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Mesenteric lymph nodes (mLNs) are sentinel sites of enteral immunosurveillance and immune homeostasis. Immune cells from the gastrointestinal tract (GIT) are constantly recruited to the mLNs in steady-state and under inflammatory conditions resulting in the induction of tolerance and immune cells activation, respectively. Surgical dissection and transplantation of lymph nodes (LN) is a technique that has supported seminal work to study LN function and is useful to investigate resident stromal and endothelial cell biology and their cellular interactions in experimental disease models. Here, we provide a detailed protocol of syngeneic mLN transplantation and report assays to analyze effective mLN engraftment in congenic recipients. Transplanted mLNs allow to study T cell activation and proliferation in preclinical mouse models. Donor mLNs proved viable and functional after surgical transplantation and regenerated blood and lymphatic vessels. Immune cells from the host completely colonized the transplanted mLNs within 7-8 weeks after the surgical intervention. After allogeneic hematopoietic cell transplantation (allo-HCT), adoptively transferred allogeneic CD4+ T cells from FVB/N (H-2q) mice homed to the transplanted mLNs in C57BL/6 (H-2b) recipients during the initiation phase of acute graft-versus-host disease (aGvHD). These CD4+ T cells retained full proliferative capacity and upregulated effector and gut homing molecules comparable to those in mLNs from unmanipulated wild-type recipients. Wild type mLNs transplanted into MHCII deficient syngeneic hosts sufficed to activate alloreactive T cells upon allogeneic hematopoietic cell transplantation, even in the absence of MHCII+ CD11c+ myeloid cells. These data support that orthotopically transplanted mLNs maintain physiological functions after transplantation. The technique of LN transplantation can be applied to study migratory and resident cell compartment interactions in mLNs as well as immune reactions from and to the gut under inflammatory and non-inflammatory conditions.
Ubiquitination is a posttranslational modification with immense impact on a wide range of cellular processes, including proteasomal degradation, membrane dynamics, transcription, translation, cell cycle, apoptosis, DNA repair and immunity. These diverse functions stem from the various ubiquitin chain types, topologies, and attachment sites on substrate proteins. Substrate recruitment and modification on lysine, serine or threonine residues is catalyzed by ubiquitin ligases (E3s). An important E3 that decides about the fate of numerous substrates is the HECT-type ubiquitin ligase HUWE1. Depending on the substrate, HUWE1 is involved in different processes, such as cell proliferation and differentiation, DNA repair, and transcription. One of the transcription factors that is ubiquitinated by HUWE1 is the MYC interacting zinc finger protein 1 (MIZ1). MIZ1 is a BTB/POZ (Bric-à-brac, Tramtrack and Broad-Complex/Pox virus and zinc finger) zinc finger (ZF) protein that binds to DNA through its 13 C2H2-type zinc fingers and either activates or represses the transcription of target genes, including genes involved in cell cycle arrest, such as P21CIP1 (CDKN1A). The precise functions of MIZ1 depend on its interactions with the MYC-MAX heterodimer, but also its heterodimerization with other BTB-ZF proteins, such as BCL6 or NAC1. How MIZ1 interacts with HUWE1 has not been studied and, as a consequence, it has not been possible to rationally develop tools to manipulate this interaction with specificity in order to better understand the effects of the interaction on the transcriptional function of MIZ1 on target genes or processes downstream. One aspect of my research, therefore, aimed at characterizing the MIZ1-HUWE1 interaction at a structural level. I determined a crystal structure of the MIZ1-BTB-domain in complex with a peptide, referred to as ASC, derived from a C terminal region of HUWE1, previously named ‘activation segment’. The binding mode observed in this crystal structure could be validated by binding and activity assays in vitro and by cell-based co-IP experiments in the context of N-terminally truncated HUWE1 constructs. I was not able to provide unambiguous evidence for the identified binding mode in the context of full-length HUWE1, indicating that MIZ1 recognition by HUWE1 requires yet unknown regions in the cell. While the structural details of the MIZ1-HUWE1 interaction remains to be elucidated in the context of the full-length proteins, the binding mode between MIZ1BTB and ASC revealed an interesting, atypical structural feature of the BTB domain of MIZ1 that, to my knowledge, has not been described for other BTB-ZF proteins: The B3 region in MIZ1BTB is conformationally malleable, which allows for a HUWE1-ASC-peptide-mediated β-sheet extension of the upper B1/B2-strands, resulting in a mixed, 3 stranded β-sheet. Such β-sheet extension does not appear to occur in other homo- or heterodimeric BTB-ZF proteins, including MIZ1-heterodimers, since these proteins typically possess a pre-formed B3-strand in at least one subunit. Instead, BCL6 co repressor-derived peptides (SMRT and BCOR) were found to extend the lower β-sheet in BCL6BTB by binding to an adjacent ‘lateral groove’. This interaction follows a 1:1 stoichiometry, whereas the MIZ1BTB-ASC-complex shows a 2:1 stoichiometry. The crystal structure of the MIZ1BTB-ASC-complex I determined, along with comparative binding studies of ASC with monomeric, homodimeric, and heterodimeric MIZ1BTB variants, respectively, suggests that ASC selects for MIZ1BTB homodimers. The structural data I generated may serve as an entry point for the prediction of additional interaction partners of MIZ1 that also have the ability to extend the upper β-sheet of MIZ1BTB. If successful, such interaction partners and structures thereof might aid the design of peptidomimetics or small-molecule inhibitors of MIZ1 signaling. Proof-of-principle for such a structure-guided approach targeting BTB domains has been provided by small-molecule inhibitors of BCL6BTB co-repressors interactions. If a similar approach led to molecules that interfere with specific interactions of MIZ1, they would provide intriguing probes to study MIZ1 biology and may eventually allow for the development of MIZ1-directed cancer therapeutics.
In eukaryotes, the enormously long DNA molecules need to be packaged together with histone proteins into nucleosomes and further into compact chromatin structures to fit it into the nucleus. This nuclear organisation interferes with all phases of transcription that require the polymerase to bind to DNA. During transcription – the process in which the hereditary information stored in DNA is transferred to many transportable RNA molecules - nucleosomes form a physical obstacle for polymerase progression. Thus, transcription is usually accompanied by processes mediating nucleosome destabilisation, including post-translational histone modifications (PTMs) or exchange of canonical histones by their variant forms. To the best of our knowledge, acetylation of histones has the highest capability to induce chromatin opening. The lysine modification can destabilise histone-DNA interactions within a nucleosome and can serve as a binding site for various chromatin remodelers that can modify the nucleosome composition. For example, H4 acetylation can impede chromatin folding and can stimulate the exchange of canonical H2A histone by its variant form H2A.Z at transcription start sites (TSSs) in many eukaryotes, including humans. As histone H4, H2A.Z can be post-translationally acetylated and as acetylated H4, acetylated H2A.Z is enriched at TSSs suggested to be critical for transcription. However, thus far, it has been difficult to study the cause and consequence of H2A.Z acetylation.
Even though, genome-wide chromatin profiling studies such as ChIP-seq have already revealed the genomic localisation of many histone PTMs and variant proteins, they can only be used to study individual chromatin marks and not to identify all factors important for establishing a distinct chromatin structure. This would require a comprehensive understanding of all marks associated to a specific genomic locus. However, thus far, such analyses of locus-specific chromatin have only been successful for repetitive regions, such as telomeres.
In my doctoral thesis, I used the unicellular parasite Trypanosoma brucei as a model system for chromatin biology and took advantage of its chromatin landscape with TSSs comprising already 7% of the total T. brucei genome (humans: 0.00000156%). Atypical for a eukaryote, the protein-coding genes are arranged in long polycistronic transcription units (PTUs). Each PTU is controlled by its own ~10 kb-wide TSS, that lies upstream of the PTU. As observed in other eukaryotes, TSSs are enriched with nucleosomes containing acetylated histones and the histone variant H2A.Z. This is why I used T. brucei to particularly investigate the TSS-specific chromatin structures and to identify factors involved in H2A.Z deposition and transcription regulation in eukaryotes. To this end, I established an approach for locus-specific chromatin isolation that would allow me to identify the TSSs- and non-TSS-specific chromatin marks. Later, combining the approach with a method for quantifying lysine-specific histone acetylation levels, I found H2A.Z and H4 acetylation enriched in TSSs-nucleosomes and mediated by the histone acetyltransferases HAT1 and HAT2. Depletion of HAT2 reduced the levels of TSS-specific H4 acetylation, affected targeted H2A.Z deposition and shifted the sites of transcription initiation. Whereas HAT1 depletion had only a minor effect on H2A.Z deposition, it had a strong effect on H2A.Z acetylation and transcription levels. My findings demonstrate a clear link between histone acetylation, H2A.Z deposition and transcription initiation in the early diverged unicellular parasite T. brucei, which was thus far not possible to determine in other eukaryotes. Overall, my study highlights the usefulness of T. brucei as a model system for studying chromatin biology. My findings allow the conclusion that H2A.Z regardless of its modification state defines sites of transcription initiation, whereas H2A.Z acetylation is essential co-factor for transcription initiation. Altogether, my data suggest that TSS-specific chromatin establishment is one of the earliest developed mechanisms to control transcription initiation in eukaryotes.
The use of human adipose-derived mesenchymal stem cells (ASCs) for cell-based therapeutic approaches, in terms of repair and regeneration of various tissues and organs, offers an alternative therapeutic tool in the field of regenerative medicine. The ability of ASCs to differentiate along mesenchymal lineages is not the only property that makes these cells particularly attractive for therapeutic purposes. Their promising functions in promoting angiogenesis, reducing inflammation as well as in functional tissue restoration are largely related to the trophic effects of a broad panel of secreted cytokines and growth factors. However, in cell-based approaches, the cell-loaded construct often is exposed to an ischemic microenvironment characterized by severe oxidative and nutritional stress after transplantation due to the initial lack of vascular connection, resulting in reduced cell viability and altered cell behaviour. Therefore, the effective use of ASCs in regenerative medicine first requires a comprehensive characterization of the cells in terms of their viability, differentiation capacity and especially their secretory capabilities under ischemia-mimicking conditions in order to better understand their beneficial role. Accordingly, in the first part of this work, ASCs were investigated under different ischemic conditions, in which cells were exposed to both glucose and oxygen deprivation, with respect to viability and secretory function. Using mRNA gene expression analysis, significantly higher expression of selected angiogenic, anti-apoptotic and immunomodulatory factors (IL-6, VEGF, STC-1) could be demonstrated under harsh ischemic conditions. These results were reflected at the protein expression level by a significantly increased secretion of these factors. For stanniocalcin-1 (STC-1), a factor not yet described in ASCs, a particularly high expression with significant secreted amounts of the protein could be demonstrated under harsh ischemic conditions. Thus, the first part of this work, in addition to the characterization of the viability, provided first insights into the secretory response of ASCs under ischemic conditions.
The response of ASCs to glucose deficiency in combination with severe hypoxia has been little explored to date. Thus, the focus of the second part of this work was on a more detailed investigation of the secretory response of ASCs under glucose and oxygen deprivation. For a more comprehensive analysis of the secretion profile, a cytokine antibody array was performed, which allowed the detection of a broad panel of secreted angiogenic factors
(IL-8, ANG), matrix-regulating proteins (TIMP-1, TIMP-2), chemokines (MCP-1/CCL2,
IP-10/CXCL 10) and other factors under ischemic conditions. To verify these results, selected factors were examined using ELISA. The analysis revealed that the secretion of individual factors (e.g., STC-1, VEGF) was significantly upregulated by the combination of glucose and oxygen deprivation compared to oxygen deprivation alone.
In order to investigate the impact of the secretome of ischemic ASCs on cell types involved in tissue regeneration, the effect of conditioned medium of ischemia-challenged ASCs on both endothelial cells and fibroblasts was investigated in subsequent experiments. Significantly increased viability and tube formation of endothelial cells as well as activated migration of fibroblasts by the secreted factors of ischemic ASCs could be demonstrated. A direct correlation of these effects to STC-1, which was significantly upregulated under ischemic conditions and has been described as a regulator of key cellular functions, could not be verified.
The particular secretory capacity of ASCs provides a valuable tool for cell-based therapies, such as cell-assisted lipotransfer (CAL), where by enriching fat grafts with isolated ASCs, a significantly improved survival rate of the transplanted construct is achieved with less resorption of the fat tissue as well as a reduction in adverse implications, such as fibrosis and cyst formation. In order to better understand the function of ASCs in CAL, an autologous transwell-based lipograft-ASC co-culture was established in the last part of this work, in which first investigations showed a markedly increased secretion of VEGF compared to lipografts without added ASCs. As the stability rate of the fat tissue and thus the success of CAL is presumably also dependent on the preparation of the tissue before transplantation, the conventional preparation method of fat tissue for vocal fold augmentation in laryngoplasty was additionally evaluated in vitro in a pilot experiment. By analyzing the viability and tissue structure of the clinically prepared injection material, a large number of dead cells and a clearly damaged tissue structure with necrotic areas could be demonstrated. In comparison, the preparation method of the fat tissue established in this work as small tissue fragments was able to provide a clearly intact, vital, and vascularized tissue structure. This type of adipose tissue preparation represents a promising alternative for clinical vocal fold augmentation.
In conclusion, the results of this work contribute to a comprehensive characterization of ASCs under ischemic conditions, such as those prevalent at the transplantation site or in tissue regeneration. The results obtained, especially on the secretory capacity of ASCs, provide new insights into how ASCs mediate regenerative effects in an ischemic milieu and why their use for therapeutic purposes is highly attractive and promising.
Articular cartilage damage caused by sports accidents, trauma or gradual wear and tear can lead to degeneration and the development of osteoarthritis because cartilage tissue has only limited capacity for intrinsic healing. Osteoarthritis causes reduction of mobility and chronic pain and is one of the leading causes of disability in the elderly population. Current clinical treatment options can reduce pain and restore mobility for some time, but the formed repair tissue has mostly inferior functionality compared to healthy articular cartilage and does not last long-term. Articular cartilage tissue engineering is a promising approach for the improvement of the quality of cartilage repair tissue and regeneration. In this thesis, a promising new cell type for articular cartilage tissue engineering, the so-called articular cartilage progenitor cell (ACPC), was investigated for the first time in the two different hydrogels agarose and HA-SH/P(AGE-co-G) in comparison to mesenchymal stromal cells (MSCs). In agarose, ACPCs´ and MSCs´ chondrogenic capacity was investigated under normoxic (21 % oxygen) and hypoxic (2 % oxygen) conditions in monoculture constructs and in zonally layered co-culture constructs with ACPCs in the upper layer and MSCs in the lower layer. In the newly developed hyaluronic acid (HA)-based hydrogel HA-SH/P(AGE-co-G), chondrogenesis of ACPCs and MSCs was also evaluated in monoculture constructs and in zonally layered co-culture constructs like in agarose hydrogel. Additionally, the contribution of the bioactive molecule hyaluronic acid to chondrogenic gene expression of MSCs was investigated in 2D monolayer, 3D pellet and HA-SH hydrogel culture. It was shown that both ACPCs and MSCs could chondrogenically differentiate in agarose and HA-SH/P(AGE-co-G) hydrogels. In agarose hydrogel, ACPCs produced a more articular cartilage-like tissue than MSCs that contained more glycosaminoglycan (GAG), less type I collagen and only little alkaline phosphatase (ALP) activity. Hypoxic conditions did not increase extracellular matrix (ECM) production of ACPCs and MSCs significantly but improved the quality of the neo-cartilage tissue produced by MSCs. The creation of zonal agarose constructs with ACPCs in the upper layer and MSCs in the lower layer led to an ECM production in zonal hydrogels that lay in general in between the ECM production of non-zonal ACPC and MSC hydrogels. Even though zonal co-culture of ACPCs and MSCs did not increase ECM production, the two cell types influenced each other and, for example, modulated the staining intensities of type II and type I collagen in comparison to non-zonal constructs under normoxic and hypoxic conditions. In HA-SH/P(AGE-co-G) hydrogel, MSCs produced more ECM than ACPCs, but the ECM was limited to the pericellular region for both cell types. Zonal HASH/P(AGE-co-G) hydrogels resulted in a native-like zonal distribution of ECM as MSCs in the lower zone produced more ECM than ACPCs in the upper zone. It appeared that chondrogenesis of ACPCs was supported by hydrogels without biological attachment sites such as agarose, and that chondrogenesis of MSCs benefited from hydrogels with biological cues like HA. As HA is an attractive material for cartilage tissue engineering, and the HA-based hydrogel HA-SH/P(AGE-co-G) appeared to be beneficial for MSC chondrogenic differentiation, the contribution of HA to chondrogenic gene expression of MSCs was investigated. An upregulation of chondrogenic gene expression was found in 2D monolayer and 3D pellet culture of MSCs in response to HA supplementation, while gene expression of osteogenic and adipogenic transcription factors was not upregulated. MSCs, encapsulated in a HA-based hydrogel, showed upregulation of gene expression for chondrogenic, osteogenic and adipogenic differentiation markers as well as for stemness markers. In a 3D bioprinting process, using the HA-based hydrogel, gene expression levels of MSCs mostly did not change. Nevertheless, expression of three tested genes (COL2A1, SOX2, CD168) was downregulated in printed in comparison to cast constructs, underscoring the importance of closely monitoring cellular behaviour during and after the printing process. In summary, it was confirmed that ACPCs are a promising cell source for articular cartilage engineering with advantages over MSCs when they were cultured in a suitable hydrogel like agarose. The performance of the cells was strongly dependent on the hydrogel environment they were cultured in. The different chondrogenic performance of ACPCs and MSCs in agarose and HA-SH/P(AGE-co-G) hydrogels highlighted the importance of choosing suitable hydrogels for the different cell types used in articular cartilage tissue engineering. Hydrogels with high polymer content, such as the investigated HA-SH/P(AGE-co-G) hydrogels, can limit ECM distribution to the pericellular area and should be developed further towards less polymer content, leading to more homogenous ECM distribution of the cultured cells. The influence of HA on chondrogenic gene expression and on the balance between differentiation and maintenance of stemness in MSCs was demonstrated. More studies should be performed in the future to further elucidate the signalling functions of HA and the effects of 3D bioprinting in HA-based hydrogels. Taken together, the results of this thesis expand the knowledge in the area of articular cartilage engineering with regard to the rational combination of cell types and hydrogel materials and open up new possible approaches to the regeneration of articular cartilage tissue.
In deafness, which is caused by the malfunctioning of the inner ear, an implantation of a cochlear implant (CI) is able to restore hearing. The CI is a neural prosthesis that is located within the cochlea. It replaces the function of the inner hair cells by direct electrical stimulation of the auditory nerve fibers. The CI enables many deaf or severe hearing-impaired people to achieve a good speech perception. Nevertheless, there is a lot of potential for further improvements. Compared to normal-hearing listeners rate pitch discrimination is much worse. Rate pitch discrimination is the ability to distinguish the pitch of two stimuli with two different pulse rates. This ability is important for enjoying music as well as speech perception (in noise). Further, the small dynamic range in electrical hearing (compared to normal-hearing listeners) and therefore the small intensity resolution limits the performance of CI users. Both, rate pitch coding and dynamic range were investigated in this doctoral thesis.
For the first issue, a pitch discrimination task was designed to determine the just-noticeable-difference (JND) in pitch with 200 and 400 pps as reference. Additionally to the default biphasic pulse (single pulse) the experiment was performed with double pulses. The double pulse consists out of two biphasic pulses directly after each other and a small interpulse interval (IPI) in between. Three different IPIs (15, 50, and 150 µs) were tested. The statistical analysis of JNDs revealed no significant effects between stimulation with single-pulse or double-pulse trains.
A follow-up study investigated an alternating pulse train consisting of single and double pulses. To investigate if the 400 pps alternating pulse train is comparable in pitch with the 400 pps single-pulse train, a pairwise pitch comparison test was conducted. The alternating pulse train was compared with single-pulse trains at 200, 300 and 400 pps. The results showed that the alternating pulse train is for most subjects similar in pitch with the 200 pps single-pulse train. Therefore, pitch perception seemed to be dominated by the double pulses within the pulse train.
Accordingly, double pulses with different amplitudes were tested. Based on the facilitation effect, a larger neuronal response was expected by stimulating with two pulses with a short IPI within the temporal facilitation range. In other studies, this effect was shown to be maximal in CIs of the manufacturer Cochlear, with first pulse amplitudes set at or slightly below the electrically evoked compound action potential (ECAP) threshold. The second pulse amplitude did not influence the facilitation effect and therefore could be choose at will. Similarly, this effect was tested in this thesis with CIs of the manufacturer MED-EL. Nevertheless, to achieve a proper signal-to-noise ratio, technical issues had to be addressed like a high noise floor, resulting in incorrect determination of the ECAP threshold. After solving this issues, the maximum facilitation effect was around the ECAP threshold as in the previous study with Cochlear. For future studies this effect could be used in a modified double pulse rate pitch experiment with the first pulse amplitude at ECAP threshold and the second pulse amplitude variable to set the most comfortable loudness level (MCL).
The last study within this thesis investigated the loudness perception at two different loudness levels and the resulting dynamic range for different interphase-gaps (IPG). A larger IPG can reduce the amplitude at same loudness level to save battery power. However, it was unknown if the IPG has an influence on the dynamic range. Different IPGs (10 and 30 µs) were compared with the default IPG (2.1 µs) in a loudness matching experiment. The experiment was performed at the most comfortable loudness level (MCL) of the subject and the amplitude of half the dynamic range (50%-ADR). An upper dynamic range was calculated from the results of MCL and 50%-ADR (therefore not the whole dynamic range was covered). As expected from previous studies a larger IPG resulted in smaller amplitudes. However, the observed effect was larger at MCL than at 50%-ADR which resulted in a smaller upper dynamic range. This is the first time a decrease of this dynamic range was shown.
Design of novel IL-4 antagonists employing site-specific chemical and biosynthetic glycosylation
(2021)
The cytokines interleukin 4 (IL-4) and IL-13 are important mediators in the humoral immune response and play a crucial role in the pathogenesis of chronic inflammatory diseases, such as asthma, allergies, and atopic dermatitis. Hence, IL-4 and IL-13 are key targets for treatment of such atopic diseases.
For cell signalling IL-4 can use two transmembrane receptor assemblies, the type I receptor consisting of receptors IL-4R and γc, and type II receptor consisting of receptors IL-4R and IL-13R1. The type II receptor is also the functional receptor of IL-13, receptor sharing being the molecular basis for the partially overlapping effects of IL-4 and IL-13. Since both cytokines require the IL-4R receptor for signal transduction, this allows the dual inhibition of both IL-4 and IL-13 by specifically blocking the receptor IL-4R.
This study describes the design and synthesis of novel antagonistic variants of human IL-4. Chemical modification was used to target positions localized in IL-4 binding sites for γc and IL-13R1 but outside of the binding epitope for IL-4R. In contrast to existing studies, which used synthetic chemical compounds like polyethylene glycol for modification of IL-4, we employed glycan molecules as a natural alternative. Since glycosylation can improve important pharmacological parameters of protein therapeutics, such as immunogenicity and serum half-life, the introduced glycan molecules thus would not only confer a steric hindrance based inhibitory effect but simultaneously might improve the pharmacokinetic profile of the IL-4 antagonist.
For chemical conjugation of glycan molecules, IL-4 variants containing additional cysteine residues were produced employing prokaryotic, as well as eukaryotic expression systems. The thiol-groups of the engineered cysteines thereby allow highly specific modification. Different strategies were developed enabling site-directed coupling of amine- or thiol- functionalized monosaccharides to introduced cysteine residues in IL-4. A linker-based coupling procedure and an approach requiring phenylselenyl bromide activation of IL-4 thiol-groups were hampered by several drawbacks, limiting their feasibility. Surprisingly, a third strategy, which involved refolding of IL-4 cysteine variants in the presence of thiol- glycans, readily allowed synthesis of IL-4 glycoconjugates in form of mixed disulphides in milligram amount. This approach, therefore, has the potential for large-scale synthesis of IL-4 antagonists with highly defined glycosylation. Obtaining a homogenous glycoconjugate with exactly defined glycan pattern would allow using the attached glycan structures for fine-tuning of pharmacokinetic properties of the IL-4 antagonist, such as absorption and metabolic stability.
The IL-4 glycoconjugates generated in this work proved to be highly effective antagonists inhibiting IL-4 and/or IL-13 dependent responses in cell-based experiments and in in vitro binding studies. Glycoengineered IL-4 antagonists thus present valuable alternatives to IL-4 inhibitors used for treatment of atopic diseases such as the neutralizing anti-IL-4R antibody Dupilumab.
G-protein- coupled receptors (GPCRs) are the largest family of membrane confined receptors and they transduce ligand binding to downstream effects. Almost 40% of the drugs in the world target GPCRs due to their function, albeit knowing less about their activation. Understanding their dynamic behaviour in basal and activated state could prove key to drug development in the future. GPCRs are known to exhibit complex molecular mobility patterns. A plethora of studies have been and are being conducted to understand the mobility of GPCRs. Due to limitations of imaging and spectroscopic techniques commonly used, the relevant timescales are hard to access. The most commonly used techniques are electron paramagnetic resonance or double electronelectron resonance, nuclear magnetic resonance, time-resolved fluorescence, single particle tracking and fluorescence recovery after photobleaching. Among these techniques only fluorescence has the potential to probe live cells. In this thesis, I use different time-resolved fluorescence spectroscopic techniques to quantify diffusion dynamics / molecular mobility of β2-adrenergic receptor (β2-AR) in live cells. The thesis shows that β2-AR exhibits mobility over an exceptionally broad temporal range (nanosecond to second) that can be linked to its respective physiological scenario. I explain how β2-AR possesses surprisingly fast lateral mobility (~10 μm²/s) associated with vesicular transport in contrast to the prior reports of it originating from fluorophore photophysics and free fluorophores in the cytosol. In addition, β2-AR has rotational mobility (~100 μs) that makes it conform to the Saffman-Delbrück model of membrane diffusion unlike earlier studies. These contrasts are due to the limitations of the methodologies used. The limitations are overcome in this thesis by using different time-resolved fluorescence techniques of fluorescence correlation spectroscopy (FCS), time-resolved anisotropy (TRA) and polarisation resolved fullFCS (fullFCS). FCS is limited to microsecond to the second range and TRA is limited to the nanosecond range. fullFCS complements the two techniques by covering the blind spot of FCS and TRA in the microsecond range. Finally, I show how ligand stimulation causes a decrease in lateral mobility which could be a hint at cluster formation due to internalisation and how β2-AR possesses a basal oligomerisation that does not change on activation. Thus, through this thesis, I show how different complementary fluorescence techniques are necessary to overcome limitations of each technique and to thereby elucidate functional dynamics of GPCR activation and how it orchestrates downstream signalling.
Die Identifizierung endogener Stammzellen mit kardiogenem Potenzial und die Möglichkeit, deren Differenzierung zu steuern, würde einen Meilenstein in der kardioregenerativen Therapie darstellen. Innerhalb der Gefäßwand konnten unterschiedliche Stamm- und Vorläuferzellen identifiziert werden, die sog. Gefäßwand-residenten Stammzellen (VW-SCs). Zuletzt konnten aus CD34(+) VW-SCs, ohne genetische Manipulation, Kardiomyozyten generiert werden. Zusätzlich fungiert die Gefäßwand als Quelle inflammatorischer Zellen, die essenziell für die kardiogene Differenzierung der VW-SCs zu sein scheinen.
Ziel dieser Arbeit war es, das Verhalten von CD44(+) VW-SCs zu untersuchen, um herauszufinden, inwieweit dieser Stammzelltyp eine endogene Generierung von Kardiomyozyten unterstützen könnte. Dabei wurde mit infarzierten Mäuseherzen, dem Aortenringassay (ARA) und dem kardialen Angiogeneseassay (CAA) gearbeitet.
Sowohl in vivo in ischämischen Arealen infarzierter Mäuseherzen als auch ex vivo im CAA kam es zu einem signifikanten Anstieg von CD44(+) Zellen. Mittels Färbungen auf CD44 und Ki-67 konnte die Teilungsfähigkeit dieser Zellen demonstriert werden.
Ex vivo ließen sich aus CD44(+) Zellen F4/80(+) Makrophagen generieren. Die CD44(+) VW-SCs können sich dabei sowohl zu pro-inflammatorischen iNOS(+) M1- als auch zu anti-inflammatorischen IL-10(+) M2-Makrophagen differenzieren. Eine Modulation der kardialen Inflammation könnte einen entscheidenden Einfluss auf die Kardiomyogenese haben.
Unter VEGF-A kam es im CAA zu einer deutlichen Zunahme von CD44(+) Zellen. Unter Lenvatinib blieb das kardiale Sprouting gänzlich aus, die Anzahl der CD44(+) Zellen stagnierte und die VW-SCs verblieben in ihren physiologischen Nischen innerhalb der Gefäßwand.
Warum es nach einem MI kaum zu einer funktionellen Herzmuskelregeneration kommt, ist weiterhin unklar. Die therapeutische Beeinflussung koronaradventitieller CD44(+) VW-SCs und inflammatorischer Prozesse könnte dabei zukünftig eine wichtige therapeutische Option darstellen.
Die alveoläre Echinokokkose (AE), verursacht durch das Metacestoden- Larvenstadium des Fuchsbandwurms Echinococcus multilocularis (E. multilocularis), ist eine lebensbedrohliche Zoonose der nördlichen Hemisphäre mit eingeschränkten therapeutischen Möglichkeiten. Bei der Suche nach neuen Therapeutika haben Mitogen-activated Proteinkinase (MAPK) -Kaskaden als pharmakologische Zielstrukturen aufgrund ihrer essentiellen Rolle bei der Zellproliferation und -differenzierung ein großes Potenzial. In der vorliegenden Arbeit wurden durch BLAST- und reziproke BLAST-Analysen elf potenzielle MAPK Kinase Kinasen (MAP3K), fünf potenzielle MAPK Kinasen (MAP2K) und sechs potenzielle MAPK im E. multilocularis-Genom identifiziert, die teils hoch konserviert sind und in nahezu allen Entwicklungsstadien des Parasiten exprimiert werden. Diese Erkenntnisse lassen auf ein komplexes MAPK-Signaltransduktions- system in E. multilocularis mit großer Bedeutung für den Parasiten schließen. Transkriptomdatenanalysen und Whole Mount in Situ Hybridisierung (WMISH) zeigten, dass emmkkk1 (EmuJ_000389600) als einzige MAP3K neben der Expression in postmitotischen Zellen in besonderem Maße in proliferativen Stammzellen des Parasiten exprimiert wird und somit eine wichtige Rolle bei der Differenzierung von Stammzellen spielen könnte. In Yeast-Two-Hybrid (Y2H) -Wechselwirkungsassays wurden Interaktionen von mehreren upstream- (EmGRB2) und downstream- wirkenden Signalkaskadekomponenten des JNK (EmMKK3, EmMPK3) und ERK (EmMKK3, EmMPK4) -Signalwegs gefunden. Daraus lässt sich schließen, dass EmMKKK1, analog zu seinem humanen Homolog HsM3K1, eine zentrale Rolle bei der Echinococcus-Wachstumsregulation durch Rezeptortyrosinkinasen und vielfältige weitere Funktionen im Parasiten besitzt. Anhand von Erkenntnissen an Platyhelminthes kann daher von einem großen Potenzial dieser neu charakterisierten Signalwege als chemotherapeutische Angriffspunkte ausgegangen werden, wenngleich erste RNA-Interferenz (RNAi)- und Inhibitorstudien an emmkkk1, emmpk1 und emmpk4 keine durchschlagenden Effekte auf das Überleben von Primärzellkulturen und die Bildung von Metacestodenvesikeln zeigten. Zusammenfassend konnte in der vorliegenden Arbeit mit EmMKKK1 und neuen ERK- und JNK-Signalwegen zentrale Komponenten der komplexen MAPK-Signalkaskaden in E. multilocularis identifiziert werden, die höchstwahrscheinlich einen großen Beitrag zur enormen Regenerationsfähigkeit der Echinococcus-Stammzellen leisten und vom Wirt abgeleitete Signale wie Insulin, Epidermaler Wachstumsfaktor (EGF) und Fibroblasten-Wachstumsfaktor (FGF) über EmGRB2 in Proliferationsnetzwerke des Parasiten integrieren. Arzneimittel-Screening-Assays, die auf diese Signalwege abzielen, könnten daher zu alternativen Arzneimitteln führen, die alleine oder in Kombination mit einer bestehenden Chemotherapie (Benzimidazol) die Prognose von für AE-Patienten verbessern könnten.