenesis, such as in ovarian cancer. The aim of this thesis is to investigate how soluble HLA-G may contribute to local immunosuppression in ovarian carcinomas, and to characterize HLA-G expression in different ovarian carcinoma subtypes and metastases.
Results
As reported by others, physiological HLA-G expression is restricted to few tissues, such as placenta and testes. Here, HLA-G was also detected in the medulla of the adrenal gland. In contrast, HLA-G expression was frequently detected in tumours of all assessed subtypes of ovarian carcinomas (serous, mucinous, endometrioid and clear cell). Highest expression levels were detected in high-grade serous carcinomas. In primary tumours, expression of HLA-G correlated with expression of classical MHC class I molecules HLA-A, -B and -C. Surprisingly, high levels of HLA-G were also detected on dendritic cells in local lymph nodes. As no expression of HLA-G was inducible in monocytes or dendritic cells from healthy donors in response to IL-10 or IL-4, we speculated that tumour-derived soluble HLA-G might be transferred to dendritic cells via the lymphatic system. Accordingly, high levels of tumour-derived soluble HLA-G were detected in ovarian cancer ascites samples. In vitro, dendritic cells expanded in the presence of IL-4, IL-10 and GM-CSF (DC-10) were particularly prone to binding high amounts of soluble HLA-G via ILT receptors. Furthermore, HLA-G loaded DC-10 cells inhibited the proliferation of CD8 effector cells and induced regulatory T cells, even when the DC-10 cells had been fixed with paraformaldehyde.
Conclusion
The immunosuppressive molecule HLA-G is overexpressed in high-grade serous ovarian carcinomas, which account for the majority of ovarian cancers. In particular tumours with a high mutational burden and intact expression of classical, immunogenic MHC class Ia molecules may use HLA-G to escape from immunosurveillance. Additionally, tumour-derived soluble HLA-G may inhibit adaptive immune responses by binding to dendritic cells in local lymph nodes. Dendritic cells usually play a decisive role in the initiation of adaptive anti-tumour immune responses by presenting tumour antigens to cytotoxic T cells. In contrast, dendritic cells loaded with soluble HLA-G inhibit the proliferation of effector T cells and promote the induction of regulatory T cells. Thus, soluble HLA-G that is transferred to dendritic cells via lymphatic vessels may enable ovarian carcinomas to remotely suppress anti-tumour immune responses in local lymph nodes. This novel immune-escape mechanism may also exist in other solid tumours that express HLA-G.
Adenosine receptors that belong to the rhodopsin-like G protein-coupled receptors (GPCRs) are involved in a lot of regulatory processes and are widely distributed throughout the body which makes them an attractive target for drugs. However, pharmacological knowledge of these receptors is still limited. A big advance regarding the structural knowledge of adenosine receptors was the development of the first crystal structure of the adenosine A2A receptor in 2008. The crystal structure revealed the amino acids that form the ligand binding pocket of the receptor and depicted the endpoint of receptor movement in the ligand binding process. Within the scope of this work two members of the adenosine receptor family were investigated, namely the adenosine A1 and the A2A receptor (A1R, A2AR). A1R was generated on base of the previously developed A2AR. Receptors were tagged with fluorophores, with the cyan fluorescent protein (CFP) at the C-terminal end of receptor and the Fluorescein Arsenical Hairpin binder (FlAsH) binding sequence within the third intracellular loop of receptors. Resulting fluorescent receptor sensors
A1 Fl3 CFP and A2A Fl3 CFP were investigated with help of Fluorescence Resonance Energy Transfer (FRET) measurements within living cells. FRET experiments enable the examination of alteration in the distance of two fluorophores and thus the observation of receptor dynamical movements.
For comparison of A1R and A2AR regarding receptor dynamical movement upon ligand binding, fluorescent receptor sensors A1 Fl3 CFP and A2A Fl3 CFP were superfused with various ligands and the outcomes of FRET experiments were compared regarding signal height of FRET ratio evoked by the distinct ligand that is correlated to the conformational change of receptor upon ligand binding. Beside the different direction of FRET ratio upon ligand binding at A1R and A2AR sensor, there were differences observable when signal height and association and dissociation kinetics of the various ligands investigated were compared to each other. Differences between the adenosine receptor subtypes were especially remarkable for the A1R subtype selective agonist CPA and the A2AR subtype selective agonist CGS 21680. Another part of the project was to investigate the influence of single amino acids in the ligand binding process within the fluorescent A1R sensor. Amino acid positions were derived from the crystal structure of the A2AR forming the ligand binding pocket and these amino acids were mutated in the A1R structure. Investigation of the A1R sensor and its mutants regarding confocal analysis showed involvement
of some amino acids in receptor localization. When these amino acids were mutated receptors were not expressed in the plasma membrane of cells. Some amino acids investigated were found to be involved in the ligand binding process in general whereas other amino acids were found to have an influence on the binding of distinct structural groups of the ligands investigated. In a further step, A1R and A2AR were N-terminally tagged with SNAP or CLIP which allowed to label receptor sensors with multiple fluorophores. With this technique receptor distribution in cells could be investigated with help of confocal analysis. Furthermore, ligand binding with fluorescent adenosine receptor ligands and their competition with help of a non-fluorescent antagonist was examined at the SNAP tagged A1R and A2AR. Finally the previously developed receptor sensors were combined to the triple labeled receptor sensors SNAP A1 Fl3 CFP and SNAP A2A Fl3 CFP which were functional regarding FRET experiments and plasma membrane expression was confirmed via confocal analysis. In the future, with the help of this technique, interaction between fluorescent ligand and SNAP tagged receptor can be monitored simultaneously with the receptor movement that is indicated by the distance alteration between FlAsH and CFP. This can
lead to a better understanding of receptor function and its dynamical movement upon ligand binding which may contribute to the development of new and more specific drugs for the A1R and A2AR in the future.
Peripheral blood mononuclear cells (PBMCs) are the only source of human lymphoid cells routinely available for immunologic research and for immunomonitoring of T-cell responses to microbial and tumor-associated antigens. However the large majority of human T-cells resides in tissues, especially in lymphatic organs, while only 1 % of the body’s T-cells circulate in the blood stream. Previous work in mice and humans had indicated that CD4 T-cells transiently lose antigen sensitivity when cellular contacts are lost, e.g. by leaving lymphoid organs such as lymph nodes (LNs) and entering the circulation. In this study, these findings were extended to CD8 T-cells. Thus, CD8 T-cell responses of the human tonsil show a significant drop in sensitivity to viral antigens if tissue-exit was simulated by keeping cells in dispersed culture at body temperature for two hours.
Conversely, tissue-like functionality in blood-derived CD8 T-cells was restored by applying the simple and robust RESTORE protocol. Indeed, application of the RESTORE protocol, i.e. pre-culturing PBMCs for two days at a high cell density before initiation of antigenic stimulation, demonstrated that CD8 T-cell responses to a broad range of viral and to tumor-associated antigens are greatly underestimated, and sometimes even remain undetected if conventional, unprocessed PBMC cultures are used. The latter finding is particularly striking with regard to the appearance of Wilms tumor 1 (WT1)-specific CD8 T-cell responses in leukemia patients after allogeneic bone marrow transplantation. My studies on the mechanism of the RESTORE protocol show that HD preculture of PBMCs does not involve antigen-or cytokine-driven clonal expansion of T-cells. Moreover, the gain in antigen sensitivity cannot be explained by a decreased activity of regulatory T-cells during the preculture step. The increased antigen sensitivity of CD8 T-cells from HD precultures of PBMCs is associated with tonic T-cell receptor signaling as indicated by enhanced tyrosine phosphorylation of the CD3 ζ chains and the tyrosine kinase Lck, thereby preparing T-cells for full responses. The upregulation of genes involved in aerobic glycolysis in “restored” CD8 memory T-cells relative to fresh cells might be an essential requirement for increased T-cell functionality including the regulation of IFN-γ production. Taken together, the RESTORE protocol, which was initially described for the CD4 T-cell response to the antibody TGN1412 permits a more meaningful monitoring of CD8 T-cell responses to viral infections and tumors. Furthermore, when generating T-cell lines for adoptive T-cell therapy, the RESTORE protocol allows the generation of CD8 T-cell lines with an improved representation of clones responding to low antigen concentrations.
Typ 1 NKT Zellen oder iNKT Zellen (invariante Natürliche Killer T Zellen) stellen eine Subpopulation der abT Zellen dar, die sich durch mehrere charakteristische Eigenschaften aus- zeichnet. Ihr Hauptmerkmal ist die Expression eines semi-invarianten T Zellrezeptors (TCR), der die Bindung von CD1d:Glycolipid Komplexen ermöglicht, wohingegen ‚klassische‘ T Zellen an Komplexe aus MHC (Haupthistokompatibilitätskomplex) Molekülen und Peptiden binden. Die während der Reifung im Thymus durch Transkriptionsfaktoren festgelegte Voraktivierung der iNKT Zellen ermöglicht das unmittelbare Freisetzen von Cytokinen bei Antigenkontakt, wodurch iNKT Zellen die adaptive Immunantwort stark beeinflussen können: Sie tragen sowohl zur Regulation von Autoimmunerkrankungen als auch der Bekämpfung von Krebs und Infektionen bei.
Der iNKT TCR setzt sich aus einer invarianten a-Kette (AV14/AJ18 in der Maus bzw. AV24/AJ18 im Menschen) und einer charakteristischen Auswahl an b-Ketten (vorwiegend BV8S2, BV7 und BV2 in der Maus und BV11 im Menschen) zusammen. Das Cerebrosid a-Galactosylceramid (aGC, KRN7000) stellt eines der potentesten Antigene für iNKT Zellen dar. Die Präsentation dieser Antigenklasse erfolgt durch CD1d Moleküle, die, abgesehen von tiefen hydrophoben Bindungstaschen, strukturell MHC I Molekülen ähneln, jedoch nicht polymorph sind und außerhalb des MHC Locus codiert sind. Die, zwischen Maus und Mensch hochkon- servierte, Interaktion von iNKT TCR und CD1d:aGC Komplex zeichnet sich bei potenten Antigenen durch die eingeschränkte Nutzung der Antigenspezifität bestimmenden Regionen aus: CDR1a, CDR3a und CDR2b. Die den CDR3b definierende V-D-J Umlagerung der b-Kette stellt im iNKT TCR den Bereich der höchsten Variabilität dar, beeinflusst jedoch nur die Bindung schwächerer Antigene. Natürlich auftretende Variabilität innerhalb der a-Kette kann durch Abweichungen von der kanonischen V-J Umlagerung am Beginn des CDR3a entstehen und beeinflusst ebenfalls die Bindung des iNKT TCR.
Die iNKT Zellpopulation in F344 Ratten ähnelt in Frequenz und Korezepotorexpression derjenigen des Menschen. Ratten besitzen ein CD1D Gen, welches hoch homolog zu denen der Maus ist und zwei dem BV8S2 Gensegment der Maus homologe BV Segmente (BV8S2 und BV8S4), die in F344 Ratten beide funktionell sind. Eine Besonderheit der Ratte ist jedoch das Auftreten einer AV14 Multigenfamilie von bis zu zehn Gensegmenten. Diese unterscheiden sich neben dem HV4 vor allem in ihren CDR2 Sequenzen und werden anhand dieser Unterschiede in zwei Gruppen (Typ 1 und 2) eingeteilt. Zusätzlich wurde in der iNKT Zellpopulation eine hohe Frequenz an natürlich auftretenden A93G Substitutionen in der TCR↵ Kette beschrieben und es wurde gezeigt, dass, im Gegensatz zur Kreuzreaktivität zwischen iNKT TCR und CD1d von Maus und Mensch, iNKT Zellen der Ratte nicht an Maus CD1d binden. Die Besonderheiten des Ratten iNKT TCR und deren Auswirkungen auf die TCR Expression und Ligandenbindung der Ratten iNKT Zellpopulation wurden in der vorliegenden Arbeit untersucht.
Durch in dieser Arbeit durchgeführte in vitro Mutagenesestudien konnten Position 68 in der vierten Hypervariablen Schleife (HV4↵) und Position 93 zu Be- ginn des CDR3↵ als entscheidende Modulatoren der CD1d Bindung im iNKT TCR von Ratte und Maus identifiziert werden, wobei auch speziesspezifische Unterschiede aufgedeckt werden konnten. Die Spezieskreuzreaktivität des Ratten iNKT TCR selbst hing stark von einer A93G Substitution im TCRa ab. Bei Untersuchungen der b-Kette zeigte sich, dass sowohl BV Segmente als auch CDR3b Region die Ligandenbindung in differenziellem Zusammenspiel beeinflussen, was bei Paarung mit unterschiedlichen AV14 Segmenten verschieden ausgeprägt sein konnte. Weiterhin wurden humane CD1d Dimere generiert und zum ersten Mal die Bindung von Ratten CD1d an humane iNKT TCR gezeigt.
Weiterhin wurde in dieser Arbeit das TCR Repertoire von iNKT Zellen der F344 Ratte und deren CD1d Bindungseigenschaften charakterisiert. Hierzu wurde die bereits etablierte Methode der in vitro Expansion von iNKT Zellen aus der Rattenmilz weiterentwickelt, was die Langzeitkultur und -expansion der sortierten iNKT Zellpopulation ermöglichte. Bei Untersuchung der TCR Expression konnte gezeigt werden, dass die Auswahl der im Ratten iNKT TCR genutzten BV Gensegmente ähnlich limitiert ist wie in der Maus. Neben der dominanten Nutzung der BV8S4 und BV8S2 Gensegmente wurden hauptsächlich BV8S1, BV14 und BV7 gefunden. Bei Untersuchungen der CD1d Dimerbindung der iNKT Zellpopulation konnte der Einfluss der na- türlich auftretenden A93G Substitution in der iNKT TCRa Kette bestätigt werden. Außerdem zeigte sich hier ebenfalls der Einfluss des BV Gensegments auf die Ligandenbindung, wobei BV8S4 negative Zellen im Vergleich zu BV8S4 positiven Zellen eine stärkere Ratten CD1d Dimerbindung zeigten.
The oncogenic MYC protein is a transcriptional regulator of multiple cellular processes and is aberrantly activated in a wide range of human cancers. MYC is an unstable protein rapidly degraded by the ubiquitin-proteasome system. Ubiquitination can both positively and negatively affect MYC function, but its direct contribution to MYC-mediated transactivation remained unresolved.
To investigate how ubiquitination regulates MYC activity, a non-ubiquitinatable MYC mutant was characterized, in which all lysines are replaced by arginines (K-less MYC). The absence of ubiquitin-acceptor sites in K-less MYC resulted in a more stable protein, but did not affect cellular localization, chromatin-association or the ability to interact with known MYC interaction partners.
Unlike the wild type protein, K-less MYC was unable to promote proliferation in immortalized mammary epithelial cells. RNA- and ChIP-Sequencing analyses revealed that, although K-less MYC was present at MYC-regulated promoters, it was a weaker transcriptional regulator. The use of K-less MYC, a proteasomal inhibitor and reconstitution of individual lysine residues showed that proteasomal turnover of MYC is required for MYC target gene induction. ChIP-Sequencing of RNA polymerase II (RNAPII) revealed that MYC ubiquitination is dispensable for RNAPII recruitment and transcriptional initiation but is specifically required to promote transcriptional elongation. Turnover of MYC is required to stimulate histone acetylation at MYC-regulated promoters, which depends on a highly conserved region in MYC (MYC box II), thereby enabling the recruitment of BRD4 and P-TEFb and the release of elongating RNAPII from target promoters. Inhibition of MYC turnover enabled the identification of an intermediate in MYC-mediated transactivation, the association of MYC with the PAF complex, a positive elongation factor, suggesting that MYC acts as an assembly factor transferring elongation factors onto RNAPII. The interaction between MYC and the PAF complex occurs via a second highly conserved region in MYC’s amino terminus, MYC box I.
Collectively, the data of this work show that turnover of MYC coordinates histone acetylation with recruitment and transfer of elongation factors on RNAPII involving the cooperation of MYC box I and MYC box II.
Alzheimer’s disease (AD) is the most prevalent neurodegenerative disease of the brain, which is characterized by a progressive loss of memory and spatial orientation. Only less than 5-10% of AD sufferers are familial cases due to genetic mutations in the amyloid precursor protein (APP) gene or presenilin (PS) 1 and 2 genes. The cause of sporadic AD (sAD) which covers > 95% of AD patients is still unknown. Current research found interactions between aging, diabetes and cognitive decline including dementia in general and in AD in particular. Disturbances of brain glucose uptake, glucose tolerance and utilization and impairment of the insulin/insulin receptor (IR) signaling cascade are thought to be key targets for the development of sAD.
In the brain of AD patients, neural plasticity is impaired indicated by synaptic and neuronal loss. Adult neurogenesis (AN), the generation of functional neurons in the adult brain, may be able to restore neurological function deficits through the integration of newborn neurons into existing neural networks. The dentate gyrus of the hippocampus is one out of few brain regions where life-long AN exists. However, there is a big controversy in literature regarding the involvement of AN in AD pathology. Most animal studies used transgenic mice based on the Amyloid ß (Aß) hypothesis which primarily act as models for the familial form of AD. Findings from human post mortem AN studies were also inconstistent. In this thesis, we focused on the possible involvement of AN in the pathogenesis of the sporadic form of AD. Streptozotocin intracerebroventricularily (STZ icv) treated rats, which develop an insulin-resistant brain state and learning and memory deficits preceding Aß pathology act as an appropriate animal model for sAD. We used STZ treatment for both parts of my work, for the in vivo and in vitro study.
In the first part of my thesis, my coworkers and I investigated STZ icv treatment effects on different stages of AN in an in vivo approach. Even if STZ icv treatment does not seem to considerably influence stem cell proliferation over a short-term (1 month after STZ icv treatment) as well as in a long-term (3 months after STZ icv treatment) period, it results in significantly less immature and newborn mature neurons 3 months after STZ icv treatment. This reduction detected after 3 months was specific for the septal hippocampus, discussed to be important for spatial learning. Subsequently we performed co-localization studies with antibodies detecting BrdU (applied appr. 27 days before sacrifice) and cell-type specific markers such as NeuN, and GFAP, we found that STZ treatment does not affect the differentiation fate of newly generated cells. Phenotype analysis of BrdU-positive cells in the hilus and molecular layer revealed that some of the BrdU-positive cells are newborn oligodendrocytes but not newborn microglia.
In the second part of my thesis I worked with cultured neural stem cells (NSCs) isolated from the adult rat hippocampus to reveal STZ effects on the proliferation of of NSCs, and on the survival and differentiation of their progeny. Furthermore, this in vitro approach enabled me to study cellular mechanisms underlying the observed impaired neurogenesis in the hippocampus of STZ-treated rats. In contrast to our findings of the STZ icv in vivo study we revealed that STZ supplied with the cell culture medium inhibits the proliferation of NSCs in a dose-dependent and time-dependent manner. Moreover, performing immunofluorescence studies with antibodies detecting cell-type specific markers after triggering NSCs to differentiate, we could show that STZ treatment affects the number of newly generated neurons but not of astrocytes. Analyzing newborn cells starting to differentiate and migrate I was able to demonstrate that STZ has no effect on the migration of newborn cells. Trying to reveal cellular mechanisms underlying the negative influence of STZ on hippocampal AN, we performed qRT-PCR and immunofluorescence staining and thus could show that in NSCs the expression of glucose transporter (GLUT)3 mRNA as well as IR and GLUT3 protein levels are reduced after STZ treatment. Therefore, the inhibition of the proliferation of NSCs may be (at least partially) caused by these two molecules. Interestingly, the effect of STZ on differentiating cells was shown to be different, as IR protein expression was not significantly changed but GLUT3 protein levels were decreased in consequence of STZ treatment.
In summary, this project delivered further insights into the interrelation between AN the sporadic form of sAD and thus provides a basis of new therapeutic approaches in sAD treatment through intervening AN. Discrepancies between the results of the two parts of my thesis, the in vivo and in vitro part, were certainly caused to a certain extent by the missing microenvironment in the in vitro approach with cultured NSCs. Future studies e.g. using co-culture systems could at least minimize the effect of a missing natural microenvironment of cultured NSCs, so that the use of an in vitro approach for the investigation of STZ treatment underlying cellular mechanisms can be improved.
Das Empfinden von Schmerz ist für uns überlebenswichtig. Chronischer Schmerz hingegen hat seine physiologische Bedeutung verloren und wird als eigenes Krankheitsbild angesehen. Schmerzempfindung beginnt mit der Nozizeption. Die Zellkörper nozizeptiver Neurone befinden sich in den Spinalganglien (Hinterwurzelganglion, dorsal root ganglion DRG) und Trigeminalganglien (TG). In den DRG-Neuronen macht der Zwei-Poren-Kaliumkanal (K2P) TRESK die Hauptkomponente eines Kaliumstromes, des „standing outward currents“ IKSO, aus. Die physiologische Hauptaufgabe der TRESK-Kanäle liegt in der Regulation der zellulären Erregbarkeit nozizeptiver Neurone. Während einer Entzündungsreaktion werden Entzündungsmediatoren wie Histamin, Bradykinin, Serotonin und Lysophosphatidsäure (LPA) ausgeschüttet und können durch die Aktivierung ihrer G-Protein gekoppelten Rezeptoren (GPCR) oder direkte Interaktion mit Ionenkanälen die nozizeptive Erregung beeinflussen. Durch Anwendung von RT-PCR und eines neu entwickelten Antikörpers wurde die Ko-Expression von TRESK-Kanälen zusammen mit Kanälen der Transient-Receptor-Potential-Kationenkanalfamilie (TRP) und LPA-Rezeptoren in DRG-Neuronen nachgewiesen.
Durch rekombinante Ko-Expression von TRESK-Kanälen und LPA2-Rezeptoren in Xenopus Oozyten konnte durch Zugabe von LPA eine fast 10-fache Aktivierung des basalen K+-Stromes erzielt werden. Die Auswertung der Dosis-Wirkungskurve ergab einen EC50-Wert von 0,2 µM LPA. Die LPA-induzierte TRESK-Stromaktivierung konnte durch die Verwendung des mutierten Kanals TRESK[PQAVAD] oder durch die Zugabe des Phospholipase C (PLC) Inhibitors U73122 verhindert werden. Dies zeigt die Beteiligung des PLC-Signalwegs und die Bindung von Calcineurin an den TRESK-Kanal bei der Stromaktivierung. TRESK ist das einzige Mitglied der K2P-Familie, das eine LPA-induzierte Aktivierung des Stromes zeigt. TREK- und TASK-1-Ströme werden durch LPA inhibiert. In DRG-Neuronen mit kleinem Durchmesser wird Nozizeption durch die Aktivierung von TRPV1-Kanälen durch Hitze oder Capsaicin, dem Inhaltsstoff des Chilis, und zusätzlich durch die Substanz LPA verursacht. Ein weiteres Mitglied der TRP-Familie, der TRPA1-Kanal, ist bei der verstärkten Nozizeption während einer Entzündung involviert. Werden TRESK- und TRP-Kanäle in Xenopus Oozyten ko-exprimiert, verursacht LPA gleichzeitig einen Kationeneinwärts- wie auch -auswärtsstrom. Unter diesen Bedingungen verschob sich das Umkehrpotenzial in einen Bereich zwischen den Umkehrpotenzialen von Oozyten, die nur den K+-Kanal exprimieren und von Oozyten, die nur den unspezifischen Kationenkanal exprimieren. Durch diese Experimente konnte gezeigt werden, dass die LPA-induzierte Ko-Aktivierung von TRP-Kanälen und TRESK zu einer Begrenzung des exzitatorischen Effekts führen kann.
Die DRG-ähnlichen F11-Zellen exprimieren keine TRESK-Kanäle. Sie sind in der Lage durch Strompulse Aktionspotenziale zu generieren. Mit TRESK transfizierte F11-Zellen zeigten eine Verschiebung des Umkehrpotenzials in negative Richtung, einen größeren Auswärtsstrom und den Verlust von spannungsgesteuerten Natriumkanälen. Auch hohe Strompulse konnten keine Aktionspotenziale mehr auslösen.
Bei Spannungs-Klemme-Messungen von primären DRG-Neuronen von TRESK[wt]-Mäusen erhöhte sich der IKSO nach Zugabe von LPA um über 20 %. Im Gegensatz dazu zeigten DRG-Neurone von TRESK[ko]-Mäusen unter diesen Bedingungen eine leichte Hemmung des IKSO von etwa 10 %. In Neuronen, die TRPV1 exprimieren, führte LPA nicht nur zum Anstieg des IKSO, sondern auch zur Aktivierung eines Einwärtsstromes (TRPV1). Im Vergleich dazu wurde in TRESK[ko]-Neuronen durch LPA nur der Einwärtsstrom aktiviert.
In Strom-Klemme-Experimenten führte LPA-Applikation zur Entstehung von Aktionspotenzialen mit höherer Frequenz in Zellen von TRESK[ko]-Mäusen im Vergleich zu Zellen von TRESK[wt]-Mäusen. Zusätzlich wurde die Erregung, die durch Strompulse von 100 pA ausgelöst wurde, in den beiden Genotypen durch LPA unterschiedlich moduliert. Die Aktionspotenzialfrequenz in TRESK[wt]-Neuronen wurde gesenkt, in TRESK[ko]-Neuronen wurde sie erhöht.
Die vorliegende Arbeit zeigt, dass die Erregung nozizeptiver Neurone durch LPA aufgrund der Ko-Aktivierung der TRESK-Kanäle abgeschwächt werden kann. Die Erregbarkeit von sensorischen Neuronen wird strak durch die Aktivität und Expression der TRESK-Kanäle kontrolliert. Deswegen sind TRESK-Kanäle gute Kandidaten für die pharmakologische Behandlung von Schmerzkrankheiten.
Das humane Genom besteht zu ungefähr 8 % aus humanen endogenen Retroviren (HERVs),
jedoch sind viele aufgrund von Mutationen oder Deletionen nicht mehr funktionell. Trotzdem
wurden funktionelle HERV-Proteine gefunden, welche offene Leserahmen (ORFs) besitzen
und für funktionelle Hüll-Glykoproteine wie z.B. Syncytin-1, Syncytin-2 und HML-2
kodieren. Diese HERV-Hüllproteine beinhalten eine suppressive Domäne (SU) und
induzieren möglicherweise eine Immunsuppression diverser Immunzellen während einer
gesunden Schwangerschaft.
In dieser Arbeit wurden spezifisch die modulatorischen Eigenschaften verschiedener HERVHüllproteine
(Syncytin-1, -2 und HML-2) auf Immunzellen untersucht.
Wir konnten zeigen, dass die HERV-Bindungsrezeptoren ASCT-1, -2 und MFSD2A auf der
Oberfläche von T-Zellen und DCs exprimiert werden. Für funktionelle Experimente wurden
HERV-Hüllproteine transgen in CHO-Zellen exprimiert, die als Effektorzellen in Ko-Kultur-
Systemen verwendet wurden. Es konnte keine Hemmung der PMA/Ionomycin-stimulierten
T-Zell-Proliferation durch die Effektorzellen gefunden werden. Darüber hinaus
beeinträchtigten die Effektorzellen nicht die Expression von Reifungsmarkern auf DCs nach
LPS-Aktivierung, induzierten jedoch die Produktion der pro-inflammatorischen Zytokine IL-
12 und TNF-α. Dagegen inhibierten die konstitutiv HERV-Hüllprotein-exprimierenden
Chorionkarzinom-Zelllinien BeWo und JEG die PMA/Ionomycin-stimulierte T-Zell-
Proliferation sehr effektiv. Die Chorionkarzinom-Zelllinien hatten ebenfalls keinen Einfluss
auf die phänotypische LPS-DC-Reifung, modulierten aber die LPS-DC-Zytokin-Antwort sehr
effektiv zu einem suppressiven Profil durch eine Inhibition der pro-inflammatorischen
Zytokine IL-12 und TNF-α sowie einen Anstieg von anti-inflammatorischem IL-10. BeWound
JEG-Zellen, aber auch HERV-Hüllprotein-exprimierende Effektorzellen verändern die
durch LPS-DC-stimulierte allogene T-Zell-Proliferation. Dies war mit einer verringerten
Bildung von DC/T-Zell-Konjugaten sowie mit einer Hemmung der IFN-γ-Sekretion und der
Ca2+-Mobilisation dieser T-Zellen assoziiert. Des Weiteren wurden eine reduzierte p-Tyrosin-
Akkumulation und kein Ausschluss des F-Aktin-Signals in der immunologischen Synapse,
der Kontaktstelle dieser DC/T-Zell-Konjugate, gefunden.
Zusammenfassend lassen diese Ergebnisse vermuten, dass HERV-Hüllproteine die T-Zell-
Proliferation nicht direkt beeinflussen, sich aber modulierend auf DCs auswirken und dadurch
mit deren allogene T-Zell-Proliferation interferieren.
Accurate information transfer between neurons governs proper brain function. At chemical synapses, communication is mediated via neurotransmitter release from specialized presynaptic intercellular contact sites, so called active zones. Their molecular composition constitutes a precisely arranged framework that sets the stage for synaptic communication.
Active zones contain a variety of proteins that deliver the speed, accuracy and plasticity inherent to neurotransmission. Though, how the molecular arrangement of these proteins influences active zone output is still ambiguous. Elucidating the nanoscopic organization of AZs has been hindered by the diffraction-limited resolution of conventional light microscopy, which is insufficient to resolve the active zone architecture on the nanometer scale. Recently, super-resolution techniques entered the field of neuroscience, which yield the capacity to bridge the gap in resolution between light and electron microscopy without losing molecular specificity. Here, localization microscopy methods are of special interest, as they can potentially deliver quantitative information about molecular distributions, even giving absolute numbers of proteins present within cellular nanodomains.
This thesis puts forward an approach based on conventional immunohistochemistry to quantify endogenous protein organizations in situ by employing direct stochastic optical reconstruction microscopy (dSTORM). Focussing on Bruchpilot (Brp) as a major component of Drosophila active zones, the results show that the cytomatrix at the active zone is composed of units, which comprise on average ~137 Brp molecules, most of which are arranged in approximately 15 heptameric clusters. To test for a quantitative relationship between active zone ultrastructure and synaptic output, Drosophila mutants and electrophysiology were employed. The findings indicate that the precise spatial arrangement of Brp reflects properties of short-term plasticity and distinguishes distinct mechanistic causes of synaptic depression. Moreover, functional diversification could be connected to a heretofore unrecognized ultrastructural gradient along a Drosophila motor neuron.