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The pancreas is the key organ for the maintenance of euglycemia. This is regulated in particular by α-cell-derived glucagon and β-cell-derived insulin, which are released in response to nutrient deficiency and elevated glucose levels, respectively. Although glucose is the main regulator of insulin secretion, it is significantly enhanced by various potentiators.
Platelets are anucleate cell fragments in the bloodstream that are essential for hemostasis to prevent and stop bleeding events. Besides their classical role, platelets were implemented to be crucial for other physiological and pathophysiological processes, such as cancer progression, immune defense, and angiogenesis. Platelets from diabetic patients often present increased reactivity and basal activation. Interestingly, platelets store and release several substances that have been reported to potentiate insulin secretion by β-cells. For these reasons, the impact of platelets on β-cell functioning was investigated in this thesis.
Here it was shown that both glucose and a β-cell-derived substance/s promote platelet activation and binding to collagen. Additionally, platelet adhesion specifically to the microvasculature of pancreatic islets was revealed, supporting the hypothesis of their influence on glucose homeostasis. Genetic or pharmacological ablation of platelet functioning and platelet depletion consistently resulted in reduced insulin secretion and associated glucose intolerance. Further, the platelet-derived lipid fraction was found to enhance glucose-stimulated insulin secretion, with 20-hydroxyeicosatetraenoic acid (20-HETE) and possibly also lyso-precursor of platelet-activating factor (lysoPAF) being identified as crucial factors. However, the acute platelet-stimulated insulin secretion was found to decline with age, as did the levels of platelet-derived 20-HETE. In addition to their direct stimulatory effect on insulin secretion, specific defects in platelet activation have also been shown to affect glucose homeostasis by potentially influencing islet vascular development. Taking together, the results of this thesis suggest a direct and indirect mechanism of platelets in the regulation of insulin secretion that ensures glucose homeostasis, especially in young individuals.
Sepsis ist ein häufiges und akut lebensbedrohliches Syndrom, das eine Organfunktionsstörung in Folge einer dysregulierten Immunantwort auf eine Infektion beschreibt. Eine frühzeitige Diagnosestellung und Therapieeinleitung sind von zentraler Bedeutung für das Überleben der Patient:innen. In einer Pilotstudie konnte unsere Forschungsgruppe mittels Durchflusszytometrie eine ausgeprägte Hyporeaktivität der Thrombozyten bei Sepsis nachweisen, die einen potenziell neuen Biomarker zur Sepsis-Früherkennung darstellt. Zur Evaluation des Ausmaßes und Entstehungszeitpunktes der detektierten Thrombozytenfunktionsstörung wurden im Rahmen der vorliegenden Arbeit zusätzlich zu Patient:innen mit Sepsis (SOFA-Score ≥ 2; n=13) auch hospitalisierte Patient:innen mit einer Infektion ohne Sepsis (SOFA-Score < 2; n=12) rekrutiert. Beide Kohorten wurden zu zwei Zeitpunkten (t1: <24h; t2: Tag 5-7) im Krankheitsverlauf mittels Durchflusszytometrie und PFA-200 untersucht und mit einer gesunden Kontrollgruppe (n=28) verglichen.
Phänotypische Auffälligkeiten der Thrombozyten bei Sepsis umfassten: (i) eine veränderte Expression verschiedener Untereinheiten des GPIb-IX-V-Rezeptorkomplexes, die auf ein verstärktes Rezeptor-Shedding hindeutet; (ii) ein ausgeprägtes Mepacrin-Beladungsdefizit, das auf eine zunehmend reduzierte Anzahl von δ-Granula entlang des Infektion-Sepsis Kontinuums hinweist; (iii) eine Reduktion endständig gebundener Sialinsäure im Sinne einer verstärkten Desialylierung. Die funktionelle Analyse der Thrombozyten bei Sepsis ergab bei durchflusszytometrischer Messung der Integrin αIIbβ3-Aktivierung (PAC-1-Bindung) eine ausgeprägte generalisierte Hyporeaktivität gegenüber multiplen Agonisten, die abgeschwächt bereits bei Infektion nachweisbar war und gemäß ROC-Analysen gut zwischen Infektion und Sepsis diskriminierte (AUC >0.80 für alle Agonisten). Im Gegensatz dazu zeigten Thrombozyten bei Sepsis und Analyse mittels PFA-200 unter Einfluss physiologischer Scherkräfte eine normale bis gar beschleunigte Aggregation.
Die Reaktivitätsmessung von Thrombozyten mittels Durchflusszytometrie stellt weiterhin einen vielversprechenden Biomarker für die Sepsis-Früherkennung dar. Für weitere Schlussfolgerungen ist jedoch eine größere Kohorte erforderlich. In nachfolgenden Untersuchungen sollten zudem mechanistische Ursachen der beschriebenen phänotypischen und funktionellen Auffälligkeiten von Thrombozyten bei Infektion und Sepsis z.B. mittels Koinkubationsexperimenten untersucht werden.
Platelets play an important role in haemostasis by mediating blood clotting at sites of blood vessel damage. Platelets, also participate in pathological conditions including thrombosis and inflammation. Upon vessel damage, two glycoprotein receptors, the GPIb-IX-V complex and GPVI, play important roles in platelet capture and activation.
GPIb-IX-V binds to von Willebrand factor and GPVI to collagen. This initiates a signalling cascade resulting in platelet shape change and spreading, which is dependent on the actin cytoskeleton. This thesis aimed to develop and implement different super-resolution microscopy techniques to gain a deeper understanding of the conformation and location of these receptors in the platelet plasma membrane, and to provide insights into their signalling pathways. We suggest direct stochastic optical reconstruction microscopy (dSTORM) and structured illumination microscopy (SIM) as the best candidates for imaging single platelets, whereas expansion microscopy (ExM) is ideal for imaging platelets aggregates.
Furthermore, we highlighted the role of the actin cytoskeleton, through Rac in GPVI signalling pathway. Inhibition of Rac, with EHT1864 in human platelets induced GPVI and GPV, but not GPIbα shedding. Furthermore, EHT1864 treatment did not change GPVI dimerisation or clustering, however, it decreased phospholipase Cγ2 phosphorylation levels, in human, but not murine platelets, highlighting interspecies differences. In summary, this PhD thesis demonstrates that; 1) Rac alters GPVI signalling pathway in human but not mouse platelets; 2) our newly developed ExM protocol can be used to image platelet aggregates labelled with F(ab’) fragments
Platelets have a key physiological role in haemostasis however, inappropriate thrombus formation can lead to cardiovascular diseases such as myocardial infarction or stroke. Although, such diseases are common worldwide there are comparatively few anti-platelet drugs, and these are associated with an increased risk of bleeding. Platelets also have roles in thrombo-inflammation, immuno-thrombosis and cancer, in part via C-type lectin-like receptor 2 (CLEC-2) and its ligand podoplanin. Although CLEC-2 contributes to these diseases in mice, as well as to thrombus stability, it is unclear whether CLEC-2 has similar roles in humans, particularly as human CLEC-2 (hCLEC-2) cannot be investigated experimentally in vivo.
To investigate hCLEC-2 in vivo, we generated a humanised CLEC-2 mouse (hCLEC-2KI) model, as well as a novel monoclonal antibody, HEL1, that binds to a different site than an existing antibody, AYP1. Using these antibodies, we have provided proof of principle for the use of hCLEC-2KI mice to test potential therapeutics targeting hCLEC-2, and shown for the first time that hCLEC-2 can be immunodepleted, with little effect on haemostasis. However, our results have also suggested that there are species differences in the role of CLEC-2 in arterial thrombosis. We further confirmed this using human blood where blocking CLEC-2 ligand binding had no effect on thrombosis, whereas we confirmed a minor role for mouse CLEC-2 in thrombus stability. We also investigated the effect of blocking CLEC-2 signalling using the Bruton’s tyrosine kinase inhibitor PRN473 on CLEC-2 mediated immuno-thrombosis in a Salmonella typhimurium infection model. However, no effect on thrombosis was observed suggesting that CLEC-2 signalling is not involved.
Overall, our results suggest that there may be differences in the role of human and mouse CLEC-2, at least in arterial thrombosis, which could limit the potential of CLEC-2 as an anti-thrombotic target. However, it appears that the interaction between CLEC-2 and podoplanin is conserved and therefore CLEC-2 could still be a therapeutic target in immuno-thrombosis, thrombo-inflammation and cancer. Furthermore, any potential human specific therapeutics could be investigated in vivo using hCLEC-2KI mice.
Every year, stroke affects over 100 million people worldwide and the number of cases continues to grow. Ischemic stroke is the most prevalent form of stroke and rapid restoration of blood flow is the primary therapeutic aim. However, recanalization might fail or reperfusion itself induces detrimental processes leading to infarct progression. Previous studies identified platelets and immune cells as drivers of this so-called ischemia/reperfusion (I/R) injury, establishing the concept of ischemic stroke as thrombo-inflammatory disease. Reduced cerebral blood flow despite recanalization promoted the hypothesis that thrombus formation within the cerebral microcirculation induces further tissue damage. The results presented in this thesis refute this: using complementary methodologies, it was shown that infarct growth precedes the occurrence of thrombi excluding them as I/R injury-underlying cause. Blood brain barrier disruption is one of the hallmarks of ischemic stroke pathology and was confirmed as early event during reperfusion injury in the second part of this study. Abolished platelet α-granule release protects mice from vascular leakage in the early reperfusion phase resulting in smaller infarcts. Using in vitro assays, platelet α-granule-derived PDGF-AB was identified as one factor contributing to blood-brain barrier disruption.
In vivo visualization of platelet activation would provide important insights in the spatio-temporal context of platelet activation in stroke pathology. As platelet signaling results in elevated intracellular Ca2+ levels, this is an ideal readout. To overcome the limitations of chemical calcium indicators, a mouse line expressing an endogenous calcium reporter specifically in platelets and megakaryocytes was generated. Presence of the reporter did not interfere with platelet function, consequently these mice were characterized in in vivo and ex vivo models.
Upon ischemic stroke, neutrophils are among the first cells that are recruited to the brain. Since for neutrophils both, beneficial and detrimental effects are described, their role was investigated within this thesis. Neither neutrophil depletion nor absence of NADPH-dependent ROS production (Ncf-/- mice) affected stroke outcome. In contrast, abolished NET-formation in Pad4-/- mice resulted in reduced infarct sizes, revealing detrimental effects of NETosis in the context of ischemic stroke, which might become a potential therapeutic target.
Cerebral venous (sinus) thrombosis, CV(S)T is a rare type of stroke with mainly idiopathic onset. Whereas for arterial thrombosis a critical contribution of platelets is known and widely accepted, for venous thrombosis this is less clear but considered more and more. In the last part of this thesis, it was shown that fab-fragments of the anti-CLEC-2 antibody INU1 trigger pathological platelet activation in vivo, resulting in foudroyant CVT accompanied by heavy neurological symptoms. Using this novel animal model for CVT, cooperative signaling of the two platelet receptors CLEC-2 and GPIIb/IIIa was revealed as major trigger of CVT and potential target for treatment.
Short functional peptidic probes can maximize the potential of high-end microscopy techniques and multiplex imaging assays and provide new insights into normal and aberrant molecular, cellular and tissue function. Particularly, the visualization of inhibitory synapses requires protocol tailoring for different sample types and imaging techniques and relies either on genetic manipulation or on antibodies that underperform in tissue immunofluorescence. Starting from an endogenous activity-related ligand of gephyrin, a universal marker of the inhibitory post-synapse, I developed a short peptidic multivalent binder with exceptional affinity and selectivity to gephyrin. By tailoring fluorophores to the binder, I have obtained Sylite, a probe for the visualization of inhibitory synapses, with an outstanding signal-to-background ratio, that bests the “gold standard” gephyrin antibodies both in selectivity and in tissue immunofluorescence. In tissue Sylite benefits from simplified handling, provides robust synaptic labeling in record-short time and, unlike antibodies, is not affected by staining artefacts. In super-resolution microscopy Sylite precisely localizes the post-synapse and enables accurate pre- to post-synapse measurements. Combined with complimentary tracing techniques Sylite reveals inhibitory connectivity and profiles inhibitory inputs and synapse sizes of excitatory and inhibitory neurons in the periaqueductal gray brain region. Lastly, upon probe optimization for live cell application and with the help of novel thiol-reactive cell penetrating peptide I have visualized inhibitory synapses in living neurons. Taken together, my work provided a versatile probe for conventional and super-resolution microscopy and a workflow for the development and application of similar compact functional synthetic probes.
Ubiquitylation is a protein post translational modification, in which ubiquitin is covalently attached to target protein substrates resulting in diverse cellular outcomes. Besides ubiquitin, various ubiquitin-like proteins including FAT10 exist, which are also conjugated to target proteins. The underlying modification mechanisms are conserved. In the initial step, ubiquitin or a ubiquitin-like protein is thioester-linked to a catalytic cysteine in the E1activating enzyme in an ATP-dependent manner. The respective protein modifier is then transferred to an E2 conjugating enzyme in a transthioesterification reaction. Finally, an E3 ubiquitin ligase E3 catalyzes the covalent attachment of the protein modifier to a substrate. In the case of ubiquitin, multiple ubiquitin molecules can be attached to a substrate in the form of either linear or branched polyubiquitin chains but also as single ubiquitin modifications. Depending on the nature of the ubiquitin chain, the substrates are destined to various cellular processes such as their targeted destruction by the proteasome but also non-degradative outcomes may occur.
As stated above FAT10 is a ubiquitin-like protein modifier which typically targets proteins for proteasomal degradation. It consists of two ubiquitin-like domains and is mainly expressed in cells of the human immune system. The reported involvement of FAT10 modifications in cancers and other diseases has caught the attention of the scientific community as an inhibition of the FAT10ylation process may provide avenues for novel therapeutic approaches. UBA6 is the E1 activating enzyme that resides at the apex of the FAT10 proteasomal degradation pathway. UBA6 not only recognizes FAT10 but can also activate ubiquitin as efficiently as the ubiquitin specific E1 UBA1. The dual specificity of UBA6 may complicate the inhibition FAT10ylation since targeting the active site of UBA6 will also inhibit the UBA6-catalyzed ubiquitin activation. Therefore, it is important to understand the underlying principles for the dual specificity of UBA6 prior to the development of compounds interfering with FAT10ylation.
In this thesis important novel insights into the structure and function of UBA6 were derived by X-ray crystallography and biochemical methods. The first crystal structure of UBA6 reveals the multidomain architecture of this enzyme in atomic detail. The enzyme is composed of a rigid core including its active and inactive adenylation domains as well as a 4 helix bundle. Overall, the molecule adopts a “Y” shape architecture with the core at the base and the first and second catalytic half domains forming one arm of the “Y” and the ubiquitin fold domain constituting the other arm. While UBA6 shares the same domain architecture as UBA1, substantial differences were revealed by the crystal structure. In particular, the first catalytic half domain undergoes a significant shift to a position more distal from the core. This rigid body movement is assumed to generate room to accommodate the second ubiquitin-like domain of FAT10. Differences are also observed in a hydrophobic platform between the core and the first catalytic half domain and the adenylation active site in the core, which together from the binding sites for ubiquitin and FAT10. Site directed mutagenesis of key residues in these areas altered the UBA6-catalyzed activation of ubiquitin and FAT10. UBA6 variants were generated with the goal of trying to block the activation of FAT10 while still maintaining that of ubiquitin activation, in order to fully explain the dual specificity of UBA6. However, none of these mutations could block the activation of FAT10, while some of these UBA6 variants blocked ubiquitin activation. Preliminary inhibition assays with a group of E1 inhibitors belonging to the adenosyl sulfamate family demonstrated potent inhibition of FAT10ylation for two compounds. The dual specificity of UBA6 hence needs to be further examined by biochemical and structural methods. In particular, the structure of a complex between UBA6 and ubiquitin or FAT10 would provide key insights for further biochemical studies, ultimately allowing the targeted inhibition of the FAT10ylation machinery.
The nervous system relies on an orchestrated assembly of complex cellular entities called neurons, which are specifically committed to information management and transmission. Inter-neuronal communication takes place via synapses, membrane-membrane junctions which ensure efficient signal transfer. Synaptic neurotransmission involves release of presynaptic neurotransmitters and their reception by cognate receptors at postsynaptic terminals. Inhibitory neurotransmission is primarily mediated by the release of neurotransmitters GABA (γ-Aminobutyric acid) and glycine, which are precisely sensed by GABA type-A receptors (GABAARs) and glycine receptors (GlyRs), respectively. GABAAR assembly and maintenance is coordinated by various postsynaptic neuronal factors including the scaffolding protein gephyrin, the neuronal adaptor collybistin (CB) and cell adhesion proteins of the neuroligin (NL) family, specifically NL2 and NL4.
At inhibitory postsynaptic specializations, gephyrin has been hypothesized to form extended structures underneath the plasma membrane, where its interaction with the receptors leads to their stabilization and impedes their lateral movement. Gephyrin mutations have been associated with various brain disorders, including autism, schizophrenia, Alzheimer’s disease, and epilepsy. Furthermore, gephyrin loss is lethal and causes mice to die within the first post-natal day. Gephyrin recruitment from intracellular deposits to postsynaptic membranes primarily relies on the adaptor protein CB.
As a moonlighting protein, CB, a guanine nucleotide exchange factor (GEF), also catalyzes a nucleotide exchange reaction, thereby regenerating the GTP-bound state of the small GTPase Cdc42 from its GDP-bound form. The CB gene undergoes alternative splicing with the majority of CB splice variants featuring an N-terminal SH3 domain followed by tandem Dbl-homology (DH) and pleckstrin-homology (PH) domains. Previous studies demonstrated that the most widely expressed, SH3-domain containing splice variant (CB2SH3+) preferentially adopts a closed conformation, in which the N-terminally located SH3 domain forms intra-molecular interaction with the DH-PH domain tandem. Previous cell-based studies indicated that SH3 domain-encoding CB variants remain untargeted and colocalize with intracellular gephyrin deposits and hence require additional factors which interact with the SH3 domain, thus inducing an open or active conformation. The SH3 domain-deficient CB isoform (CB2SH3-), on the contrary, adopts an open conformation, which possess enhanced postsynaptic gephyrin-clustering and also effectively replenishes the GTP-bound small GTPase-Cdc42 from its GDP-bound state.
Despite the fundamental role of CB as a neuronal adaptor protein maintaining the proper function of inhibitory GABAergic synapses, its interactions with the neuronal scaffolding protein gephyrin and other post synaptic neuronal factors remain poorly understood. Moreover, CB interaction studies with the small GTPase Cdc42 and TC10, a closely related member of Cdc42 subfamily, remains poorly characterized. Most importantly, the roles of the neuronal factors and small GTPases in CB conformational activation have not been elucidated.
This PhD dissertation primarily focuses on delineating the molecular basis of the interactions between CB and postsynaptic neuronal factors. During the course of my PhD dissertation, I engineered a series of CB FRET (Förster Resonance Energy Transfer) sensors to characterize the CB interaction with its binding partners along with outlining their role in CB conformational activation. Through the aid of these CB FRET sensors, I analyzed the gephyrin-CB interaction, which, due to technical limitations remained unaddressed for more than two decades (refer Chapter 2 for more details). Subsequently, I also unraveled the molecular basis of the interactions between CB and the neuronal cell adhesion factor neuroligin 2 (refer chapter 2) and the small GTPases Cdc42 and TC10 (refer chapter 3) and describe how these binding partners induce a conformational activation of CB.
In summary, this PhD dissertation provides strong evidence of a closely knit CB communication network with gephyrin, neuroligin and the small GTPase TC10, wherein CB activation from closed/inactive to open/active states is effectively triggered by these ligands.
Platelets play an important role in the body, since they are part of the hemostasis
system, preventing and stopping blood loss. Nevertheless, when platelet or
coagulation system function are impaired, uncontrolled bleedings but also irreversible
vessel occlusion followed by ischemic tissue damage can occur. Therefore,
understanding platelet function and activation, mechanisms which are controlled by a
variety of platelet membrane receptors and other factors is important to advance out
knowledge of hemostasis and platelet malfunction. For a complete picture of platelet
function and their modulating behavior it is desired to be able to quantify receptor
distributions and interactions of these densely packed molecular ensembles in the
membrane. This challenges scientists for several reasons. Most importantly, platelets
are microscopically small objects, challenging the spatial resolution of conventional
light microscopy. Moreover, platelet receptors are highly abundant on the membrane
so even super-resolution microscopy struggles with quantitative receptor imaging on
platelets.
With Expansion microscopy (ExM), a new super-resolution technique was introduced,
allowing resolutions to achieve super-resolution without using a super-resolution
microscope, but by combining a conventional confocal microscopy with a highly
processed sample that has been expanded physically. In this doctoral thesis, I
evaluated the potential of this technique for super-resolution platelet imaging by
optimizing the sample preparation process and establishing an imaging and image
processing pipeline for dual-color 3D images of different membrane receptors. The
analysis of receptor colocalization using ExM demonstrated a clear superiority
compared to conventional microscopy. Furthermore, I identified a library of
fluorescently labeled antibodies against different platelet receptors compatible with
ExM and showed the possibility of staining membrane receptors and parts of the
cytoskeleton at the same time.
This decade saw the development of new high-end light microscopy approaches. These technologies are increasingly used to expand our understanding of cellular function and the molecular mechanisms of life and disease. The precision of state-of-the-art super resolution microscopy is limited by the properties of the applied fluorescent label. Here I describe the synthesis and evaluation of new functional fluorescent probes that specifically stain gephyrin, universal marker of the neuronal inhibitory post-synapse. Selected probe precursor peptides were synthesised using solid phase peptide synthesis and conjugated with selected super resolution capable fluorescent dyes. Identity and purity were defined using chromatography and mass spectrometric methods. To probe the target specificity of the resulting probe variants in cellular context, a high-throughput assay was established. The established semi-automated and parallel workflow was used for the evaluation of three selected probes by defining their co-localization with the expressed fluorescent target protein. My work provided NN1Dc and established the probe as a visualisation tool for essentially background-free visualisation of the synaptic marker protein gephyrin in a cellular context. Furthermore, NN1DA became part of a toolbox for studying the inhibitory synapse ultrastructure and brain connectivity and turned out useful for the development of a label-free, high-throughput protein interaction quantification assay.
Stroke and myocardial infarction are the most prominent and severe consequences of pathological thrombus formation. For prevention and/or treatment of thrombotic events there is a variety of anti-coagulation and antiplatelet medication that all have one side effect in common: the increased risk of bleeding. To design drugs that only intervene in the unwanted aggregation process but do not disturb general hemostasis, it is crucial to decipher the exact clotting pathway which has not been fully understood yet. Platelet membrane receptors play a vital role in the clotting pathway and, thus, the aim of this work is to establish a method to elucidate the interactions, clustering, and reorganization of involved membrane receptors such as GPIIb/IIIa and GPIX as part of the GPIb-IX-V complex. The special challenges regarding visualizing membrane receptor interactions on blood platelets are the high abundancy of the first and the small size of the latter (1—3µm of diameter). The resolution limit of conventional fluorescence microscopy and even super-resolution approaches prevents the successful differentiation of densely packed receptors from one another. Here, this issue is approached with the combination of a recently developed technique called Expansion Microscopy (ExM). The image resolution of a conventional fluorescence microscope is enhanced by simply enlarging the sample physically and thus pulling the receptors apart from each other. This method requires a complex sample preparation and holds lots of obstacles such as variable or anisotropic expansion and low images contrast. To increase ExM accuracy and sensitivity for interrogating blood platelets, it needs optimized sample preparation as well as image analysis pipelines which are the main part of this thesis. The colocalization results show that either fourfold or tenfold expanded, resting platelets allow a clear distinction between dependent, clustered, and independent receptor organizations compared to unexpanded platelets.Combining dual-color Expansion and confocal fluorescence microscopy enables to image in the nanometer range identifying GPIIb/IIIa clustering in resting platelets – a pattern that may play a key role in the clotting pathway
Protein-DNA interactions are central to many biological processes and form the bedrock of gene transcription, DNA replication, and DNA repair processes. Many proteins recognize specific sequences in DNA- a restriction enzyme must only cut at the correct sequence and a transcription factor should bind at its consensus sequence. Some proteins are designed to bind to specific structural or chemical features in DNA, such as DNA repair proteins and some DNA modifying enzymes. Target-specific DNA binding proteins initially bind to non-specific DNA and then search for their target sites through different types of diffusion mechanisms. Atomic force microscopy (AFM) is a single-molecule technique that is specifically well-suited to resolve the distinct states of target-specific as well as nonspecific protein-DNA interactions that are vital for a deeper insight into the target site search mechanisms of these enzymes. In this thesis, protein systems involved in epigenetic regulation, base excision repair (BER), and transcription are investigated by single-molecule AFM analyses complemented by biochemical and biophysical experiments.
The first chapter of this thesis narrates the establishment of a novel, user-unbiased MatLab-based tool for automated DNA bend angle measurements on AFM data. This tool has then been employed to study the initial lesion detection step of several DNA glycosylases. These results promoted a model describing the altered plasticities of DNA at the target lesions of DNA glycosylases as the fundamental mechanism for their enhanced efficiency of lesion detection.
In the second chapter of this thesis, the novel automated tool has been further extended to provide protein binding positions on the DNA along with corresponding DNA bend angles and applied to the study of DNMT3A DNA methyltransferase. These AFM studies revealed preferential co-methylation at specific, defined distances between two CpG sites by the enzyme and when combined with biochemical analyses and structural modelling supported novel modes of CpG co-methylation by DNMT3A.
In the third chapter of this thesis, the role of 8-oxo-guanine glycosylase (hOGG1) in Myc-mediated transcription initiation has been investigated. AFM analyses revealed that in the presence of oxidative damage in DNA, Myc is recruited to its target site (E-box) by hOGG1 through direct protein-protein interactions, specifically under oxidizing conditions. Intriguingly, oxidation of hOGG1 was further observed to result in dimerization of hOGG1, which may also play a role in the mechanism of transcription regulation by hOGG1 under oxidative stress.
Protein kinase D2 drives chylomicron-mediate lipid transport in the intestine and promotes obesity
(2022)
Obesity and associated metabolic syndrome are growing concerns in modern society due to the negative consequences for human health and well-being. Cardiovascular diseases and type 2 diabetes are only some of the pathologies associated to overweight. Among the main causes are decreased physical activity and food availability and composition. Diets with high content of fat are energy-dense and their overconsumption leads to an energy imbalance, which ultimately promotes energy storage as fat and obesity. Aberrant activation of signalling cascades and hormonal imbalances are characteristic of this disease and members of the Protein Kinase D (PKD) family have been found to be involved in several mechanisms mediating metabolic homeostasis. Therefore, we aimed to investigate the role of Protein Kinase D2 (PKD2) in the regulation of metabolism. Our investigation initiated with a mice model for global PKD2 inactivation, which allowed us to prove a direct involvement of this kinase in lipids homeostasis and obesity. Inactivation of PKD2 protected the mice from high-fat diet-induced obesity and improved their response to glucose, insulin and lipids. Furthermore, the results indicated that, even though there were no changes in energy intake or expenditure, inactivation of PKD2 limited the absorption of fat from the intestine and promoted energy excretion in feces. These results were verified in a mice model for specific deletion of intestinal PKD2. These mice not only displayed an improved metabolic fitness but also a healthier gut microbiome profile. In addition, we made use of a small-molecule inhibitor of PKD in order to prove that local inhibition of PKD2 in the intestine was sufficient to inhibit lipid absorption. The usage of the inhibitor not only protected the mice from obesity but also was efficient in avoiding additional body-weight gain after obesity was pre-established in mice. Mechanistically, we determined that PKD2 regulates lipids uptake in enterocytes by phosphorylation of Apolipoprotein A4 (APOA4) and regulation of chylomicron-mediated triglyceride absorption. PKD2 deletion or inactivation increased abundance of APOA4 and decreased the size of chylomicrons and therefore lipids absorption from the diet. Moreover, intestinal activation of PKD2 in human obese patients correlated with higher levels of triglycerides in circulation and a detrimental blood profile. In conclusion, we demonstrated that PKD2 is a key regulator of dietary fat absorption in murine and human context, and its inhibition might contribute to the treatment of obesity.
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.
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.
The small protein modifier ubiquitin is at the heart of an immensely versatile posttranslational modification system that orchestrates countless physiological and disease-associated cellular processes. Key to this versatility are the manifold modifications that can be assembled from ubiquitin “building blocks” and are associated with specific functional outcomes for the modified substrates. In particular, ubiquitin molecules can form polymeric chains of distinct lengths and linkage types that give rise to distinct chain conformations, thereby providing recognition sites for specific signaling receptors/effectors. The class of E3 enzymes (ubiquitin ligases) provides critical specificity determinants in ubiquitin linkage formation; it is therefore crucial to unravel precisely how E3 enzymes operate in order to understand the structural basis of ubiquitin signaling and exploit these insights for therapeutic benefit.
Overexpression and deregulation of the HECT-type ubiquitin ligase HUWE1 is implicated in several different cancer types and neurodegenerative disorders. It is largely unknown which factors control the ubiquitin modifications formed by HUWE1, how the catalytic HECT domain interacts with functionally distinct ubiquitin molecules (donor, acceptor and regulatory ubiquitin molecules) and which conformational transitions enable these interactions during ubiquitin chain formation.
One aim of this study was to structurally elucidate the recognition of donor ubiquitin by the HECT domain of HUWE1. To this end I utilized a ubiquitin activity-based probe to reconstitute a proxy for a donor ubiquitin-linked conjugate of the HECT domain of HUWE1 and determined its structure by X-ray crystallography. This structure reveals that the donor ubiquitin binds to the C-lobe of HUWE1 in the same way as NEDD4-type ligases, corroborating the idea that HECT ligases utilize a conserved mode of donor ubiquitin recognition. independent of their linkage and substrate specificities. With the help of biochemical analyses, I also validated specific features of the structure, in particular the positioning of the C-terminal tail of the ligase, which was known to be critical for activity. In the newly determined structure, which reflects an “L-shaped”, active state of the HECT domain, this tail is fully resolved and coordinated at the N-lobe-C-lobe interface. I defined residues that are critical for this coordination and showed that they are also essential for the activity of HUWE1, including auto-ubiquitination, free ubiquitin chain formation, and substrate ubiquitination.
Furthermore, I discovered that the N-lobe of HUWE1 harbors a ubiquitin-binding exosite similar to NEDD4-type ligases and E6AP. My in-vitro activity and binding assays show that HUWE1 uses the exosite for isopeptide bond formation, but that it is dispensable for thioester bond formation. The binding assays further show that the donor ubiquitin loaded HECT domain binds an additional ubiquitin molecule at the exosite more tightly than the apo HECT domain, which possibly suggests allosteric communication between the two sites.
Finally, I showed that the ubiquitin activity-based probe (ubiquitin-propargylamine) can label the catalytic cysteine of HUWE1 and NEDD4-type with close to quantitative turn- over, while it does not react with the HECT domain of the evolutionarily more divergent E6AP. The determinants underlying these differential reactivities remain to be explored.
Taken, together my results significantly enhance our mechanistic understanding of the catalytic domain of HUWE1 and pinpoint linchpins for therapeutic interventions with the activity of this disease-relevant enzyme.
Obesity-induced diabetes affects over 400 million people worldwide. Obesity is a complex metabolic disease and is associated with several co-morbidities, all of which negatively affect the individual’s quality of life. It is commonly considered that obesity is a result of a positive energy misbalance, as increased food intake and lower expenditure eventually lead to the development of this disease. Moreover, the pathology of obesity is attributed to several genetic and epigenetic factors that put an individual at high risk compared to another. Adipose tissue is the main site of the organism’s energy storage. During the time when the nutrients are available in excess, adipocytes acquire triglycerides, which are released during the time of food deprivation in the process of lipolysis (free fatty acids and glycerol released from adipocytes). Uncontrolled lipolysis is the consequent event that contributes to the development of diabetes and paradoxically obesity. To identify the genetic factors aiming for future therapeutic avenues targeting this pathway, we performed a high-throughput screen and identified the Extracellular-regulated kinase 3 (ERK3) as a hit. We demonstrate that β-adrenergic stimulation stabilizes ERK3 leading to the formation of a complex with the co-factor MAP kinase-activated protein kinase 5 (MK5) thereby driving lipolysis. Mechanistically, we identify a downstream target of the ERK3/MK5 pathway, the transcription factor FOXO1, which promotes the expression of the major lipolytic enzyme ATGL. Finally, we provide evidence that targeted deletion of ERK3 in mouse adipocytes inhibits lipolysis, but elevates energy dissipation, promoting lean phenotype and ameliorating diabetes. Moreover, we shed the light on our pharmacological approach in targeting ERK3/MK5 pathways using MK5 specific inhibitor. Already after 1 week of administering the inhibitor, mice showed signs of improvement of their metabolic fitness as showed here by a reduction in induced lipolysis and the elevation in the expression of thermogenic genes. Taken together, our data suggest that targeting the ERK3/MK5 pathway, a previously unrecognized signaling axis in adipose tissue, could be an attractive target for future therapies aiming to combat obesity-induced diabetes.
Platelets, small anucleate cell fragments in the blood stream, derive from large precursor cells, so-called megakaryocytes (MK) residing in the bone marrow (BM). In addition to their role in wound healing, platelets have been shown to play a significant role during inflammatory bleeding. Above all, the immunoreceptor tyrosine-based activation motif (ITAM) receptors GPVI as well as CLEC-2 have been identified as main regulators of vascular integrity.
In addition to ITAM-bearing receptors, our group identified GPV as another potent regulator of hemostasis and thrombosis. Surprisingly, concomitant lack of GPV and CLEC-2 deteriorated blood-lymphatic misconnections observed in Clec2-/- mice resulting in severe edema formation and intestinal inflammation. Analysis of lymphatic and vascular development in embryonic mesenteries revealed severely defective blood-lymph-vessel separation, which translated into thrombocytopenia and increased vascular permeability due to reduced tight junction density in mesenteric blood vessels and consequent leakage of blood into the peritoneal cavity.
Recently, platelet granule release has been proposed to ameliorate the progression of retinopathy of prematurity (ROP), a fatal disease in newborns leading to retinal degradation. The mechanisms governing platelet activation in this process remained elusive nonetheless, which prompted us to investigate a possible role of ITAM signaling. In the second part of this thesis, granule release during ROP was shown to be GPVI- and partly CLEC-2-triggered since blockade or loss of these receptors markedly deteriorated ROP progression.
Proplatelet formation from MKs is highly dependent on a functional microtubule and actin cytoskeleton, the latter of which is regulated by several actin-monomer binding proteins including Cofilin1 and Twinfilin1 that have been associated with actin-severing at pointed ends. In the present study, a redundancy between both proteins especially important for the guided release of proplatelets into the bloodstream was identified, since deficiency in both proteins markedly impaired MK functionality mainly due to altered actin-microtubule crosstalk.
Besides ITAM-triggered activation, platelets and MKs are dependent on inhibitory receptors, which prevent overshooting activation. We here identified macrothrombocytopenic mice with a mutation within Mpig6b encoding the ITIM-bearing receptor G6b-B. G6b-B-mutant mice developed a severe myelofibrosis associated with sex-specific bone remodeling defects resulting in osteosclerosis and -porosis in female mice. Moreover, G6b-B was shown to be indispensable for MK maturation as verified by a significant reduction in MK-specific gene expression in G6b-B-mutant MKs due to reduced GATA-1 activity.
The liver plays a pivotal role in maintaining energy homeostasis. Hepatic carbohydrate and lipid metabolism are tightly regulated in order to adapt quickly to changes in nutrient availability. Postprandially, the liver lowers the blood glucose levels and stores nutrients in form of glycogen and triglycerides (TG). In contrast, upon fasting, the liver provides glucose, TG, and ketone bodies. However, obesity resulting from a discrepancy in food intake and energy expenditure leads to abnormal fat accumulation in the liver, which is associated with the development of hepatic insulin resistance, non-alcoholic fatty liver disease, and diabetes. In this context, hepatic insulin resistance is directly linked to the accumulation of diacylglycerol (DAG) in the liver. Besides being an intermediate product of TG synthesis, DAG serves as second messenger in response to G-protein coupled receptor signaling. Protein kinase D (PKD) family members are DAG effectors that integrate multiple metabolic inputs. However, the impact of PKD signaling on liver physiology has not been studied so far. In this thesis, PKD3 was identified as the predominantly expressed isoform in liver. Stimulation of primary hepatocytes with DAG as well as high-fat diet (HFD) feeding of mice led to an activation of PKD3, indicating its relevance during obesity. HFD-fed mice lacking PKD3 specifically in hepatocytes displayed significantly improved glucose tolerance and insulin sensitivity. However, at the same time, hepatic deletion of PKD3 in mice resulted in elevated liver weight as a consequence of increased hepatic lipid accumulation. Lack of PKD3 in hepatocytes promoted sterol regulatory element-binding protein (SREBP)-mediated de novo lipogenesis in vitro and in vivo, and thus increased hepatic triglyceride and cholesterol content. Furthermore, PKD3 suppressed the activation of SREBP by impairing the activity of the insulin effectors protein kinase B (AKT) and mechanistic target of rapamycin complexes (mTORC) 1 and 2. In contrast, liver-specific overexpression of constitutive active PKD3 promoted glucose intolerance and insulin resistance. Taken together, lack of PKD3 improves hepatic insulin sensitivity but promotes hepatic lipid accumulation. For this reason, manipulating PKD3 signaling might be a valid strategy to improve hepatic lipid content or insulin sensitivity. However, the exact molecular mechanism by which PKD3 regulates hepatocytes metabolism remains unclear.
Unbiased proteomic approaches were performed in order to identify PKD3 phosphorylation targets. In this process, numerous potential targets of PKD3 were detected, which are implicated in different aspects of cellular metabolism. Among other hits, phenylalanine hydroxylase (PAH) was identified as a target of PKD3 in hepatocytes. PAH is the enzyme that is responsible for the conversion of phenylalanine to tyrosine. In fact, manipulation of PKD3 activity using genetic tools confirmed that PKD3 promotes PAH-dependent conversion of phenylalanine to tyrosine. Therefore, the data in this thesis suggests that PKD3 coordinates lipid and amino acid metabolism in the liver and contributes to the development of hepatic dysfunction.
Identification and characterization of TAT-5 interactors that regulate extracellular vesicle budding
(2021)
Cells from bacteria to man release extracellular vesicles (EV) such as microvesicles (MV) that carry signaling molecules like morphogens and miRNAs to control intercellular communication during health and disease. MV release also sculpts membranes, e.g. repairing damaged membranes to avoid cell death. HIV viruses also bud from the plasma membrane in a similar fashion. In order to determine the in vivo functions of MVs and regulate their release, we need to understand the mechanisms of MV release by plasma membrane budding (ectocytosis).
The conserved phospholipid flippase TAT-5 maintains the asymmetric localization of phosphatidylethanolamine (PE) in the plasma membrane and was the only known inhibitor of ESCRT-mediated ectocytosis in C. elegans. Loss of TAT-5 lipid flipping activity increased the externalization of PE and accumulation of MVs. However, it was unclear how cells control TAT-5 activity to release the right amount of MVs at the right time, since no upstream regulators of TAT-5 were known.
To identify conserved TAT-5 regulators we looked for new proteins that inhibit MV release. To do so, we first developed a degradation-based technique to specifically label MVs. We tagged a plasma membrane reporter with the endogenous ZF1 degradation tag (degron) and expressed it in C. elegans embryos. This reporter is protected from degradation inside MVs, but is degraded inside the cell. Thus, the fluorescence is selectively maintained inside MVs, creating the first MV-specific reporter. We identified four MV release inhibitors associated with retrograde recycling, including the class III PI3Kinase VPS-34, Beclin1 homolog BEC-1, DnaJ protein RME-8, and the uncharacterized Dopey homolog PAD-1. We found that VPS-34, BEC-1, RME-8, and redundant sorting nexins are required for the plasma membrane localization of TAT-5, which is important to maintain PE asymmetry and inhibit MV release. Although we confirmed that PAD-1 and the GEF-like protein MON-2 are required for endosomal recycling, they only traffic TAT-5 in the absence of sorting nexin-mediated recycling. Instead, PAD-1 is specifically required for the lipid flipping activity of TAT-5 that inhibits MV release.
Thus, our work pinpoints TAT-5 and PE as key regulators of plasma membrane budding, further supporting the model that PE externalization drives ectocytosis. In addition, we uncovered redundant intracellular trafficking pathways, which affect organelle size and revealed new regulators of TAT-5 flippase activity. These newly identified ectocytosis inhibitors provide a toolkit to test the in vivo roles of MVs. In the long term, our work will help to identify the mechanisms that govern MV budding, furthering our understanding of the mechanisms that regulate disease-mediated EV release, membrane sculpting and viral budding.
The ubiquitination of proteins serves as molecular signal to control an enormous number of physiological processes and its dysregulation is connected to human diseases like cancer. The versatility of this signal stems from the diverse ways by which ubiquitin can be attached to its targets. Thus, specificity and tight regulation of the ubiquitination are pivotal requirements of ubiquitin signaling. Ubiquitin-conjugating enzymes (E2s) act at the heart of the ubiquitination cascade, transferring ubiquitin from a ubiquitin-activating enzyme (E1) to a ubiquitin ligase (E3) or substrate. When cooperating with a RING-type E3, ubiquitin-conjugating enzymes can determine linkage specificity in ubiquitin chain formation. Our understanding of the regulation of E2 activities is still limited at a structural level.
The work described here identifies two regulation mechanisms in UBE2S, a cognate E2 of the human RING-type E3 anaphase-promoting complex/cyclosome (APC/C). UBE2S elongates ubiquitin chains on APC/C substrates in a Lys11 linkage-specific manner, thereby targeting these substrates for degradation and driving mitotic progression. In addition, UBE2S was found to have a role in DNA repair by enhancing non-homologous end-joining (NHEJ) and causing transcriptional arrest at DNA damage sites in homologous recombination (HR). Furthermore, UBE2S overexpression is a characteristic feature of many cancer types and is connected to poor prognosis and diminished response to therapy.
The first regulatory mechanism uncovered in this thesis involves the intramolecular auto-ubiquitination of a particular lysine residue (Lys+5) close to the active site cysteine, presumably through conformational flexibility of the active site region. The Lys+5-linked ubiquitin molecule adopts a donor-like, ‘closed’ orientation towards UBE2S, thereby conferring auto-inhibition. Notably, Lys+5 is a major physiological ubiquitination site in ~25% of the human E2 enzymes, thus providing regulatory opportunities beyond UBE2S. Besides the active, monomeric state and the auto-inhibited state caused by auto-ubiquitination, I discovered that UBE2S can adopt a dimeric state. The latter also provides an auto-inhibited state, in which ubiquitin transfer is blocked via the obstruction of donor binding. UBE2S dimerization is promoted by its unique C-terminal extension, suppresses auto-ubiquitination and thereby the proteasomal degradation of UBE2S.
Taken together, the data provided in this thesis illustrate the intricate ways by which UBE2S activity is fine-tuned and the notion that structurally diverse mechanisms have evolved to restrict the first step in the catalytic cycle of E2 enzymes.
A continuous arms race between the development of novel antibiotics and the evolution of corresponding resistance mechanisms in bacteria has been observed, since antibiotic agents like arsphenamines (e.g. Salvarsan, developed by Paul Ehrlich [1]), sulphonamides (e.g. Prontosil, Gerhard Domagk [2]) and penicillin (Alexander Fleming [3]) were first applied to effectively cure bacterial infections in the early 20th century. The rapid emergence of resistances in contrast to the currently lagging discovery of antibiotics displays a severe threat to human health. Some serious infectious diseases, such as tuberculosis or melioidosis, which were either thought to be an issue only in Third-World countries in case of tuberculosis, or regionally restricted with respect to melioidosis, are now on the rise to expand to other areas. In contrast, methicillin-resistant Staphylococcus aureus (MRSA) is already present in clinical setups all over the world and causes severe infections in immunocompromised patients. Thus, there is an urgent need for new and effective antimicrobial agents, which impair vital functions of the pathogen’s metabolism.
One central metabolic pathway is represented by the bacterial fatty-acid synthesis pathway (FAS II), which is essential for the synthesis of long and branched-chain fatty acids, as well as mycolic acids. These substances play a major role as modulating components of the properties of the most important protective barrier – the cell envelope. The integrity of the bacterial cell wall and the associated membrane(s) is crucial for cell growth and for protection against physical strain, intrusion of antibiotic agents and regulation of uptake of ions and other small molecules. Thus, this central pathway represents a promising target for antibiotic action against pathogens to combat infectious diseases. The last and rate-limiting step is catalysed by the trans-2-enoyl-ACP reductase (ENR) FabI or InhA (in mycobacteria), which has been demonstrated to be a valuable target for drug design and can be addressed, amongst others, by diphenyl ether (DPE) compounds, derived from triclosan (TCL) – the first one of this class which was discovered to bind to ENR enzymes [4, 5].
Based on this scaffold, inhibitors containing different combinations of substituents at crucial positions, as well as a novel type of substituent at position five were investigated regarding their binding behaviour towards the Burkholderia pseudomallei and Mycobacterium tuberculosis ENR enzymes bpFabI and InhA, respectively, by structural, kinetic and in-vivo experiments. Generally, substitution patterns modulate the association and dissociation velocities of the different ENR inhibitors in the context of the two-step slow-onset binding mechanism, which is observed for both enzymes. These alterations in the rapidity of complex formation and decomposition have a crucial impact on the residence time of a compound and hence, on the pharmacokinetic properties of potential drug candidates. For example, the substituents at the 2’-position of the DPE scaffold influence the ground- and transition state stability during the binding process to bpFabI, whereas 4’-substituents primarily alter the transition state [6]. The novel triazole group attached to the 5-position of the scaffold, targeting the hydrophobic part of the substrate-binding pocket in InhA, significantly enhances the energy barrier of the transition state of inhibitor binding [7] and decelerates the association- as well as the dissociation processes. Combinations with different substituents at the 2’-position can enhance or diminish this effect, e.g. by ground-state stabilisation, which will result in an increased residence time of the respective inhibitor on InhA.
Further structural investigations carried out in this work, confirm the proposed binding mode of a customised saFabI inhibitor [8], carrying a pyridone moiety on the DPE scaffold to expand interactions with the protein environment. Structural and preliminary kinetic data confirm the binding of the same inhibitor to InhA in a related fashion. Comparisons with structures of the ENR inhibitor AFN-1252 [9] bound to ENR enzymes from other organisms, addressing a similar region as the pyridone-moiety of the DPE inhibitor, suggest that also the DPE inhibitor bears the potential to display binding to homologues of saFabI and InhA and may be optimised accordingly.
Both of the newly investigated substituents, the pyridone moiety at the 4’-position as well as the 5-triazole substituent, provide a good starting point to modify the DPE scaffold also towards improved kinetic properties against ENR enzymes other than the herein studied and combining both groups on the DPE scaffold may have beneficial effects. The understanding of the underlying binding mechanism is a crucial factor to promote the dedicated design of inhibitors with superior pharmacokinetic characteristics.
A second target for a structure-based drug-design approach is the interaction surface between ENR enzymes and the acyl-carrier protein (ACP), which delivers the growing acyl chain to each distinct enzyme of the dissociated FAS-II system and presumably recognises its respective interaction partner via electrostatic contacts. The interface between saACP and saFabI was investigated using different approaches including crosslinking experiments and the design of fusion constructs connecting the ACP and the FabI subunits via a flexible linker region of varying lengths and compositions. The crosslinking studies confirmed a set of residues to be part of the contact interface of a previously proposed complex model [10] and displayed high crosslinking efficiency of saACP to saFabI when mutated to cysteine residues. However, crystals of the complex obtained from either the single components, or of the fusion constructs usually displayed weak diffraction, which supports the assumption that complex formation is highly transient. To obtain ordered crystals for structural characterisation of the complex it is necessary to trap the complex in a fixed state, e.g. by a high-affinity substrate attached to ACP [11], which abolishes rapid complex dissociation. For this purpose, acyl-coupled long-residence time inhibitors might be a valuable tool to elucidate the detailed architecture of the ACP-FabI interface. This may provide a novel basis for the development of inhibitors that specifically target the FAS-II biosynthesis pathway.
Divalent cations are important second messengers triggering various signal transduction events in platelets. Whereas calcium channel blockers have an established antithrombotic effect and the regulation of Ca2+ homeostasis has been elucidated in platelets, the molecular regulation of Mg2+ and Zn2+ homeostasis has not been investigated so far.
In the first part of the thesis, the role of -type serine-threonine kinase linked to transient receptor potential cation channel, subfamily M, member 7 (TRPM7) in platelets was investigated. Using Trpm7R/R mice with a point mutation deleting the kinase activity, we showed that the TRPM7 kinase regulates platelet activation via immunoreceptor tyrosine-based activation motif (ITAM), hem(ITAM) and protease-activated receptor (PAR) signaling routes. Furthermore, Trpm7R/R mice were protected from in vivo thrombosis and stroke, thus establishing TRPM7 kinase as a promising anti-thrombotic target.
In the second part of the thesis, the role of TRPM7 channel in a megakaryocyte (MK) and platelet-specific knockout mouse, Trpm7fl/fl-Pf4Cre, was investigated. Here, we observed that depending on the type of stimulation, Trpm7fl/fl-Pf4Cre platelets showed either enhanced or inhibited responses. Although Trpm7fl/fl-Pf4Cre mice were thrombocytopenic, no differences to wildtype mice were observed in models of in vivo thrombosis and stroke. The above two studies highlight that inhibition of TRPM7 kinase but not the channel itself (in MKs and platelets) may be a promising anti-thrombotic strategy.
Besides TRPM7, we investigated the role of magnesium transporter 1 (MAGT1) in platelet Mg2+ homeostasis and found that MAGT1 primarily regulates receptor-operated calcium entry (ROCE) in platelets specifically upon GPVI activation. This physiological crosstalk is triggered by protein kinase C (PKC) isoforms. Platelets from Magt1-/y mice hyper-reacted to GPVI and thromboxane A2 (TXA2) receptor stimulation in vitro. Consequently, Magt1-/y platelets were found to be pro-thrombotic in disease models of thrombosis and stroke.
To compare platelet ITAM-signaling to the immune system, we further investigated the role of MAGT1 in T and B cells. We described the primary role of MAGT1 in mice under pathogen-free conditions. Magt1-/y B cells showed dysregulated Mg2+ and Ca2+ homeostasis upon B-cell receptor activation, thereby altering Syk, LAT, phospholipase C (PLC)2 and PKC phosphorylation. In contrast to human MAGT1-deficient T cells, development and effector functions of mouse Magt1-/y T cells showed no alterations.
Finally, in the last part of the thesis, we described methods to measure intracellular free zinc [Zn2+]i in human and mouse platelets with storage pool disease (SPD). We propose to measure the [Zn2+]i status in SPD platelets as a relatively easy diagnostic to screen platelet granule abnormalities.
Maintenance of tumor vasculature integrity is indispensable for tumor growth and thus affects tumor progression. Previous studies have identified platelets as major regulators of tumor vascular integrity, as their depletion selectively renders tumor vessels highly permeable, causing massive intratumoral hemorrhage. While these results establish platelets as potential targets for anti-tumor therapy, depletion is not a treatment option due to the essential role of platelets for hemostasis. This thesis demonstrates for the first time that functional inhibition of glycoprotein (GP) VI on the platelet surface rapidly induces tumor hemorrhage and diminishes tumor growth similar to complete platelet depletion but without inducing systemic bleeding complications. Both, the intratumoral bleeding and tumor growth arrest could be reverted by depletion of Ly6G+ cells confirming them to be responsible for the induction of bleeding and necrosis within the tumor. In addition, GPVI inhibition increased intra-tumoral accumulation of co-administered chemotherapeutic agents, thereby resulting in a profound anti-tumor effect. In summary, this thesis manifests platelet GPVI as a key regulator of vascular integrity specifically in growing tumors, serving as a potential basis for the development of anti-tumor strategies.
In the second part of this thesis, light is shed on the modulating role of bridging integrator 2 (BIN2) in platelet Ca2+ signaling. Stromal interaction molecule 1 (STIM1) mediated store-operated calcium entry (SOCE) is the major route of Ca2+ influx in platelets, triggered by inositol trisphosphate receptor (IP3R)-dependent Ca2+ store release. In this thesis, the BAR domain superfamily member BIN2 was identified as the first Ca2+ signaling modulator, interacting with both, STIM1 and IP3R in platelets. Deletion of BIN2 resulted in reduced Ca2+ store release and Ca2+ influx in response to all tested platelet agonists. These defects were a consequence of impaired IP3R function in combination with defective STIM1-mediated SOC channel activation, while Ca2+ store content and agonist-induced IP3 production were unaltered. These results establish BIN2 as a central regulator of platelet Ca2+ signaling.
The third part of this thesis focuses on the effect of the soluble neuronal guidance protein Sema7A on platelet function. Rosenberger et al. discovered that Sema7A cleavage from red blood cells increases the formation of platelet-neutrophil complexes, thereby reinforcing thrombo-inflammation in myocardial ischemia-reperfusion injury (MIRI). This thesis establishes soluble Sema7A as a stimulator of platelet thrombus formation via its interaction with platelet GPIbα, thereby reinforcing PNC formation. Thus, interfering with the GPIb-Sema7A interaction during MIRI represents a potential strategy to reduce cardiac damage and improve clinical outcome following MI.
Structural and functional elucidation of the Type VIIb secretion system from Staphylococcus aureus
(2020)
The Type VII secretion system (T7SS) is linked to virulence and long-term pathogenesis in a broad range of Gram-positive bacteria, including the human commensal and pathogen Staphylococcus aureus. The Type VIIb secretion system (T7SSb) is responsible for the export of small toxic proteins, which induce antibacterial immune responses and mediate bacterial persistence in the host. In addition, it is also involved in bacterial competition. The T7SSb requires several proteins to build up the secretion machinery. This work focuses on the structural and functional investigation of the motor ATPase EssC and the putative pore forming, multi-pass membrane component EsaA. Both proteins are indispensable for substrate secretion.
EssC belongs to the FtsK/SpoIIIE ATPase family and is conserved among the T7SSs. It contains three C-terminal, cytosolic ATPase domains, designated as EssC- D1, -D2 and -D3, whereby EssC-D3 is the most distal one. In this thesis, I am presenting the crystal structure of the EssC-D3 at 1.7 Å resolution. As the deletion of EssC-D3 abrogates substrate export, I have demonstrated that this domain comprises a hydrophobic, surface-exposed pocket, which is required for substrate secretion. More specifically, I have identified two amino acids involved in the secretion process. In addition, my results indicate that not only EssC-D3 is important for substrate interaction but also EssC-D2 and/or EssC-D1. Unlike in the related Yuk T7SSb of Bacillus subtilis, the ATPase activity of D3 domain contributes to substrate secretion. Mutation of the modified Walker B motif in EssC-D3 diminishes substrate secretion completely.
The membrane protein EsaA encompasses an extracellular segment spanning through the cell wall of S. aureus. I was able to reveal that this part folds into a stable domain, which was crystallized and diffracted up to 4 Å. The first attempts to dissolve the structure failed due to a lack of homologues structures. Therefore, crystals for single-wavelength anomalous dispersion, containing selenomethionyl-substitutes, were produced and the structure solution is still in progress. Preliminary experiments addressing the function of the extracellular domain indicate an important role in substrate secretion and bacterial competition.
Sharpening super-resolution by single molecule localization microscopy in front of a tuned mirror
(2020)
The „Resolution Revolution" in fluorescence microscopy over the last decade has given rise to a variety of techniques that allow imaging beyond the diffraction limit with a resolution power down into the nanometer range. With this, the field of so-called super-resolution microscopy was born. It allows to visualize cellular architecture at a molecular level and thereby achieve a resolution level that had been previously only accessible by electron microscopy approaches.
One of these promising techniques is single molecule localization microscopy (SMLM) in its most varied forms such as direct stochastic optical reconstruction microscopy (dSTORM) which are based on the temporal separation of the emission of individual fluorophores. Localization analysis of the subsequently taken images of single emitters eventually allows to reconstruct an image containing super-resolution information down to typically 20 nm in a cellular setting. The key point here is the localization precision, which mainly depends on the image contrast generated the by the individual fluorophore’s emission. Thus, measures to enhance the signal intensity or reduce the signal background allow to increase the image resolution achieved by dSTORM. In my thesis, this is achieved by simply adding a reflective metal-dielectric nano-coating to the microscopy coverslip that serves as a tunable nano-mirror.
I have demonstrated that such metal-dielectric coatings provide higher photon yield at lower background and thus substantially improve SMLM performance by a significantly increased localization precision, and thus ultimately higher image resolution. The strength of this approach is that ─ except for the coated cover glass ─ no specialized setup is required. The biocompatible metal-dielectric nano-coatings are fabricated directly on microscopy coverslips and have a simple three-ply design permitting straightforward implementation into a conventional fluorescence microscope. The introduced improved lateral resolution with such mirror-enhanced STORM (meSTORM) not only allows to exceed Widefield and Total Internal Reflection Fluorescence (TIRF) dSTORM performance, but also offers the possibility to measure in a simplified setup as it does not require a special TIRF objective lens.
The resolution improvement achieved with meSTORM is both spectrally and spatially tunable and thus allows for dual-color approaches on the one hand, and selectively highlighting region above the cover glass on the other hand, as demonstrated here.
Beyond lateral resolution enhancement, the clear-cut profile of the highlighted region provides additional access to the axial dimension. As shown in my thesis, this allows for example to assess the three-dimensional architecture of the intracellular microtubule network by translating the local localization uncertainty to a relative axial position. Even beyond meSTORM, a wide range of membrane or surface imaging applications may benefit from the selective highlighting and fluorescence enhancing provided by the metal-dielectric nano-coatings. This includes for example, among others, live-cell Fluorescence Correlation Spectroscopy and Fluorescence Resonance Energy Transfer studies as recently demonstrated.
Protein kinase D1 deletion in adipocytes enhances energy dissipation and protects against adiposity
(2019)
Adaptation to alterations in nutrient availability ensures the survival of organisms. In vertebrates, adipocytes play a decisive role in this process due to their ability to store large amounts of excess nutrients and release them in times of food deprivation. In todays western world, a rather unlimited excess of nutrients leads to high-caloric food consumption in humans. Nutrient overload together with a decreased energy dissipation result in obesity as well as associated diseases such as insulin resistance, diabetes, and liver steatosis. Obesity causes a hormonal imbalance, which in combination with altered nutrient levels can aberrantly activate G-protein coupled receptors utilizing diacylglycerol (DAG) as secondary messenger. Protein kinase D (PKD) 1 is a DAG effector integrating multiple hormonal and nutritional inputs. Nevertheless, its physiological role in adipocytes has not been investigated so far. In this thesis, evidence is provided that the deletion of PKD1 in adipocytes suppresses lipogenesis as well as the accumulation of triglycerides. Furthermore, PKD1 depletion results in increased mitochondrial biogenesis as well as decoupling activity. Moreover, PKD1 deletion promotes the expression of the β3-adrenergic receptor (ADRB3) in a CCAAT/enhancer-binding protein (C/EBP)-α and δ-dependent manner. This results in elevated expression levels of beige markers in adipocytes in the presence of a β-agonist. Contrarily, adipocytes expressing a constitutive active form of PKD1 present a reversed phenotype. Additionally, PKD1 regulates adipocyte metabolism in an AMP-activated protein kinase (AMPK)-dependent manner by suppressing its activity through phosphorylation of AMPK α1/α2 subunits. Thus, PKD1 deletion results in an enhanced activity of the AMPK complex. Consistent with the in vitro findings, mice lacking PKD1 in adipocytes demonstrate a resistance to high-fat diet-induced obesity due to an elevated energy expenditure caused by trans-differentiation of white into beige adipocytes. Moreover, deletion of PKD1 in murine adipocytes improves systemic insulin sensitivity and ameliorates liver steatosis. Finally, PKD1 levels positively correlate with HOMA-IR as well as insulin levels in human subjects. Furthermore, inhibition of PKD1 in human adipocytes leads to metabolic alterations, which are comparable to the alterations seen in their murine counterparts. Taken together, these data demonstrate that PKD1 suppresses energy dissipation, drives lipogenesis, and adiposity. Therefore, increased energy dissipation induced by several complementary mechanisms upon PKD1 deletion might represent an attractive strategy to treat obesity and its related complications.
The thesis provides insights in reconstruction and analysis pipelines for processing of
three-dimensional cell and vessel images of megakaryopoiesis in intact murine bone.
The images were captured in a Light Sheet Fluorescence Microscope. The work
presented here is part of Collaborative Research Centre (CRC) 688 (project B07) of
the University of Würzburg, performed at the Rudolf-Virchow Center. Despite ongoing
research within the field of megakaryopoiesis, its spatio-temporal pattern of
megakaryopoiesis is largely unknown. Deeper insight to this field is highly desirable to
promote development of new therapeutic strategies for conditions related to
thrombocytopathy as well as thrombocytopenia. The current concept of
megakaryopoiesis is largely based on data from cryosectioning or in vitro studies
indicating the existence of spatial niches within the bone marrow where specific stages
of megakaryopoiesis take place. Since classic imaging of bone sections is typically
limited to selective two-dimensional views and prone to cutting artefacts, imaging of
intact murine bone is highly desired. However, this has its own challenges to meet,
particularly in image reconstruction. Here, I worked on processing pipelines to account
for irregular specimen staining or attenuation as well as the extreme heterogeneity of
megakaryocyte morphology. Specific challenges for imaging and image reconstruction
are tackled and solution strategies as well as remaining limitations are presented and
discussed. Fortunately, modern image processing and segmentation strongly benefits
from continuous advances in hardware as well as software-development. This thesis
exemplifies how a combined effort in biomedicine, computer vision, data processing
and image technology leads to deeper understanding of megakaryopoiesis. Tailored
imaging pipelines significantly helped elucidating that the large megakaryocytes are
broadly distributed throughout the bone marrow facing a surprisingly dense vessel
network. No evidence was found for spatial niches in the bone marrow, eventually
resulting in a revised model of megakaryopoiesis.
Fluorescence microscopy has become one of the most important techniques for the imaging of biological cells and tissue, since the technique allows for selective labeling with fluorescent molecules and is highly suitable for low-light applications down to the single molecule regime. The methodological requirements are well-defined for studying membrane receptors within a highly localized nanometer-thin membrane. For example, G-protein-coupled receptors (GPCRs) are an extensively studied class of membrane receptors that represent one of the most important pharmaceutical targets. Ligand binding and GPCR activation dynamics are suspected to take place at the millisecond scale and may even be far faster. Thus, techniques that are fast, selective, and live-cell compatible are required to monitor GPCR dynamics. Fluorescence resonance energy transfer (FRET) and total internal reflection fluorescence microscopy (TIRF-M) are methods of choice to monitor the dynamics of GPCRs selectively within the cell membrane.
Despite the remarkable success of these modalities, there are limitations. Most importantly, inhomogeneous illumination can induce imaging artifacts, rendering spectroscopic evaluation difficult. Background signal due to scattering processes or imperfect labeling can hamper the signal-to-noise, thus limiting image contrast and acquisition speed. Careful consideration of the internal physiology is required for FRET sensor design, so that ligand binding and cell compatibility are well-preserved despite the fluorescence labeling procedures. This limitation of labeling positions leads to very low signal changes in FRET-based GPCR analysis. In addition, microscopy of these systems becomes even more challenging in single molecule or low-light applications where the accuracy and temporal resolution may become dramatically low. Fluorescent labels should therefore be brighter, protected from photobleaching, and as small as possible to avoid interference with the binding kinetics. The development of new fluorescent molecules and labeling methods is an ongoing process. However, a complete characterization of new labels and sensors takes time. So far, the perfect dye system for GPCR studies has not been found, even though there is high demand.
Thus, this thesis explores and applies a different approach based on improved illumination schemes for TIRF-M as well as metal-coated coverslips to enhance fluorescence and FRET efficiency. First, it is demonstrated that a 360° illumination scheme reduces typical TIRF artifacts and produces a much more homogenously illuminated field of view. Second, membrane imaging and FRET spectroscopy are improved by metal coatings that are used to modulate the fluorescent properties of common fluorescent dyes. Computer simulation methods are used to understand the underlying photophysics and to design the coatings. Third, this thesis explores the operational regime and limitations of plasmonic approaches with high sectioning capabilities. The findings are summarized by three publications that are presented in the results section of this work. In addition, the theory of fluorescence and FRET is explained, with particular attention to its emission modulations in the vicinity of metal-dielectric layers. Details of the instrumentation, computer simulations, and cell culture are described in the method section. The work concludes with a discussion of the findings within the framework of recent technological developments as well as perspectives and suggestions for future approaches complete the presented work.
Humans are continuously exposed to airborne spores of the saprophytic fungus Aspergillus fumigatus. However, in healthy individuals pulmonary host defense mechanisms efficiently eliminate the fungus. In contrast, A. fumigatus causes devastating infections in immunocompromised patients. Host immune responses against A. fumigatus lung infections in immunocompromised conditions have remained largely elusive. Given the dynamic changes in immune cell subsets within tissues upon immunosuppressive therapy, we dissected the spatiotemporal pulmonary immune response after A. fumigatus infection to reveal basic immunological events that fail to effectively control invasive fungal disease. In different immunocompromised murine models, myeloid, notably neutrophils, and macrophages, but not lymphoid cells were strongly recruited to the lungs upon infection. Other myeloid cells, particularly dendritic cells and monocytes, were only recruited to lungs of corticosteroid treated mice, which developed a strong pulmonary inflammation after infection. Lymphoid cells, particularly CD4\(^+\) or CD8\(^+\) T-cells and NK cells were highly reduced upon immunosuppression and not recruited after A. fumigatus infection. Moreover, adoptive CD11b\(^+\) myeloid cell transfer rescued cyclophosphamide immunosuppressed mice from lethal A. fumigatus infection but not cortisone and cyclophosphamide immunosuppressed mice. Our findings illustrate that CD11b\(^+\) myeloid cells are critical for anti-A. fumigatus defense under cyclophosphamide immunosuppressed conditions.
Platelet aggregation at sites of vascular injury is essential to limit posttraumatic blood loss, but may also cause acute ischemic disease states such as myocardial infarction or stroke. Stable thrombus formation requires a series of molecular events involving platelet receptors and intracellular signal transduction, which contribute to adhesion, activation and aggregation of platelets. In this thesis, the cellular regulation of platelet surface receptors and their involvement in thrombus formation was investigated using genetically modified mice.
In the first part of the study, the functional relevance of the immunoreceptor tyrosine-based activation motif (ITAM)-coupled collagen receptor GPVI and of the recently identified hemITAM-bearing C-type lectin-like receptor 2 (CLEC-2) for in vivo thrombus formation was analyzed. Megakaryocyte/ platelet-specific CLEC-2 knock out mice displayed a defective lymphatic development and were protected from occlusive arterial thrombus formation. These phenotypes were more pronounced in mice with a GPVI/CLEC-2 double deficiency. Hemostasis was not compromised in CLEC-2 or GPVI single-deficient animals, as they showed only mildly prolonged tail bleeding times. Combined depletion of both receptors resulted in markedly prolonged bleeding times revealing an unexpected redundant function of the two receptors in hemostasis as well as thrombosis. These findings might have important implications for the development of anti-CLEC-2/ anti-GPVI agents as therapeutics.
In the second part, mechanisms underlying the cellular regulation of CLEC-2 were studied. Previous studies have shown that injection of the anti-CLEC-2 antibody INU1 results in complete immunodepletion of platelet CLEC-2 in mice, which is preceded by a severe transient thrombocytopenia thereby limiting its potential therapeutic use. It is demonstrated that INU1-induced CLEC-2 immunodepletion occurs through Src family kinase (SFK)-dependent receptor internalization in vitro and in vivo, presumably followed by intracellular degradation. In mice with spleen tyrosine kinase (Syk) deficiency, INU1-induced CLEC-2 internalization/ degradation was fully preserved, whereas the associated thrombocytopenia was largely prevented. These results show that CLEC-2 can be downregulated from the platelet surface through internalization in vitro and in vivo and that this can be mechanistically uncoupled from the associated antibody-induced thrombocytopenia.
Since INU1 IgG induced a pronounced thrombocytopenia, the in vivo effects of monovalent INU1 F(ab) fragments were analyzed. Very unexpectedly, injection of the F(ab) fragments resulted in widespread thrombus formation leading to persistent neurological deficits of the animals. This intravascular thrombus formation is the result of CLEC-2-dependent platelet activation and aggregation. The mechanism underlying the thrombus formation is still unknown and depends potentially on binding of a yet unidentified ligand to F(ab)-opsonized CLEC-2 on platelets.
Influence of interleukin-6-type cytokine oncostatin M on murine aortic vascular smooth muscle cells
(2018)
Oncostatin M (OSM) is a cytokine of the interleukin-6 family and released in the early
phase of inflammation by neutrophils, activated macrophages, dendritic cells, and T
lymphocytes. Its roles in physiology and disease are not entirely understood yet. It
has been shown recently that substantial amounts of OSM are found in atherosclerotic
plaques.
The first part of this thesis addresses the effects of OSM on vascular smooth muscle
cells (VSMCs). This cell type is known to contribute to atherogenesis and expresses
the type I and type II OSM receptor complexes. This study revealed that OSM is a
strong inducer of an array of genes which have recently been shown to play important
roles in atherosclerosis. Investigation of VSMCs isolated from OSMRbeta-deficient
(Osmr-/-) mice proved that the regulation of these target genes is entirely dependent
on the activation of the type II OSMR complex. In addition to OSM, other cytokines
expressed by T lymphocytes were found to contribute to plaque development. According
to earlier publications, the influence of IL-4, IL-13, and IL-17 on the progression of
plaques were discussed controversially. Nevertheless, for the regulation of investigated
atherosclerotic target genes and receptor complexes in VSMCs, they seemed to play a
minor role compared to OSM. Only the expression of the decoy receptor IL-13Ralpha2 - a
negative feedback mechanism for IL-13-mediated signalling - was strongly induced after
treatment with all mentioned cytokines, especially when VSMCs were primed with OSM
before stimulation.
The second part of this thesis focuses on the role of OSM during the progression of
atherosclerosis in vivo. Therefore, Ldlr-/-Osmr-/- mice were generated by crossing Ldlr-/-
mice - a typical mouse model for atherosclerosis - with Osmr-/- mice. These double-deficient
mice together with Ldlr-/-Osmr+/+ mice were set on cholesterol rich diet (Western
diet, WD) for 12 weeks before they were sacrificed. Determination of body and
organ weight, staining of aortas and aortic roots as well as gene expression profiling
strongly suggested that Ldlr-/-Osmr-/- mice are less susceptible for plaque development
and weight gain compared to Ldlr-/-Osmr+/+ mice. However, further experiments and
additional controls (C57Bl/6 and Osmr-/- mice) on WD are necessary to clarify the
underlying molecular mechanisms.
Taken together, the interleukin-6-type cytokine OSM is a strong inducer of an array of
target genes involved in de-differentiation and proliferation of VSMCs, a process known
to contribute substantially to atherogenesis. Further in vivo studies will help to clarify
the role of OSM in atherosclerosis.
This work summarizes the results of studies on several major aspects of platelet activation and platelet receptor regulation. Therefore, this thesis is divided into four parts.
Platelet activation and aggregation at sites of vascular injury is critical to prevent excessive blood loss, but may also lead to life-threatening ischemic disease states, such as myocardial infarction and stroke. Agonist-induced elevation in cytosolic Ca2+ concentrations is essential for platelet activation in hemostasis and thrombosis. The principal route of Ca2+ influx in platelets is store-operated calcium entry (SOCE). The calcium sensor molecule stromal interaction molecule 1 (STIM1) regulates SOCE by activating the membrane calcium channel protein Orai1, but the exact mechanisms of this interaction are not fully understood. Using affinity chromatography to screen for STIM1 interacting proteins in platelets, bridging integrator 2 (BIN2), an adapter protein belonging to the family of BAR proteins that is mainly expressed in the hematopoietic system, was identified. Newly generated BIN2 KO mice were viable and fertile but their platelets displayed markedly impaired SOCE in response to thapsigargin (TG) as well as agonists acting on immunoreceptor tyrosine-based activation motif (ITAM) or G protein-coupled receptors. This SOCE defect resulted in impaired (hem)ITAM induced platelet activation, aggregate formation under flow and procoagulant activity. As a consequence, mice lacking BIN2 in platelets were protected from occlusive arterial thrombus formation and thrombo-inflammatory cerebral infarct progression in a model of experimental stroke. These results identify BIN2 as a critical regulator of platelet SOCE in thrombosis and thrombo-inflammatory disease.
Integrin αIIbβ3 plays a central role in the adhesion and aggregation of platelets. Integrin activation requires the transmission of a signal from the small cytoplasmic tails of the α or β
subunit to the large extracellular domains resulting in conformational changes of the extracellular domains to enable ligand binding. It was hypothesized that Hic-5 is a novel regulator of integrin αIIbβ3 activation in mice. As demonstrated in the second part of this thesis, lack of Hic-5 had no detectable effect on platelet integrin activation and function in vitro and in vivo under all tested conditions. These results indicate that Hic-5 is dispensable for integrin αIIbβ3 activation and consequently for arterial thrombosis and hemostasis in mice.
The Rho GTPase family members RhoA and Rac1 play major roles in platelet activation at sites of vascular injury. Little is known about possible redundant functions of these Rho GTPases in regulating platelet function. To investigate functional redundancies of RhoA and Rac1 in platelet production and function, mice with MK- and platelet-specific double- deficiencies in RhoA and Rac1 were generated. RhoA/Rac1 double-deficiency phenocopied the respective single knockouts without any additional effects in the double-knockout animals, demonstrating for the first time a functional non-redundancy of RhoA and Rac1 in platelet function.
Antibodies against platelet glycoproteins (GP) trigger platelet destruction in immune thrombocytopenia (ITP) by binding to Fcγ receptors (FcγRs) on immune cells. However, antibodies against the platelet collagen receptor GPVI exert powerful anti-thrombotic action in vivo by inducing ectodomain shedding of the receptor associated with a transient thrombocytopenia. As shown in the final part of this thesis, blockade or deficiency of the inhibitory FcγRIIB abolished sequestration of anti-GPVI opsonized platelets in the hepatic vasculature and GPVI shedding. This process was mediated by liver sinusoidal endothelial cells (LSEC), the major FcγRIIB expressing cell type in the body. Furthermore, LSEC FcγRIIB mediated hepatic platelet sequestration and contributed to thrombocytopenia in mice treated with antibodies against αIIbβ3, the major target antigen in human ITP. These results reveal a novel and unexpected function of hepatic FcγRIIB in the processing of antibody-opsonized platelets.
This work summarizes the results of studies on three major aspects of platelet signaling and of the pathogenesis of immune thrombocytopenia. Therefore, this thesis is divided into three parts. i) Platelet activation and subsequent thrombus formation at sites of vascular injury is crucial for normal hemostasis, but it can also trigger myocardial infarction and stroke. The initial capture of flowing platelets to the injured vessel wall is mediated by the interaction of the glycoprotein (GP) Ib-V-IX complex with von Willebrand factor (vWF) immobilized on the exposed subendothelial extracellular matrix (ECM). The central importance of GPIb for platelet adhesion is well established, whereas GPV is generally considered to be of minor relevance for platelet physiology and thrombus formation. This study intended to clarify the relevance of this receptor during thrombus formation using Gp5-/- mice and mice with different double-deficiencies in GPV and in other platelet receptors. It was found that GPV and the collagen receptor integrin a2b1 have partially redundant functions in collagentriggered platelet aggregation. Further, it was revealed that GPV limits thrombus formation and impairs hemostasis in vivo. The data presented here demonstrate that the protective effect of GPVI-deficiency (another platelet collagen receptor) in arterial thrombosis and ischemic stroke depends on the expression of GPV. Moreover, it was demonstrated that lack of GPV restores the hemostatic function of mice lacking both GPVI and a2b1 or mice lacking GPVI and the C-type lectin receptor 2 (CLEC-2). Conclusively, GPV-depletion or blockade might have the potential to treat hemorrhagic disease states. ii) Platelets contain the two phospholipase (PL) D isoforms, PLD1 and PLD2, both of which presumably become activated upon platelet stimulation. However, the function of PLD in the process of platelet activation and aggregation has not been definitively explored. Thus, PLD-deficient mice were analyzed. Mice lacking PLD1 or PLD2 were viable, fertile and had normal platelet counts. PLD1 was found to be responsible for the inducible PLD-activity in platelets and to contribute to efficient integrin activation under static conditions. Moreover, flow adhesion experiments revealed that PLD1 is essential for efficient GPIb-mediated integrin activation. Consequently, Pld1-/- mice were protected from arterial thrombosis and ischemic brain infarction without affecting tail bleeding times. Hence, inhibition of PLD1 might be a novel approach for antithrombotic therapy. iii) Cellular activation of platelets or immune cells results in increased cytosolic calcium (Ca2+) levels. Store-operated calcium entry (SOCE) via the STIM1-Orai1 axis is the main route of Ca2+ entry downstream of immunoreceptor tyrosine-based activating motif (ITAM) receptor stimulation in mast cells and T cells. However, the requirement of Ca2+-mobilization in Fcg receptor (FcgR)-signaling and the relevance of STIM2 for T cell SOCE have been unclear. To address these questions, genetically modified mice lacking central molecules of the SOCE machinery were analyzed. Ca2+-measurements revealed that both STIM isoforms contribute to Ca2+-mobilization downstream of T cell receptor activation. Additionally, it was found that FcgR stimulation results in SOCE and is mediated by STIM1 and probably Orai1. Animal models of immune thrombocytopenia (ITP) revealed that SOCE is essential for platelet clearance and that both STIM isoforms contribute to the pathology of ITP. Moreover, in this work it was also demonstrated that STIM1 and Orai1 are essential in IgG-mediated systemic anaphylaxis. STIM2 contributes to IgG-mediated, but not to IgE-mediated anaphylaxis. The data indicate that interference with SOCE might become a new strategy to prevent or treat IgG-dependent autoimmune diseases.
In mammals, anucleate blood platelets are constantly produced by their giant bone marrow (BM) progenitors, the megakaryocytes (MKs), which originate from hematopoietic stem cells. Megakaryopoiesis and thrombopoiesis have been studied intensively, but the exact mechanisms that control platelet generation from MKs remain poorly understood. Using multiphoton intravital microscopy (MP-IVM), thrombopoiesis and proplatelet formation were analyzed in the murine BM in real-time and in vivo, identifying an important role for several proteins, including Profilin1, TRPM7 and RhoA in thrombopoiesis. Currently, it is thought that blood cell precursors, such as MKs, migrate from the endosteal niche towards the vascular niche during maturation. In contrast to this paradigm, it was shown that MKs are homogeneously distributed within the dense BM blood vessel network, leaving no space for vessel-distant niches. By combining results from in vivo MP-IVM, in situ light-sheet fluorescence microscopy (LSFM) of the intact BM as well as computational simulations, surprisingly slow MK migration, limited intervascular space and a vessel-biased MK pool were revealed, contradicting the current concept of directed MK migration during thrombopoiesis.
Platelets play an essential role in hemostasis and thrombosis, but also in the pathogenesis of ischemic stroke. Ischemic stroke, which is mainly caused by thromboembolic occlusion of brain arteries, is among the leading causes of death and disability worldwide with limited treatment options. The platelet collagen receptor glycoprotein (GP) VI is a key player in arterial thrombosis and a critical determinant of stroke outcome, making its signaling pathway an attractive target for pharmacological intervention. The spleen tyrosine kinase (Syk) is an essential signaling mediator downstream of GPVI, but also of other platelet and immune cell receptors. In this thesis, it was demonstrated that mice lacking Syk specifically in platelets are protected from arterial thrombus formation and ischemic stroke, but display unaltered hemostasis. Furthermore, it was shown that mice treated with the novel, selective and orally bioavailable Syk inhibitor BI1002494 were protected in a model of arterial thrombosis and had smaller infarct sizes and a significantly better neurological outcome 24 h after transient middle cerebral artery occlusion (tMCAO), also when BI1002494 was administered therapeutically, i.e. after ischemia. These results provide direct evidence that pharmacological Syk inhibition might become a safe therapeutic strategy. The T cell receptor chain-associated protein kinase of 70 kDA (Zap-70) is also a spleen tyrosine kinase family member, but has a lower intrinsic activity compared to Syk and is expressed in T cells and natural killer (NK) cells, but not in platelets. Unexpectedly, arterial thrombus formation in vivo can occur independently of Syk kinase function as revealed by studies in Sykki mice, which express Zap-70 under the control of intrinsic Syk promoter elements.
Posttranslational modifications (PTMs) play a crucial role in many cellular processes. They are reversible, dynamic, and highly regulated events that alter the properties of proteins and increase their functional diversity. The identification and quantification of PTMs are critical for deciphering the molecular mechanisms of PTMs-related biological processes and disease treatment and prevention. Two of the most common and important PTMs that regulate many protein functions are acetylation and phosphorylation.
An important role of acetylation is the regulation of DNA/RNA-protein interactions. A prominent example for this are histones, whose tail regions are lysine-rich and can be highly acetylated at their N-terminal domain. In spite of the utmost importance of this PTM, methods that allow the accurate measuring the site-specific acetylation degree are missing. One of the challenges in quantifying the acetylation degree at an individual lysine residue of the histones N-termini is the occurrence of multiple lysines in close proximity. Herein, we describe the development of the ”Fragment Ion Patchwork Quantification,” a new mass spectrometry-based approach for the highly accurate quantification of sites-pecific acetylation degrees. This method combines 13C1-acetyl derivatization on the protein level, proteolysis by low-specificity proteases and quantification on the fragment ion level. Acetylation degrees are determined from the isotope patterns of acetylated b and y ions. We have shown that this approach allows determining the site-specific acetylation degrees of all lysine residues for all core histones of Trypanosoma brucei. In addition, we demonstrate the use of this approach to identify the substrate sites of histone acetyltransferases and to monitor the changes in acetylation of the histones of canonical nucleosome and transcription start site nucleosomes.
Phosphorylation is one of the most common and most important PTMs. The analysis of the human genome showed that there are about 518 kinases and more than 500,000 phosphorylation sites are believed to exist in the cellular proteome. Protein phosphorylation plays a crucial role in signaling many different cell processes, such as intercellular communication, cell growth, differentiation of proliferation and apoptosis. Whereas MS-based identification and relative quantification of singly phosphorylated peptides have been greatly improved during the last decade, and large-scale analysis of thousands of phosphopeptides can now be performed on a routine-base, the analysis of multi-phosphorylated peptides is still lagging vastly behind. The low pKa value of phosphate group and the associated negative charge are considered the major source of the problems with the analysis of
multi-phosphorylated peptides. These problems include the formation of phosphopeptide-metal complexes during liquid chromatography (e.g. Fe 3+), which leads to a drastic deterioration of the chromatographic properties of these peptides (peak tailing), the decreased ionization efficiencies of phosphorylated peptides compared to their unphosphorylated counterparts, the labile nature of phosphate during CID/HCD fragmentation, and the unsuitability of low-charged phosphopeptides for ETD fragmentation are the most important factors that hinder phosphorylation analysis by LC-MS/MS. Here we aimed to develop a method for improving the identification of multi-phosphorylated peptides as well as the localization of phosphorylation sites by charge-reversal derivatization of the phosphate groups. This method employs a carbodiimide-mediated phosphoramidation to converted the phosphates to stable aromatic phosphoramidates. This chemical modification of phosphosite(s) reversed the negative charge of the phosphate group(s) and increased the number of the positive charges within the phosphopeptide. This modification prevented the formation of phosphopeptide-metal ion complexes that dramatically decreases or completely diminishes the signal intensity of protonated phosphopeptides, specifically multi-phosphorylated peptides. Furthermore, the increased net charge the (phospho-)peptides made them suitable for ETD fragmentation, which generated a high number of fragment ions with high intensities that led to a better phosphopeptide identification and localization of phosphosite(s) with high confidence.
Platelets are continuously produced from megakaryocytes (MK) in the bone marrow by a cytoskeleton-driven process of which the molecular regulation is not fully understood.
As revealed in this thesis, MK/ platelet-specific Profilin1 (Pfn1) deficiency results in micro- thrombocytopenia, a hallmark of the Wiskott-Aldrich syndrome (WAS) in humans, due to accelerated platelet turnover and premature platelet release into the bone marrow. Both Pfn1-deficient mouse platelets and platelets isolated from WAS patients contained abnormally organized and hyper-stable microtubules. These results reveal an unexpected function of Pfn1 as a regulator of microtubule organization and point to a previously unrecognized mechanism underlying the platelet formation defect in WAS patients.
In contrast, Twinfilin2a (Twf2a) was established as a central regulator of platelet reactivity and turnover. Twf2a-deficient mice revealed an age-dependent macrothrombocytopenia that could be explained by a markedly decreased platelet half-life, likely due to the pronounced hyper-reactivity of \(Twf2a^{-/-}\) platelets. The latter was characterized by sustained integrin acti- vation and thrombin generation in vitro that translated into accelerated thrombus formation in vivo. To further elucidate mechanisms of integrin activation, Rap1-GTP-interacting adaptor molecule (RIAM)-null mice were generated. Despite the proposed critical role of RIAM for platelet integrin activation, no alterations in this process could be found and it was concluded that RIAM is dispensable for the activation of β1 and β3 integrins, at least in platelets. These findings change the current mechanistic understanding of platelet integrin activation.
Outside-in signaling by integrins and other surface receptors was supposed to regulate MK migration, but also the temporal and spatial formation of proplatelet protrusions. In this the- sis, phospholipase D (PLD) was revealed as critical regulator of actin dynamics and podo- some formation in MKs. Hence, the unaltered platelet counts and production in \(Pld1/2^{-/-}\) mice and the absence of a premature platelet release in the bone marrow of \(Itga2^{-/-}\) mice question the role of podosomes in platelet production and raise the need to reconsider the proposed inhibitory signaling by α2β1 integrins on proplatelet formation.
Non-muscle myosin IIA (NMMIIA) has been implicated as a downstream effector of the in- hibitory signals transmitted via α2β1 integrins. Besides Rho-GTPase signaling, also \(Mg^{2+}\) and transient receptor potential melastatin-like 7 (TRPM7) channel α-kinase are known regulators of NMMIIA activity. In this thesis, TRPM7 was identified as major regulator of \(Mg^{2+}\) homeostasis in MKs and platelets. Furthermore, decreased \([Mg^{2+}]_i\) led to deregulated NMMIIA activity and altered cytoskeletal dynamics that impaired thrombopoiesis and resulted in macrothrombocytopenia in humans and mice.
G protein-coupled receptors (GPCRs) are the major group of cell-surface receptors that transmit extracellular signals via classical, G protein-dependent pathways into the cell. Although GPCRs were long assumed to signal exclusively from the cell-surface, recent investigations have demonstrated a possibly completely new paradigm. In this new view, GPCR continues signaling via 3´,5´-cyclic adenosine monophosphate (cAMP) after their agonist-induced internalization of ligand/receptor complexes into an intracellular compartment, causing persistent cAMP elevation and apparently specific signaling outcomes. The thyroid stimulating hormone (TSH) receptor is one of the first GPCRs, which has been reported to show persistent signaling after ligand removal (Calebiro et al., 2009). In the meantime, signaling by internalized GPCR become a highly investigated topic and has been shown for several GPCRs, including the parathyroid hormone receptor (Ferrandon et al., 2009), D1 dopamine receptor (Kotowski et al., 2011) and beta2-adrenergic receptor (Irannejad et al., 2013). A recent study on the beta2-adrenergic receptor revealed that internalized receptor not only participates in cAMP signaling, but is also involved in gene transcription (Tsvetanova and von Zastrow, 2014). However, a biological effect of GPCR signaling at intracellular sites, which would demonstrate its physiological relevance, still remained to be shown.
To investigate GPCR signaling from intracellular compartment under physiological condition, two different cellular models were utilized in the present study: intact ovarian follicles expressing luteinizing hormone (LH) receptors and primary thyroid cells expressing TSH receptors.
Intact ovarian follicles were obtained from a transgenic mouse expressing, a Förster/Fluorescence Resonance Energy Transfer (FRET) sensor for cAMP to monitor cAMP/LH receptor signaling. This study provides the first accurate spatiotemporal characterization of cAMP signaling, which is derived from different cell layers of an intact ovarian follicle. Additionally, it could be shown that cAMP diffusion via gap junctions is implicated in spreading the LH-induced cAMP signals from one the outermost (mural granulosa) to the innermost (cumulus oophorus) cell layer of an ovarian follicle. Interestingly, LH receptor stimulation was associated with persistent cAMP signaling after LH removal and negligible desensitization of the cAMP signal. Interfering with receptor internalization with a dynamin inhibitor dynasore did not only prevent persistent LH-induced cAMP signaling, but also impaired the resumption of meiosis in follicle-enclosed oocytes, a key biological effect of LH.
In order to investigate the downstream activation of protein kinase A (PKA) in primary thyroid cells, FRET sensors with different subcellular localization (plasma membrane, cytosol and nucleus) were transiently transfected into primary thyroid cells of wild-type mice via electroporation. Interestingly, TSH stimulation causes at least two distinct phases of PKA activation in the global primary thyroid cell, which are temporally separated by approximately 2 min. In addition, PKA activation in different subcellular compartments are characterized by dissimilar kinetics and amplitudes. Pharmacological inhibition of TSH receptor internalization largely prevented the second (i.e. late) phase of PKA activation as well as the subsequent TSH-dependent phosphorylation of CREB and TSH-dependent induction of early genes. These results suggest that PKA activation and nuclear signaling require internalization of the TSH receptor.
Taken together, the data of the present study provide strong evidence that GPCR signaling at intracellular sites is distinct from the one occurring at the cell-surface and is highly physiologically relevant.
Several important cellular processes, including transcription, nucleotide excision repair and cell cycle control are mediated by the multifaceted interplay of subunits within the general transcription factor II H (TFIIH).
A better understanding of the molecular structure of TFIIH is the key to unravel the mechanism of action of this versatile protein complex within these pathways. This becomes especially important in the context of severe diseases like xeroderma pigmentosum, Cockayne syndrome and trichothiodystrophy, that arise from single point mutations in some of the TFIIH subunits.
In an attempt to structurally characterize the TFIIH complex, we harnessed the qualities of the eukaryotic thermophile Chaetomium thermophilum, a remarkable fungus, which has only recently been recognized as a novel model organism. Homologues of TFIIH from C. thermophilum were expressed in E. coli, purified to homogeneity and subsequently utilized for crystallization trials and biochemical studies.
The results of the present work include the first crystal structure of the p34 subunit of TFIIH, comprising the N-terminal domain of the protein. The structure revealed a von Willebrand Factor A (vWA) like fold, which is generally known to be involved in a multitude of protein-protein interactions. Structural comparison allowed to delineate similarities as well as differences to already known vWA domains, providing insight into the role of p34 within TFIIH. These results indicate that p34 assumes the role of a structural scaffold for other TFIIH subunits via its vWA domain, while likely serving additional functions, which are mediated through its
C-terminal zinc binding domain and are so far unknown.
Within TFIIH p34 interacts strongly with the p44 subunit, a positive regulator of the XPD helicase, which is required for regulation of RNA Polymerase II mediated transcription and essential for eukaryotic nucleotide excision repair. Based on the p34 vWA structure putative protein-protein interfaces were analyzed and binding sites for the p34 p44 interaction suggested. Continuous crystallization efforts then led to the first structure of a p34 p44 minimal complex, comprising the N-terminal vWA domain of p34 and the C-terminal C4C4 RING domain of p44. The structure of the p34 p44 minimal complex verified the previous hypothesis regarding the involved binding sites. In addition, careful analysis of the complex interface allowed to identify critical residues, which were subsequently mutated and analyzed with respect to their significance in mediating the p34 p44 interaction, by analytical size exclusion chromatography, electrophoretic mobility shift assays and isothermal titration calorimetry. The structure of the p34 p44 complex also revealed a binding mode of the p44 C4C4 RING domain, which differed from that of other known RING domains in several aspects, supporting the hypothesis that p44 contains a novel variation of this domain.
Role of Hypoxia-Inducible Factor (HIF) 1α in Dendritic Cells in Immune Regulation of Atherosclerosis
(2013)
Atherosclerosis is the underlying cause of cardiovascular diseases and a major threat to human health worldwide. It involves not only accumulation of lipids in the vessel wall but a chronic inflammatory response mediated by highly specific cellular and molecular responses. Macrophages and dendritic cells (DCs) play an essential role in taking up modified lipids and presenting them to T and B lymphocytes, which promote the immune response. Enhanced activation, migration and accumulation of inflammatory cells at the local site leads to formation of atherosclerotic plaques.
Atherosclerotic plaques become hypoxic due to reduced oxygen diffusion and high metabolic demand of accumulated cells. The various immune cells experience hypoxic conditions locally and inflammatory stimuli systemically, thus up-regulating Hypoxia-inducible factor 1α. Though the role of HIF1α in macrophages and lymphocytes has been elucidated, its role in DCs still remains controversial, especially with respect to atherosclerosis. In this project work, the role of HIF1α in DCs was investigated by using a cell specific knockout mouse model where HIF1α was deleted in CD11c+ cells.
Aortic root sections from atherosclerotic mice showed presence of hypoxia and up-regulation of HIF1α which co-localized with CD11c+ cells. Atherosclerotic splenic DCs also displayed enhanced expression of HIF1α, proving non-hypoxic stimulation of HIF1α due to systemic inflammation. Conditional knockout (CKO) mice lacking HIF1α in CD11c+ cells, under baseline conditions did not show changes in immune responses suggesting effects of HIF1α only under inflammatory conditions. When these mice were crossed to the Ldlr-/- line and placed on 8 weeks of high fat diet, they developed enhanced plaques with higher T-cell infiltration as compared to the wild-type (WT) controls. The plaques were of a complex phenotype, defined by increased percent of smooth muscle cells (SMCs) and necrotic core area and reduced percent of macrophages and DCs. The mice also displayed enhanced T-cell activation and a Th1 bias in the periphery.
The CKO DCs themselves exhibited increased expression of IL 12 and a higher capacity to proliferate and polarize naive T cells to the Th1 phenotype in vitro. The DCs also showed decreased expression of STAT3, in line with the inhibitory effects of STAT3 on DC activation seen in previous studies. When STAT3 was overexpressed in DCs in vitro, IL 12 was down-regulated, but its expression increased significantly on STAT3 inhibition using a mutant vector. In addition, when STAT3 was overexpressed in DCs in vivo using a Cre regulated lentiviral system, the mice showed decreased plaque formation compared to controls. Interestingly, the effects of STAT3 modulation were similar in WT and CKO mice, intending that STAT3 lies downstream of HIF1α. Finally, using a chromatin immunoprecipitation assay (ChIP), it was confirmed that HIF1α binds to hypoxia responsive elements (HREs) in the Stat3 gene promoter thus regulating its expression. When DCs lack HIF1α, STAT3 expression is not stimulated and hence IL 12 production by DCs is uninhibited. This excessive IL 12 can activate naive T cells and polarize them to the Th1 phenotype, thereby enhancing atherosclerotic plaque progression.
This project thus concludes that HIF1α restrains DC activation via STAT3 generation and prevents excessive production of IL 12 that helps to keep inflammation and atherosclerosis under check.
Studies on receptor signaling and regulation in platelets and T cells from genetically modified mice
(2014)
Receptors with tyrosine-based signaling motifs control essential functions of hematopoietic cells, including lymphocytes and platelets. Downstream of the platelet receptor glycoprotein (GP) VI and the T cell receptor (TCR) the immunoreceptor tyrosine-based activation motif (ITAM) initiates a signaling cascade that involves kinases, adapter and effector proteins and finally leads to cellular activation. This thesis summarizes the results of three studies investigating different aspects of receptor signaling and regulation in platelets and T cells.
In the first part, the impact of constitutive Ca2+ influx on TCR signaling and T cell physiology was investigated using a transgenic mouse line with a mutation in the Ca2+ sensor stromal interaction molecule 1 (STIM1). The elevated cytoplasmic Ca2+ level resulted in an altered phosphorylation pattern of the key enzyme phospholipase (PL) Cγ1 in response to TCR stimulation, but without affecting its enzymatic activity. Withdrawal of extracellular Ca2+ or inhibition of the phosphatase calcineurin restored the normal phosphorylation pattern. In addition, there was a decrease in the release of Th2-type cytokines interleukin 4, 5 and 13 upon stimulation in vitro.
The second part of the thesis deals with the role of the adapter protein growth factor receptor-bound protein 2 (Grb2) in platelets using a megakaryocyte/platelet-specific knockout mouse line. Loss of Grb2 severely impaired signaling of GPVI and C-type lectin-like receptor 2 (CLEC-2), a related hemITAM receptor. This was attributed to defective stabilization of the linker for activation of T cells (LAT) signalosome and resulted in reduced adhesion, aggregation, Ca2+ mobilization and procoagulant activity downstream of (hem)ITAM-coupled receptors in vitro. In contrast, the signaling pathways of G protein-coupled receptors (GPCRs) and the integrin αIIbβ3, which do not utilize the LAT signalosome, were unaffected. In vivo, the defective (hem)ITAM signaling caused prolonged bleeding times, however, thrombus formation was only affected under conditions where GPCR signaling was impaired (upon acetylsalicylic acid treatment). These results establish Grb2 as an important adapter protein in the propagation of GPVI- and CLEC-2-induced signals.
Finally, the proteolytic regulation of the immunoreceptor tyrosine-based switch motif (ITSM)-bearing receptor CD84 in platelets was investigated. This study demonstrated that in mice CD84 is cleaved by two distinct and independent proteolytic mechanisms upon platelet activation: shedding of the extracellular part, which is exclusively mediated by a disintegrin and metalloproteinase (ADAM) 10 and cleavage of the intracellular C-terminus by the protease calpain. Finally, the analysis of soluble CD84 levels in the plasma of transgenic mice revealed that shedding of CD84 by ADAM10 occurs constitutively in vivo.
Whereas most currently used antibiotics act by interfering with essential bacterial processes, a smaller group of antibacterials disturbs the integrity of the cell membrane. Since fatty acids are a vital component of membrane phospholipids, the type-II fatty acid biosynthesis pathway (FAS-II) of bacteria constitutes a promising drug target. The front-line anti-tuberculosis prodrug isoniazid blocks the FAS-II pathway in M. tuberculosis thereby leading to morphological changes and finally to cell lysis. When it became evident that the enoyl-ACP reductase in the FAS-II pathway is the target of the activated isoniazid, several programs were initiated to develop novel inhibitors directed against this protein in different pathogens. The S. aureus enoyl-ACP reductase (saFabI) is of particular interest since three promising drug candidates inhibiting this homologue have reached clinical trials. However, despite these prospects, no crystal structures of saFabI were publicly available at the time the present work was initiated. Thus, one major goal of this thesis was the generation of high-resolution atomic models by means of X-ray crystallography. The development of a highly reproducible approach to co-crystallize saFabI in complex with NADP+ and diphenyl ether-based inhibitors led to crystal structures of 17 different ternary complexes. Additional crystallographic experiments permitted the view into two apo-structures and two atomic models of saFabI in complex with NADPH and 2-pyridone inhibitors. Based on the established saFabI structure, molecular dynamics (MD) simulations were performed to improve our understanding of the conformational mobility of this protein. Taken together, these investigations of the saFabI structure and its flexibility served as an ideal platform to address important questions surrounding substrate and inhibitor recognition by this enzyme. Intriguingly, our saFabI structures provide several vastly different snapshots along the reaction coordinate of ligand binding and hydride transfer, including the closure of the flexible substrate binding loop (SBL). The extraordinary mobility of saFabI was confirmed by MD simulations suggesting that conformational motions indeed play a pivotal role during substrate delivery and turnover. A water chain linking the active site with a water-basin inside the homo-tetrameric enzyme was found likely to be crucial for the closure and opening of the SBL and, thus, for the catalyzed reaction. Notably, the induced-fit ligand binding process involves a dimer-tetramer transition, which could be related to the observed positive cooperativity of cofactor and substrate binding. Overall, saFabI displays several unique characteristics compared to FabI proteins from other organisms that might be necessary for the synthesis of branched-chain fatty acids, which in turn are required for S. aureus fitness in vivo. This finding may explain why S. aureus is sensitive to FAS-II inhibitors even in the presence of exogenous fatty acids. Accordingly, saFabI remains a valid drug target and our structures can be used as a molecular basis for rational drug design efforts. In fact, binding affinity trends of diphenyl ether inhibitors and, more importantly, the correlated residence times could be rationalized at the molecular level. Furthermore, the structure of saFabI in complex with the 2-pyridone inhibitor CG400549 revealed unique interactions in the wider binding crevice of saFabI compared to other FabI homologues explaining the narrow activity spectrum of this clinical candidate with proven human efficacy. In summary, these studies provide an ideal platform for the development of new, effective saFabI inhibitors as exemplified by the promising 4-pyridone PT166. In the context of this dissertation, crystal structures of the condensing enzyme KasA in complex with several analogs of the naturally occurring inhibitor thiolactomycin have been solved.
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.
Spreading drug resistances among Gram-negative pathogens and the paucity of new agents on the antibacterial drug market against these tenacious bacteria create a pressing need for the development of new antibiotics. The bacterial fatty acid biosynthesis pathway FAS-II, especially the enoyl-ACP reductase catalyzing the last step of the elongation cycle, is an established drug target against tuberculosis but has not been extensively exploited for drug design against other bacterial pathogens. In this thesis the enoyl-ACP reductases of the Gram-negative biothreat organisms Burkholderia pseudomallei and Yersinia pestis were targeted in a structure-based drug design approach. The structure of the most recently identified enoyl-ACP isoenzyme FabV was characterized by X-ray crystallography and could be determined in three different states. FabV from B. pseudomallei was obtained in the apo-form of the enzyme, whereas FabV from Y. pestis was characterized in a binary complex with the cofactor NADH as well as in a ternary complex with NADH and the triclosan-based 2-pyridone inhibitors PT172 and PT173. Analysis of the FabV structure revealed the typical fold of the short chain dehydrogenase/reductase superfamily with the NADH-binding Rossmann fold and a substrate-binding pocket with a conserved active site geometry compared to the related isoenzyme FabI. Additional structural elements of FabV are located around the active site. The monomeric form of the enzyme is thereby stabilized and the substrate-binding loop is kept in a closed, helical conformation. The ternary complexes of FabV exhibited a similar inhibitor-binding mode as observed for triclosan inhibition in FabI and point to a potential substrate-binding mechanism. B. pseudomallei possesses FabI as an additional enoyl-ACP reductase isoenzyme, which was structurally characterized in the apo form and in ternary complexes with NAD+ and the diphenyl ether inhibitors triclosan, PT02, PT12 or PT404 as well as the 4-pyridone inhibitor PT155. The structural data of the ternary enoyl-ACP reductases complexes of B. pseudomallei and Y. pestis hold the promise for the possibility to develop antibacterials targeting FabV or even both isoenzymes, FabI and FabV, based on the triclosan scaffold.
Atherosclerosis is accepted to be a chronic inflammatory disease of the arterial vessel wall. Several cellular subsets of the immune system are involved in its initiation and progression, such as monocytes, macrophages, T and B cells. Recent research has demonstrated that dendritic cells (DCs) contribute to atherosclerosis, too. DCs are defined by their ability to sense and phagocyte antigens, to migrate and to prime other immune cells, such as T cells. Although all DCs share these functional characteristics, they are heterogeneous with respect to phenotype and origin. Several markers have been used to describe DCs in different lymphoid and non-lymphoid organs; however, none of them has proven to be unambiguous. The expression of surface molecules is highly variable depending on the state of activation and the surrounding tissue. Furthermore, DCs in the aorta or the atherosclerotic plaque can be derived from designated precursor cells or from monocytes. In addition, DCs share both their marker expression and their functional characteristics with other myeloid cells like monocytes and macrophages. The repertoire of aortic DCs in healthy and atherosclerotic mice has just recently started to be explored, but yet there is no systemic study available, which describes the aortic DC compartment. Because it is conceivable that distinct aortic DC subsets exert dedicated functions, a detailed description of vascular DCs is required. The first part of this thesis characterizes DC subsets in healthy and atherosclerotic mice. It describes a previously unrecognized DC subset and also sheds light on the origin of vascular DCs. In recent years, microRNAs (miRNAs) have been demonstrated to regulate several cellular functions, such as apoptosis, differentiation, development or proliferation. Although several cell types have been characterized extensively with regard to the miRNAs involved in their regulation, only few studies are available that focus on the role of miRNAs in DCs. Because an improved understanding of the regulation of DC functions would allow for new therapeutic options, research on miRNAs in DCs is required. The second part of this thesis focuses on the role of the miRNA cluster miR- 17~92 in DCs by exploring its functions in healthy and atherosclerotic mice. This thesis clearly demonstrates for the first time an anti-inflammatory and atheroprotective role for the miR17-92 cluster. A model for its mechanism is suggested.
Platelet activation and aggregation at sites of vascular injury are essential processes to limit blood loss but they also contribute to arterial thrombosis, which can lead to myocardial infarction and stroke. Stable thrombus formation requires a series of events involving platelet receptors which contribute to adhesion, activation and aggregation of platelets. Regulation of receptor expression by (metallo-)proteinases has been described for several platelet receptors, but the molecular mechanisms are ill-defined. The signaling lymphocyte activation molecule (SLAM) family member CD84 is expressed in immune cells and platelets, however its role in platelet physiology was unclear. In this thesis, CD84 deficient mice were generated and analyzed. In well established in vitro and in vivo assays testing platelet function and thrombus formation, CD84 deficient mice displayed phenotypes indistinguishable from wild-type controls. It was concluded that CD84 in platelets does not function as modulator of thrombus formation, but rather has other functions. In line with this, in the second part of this thesis, a novel regulation mechanism for platelet CD84 was discovered and elucidated. Upon platelet activation, the N-terminus of CD84 was found to be cleaved exclusively by the a disintegrin and metalloproteinase 10 (ADAM10), whereas the intracellular part was cleaved by calpain. In addition, regulation of the platelet activating collagen receptor glycoprotein VI (GPVI) was studied and it was shown that GPVI is in contrast to CD84 differentially regulated by ADAM10 and ADAM17. A novel role of CD84 under pathophysiological conditions was revealed as CD84 deficient mice were protected from ischemic stroke in the model of transient middle cerebral artery occlusion and this protection was based on the lack of CD84 in T cells. Ca2+ is an essential second messenger that facilitates activation of platelets and diverse functions in different eukaryotic cell types. Store-operated Ca2+ entry (SOCE) represents the major mechanism leading to rise in intracellular Ca2+ concentration in non-excitable cells. The Ca2+ sensor STIM1 (stromal interaction molecule 1) and the SOC channel subunit protein Orai1 are established mediators of SOCE in platelets. STIM2 is the major STIM isoform in neurons, but the role of the SOC channel subunit protein Orai2 in platelets and neurons has remained elusive. In the third part of this thesis, Orai2 deficient mice were generated and analyzed. Orai2 was dispensable for platelet function, however, Orai2 deficient mice were protected from ischemic neurodegeneration and this phenotype was attributed to defective SOCE in neurons.
Pro-migratory signals mediated by the tumor microenvironment contribute to the cancer progression cascade, including invasion, metastasis and resistance to therapy. Derived from in vitro studies, isolated molecular steps of cancer invasion programs have been identified but their integration into the tumor microenvironment and suitability as molecular targets remain elusive. The purpose of the study was to visualize central aspects of tumor progression, including proliferation, survival and invasion by real-time intravital microscopy. The specific aims were to monitor the kinetics, mode, adhesion and chemoattraction mechanisms of tumor cell invasion, the involved guidance structures, and the response of invasion zones to anti-cancer therapy. To reach deeper tumor regions by optical imaging with subcellular resolution, near-infrared and infrared excited multiphoton microscopy was combined with a modified dorsal skinfold chamber model. Implanted HT-1080 fibrosarcoma and B16/F10 and MV3 melanoma tumors developed zones of invasive growth consisting of collective invasion strands that retained cell-cell contacts and high mitotic activity while invading at velocities of up to 200 μm per day. Collective invasion occurred predominantly along preexisting tissue structures, including blood and lymph vessels, collagen fibers and muscle strands of the deep dermis, and was thereby insensitive to RNAi based knockdown and/or antibody-based treatment against β1 and β3 integrins, chemokine (SDF-1/CXCL12) and growth factor (EGF) signaling. Therapeutic hypofractionated irradiation induced partial to complete regression of the tumor main mass, yet failed to eradicate the collective invasion strands, suggesting a microenvironmentally privileged niche. Whereas no radiosensitization was achieved by interference with EGFR or doxorubicin, the simultaneous inhibition of β1 and β3 integrins impaired cell proliferation and survival in spontaneously growing tumors and strongly enhanced the radiation response up to complete eradication of both main tumor and invasion strands. In conclusion, collective invasion in vivo is a robust process which follows preexisting tissue structures and is mainly independent of established adhesion and chemoattractant signaling. Due to its altered biological response to irradiation, collective invasion strands represent a microenvironmentally controlled and clinically relevant resistance niche to therapy. Therefore supportive regimens, such as anoikisinduction by anti-integrin therapy, may serve to enhance radio- and chemoefficacy and complement classical treatment regimens.
Thrombus formation at sites of vascular lesions is a dynamic process that requires a defined series of molecular events including the action of platelet adhesion/activation receptors, intracellular signal transduction, cytoskeletal rearrangements and activation of plasma coagulation factors. This process is essential to limit post-traumatic blood loss but may also contribute to acute thrombotic diseases such as myocardial infarction and stroke. With the help of genetically modified mice and the use of specific protein inhibitors and receptordepleting antibodies, the work presented in this thesis identified novel mechanisms underlying thrombus formation in hemostasis and thrombosis. In the first part of the study, it was shown that von Willebrand Factor (vWF) binding to glycoprotein (GP)Iba is critical for the formation of stable pathological thrombi at high shear rates, suggesting GPIba as an attractive pharmacological target for antithrombotic therapy. The subsequent analysis of recently generated phospholipase (PL)D1-deficient mice identified this enzyme, whose role in platelet function had been largely unknown, as a potential target protein downstream of GPIba. This was based on the finding that PLD1- deficient mice displayed severely defective GPIba-dependent thrombus stabilization under high shear conditions in vitro and in vivo without affecting normal hemostasis. The second part of the thesis characterizes the functional relevance of the immunoreceptor tyrosine-based activation motif (ITAM)-bearing collagen receptor GPVI and the recently identified hemITAM-coupled C-type lectin-like receptor 2 (CLEC-2) for in vivo thrombus formation. Genetic- and antibody-induced GPVI deficiency was found to similarly protect mice from arterial vessel occlusion in three different thrombosis models. These results confirmed GPVI as a promising antithrombotic target and revealed that antibody-treatment had no obvious off-target effects on platelet function. Similarly, immunodepletion of CLEC-2 by treating mice with the specific antibody INU1 resulted in markedly impaired thrombus growth and stabilization under flow in vitro and in vivo. Furthermore, it could be demonstrated that double-immunodepletion of GPVI and CLEC-2 resulted in severely decreased arterial thrombus formation accompanied by dramatically prolonged bleeding times. These data revealed an unexpected redundant function of the two receptors for in vivo thrombus formation and might have important implications for the potential development of anti-GPVI and anti-CLEC-2 antithrombotic agents. The third part of the thesis provides the first functional analysis of megakaryocyte- and platelet-specific RhoA knockout mice. RhoA-deficient mice displayed a defined signaling defect in platelet activation, leading to a profound protection from arterial thrombosis andand ischemic brain infarction, but at the same time also strongly increased bleeding times. These findings identified the GTPase as an important player for thrombus formation in hemostasis and thrombosis. Based on the previous proposal that the coagulation factor (F)XII might represent an ideal target for safe antithrombotic therapy without causing bleeding side effects, the last part of this thesis assesses the antithrombotic potential of the newly generated FXIIa inhibitor rHAInfestin- 4. It was found that rHA-Infestin-4 injection into mice resulted in virtually abolished arterial thrombus formation but no change in bleeding times. Moreover, rHA-Infestin-4 was similarly efficient in a murine model of ischemic stroke, suggesting that the inhibitor might be a promising agent for effective and safe therapy of cardio- and cerebrovascular diseases.
Investigation on Distinct Roles of Smad Proteins in Mediating Bone Morphogenetic Proteins Signals
(2011)
Bone morphogenetic proteins (BMPs) belong to the transforming growth factor-β (TGF-β) superfamily and play important roles in numerous biological events in the development of almost all multi-cellular organisms. Dysregulated BMP signaling is the underlying causes of numerous heritable and non-heritable human diseases including cancer. The vast range of biological responses induced by BMPs converges on three closely related Smad proteins that convey intracellular signals from BMP receptors to the nucleus. The specificity of BMP signaling has been intensively investigated at the level of ligand-receptor interactions, but how the different Smad proteins contribute to differential signals elicited by BMPs remains unclear. In this work, we investigated the BMP/Smad signaling in different aspects. In search for an appropriate fluorescence reporter in zebrafish, we compared different photo-switchable proteins and found EosFP the best candidate this model system for its fast maturation and fluorescence intensity. We modified and created appropriate vectors enabling Tol2-transposon based trangenesis in zebrafish, with which transgenic zebrafish lines were generated. We combined fluorescence protein tagging with high resolution microscopy and investigate the dynamics of Smad proteins in model system zebrafish. We observed that Smad5 undergoes nucleo-translocation as BMP signal transmitter during zebrafish gastrulation. We explored the Smad involvement during myogenic-to-osteogenic conversion of C2C12 cell line induced by BMP4. We created transient loss-of-function of Smads by siRNA-mediated knockdowns and analyzed the effects on these coupled yet distinct procedures by quantitative real-time PCR and terminal marker staining. We found that different Smad-complex stoichiometry might be responsible for distinct cellular signals elicited by BMPs.
Platelet activation and adhesion results in thrombus formation that is essential for normal hemostasis, but can also cause irreversible vessel occlusion leading to myocardial infarction or stroke. The C-type lectin-like receptor 2 (CLEC-2) was recently identified to be expressed on the platelet surface, however, a role for this receptor in hemostasis and thrombosis had not been demonstrated. In the current study, the involvement of CLEC-2 in platelet function and thrombus formation was investigated using mice as a model system. In the first part of the thesis, it was found that treatment of mice with a newly generated monoclonal antibody against murine CLEC-2 (INU1) led to the complete and highly specific loss of the receptor in circulating platelets (a process termed “immunodepletion”). CLEC-2-deficient platelets were completely unresponsive to the CLEC-2-specific agonist rhodocytin, whereas activation induced by all other tested agonists was unaltered. This selective defect translated into severely decreased platelet aggregate formation under flow ex vivo; and in vivo thrombosis models revealed impaired stabilization of formed thrombi with enhanced embolization. Consequently, CLEC-2 deficiency profoundly protected mice from occlusive arterial thrombus formation. Furthermore, variable bleeding times in INU1-treated mice indicated a moderate hemostatic defect. This reveals for the first time that CLEC-2 significantly contributes to thrombus stability in vitro and in vivo and plays a crucial role in hemostasis and arterial thrombosis. Thus, CLEC-2 represents a potential novel anti-thrombotic target that can be functionally inactivated in vivo. This in vivo down-regulation of platelet surface receptors might be a promising approach for future anti-thrombotic therapy. The second part of the work investigated the effect of double-immunodepletion of the immunoreceptor tyrosine-based activation motif (ITAM)- and hemITAM-coupled receptors, platelet glycoprotein (GP) VI and CLEC-2, on hemostasis and thrombosis using a combination of the GPVI- and CLEC-2-specific antibodies, JAQ1 and INU1, respectively. Isolated targeting of either GPVI or CLEC-2 in vivo did not affect expression or function of the respective other receptor. However, simultaneous treatment with both antibodies resulted in the sustained loss of GPVI and CLEC-2 signaling in platelets, while leaving other activation pathways intact. In contrast to single deficiency of either receptor, GPVI/CLEC-2 double-deficient mice displayed a dramatic hemostatic defect. Furthermore, this treatment resulted in profound impairment of arterial thrombus formation that far exceeded the effects seen in single-depleted animals. Importantly, similar results were obtained in Gp6-/- mice that were depleted of CLEC-2 by INU1-treatment, demonstrating that this severe bleeding phenotype was not caused by secondary effects of combined antibody treatment. These data suggest that GPVI and CLEC-2 can be independently or simultaneously down-regulated in platelets in vivo and reveal an unexpected functional redundancy of the two receptors in hemostasis and thrombosis. Since GPVI and CLEC-2 have intensively been discussed as potential anti-thrombotic targets, these results may have important implications for the development of novel, yet save anti-GPVI or anti-CLEC-2-based therapies.
Upon synthesis, nascent polypeptide chains are subject to major rearrangements of their side chains to obtain an energetically more favorable conformation in a process called folding. About one third of all cellular proteins pass through the secretory pathway and undergo oxidative folding in the endoplasmic reticulum (ER). During oxidative folding, the conformational rearrangements are accompanied by the formation of disulfide bonds – covalent bonds between cysteine side chains that form upon oxidation. Protein disulfide isomerase (PDI) assists in the folding of substrates by catalyzing the oxidation of pairs of cysteine residues and the isomerization of disulfide bonds as well as by acting as chaperones. In addition to PDI itself, a family of related ER-resident proteins has formed. All PDI family members share the thioredoxin fold in at least one of their domains and exhibit a subset of the PDI activities. Despite many studies, the role of most PDI family members remains unclear. The project presented in this thesis was aimed to establish tools for the biochemical characterization of single members of the PDI family and their role in the folding process. A combination of fluorescence based assays was developed to selectively study single functions of PDI family members and relate their properties of either catalysis of oxidation or catalysis of isomerization or chaperone activity to the rest of the protein family. A binding assay using isothermal titration calorimetry (ITC) was established to complement the activity assays. Using ITC we could show for the first time that members of the PDI family can distinguish between folded and unfolded proteins selectively binding the latter. The unique information provided by this method also revealed a two-site binding of unfolded proteins by PDI itself. In addition to the functional characterization, experiments were conducted to further investigate the oligomeric state of PDI. We could show that the equilibrium between structurally different states of PDI is heavily influenced by the redox state of the protein and its environment. This new data could help to further our understanding of the interplay between oxidases like PDI and their regenerative enzymes like Ero1, which may be governed by structural changes in response to the change in redox status. Another structural approach was the screening of all investigated PDI family members for suitable crystallization conditions. As a result of this screening we could obtain protein crystals of human ERp27 and were able to solve the structure of this protein with X-ray crystallography. The structure gives insight into the mechanisms of substrate binding domains within the PDI family and helps to understand the interaction of ERp27 with the redox active ERp57. In collaboration with the group of Heike Hermanns we could further show the physiological importance of this interaction under oxidative stress. In conclusion, the project presented in this thesis provides novel tools for an extensive analysis of the activities of single PDI family members as well as a useful set of methods to characterize novel oxidoreductases and chaperones. The initial results obtained with the our novel methods are very promising. At the same time, the structural approach of this project could successfully solve the structure of a PDI family member and give information about the interplay within the PDI family.
Platelet activation induces cytoskeletal rearrangements involving a change from discoid to spheric shape, secretion, and eventually adhesion and spreading on immobilized ligands. Small GTPases of the Rho family, such as Rac1 and Cdc42, are known to be involved in these processes by facilitating the formation of lamellipodia and filopodia, respectively. This thesis focuses on the role Rac1 and Cdc42 for platelet function and formation from their precursor cells, the megakaryocytes (MKs), using conditional knock-out mice. In the first part of the work, the involvement of Rac1 in the activation of the enzyme phospholipase (PL) C2 in the signaling pathway of the major platelet collagen receptor glycoprotein (GP) VI was investigated. It was found that Rac1 is essential for PLC2 activation independently of tyrosine phosphorylation of the enzyme, resulting in a specific platelet activation defect downstream of GPVI, whereas signaling of other activating receptors remains unaffected. Since Rac1-deficient mice were protected from arterial thrombosis in two different in vivo models, the GTPase might serve as a potential target for the development of new drugs for the treatment and prophylaxis of cardio- and cerebrovascular diseases. The second part of the thesis deals with the first characterization of MK- and platelet-specific Cdc42 knock-out mice. Cdc42-deficient mice displayed mild thrombo-cytopenia and platelet production from mutant MKs was markedly reduced. Unexpectedly, Cdc42-deficient platelets showed increased granule content and release upon activation, leading to accelerated thrombus formation in vitro and in vivo. Furthermore, Cdc42 was not generally required for filopodia formation upon platelet activation. Thus, these results indicate that Cdc42, unlike Rac1, is involved in multiple signaling pathways essential for proper platelet formation and function. Finally, the outcome of combined deletion of Rac1 and Cdc42 was studied. In contrast to single deficiency of either GTPase, platelet production from double-deficient MKs was virtually abrogated, resulting in dramatic macrothrombocytopenia in the animals. Formed platelets were largely non-functional leading to a severe hemostatic defect and defective thrombus formation in double-deficient mice in vivo. These results demonstrate for the first time a functional redundancy of Rac1 and Cdc42 in the hematopoietic system.
XPD is a 5‘-3‘ helicase of the superfamily 2. As part of the transcription factor IIH it functions in transcription initiation and nucleotide excision repair. This work focus on the role of XPD in nucleotide excision repair. NER is a DNA repair pathway unique for its broad substrate range. In placental mammals NER is the only repair mechanism able to remove lesions induced by UV-light. NER can be divided into four different steps that are conserved between pro- and eukaryotes. Step 1 consists of the initial damage recognition, during step 2 the putative damage is verified, in step 3 the verified damage is excised and in the 4th and final step the resulting gap in the DNA is refilled. XPD was shown to be involved in the damage verification step. It was possible to solve the first apo XPD structure by a MAD approach using only the endogenous iron from the iron sulfur cluster. Based on the apo XPD structure several questions arise: where is DNA bound? Where is DNA separated? How is damage verification achieved? What is the role of the FeS cluster? These questions were addressed in this work. Hypothesis driven structure based functional mutagenesis was employed and combined with detailed biochemical characterization of the variants. The variants were analyzed by thermal unfolding studies to exclude the possibility that the overall stability could be affected by the point mutation. DNA binding assays, ATPase assays and helicase assays were performed to delineate amino acid residues important for DNA binding, helicase activity and damage recognition. A structure of XPD containing a four base pair DNA fragment was solved by molecular replacement. This structure displays the polarity of the translocated strand with respect to the helicase framework. Moreover the properties of the FeS cluster were studied by electron paramagnetic resonance to get insights into the role of the FeS cluster. Furthermore XPD from Ferroplasma acidarmanus was investigated since it was shown that it is stalled at CPD containing lesions. The data provide the first detailed insight into the translocation mechanism of a SF2B helicase and reveal how polarity is achieved. This provides a basis for further anlayses understanding the combined action of the helicase and the 4Fe4S cluster to accomplish damage verification within the NER cascade.
Type 1 diabetes is an autoimmune disease that leads to the destruction of insulin-producing pancreatic beta cells and consequently to hyperglycemia. In the last 60 years, the prevalence of type 1 diabetes has been increasing constantly and is predicted to continue rising. About 80% of the disease risk is attributable to the genetic variation. Thanks to genome wide association studies the number of known disease-associated polymorphisms climbed from five to 53 in the last 10 years. As these studies reveal possible candidate genes but not underlying mechanisms we strove to take the next step and explore the association of two genes suggested by these studies with type 1 diabetes. As a method of choice we decided to use lentiviral RNAi in non obese diabetic (NOD) mice, a widely-used model for type 1 diabetes, introducing a shRNA directed against the target message into the genome of this mouse strain via a lentivirus. This allowed us to study the partial loss-of-function of the target gene within the context of diabetes, directly seeing its effect on autoimmune mechanisms. In this thesis we examined two different genes in this manner, Ctla4 and Clec16a. A type 1 diabetes associated polymorphism in the CTLA4 gene had been found to alter the splicing ratio of its variants soluble CTLA-4 (sCTLA-4) and full length CTLA-4, the associated allele producing less sCTLA-4 than the protective allele. We mimicked this effect by specifically targeting the sCtla4 mRNA via lentiviral RNAi in the NOD model. As a result we could confirm the reduction of sCTLA-4 to accelerate type 1 diabetes development. Furthermore we could show a function of sCTLA-4 in regulatory T cells, more specifically at least partly in their ability to modulate costimulation by antigen presenting cells. The second candidate gene, Clec16a was targeted with the shRNA in a way that was designed to knock down most splice variants. As the gene function and the effect of the associated SUMMARY 10 polymorphism was unknown, we reasoned this method to be feasible to investigate its role in type 1 diabetes. The knockdown of Clec16a in NOD mice resulted in an almost complete protection from diabetes development that could be attributed to T cells dysfunction. However, as expression patterns and a study of the Drospophila orthologue suggested a possible role of CLEC16A in antigen presentation we also examined antigen presenting cells in the thymus and periphery. Although we did not detect any effect of the knockdown on peripheral antigen presenting cells, thymic epithelial cells were clearly affected by the loss of CLEC16A, rendering them more activated and shifting the ratio of cortical to medullary epithelial cells in favor of cortical cells. We therefore suggest a role of CLEC16A in the selection of T cells, that needs, however, to be further investigated. In this thesis we provided a feasible and fast method to study function of genes and even of single splice variants within the NOD mouse model. We demonstrate its usefulness on two candidate genes associated with type 1 diabetes by confirming and unraveling the cause of their connection to the disease.
PTPN22 encodes the lymphoid tyrosine phosphatase Lyp that can dephosphorylate Lck, ZAP-70 and Fyn to attenuate TCR signaling. A single-nucleotide polymorphism (C1858T) causes a substitution from arginine (R) to tryptophan (W) at 620 residue (R620W). Lyp-620W has been confirmed as a susceptible allele in multiple autoimmune diseases, including type 1 diabetes (T1D). Several independent studies proposed that the disease-associated allele is a gain-of-function variant. However, a recent report found that in human cells and a knockin mouse containing the R620W homolog that Ptpn22 protein degradation is accelerated, indicating Lyp-620W is a loss-of-function variant. Whether Lyp R620W is a gain- or loss-of-function variant remains controversial. To resolve this issue, we generated two lines (P2 and P4) of nonobese diabetic (NOD) mice in which Ptpn22 can be inducibly silenced by RNAi. We found long term silencing of Ptpn22 increased spleen cellularity and regulatory T (Treg) cell numbers, replicating the effect of gene deletion reported in the knockout (KO) B6 mice. Notably, Ptpn22 silencing also increased the reactivity and apoptotic behavior of B lymphocytes, which is consistent with the reduced reactivity and apoptosis of human B cells carrying the alleged gain-of-function PTPN22 allele. Furthermore, loss of Ptpn22 protected P2 KD mice from spontaneous and Cyclophosphamide (CY) induced diabetes. Our data support the notion that Lyp-620W is a gain-of-function variant. Moreover, Lyp may be a valuable target for the treatment of autoimmune diseases.
Single-molecule microscopy is one of the decisive methodologies that allows one to clarify cellular signaling in both spatial and temporal dimentions by tracking with nanometer precision the diffusion of individual microscopic particles coupled to relevant biological molecules. Trajectory analysis not only enables determination of the mechanisms that drive and constrain the particles motion but also to reveal crucial information about the molecule interaction, mobility, stoichiometry, all existing subpopulations and unique functions of particular molecules. Efficacy of this technique depends on two problematic issues the usage of the proper fluorophore and the type of biochemical attachment of the fluorophore to a biomolecule. The goal of this study was to evolve a highly specific labeling method suitable for single molecule tracking, internalization and trafficking studies that would attain a calculable 1:1 fluorophore-to-receptor stoichiometry. A covalent attachment of quantum dots to transmembrane receptors was successfully achieved with a techinque that amalgamates acyl carrier protein (ACP) system as a comparatively small linker and coenzyme A (CoA)-functionalized quantum dots. The necessity of optimization of the quantum dot usage for more precise calculation of the membrane protein stoichiometries in larger assemblies led to the further study in which methods maximizing the number of signals and the tracking times of diverse QD types were examined. Next, the optimized techniques were applied to analyze behavior of interleukin-5 β-common chain receptor (IL-5Rβc) receptors that are endogenously expressed at low level on living differentiated eosinophil-like HL-60 cells. Obtained data disclosed that perused receptors form stable and higher order oligomers. Additionally, the mobility analysis based on increased in number (>10%) uninterrupted 1000-step trajectories revealed two patterns of confined motion. Thereupon methods were developed that allow both, determination of stoichiometries of cell surface protein complexes and the acquisition of long trajectories for mobility analysis. Sequentially, the aforementioned methods were used to scrutinize on the mobility, internalization and recycling dynamics characterization of a G protein-coupled receptor (GPCRs), the parathyroid hormone receptor (PTHR1) and several bone morphogenetic proteins (BMPs), a member of the TGF-beta superfamily of receptors. These receptors are two important representatives of two varied membrane receptor classes. BMPs activate SMAD- and non-SMAD pathways and as members of the transforming growth factor β (TGF-β) superfamily are entailed in the regulation of proliferation, differentiation, chemotaxis, and apoptosis. For effective ligand induced and ligand independent signaling, two types of transmembrane serine/threonine kinases, BMP type I and type II receptors (BMPRI and BMPRII, respectively) are engaged. Apparently, the lateral mobility profiles of BMPRI and BMPRII receptors differ markedly, which determinate specificity of the signal. Non-SMAD signaling and subsequent osteoblastic differentiation of precursor cells particularly necessitate the confinement of the BMP type I receptor, resulting in the conclusion that receptor lateral mobility is a dominative mechanism to modulate SMAD versus non-SMAD signaling during differentiation. Confined motion was also predominantly observed in the studies devoted to, entailed in the regulation of calcium homeostasis and in bone remodeling, the parathyroid hormone receptor (PTHR1), in which stimulation with five peptide ligands, specific fragments of PTH: hPTH(1–34), hPTHrP(107–111)NH2; PTH(1–14); PTH(1–28) G1R19, bPTH(3–34), first four belonging to PTH agonist group and the last to the antagonist one, were tested in the wide concentration range on living COS-1 and AD293 cells. Next to the mobility, defining the internalization and recycling rates of the PTHR1 receptor maintained in this investigation one of the crucial questions. Internalization, in general, allows to diminish the magnitude of the receptor-mediated G protein signals (desensitization), receptor resensitization via recycling, degradation (down-regulation), and coupling to other signaling pathways (e.g. MAP kinases). Determinants of the internalization process are one of the most addressed in recent studies as key factors for clearer understanding of the process and linking it with biological responses evoked by the signal transduction. The internalization of the PTH-receptor complex occurs via the clathrin-coated pit pathway involving β-arrestin2 and is initiated through the agonist occupancy of the PTHR1 leading to activation of adenylyl cyclase (via Gs), and phosphatidylinositol-specific phospholipase Cβ (via Gq). Taken together, this work embodies complex study of the interleukin-5 β-common chain receptor (IL-5Rβc) receptors, bone morphogenetic proteins (BMPs) and the parathyroid hormone receptor with the application of single-molecule microscopy with the newly attained ACP-quantum dot labeling method and standard techniques.
Pneumolysin, a protein toxin, represents one of the major virulence factors of Streptococcus pneumoniae. This pathogen causes bacterial meningitis with especially high disease rates in young children, elderly people and immunosuppressed patients. The protein toxin belongs to the family of cholesterol-dependent cytolysins, which require membrane cholesterol in order to bind and to be activated. Upon activation, monomers assemble in a circle and undergo conformational change. This conformational change leads to the formation of a pore, which eventually leads to cell lysis. This knowledge was obtained by studies that used a higher concentration compared to the concentration of pneumolysin found in the cerebrospinal fluid of meningitis patients. Thus, a much lower concentration of pneumolysin was used in this work in order to investigate effects of this toxin on primary mouse astrocytes. Previously, a small GTPase activation, possibly leading to cytoskeletal changes, was found in a human neuroblastoma cell line. This led to the hypothesis that pneumolysin can lead to similar cytoskeletal changes in primary cells. The aim of this work was to investigate and characterise the effects of pneumolysin on primary mouse astrocytes in terms of a possible pore formation, cellular trafficking and immunological responses. Firstly, the importance of pore-formation on cytoskeletal changes was to be investigated. In order to tackle this question, wild-type pneumolysin and two mutant variants were used. One variant was generated by exchanging one amino acid in the cholesterol recognising region, the second variant was generated by deleting two amino acids in a protein domain that is essential for oligomerisation. These variants should be incapable of forming a pore and were compared to the wild-type in terms of lytic capacities, membrane binding, membrane depolarisation, pore-formation in artificial membranes (planar lipid bilayer) and effects on the cytoskeleton. These investigations resulted in the finding that the pore-formation is required for inducing cell lysis, membrane depolarisation and cytoskeletal changes in astrocytes. The variants were not able to form a pore in planar lipid bilayer and did not cause cell lysis and membrane depolarisation. However, they bound to the cell membrane to the same extent as the wild-type toxin. Thus, the pore-formation, but not the membrane binding was the cause for these changes. Secondly, the effect of pneumolysin on cellular trafficking was investigated. Here, the variants showed no effect, but the wild-type led to an increase in overall endocytotic events and was itself internalised into the cell. In order to characterise a possible mechanism for internalisation, a GFP-tagged version of pneumolysin was used. Several fluorescence-labelled markers for different endocytotic pathways were used in a co-staining approach with pneumolysin. Furthermore, inhibitors for two key-players in classical endocytotic pathways, dynamin and myosin II, were used in order to investigate classical endocytotic pathways and their possible involvement in toxin internalisation. The second finding of this work is that pneumolysin is taken up into the cell via dynamin- and caveolin-independent pinocytosis, which could transfer the toxin to caveosomes. From there, the fate of the toxin remains unknown. Additionally, pneumolysin leads to an overall increase in endocytotic events. This observation led to the third aim of this work. If the toxin increases the overall rate of endocytosis, the question arises whether toxin internalisation favours bacterial tissue penetration of the host or whether it serves as a defence mechanism of the cell in order to degrade the protein. Thus, several proinflammatory cytokines were investigated, as previous studies describe an effect of pneumolysin on cytokine production. Surprisingly, only interleukin 6-production was increased after toxin-treatment and no effect of endocytotic inhibitors on the interleukin 6-production was observed. The conclusion from this finding is that pneumolysin leads to an increase of interleukin 6, which would not depend on the endocytotic uptake of pneumolysin. The production of interleukin 6 would enhance the production of acute phase proteins, T-cell activation, growth and differentiation. On the one hand, this activation could serve pathogen clearance from infected tissue. On the other hand, the production of interleukin 6 could promote a further penetration of pathogen into host tissue. This question should be further investigated.
Streptococcus pneumoniae is one of the major causes of bacterial meningitis, which mainly affects young infants in the developing countries of Africa, Asia (esp. India) and South America, and which has case fatality rates up to 50% in those regions. Bacterial meningitis comprises an infection of the meninges and the sub-meningeal cortex tissue of the brain, whereat the presence of pneumolysin (PLY), a major virulence factor of the pneumococcus, is prerequisite for the development of a severe outcome of the infection and associated tissue damage (e. g. apoptosis, brain edema, and ischemia). Pneumolysin belongs to the family of pore forming, cholesterol-dependent cytolysins (CDCs), bacterial protein toxins, which basically use membrane-cholesterol as receptor and oligomerize to big aggregates, which induce cell lysis and cell death by disturbance of membrane integrity. Multiple recent studies, including this work, have revealed a new picture of pneumolysin, whose cell-related properties go far beyond membrane binding, pore formation and the induction of cell death and inflammatory responses. For a long time, it has been known that bacteria harm the tissues of their hosts in order to promote their own survival and proliferation. Many bacterial toxins aim to rather hijack cells than to kill them, by interacting with cellular components, such as the cytoskeleton or other endogenous proteins. This study was able to uncover a novel capacity of pneumolysin to interact with components of the actin machinery and to promote rapid, actin-dependent cell shape changes in primary astrocytes. The toxin was applied in disease-relevant concentrations, which were verified to be sub-lytic. These amounts of toxin induced a rapid actin cortex collapse in horizontal direction towards the cell core, whereat membrane integrity was preserved, indicating an actin severing function of pneumolysin, and being consistent with cell shrinkage, displacement, and blebbing observed in live cell imaging experiments. In contrast to neuroblastoma cells, in which pneumolysin led to cytoskeleton remodeling and simultaneously to activation of Rac1 and RhoA, in primary astrocytes the cell shape changes were seen to be primarily independent of small GTPases. The level of activated Rac1 and RhoA did not increase at the early time points after toxin application, when the initial shape changes have been observed, but at later time points when the actin-dependent displacement of cells was slower and less severe, probably presenting the cell’s attempt to re-establish proper cytoskeleton function. A GUV (giant unilamellar vesicle) approach provided insight into the effects of pneumolysin in a biomimetic system, an environment, which is strictly biochemical, but still comprises cellular components, limited to the factors of interest (actin, Arp2/3, ATP, and Mg2+ on one side, and PLY on the other side). This approach was able to show that the wildtype-toxin, but not the Δ6 mutant (mutated in the unfolding domain, and thus non-porous), had the capacity to exhibit its functions through a membrane bilayer, meaning it was able to aggregate actin, which was located on the other side of the membrane, either via direct interaction with actin or in an Arp2/3 activating manner. Taking a closer look at these two factors with the help of several different imaging and biochemical approaches, this work unveiled the capacity of pneumolysin to bind and interact both with actin and Arp2 of the Arp2/3 complex. Pneumolysin was capable to slightly stabilize actin in an actin-pyrene polymerization assay. The same experimental setup was applied to show that the toxin had the capacity to lead to actin polymerization through activation of the Arp2/3 complex. This effect was additionally confirmed with the help of fluorescent microscopy of rhodamine (TRITC)-tagged actin. Strongest Arp2/3 activation, and actin nucleation/polymerization is achieved by the VCA domain of the WASP family proteins. However, addition of PLY to the Arp2/3–VCA system led to an enhanced actin nucleation, suggesting a synergistic activation function of pneumolysin. Hence, two different effects of pneumolysin on the actin cytoskeleton were observed. On the one hand an actin severing property, and on the other hand an actin stabilization property, both of which do not necessarily exclude each other. Actin remodeling is a common feature of bacterial virulence strategies. This is the first time, however, that these properties were assigned to a toxin of the CDC family. Cytoskeletal dysfunction in astrocytes leads to dysfunction and unregulated movement of these cells, which, in context of bacterial meningitis, can favor bacterial penetration and spreading in the brain tissue, and thus comprises an additional role of pneumolysin as a virulence factor of Streptococcus pneumonia in the context of brain infection.
The Nucleotide Excision Repair (NER) pathway is able to remove a vast diversity of structurally unrelated DNA lesions and is the only repair mechanism in humans responsible for the excision of UV induced DNA damages. The NER mechanism raises two fundamental questions: 1) How is DNA damage recognition achieved discriminating damaged from non damaged DNA? 2) How is DNA incision regulated preventing endonucleases to cleave DNA non specifically but induce and ensure dual incision of damaged DNA? Thus, the aim of this work was to investigate the mechanisms leading from recognition to incision of damaged DNA. To decipher the underlying process of damage recognition in a prokaryotic model system, the intention of the first part of this work was to co crystallize the helicase UvrB form Bacillus caldotenax together with a DNA substrate comprising a fluorescein adducted thymine as an NER substrate. Incision assays were performed to address the question whether UvrB in complex with the endonuclease UvrC is able to specifically incise damaged DNA employing DNA substrates with unpaired regions at different positions with respect to the DNA lesion. The results presented here indicate that the formation of a specific pre incision complex is independent of the damage sensor UvrA. The preference for 5’ bubble substrate suggests that UvrB is able to slide along the DNA favorably in a 5’ → 3’ direction until it directly encounters a DNA damage on the translocating strand to then recruit the endonuclease UvrC. In the second part of this work, the novel endonuclease Bax1 from Thermoplasma acidophilum was characterized. Due to its close association to archaeal XPB, a potential involvement of Bax1 in archaeal NER has been postulated. Bax1 was shown to be a Mg2+ dependent, structure specific endonuclease incising 3’ overhang substrates in the single stranded region close to the ssDNA/dsDNA junction. Site directed mutagenesis of conserved amino acids was employed to identify putative active site residues of Bax1. In complex with the helicase XPB, however, incision activity of Bax1 is altered regarding substrate specificity. The presence of two distinct XPB/Bax1 complexes with different endonuclease activities indicates that XPB regulates Bax1 incision activity providing insights into the physical and functional interactions of XPB and Bax1.
There is such vast amount of visual information in our surroundings at any time that filtering out the important information for further processing is a basic requirement for any visual system. This is accomplished by deploying attention to focus on one source of sensory inputs to the exclusion of others (Luck and Mangun 2009). Attention has been studied extensively in humans and non human primates (NHPs). In Drosophila, visual attention was first demonstrated in 1980 (Wolf and Heisenberg 1980) but this field remained largely unexplored until recently. Lately, however, studies have emerged that hypothesize the role of attention in several behaviors but do not specify the characteristic properties of attention. So, the aim of this research was to characterize the phenomenon of visual attention in wild-type Drosophila, including both externally cued and covert attention using tethered flight at a torque meter. Development of systematic quantifiable behavioral tests was a key aspect for this which was not only important for analyzing the behavior of a population of wild-type flies but also for comparing the wild-type flies with mutant flies. The latter would help understand the molecular, genetic, and neuronal bases of attention. Since Drosophila provides handy genetic tools, a model of attention in Drosophila will serve to the greater questions about the neuronal circuitry and mechanisms involved which might be analogous to those in primates. Such a model might later be used in research involving disorders of attention. Attention can be guided to a certain location in the visual field by the use of external cues. Here, using visual cues the attention of the fly was directed to one or the other of the two visual half-fields. A simple yet robust paradigm was designed with which the results were easily quantifiable. This paradigm helped discover several interesting properties of the cued attention, the most substantial one being that this kind of external guidance of attention is restricted to the lower part of the fly’s visual field. The guiding cue had an after-effect, i.e. it could occur at least up to 2 seconds before the test and still bias it. The cue could also be spatially separated from the test by at least 20° and yet attract the attention although the extent of the focus of attention (FoA) was smaller than one lower visual half-field. These observations excluded the possibility of any kind of interference between the test and the cue stimuli. Another interesting observation was the essentiality of continuous visibility of the test stimulus but not the cue for effective cuing. When the contrast of the visual scene was inverted, differences in response frequencies and cuing effects were observed. Syndirectional yaw torque responses became more frequent than the antidirectional responses and cuing was no longer effective in the lower visual field with inverted contrast. Interestingly, the test stimulus with simultaneous displacement of two stripes not only effectuated a phasic yaw torque response but also a landing response. A 50 landing response was produced in more than half of the cases whenever a yaw torque response was produced. Elucidation of the neuronal correlates of the cued attention was commenced. Pilot experiments with hydroxyurea (HU) treated flies showed that mushroom bodies were not required for the kind of guidance of attention tested in this study. Dopamine mutants were also tested for the guidance of attention in the lower visual field. Surprisingly, TH-Gal4/UAS-shits1 flies flew like wild-type flies and also showed normal optomotor response during the initial calibration phase of the experiment but did not show any phasic yaw torque or landing response at 18 °C, 25 °C or 30 °C. dumb2 flies that have almost no D1 dopamine receptor dDA1 expression in the mushroom bodies and the central complex (Kim et al. 2007) were also tested and like THGal4/ UAS-shits1 flies did not show any phasic yaw torque or landing response. Since the dopamine mutants did not show the basic yaw torque response for the test the role of dopamine in attention could not be deduced. A different paradigm would be needed to test these mutants. Not only can attention be guided through external cues, it can also be shifted endogenously (covert attention). Experiments with the windows having oscillating stripes nicely demonstrated the phenomenon of covert attention due to the production of a characteristic yaw torque pattern by the flies. However, the results were not easily quantifiable and reproducible thereby calling for a more systematic approach. Experiments with simultaneous opposing displacements of two stripes provide a promising avenue as the results from these experiments showed that the flies had a higher tendency to deliver one type of response than when the responses would be produced stochastically suggesting that attention increased this tendency. Further experiments and analysis of such experiments could shed more light on the mechanisms of covert attention in flies.
Die chronische Herzinsuffizienz stellt nach wie vor eine der häufigsten Todesursachen weltweit dar. Trotz intensiver Forschung ist es bisher nicht möglich die pathophysiologischen Prozesse aufzuhalten. Es wird nach neuen Strategien gesucht, hier therapeutisch eingreifen zu können. Kleine nicht-kodierende RNAs, sogenannte microRNAs (miRNAs), wurden als wichtige Faktoren bei verschiedenen Herzkrankheiten beschrieben. Die Mehrzahl der bisherigen Studien fokussierte sich dabei auf die am stärksten deregulierten miRNAs im erkrankten Herz. In einer automatisierten Analyse im 96 Well-Format untersuchten wir 230 miRNAs auf ihr Potential, in das Größenwachstum von primären Kardiomyozyten einzugreifen. Aus den miRNAs mit den größten Effekten selektierten wir diejenigen, die eine hohe endogene Expression aufwiesen, und unterzogen sie einem Validierungsprozess. Hier konnten wir die Effekte aller pro- (miR-22, miR-30c, miR-30d, miR-212, miR-365) und anti-hypertrophen (miR-27a, miR-27b, miR-133a) miRNAs bestätigen. Die Mehrzahl dieser miRNAs wurde hiermit erstmalig beschrieben, dass sie eine wichtige Rolle beim Größenwachstum von Kardiomyozyten spielen. Sie wären daher interessante Kandidaten für detaillierte funktionelle Studien mit dem Ziel ihr therapeutisches Potential zu evaluieren. In einem früheren genetischen Screen zur Identifizierung von kardialen, sezernierten Faktoren wurde der Protease Inhibitor 16 (PI16) entdeckt, der sich im insuffizienten Herz durch eine starke Akkumulation auszeichnet. Gegenstand des zweiten Teils dieser Arbeit war es, eine Mauslinie zu generieren, in der PI16 global oder konditionell mit Hilfe des Cre/LoxP-Systems ausgeschaltet werden kann. Nach Elektroporation des Pi16floxneo Targeting Vektors in embryonale Stammzellen und Blastozysteninjektion erhielten wir eine Mauslinie, die Träger der zielgerichteten Modifikation des Pi16 Allels war. Mit der globalen genetischen Deletion des LoxP-flankierten Abschnitts von Exon 3 bis 4 konnten wir die Expression des Pi16 Gens komplett unterbinden. Die PI16 Defizienz führte weder im Herz noch in anderen Organen per se zu pathologischen Veränderungen. Zudem war unbekannt, dass PI16 in der gesunden Maus in der kardialen Fibroblastenfraktion enthalten sowie in den Zilien der Epididymis und der Trachea und im Lumen der Schilddrüse lokalisiert ist. Im insuffizienten Herz bestätigten wir eine Akkumulation von PI16, die sich vor allem auf die fibrotischen Bereiche beschränkte. Das lässt Grund zur Annahme, dass die kardiale Funktion von PI16 erst dann offensichtlich wird, wenn man die defizienten Mäuse zukünftig entsprechenden Stressmodellen aussetzt. Das wird zu einem umfassenden Verständnis der kardialen Funktion von PI16 und dessen Potential als therapeutisches Zielmolekül führen.
Type 1 diabetes affects around 0.5% of the population in developed countries and the incidence rates have been rising over the years. The destruction of beta cells is irreversible and the current therapy available to patients only manages the symptoms and does not prevent the associated pathological manifestations. The patients need lifelong therapy and intensive research is being carried out to identify ways to eliminate autoimmune responses directed against pancreatic beta cells and to replace or regenerate beta cells. The work presented herein aimed at analyzing the role of the Th17 T cell subset, characterized by secretion of the pro- inflammatory cytokine IL-17A, in autoimmune diabetes and also at generating a beta cell reporter mouse line in the NOD background, the most widely- used mouse model for type 1 diabetes. We generated IL- 17A knockdown (KD) NOD mice, using RNAi in combination with lentiviral transgenesis. We analyzed diabetes frequency in IL-17A deficient mice and found that the loss of IL-17A did not protect the transgenic mice from diabetes. Based on these observations, we believe that Th17 cells do not play a critical role in type 1 diabetes through the IL-17A pathway, though they might still be involved in the disease process through alternate pathways. We also generated NOD and NOD-SCID mice with a transgene that drives the beta cell specific expression of a luciferase reporter gene. We used a lentiviral construct, which combined a luciferase sequence and a short- hairpin RNA (shRNA) expression cassette, allowing gene- knockdown under the beta cell specific rat insulin promoter (RIP). These mice will be of use in studying beta cell phenotypes resulting from the knockdown of target genes, using non- invasive bioimaging. We believe that the generation of these reporter mouse lines for diabetes studies will prove valuable in future investigations. Furthermore, the demonstration that the loss of IL-17A does not alter susceptibility to type 1 diabetes should help clarify the controversial involvement of Th17 cells in this disease.
Das ANP/GC-A-System spielt durch die Produktion des sekundären Botenstoffs cGMP eine wichtige Rolle bei der Regulation des Blutdruckes und des Blutvolumens. Bei Patienten mit Herzhypertrophie oder Herzinsuffizienz sind die ANP-Plasmakonzentrationen erhöht, aber die GC-A-vermittelten Effekte stark reduziert, was auf einen Defekt des Signalsystems hinweist. Studien an metabolisch markierten GC-A-überexprimierenden HEK 293-Zellen zeigten, dass der GC-A-Rezeptor im basalen Zustand stark phosphoryliert und die homologe bzw. heterologe Desensitisierung wahrscheinlich mit einer Dephosphorylierung verbunden ist. Die Desensitisierung stellt einen Mechanismus dar, der in vivo zu einem Funktionsverlust des Rezeptors beitragen könnte. Im Rahmen dieser Arbeit konnten mittels Massenspektrometrie sieben Phosphorylierungsstellen in der Kinasehomologen Domäne aus FLAG-GC-A exprimierenden HEK 293-Zellen detektiert werden: Ser487, Ser497, Thr500, Ser502, Ser506, Ser510 und Thr513. Die massenspektrometrische relative Quantifizierung basierend auf der Multiple-Reaction-Monitoring (MRM)-Methode zeigte bei ANP-induzierter, homologer Desensitisierung eine Dephosphorylierung der Phosphorylierungsstellen Ser497, Thr500, Ser502, Ser506, Ser510 und Thr513, was mit bereits publizierten Daten übereinstimmt, und einen starken Anstieg der Phosphorylierung an Ser487. Nach Inkubation mit Angiotensin II, welches eine heterologe Desensitisierung hervorruft, wurde eine Reduzierung aller Phosphorylierungen verzeichnet, die zudem stärker ausgeprägt war als bei der ANP-abhängigen Desensitisierung. Die Funktion der neu identifizierten Phosphorylierung an Ser487 wurde mittels Mutagenese analysiert. Die Substitution des Serins durch Alanin, welche den unphosphorylierten Zustand nachstellt, resultierte in einer Rezeptoraktivität und desensitisierung vergleichbar zum GC-A Wildtyp-Rezeptor. Wurde hingegen Serin gegen Glutamat getauscht, um den phosphorylierten Zustand zu imitieren, konnte der Rezeptor weder aktiviert noch desensitisiert werden. Diese Ergebnisse bestätigen vorherige Studien, dass die GC-A-Rezeptorantwort auf ANP durch die Phosphorylierungen reguliert wird. Allerdings scheint bei der homologen Desensitisierung die Phosphorylierung an der Position Ser487 eine Rolle zu spielen, da sie die Aktivität des Rezeptors inhibiert. Die Identifizierung und Charakterisierung dieser Phosphorylierungsstelle trägt zum Verständnis des Mechanismus der homologen Desensitierung bei. Zusätzlich konnten einige der beschriebenen Phosphorylierungen in Zellsystemen detektiert werden, die die GC-A endogen exprimieren. Dadurch sind unter physiologischen Bedingungen Analysen der Mechanismen möglich, die bei der Aktivierung und Deaktivierung der GC-A involviert sind und somit wichtige pathophysiologische Konsequenzen haben können.
Studies on platelet cytoskeletal dynamics and receptor regulation in genetically modified mice
(2009)
Platelets are produced by bone marrow megakaryocytes in a process involving actin dynamics. Actin-depolymerizing factor (ADF) and cofilin are actin-binding proteins that act as key regulators in actin turnover by promoting filament severing and depolymerization. The overall significance of ADF/cofilin function and actin turnover in platelet formation is presently unclear. In the first part of this thesis, platelet formation and function were studied in mice constitutively lacking ADF and/or mice with a conditional deficiency (Cre/loxP) in n-cofilin. To delete cofilin exclusively in megakaryocytes and platelets, cofilinfl/fl mice were crossed with PF4 (platelet factor 4)-Cre mice. While a single-deficiency in ADF or n-cofilin resulted in no or only a minor platelet formation defect, respectively, a double-deficiency in ADF and n-cofilin led to an almost complete loss of platelets. Bone marrow megakaryocytes of ADF/n-cofilin-deficient mice showed defective platelet zone formation. Interestingly, in vitro and ex vivo megakaryocyte differentiation revealed reduced proplatelet formation and absence of platelet-forming swellings. These data establish that ADF and n-cofilin have redundant but essential roles in the terminal step of platelet formation in vitro and in vivo. In the second part of the thesis, mechanisms underlying cellular regulation of the major platelet collagen receptor, glycoprotein VI (GPVI), were studied. GPVI mediates platelet activation on exposed subendothelial collagens at sites of vascular injury, and thereby contributes to normal hemostasis but also to occlusion of diseased vessels in the setting of myocardial infarction or stroke. Thus, GPVI is an attractive target for anti-thrombotic therapy, particularly because previous studies have shown that anti-GPVI antibodies induce irreversible down-regulation of the receptor in circulating platelets by internalization and ectodomain shedding. Metalloproteinases of the ADAM (a disintegrin and metalloproteinase domain) family are suspected to mediate this ectodomain shedding, but in vivo evidence for this is lacking. To study the mechanism of GPVI regulation in vivo, two mouse lines, Gp6 knock-out and Adam10fl/fl, PF4-Cre mice, were generated and in addition low TACE (TNFalpha converting enzyme) mice were analyzed. It was shown that GPVI can be cleaved in vitro by ADAM10 or TACE depending on the shedding-inducing signaling pathway. Moreover, GPVI was down-regulated in vivo upon antibody injection in ADAM10-deficient and low TACE mice suggesting that either both or an additional metalloproteinase is involved in GPVI regulation in vivo.
An increase in cytosolic Ca2+ levels ([Ca2+]i) is a key event that occurs downstream of many signaling cascades in response to an external stimulus and regulates a wide range of cellular processes, including platelet activation. Eukaryotic cells increase their basal [Ca2+]i allowing extracellular Ca2+ influx into the cell, which involves different mechanisms. Store-operated Ca2+ entry (SOCE) is considered the main mechanism of extracellular Ca2+ influx in electrically non-excitable cells and platelets, and comprises an initial Ca2+ depletion from intracellular Ca2+ stores prior to activation of extracellular Ca2+ influx. Although the close relation between Ca2+ release from intracellular stores and extracellular Ca2+ influx was clear, the nature of the signal that linked both events remained elusive until 2005, when Stromal Interaction Molecule 1 (STIM1) was identified as an endoplasmic reticulum (ER) Ca2+ sensor essential for inositol (1,4,5)-trisphosphate (IP3)-mediated SOCE in vitro. However, the function of its homologue STIM2 in Ca2+ homeostasis was in general unknown. Therefore, mice lacking STIM2 (Stim2-/-) were generated in this work to study initially STIM2 function in platelets and in cells of the immune system. Stim2-/- mice developed normally in size and weight to adulthood and were fertile. However, for unknown reasons, they started to die spontaneously at the age of 8 weeks. Unexpectedly, Stim2-/- mice did not show relevant differences in platelets, revealing that STIM2 function is not essential in these cells. However, STIM2 seems to be involved in mammary gland development during pregnancy and is essential for mammary gland function during lactation. CD4+ T cells lacking STIM2 showed decreased SOCE. Our data suggest that STIM2 has a very specific function in the immune system and is involved in Experimental Autoimmune Encephalomyelitis (EAE) at early stages of the disease progression. Stim2-/- neurons were also defective in SOCE. Surprisingly, our results evidenced that STIM2 participates in mechanisms of neuronal damage after ischemic events in brain. This is the first time that the involvement of SOCE in ischemic neuronal damage has been reported. This finding may serve as a basis for the development of novel neuroprotective agents for the treatment of ischemic stroke, and possibly other neurodegenerative disorders in which disturbances in cellular Ca2+ homeostasis are considered a major pathophysiological component.
Mycobacterium tuberculosis is the causative agent of tuberculosis and responsible for more than eight million new infections and about two million deaths each year. Novel chemotherapeutics are urgently needed to treat the emerging threat of multi drug resistant and extensively drug resistant strains. Cell wall biosynthesis is a widely used target for chemotherapeutic intervention in bacterial infections. In mycobacteria, the cell wall is comprised of mycolic acids, very long chain fatty acids that provide protection and allow the bacteria to persist in the human macrophage. The type II fatty acid biosynthesis pathway in Mycobacterium tuberculosis synthesizes fatty acids with a length of up to 56 carbon atoms that are the precursors of the critical mycobacterial cell wall components mycolic acids. KasA, the mycobacterial ß-ketoacyl synthase and InhA, the mycobacterial enoyl reductase, are essential enzymes in the fatty acid biosynthesis pathway and validated drug targets. In this work, KasA was expressed in Mycobacterium smegmatis, purified and co-crystallized in complex with the natural thiolactone antibiotic thiolactomycin (TLM). High-resolution crystal structures of KasA and the C171Q KasA variant, which mimics the acyl enzyme intermediate of the enzyme, were solved in absence and presence of bound TLM. The crystal structures reveal how the inhibitor is coordinated by the enzyme and thus specifically pinpoint towards possible modifications to increase the affinity of the compound and develop potent new drugs against tuberculosis. Comparisons between the TLM bound crystal structures explain the preferential binding of TLM to the acylated form of KasA. Furthermore, long polyethylene glycol molecules are bound to KasA that mimic a fatty acid substrate of approximately 40 carbon atoms length. These structures thus provide the first insights into the molecular mechanism of substrate recognition and reveal how a wax-like substance can be accommodated in a cytosolic environment. InhA was purified and co-crystallized in complex with the slow, tight binding inhibitor 2-(o-tolyloxy)-5-hexylphenol (PT70). Two crystal structures of the ternary InhA-NAD+-PT70 were solved and reveal how the inhibitor is bound to the substrate binding pocket. Both structures display an ordered substrate binding loop and corroborate the hypothesis that slow onset inhibition is coupled to loop ordering. Upon loop ordering, the active site entrance is more restricted and the inhibitor is kept inside more tightly. These studies provide additional information on the mechanistic imperatives for slow onset inhibition of enoyl ACP reductases.