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Since the early 2000s, nucleic acid aptamers have gained considerable attention of life science communities. This is in particular due to the fact that aptamers are known to function as artificial riboswitches, which presents an efficient way to regulate gene expression. A promising candidate is the tetracycline-binding RNA aptamer (TC-aptamer) since the TC-aptamer is known to function in vivo and exhibits a very high affinity towards its ligand tetracycline (TC) (Kd = 800 pM at 10mM Mg2+). Although a highly resolved crystal structure exists in the ligand bound state, questions related to dynamics cannot be answered with X-ray crystallography. In this work, pulsed electron paramagnetic resonance (EPR) spectroscopy was used to study different biochemical and structural aspects of the TC-aptamer.
On the one hand, pulsed hyperfine spectroscopy was used to study the binding of TC via Mn2+ to the TC-aptamer at lower and thus more physiological divalent metal ion concentrations. In a first step, a protocol for the relatively new pulsed hyperfine technique electron-electron double resonance detected NMR (ELDORdetected NMR or just EDNMR) was developed for Q-band frequencies (34 GHz). After a successful verification of the EDNMR technique at Q-band frequencies on Mn2+ model complexes ([Mn(H2O)6]2+ and Mn-DOTA), two dimensional hyperfine techniques were used to confirm the formation of a ternary RNA-Mn2+- TC complex at physiological divalent metal ion concentrations. Correlation signals between 13C (13C-labeled TC) and 31P (from the RNA backbone) to the same Mn2+ electron spin were detected with 2D-EDNMR and triple hyperfine correlation spectroscopy (THYCOS).
On the other hand, pulsed electron-electron double resonance (PELDOR) spectroscopy on a doubly nitroxide-labeled TC-aptamer was used to investigate the conformational rearrangement upon ligand binding and how the conformational flexibility is affected by different Mg2+ concentrations. The Çm spin label was used as a nitroxide spin probe. Due to its rigidity and low degree of internal flexibility, the Çm spin label yields very narrow distance distributions and pronounced orientation selection (OS). As a consequence, the width of the distance distributions can be used to draw conclusions about the conformational flexibility of the spin-labeled helices. Analysis of the distance distributions showed that at high Mg2+ concentrations, the TC-aptamer is in its folded state, irrespective of the fact if TC is present or absent. Orientation selective PELDOR revealed that the orientation of the spin-labeled helices in frozen solution is the same as in the crystal structure. First Mn2+-nitroxide pulsed electron electron double resonance (PELDOR) measurements on a singly nitroxide-labeled and Mg2+/Mn2+-substituted TCaptamer at different Mn2+ concentrations in the presence and absence of TC gave insight into the affinities of the additional divalent metal ion binding sites of the TC-aptamer.
The enzyme 5-lipoxygenase (5-LO) occupies a central role in the biosynthesis of inflammatory leukotrienes and thus takes part in the pathogenesis of related diseases. Its occurrence is mainly restricted to cells of the immune system including granulocytes, monocytes/macrophages or B-lymphocytes and can be induced by cell differentiation of myeloid cells after treatment with differentiating agents, such as DMSO, retinoic acid or the combination of TGFβ/1,25(OH)2D3. The latter contribute to the highest level of induction of mRNA and protein expression. Its cell specific occurrence is at least partly due to DNA methylation in cells that do not exhibit 5-LO activity and genetic regulation is further dependent on histone acetylation. 5-LO expression is controlled by transcription factors binding to the promoter sequence of the ALOX5 gene that induce basal promoter activity, as well as promoter independent effects including transcript initiation and elongation, which are mostly attributed to TGFβ/1,25(OH)2D3 signaling. The ALOX5 gene resembles a typical housekeeping gene, hence lacks TATA- or CAAT-boxes for transcriptional regulation, but displays a high GC-content with eight GC-boxes, five of which are arranged in tandem, that provide binding sites for transcription factors Sp1, Sp3 and Egr-1.
The proximal ALOX5 promoter is furthermore a target for additional factors, such as TGFβ effector proteins SMADs or the vitamin D receptor and possesses additional consensus sequences for transcriptional regulators, including NF-κB or PU.1. However, as yet no actual binding of these proteins to the promoter sequence was demonstrated and an unbiased screening for identifying further ALOX5 promoter interacting proteins, which might have impact on 5-LO expression, is still lacking. For this purpose, the present study focused on the identification of significantly interacting proteins, employing DNA-affinity enrichment coupled to label-free quantitative proteomics, spanning a sequence of about 270 base pairs of the proximal ALOX5 promoter. For the elucidation of potential cell specific differences in protein patterns and compositions, DNA pulldowns were performed by using oligonucleotide stretches comprising the core promoter sequence including the 5-fold GC-box, which were incubated with different cell lines and differentiation states of myeloid, as well as B-lymphocytic lineages. In order to compare different mass spectrometric quantification strategies that would allow for identification of interactors, dimethyl labeling and label-free techniques were used. Since the label-free approach outperformed the label-based one in initial experiments, it was established as standard quantification strategy in all DNA pulldowns performed. The pulldowns of myeloid cell lines in both undifferentiated and differentiated state and B-lymphocytes resulted in a cell-unspecific protein pattern whose composition was similar, regardless of cell lineage. Additionally, further DNA sequences comprising either a vitamin D response element or a SMAD binding element were investigated in the promyelocytic model cell line HL-60 in both undifferentiated and differentiated state. The identified proteins confirmed known interaction partners and furthermore revealed novel potential regulators of the 5-LO promoter. Out of these, the most prominently identified and promising proteins included transcription factors of the KLF- and CCAAT/enhancer binding protein-family. In this context, KLF5 and KLF13 are both involved in the regulation of inflammatory processes, the former additionally being an effector protein of TGFβ-signaling, whose functional characterization is of utmost interest in terms of regulation of 5-LO expression. Further protein characterization will be inevitable for the CCAAT/enhancer binding proteins C/EBPα, C/EBPβ and C/EBPε. These transcription factors are involved in the regulation of inflammatory processes and heterodimers thereof (C/EBPα/β) are known to control TGFβ/1,25(OH)2D3-mediated effects of the CD14 gene.
Several of the identified proteins of the pulldowns containing the tandem GC-box represented interactors of G-quadruplex DNA, including the helicases BLM and DHX36, the ribonucleoproteins hnRNP D and hnRNP K and transcription factor MAZ. Since G-quadruplexes form in G-rich DNA sequences as secondary DNA structures and exhibit substantial regulatory effects on the transcription of their target genes, the potential formation thereof in the ALOX5 core promoter sequence was investigated in a second project. Out of the proteins mentioned above, MAZ is shown to exert resolving effects on G4-DNA and synergistically induce Sp1-dependent gene activation of oncogene h-RAS, which displays analogous promoter characteristics to the ALOX5 gene. A DNA stretch comprising the tandem GC-box was used for elucidating the potential of secondary DNA structure formation. Intriguingly, both immune-based and spectroscopic methods provided clear evidence for the in vitro G-quadruplex formation of the proximal promoter sequence for the first time. In order to provide additional information on a possible regulatory effect of existing G-quadruplex structures on 5-LO transcription, differentiated HL-60 cells were subsequently treated with two distinct G4-DNA stabilizing agents. A porphyrin analogon (TMPyP4) did not exhibit any effects on 5-LO mRNA and protein expression after cell treatment. A second G4-DNA stabilizing agent (pyridostatin) on the other hand revealed significant reduction on 5-LO protein expression after cellular treatment. These mixed results render further experiments inevitable, in order to provide a clear assertion as to whether 5-LO expression is regulated by G-quadruplex structures or not.
Altogether, this study enlarges the knowledge of ALOX5 proximal promoter interacting proteins by corroborating the binding of already known transcription factors and identifying novel interactors. It yields essential groundwork for subsequent functional studies of proteins involved in 5-LO transcription and introduces G-quadruplexes as a new potential mechanism in ALOX5 gene regulation.
Metabolites such as lactate and free fatty acids (FFAs) abundantly occur in high concentrations in tumor and stromal cells of solid malignancies. Their known functions comprise the allocation of nutrients and intermediates for the generation of cell components, the evasion of immune destruction, the induction of vessel formation and the stimulation of cell migration in order to promote tumor growth, progression and metastasis. However, the role of metabolites as signaling molecules and the downstream mechanisms of metabolite receptor mediated signaling in tumor and stromal cells is poorly understood. Our study confirms the expression of Hydroxycarboxylic acid receptor 1 (HCA1) in solid human breast tumors and the expression of Free fatty acid receptor 4 (FFA4) in solid human colorectal tumors. In addition, the expression of HCA1 in human breast cancer cell lines as well as the expression of FFA4 in human colorectal cancer cell lines was proved. Moreover, our research reveals the expression HCA2, FFA2 and FFA4 in tumor associated macrophages (TAMs).
To test whether the loss of any of the metabolite receptors affects tumor growth and progression we utilized a syngeneic Lewis lung cancer (LLC1) tumor model, an azoxymethane (AOM) – dextran sulfate (DSS) colorectal cancer model and a Mouse mammary tumor virus Polyoma Virus middle T antigen (MMTV-PyMT) breast cancer model. The loss of HCA2 did not lead to a changed outcome compared to wild type littermates in any of the models. Likewise, the deletion of FFA4 had no influence on the LLC1 model and, surprisingly, tumor number and area in the AOM-DSS model also remained unaltered. The impact of HCA1 deficiency was investigated utilizing the MMTV-PyMT model and revealed a moderately improved tumor growth. The absence of FFA2 did not affect tumor growth in the LLC1 model but led to an increased number of colorectal tumors in the AOM-DSS model while the tumor area remained unchanged. The most compelling results were obtained upon the deletion of FFA2 in the MMTV-PyMT model. Here, we demonstrate that the loss of FFA2 significantly reduces tumor latency and also significantly improves tumor growth. Nevertheless, the formation of metastases in the LLC1 model and the MMTV-PyMT model did not show any changes upon the loss of any of the metabolite receptors.
Together, our results describe a tumor-protective effect of FFA2 with an unclear impact on metastatic processes. Considerations about putative mechanisms of short chain fatty acid (SCFA) mediated FFA2 signaling suggest potential targets for pharmacological interventions to treat mammary tumors.
Lange ging man davon aus, dass die Physiologie der Thyroidhormone weitestgehend erforscht ist und nahm an, dass sämtliche Thyroidhormon-Wirkungen auf einer Bildung von L-Thyroxin (T4) und einer anschließenden Deiodierung zu Triiodthyronin (T3) beruhen, welches an die nukleären Thyroidhormon Rezeptoren (THRs) bindet. Über die THRs werden genomische Signalwege vermittelt, die während der Wachstums- und Entwicklungsphase essentiell sind. Beim Erwachsenen werden zudem vorwiegend katabole Stoffwechsel-Prozesse induziert. Jedoch zeigte sich in den letzten 20 Jahren, dass die Signalwege der Thyroidhormone komplexer sind als bisher angenommen. Vor allem die Metabolite des in der Schilddrüse gebildeten T4s, zeigen ein breites Interaktions-Profil mit anderen molekularen Zielstrukturen. Thyronamine, die decarboxylierten Thyroidhormon-Metabolite, binden beispielsweise den G-Protein-gekoppelten Trace Amine Associated Receptor 1 (TAAR1). Wird dieser Rezeptor aktiviert, kommt es innerhalb kürzester Zeit zu einem rapiden Abfall der Köpertemperatur, sowie zu einer akuten Bradykardie. Die durch oxidative Deaminierung gebildeten Iodthyroacetate Tetraiodthyroacetat (TETRAC) und Triiodthyroacetat (TRIAC) sind Antagonisten des Membran-Rezeptors Integrin αVβ3 und besitzen antiproliferative und pro-apoptotische Eigenschaften.
In dieser Arbeit sollte die Hypothese untersucht werden, ob Thyroidhormone neben diesen neuen zumeist nicht-genomischen Signalwegen, auch THR-unabhängige genomische Wirkmechanismen besitzen.
Mit Hilfe eines Gal4-Luciferase-Reportergen-Assays wurde in einem Screening die Aktivität einiger Thyroidhormone und Thyroidhormon-Metabolite an elf THR-ähnlichen Rezeptoren und den drei Retinoid X Rezeptor (RXR)-Subtypen untersucht. Es konnte detektiert werden, dass Thyroidhormone, vor allem TETRAC, potente Peroxisom-Proliferator-aktivierter Rezeptor (PPAR)γ-Agonisten sind, die zum Teil zusätzlich dessen Heterodimer-Partner RXR aktivieren können. Diese PPARγ- und RXR-Aktivität wurde zunächst mit Hilfe eines Coaktivator-Rekrutierungs-Assays, einer Isothermen Titrationskalorimetrie (ITC) und einer Kristallstrukturanalyse genauer charakterisiert. Zum einen konnte nachgewiesen werden, dass sowohl PPARγ, als auch RXR in artifizielleren Testsystemen durch Thyroidhormone aktiviert werden. Zum anderen konnte die für permissive Heterodimere, wie das PPARγ/RXR-Heterodimer, typische additive Transaktivierungs-Effizienz nach Bindung beider Heterodimer-Partner bestätigt werden. Außerdem zeigte die Untersuchung der Kristallstruktur von TETRAC und PPARγ, dass Thyroidhormone einen abweichenden Bindungsmodus im Vergleich zu anderen PPARγ Agonisten, wie den Glitazonen und entsprechende Fettsäuren oder Fettsäuremimetika, besitzen.
Die Evaluation der biologischen Relevanz der PPARγ/RXR-Heterodimer-Aktivierung ergab zudem, dass TETRAC, als potentester PPARγ-Agonist, in der Lage ist die Differenzierung von Präadipocyten zu Adipocyten zu induzieren. Außerdem wurde die mRNA-Expression wichtiger PPARγ-regulierter Gene in Hepatozyten trotz knockdown beider THR-Isoformen signifikant durch Thyroidhormone induziert.
Für eine erste Abschätzung einer möglichen physiologischen Relevanz der PPARγ/RXR-Aktivierung durch Thyroidhormone, wurde die Bildung von TETRAC nach Inkubation von Hepatozyten mit T4 quantifiziert. Es konnte festgestellt werden, dass ausreichend TETRAC in den Hepatozyten gebildet werden kann, um PPARγ zu aktivieren. Auch in einem in vivo-Experiment, bei dem Mäusen ein mit Brom substituiertes T4-Analog (Br-T4) appliziert wurde, um Interferenzen mit der endogenen Thyroidhormon-Produktion zu verhindern, konnte gezeigt werden, dass die PPARγ-regulierte Genexpression in den Lebern der Tiere induziert wurde. Dies deutete auf eine physiologisch relevante Bildung von Br-TETRAC hin, da Br-TETRAC analog zu TETRAC eine hohe Bindungs-Aktivität an PPARγ besaß, während Br-T4 keine Aktivität an diesem Rezeptor aufwies.
Die Ergebnisse dieser Arbeit deuten darauf hin, dass Thyroidhormone neben den THR-vermittelten Effekten auch andere genomische Wirkmechanismen besitzen, indem sie das PPARγ/RXR-Heterodimer aktivieren. Diese biologische Aktivität könnte sowohl eine physiologische als auch eine pharmakologische Relevanz besitzen. Die beiden T4-Metabolite T3 und TETRAC sind in der Lage komplementäre Signalwege zu induzieren. Wird T4 deiodiert kommt es zur Bildung von T3, welches den THR aktiviert. Durch oxidative Deaminierung des T4s bildet sich TETRAC, das wiederum PPARγ bindet und aktiviert. Durch die vermehrte Bildung von TETRAC und anschließende Aktivierung von PPARγ könnte die katabole Wirkung der THR-Signalwege abgeschwächt werden und so eine Art negative Rückkopplung gewährleistet werden. Die physiologische Bedeutung der Interaktion von Thyroidhormonen mit PPARγ/RXR muss jedoch noch genauer untersucht werden.
Aber auch pharmakologisch könnte die Iodthyroacetat-Aktivität an PPARγ eine Rolle spielen. TETRAC könnte durch seinen individuellen Bindungsmodus als Leitstruktur für neue PPARγ-Partialagonisten mit verbessertem Nebenwirkungs-Profil dienen. Außerdem wird das Thyroidhormon-Derivat TRIAC schon jetzt als Leitstruktur für die Entwicklung von Thyroidhormon-Analoga mit THRβ-Selektivität verwendet. Durch die zusätzliche PPARγ-Aktivität könnte zukünftig ein dualer THRβ/PPARγ-Agonist bei Erkrankungen, die mit einer Insulinresistenz einhergehen, Verwendung finden.
Zusammenfassend stellt die Entdeckung der Aktivität von Thyroidhormonen an PPARγ und RXR einen weiteren Baustein im komplexen System der Thyroidhormone dar.
Bacteria constantly attempt to hold up ion gradients across their membranes to maintain their resting potential for routine cell function, while coping with sudden environmental changes. Under abrupt hyperosmotic conditions, as faced when invading a host, most bacteria restore their turgor pressure by taking up potassium ions to prevent death by plasmolysis. Here, the potassium transporter AB, or KtrAB for short, is a key player. KtrAB consists of the membrane-embedded KtrB dimer, which includes two pores organized in tandem, and a cytoplasmic, octameric KtrA ring, which regulates these two pores. The KtrB subunits alone were suggested to function as rather non-selective ion channels translocating potassium and sodium ions. The KtrA subunits confer transport velocity, K+ selectivity as well as Na+ and nucleotide dependency to the Ktr system. The nucleotide regulation by binding to KtrA is rather well characterized. In contrast, the regulatory role of Na+ remains elusive. Controversially discussed is how selective the ion translocation by KtrB is and how KtrA affects it. Although there are several functional and structural data available of KtrAB and its homolog TrkAH, the selectivity of the ion translocation was never thoroughly addressed. The functional characterization of whether KtrAB is a selective ion channel and how selectivity is achieved is in the focus of this thesis. Since selectivity is usually defined by the ion channels’ selectivity filter contained in the pore-forming domain, a particular attention was laid on the ion-translocating subunits KtrB.
KtrB belongs to the superfamily of K+ transporters (SKT). Each KtrB monomer consists of four covalently attached M1-P-M2 motifs, each motif is made of two transmembrane (TM or M) helices that are connected by a pore (P) helix. The four motifs, referred to as domains D1 to D4, are arranged in a pseudo-fourfold symmetry and together form the pore for potassium ion translocation. Each pore contains two structural features thought to be involved in ion selectivity and ion gating. These are the non-canonical selectivity filter and the intramembrane loop. The selectivity filter is localized at the extracellular side of the pore and mostly shaped by the backbone carbonyl groups of the loops connecting the P and M2 helices in each domain. In KtrB, each P-loop contains only one highly conserved glycine residue instead of the classical -TVGYG- signature sequence of a K+ channel. This simple constructed selectivity filter led to the hypothesis that KtrAB would only have low ion selectivity. The intramembrane loop is formed by broken helix D3M2 and is located directly under the selectivity filter. It consists mostly of polar residues and acts as a molecular gate restricting ion fluxes. The intramembrane loop has been shown to be regulated by nucleotide binding to KtrA. Additionally, it could directly or indirectly be affected by Na+ binding. Further, the loop might even be involved in ion selectivity because it presents a physical barrier inside the pore.
To address the ion selectivity of the Ktr system, first, the ion binding specificity of KtrB was investigated. Binding affinities of different cations to KtrB were determined using isothermal titration calorimetry (ITC). For this, KtrB from Vibrio alginolyticus was heterologously produced in and purified from Escherichia coli. 12 L of culture roughly yielded 4 to 8 mg of the functional KtrB dimer in detergent solution. ITC measurements were performed in two different buffers, one choline-Cl-based and one LiCl-based buffer. No differences in the affinity between Na+ (KD = 1.8 mM), K+ (KD = 2.9 mM), Rb+ (KD = 1.9 mM) or Cs+ (KD = 1.6 mM) were detected in the choline-Cl-based buffer; only Li+ did not bind. In contrast, ITC measurements in LiCl-based buffer revealed a significant preference for K+ (KD = 91 µM) over Rb+ (KD = 2.4 mM), Cs+ (KD = 1.7 mM) and particularly Na+ (for which no binding was observed). Similarly, the presence of low millimolar NaCl concentrations in the choline-Cl-based buffer led to a decreased KD value of 260 µM. Hence, small cations, which usually are present in the natural environment, seem to modulate the selectivity filter for a better binding of K+ ions providing K+ selectivity. In fact, the low binding affinities of the other ions could indicate that they do not even bind to the selectivity filter but to the cavity. However, ITC competition experiments showed that all four ions compete for the same or overlapping binding sites, with Rb+ and Cs+ even blocking K+ binding at concentrations 10-fold above their binding affinities. Importantly, at physiological NaCl concentrations of 200 mM, the apparent binding affinity for K+ to KtrB was still 3.5 mM. This suggested that Na+ can also bind to KtrB’s selectivity filter but with a comparably low binding affinity providing an unexpectedly high preference for K+ ions.
...
Die vorliegende Dissertation gliedert sich in 2 Abschnitte: Im 1. Abschnitt wurden die Auswirkungen des Naturstoffs Phytol auf den Krankheitsverlauf des murinen EAE-Modells charakterisiert, während im 2. Abschnitt die immunmodulierenden Eigenschaften der neuartigen Leitsubstanzen Silvestrol sowie Steroid Substanz 1o untersucht wurden.
Vorarbeiten zeigten einen positiven Einfluss von Phytol auf den Krankheitsverlauf im murinen EAE-Modell für Multiple Sklerose, eine verringerte Proliferationsfähigkeit von Splenozyten sowie eine Regulation der NOX2 mRNA-Expression (Blum et al., 2018b).
In der vorliegenden Arbeit konnte nachgewiesen werden, dass die Gabe von Phytol den Prozess der Demyelinisierung im lumbalen Rückenmark deutlich reduzierte und die Anzahl der Immunzellen in den inguinalen Lymphknoten sowie im lumbalen Rückenmark signifikant verringerte. Weiterhin konnte eine Regulation der spezifischen T-Zell Transkriptionsfaktoren T Bet sowie Foxp3 nachgewiesen werden. Es zeigte sich, dass Phytansäure, nicht jedoch Pristansäure, die beiden Metaboliten von Phytol, die Proliferationsfähigkeit der T-Zellen signifikant verringerte. Beide Metaboliten zeigten zusätzlich unterschiedlichen Einfluss auf die T-Zell Subtypen. Hultqvist et al. konnten eine verstärkte Bildung von reaktiven Sauerstoffspezies (ROS) durch Phytol nachweisen (Hultqvist et al., 2006). Vorarbeiten zeigten eine Steigerung der mRNA-Expression des ROS-produzierenden Enzymkomplex NOX2 im Verlauf des EAE-Modells sowie eine Regulation der NOX2-Expression im lumbalen Rückenmark und in den inguinalen Lymphknoten durch Phytol (Blum et al., 2018b). Deshalb wurde die Rolle von NOX2 an den Phytol-vermittelten Effekten weiter charakterisiert. Dabei zeigte sich, dass die gesteigerte NOX2-Expression im lumbalen Rückenmark auf die eingewanderten Immunzellen zurückzuführen war. Die von NOX2 im zentralen Nervensystem (ZNS) gebildeten ROS, welche zur Schädigung der Myelinschicht beitragen können, wurden durch die Gabe von Phytol im lumbalen Rückenmark verringert. Untersuchungen in NOX2KO-Mäusen zeigten, dass die beobachteten ex vivo Effekte von Phytol sowie dessen Metaboliten nur teilweise NOX2-abhängig waren. Im murinen EAE-Modell mit NOX2KO-Mäusen zeigte Phytol weiterhin einen positiven Einfluss auf die klinischen Symptome. Auffällig war dabei, dass NOX2KO-Tiere grundsätzlich weniger klinische Scores zeigten als Wildtyp Tiere. In NOX2-Chimären hatte Phytol keinen signifikanten Einfluss auf den Krankheitsverlauf. Grund dafür könnte eine Beschädigung der Blut-Hirn-Schranke bei der Generierung der Chimären und eine damit verbundene verstärkte Infiltration von Immunzellen in das ZNS gewesen sein. Weiterhin konnte Phytol möglicherweise über die geschädigte Blut-Hirn-Schranke verstärkt in das ZNS eindringen und dort über eine gesteigerte ROS-Produktion zu schädigenden Effekten führen.
Die in vivo Daten weisen auf einen überwiegend NOX2-unabhängigen Wirkmechanismus von Phytol hin. Dennoch scheint NOX2 bei einigen Effekten zumindest beteiligt zu sein. Zusammenfassend zeigte die Gabe von Phytol einen überwiegend positiven Einfluss auf den Krankheitsverlauf im murinen EAE-Modell, dennoch ist die Phytol-vermittelte Induktion von NOX2 und die Bildung von ROS kritisch zu sehen, da diese sowohl positive als auch negative Effekte vermitteln und stark von der Quantität sowie der Lokalisation der Bildung abhängig sind.
Im 2. Teilprojekt wurden die immunmodulierenden Auswirkungen der neuartigen Leitsubstanzen Silvestrol sowie Steroid Substanz 1o charakterisiert. Der anti-viral wirksame Naturstoff Silvestrol zeigte dabei diverse Auswirkungen auf die Differenzierung sowie Polarisierung von humanen Makrophagen. Während der Differenzierung inhibierte Silvestrol das anti-inflammatorische bzw. resolutionsfördernde Potential der Makrophagen durch eine Reduktion der resolutionsfördernden Oberflächenmarker CD206 und TREM2. Weiterhin wurde die Sezernierung der anti-inflammatorischen Zyto- bzw. Chemokine IL-10 und CCL18 verringert. Der pro-inflammatorische Phänotyp von M1-Makrophagen wurde weiterhin durch die vermehrte Bildung von TNF-α unterstützt, während bei M2-Makrophagen der anti-inflammatorische bzw. resolutionsfördernde Phänotyp verstärkt wurde. In Dendritischen Zellen schien Silvestrol sowohl die Differenzierung als auch die Aktivierung zu inhibieren, da zahlreiche Oberflächenmarker und sezernierte Zytokine signifikant verringert wurden. Die Stoffwechselwege der oxidativen Phosphorylierung und der Glykolyse wurden sowohl in Makrophagen als auch in Dendritischen Zellen signifikant reduziert. Demnach ist unklar, ob in der Summe die pro- oder anti-inflammatorischen Aspekte von Silvestrol überwiegen und ob der Einfluss auf den Stoffwechsel die Immunantwort beeinträchtigt.
Der anti-parasitäre Wirkstoff Steroid Substanz 1o zeigte keinen negativen Einfluss auf die Viabilität in primären humanen Immunzellen bis zu einer Konzentration von 50 µM und verstärkte das pro-inflammatorische Profil von M1-Makrophagen. Weiterhin wurde der anti-inflammatorische bzw. resolutionsfördernde Phänotyp von M2-Makrophagen unterdrückt und stattdessen die pro-inflammatorischen Aspekte verstärkt. Diese Beobachtungen der veränderten Oberflächenmarker sowie der sezernierten Zytokine wurden weiterhin durch die Veränderung des zellulären Stoffwechsels gestützt. Dabei steigerte Steroid Substanz 1o die Glykolyse in M2-Makrophagen, welche eigentlich für M1-Makrophagen charakteristisch ist. Dadurch kann die Verschiebung der M2-Makrophagen zu einem M1-Phänotyp erklärt werden. Weiterhin beeinträchtigte Steroid Substanz 1o die Differenzierung und Aktivierung von Dendritischen Zellen. Zusammenfassend verstärkte Steroid Substanz 1o überwiegend die pro-inflammatorischen Aspekte der Immunreaktion durch eine Aktivierung der M1-Makrophagen. Bei der möglichen Anwendung als Therapeutikum für Malaria sowie Schistosomiasis kann somit das Immunsystem bei der initialen Abwehr der Parasiten unterstützt werden.
The electron transport chain (ETC) is used by cells to create an electrochemical proton gradient which can be used by the ATP synthase to produce ATP. ETC, also called respiratory chain, is formed in mitochondria by four complexes (complex I-IV) and mediated by two electron carriers: cytochrome c and ubiquinone. Electrons are passed from one complex to another in a series of redox reactions coupling proton pumping from the negative (N) side of the membrane to the positive (P) side. Complex I can introduce electrons into the ETC by oxidizing NADH to NAD+ and reducing quinone (Q) to quinol (QH2). The process accomplishes pumping of four protons across the membrane. Complex II is another electrons entry point. It catalyzes the oxidation of succinate to fumarate while reducing Q to QH2. Complex III, also called cytochrome bc1 complex, can transfer the electrons from QH2 to cytochrome c and couple to proton pumping. In complex III the Q-cycle contributes four proton translocations: two protons are required for the reduction of one quinone to a quinol and two protons are released to the P side. Complex IV (cytochrome c oxidase), the terminal complex of the ETC, catalyzes the electron transfer to oxygen and pumps four protons to the P side. Structures of ETC complexes are available. However, the structure of a hyperthermophilic cytochrome bc1 complex has not been elucidated till now. Additionally, the dimeric crystal structure of cytochrome c oxidase from bovine has been discussed controversially.
To build up a functional complex, cofactors are required. The active site of A- and B-type cytochrome c oxidases contain the high spin heme a which is synthesized by the integral membrane protein heme A synthase (HAS). HAS can form homooligomeric complexes and its oligomerization is essential for the biological function of HAS. HAS is evolutionarily conserved among prokaryotes and eukaryotes. Despite its importance, little is known about the detailed structural properties of HAS oligomers.
During my PhD studies, I focused on the cytochrome c oxidase (AaCcO), the cytochrome bc1 complex (Aabc1) and the heme A synthase (AaHAS) from Aquifex aeolicus. This organism is one of the most hyperthermophilic ones and can live at extremely high temperatures, even up to 95 °C. Respiratory chain complexes provide energy for the metabolism of organisms, and their structures have been studied extensively in the past few years. However, there has been a lack of atomic structures of complexes from hyperthermophilic and ancient bacteria, so little is known about the mechanism of these macromolecular machines under hyperthermophilic conditions. Therefore, my PhD studies had four main objectives: 1) to structurally and functionally characterize AaCcO, 2) to reveal the mechanism of Aabc1 thermal stability based on its structure, 3) to determine the oligomerization of AaHAS, 4) to provide valuable insights into the relationship between function and oligomerization of AaHAS.
1) Structure of AaCcO
Heme-copper oxidases (HCOs) catalyze the oxygen reduction reaction being the terminal enzymes in the plasma membranes in many prokaryotes or of the aerobic respiratory chain in the inner mitochondrial membrane. By coupling this exothermic reaction to proton pumping across the membrane to the P side, they contribute to the establishment of an electrochemical proton gradient. The energy in the proton electrochemical proton gradient is used by the ATP synthase to generate ATP. HCOs are classified into three major families: A, B and C, based on phylogenetic comparisons. The well-studied aa3-type cytochrome c oxidase from Paracoccus denitrificans (P. denitrificans) represents A-family HCOs. So far, the only available structure of the ba3-type cytochrome c oxidase from Thermus thermophilus represents the B-family of HCOs. This family contains a number of bacterial and archaeal oxidases. The C-family contains only cbb3-type cytochrome c oxidases.
The AaCcO is one of the ba3-type cytochrome c oxidases. Based on the genomic DNA sequence analysis, it has been revealed that A. aeolicus possesses two operons coding for cytochrome c oxidases (two different subunit I genes, two different subunit II genes and one subunit III gene). So far, only subunits CoxB2 and CoxA2 were identified. The presence of the additional subunit IIa was reported in 2012. Moreover, a previous paper reported that AaCcO can use horse heart cytochrome c and decylubiquinol as electron donors and the typical cytochrome c oxidase inhibitor cyanide does not block the reaction completely.
In the course of my PhD studies, I performed heterologous expression of AaCcO in Pseudomonas stutzeri (P. stutzeri) and co-expression with AsHAS in Escherichia coli, respectively. The subcomplex CoxA2 and CoxB2 can be purified from P. stutzeri, however, it lacks heme A. Additionally, a protocol for the heterologous production of cytochrome c555 from A. aeolicus was established. In parallel, I also purified the AaCcO from native membranes according to previously reported methods with some modifications. The activity of AaCcO with its native substrate, cytochrome c555, was 14 times higher than with horse heart cytochrome c.
To enable a detailed investigation and comparison of AaCcO and other cytochrome c oxidases, the cryo-EM structure of AaCcO was determined to 3.4 Å resolution. It shows that the three subunits CoxA2, CoxB2, and IIa are tightly bound together to form a dimer in the membrane. Surprisingly, CoxA2 contains two additional TMHs (TMH13 and TMH14) to enhance the protein stability. The cofactors heme a3, heme b, CuA and CuB are also identified. Interestingly, two molecules of 1,4-naphthoquinone and cardiolipin were observed in the dimer interface. Based on the structure analysis, the AaCcO possesses only the K-pathway for proton delivery to the active site and proton pumping.
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Uncaging approach, native membrane dynamics and lipidic cubic phases in biomolecular solid-state NMR
(2019)
It was previously shown for the Escherichia coli diacylglycerol kinase (DgkA) that enzyme-reactions at the membrane interface can be monitored by solid-state NMR. However, such studies can face problems due to limited accessibility of the active sites: Natural substrates for membrane enzymes, but also ligands for membrane proteins or lipid mediators, are either partitioning into the membrane and cannot be added easily, or if soluble exhibit accessibility restrictions, as they cannot freely pass through lipid bilayers. This situation complicates quantitative kinetic analysis of biochemical processes such as enzyme activity, ligand binding, but also oligomerization or folding reactions in the membrane or at its interface under MAS NMR conditions.
To overcome these limitations the feasibility and possible advantages of the uncaging approach as a new tool for biomolecular solid-state NMR to trigger reactions by light have been explored. DgkA’s enzymatic activity, exemplary of a biochemical process on the membrane interface, was thereby triggered in situ during MAS by light-induced release of its substrates that were rendered inactive with photolabile protecting groups. To be capable of uncaging sufficient amounts of substrate during MAS to follow the enzymatic reaction via 31P real-time NMR measurements, several illumination variants including an existing illumination setup to study retinal proteins under cryogenic conditions via DNP enhanced NMR were tested. As uncaging of micromole amounts of substrates requires a higher flux compared to initiation of a photocycle in retinal proteins, a new illumination setup was built with Bruker Biospin and Leoni Fibertech. It consists of a modified MAS probe and a suitable fiber bundle, allowing to efficiently couple light from high power LEDs into a sapphire rotor containing the sample, without disturbing the magnetic field homogeneity or sample rotation. By reducing the sample volume to the illuminated area up to 60 mM ATP were released by uncaging NPE ATP to initiate DgkA’s activity in several tested membrane mimetics. These mimetics included liposomes and bicelles, which are well established in the field of biomolecular solid state NMR as well as the optically transparent lipidic cubic phase of monoolein, widely used in membrane protein crystallography, but not yet well characterized as membrane mimetic under MAS conditions. A unique and powerful but compared to time and spatial resolution often underrepresented advantage of the uncaging approach for biophysical studies has been demonstrated by successful uncaging of a non-miscible lipid substrate to trigger DgkA’s kinase reaction: Initiation of processes that cannot easily be triggered by mixing. Examples of these are reactions involving highly hydrophobic, membrane partitioning compounds including lipid substrates, ligands or interaction partners, but also oligomerization or folding of biomacromolecules. The herein performed experiments therefore serve as a first demonstration of the uncaging approach’s feasibility and compatibility with a wide variety of membrane mimetics and give a first indication of its potential for a variety of biomolecular solid state NMR experiments.
As high accessibility for solutes has been a second focus for the choice of membrane mimetics, DgkA’s activity in the lipidic cubic phases of monoacylglycerols with its two continuous networks of water channels has been further characterized. Kinetic parameters obtained from 31P real time solid state NMR experiments revealed that DgkA’s activity is similar to activities obtained in swollen cubic phases in a bath solution with wider water channels. Diffusion of ATP in a non swollen cubic phase was however strongly reduced compared to ATP in solution as diffusion measurements showed. Therefore, saturation of the enzyme required distinctly higher ATP concentrations. These results thereby underline the advantage of a non invasive and label free method like NMR to directly gain information about enzymatic reactions of immobilized enzymes in porous materials. The obtained wealth of information from 31P real time NMR experiments and biochemical assays in different membrane mimetics in presence and absence of lipid substrates and activators also provided further insight into DgkA’s enzymatic activity. It confirms ATP binding and hydrolysis in the absence of a lipid substrate, in agreement with the proposed mode of substrate binding, and allowed to estimate the in vivo relevance of previously observed ATPase activity in liposomes.
Further exploration of the cubic phase as membrane mimetic for protein solid state NMR revealed its high stability under MAS at elevated temperatures and capacity to reconstitute sufficient amounts of DgkA. Unlike monoolein, DgkA was cross-polarizable in a cubic phase and exhibited similar dynamics compared to DgkA reconstituted into liposomes, allowing to acquire the herein shown dipolar coupling based 2D protein spectra. As lipidic cubic phases are not containing phospholipids, monoacylglycerols could be especially useful as membrane mimetics for 31P correlation spectra. Initial experiments under DNP conditions, where in liposomes line broadening causes severe overlap of phospholipid signals and unspecific cross polarization highlight this aspect.
In summary, herein reported results of the experiments performed with lipidic cubic phases demonstrate that they are robust and versatile membrane mimetics. They could be of advantage for a variety of solid-state NMR experiments where either optical transparency for efficient illumination is desired, accessibility for solutes and membrane components under MAS is required, or interference of phosphorous signals of other membrane mimetics must be avoided.
In the second chapter of this thesis 1H solid-state NMR as a label free method to probe membrane order and dynamics directly within a cellular and disease relevant context was used to observe the effects of soluble epoxide hydrolase (sEH) encoding gene knock-outs on membrane dynamics. Knock-out of the sEH encoding gene changed the overall membrane dynamics in the physiological temperature range of native membranes derived from mouse brains, making the bulk membrane more dynamic. To confirm that these effects are related to the enzymatic activity of sEH, substrates and products of sEH were added to evaluate their effects on membrane dynamics. 19,20 dihydroxydocosapentaenoic acid (DHDP), a product of sEH, partially reversed the knock out phenotype in a concentration dependent manner whereas the substrate 19,20 epoxydocosapentaenoic acid did not cause any effects. As both polyunsaturated fatty acids did not show differences in phase behavior in a simple phospholipid bilayer these results provide evidence that the previously observed concentration dependent DHDP induced relocation of cholesterol away from detergent resistant lipid raft fractions is associated with alteration of membrane dynamics. Therefore, also the effect of cholesterol removal via cyclodextrin on membrane dynamics was analyzed. Removal of cholesterol led to a similar temperature profile of wild type and knock out membranes thereby supporting the hypothesis that DHDP induced relocation of cholesterol is causing altered membrane dynamics. These alterations have been shown by the lead authors of the collaborative research project to induce relocation of various membrane proteins and are involved in the development of diabetic retinopathy. Furthermore, in this context inhibition of sEH has been shown to inhibit diabetic retinopathy and proposed as target for prevention of one of the leading causes of blindness in the developed world.
The endosteal bone marrow niche and vascular endothelial cells provide sanctuaries to leukemic cells. In murine chronic myeloid leukemia (CML) CD44 on leukemia cells and E-selectin on bone marrow endothelium are essential mediators for the engraftment of leukemic stem cells (LSC). We hypothesized that non-adhesion of CML-initiating cells to E-selectin on the bone marrow endothelium may lead to superior eradication of LSC in CML after treatment with imatinib than imatinib alone. Indeed, here we show that treatment with the E-selectin inhibitor GMI-1271 in combination with imatinib prolongs survival of mice with CML via decreased contact time of leukemia cells with bone marrow endothelium. Non-adhesion of BCR-ABL1+ cells leads to an increase of cell cycle progression and an increase of expression of the hematopoietic transcription factor and protooncogene Scl/Tal1 in leukemia-initiating cells (LIC). We implicate SCL/TAL1 as indirect phosphorylation target of BCR-ABL1 and as a negative transcriptional regulator of CD44 expression. We show that increased SCL/TAL1 expression is associated with improved outcome in human CML. These data demonstrate the BCR-ABL1-specific, cell-intrinsic pathways leading to altered interactions with the vascular niche via the modulation of adhesion molecules - a strategy therapeutically exploitable in future.
In der vorliegenden Arbeit konnte die Entwicklung und Evaluierung einer neuen Apparatur zur Untersuchung der Freisetzungseigenschaften von kolloidalen Arzneiträgern erfolgreich umgesetzt werden. Verschiedene Prototypen und Versionen des Dispersion Releasers konnten entwickelt und mit Hilfe der Werkstatt des Fachbereiches 14 umgesetzt werden. Dabei ermöglicht die letzte Optimierung (Version 3) den Einsatz beider relevanter Dialysemembranen. Sowohl regenerierte Cellulose als auch Celluloseacetat konnten zur Freisetzungsuntersuchung eingesetzt werden. Vorteilhaft ist diese Optionalität vor allem, da auf diese Weise Partikelsysteme und Wirkstoffe mit unterschiedlichen physiko-chemischen Eigenschaften in der gleichen Apparatur auf das Freigabeverhalten untersucht werden können. Darüber hinaus hat der Dispersion Releaser das Potential, sich im Bereich der Freisetzungsuntersuchungen kolloidaler Arzneiträger über den Arbeitskreis von Dr. Wacker hinaus zu einem bevorzugten Testsystem zu entwickeln. In diesem speziellen Gebiet der Freisetzungsuntersuchung von kolloidalen Arzneiträgern wie Nanopartikeln oder Liposomen existiert bisher keine Apparatur, die als sogenannter Gold-Standard angesehen werden kann. Untersuchungen mittels der Durchflusszelle, dem A4D oder Sample & Separate Methoden im Labormaßstab unterliegen kaum standardisierbaren Bedingungen und diversen Limitierungen. Der Dispersion Releaser ist einfach zu handhaben und mit wenig Aufwand in die Freisetzungsapparatur 2 nach Ph. Eur. einzubauen. Zu den zahlreichen Vorteilen gehören außerdem die Kontrolle der Rührgeschwindigkeit sowie der Temperatur und der mögliche Probenzug in beiden Kompartimenten der Dialysezelle. Würden mehr Freisetzungsuntersuchungen von kolloidalen Arzneiträgern mit der gleichen, im besten Falle standardisierten, Apparatur durchgeführt, so würde dies die Vergleichbarkeit der Resultate erheblich verbessern.
Die präparierten Modellarzneiformen der beiden Arzneistoffe mTHPC und Flurbiprofen konnten die Funktionalität des Dispersion Releasers mittels der erhobenen Freisetzungsprofile belegen. Es konnten sowohl schnell als auch langsamer freisetzende kolloidale Formulierungen produziert und identifiziert werden. Als Standard-Freisetzungsmedium diente ein 10 mM Phosphatpuffer versetzt mit Natrium- und Kaliumchlorid bei pH 7,4. Dieser im Hinblick auf pH-Wert, Osmolalität und Pufferkapazität dem Blut angepasste Puffer lieferte reproduzierbare Freisetzungsprofile für alle untersuchten Partikelsysteme. Der Zusatz von Plasmaproteinen erfolge durch Zufügen von FBS zu diesem Standardpuffersystem oder durch Verwendung des im Ph. Eur. gelisteten Phosphatpuffers pH 7,2 mit Rinderalbumin. Der Effekt der im Plasma natürlicherweise enthaltenen Komponenten, insbesondere der Plasmaproteine, auf das Freisetzungsprofil zeigt in dieser Arbeit, dass -wie erwartet- die Freisetzungseigenschaften in komplexen, bzw. physiologischen Medien deutlich von denen in einfachen Puffersystemen abweichen können. Die Anwesenheit von Plasmaproteinen führte zu einer veränderten Freisetzungsrate, sowohl im Falle von Flurbiprofen als auch im Falle von mTHPC. Für mTHPC konnte außerdem der Zusatz von lösungsvermittelndem Methyl-ß-cyclodextrin zum Freisetzungsmedium etabliert werden. Gegenüber üblicherweise eingesetzten Tensiden verändert dieses cyclische Zuckermolekül die Oberflächenspannung des Mediums und damit die Benetzbarkeit der Partikel nicht.
Die mittels Dispersion Releaser und Dialysesack erhobenen Freisetzungsdaten des Wirkstoffes Flurbiprofen wurden in Zusammenarbeit mit Frau Dr. Li Kirsamer einer mathematischen Auswertung unterzogen. Auf diese Weise konnte zunächst das Freisetzungsprofil beider Kompartimente der Dialyse dargestellt werden, wodurch weitere Erkenntnisse der Qualität des kolloidalen Trägers und seiner Eignung für den jeweiligen Arzneistoff abgeleitet werden können. Die Auswertung an Hand dieses Modells berücksichtigt zwar die Fraktion des freigesetzten Wirkstoffes in beiden Kompartimenten, ermittelt jedoch keine theoretische Freisetzungsrate welche ohne Membrankinetik messbar wäre. Dies wäre in der Auswertung von Freisetzungsdaten ebenfalls von Interesse, konnte jedoch im Rahmen dieser Arbeit nicht näher untersucht werden. Berechnungen wie diese können in weiterführenden Arbeiten möglicherweise dazu dienen, in vitro Freisetzungsdaten mit Plasmaprofilen zu korrelieren. Mit dem Erwerb der Rechte an dem Dispersion Releaser durch die Firma Pharma Test Apparatebau AG im Jahr 2016 wurde der Weg für eine mögliche breite und auch kommerzielle Nutzung der neuartigen Apparatur eingeleitet. Diese Transaktion und die andauernde Kooperation zwischen Pharmatest und dem Arbeitskreis von Herrn Prof. Dr. Wacker soll die erfolgreiche Beantwortung der Fragestellungen innerhalb der vorliegenden Arbeit mit dem Titel „Entwicklung einer Apparatur zur in vitro Testung der Wirkstofffreisetzung aus kolloidalen Arzneistoffträgern“ hervorheben.
The members of the multidrug/oligosaccharidyl-lipid/polysaccharide (MOP) transporter superfamily mediate export of a wealth of molecules of physiological and pharmacological importance. According to the Transporter Classification Database (TCDB), the MOP superfamily is mainly categorized into six distantly related families functionally characterized families: the multidrug and toxic compound extrusion (MATE), the polysaccharide transporter (PST), the oligosaccharidyl-lipid flippase (OLF), the mouse virulence factor (MVF) the agrocin 84 antibiotic exporter (AgnG), and the progressive ankylosis (Ank) family. Among these, the multidrug resistance MATE family transporters are most ubiquitous, being present in all domains of life: Archaea, Bacteria and Eukarya. As secondary active transporters, they utilize transmembrane electrochemical ion gradients of Na+ and/or H+ in order to drive the efflux of xenobiotics or cytotoxic metabolic waste products with specificity mainly for polyaromatic and cationic substrates. Active efflux of drugs and toxic compounds carried out by multidrug transporters is one of the strategies developed by bacterial pathogens to confer multidrug resistance. MATE proteins provide resistance to, e.g., fluoroquinolone, aminoglycoside antibiotics, and anticancer chemotherapeutical agents, thus serving as promising pharmacological targets for tackling a severe global health issue. Based on their amino acid sequence similarity, the MATE family members are classified into the NorM, the DNA-damage-inducible protein F (DinF), and the eukaryotic subfamilies. Structural information on the alternate conformational states and knowledge of the detailed mechanism of the MATE transport are of great importance for the structure-aided drug design. Over the past decade, the crystal structures of representative members of the NorM, DinF and eukaryotic subfamilies have been presented. They all share similar overall architecture comprising 12 transmembrane helices (TMs) divided into two domains, the N-terminal domain (TMs 1-6) and the C-terminal domain (TMs 7-12), connected by a cytoplasmic loop between TM6 and TM7 (Fig. II.1). Since all available MATE family structures are known only in V-shaped outward-facing states with the central binding cavity open towards the extracellular side, a detailed understanding of the complete transport cycle has remained elusive. In order to elucidate the underlying steps of the MATE transport mechanism, structures of distinct intermediates, particularly inward-facing conformation, are required.In my PhD project, structural and functional studies have been performed on a MATE family (DinF subfamily) transporter, PfMATE, from the hyperthermophilic and anaerobic archaeon Pyrococcus furiosus. This protein was produced homologously in Pyrococcus furiosus as well as heterologously in Escherichia coli, and used for the subsequent purification and crystallization trials by the vapor diffusion (VD) and lipidic cubic phase (LCP) method. To the best of my knowledge, PfMATE is the first example of a successful homologous production of a membrane protein in P. furiosus. Due to the very low final amount of the purified protein from the native source, the heterologously produced PfMATE samples were typically used for the extensive structural studies. Crystal structures of PfMATE have been previously determined in an outward-facing conformation in two distinct states (bent and straight) defined on the arrangement of TM1. A pH dependent conformational transition of this helix regulated by the protonation state of the conserved aspartate residue Asp41 was proposed. However, it has been discussed controversially, leading to the hypothesis about TM1 bending to be rather affected by interactions with exogenous lipids (monoolein) present under the crystallization conditions. Based on these open questions, an experimental approach to investigate the role of lipids as structural and functional modulators of PfMATE has been taken in the course of my PhD project. The interplay between membrane proteins and lipids can affect membrane protein topology, structure and function. Considering differences between archaeal and bacterial lipid composition, cultivation of P. furiosus cells and extraction of its lipids was followed by the mass spectrometry (MS) based lipidomics for identification of individual lipid species in the archaeal extract. In order to assess the effects of lipids on PfMATE, different lipid molecules were used for co-purification and co-crystallization trials. This dissertation presents a workflow leading to the structure determination of a MATE transporter in the long sought-after inward-facing state, which has been achieved upon purification and crystallization of the heterologously produced PfMATE in the presence of lipids from its native source P. furiosus. Also, the PfMATE outward-facing state obtained from the crystals grown at the acidic pH conditions sheds light on the previously proposed pH-dependent structural alterations within TM1. It is interesting to note that the inward and outward-facing states of PfMATE were obtained from the crystals grown under similar conditions, but in the presence and absence of native lipids, respectively. This observation supports the hypothesis about physiologically relevant lipids to act as conformational modulators or/and a new class of substrates, expanding the substrate spectrum of the MATE family transporters. Comparative analysis of two PfMATE states reveals that transition from the outward to the inward-facing state involves rigid body movements of TMs 2-6 and 8-12 to form an inverted V, facilitated by a loose binding of TMs 1 and 7 to their respective bundles and their conformational flexibility. Local fluctuations within TM1 in the inward-facing structure, including bending and unwinding in the intracellular half of the helix, invoke its highly flexible nature, which is suitable for ion and substrate gating.
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Food allergies are defined as an adverse health effect arising from a specific immune response that occurs reproducibly on exposure to a given food. The prevalence of food allergies has increased in the past decade. Epidemiologic studies involving controlled food challenges for the diagnosis of food allergies indicated that between 1 % to 10.8 % of the population have immunemediated non-toxic food hypersensitivity.
Despite the increasing prevalence, no curative treatment has been established for food allergies so far except the complete avoidance of the elicited food. To establish safe and effective immunotherapy for food allergies, it is of crucially importance to elucidate pathological mechanism of such diseases.
Food allergies are classified into IgE-mediated and non-IgE mediated (T-cell mediated) allergies, depending on the immunologic pathways and the role of the IgE on the pathogenesis of the disease. Allergic enteritis (AE) is a gastrointestinal form of food allergy. It is classified as non-IgE-mediated food allergy. However, patients with AE often develop IgE and high levels of IgE have been associated with development of persistent AE. The gastrointestinal symptoms of AE are nonspecific, resulting in the fact that a broad differential diagnoses including diagnostic approaches for allergic diseases are necessary to rule out other gastrointestinal pathologies. Biopsies of patients with allergic enteritis have shown infiltration of inflammatory cells (e.g. mast cells, eosinophils, neutrophils, and T cells) in the lamina propria, disruption of intestinal villi, edema, and presence of goblet cells in the intestine...
This dissertation contains two chapters. Each chapter covers a unique topic within RNA science and is divided in two sub sections, part A and B. Each chapter contains an introduction.
Chapter 1 gives an insight into challenges encountered during sample design and preparation for single molecule Förster energy transfer (smFRET) spectroscopy and offers a solution via a newly establishedestablished workflow to obtain accurate smFRET constructs. Following this workflow, a FRET network could be generated, which allowed a detailed structural dynamics study on H/ACA RNP during catalysis with smFRET spectroscopy. This led to detailed mechanistic insights into H/ACA RNPs dynamics during catalysis.
Chapter 2 deals with RNA synthetic biology whereby a novel eclectic design strategy for RNA of interest (ROI) release platform is presented, which allows to release a diverse ROI sequences with single nucleotide precision triggered by an external stimulus. This design strategy was used to establish a ROI release system and its powerful performance in in vitro and in vivo applications was shown.
Eukaryotische Zellen sind durch, aus Lipiddoppelschichten bestehenden, Membranen in Kompartimente mit unterschiedlichen Funktionen eingeteilt. Um einen Transport von Molekülen über die Membranen hinweg zu gewährleisten, werden Kanälen und Transporter benötigt. Eine Familie von Transportern sind die ATP-binding cassette (ABC) Transporter, die in allen Lebewesen, von Bakterien bis zum Menschen, vorkommen. Ein Mitglied dieser Familie ist der transporter associated with antigen processing-like (TAPL oder ABCB9). TAPL ist ein lysosomaler Polypeptidtransporter der per ATP-Hydrolyse Peptide von 6 – 59 Aminosäuren Länge vom Zytosol in das Lumen der Lysosomen transportiert. Hierbei kann TAPL, das ein Homodimer ist, in zwei funktionale Domänen geteilt werden. Der Teil des Komplexes, der für den Transport zuständig ist, wird als coreTAPL bezeichnet. Dieser beinhaltet die zytosolischen nucleotide binding domains (NBDs), die ATP binden und hydrolysieren können, und die Transmembrandomänen (TMDs), die Peptide binden und sie durch konformationelle Änderungen auf der anderen Membranseite freilassen. Die zweite Domäne ist eine N-terminale TMD, die als TMD0 bezeichnet wird. Dieser, aus vier Transmembranhelices (TMHs) bestehende Teil des Proteins, ist für die Lokalisation von TAPL in der lysosomalen Membran verantwortlich, sowie für die Interaktion mit den dort lokalisierten Membranproteinen LAMP-1 und LAMP-2. CoreTAPL ohne die TMD0s erreicht nicht die Lysosomen, sondern liegt in der Plasmamembran (PM) der Zelle vor. Die TMD0 hingegen benötigt coreTAPL nicht um korrekt in der lysosomalen Membran lokalisiert zu sein.
Die korrekte Lokalisation in der Zelle ist ein kritischer Punkt für ein Protein, um seine Funktion ausüben zu können. Die Transportprozesse vom Ort der Synthese des Proteins, dem Endoplasmatischem Reticulum (ER), zum Organell wo es seine Funktion ausüben soll, umfassen dutzende Proteine und Proteinkomplexe und ein komplexes Zusammenspiel zwischen Proteinen und den einzigartigen Lipidzusammensetzungen der Membranen verschiedener Organellen. Auf das Einfachste heruntergebrochen benötigt ein Transmembranprotein eine kurze Aminosäuresequenz auf der zytosolischen Seite, die Signalsequenz. Diese Sequenz wird von sogenannten Adapterproteinen erkannt, die wiederum andere Bestandteile der zellulären Maschinerie rekrutieren, die letztlich Vesikelbildung, Transport und Fusion mit der Zielorganelle vermitteln. Allerdings weisen nicht alle lysosomalen Transmembranproteine eine solche Signalsequenz auf, sondern besitzen unkonventionelle Zieldeterminanten, wie posttranslationale Modifikationen, oder sie interagieren mit anderen Proteinen, die wiederum die Interaktion mit den Adapterproteinen vermitteln.
Der Fokus der vorliegenden Arbeit liegt in der erfolgreichen Entwicklung von vier neuen Methoden zur Darstellung von Sulfonen und von einer neuen Methode zur Synthese von N-Aminosulfonamiden. Dabei sollen die Strukturmotive von Sulfonen und Sulfonamiden aus stabilen Startmaterialien in einer einfachen Durchführung, vorzugsweise in einer Eintopf-Synthese oder Multikomponenten-Reaktion, aufgebaut und der Reaktionsmechanismus weitestgehend experimentell aufgeklärt werden. In diesem Rahmen konnte die Lücke einer Nickel-katalysierten Darstellung von Diarylsulfonen sowohl unter thermischen als auch unter photochemischen Bedingungen gefüllt werden. Zusätzlich konnten im Bereich der SO2-Fixierung Sulfonylradikale mittels Diaryliodoniumsalzen und sichtbaren Licht erzeugt werden, die mit dem entsprechenden Quencher zum Sulfonamid oder Sulfon weiter reagieren konnten.
Aim: Long noncoding RNAs (lncRNAs) belong to the interface of epigenetics and exhibit diverse functions. Their features depend on their sequence, genomic location and tertiary structure. The aim was to identify novel lncRNAs and characterise their physiological functions and mechanisms in endothelial cells. Three different approaches were performed:
The hypothesis that pseudogene-annotated lncRNA NONHSAT073641 regulates the expression of their parental gene platelet activating factor acetylhydrolase 1b regulatory subunit 1 (PAFAH1B1) was examined.
The physiological functions and in vivo relevance of most lncRNAs are still unknown, therefore a part of this work aimed to identify lncRNAs in response to a pathophysiological stimulus (high amplitude stretch) in endothelial cells.
The long intergenic noncoding RNA antisense to S1PR1 (LISPR1) gene, is located within the promotor of sphingosine-1-phosphate receptor 1 (S1PR1) and shares a part of the promotor region. This study examined additionally the hypothesis that LISPR1 controls the S1PR1 expression in endothelial cells.
Methods: The angiogenic functions of NONHSAT073641 and LISPR1 were examined with spheroid-outgrowth and scratch wound assays. Furthermore, stretch experiments were performed in order to identify differently expressed lncRNAs in human umbilical vein endothelial cells (HUVECs). In addition, the in vivo relevance of both lncRNAs was examined in samples from pulmonary arterial hypertension patients. Knockdown (e.g. LNA GapmeRs), knockout (CRISPR/ Cas9) and overexpression experiments (e.g. CRISPR activation) were performed to analyse target genes. The molecular mechanism of LISPR1 was investigated with RNA and Chromatin immunoprecipitation.
Results: NONHSAT073641 and PAFAH1B1 exhibited angiogenic function in endothelial cells. It could be observed that NONHSAT073641 is not regulating the expression of PAFAH1B1. The pro-angiogenic feature of PAFAH1B1 might be attributed to the target gene matrix Gla protein (MGP). NONHSAT073641 and PAFAH1B1 were significantly induced in CTEPH samples and might be important in the development of this disease. It could be speculated that NONHSAT073641 is regulating the expression of the cell-cycle regulator BCL2L11 as has been investigated in mice.
LISPR1 is a cis-acting lncRNA which maintains S1PR1 gene transcription by intercepting the transcriptional repressor ZNF354C and enabling Polymerase II (PolII) to bind. ZNF354C regulates S1PR1 expression in HUVECs. However, the role of ZNF354C in pulmonary arterial hypertension (PAH) is unknown. LISPR1 and S1P1 receptor were both significantly depleted in COPD samples. It can be assumed that due to higher S1P production, the signalling is attenuated through reduction of the lncRNA LIPSR1 and thus the receptor S1P1.
The stretch experiments present a possible in vitro model in order to mimic the condition of endothelial cells during high blood pressure, such as in PAH. Referring to published data, it could be confirmed that stretching of endothelial cells alters the gene expression, which is on the other hand linked to cardiovascular disease. In cardiovascular disease mechanical stretch altered genes, which are participating in the vascular remodelling process. The role of differently expressed lncRNAs (TGFβ2-AS1, CTD-2033D15.2, INHBA-AS1, RP11-393I2.4, TAPT1-AS1, TPM1-AS1, CFLAR-AS1 and HIF1α-AS2) upon mechanical stretch is yet not clarified.
Conclusion: NONHSAT073641 and LISPR1 are important for the endothelial angiogenic function. Both lncRNAs were deregulated in PAH samples. The pathophysiological stimulus had an impact on the expression of different lncRNAs (e.g. TGFβ2-AS1) and pathways (e.g. TGF-β) in endothelial cells.
A necessary requirement for a pharmacological effect is that a drug molecule tightly interacts with its disease relevant target molecule in the patient. Kinases are regulatory, signal transmitting enzymes and are a large protein family that belongs to the most frequent targets of pharmaceutical industry, as deregulation of kinases has been associated with the development of a variety of diseases, including cancer. In drug discovery, equilibrium binding metrics such as the affinity (Ki, KD) or potency (IC50, EC50) are usually applied for the systematic profiling for potent and selective drug candidates. In recent years, dynamic binding parameters, the drugs association (kon) and dissociation (koff) rates for desired primary-targets and undesired off-targets, were discussed to be better predictors than steady-state affinity per se (KD = koff / kon) for the onset and duration of the drug-target complex in the open in vivo environment and thereby for the therapeutic effect and safety of the drug. It is yet unclear whether and when the binding kinetics parameters can influence drug action in the complex context of pharmacokinetics and pharmacodynamics and how the kinetic rate constants can be optimized rationally. One major obstacle for providing proof for the hypothesis that drug binding kinetics is of importance for drug action is the generation of large and comparable binding kinetic datasets.
The aim of this thesis was the comprehensive analysis of the binding kinetic and affinity parameters of a diverse spectrum of 270 small-molecule kinase inhibitors against a panel of pharmacologically relevant kinases to study the role played by binding kinetics for drug discovery: The generated dataset was utilized to assess the effect of chemical properties on drug binding kinetics, and to evaluate the impact of kinetic rate constants on the success of compounds in the drug discovery pipeline.
Large scale profiling was made possible by a recently developed “kinetic Probe Competition Assay” (kPCA), whose evaluation is based on Motulsky’s and Mahan’s “kinetics of competitive binding” theory. Monte Carlo analyses performed in this dissertation widened the theoretical knowledge of this theory, provided new insights into its limitations and allowed to derive recommendations about how to best design assays. It was demonstrated that kPCA is indeed high-throughput compatible and that it is comparable to other biochemical and biophysical assay formats in terms of precision and accuracy.
Multivariable linear regression for the description of the determined kinase inhibitors’ target binding characteristics (kon or koff or KD) using molecular properties and/or particular kinase-inhibitor interactions as descriptors supported the assumption that molecular properties of compounds might affect binding kinetics, generated new hypothesis about molecular determinants influencing binding kinetic parameters and provided a rational basis for following structure-kinetic relationship studies. Remarkably, the binding kinetic rate constants were better described by the established models than binding affinities.
Interestingly, the systematic, quantitative analysis of kinase inhibitors’ target binding kinetics indicated that a slow dissociation rate for the main target is a feature which is more frequently observed in inhibitors that reached approval or late stage clinical testing than in earlier phases of clinical development. In addition, it was demonstrated that binding kinetics of kinase inhibitors is a better predictor for the time course of target engagement in cells as compared to affinity per se. Furthermore, in some study cases simulations using a standard pharmacokinetics model and a modified model considering the inhibitors binding kinetics lead to different in vivo kinase occupancy time profiles. It was illustrated by simulations how the concept of kinetic selectivity can be applied to turn an unselective compound in equilibrium conditions into a more selective compound in the open in vivo situation, where the thermodynamic equilibrium of drug-target binding is not necessarily reached.
Thus the generated data and models provide evidence for the importance of binding kinetics in drug discovery and represent a valuable resource for future studies in this field.
Protein quality control (PQC) machinery is in charge of ensuring protein homeostasis in the cell, i.e. proteostasis. Chaperones assist polypeptides throughout their maturation until functionality is achieved. This process might be disrupted in the presence of mutations or external damaging agents that affect the folding and stability of proteins. In this case, proteins can be efficiently recognized and targeted for degradation in a controlled manner. Ubiquitylation refers to the covalent attachment of one or more ubiquitin moieties to faulty proteins, thus triggering their degradation by the 26S proteasome.
More than 30% of proteins need cofactor molecules. Lack of cofactors renders proteins non-functional. We wanted to understand how the PQC deals with wild-type proteins in the absence of their cofactors. Several studies have indicated the importance of the riboflavin-derived cofactor FAD in the stability of individual flavoproteins, and hence we assumed that loss of flavin should mediate a targeted degradation of this group of proteins. Indeed, our mass spectrometry experiments showed that flavoproteome levels decreased under riboflavin starvation. The oxidoreductase NQO1 was used as a model enzyme to further investigate the mechanism of flavoproteome targeting by the PQC. We showed that cofactor loading determines ubiquitylation of NQO1 by the co-chaperone CHIP, both in vivo and in vitro. Furthermore, subtle changes in the C-terminus of NQO1 in the absence of FAD seemed to be crucial for this recognition event. ApoNQO1 interactome differed from holoNQO1. Chaperones and degradation factors were enriched on NQO1 upon cofactor withdrawal, probably to support maturation and prevent aggregation of the enzyme.
Loss of protein folding and stability, even to a small extent, can enhance the aggregating behavior of proteins. Proper loading with FAD reduced the co-aggregation of NQO1 with Aβ1-42 peptide. We assumed that the flavoproteome might represent aggregating-prone species under riboflavin deprivation. Supportingly, reversible apoNQO1 aggregates were observed in vivo in the absence of cofactor. General amyloidogenesis in vivo also increased under these conditions, apparently as a result of flavoproteome destabilization. In this context, we think that our data might have important implications considering the onset and development of conformational diseases.
This work has shed some light on the therapeutic implications of riboflavin deficiency as well. The sensitivity of melanoma cells towards the alkylating agent methyl methanesulfonate (MMS) increased under riboflavin starvation. Subsequent analyses indicated that a complex metabolic reorganization, mostly affecting proliferation and energy metabolism, occurs in response to starvation. What we suggest to call “flavoaddiction” can be understood as the dependence of melanoma cells on the flavoproteome structural and functional intactness to survive chemotherapy. Understanding this cellular reprogramming in detail might reveal new possibilities for future therapies.
Epigenetic mechanisms largely influence how genetic information on DNA level is translated into different phenotypes. DNA methylations and histone post-translational modifications make up what is referred to as "epigenetic landscape", an interconnected pattern that regulates access to genes and serves as platform for specific binding partners. The epigenetic landscape is maintained by "writers", which add the modifications, "erasers", which delete the modifications and "readers" which specifically bind modifications and mediate their location to other proteins connected to transcription. In the context of acetylations, which are the focus of this thesis, the writers are called histone acetyl transferases (HATs), the erasers are called histone deacetylases (HDACs) and the readers comprise Bromodomains (BRDs) as well as Yaf9, ENL, AF9, Taf14, Sas5 (YEATS) domains. An aberrant epigenetic landscape and mutated forms of epigenetic readers can lead to diseases including cancer and inflammatory diseases, making epigenetic reader domains attractive drug targets.
The focus of this thesis were YEATS domains and the development of inhibitors for this new class of epigenetic readers. Eleven-nineteen-leukemia protein (ENL) and ALL1-fused gene from chromosome 9 protein (AF9) are also part of the super elongation complex and are common fusion partners of mixed lineage leukemia protein (MLL) in acute myeloid leukemia (AML) (Wan et al., 2017, Erb et al., 2017). In this thesis, the first ligand-free crystal structure of ENL YEATS revealed an inherent flexibility of the Y78 side chain in the aromatic triad and two conserved water molecules. Soaking experiments led to the first co-crystal structures between a YEATS domain and small molecule inhibitors and defined prerequisites for ENL YEATS inhibitor scaffolds. The discovered inhibitory fragments had a central amide bond in common, which replaced one of the two conserved water molecules to form beta-sheet-like hydrogen bonds between the loop 6 backbone and the S58 side chain. The amide bond was flanked by two aromatic moieties, of which one stacks with H56 in the front pocket and the other interacts with the aromatic triad in the rear pocket. The development of the first chemical probe for ENL/AF9, SGC-iMLLT, show that the affinity is increased to low nanomolar levels if the rear flanking aromatic moiety forms additional hydrogen bonds with loop 6 and the side chain of E75 (Moustakim et al., 2018). In case of the probe, this is achieved with a 2-methyl-pyrrolidine-benzimidazole moiety. The probe binds with high affinity to ENL (129 nM) and AF9 (77 nM) and shows no significant affinity towards other human YEATS domains or BRDs. Target engagement was shown by fluorescence recovery after photobleaching (FRAP), cellular thermal shift assay (CETSA) and in case of AF9 also with NanoBRET. The probe changed the expression of three AML-related genes (MYC, dendrin and CD86) in MV4;11 cells, encouraging application of this probe in more AML cell lines.
This doctoral thesis deals with the structural and dynamical NMR characterization of biomolecules, covering a broad range of proteins, from small peptides to large GPCRs proteins. This work consists of two projects, which are presented in chapter II and III. Chapter II is focused on the structural screening of peptides and small proteins ranging from 14 to 71 amino acids, while chapter III describes the structure and light dynamics of the disease relevant rhodopsin G90D mutant. The main method used to investigate both types of proteins is NMR spectroscopy. Both chapters comprise individual general introduction, materials and methods, results and discussion sections, and a final conclusion paragraph.
‘Chapter I: Methodological aspects of protein NMR spectroscopy’ presents an overview of different NMR methods developed for the rapid characterization of protein structure and dynamics. Multidimensional NMR, which is routinely used in structural biology, is indispensable for protein structure determination in solution. However, detailed information with resolution at the atomic level is time consuming and requires weeks of expensive measurement time, followed by the manual data analysis. Therefore, the development of time-saving NMR techniques is highly required for screening studies of a large amount of proteins, and can be also helpful for studying unstable biomolecules, as their short lifetime often restricts the experimental procedure.
This chapter covers the two main approaches to accelerate a multidimensional NMR experiment: fast-pulsing techniques that aim to reduce the duration of an individual measurement, and non-uniform sampling technique (NUS), which was developed to reduce the overall number of increments in virtual time domains. A combination of both approaches, fast-pulsing and non-uniform sampling, allows speeding up the measurement time by 2-3 orders of magnitude. Furthermore, recently developed software called TA (targeted acquisition) combines various time-saving approaches, including fast-pulsing, non-uniform sampling and targeted acquisition. Targeted acquisition algorithm records a set of multidimensional NMR spectra in semi-interleaved incremental mode. This provides the ability to monitor the quality of the recorded spectra in real-time and therefore enables the completion of the experiments after the desired quality is achieved. Using this approach will greatly reduce the measurement time without losing important structural information. The implemented automated FLYA assignment further contributes to the rapid and simplified readout of the chemical shift assignment progress of the TA program. During this doctoral dissertation, the scientific collaboration with the TA software developer Prof. Vladislav Orekhov (Sweden) took place, and resulted in the successful establishing of this new NMR technology in the Schwalbe laboratory. TA is now routinely applied in Prof. Schwalbe group for the structure elucidation of small proteins.
‘Chapter II: Rapid NMR and biophysical characterization of small proteins’ describes the structural analysis of peptides and small proteins, which were recently identified within the framework of the Priority Program (SPP 2002). Due to technical limitations in detections of small systems and strict assumptions concerning the smallest size of the gene that can be translated, small open reading frames (sORFs) were excluded from the automated gene annotation for a very long time. Thanks to the newly developed computational and experimental approaches, the ability to identify and detect the small proteins consisting of less than approximately 70 amino acids sparked a growing scientific interest by microbiologist. In the past years, hundreds of new short protein sequences were discovered. Although some peptides were found to be involved in diverse essential biological processes, the functional elucidation of a large number of recently discovered peptides and small proteins remains a challenging task. It is well established that the structure of proteins is often linked to their function. However, the size of small constructs often restricts the possible diversity of secondary structure elements that might be adopted by a protein. Furthermore, as was shown for intrinsic discorded proteins (IDPs), the absence of a well-defined three-dimensional structure does not necessarily mean lack of function. Moreover, peptides, which are initially unstructured in the isolated form can fold in a stable structured conformation upon interaction with their biological partners. Solution state NMR spectroscopy is perfectly amenable for the structural characterization of systems of this size. It provides a rapid readout about the conformational state of small peptides unambiguously, distinguishing between folded, molten globule and unstructured conformations.
During this doctoral thesis the workflow protocol for fast screening of peptides and small proteins was established and applied to 20 candidates ranging from 14 to 71 amino acids, which were identified and selected by six microbiological groups, all members of the Priority Program on small proteins (SPP2002) funded by the German research foundation (DFG). The screening protocol includes sample preparation and biochemical characterization. Peptides containing less than 30 amino acids were synthesized by solid phase synthesis (SPPS), while small proteins containing more than 30 amino acids were heterologously expressed in E. coli.
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Die Kenntnis der Struktur von Biomolekülen und der biologischen Abläufe, in welche diese involviert sind, ist grundlegend für die Entwicklung von medizinischen Behandlungen. Im Rahmen dieser Arbeit wurden Systeme zur Untersuchung von Biomolekülen, insbesondere Proteinen, hergestellt. Im Mittelpunkt stand die Entwicklung von Materialien, welche neue Möglichkeiten zur Präparation von Proteinen zur Untersuchung derer Struktur mittels Kryo-Transmissionselektronenmikroskopie (Kryo-TEM) eröffnen. In zwei weiteren Projekten wurden biomimetische Systeme aufgebaut, welche die Oberfläche eines Biomoleküls oder biologischen Ensembles nachahmen und hierdurch deren Untersuchung ermöglichen. Hier wurden Systeme zur einfachen Nachbildung biologischer Membranen oder Proteinoberflächen betrachtet.
Eine wichtige Methode zur Untersuchung der dreidimensionalen Struktur von Biomolekülen ist die Kryo-TEM. Zur Mikroskopie werden die Biomoleküle in wenige Mikrometer großen Löchern eines amorphen Kohlenstofflochfilms mittels einer wenige Nanometer dicken Schicht aus amorphem Eis fixiert. Hierfür wird ein dünner Film einer wässrigen Probe auf den Kohlenstofflochfilm aufgebracht und gefroren. Insbesondere für Membranproteine ist die Herstellung derartiger Proben schwierig, da die Proteinpartikel zur Aggregation und Adsorption an dem Kohlenstofflochfilm neigen, wodurch keine Partikel in den Löchern des Kohlenstofffilmes auftreten, welche mikroskopiert werden können.
In dieser Arbeit wurden Materialien zur Verbesserung der Präparation von Proteinen für die Kryo-TEM entwickelt. Es wurden hierfür verschiedene biorepulsive Materialien, auch solche, welche eine spezifische Anbindung der Biomoleküle erlauben, untersucht. Da in der TEM die Probe durchstrahlt wird, eignen sich Nanometer dünne Membranen dieser Materialien als Trägermaterial für die Biomoleküle, da sie nur zu einem geringen Hintergrund führen. Zum einen wurden Nanomembranen durch die chemische Quervernetzung von Nanometer dicken Hydrogelfilmen mit verschiedenen quervernetzenden Molekülen hergestellt. Zum anderen wurden Trägerfilme, wie amorphe Kohlenstofffilme oder Kohlenstoffnanomembranen (engl. carbon nanomembranes, CNM) biorepulsiv funktionalisiert. Darüber hinaus wurde eine Nitrilotriessigsäure(NTA)-funktionalisierte Hydrogel-beschichtete Nanomembran entwickelt, welche markierte Proteine selektiv über einen His-Tag bindet.
Neben der Entwicklung von Materialien zur Untersuchung von Proteinen mittels Kryo-TEM wurden Beschichtungen hergestellt, welche die Oberfläche eines Biomoleküls oder eines Ensembles von Biomolekülen nachahmen. Diese Modelloberflächen sollten ebenfalls die Untersuchung von Eigenschaften der biologischen Systeme ermöglichen. Biologische Membranen bestehen aus einem Ensemble von Biomolekülen. Eine Vielzahl verschiedener Biomolekülen tritt in einer komplexen Anordnung in diesen dünnen Membranen auf. Es wurde versucht, strukturierte Membranen mit lokalen Variationen der physikalischen und chemischen Eigenschaften, jedoch weitaus weniger komplexen Aufbau, herzustellen. Die hergestellten Membranen mit biologisch relevanten Strukturen im Mikrometer- bis Zentimeterbereich, können nach weiterer Forschung als einfache Modellsysteme zur Nachahmung ihrer komplexen biologischen Vorbilder dienen.
In einem weiteren Projekt wurde eine Modelloberfläche für die Bindungstasche des Proteins FimH, welches eine wichtige Rolle in der bakteriellen Adhäsion spielt, entwickelt. In dem Kooperationsprojekt mit der Arbeitsgruppe Lindhorst wurde ein Modellsystem entwickelt, welches dazu dient, herauszufinden, inwiefern eine Funktionalisierung einer Aminosäurevon FimH über eine vorgeschlagenen Ligationsstrategie möglich ist. Das Modellsystem besteht aus einer biorepulsiven Hydrogel-Matrix, aus welcher die Seitenkette der Aminosäure Tyrosin in die Lösung exponiert ist. Die Substrat-katalysierte Reaktion der Aminosäuren-Seitenkette mit dem Photoschalter wurde mithilfe eines Bakterienadhäsionstests untersucht. Es konnte gezeigt werden, dass sich die vorgeschlagene Ligationsstrategie unter Berücksichtigung von Nebenreaktionen zur Modifizierung des Proteins eignet.
Es konnten vier neuartige Systeme, welche die Probenpräparation zur Untersuchung von Proteinen mittels Kryo-TEM vereinfachen, entwickelt werden. Die Ergebnisse sind von wissenschaftlicher Relevanz, da sie die Strukturbestimmung vieler Proteine deutlich vereinfachen und hierdurch beschleunigen können. Außerdem wurden biomimetische Beschichtungen entwickelt, welche entweder Proteinoberflächen oder Biomembranen nachahmen. Die entwickelten Modellsysteme erweitern das Spektrum an Möglichkeiten, Biomoleküle oder biologische Ensembles zu untersuchen.
Protein biosynthesis is a conserved process, essential for life. Proteins are assembled from single amino acids according to their genetic blueprint in the form of a messenger ribonucleic acid (mRNA). Peptide bond formation is catalyzed by ancient ribonucleic acid (RNA) residues within the supramolecular ribosomal complex, which is organized in two dynamic subunits (Ramakrishnan, 2014). Each subunit comprises large ribosomal RNA (rRNA) molecules and several dozens of peripheral proteins. mRNA translation has been divided into three phases, namely translation initiation, elongation and termination in biochemistry textbooks. During initiation, the ribosomal subunits assemble into a functional ribosome on an activated mRNA and acquire the first transfer RNA (tRNA), an adapter between the start codon on the mRNA and the N-terminal methionine of the protein (Hinnebusch and Lorsch, 2012). During elongation, the ribosome translocates along the mRNA exposing one codon after the other, and amino acids are delivered to the ribosome by the respective tRNAs, and attached to the nascent polypeptide chain. During termination, the polypeptide is released and the ribosome remains loaded with mRNA and tRNA at the end of the open reading frame for the translated gene (Hellen, 2018). Bacterial ribosomes are subsequently recycled by a specific ribosome recycling factor and the small ribosomal subunit is simultaneously consigned to initiation factors for a next round of translation – rendering bacterial translation as a cyclic process with an additional ribosome recycling phase. However, the process of ribosome recycling remained enigmatic in Eukarya and Archaea until the simultaneous discovery of the twin-ATPase ABCE1 as the major ribosome recycling factor. Strikingly, ABCE1 has initially been shown to participate in translation initiation (Nürenberg and Tampé, 2013). Thus, closing the translation cycle by revealing the detailed molecular mechanism of ABCE1 and its role for translation initiation are the two goals of this research.
Beyond the plenitude of well-studied translational GTPases, ABCE1 is the only essential factor energized by ATP, delivering the energy for ribosome splitting via two nucleotide-binding sites. Here, I define how allosterically coupled ATP binding and hydrolysis events in ABCE1 empower ribosome recycling. ATP occlusion in the low-turnover control site II promotes formation of the pre-splitting complex and facilitates ATP engagement in the high-turnover site I, which in turn drives the structural re- organization required for ribosome splitting. ATP hydrolysis and ensuing release of ABCE1 from the small subunit terminate the post-splitting complex. Thus, ABCE1 runs through an allosterically coupled cycle of closure and opening at both sites consistent with a processive clamp model. This study delineates the inner mechanics of ABCE1 and reveals why various ABCE1 mutants lead to defects in cell homeostasis, growth, and differentiation (Nürenberg-Goloub et al., 2018).
Additionally, a high-resolution cryo-electron microscopy (EM) structure of the archaeal post-splitting complex was obtained, revealing a central macromolecular assembly at the crossover of ribosome recycling and translation initiation. Conserved interactions between ABCE1 and the small ribosomal subunit resemble the eukaryotic complex (Heuer et al., 2017). The conformational state of ABCE1 at the post-splitting complex confirms the molecular mechanism of ribosome recycling uncovered in this study. Moving further along the reaction coordinate of cellular translation, I reconstitute the complete archaeal translation initiation pathway and show that essential archaeal initiation factors are recruited to the post-splitting complex by biochemical methods and cryo-EM structures at intermediate resolution. Thus, the archaeal translation cycle is closed, following its bacterial model and paving the way for a deeper understanding of protein biosynthesis.
An essential part of the animal survival strategy comprises the ability to control body movement and coordinate long-term navigational strategies, in order to maintain locomotion towards a nutrition source and stay in its vicinity. In the nematode Caenorhabditis elegans (C. elegans) this function is carried out by neuronal circuits, that vary their activity in response to diverse environmental condition.
This comprises different classes of neurons, acting together in a sensory, signaling and modulatory system to control body posture and induce behavioral responses. For this reason, one particular goal in the field of neuroscience research is to elucidate the mechanisms of how neuronal circuits integrate multiple sensory cues to navigate the environment. Aim of this study was to analyze the function of a neuronal network comprising the interneurons AVK, as well as the identification of signaling molecules, controlling body posture during food related locomotory behavior. This should be achieved by establishing optogenetic approaches, which provide a non inversive and temporally precise control of neuronal activity and drives the activation or silencing of individual neurons, to alter the neuronal basis of behavior. Animals exposed to food perform a dwelling-like behavior, characterized by a slowing of locomotion with a reduced crawling distance and an irregular movement, accompanied by a high frequency of pauses, reversals and directional changes. Upon food-removal, they initiate a local-search behavior with the same behavioral characteristics, but with a more pronounced sinusoidal movement. After a prolonged period of unsuccessful food finding, animals exhibited long runs with reduced pauses, reversals and turnings, increasing their maximal covered distance, indicated as dispersal behavior. Acute photoinhibition of AVK neurons, mediated by cell-specific expression of halorhodopsin (NpHR) caused the animals to perform a dwelling-like locomotory state with increased bending angles, as seen during local-search behavior. Thus, food-induced behavioral effects are mimicked by the optogenetic manipulation of AVK interneurons.
In this study, signaling molecules were ascertained by cell specific mRNA profiling of AVK neurons, mediating these behavioral responses. It was able to demonstrate, that flp-1, coding for a FMRFamidelike neuropeptide, is one of the genes with the highest distribution in AVK. In the absence of food, AVK neurons continuously release the FMRFamide-like neuropeptide FLP-1 to inhibit a subset of target motoneurons, leading the animals to maintain a low body curvature to promote dispersing behavior.
Conversely, if AVK was inhibited by NpHR or the presence of food, less FLP-1 was secreted to the body fluid, indicated by reduced intracellular fluorescence levels of mCherry-tagged FLP-1 proteins in the scavenger cells. The search of a FLP-1 receptor was successful by in vitro investigation on G protein-coupled receptors (GPCRs) and neuropeptide ligands, revealing NPR-6 to be activated by FLP-1 neuropeptides, but with a low potency. Expression pattern of the NPR-6 receptor indicated receptor localization in in the VC ventral cord and SMB head motoneurons, as well as in a subset of other neurons required for chemosensation and feeding. AVK interneurons are highly coupled to SMB head motoneurons, forming electrical synapses composed of the gap junction protein subunits UNC-7 and UNC-9. Elimination of SMB or gap junction genes using cell ablation and RNA interference, respectively, phenocopied effects of AVK inhibition on bending angles. Furthermore, this study was able to demonstrate that these neurons get inhibited during FLP-1 transmission to the NPR-6 receptor, which was required to mediate AVK effects on crawling behavior. Consequently, photoinhibition of AVK caused disinhibition of VC and SMB neurons, in order to enhance sinusoidal movement and to induce a local-search related locomotory behavior.
Thereby, FLP-1 neuropeptide transmission is the preferred used signaling pathway over direct gap junction coupling. Additional neuropeptides and receptors were identified to be essential downstream to AVK neurons to mediate effects on body curvature and locomotory behavior as well. The high-potency FRPR-7 receptor was shown to mediate FLP-1 peptide effects on undulatory motion during swimming in a liquid environment, rather than crawling locomotion on a solid surface. This result suggests that the receptor NPR-6 is required for FLP-1 peptide effects on bending and crawling locomotion, whereas conversely the receptor FRPR-7 is addressed by FLP-1 peptides to exclusively regulate swimming behavior. The FRPR-7 receptor is expressed in the AIM and NSM motoneurons, which are suggested to be the primary neuronal candidates mediating swimming behavior. Furthermore, this study provides evidence, that FRPR-7 acts in the DVC interneuron to control spontaneous reversal behavior, most probably by inhibitory FLP-1 signaling from the AVK neurons. Among other neuropeptides, the FMRFamide-like peptide FLP-26 binds with higher affinity to NPR-6 receptors than FLP-1 peptides. FLP-26 peptides are expressed in the SMB motoneurons, where they are able to further potentiate FLP-1 inhibitory effects by simultaneous binding to NPR-6.
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Rhabdomyosarcoma (RMS) is the most frequent pediatric soft-tissue sarcoma comprising two major subtypes – the alveolar and the embryonal rhabdomyosarcoma. The current therapeutic regime is multimodal including surgery, radiation and chemotherapy with cytostatic drugs. Although the prognosis for RMS patients has steadily improved to a 5-year overall survival rate of 70% for ERMS and 50% for ARMS, prognosis for subgroups with primary metastases or relapsed patients is still less than 25%, highlighting the need for development of new therapies for these subgroups. Since cancer cells are addicted to their cancer promoting transcriptional program, remodeling transcription by targeting bromodomain and extraterminal (BET) proteins has emerged as compelling anticancer strategy. However, in many cancer types BET inhibition was proved cytostatic but not cytotoxic emphasizing the need for combination protocols.
In this study we identify a novel synergistic interaction of the BET inhibitor JQ1 with p110α-isoform-specific Phosphoinositid-3-Kinase (PI3K) inhibitor BYL719 (Alpelisib) to induce mitochondrial apoptosis and global reallocation of BRD4 to chromatin. At first, we showed that JQ1 single treatment had cytostatic effects at nanomolar concentrations and inhibited MYC and Hedgehog (Hh) signaling in RMS known to promote proliferation of RMS. However, JQ1 single treatment barely induced cell death in RMS cells even at concentrations of up to 20 µM (< 20% cell death). Thus, we next tested combination approaches to elicit cell death. Since we previously identified synergistic cell death induction of Hh inhibition and PI3K inhibition in RMS cells we tested JQ1 in combination with the pan-PI3K/mTOR inhibitor PI-103 and the p110α-isoform-specific PI3K inhibitor BYL719. In addition, we tested JQ1 in combination with distinct HDAC inhibitors namely JNJ-26481585, SAHA (Vorinostat), MS-275 (Entinostat) and LBH-589 (Panobinostat) since the synergistic interaction of BET and HDAC inhibition has previously been described for other tumor entities.
Interestingly the synergism of cell death induction of JQ1/BYL719 co-treatment is superior to the synergism of JQ1 with pan-PI3K/mTOR inhibitor PI-103 or the tested HDAC inhibitors as confirmed by calculation of combination index. To investigate the molecular mechanisms underlying the synergy of JQ1/BYL719 co-treatment, we performed RNA-Seq and BRD4 ChIP-Seq experiments. RNA-Seq exhibited, that JQ1/BYL719 co-treatment shifted the overall balance of BCL-2 family gene expression towards apoptosis and increased gene expression of proapoptotic BMF, BCL2L11 (BIM) and PMAIP1 (NOXA) while decreasing gene expression of antiapoptotic BCL2L1 (BCL xL). These changes were verified by qRT-PCR and Western blot. Notably, BRD4 is phosphorylated upon JQ1/BYL719 co-treatment and globally reallocates BRD4 to chromatin. This BRD4 reallocation includes enrichment of BRD4 at the super-enhancer site of BMF, at the super-enhancer, typical enhancer and promoter regions of BCL2L11 (BIM) and at the PMAIP1 (NOXA) promoter, while JQ1 alone, as expected, reduces global chromatin binding of BRD4. Integration of RNA-Seq and BRD4 ChIP-Seq data underlines the transcriptional relevance of reallocated BRD4 upon JQ1/BYL719 co-treatment. Immunopreciptation studies showed, that RMS cells are initially primed to undergo mitochondrial apoptosis since BIM is constitutively bound to antiapoptotic BCL-2, BCL xL and MCL-1. JQ1/BYL719 co-treatment increased BIM expression and its neutralization of antiapoptotic BCL-2, BCL-xL and MCL-1 thereby rebalancing the ratio of pro- and antiapoptotic BCL-2 proteins in favor of apoptosis. This promotes activation of BAK and BAX resulting in caspase-dependent apoptosis. The functional relevance of proapoptotic re-balancing for the execution of JQ1/BYL719-mediated apoptosis was confirmed by individual silencing of BMF, BIM, NOXA or overexpression of BCL-2 or MCL-1, which all significantly rescued JQ1/BYL719-induced cell death. Execution of cell death by mitochondrial caspase-dependent apoptosis was veryfied by individual knockdown of BAK and BAX or caspase inhibitor N-Benzyloxycarbonyl-Val-Ala-Asp(O-Me) fluoromethylketone (zVAD.fmk), which all significantly rescued JQ1/BYL719-induced cell death.
In summary, combined BET and PI3Kα inhibition cooperatively induces mitochondrial apoptosis by proapoptotic re-balancing of BCL-2 family proteins accompanied by reallocation of BRD4 to transcriptional regulatory elements of BH3-only proteins.
Die Plasmamembran eukaryotischer Zellen dient als Barriere zwischen dem Inneren einer Zelle und ihrer Umgebung. Eine wichtige Aufgabe von Proteinen, die sich in der Plasmamembran befinden, besteht in der Erkennung der Umgebung, der Übermittlung dieser Informationen über die Plasmamembran in das Innere einer Zelle und der Einleitung einer zellulären Antwort. Membranrezeptoren binden Liganden, was zu ihrer Aktivierung und der Rekrutierung von intrazellulären Proteinen führt. Funktionelle Signalkomplexe werden gebildet und leiten einen Informationstransfer durch die Zellmembran ein, so dass die Expression bestimmter Gene stimuliert oder unterdrückt wird. Eine Störung der Signalinitiierung und -übertragung tritt bei vielen Krankheiten auf, so dass Membranproteine ein wichtiges Ziel in der Medikamentenentwicklung sind.
In dieser Arbeit wird die Fragestellung bearbeitet, wie der Tumornekrosefaktor-Rezeptor 1 (TNFR1) in funktionelle Komplexe in der Plasmamembran einer intakten Zelle organisiert ist. TNFR1 besitzt vier cysteinreiche Domänen (CRDs) in seiner extrazellulären Region. Die erste und von der Plasmamembran am weitesten entfernte CRD ist die Pre-Ligand Assembly Domain (PLAD). Kristallstrukturen zeigten, dass sich in einem TNFR1-Dimer zwei PLAD in unmittelbarer Nähe befinden. Crosslinking-Experimente berichteten über mehrere oligomere Zustände von TNFR1; die Ergebnisse unterschieden sich nach Art und Konzentration des Crosslinkers. In der nativen Umgebung einer intakten Zelle wurde der oligomere Zustand von TNFR1 bisher nicht bestimmt. Der kanonische Ligand für TNFR1 ist der Tumornekrosefaktor alpha (TNF), ein Homotrimer, welches in löslicher oder membrangebundener Form vorliegt. Nach der Bindung von TNF an TNFR1 bilden sich Rezeptortrimere. Diese Proteinkomplexe rekrutieren intrazellulär Proteine und bilden einen funktionellen Membrankomplex, der intrazelluläre Signalkaskaden aktiviert. Die kanonische Signalweiterleitung erfolgt durch den nuclear factor kappa-light-chain-enhancer of activated B-cells (NF-B), welcher Zellteilung oder Entzündung induziert. TNFR1 kann auch andere Signalwege wie beispielsweise Apoptose durch einen zytosolischen Komplex und die Procaspase-8, oder Nekroptose durch das Nekrosom und die mixed lineage kinase domain-like (MLKL)-Domäne einleiten. Die Dysregulation von TNFR1 ist bei einer Vielzahl von Krankheiten zu finden. Erhöhte TNFR1-Expressiosraten treten bei acquired immune deficiency syndrome (AIDS), multipler Sklerose und verschiedenen Krebsarten auf.
In einem zweiten Projekt wurde in Zusammenarbeit mit Prof. Dr. Michael Lanzer (Heidelberg, Germany) der Expressionsgrad des Proteins VAR2CSA in membranassoziierten knobs bestimmt, welche in Erythrozyten vorkommen, die mit dem Parasiten Plasmodium falciparum infizierten wurden. VAR2CSA gehört zur Proteinfamilie des Plasmodium falciparum erythrocyte membrane protein 1 (pfEMP1). Nach einer Infektion wird VAR2CSA zur Wirtszellmembran transportiert und in knobs eingelagert. Patienten, die Sichelzellenanämie-Erythrozyten (HbAS) aufweisen, sind im Gegensatz zu Patienten mit gesunden Erythrozyten (HbAA) immun gegen Malaria. Während die beiden Erythrozytentypen eine unterschiedliche Morphologie der knobs aufweisen, blieb ihre Zusammensetzung in Bezug auf VAR2CSA bisher ungeklärt.
Das Verständnis der Proteinfunktion erfordert eine Beschreibung der molekularen Organisation funktioneller Einheiten in der zellulären Umgebung. Hierfür ist die Fluoreszenzmikroskopie eine geeignete Methode, da sie eine gezielte Markierung von Zielproteinen ermöglicht. Die hohe Sensitivität ermöglicht die Visualisierung einzelner Proteine. Eine Einschränkung in der konventionellen Fluoreszenzmikroskopie ist die Auflösungsgrenze. Strukturelle Elemente, die kleiner als etwa die halbe Anregungswellenlänge sind (für die meisten Anwendungen 200 bis 300 nm) können nicht aufgelöst werden. Die Entwicklung der hochauflösenden Fluoreszenzmikroskopie ermöglichte es, diese Auflösungsgrenze zu umgehen und eine räumliche Auflösung von wenigen Nanometern zu erreichen, was die Visualisierung und Charakterisierung einzelner Proteinkomplexe ermöglichte. Eine Art der hochauflösenden Fluoreszenzmikroskopie ist die single-molecule localization microscopy (SMLM), die auf der Detektion einzelner Fluorophore, einer genauen Bestimmung ihrer Position (Lokalisation) und der Erzeugung eines rekonstruierten Bildes unterhalb der optischen Auflösungsgrenze basiert. Da die meisten Proben in der Fluoreszenzmikroskopie eine zu hohe räumliche Dichte an Fluorophoren aufweisen, um den Nachweis von einzelnen Fluorophoren zu ermöglichen, werden Verfahren zur Kontrolle der Emission von Fluorophoren eingesetzt. Eine Möglichkeit ist der Einsatz von Fluorophoren, die optisch zwischen einem nicht-fluoreszierenden und einem fluoreszierenden Zustand geschaltet werden können, z.B. photoschaltbare fluoreszierende Proteine in photoactivated localization microscopy (PALM) oder organische Farbstoffe in (direct) stochastic optical reconstruction microscopy ((d)STORM). SMLM erreicht eine räumliche Auflösung von 20 nm, was in den meisten Fällen ausreicht, um einzelne Proteinkomplexe in einer Zelle aufzulösen. Diese räumliche Auflösung ist jedoch nicht ausreichend, um Untereinheiten innerhalb eines Proteinkomplexes zu visualisieren. Zu diesem Zweck wurde SMLM erweitert und die verfügbare kinetische Information genutzt, die bei der Detektion einzelner Fluorophore ausgelesen wird. Viele Fluorophore weisen metastabile Dunkelzustände auf, die eine Lebensdauer von bis zu Sekunden aufweisen. Diese Übergänge erscheinen als "Blinken" der Fluoreszenzemission. In Kombination mit kinetischen Modellen kann aus der Anzahl an Blink-Ereignissen die Anzahl der Fluorophore ermittelt werden. Angewendet auf hochaufgelöste Proteinkomplexe kann die Auflösungsgrenze von hochauflösender Mikroskopie umgangen werden, und die Anzahl der Protein-Untereinheiten in einem hochaufgelösten Proteincluster ermittelt werden. Hierzu wird beispielsweise das photoschaltbare fluoreszierende Protein mEos2 an ein Zielprotein funsioniert (quantitative PALM (qPALM)).
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Electron microscopy (EM) demarcates itself from other structural biology techniques by its applicability to a large range of biological objects that spans from whole cells to individual macromolecules. In single-particle cryo-EM, frozen-hydrated samples, prepared by vitrification with liquid ethane, retain macromolecules in a medium that approximates their natural aqueous environment and that, in this way, preserves high-resolution structural information. Nonetheless, the sensitivity of biological specimens to the high-energy electron beam introduces restrictions on the total dose that can be used during imaging while avoiding significant radiation damage. Consequently, the signal-to-noise ratio attained in each individual image is very low, and structures with high-resolution detail must be recovered by averaging thousands of projections in random orientations. This is achieved through the use of image processing algorithms capable of aligning and classifying particle images through the evaluation of cross-correlation functions between each particle and a reference.
In recent years, several innovations took place in the field of single-particle cryo-EM, among which the development of direct electron detectors must be highlighted. Direct electron detectors have a better detective quantum efficiency (DQE) than both photographic film and CCD cameras, and offer a fast readout, compatible with the acquisition of movie stacks. Additionally, new image processing software has become available, with more sophisticated algorithms and designed to take advantage of the specific characteristics of the movies produced with direct electron detectors. These technological advances in both hardware and software catalyzed a revolution in single-particle cryo-EM, which is now routinely used for the determination of near-atomic structures. As a result, the range of macromolecules accessible to cryo-EM has increased drastically, as targets that were unsuitable before for imaging due to their small dimensions can now be adequately visualized and refined to high-resolution.
During my doctoral work, I have used single-particle cryo-EM to structurally characterize challenging membrane proteins, with a strong emphasis on protein complexes from aerobic respiratory chains. In chapter I of this thesis, I present my results on the bovine respirasome, a mitochondrial supercomplex composed of complexes I, III and IV. Chapter II is dedicated to the analysis of the structure of alternative complex III (ACIII) from Rhodothermus marinus, a bacterial quinol:cytochrome c/HiPIP oxidoreductase unrelated to the canonical cytochrome bc1 complex (complex III). In addition, in chapter III I describe the structure of KimA, a high-affinity potassium transporter that drives the transport of its substrate by using the energy stored in the form of a proton gradient. These three membrane proteins, with molecular weights ranging from 140 kDa to 1.7 MDa, illustrate the possibilities and limitations faced in single-particle cryo-EM.
The aerobic respiratory chain is responsible for the generation of a transmembrane difference of electrochemical potential that is then used by ATP synthase for the production of ATP or for driving solute transport over the membrane. They catalyze the transfer of electrons from a substrate, such as NADH or succinate, to molecular oxygen and use the chemical energy released in these redox reactions to drive the translocation of protons, or in some cases sodium ions, to the intermembrane space in mitochondria or the periplasm in bacteria.
In mitochondria, the respiratory chain is composed of four complexes: complex I (NADH:ubiquinone oxidoreductase), complex II (succinate dehydrogenase), complex III (cytochrome bc1 complex) and complex IV (cytochrome c oxidase). While it was for a long time believed that these complexes existed as single entities in the membrane, the use of milder procedures for protein purification and analysis revealed that respiratory complexes associate into well-ordered structures, known as supercomplexes. These have been proposed to offer different structural and functional advantages that are still controversial, including substrate channeling, stabilization of individual complexes and reduction of reactive oxygen species (ROS) production. The most thoroughly studied respiratory supercomplex has been the respirasome, conserved in higher eukaryotes and composed of one copy of complex I, a complex III dimer and one complex IV. By single-particle cryo-EM analysis, I retrieved a 9 Å map of the respirasome from Bos taurus, which allowed the accurate docking of atomic models of the three component complexes. The structure shows that complex III associates to the concave side of the membrane arm of complex I, while complex IV is located between the end of the complex I hydrophobic arm and complex III. Several defined protein-protein contacts are observed between the component complexes, which are mediated predominantly by supernumerary subunits and close to the membrane surfaces. The interactions established between complex I and complex III are extensive and may support the argument that the association of complex I into supercomplexes is required for the stabilization or even the biogenesis of this complex.
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Polyketide synthases (PKSs) are large megaenzymes that occur in bacteria, fungi, and plants and produce polyketides, a class of secondary metabolites. Many polyketide natural products exhibit high biological activities e.g. as antibiotics or anti-fungal compounds. The modular architecture of assembly line PKSs makes them exciting targets for engineering approaches via the exchange of whole modules or single domains. Although many engineering attempts have been pursued over the last three decades, the resulting chimeric PKSs often exhibit decreased turnover rates or diminished product yields.
In this thesis, new approaches to engineer chimeric PKSs were explored, each targeting a different aspect of the chimeric system: First the relative contribution of protein-protein and protein-substrate recognition on the turnover of chimeric PKS was assessed, revealing the importance of protein-protein interactions between the acyl carrier protein (ACP) and the ketosynthase (KS) domain in the chain translocation step. Directed evolution experiments followed to optimize the protein-protein interaction across a chimeric interface. Additionally, different junction sites for the generation of chimeric PKSs were compared, showing the ability for recombination without interfering with the chain translocation reaction, and highlighting the use of SYNZIP domains to bridge PKS modules. To optimize chimeric PKSs even further, multipoint mutagenesis of KS domains was established, with positive effects on the activity of chimeric systems.
To support engineering attempts, several structure elucidation techniques were combined with in silico modeling to characterize the architecture of a PKS module and the domain-domain interactions within it. Preliminary results show a strong conformational flexibility of the PKS module and the great potential of these techniques to define the multitude of transient interactions in PKS modules.
Transport mechanism of a multidrug resistance protein investigated by pulsed EPR spectroscopy
(2019)
In human several diseases result from malfunctions of ATP-binding cassette (ABC) systems, which form one of the largest transport system superfamily. Many ABC exporters contain asymmetric nucleotide-binding sites (NBSs) and some of them are inhibited by the transported substrate.1 For the active transport of diverse chemically substrates across biological membranes, ABC transport complexes use the energy of ATP binding and subsequent hydrolysis. In this thesis, the heterodimeric ABC exporter TmrAB2,3 from Thermus thermophilus, a functional homolog of the human antigen translocation complex TAP, was investigated by using pulsed electron-electron double resonance (PELDOR/DEER) spectroscopy. In the presence of ATP, TmrAB exists in an equilibrium between inward- and outward-facing conformations. This equilibrium can be modulated by changing the ATP concentration, showing asymmetric behaviour in the open-to-close equilibrium between the consensus and the degenerate NBSs. At the degenerate NBS the closed conformation is more preferred and closure of one of the NBSs is sufficient to open the periplasmic gate at the transmembrane domain (TMD).3 By determining the temperature dependence of this conformational equilibrium, the thermodynamics of the energy coupling during ATP-induced conformational changes in TmrAB were investigated. The results demonstrate that ATP-binding alone drives the global conformational switching to the outward-facing state and allows the determination of the entropy and enthalpy changes for this step. With this knowledge, the Gibbs free energy of this ATP induced transition was calculated. Furthermore, an excess of substrate, meaning trans-inhibition of the transporter is resulting mechanistically in a reverse transition from the outward-facing state to an occluded conformation predominantly.3 This work unravels the central role of the reversible conformational equilibrium in the function and regulation of an ABC exporter. For the first time it is shown that the conformational thermodynamics of a large membrane protein complex can be investigated. The presented experiments give new possibilities to investigate other related medically important transporters with asymmetric NBSs or other similar protein complexes.
Many processes in living cells involve interaction and cooperation of multiple proteins to fulfill a specific function. To understand biological processes in their full complexity, it is not sufficient to only identify the molecules being involved but also to understand the kinetic aspects of a reaction. Mass spectrometry (MS) is a very powerful tool which allows to precisely identify the molecules of a reaction. Usually this is done with tandem-MS experiments for purpose of de-novo peptide sequencing. However, since this involves protein digestion, a statement of the in-vivo constitution of non-covalently bound protein complexes is not possible. In order to detect an intact protein complex it is necessary to analyze the biological system softly and in a near-native environment with native MS. Native MS allows the non-destructive analysis of these non-covalent protein complexes as well as to detect their components. However, up to now native MS does not offer a possibility to resolve the timing of the constitution of protein complexes on a fast time-scale. Therefore, the progress of reactions on fast time-scales is invisible. However, a method which delivers both types of information - identification of the components of a protein complex, as well as time-resolving their interaction - would be of high interest.
A suitable ionization technique for native MS is laser-induced liquid-bead ion desorption (LILBID). LILBID employs well-defined droplets which are irradiated by IR laser pulses to generate gas phase ions. The not-continuous, repetitive nature of ion generation offers itself to the development of a time-resolved (TR) native MS system which is able to investigate protein complexes on a fast time scale. The LILBID-droplets can serve as reaction vessels if they are levitated in an electrodynamic Paul-trap. This new setup would allow sample manipulation and MS analysis on precise and fast reaction time-scales. The first part of this dissertation presents the construction and characterization of a setup for TR-LILBID-MS.
An example for a complex biological system is the self-assembly of beta-amyloid (Aβ). This small peptide is the major component in plaques related to Alzheimer’s disease. Clinically relevant is especially the 42 amino acid peptide Aβ42 which aggregates from monomers to oligomers through to fibrils. The oligomers are the neurotoxic species in this process and thus of high interest. Nevertheless, standard analytical techniques are unable to detect those oligomers which makes MS an optimal tool to study the oligomerization process of Aβ with the focus on disease relevant oligomers. TR-LILBID-MS allows to follow the oligomerization of Aβ enabling to study molecules which influence this kinetic. Combining MS with ion-mobility spectrometry adds an additional dimension - the collision cross section - to the mass-to-charge ratio obtained from MS. Therewith structural alterations induced by ligands can be correlated to differences in the aggregation kinetic. This allows to draw a picture of the aggregation process of Aβ for the development of disease-relevant small oligomers on a molecular level.
Die in der vorliegenden Arbeit gewonnenen Erkenntnisse zur Reaktivität zweifach reduzierter 9,10-Dihydro-9,10-diboraanthracene [A]2– erweitern das Einsatzspektrum von Hauptgruppenverbindungen im Hinblick auf die Aktivierung kleiner Moleküle. Komplementär zu Übergangsmetallkomplexen und FLPs ermöglichen die Salze M2[A] (M+ = Li+, Na+, K+) die Entwicklung neuartiger Synthesestrategien. Als besondere Herausforderung gilt die Aktivierung des stabilen H2-Moleküls, dessen Bindung die Dianionen [A]2– homolytisch in einer konzertierten Reaktion spalten.
Untersuchungen zur Kinetik der H2-Addition an M2[A] stellten die Abhängigkeit dieses Reaktionsschritts vom borgebundenen Substituenten und vom Kation heraus. Eine geringe sterische Abschirmung der Boratome durch kleine borgebundene Substituenten (C≡CtBu, Me, H) begünstigt die H2-Aufnahme gegenüber großen Substituenten (pTol, Xyl, Et). Die maximale Ausbeute an M2[A-H2] wird für M+ = Li+ erst nach mehreren Tagen bei 100 °C erhalten, während einige Stunden bei nur 50 °C für die quantitative Bildung von K2[A-H2] ausreichen.
Unter den Salzen M2[A] eignet sich Li2[68] mit borgebundenen Me-Substituenten besonders gut für den Einsatz als Hydrierungskatalysator. Mit Li2[68] konnten das Imin Ph(H)C=NtBu, das terminale Alken Ph2C=CH2 und Anthracen erfolgreich im NMR-Maßstab hydriert werden (Katalysatorladung 37 mol%, THF-d8, 1 atm H2-Initialdruck, 100 °C, 16 h). Im Reaktionsautoklaven war für die Hydrierung von Ph(H)C=NtBu eine Verringerung der Katalysatorladung auf 10 mol% Li2[68] möglich (THF, 7 atm H2-Initialdruck, 100 °C, 18 h). Konkurrenzreaktionen begründen Einschränkungen in Bezug auf die Substratpalette, da M2[68] (M+ = Li+, Na+) mit elektronenarmen ungesättigten Verbindungen, die C=C-, C≡C-, C=O- oder C=N-Bindungen enthalten, [4+2]-Cycloadditionsprodukte bilden können. Die Reversibilität dieser Reaktion entscheidet, ob Li2[68] als Katalysator fungiert oder irreversibel in den Strukturen gebunden bleibt.
Vielseitiger sind die H2-Aktivierungsprodukte M2[A-H2] als H–-Donoren geeignet: Na2[68-H2] ersetzt Halogenid- durch H–-Substituenten in Bromethan, sowie in Chlorsilanen und PCl3; CO2 wird in Natriumformiat überführt. Unabhängig von der Anzahl der Chlorliganden werden die Produkte immer vollständig hydriert. Eine erneute Reduktion von 68 kann wieder Na2[68] bereitstellen, das H2 aufnimmt und Na2[68-H2] regeneriert, welches für neue H–-Abgaben zur Verfügung steht. Bei der experimentellen Umsetzung des Kreislaufs ist es wichtig, die beschriebenen Reaktionsschritte nacheinander auszuführen und jeweils nur stöchiometrische Mengen des Elektrophils zuzugeben. Bei Abweichungen vom schrittweisen Syntheseprotokoll finden formale nukleophile Substitutionen mit M2[68] statt und monoanionische Spezies entstehen, z. B. wenn Et3SiBr als Elektrophil anwesend ist.
Gegenüber CO2 zeigt Li2[68] eine hohe Reaktivität, durch die selektiv CO und [CO3]2– gebildet werden. Wie zuvor bei den H–-Transferreaktionen ermöglicht die Reduktion der Neutralverbindung 68 die Regeneration von Li2[68].
Die Dianionen [A]2– stechen unter anderen cyclischen Borverbindungen in niedrigen Oxidationsstufen heraus, da mit [A]2– nicht nur die Aktivierung von H2 oder CO2 gelang, sondern erstmalig über die Einbindung der Additionsprodukte in zum Teil katalytische Folgereaktionen berichtet werden konnte.
Multidomain enzymes, such as fatty acid synthases (FASs) or polyketide synthases (PKSs), play a crucial role in the biosynthesis of important natural products. They have a high significance in the development of new pharmaceuticals and various research approaches focus on the engineering of these proteins. For example, human type I FAS is an interesting therapeutic target. Owing to its importance in lipogenesis, upregulation of human type I FAS expression has been observed in numerous cancers. Type I FAS is also regarded as important target in antiobesity treatment. Both multidomain enzyme classes - FASs and PKSs - show high structural and functional similarities. Particularly animal type I FAS is most relevant as evolutionary precursor of the PKS family. Therefore, the well characterized FASs are suitable model proteins for the poorly characterized PKSs, to gain deeper understanding in these megasynthases.
Furthermore, fatty acids are considered to be strategically important platform chemicals accessible through sustainable microbial approaches. The recently acquired structural information on FASs provides an excellent understanding of the molecular basis of fatty acid synthesis. The specific understanding of chain-length control, the characterization of a multitude of substrate-specific thioesterases, and the emerging tools and means for metabolic engineering have fostered targeted approaches for modulating chain length. There is large interest in short-chain fatty acids, since these compounds are biotechnologically valuable platform chemicals and biofuel precursors, and attempts on the synthesis of short-chain fatty acids have been reported during the last years.
Primary focus of this thesis lies on the animal type I FASs, which exhibit large conformational variety, as seen in electron microscopy and high-speed atomic force microscopy. Conformational dynamics facilitate productive protein-protein interactions between catalytic domains within the enzyme and aid acyl carrier protein (ACP)-mediated substrate shuttling during the catalytic cycle of fatty acid biosynthesis. To gain deeper insight into the fundamental processes of ACP-mediated substrate shuttling and the underlying conformational dynamics, spectroscopic methods like Förster resonance energy transfer and electron paramagnetic resonance spectroscopy shall be employed. These spectroscopic methods demand site-specific labeling of proteins with fluorophore or spin labels, which can be accomplished with the amber codon suppression technology. Through amber codon suppression, a non-canonical amino acid (ncAA) with an orthogonal functional group is incorporated site-specifically into the protein sequence, which can be used in chemoselective reactions for protein labeling.
This thesis is at the forefront of employing the technology of amber codon suppression for addressing complex biological questions on megasynthases. The successful production of ncAA-modified FASs is challenging. With the aim of incorporating ncAAs into the multidomain 540 kDa large murine FAS, we by far exceed boundaries of documented application of amber codon suppression. Most of the proteins that are reported by Liu & Schultz in applications of amber codon suppression are in the range of 30kDa - for example the TE domain of human FAS. In the same review, the largest protein amber codon suppression was applied to is a potassium channel with roughly 80 kDa. Thus, to the best of my knowledge no protein exceeding 100 kDa has been used in amber codon suppression so far.
In this thesis a low-complex, well-plate based reporter assay is presented, based on an ACP-GFP fusion protein for fast and efficient screening of ncAA incorporation. Reliability and applicability of the reporter assay is demonstrated by successful upscaling to larger protein constructs and increased expression scale.
As outlined in this thesis, we have carefully set up methods for the modification of murine FAS and made several achievements:
(i) We have created our own toolbox with a multitude of suppressor plasmids and various orthogonal pairs. pACU and pACE plasmids are compatible for fast exchange of cassettes, and cloning procedures are optimized for modification of synthetases by site-directed mutagenesis. (ii) We have organic synthesis of several ncAAs stably running in the lab and synthesis of other ncAAs can be established when required. Therefore, extensive screening at moderate costs is possible. (iii) We have established a reporter assay for screening our own library of vectors for amber codon suppression and for optimizing incorporation of ncAAs. (iv) We successfully incorporated ncAAs into subconstructs and full-length murine FAS, and collected initial promising results for the application of these proteins in spectroscopic methods. Thus, laying the foundation for future studies to address fundamental questions of the ACP-mediated substrate shuttling and other conformational dynamics of these enzymes.
Paramyxo- and pneumoviruses include many pathogens with great relevance for human and animal health. To identify common host factors involved in the Paramyxo- and Pneumoviridae life cycle as a basis for new insights in the biology of these viruses and the development of rationally designed therapeutics, genome scale siRNA screens with wild-type measles, mumps, and respiratory syncytial viruses in A549 cells, a human lung adenocarcinoma cell line, were performed. A comparative bioinformatics analysis yielded different members of the coatomer complex I, the translation factors ABCE1 and eIF3A, and several RNA binding proteins as cellular proteins with proviral activity for all three viruses. The strongest common hit, ABCE1, an ATP-binding cassette transporter member, was chosen for further study. We found that ABCE1 supports replication of all three viruses, confirming its importance for both virus families. While viral protein kinetics showed that ABCE1 knockdown resulted in a drastic decrease of MeV protein expression, viral mRNA kinetics are not directly affected by a reduction of ABCE1.
The impact of ABCE1 on viral and global cellular translation was investigated using both 35S metabolic labelling and non radioactive fluorescent protein labelling. ABCE1 knockdown strongly inhibited the production of MeV proteins, while only modestly affecting global cellular protein synthesis and showed that ABCE1 is specifically required for efficient viral, but not general cellular, protein synthesis, indicating that paramyxoand pneumoviral mRNAs may exploit specific translation mechanisms.
In a second approach the efficacy of the small-molecule polymerase inhibitor ERDRP-0519 against MeV was assessed in squirrel monkeys. Animals treated with the drug experienced less severe clinical disease compared to untreated controls, and this effect correlated with the onset of drug treatment.
We observed a reduction of levels of PBMC-associated viremia and virus release in the upper airways, illustrating effective inhibition of virus replication by the drug treatment. ERDRP-0519 drug treatment also alleviated MeV-induced immunosuppression. In addition to providing proof-of-concept for the support of MeV eradication efforts by preventing disease and transmission with a small-molecule polymerase inhibitor, this dissertation provides a novel perspective on cellular proteins that impact the replication of MeV, MuV and HRSV and highlights the role of ABCE1 as host factor that is required for efficient paramyxo- and pneumovirus translation.
ATP-binding cassette (ABC) transporters constitute an omnipresent superfamily of integral membrane proteins, which catalyze the translocation of a multitude of chemically diverse substrates across biological membranes. In humans, ABC transporters typically act as highly promiscuous exporters, responsible for many physiological processes, multi-drug resistance, and severe diseases, such as hypercholesterolemia, lipid trafficking disorders, and immune deficiency. In all ABC transporters, ATP-driven movements within two highly conserved nucleotide-binding domains (NBDs) are coupled to conformational changes of two transmembrane domains (TMDs), which provide a framework for substrate binding and release on the opposite side of the membrane and enable the transporter to cycle between inward-facing and outward-facing orientations. Several structures of ABC transporters determined either by X-ray crystallography or single-particle electron cryo-microscopy (cryo-EM) have been reported, mostly exhibiting a variation of the inward-facing state, which highlights their dynamic behavior. However, for a complete understanding of the conformational dynamics, further structural information on intermediates is needed – especially for heterodimeric ABC transporters, which are predominant in humans and for which only limited structural information is available.
One prime example of such human heterodimeric ABC transport complexes is the transporter associated with antigen processing (TAP). TAP is a key player of the adaptive immune response, because it translocates proteasomal degradation products into the ER lumen for loading of MHC I molecules. Many functional aspects of TAP have been disclosed in recent years. However, structural information is lacking far behind and a major challenge in the field of medical relevant transporters. Recently, the heterodimeric ABC export system TmrAB (Thermus thermophilus multidrug resistance proteins A and B) was identified as an ortholog of TAP, by sharing structural homology with TAP and, intriguingly, being able to restore antigen presentation in human TAP-deficient cells. Thus, TmrAB is a biochemically well-characterized ABC exporter that can be regarded as a functional ortholog of TAP and serves as a model system for (heterodimeric) ABC export systems in general.
Thus, to illuminate the molecular basis of substrate translocation by single-particle cryo-EM, one of the main objectives of this work was the generation of stabilizing chaperones (synthetic antibodies, nanobodies, cyclic peptides) to reduce the conformational heterogeneity of TAP and TmrAB. Selected antibodies were analyzed with respect to stable complex formation, conformational trapping, and the ability to serve as alignment tools for structural studies by single-particle cryo-EM. Both antibody types were shown to form sufficiently stable complexes to serve as a rigid body for EM analyses. However, all selected antibodies bound to the inward-facing state exclusively.
Hence, for EM studies, various ligands were added to elucidate the full spectrum of conformational states during the catalytic cycle. For TAP, first attempts by negative-stain EM revealed a homogenous distribution of particles on the grid. Surprisingly, no transporter-like features were observed although various attempts were applied to increase the overall sample quality.
For TmrAB, in contrast, the complete conformational space in a native-like lipid environment under turnover conditions was mapped. Cryo-EM analysis of TmrAB incubated with ATP-Mg2+ and substrate revealed two distinct inward-facing conformations (IFwide and IFnarrow) as well as two asymmetric conformations with dimerized NBDs, which were markedly different from all previously reported structures. Here, the catalytically active site was slightly wider and contained ADP, while ATP was still bound at the catalytically-inactive site within the NBDs, demonstrating an asymmetric post-hydrolysis state. Intriguingly for the inward-facing conformations, a weak additional density close to residues M139TmrB and W297TmrB was observed in the inward-facing conformation, which displayed a higher degree of cytosolic gate opening (IFwide) indicating the presence of substrate. To verify that this density corresponds to substrate, single alanine mutations of M139TmrB and W297TmrB were introduced, leading to a strong reduction in substrate binding and transport. Since substrate release requires the opening of the extracellular gate, the absence of an outward-facing open conformation indicated that the opening must be highly transient. In order to explore the outward-facing open conformation, a cryo-EM analysis of the catalytically-inactive TmrAE523QB mutant upon incubation with ATP-Mg2+ was performed. Remarkably, within the same dataset, two different outward-facing conformations (occluded and open) were resolved, both in an ATP-bound state, which indicated that binding of ATP is sufficient to drive the large-scale conformational transition from inward-facing to outward-facing open. To explore the effect of nucleotide hydrolysis, TmrAB was trapped by vanadate. Again, two populations were observed, representing the outward-facing open and outward-facing occluded conformation.
Based on several structures of key intermediates, determined under turnover conditions or trapped in the pre-hydrolysis and hydrolysis transition state, for the first time the complete description of the ATP hydrolysis and translocation cycle of a heterodimeric ABC transport complex was elucidated in one single study. By mapping the conformational landscape during active turnover, aided by mutational and chemical modulation of kinetic rates, fundamental and so-far hidden steps of the substrate translocation cycle of asymmetric ABC transporters were resolved and a general template for (heterodimeric) ABC exporter-catalyzed substrate translocation was provided.
Proteostasis stressors that destabilize the cellular proteome, like heat shock, trigger transcription and translational reactions leading to the accumulation of heat shock proteins, also called molecular chaperones. During stress, induction of stress response genes is prioritized so that molecular chaperones and other stress response proteins are synthesized to cope with proteome misfolding and aggregation. In order to promote the selective translation of stress-specific genes, translation of others genes that are nonessential for cell survival has to stop. Nonessential protein-coding mRNAs accumulate in the cytosol with the associated proteins to form granular structures called stress granules (SG). These membrane-less organelles are thought to be involved in cell survival, mRNA stabilization and mRNA triage. They were proposed to form via the liquid-liquid phase separation which can be triggered by the high local concentration of RNA-binding proteins. mRNAs were long thought to simply play a scaffolding role by bringing RNA-binding proteins together and allowing their concentration and local aggregation. Recently, the active role of mRNAs in the SG assembly became apparent, too. For example, the spontaneous assembly of total yeast RNA into granules was observed, and these RNA granules showed a large overlap with SG transcriptome. Furthermore, cytosolic mRNAs can be released from polyribosomes under stress and be exposed to the cytosolic contents as free mRNAs. It has been suggested that this massive increase of free mRNA in the cytosol might overload the capacities of RNA-stabilizing proteins. The remaining free mRNA molecules would then become exposed to misfolded and aggregation-prone proteins and trigger granulation.
We investigated the role of free mRNAs in different stress conditions during the early and chronic phases of stress response and explored their involvement in SGs assembly and amlyoidogenesis. We identified and studied the interactome of a free mRNA probe incubated with heat shocked cell lysate by means of quantitative mass spectrometry. Proteomics analysis allowed us to identify 79 interactors of free mRNA. Among these interactors, we focused on the translation initiation factor eIF2α and on the RNA methyltransferase TRMT6/61A. Both interactions were verified biochemically, which confirmed that the association is enhanced in heat shocked lysate. In vitro reconstitution showed that free mRNA and TRMT6 interact directly. Ex vivo pulldowns revealed that eIF2α and TRMT6/61A interact under stress conditions and that this interaction is RNA-dependent.
TRMT6/61A is a tRNA methytransferase responsible for the methylation of the adenosine 58 at the position 1 producing m1A. However, also mRNAs have been recently found to be methylated by TRMT6/61A. Our bioinformatics analyses revealed that significantly more mRNAs enriched in SG contain the motif for methylation than SG-depleted mRNAs. We hypothesized that m1A methylation of mRNAs could constitute a tag for the mRNAs targeting to SGs. TRMT61A knock-down (KD) cell lines were generated using the CRISPR-Cas9 technique. In TRMT61A KD cells, m1A was significantly reduced on mRNAs, which correlated with an increased sensitivity of the cells to proteostasis stress. KD cells also showed defects in SG assembly. In heat shocked cells, an m1A motif-containing mRNA recovered better after returning to normal temperature than a control mRNA with mutated motif. In addition, we could isolate SGs and analyze their m1A and m6A content by mass spectrometry. While m6A content in SG mRNAs was very similar to cytosolic mRNAs, m1A was almost 8 times enriched in SGs. Thus, we could confirm experimentally the results of the bioinformatics analysis and directly support the hypothesis that m1A is a tag to direct mRNAs for sequestration. Finally, we compared amyloidogenesis in wild-type and TRMT61A KD cell lines. Cells with reduced levels of TRMT61A demonstrated an increased accumulation of transfected Aβ and an impaired aggregate clearance. Various assays led us to conclude that the lack of m1A deposition on mRNAs enhanced RNA co-aggregation with amyloids.
Based on our results, we propose a model explaining the fate of free mRNA during proteostasis stress. Upon polysome disassembly, free mRNA is released and becomes free to interact with other proteins, including the methyltransferase TRMT6/61A. TRMT6/61A methylates the freed mRNAs containing the cognate motif. The m1A tag then targets mRNAs to SGs promoting sequestration. Upon stress release, SGs disassemble, thus releasing rescued mRNAs which could now reenter translation and support cell recovery. On the other hand, non-sequestered mRNAs increasingly co-aggregate with aggregating proteins. Thus, deficiency of the N1-adenine methylation of mRNAs due to the lack of TRMT6/61A increases the amount of unpacked mRNAs. The deposition of m1A on mRNAs could then be a way to protect them during exposure to stress, to limit their co-aggregation with misfolded proteins and to allow a faster recovery upon stress release.
Die Lebensfunktion der Zelle beruht unter anderem auf der Funktion und Wechselwirkung der Nukleinsäuren DNA (2’-Desoxyribonukleinsäure) und RNA (Ribonukleinsäure). Mit Hilfe von PDS (engl. ’pulsed dipolare spectroscopy’)-Techniken, basierend auf der EPR (engl. ’electron paramagnetic resonance’)-Spektroskopie, können Abstände in einem Bereich von 2-10 nm zwischen zwei markierten Positionen einer Nukleinsäure bestimmt werden. Daneben kann mit der Abstandsverteilung auf die Flexibilität des Moleküls geschlossen werden. Durch PDS-Messungen eröffnet sich die Möglichkeit, Bewegungen und Zustandsänderungen zu untersuchen. Die Messungen beruhen auf der dipolaren Kopplung von Radikalen (Spinlabel). Da die gemessenen dipolaren Kopplungen eine anisotrope Wechselwirkung sind, können an starren Systemen neben den Abstandsinformationen auch die Orientierungen der beiden Spinlabel zueinander bestimmt werden. Diese zusätzliche Information ermöglicht es, mittels orientierungsselektiver PDS-Messungen noch genauer die Geometrie und Flexibilität des Systems zu untersuchen. Klassischerweise werden alle Messungen mit der Doppelfrequenztechnik PELDOR (engl. ’pulsed electron-electron double resonance’) durchgeführt. Einzelfrequenzmethoden basieren dagegen auf Breitbandanregung, die mit den technischen Gegebenheiten l nge nicht möglich war. Eine solche Sequenz ist 2D-SIFTER.ImmRahmen dieser Arbeit von PELDOR ausgehende, weiterentwickelte Simulationsprozedur etabliert. Eine große Herausforderung ist die eindeutige Interpretation der sensitiven orientierungsselektiven PELDOR-Messungen. Sie mittels MD (Moleküldynamik)-Simulationen zu beschreiben war bisher nur qualitativ möglich. Allerdings wurden mehrere neue Kraftfelder publiziert. Mit einem quantitativen Vergleich mit orientierungsselektiven PELDOR-Daten kann sichergestellt werden, dass die Flexibilität des Systems durch Kraftfelder richtig beschrieben ist. PELDOR-Zeitspuren, gemessen bei Raumtemperatur und 50 K, unterscheiden sich besonders in ihrer Dämpfung. Der physikalische Unterschied beider Messungen konnte durch MD-Simulationen qualitativ nachvollzogen worden. Eine Schwierigkeit für speziell orientierungsselektive PELDOR-Messungen ist die aufwendige Synthese von mit dem starren Ç-Label markierten Nukleinsäuren. Als Alternative wurde in der Sigurdsson-Gruppe das halbstarre IMU-Label entwickelt. Die Analyse der orientierungsselektiven Daten ergab ein klares Bild der Dynamik dieses Labels. Ein weiterer interessanter Spinlabel ist der `G. Dieser Label ist nicht kovalent gebunden, sondern interkaliert in eine Stelle der Nukleinsäure, in der eine Guanin- Base fehlt. MD-Simulationen im quantitativen Vergleich mit orientierungsselektiven PELDOR-Messungen an verschiedenen Magnetfeldern haben eine hohe Übereinstimmung. Dabei konnte gezeigt werden, dass der Label, interkaliert in eine dsDNA, flippen kann, was zu einer Ausmittelung der Anisotropie führt, allerdings zu keiner Verbreiterung der Abstandsverteilung. Dagegen wird in der dsRNA dieses Flippen um die Einfachbindung sterisch gehindert, so dass neben dem Abstand auch die Orientierung des Labels bestimmt werden kann. Kurze dsRNA-Bausteine tendieren dazu, Oligomere zu bilden, was zu Multispineffekten führte. Zusätzlich beeinflusst diese Aggregation die Dynamik der einzelnen RNAs. Daher musste dieses ’end-to-end’-Stacking verhindert werden. Eine Nukleobasean einem Ende der dsRNA führt zu einer Dimerisierung, während eine Nukleobase an beiden Seiten dieses Stacking vollständig verhindert. Messungen mit unterschiedlichen Salzkonzentrationen konnten zusätzlich zeigen, dass die Interaktion zweier dsRNAs bei höheren Salzkonzentrationen zunimmt.
The three major autoimmune diseases (ADs) of the liver are primary biliary cholangitis (PBC), primary sclerosing cholangitis (PSC), and autoimmune hepatitis (AIH). All of those diseases show an aggressive immune reaction resulting in the destruction of liver tissue and finally to the development of hepatic fibrosis.
PSC is an autoimmune mediated disease of unknown etiology. It is characterized by inflammation of intra- and extrahepatic bile ducts. The progressive destruction of the bile ducts can lead to liver cirrhosis and finally to liver failure. Clinical signs for PSC are increased alkaline phosphatase (AP) and gamma glutamyltransferase (GGT) levels, presence of perinuclear anti-neutrophil cytoplasmic antibodies (pANCA) and bile ducts with characteristic strictures and dilations of the biliary tree as well as onion skin fibrosis surrounding the damaged bile ducts. Currently, there is no established treatment for PSC patients. The administration of ursodeoxycholic acid (UDCA) is being use as a therapy. However, it merely serves a symptomatic treatment to reduce serum AP and GGT as well as the formation of gallstones. In the advanced stage of PSC, liver transplantation is the last therapeutic option. Mdr2-/- mice are an excepted mouse model for human PSC. Such mice show lymphocytes infiltration into the liver, bile duct lesions, as well as the presence of the typical onion skin-like pericholangitis and periductal fibrosis.
AIH is a rare chronic autoimmune disease of the liver that results from the loss of self-tolerance to hepatocytes and leads to destruction of the hepatic parenchyma with the onset of cirrhosis. Clinical signs for AIH are elevated alanine aminotransferase (ALT) and aspartate transaminase (AST) levels, hypergammaglobulinemia and different types of autoantibodies. In addition, interphase hepatitis with lymphocytic and plasmacellular infiltrates in the periportal field are characteristic for AIH. Two different subtypes of AIH exist and depending on their autoantibody profile they can be distinguished into AIH type 1 which is characterized by the presence of anti-nuclear (ANA) and/or anti-smooth muscular (SMA) autoantibodies, and AIH type 2 showing liver/kidney microsomal autoantibodies (LKM-1). LKM-1 recognizes the major autoantigen, the 2D6 isoform of the cytochrome P450 enzyme family (CYP2D6). One mouse model for AIH is the CYP2D6 model in which the injection of Ad-2D6 leads to a breakdown of the immune tolerance by the destruction of hepatocytes.
There are some patients with autoimmune diseases of the liver who have both cholestatic and hepatic liver enzymes and histological features suggestive of two different liver diseases. These patients are diagnosed with an overlap syndrome (OS).
In my thesis I generated an animal model with characteristics of both diseases, which would mimic features of human PSC-AIH OS. Mdr2-/- mice which spontaneously develop PSC were infected with Ad-2D6 to trigger the autoimmune-driven hepatic injury. Pathogenesis of PSC-AIH OS mice was compared to mice with solitary PSC or AIH. Naïve FVB wild type mice have been used as healthy controls. The characterization of the PSC-AIH OS model was done by analyzing serological parameters like ALT, AP, different antibodies like pANCA, LKM-1 like CYP2D6 and total IgG. Additionally, fibrosis and cholangitis were analyzed by immunohistochemistry and Western blotting. Moreover, cellular infiltrations of CD4+ and CD8+ T cells, dendritic cells (DCs), monocytes/macrophages and neutrophils were determined with immunohistochemistry. Finally, the overall immune balance in the liver and the frequency of CYP specific T cells were analyzed via flow cytometry. Our new mouse model indeed represents the characteristics of both PSC and AIH and mimics features of the human PSC-AIH OS. It allows studying the development of a PSC-AIH OS and how the two overlapping diseases are influencing one another. In a second approach I wanted to induce CYP2D6-specific tolerance in AIH mice. Therefore, I tried four different approaches, namely intranasal peptide administration, injection of tolerogenic DCs, antigen-coupled splenocytes, and Ag-coupled nanoparticles (NP) and evaluated their potential to induce CYP2D6 specific Treg with the capacity to prevent AIH in mice. Unfortunately, the intranasal peptide administration and also the injection of tolerogenic DCs did not increase the amount of CYP2D6 specific Treg which would lead to a reduction of the frequency of inflammatory T cells. Surprisingly, the injection of antigen-coupled splenocytes showed the opposite effect characterized by a very strong cytokine secretion in the tolerized mice. The use of NPs led to an increase in CYP2D6 specific Treg as well as in decrease in the frequency of inflammatory T cells and finally has the potential for a therapeutic approach.
In summary, the generated PSC-AIH OS model represents many clinical signs which can also be observed in PSC-AIH OS patients. This model can be used to study the etiology of this overlap syndrome and further to test potential therapeutic approaches. The different immune tolerance induction pathways which I tried in the AIH model show that NPs have to potential to induce immune tolerance but this approach has to be refined and the outcome has to be characterized in more detail.
Die CXCR4-CXCL12-Signalachse gilt als eines der bislang am besten studierten Signalsysteme in der Hämatopoese. Allerdings stammt unser Wissen über diesen kritischen Signalweg maßgeblich aus subtraktiven Studien, wie z.B. knock-out Modellen oder pharmakologischer Inaktivierung. Zwar können aus diesen Modellen wichtige Erkenntnisse über die physiologische Rolle dieses Signalwegs abgeleitet werden, aber dennoch bleiben einige Phänomene ungeklärt. So konnte gezeigt werden, dass es sowohl bei CXCR4-Defizienz als auch bei Patienten mit dem WHIM-Syndrom (ausgelöst durch eine überaktive CXCR4-Mutante) zu einer ausgeprägten B-Zellaplasie kommt. Dies scheint intuitiv nicht vereinbar. Daher wurde in der vorliegenden Arbeit ein Modell mit einer überaktiven CXCR4- Mutante (CXCR41013/1013) hinsichtlich der (un)reifen Hämatopoese systematisch untersucht.
Zunächst wurden hämatopoetische Stamm- und Vorläuferzellen (HSPC) hinsichtlich der aberranten CXCR4-Signalweiterleitung ex vivo analysiert. Die CXCR4-Überaktivierung konnte sowohl in frühen Effekten nach Aktivierung des Rezeptors (F-Aktinpolymerisierung, Aktivierung des MAPK- Signalweges), als auch in späten, zellfunktionellen Effekten (Migrationsassay) nachgewiesen werden. Die veränderte CXCR4 Signalintegration hatte auch bereits in der Homöostase organismische Konsequenzen im Mausmodell. So konnte eine massiv vergrößerte HSPC-Population in der Milz von CXCR41013/1013-Tieren detektiert werden, im Sinne einer extramedullären Hämatopoese. Knochenmarks-HSPC aus CXCR41013/1013-Tiere zeigten ein massiv eingeschränktes (serielles) Repopulationspotenzial. Kombiniert mit der oben genannten ausgeprägten extramedullären Hämatopoese in diesen Tiere interpretieren wir diese Beobachtung als starken Hinweis auf eine dysfunktionelle Interaktion der Stammzellen mit der hämatopoetischen Stammzellnische im Knochenmark. In diesem Zusammenhang besonders interessant ist die Tatsache, dass auch ein Kompetitorknochenmark das Überleben einer Sekundärtransplantation nicht sichert. Dabei ist zu diskutieren, ob dieser Effekt durch eine effizientere Besetzung von Stammzellnischen durch CXCR41013/1013-Zellen, eine Akkumulation von CXCL12 in der Knochenmarkflüssigkeit (siehe unten) oder eventuell sogar ein vesikelabhänginger Transport von mutiertem CXCR4 in Kompetitorzellen ausgelöst wird. Ein weiteres Merkmal dieser Dysfunktion könnte ebenfalls die gezeigte Akkumulation von CXCL12 in der Knochenmarkflüssigkeit von CXCR41013/1013-Tiere darstellen. Diese Akkumulation könnte die Suppression co-transplantierter wildtypischer Hämatopoese sowie die verminderte Effizienz der G-CSF-induzierten Stammzellmobilisierung funktionell erklären. Zusätzlich konnte gezeigt werden, dass die Mobilisierung von Stammzellen aus dem Knochenmark durch einen CXCR4- Inhibitor in CXCR41013/1013-Tieren ebenfalls erheblich hinter der in Wildtypmäusen zurückbleibt.
Analog zu Patienten mit WHIM-Syndrom zeichnen sich CXCR41013/1013-Mäuse weiterhin durch eine ausgeprägte Leukopenie, insbesondere durch einen schweren B-Zell-Mangel, aus. Aus diesem Grund wurde die B-Lymphopoese und humorale Immunfunktion genauer analysiert. Eine grundsätzliche humorale Immunkompetenz von CXCR41013/1013-Tieren konnte nachgewiesen werden, jedoch ist die B-Memory-Funktion erheblich eingeschränkt. Durchflusszytometrisch und funktionell konnte eine reduzierte preB/pro-B Population im Knochenmark bei einer gleichzeitig vergrößerten preB/pro-B Population in der Milz (vgl. extramedulläre Hämatopoese) nachgewiesen werden. Ebenfalls konnten wir in dieser Zellpopulation eine stark erhöhte CXCR4-Oberflächenexpression im Vergleich zu wildtypischen Zellen nachweisen. Da diese unreifen B-Zellen keine verstärke Apoptoserate aufweisen, gehen wir derzeit davon aus, dass der Differenzierungsstopp nicht durch selektiven Zelltod, sondern durch aberrante Retention der preB/proB-Zellen in einer primitiven B-Vorläufer- Nische im Knochenmark zustande kommt, beziehungsweise durch eine gestörte Migration in differenzierende Nischen im Knochenmark. Alternativ könnte die Überdosis CXCR4-Signal differenzierenden Signalen entgegenstehen. Beide Hypothesen können das eingangs erwähnte Paradoxon bezüglich einer B-Zellaplasie in CXCR4-defizienten und CXCR4-überaktiven Zellen hinreichend erklären.
The membrane protein Green Proteorhodopsin (GPR), found in an uncultured marine γ-proteobacterium, is a retinal binding protein and contains a conserved structure of seven transmembrane helices (A-G). The retinal is bound to a conserved lysine residue (K231) in helix G via Schiff base linkage. It belongs to the widespread family of microbial rhodopsins and functions as a light dependent outward proton pump that bacteria may utilize for establishing a proton gradient across the cellular membrane. Proton pumping takes place after photon absorption, where GPR goes through a series of conformational changes, termed photocycle, causing the proton to be transported across the cellular membrane from the intra-cellular to the extracellular space. It is further mediated by the highly conserved functional residues D97 and E108, which function as the primary proton acceptor and primary proton donor for the protonated Schiff base, respectively. Another functionally important residue is the highly conserved H75 in helix B. It forms an intra-molecular cluster with D97 and is responsible for the high pKa value of the primary proton acceptor, stabilized by a direct interaction between D97 and H75.
Different Proteorhodopsin variants are globally distributed and colour tuned to their environment, depending on the water depth in which they occur. A single residue in the retinal binding pocket at position 105 is responsible for determining the absorption wavelength of the protein. GPR (from eBAC31A08) contains a leucine at position 105, while BPR (blue proteorhodopsin, from Hot75m4) in deeper waters possesses a glutamine. Although GPR shows 79% sequence identity with BPR, a single amino acid substitution (L105Q) in GPR is able to switch the absorption maximum to the one of BPR.
Protein oligomerisation describes the association of subunits (protomers) through non-covalent interactions, forming macromolecular complexes. It is an important structural characteristic of microbial rhodopsins, contributing to structural stability and promoting tight packing of the protomers in the bacterial membrane. GPR was shown to assemble into radially arranged oligomers, mainly pentamers and hexamers. No high resolution crystal structure of the whole GPR complex is available, but the structurally related BPR (Hot75m4) was successfully crystallized, showing pentameric oligomers.
The BPR crystal structure model reveals detailed information about complex assembly of the whole proteorhodopsin family. It reveals the oligomeric structures and shows residues that are part of the protomer interfaces, forming cross-protomer contacts, which is valuable information for the elaborate analysis of cross-protomer interactions of GPR oligomers.
Based on the knowledge of GPR and BPR oligomeric complexes, the aim of this study is to analyse specific cross-protomer contacts and to characterize the functional role of GPR oligomerisation. This includes the identification of residues, which are part of charged cross-protomer contacts and play an important role for the formation of the GPR oligomeric complex. Furthermore, this study deals with a detailed characterization of a potentially functional cross-protomer triad between the residues D97-H75-W34, which was detected in the BPR structural model. Hereby, the focus lies especially on the functional role H75, which is highly conserved and is positioned in between the primary proton acceptor D97 and W34 across the protomer interface. In summary, this study addresses GPR oligomerisation via specific cross-protomer contacts and its potential role for the functional mechanism of the protein.
The fundamental technique used in this study is solid-state NMR. Furthermore, an elaborate characterization of GPR oligomerisation was executed using a variety of biochemical methods and mutational approaches. Solid-state NMR is a powerful biophysical method to analyse membrane proteins in their native lipid environment and can be used to obtain diverse information about structure, molecular dynamics and orientation of the protein in the lipid bilayer.
Solid-state NMR naturally has a low sensitivity. In order to detect the low number of spins, DNP signal enhancement is of particular importance in this study. It is exhibited under cryogenic conditions and allows to drastically enhance the solid-state NMR signal by transferring magnetization from highly polarized electrons to the nuclear spins.
By applying these methods and techniques on GPR oligomers, this study reveals new insights in specific cross-protomer interactions in the complex. First the oligomeric states of GPR were determined for the specific experimental conditions used in this study. LILBID-MS, BN-PAGE and SEC analysis identified the pentameric state to be dominant for GPR. Furthermore, specific interactions across the protomer interface, which drive GPR oligomerisation, were identified. This was conducted by creating mixed 13C-15N labelled complexes. These mixed complexes show a unique isotope labelling pattern across their protomer interfaces. Solid-state NMR 13C-15N-correlation spectroscopy (TEDOR) was used to identify through-space dipole-dipole couplings, which indicate specific cross-protomer contacts. The results indicated that the residues R51, D52, E50 and T60 are important for GPR oligomerisation, and further analysis via single mutations of these residues showed a severe impact of the GPR oligomerisation behaviour.
The functional importance of GPR oligomerisation was analysed by DNP-enhanced solid-state NMR on the cross-protomer D97-H75-W34 triad. The DNP cryogenic conditions allowed to trap GPR in distinct stages of the photocycle. It could be shown that trapping GPR in a specific intermediate leads to a drastic conformational effect for the highly conserved H75 residue. Furthermore, DNP-enhanced solid-state NMR was used to characterize the cross-protomer contact between H75 and W34. Mutations of W34 could show that the cross-protomer interaction is highly important for the functionality of the protein, as negative mutants such as W34E showed a reverse proton transport across the bacterial membrane.
In summary this study represents a detailed analysis of GPR cross-protomer interactions and sheds light into the cause and functional importance of oligomeric complex formation in the microbial rhodopsin.
FPP und GGPP sind Intermediate des Mevalonat-Weges und fungieren als post-translationale Modifikation kleiner GTPasen. Die Prenylierung kleiner GTPasen erfolgt katalysiert von spezifischen Prenyltransferasen und ist notwendig um die kleinen GTPasen in Membranen zu verankern, wo ihre Aktivierung stattfindet. Zu den intrazellulären Funktionen der GTPasen gehören unter anderem der Aufbau des Cytoskeletts, das neuronale Zellwachstum, die Leitung und Ausläuferbildung von Axonen, das Dendritenwachstum, die Synapsenformation, die synaptische Plastizität und die Apoptose. Diese Funktionen spielen in der Gehirnalterung sowie in neurodegenerativen Erkrankungen wie der Alzheimer Demenz (AD) und auch bei der Glioblastoma multiforme (GBM) eine wichtige Rolle.
Im Zuge einer in vivo Studie an C57BL/6 Mäusen konnten in der vorliegenden Arbeit altersbedingte Veränderungen der Lokalisation verschiedener Rho- und Rab-GTPasen in Membran- und Cytosol-Präparationen sowie der GGTase-I in Gehirnen gealterter Tiere gezeigt werden. Die zelluläre Lokalisation der Rho GTPasen Rac1, RhoA und Cdc42 verschiebt sich im Alter zu reduzierten Membran-gebundenen und erhöhten cytosolischen Gehalten. Dies ist mit einer Reduktion der Protein- und mRNA- Gehalte des Enzyms GGTase-Iβ assoziiert, der Untereinheit der GGTase-I, die die Bindung des Isoprenoids GGPP an die Rho-GTPasen reguliert. Diese wiederum korrelieren direkt mit der altersbedingten Reduktion der relativen GGTase-Aktivität. Die in vitro Inhibition der GGTase-I mittels GGTI-2133 an SH-SY5Y Zellen erwies sich als Modell, welches die gleichen Effekte wie die gealterten Gehirne in vivo zeigt.
7, 8-Dihydroxyflavon (7, 8-DHF) ist ein natürlich vorkommendes Flavon, welches als hoch affiner selektiver TrkB-Rezeptor-Agonist fungiert und hierdurch wie das Neurotrophin BDNF das Überleben von Neuronen, deren Differenzierung, synaptische Plastizität und Neurogenese vermittelt. In vivo verursacht die orale Gabe von 7, 8-Dihydroxyflavon in Gehirnen alter Tiere eine Abnahme des Isoprenoids GGPP, die Zunahme der prenylierten Membran-gebundenen GTPase Rac1 und eine Reduktion des Gehaltes an Membran-gebundenem Rab3A auf das Niveau der Gehalte in den Gehirnen der jungen Kontroll-Tiere. Das Neurotrophin BDNF interagiert mit dem TrkB-Rezeptor und ist in der Lage direkt an den Rac1-spezifischen GEF Tiam1 zu binden, wodurch dieser aktiviert wird und Veränderungen der zellulären Morphologie der betroffenen Neurone induziert. Während das Alter und die orale Gabe von 7, 8-Dihydroxyflavon in vivo keine Effekte auf die Proteingehalte von BDNF und TrkB in der Tierstudie aufzeigten, konnte eine alterbedingte Reduktion von Tiam1 im Hirngewebe detektiert werden, die wiederum durch 7, 8-Dihydroxyflavon aufgehoben werden konnte.
Die Isoprenoide FPP und GGPP, sowie die Regulation kleiner GTPasen spielen auch eine wichtige Rolle im Zusammenhang mit Veränderungen der APP-Prozessierung in der molekularen Pathogenese der AD. Bei der APP-Prozessierung sind die beiden Sekretasen β- und γ-Sekretase für die Bildung des β-Amyloid-Peptids verantwortlich. In vitro Studien mit dem β-Sekretase-Inhibitor IV und dem γ-Sekretase-Inhibitor DAPT an untransfizierten und APP-transfizierten HEK293 Zellen (HEK293-APP695wt und HEK293-APPsw Zellen) konnten zeigen, dass sowohl die β- als auch die γ-Sekretase an der Regulation der Isoprenoide FPP und GGPP beteiligt sind. FPP und GGPP liegen in APP-transfizierten HEK293 Zellen erhöht vor. Die Inhibition der β-Sekretase führt zur Reduktion von FPP und GGPP. Durch die Inhibition der γ-Sekretase wird ausschließlich FPP reduziert. Weiterhin liegen in APP-transfizierten HEK293 Zellen die Membran-gebundenen prenylierten Rho-GTPasen Rac1, Cdc42 und RhoA erhöht vor. Das Membran-gebundene prenylierte H-Ras kommt jedoch in APP-transfizierten Zellen im Vergleich zu untransfizierten HEK293 Zellen in deutlich niedrigeren Mengen vor. Die Inhibition der β-Sekretase bedingt die Reduktion von Membran-gebundenem prenylierten Rac1 und auch von Membran-gebundenem H-Ras in HEK293-APPsw Zellen.
Veränderungen von Signaltransduktionswegen, die durch kleine GTPasen vermittelt werden, haben sich auch bei der GBM als zentraler Teil der molekularen Pathogenese herausgestellt. Hierbei ist die Prenylierung durch FPP und GGPP die Voraussetzung für die Membran-Insertion und onkogenen Funktion der Ras- und Rho-Proteine über die Stimulierung des Ras-Raf-MEK-ERK Signalweges. In dieser Arbeit konnte gezeigt werden, dass der HMG-CoA-Reduktase Inhibitor Lovastatin die Bildung der beiden Isoprenoide FPP und GGPP in U87 und U343 Glioblastoma Zellen verringert und hierdurch die Isoprenylierung von H-Ras und Rac1 reduziert. Das natürlich vorkommende Monoterpen Perrilylalkohol hingegen inhibiert die Prenyltransferasen FTase und GGTase und verändert dadurch die post-translationale Prenylierung der GTPasen Rac1 und H-Ras in U87 und U343 Zellen ohne die Isoprenoide FPP und GGPP signifikant zu beeinflussen. Jedoch bewirkt Perillylalkohol in U343 Zellen eine Erhöhung des GGPPs. Beide Substanzen bewirkten die Reduktion der ERK-Phosphorylierung und der Migration, Invasion und Proliferation der untersuchten U87 und U343 Glioblastoma Zellen.
The focus of this thesis is the integral membrane protein Escherichia coli diacylglycerol kinase (DGK). It is located within the inner membrane, where it catalyzes the ATP-dependent phosphorylation of diacylglycerol (DAG) to phosphatic acid (PA). DGK is a unique enzyme, which does not share any sequence homology with typical kinases. In spite of its small size, it exhibits a notable complexity in structure and function. The aim of this thesis is the investigation of DGK’s structure and function at an atomic level directly within the native-like lipid bilayer using MAS NMR. This way, a deeper understanding of DGK’s catalytic mechanism should be obtained.
First, the preparation of DGK was optimized, leading to a sample, which provides well-resolved MAS NMR spectra. The high quality MAS NMR spectra formed the foundation for the second step, the resonance assignment of DGK’s backbone and side chains. The assignment was performed at high magnetic field (1H frequency 850 MHz). The sequential assignment of immobile domains was carried out using dipolar coupling based 3D experiments, NCACX, NCOCX and CONCA. The measurement time could be reduced by paramagnetic doping with Gd3+-DOTA in combination with an E-free probehead. The sequential assignment was mainly performed using a uniformly labelled sample (U-13C,15N-DGK). Residual ambiguities could be resolved by reverse labelling (U-13C,15N-DGK-I,L,V). Resonances could be assigned for 82% of the residues, from which 74% were completely assigned. For validation, ssFLYA was applied, which is a generally applicable algorithm for the automatic assignment of protein solid state NMR spectra. Its principal applicability for demanding systems as membrane proteins could be proven for the first time. Overall, ~90% of the manually obtained assignments could be confirmed by ssFLYA. For the completion of DGK’s assignment, J-coupling based 2D experiments, 1H-13C/15N HETCOR and 13C-13C TOBSY, were carried out to detect highly mobile residues. This way, residues of the two termini and the cytosolic loop, which were not detectable by dipolar coupling based experiments, could be assigned tentatively. Whereupon, peaks for arginine and lysine were assigned unambiguously to Arg9 and Lys12. Overall, ~84% of the residues could be assigned by the applied NMR strategy. Furthermore, a secondary structure analysis was carried out. It showed substantial similarities between wild-type DGK, its thermostable mutant determined both by MAS NMR and the crystal structure of wtDGK. However, there are few differences around the flexible regions most likely caused by the high mobility of these regions. During the assignment procedure, no systematic peak doublets or triplets were detected, indicating that the DGK trimer adopts a symmetric conformation. This is in contrast to the X-ray structure, which shows asymmetries between the three subunits. Especially, crystal packing may be a potential source for these structural asymmetries.
On the basis of the nearly complete assignment of DGK, the apo state was compared with the substrate bound states. Perturbations in peak position and intensity of the substrate bound states were analysed for all assigned residues in 3D and 2D spectra. The nucleotide-bound state was emulated by adenylylmethylenediphosphonate (AMP-PCP), a non-hydrolysable ATP analogue, whereas the DAG-bound state was mimicked by 1,2-dioctanoyl-sn-glycerol (DOG, chain length n = 8). Upon nucleotide binding, extensive chemical shift perturbations could be observed. These data provide evidence for a symmetric DGK trimer with all of its three active sites concurrently occupied. Additionally, it could be demonstrated that the nucleotide substrate induces a substantial conformational change. This most likely supports the enzyme in binding of the lipid substrate, indicating positive heteroallostery. In contrast, the overall alterations caused by DOG are very minor. They involve mainly changes in peak intensities. For DGK bound with either AMP-PCP+DOG or only AMP-PCP, a similar spectral fingerprint was observed. This implies that binding of the nucleotide seems to set the enzyme into a catalytic active state, triggering the actual phosphoryl transfer reaction.
The investigation of DGK’s remarkable stability and the cross-talk between its subunits forms the last part of this thesis. This demands for the identification of key intra- and interprotomer contacts, which are of structural or functional importance. For this purpose, 13C-13C DARR and 2D NCOCX spectra with long mixing times were recorded using high field MAS NMR. Additionally, DNP-enhanced 13C−15N TEDOR experiments were conducted on mixed labelled DGK trimers to enable the visualization of interprotomer contacts. With the applied NMR strategy, intra- (Arg32 - Trp25/ Glu28/ Ala29 and Trp112 - Ser61) and interprotomer (ArgNn,e - AspCg/ GluCd/ AsnCg) long-range interactions could be identified.
As central component of the peptide loading complex, the ABC transporter TAP is a key player in the adaptive immune response. By recognizing and translocating antigenic peptides derived from proteasomal degradation into the ER lumen it connects the processing of harmful intruders and the marking of an infected cell for elimination. This work focused mainly on the interaction between TAP and one of its viral inhibitors. Of the five known TAP inhibitors, ICP47 is the only one that is not anchored in the ER membrane and has a nonomolar affinity to TAP. These properties and its specific architecture make it an interesting protein engineering tool that can be used in a variety of ways to generate functionally arrested TAP complexes. Different lengths of ICP47 were chosen to map the optimal distance between the binding pocket and the N-terminal elbow helix of either TAP1 or TAP2. I demonstrated that the interaction of fused ICP47 with coreTAP inhibits antigen presentation via MHC I. Interestingly, the loss of MHC I surface expression only depended on the presence of the active domain and not on the length of the fused ICP47 fragments. Summarizing it can be said that TAP complexes containing an intact active domain of ICP47 successfully suppressed MHC I surface expression. Considering the MHC I surface expression in the use of free ICP47 fragments it was revealed that the active domain may not be sufficient. All free constructs, except the one that contains exclusively the active domain (1-35), were able to fully arrest peptide translocation, while the fragment 1-35 partially restored MHC I surface expression. This was the first evidence suggesting that more residues might be present in the ICP47 sequence that contribute to the interaction with TAP.
Further characterization of the ICP47-coreTAP fusion complexes comprised the determination of their thermostability and melting temperatures. The ICP47-coreTAP fusion complexes revealed a preferred orientation for ICP47. The ICP47(1-65) fragment led to a stable complex only if fused to TAP2, highlighting an interesting asymmetry at the TAP1/TAP2 interface, which suggests a shorter distance of the C-terminus of the stabilizing region to the elbow helix of TAP2 than of TAP1. The shorter fragments 1-35 and 1-50, and the ICP47 linker fragments, which inhibited, but did not trigger any thermostabilizing effects on TAP, revealed a second hint for the presence of other residues important for the ICP47/TAP interaction. To define the thermostability in more detail, the melting temperature of complexes with fused or freely bound ICP47 fragments was determined. Short fused fragments of ICP47 (residues 1-35 or 1-50) did not fully stabilize the TAP complex. Only ICP47 fragments longer than residues 1-50 raised the melting temperature to the full extent and led to a completely stabilized complex, suggesting that the critical melting temperature, which determines whether a complex is fully stabilized or not, is about 44-45°C. By comparing different ICP47 proteins from the herpesviral clade, I further noticed that the 21 residues following the active domain are highly conserved. The residues in this region were exchanged by glycines and alanines to study their impact on the thermostabilization of TAP. I demonstrated that several charged residues, an alanine rich, and a proline rich sequence were mainly responsible for the preservation of high melting temperatures. In summary, these findings reveal a dual inhibition mechanism of ICP47. While the active domain of ICP47 is wedged at the TAP1/2 interface and arrests the complex in an open-inward facing conformation, the highly conserved C-terminal region stabilizes the ICP47/TAP interaction and generates a thermostabilized TAP complex.
The second part of this thesis deals with two alternative expression and stabilization strategies for coreTAP, designed to provide a 1:1 ratio of TAP subunits during protein biosynthesis. Different glycine-serine (GS) linkers and a self cleaving 2A site were im- plemented into the TAP sequence and used for comparison with the classical coreTAP. Despite their functionality in antigen translocation, the utilization of GS linkers proved to be unsuitable due to low expression and scarce purification efficiency caused by the unfeasible orthogonal purification. In contrast, the use of a 2A site allowed orthogonal His10- and SBP-tag purification and yielded comparable amounts to the classical coreTAP. However, the ICP47/coreTAP interaction appeared to be hampered by the modified N-terminus of ICP47, due to the cleavage process.
The third and last part of this work deals with the Thermus thermophilus ABC trans- porter TmrAB, which was identified to be part of the same ABC subfamily as TAP. The structure of TmrAB is similar to that of coreTAP and includes a TMD and an NBD for each subunit. In comparison to TAP, TmrAB has a broader substrate range, but it can transport peptides, which are also transported by TAP. Since the natural substrate, and thus the actual function, of TmrAB has not yet been identified, it is counted among the multidrug resistance ABC transporters, from where it also takes its name. In this work, the question was investigated whether TmrAB can be utilized as a TAP substitute. To compare the function of TmrAB and TAP in a natural cell environment, the N-terminal domains of the TAP subunits called TMD0s were fused to the TmrAB subunits and subsequently expressed as different combinations. I found that especially the hybrid complexes containing a TMD0 of TAP2 were functional in terms of MHC I surface expression. Furthermore, TmrAB with TMD0 co-localized prevalently with the ER marker PDI while complexes without TMD0 did not co-localize. Interestingly, the analysis of the interaction with components of the PLC revealed that interaction with tapasin could only occur when a TMD0 was present. In turn, calreticulin, MHC I, and ERp57 were bound, regardless of the presence of a TMD0. It is remarkable that a bacterial protein, sharing only 27-30% sequence identity with human TAP is able to take over a key function of our adaptive immune system. Yet, TmrAB originates from a hyperthermophilic bacterium and may have assembly and folding difficulties that the human cell seeks to overcome by recruiting chaperones like calreticulin and ERp57. Although further experiments will be necessary to analyze the interaction of TmrAB with the PLC components in more detail, TmrAB appears to be homologous to coreTAP, not only in terms of sequence and structure, but also in terms of function.
In this research project we aimed to generate genetically modified megakaryocytes and platelets, by targeting protein expression to their secretory alpha-granules to delivery ectopic or therapeutic proteins, to be stored and kept there until an external stimulus triggers platelet activation and platelet secretion takes place. During platelet activation, the therapeutic proteins would then be released to the extracellular space, either as a soluble protein or exposed as a transmembrane protein on the cell surface of platelets. For long-term approaches, genetic modifications must be introduced at the hematopoietic stem cell level.
AIMS: As first approach, we aimed to characterize the lineage-specificity of expression of six different promoter fragments in lentiviral vectors: the murine platelet factor 4 (mPf4) 1222 bp (-1074 to +148), human glycoprotein Ib alpha (hGP1BA) 595 bp (-265 to +330), a short and a longer fragment of the human glycoprotein 6 (hGP6 / hGP6s) 351 bp (-322 to +29) / 726 bp (-697 to +29), as well the human glycoprotein 9 (GP9) promoter 794 bp (-782 to -12). These promoter fragments were included as internal cellular promoters in self-inactivating lentiviral vectors (SIN), using an enhanced green fluorescent protein (eGFP) as gene reporter. GFP detection was evaluated in vitro (in transduced non-megakaryocitc blood cell progenitors and in-vitro differentiated megakaryocytes) and in vivo (Bone marrow cells, blood cells and spleen cells). For targeting of proteins to the secretory alpha granules of megakaryocytes and platelets, we followed two strategies: A) The sorting signal of the cytokine RANTES was fused N-terminally to the destabilized GFP, d2eGFP (RANTES. d2eGFP), to deliver the protein into the granules as soluble cargo. B) The transmembrane granular targeting sequence of P-selectin (the transmembrane domain and cytoplasmic tail (referred as TDCT) was fused to d2eGFP or the B domain deleted codon optimized human coagulation Factor VIII cDNA (referred as BDcohFVIII_TDCT or FVIII_TDCT), to deliver the protein into the membrane of alpha granules. These two strategies were tested in-vitro, from transduced differentiated megakaryocytes in liquid cultures, and in-vivo, by analysis of genetically modified platelets by means of Laser Scanning Confocal Microscopy (LSM) in colocalization analysis (performed at the single cell level) and fluorescence intensity analysis.
RESULTS: GFP expression in blood cells from transplanted mice was significantly higher in platelets, with a smaller background promoter activity in leukocytes and erythrocytes. The highest expression was observed from the mPf4-vector, followed by hGP1BA, hGP6 and hGP6s vectors, identifying the hGP6 vectors as the most restricted to the megakaryocyte and platelet lineage. Analysis in bone marrow cells showed that hGP6-vectors have the lowest activity in the hematopoietic stem and progenitor cells (HSPC) with less than 10% of GFP positive stem cells. Surprisingly, the mPf4 and hGP1BA vectors were both highly active in the HSPC, in a range of 20 to 70% of GFP-positive cells. Polyploidization in later stages of MK-maturation of in-vitro Mks differentiated from Mpl-/- lineage marker negative cells were recovered after gene transfer of the thrombopoietin receptor Mpl, under the control of MK-specific vectors in differentiated into MKs. These results were corroborated in in-vivo analysis, where Mpl-/- mice transplanted with lin-BM cells transduced with the mPf4.Mpl and hGP6.Mpl vectors, showed significantly elevated platelet counts compared to control mice transplanted with a GFP-encoding control vector (PGK-GFP). In the Fluorescent intensity and colocalization analysis of transduced megakaryocytes with the targeting vectors, we observed a significant difference in the GFP targeting compared with those MK transduced with the non-targeting vectors. The median of the WCC values observed from the RANTES.d2eGFP targeting vector was 0.8 (80 % of colocalization) with P-selectin stained granules, and 0.7 (70%) with von Willebrand Factor stained granules. In the case of the non-targeting vector SFFV.d2eGFP the median of the WCC observed were <0.3 (30%) both in P-selectin and von Willebrand Factor stained granules. We observed as well that the GFP signal of MK transduced with the P-selectin.d2eGFP fusion overlapped the signals emitted by P-selectin and von Willebrand factor stained granules, not just in LSM-digitalized images but in the fluorescens intensity analysis as well, indicating a clear signal of GFP colocalization. Likewise, an evident signal overlap between the targeted FVIII (FVIII_TDCT) with the P-selectin / von Willebrand marker was observed. Colocalization and fluorescens intensity analysis performed on activated platelets from transplanted mice with the targeting vectors, corroborated what was previously observed in in-vitro megakaryocytes. The genetic modification of megakaryocyte and platelets will allow in the furture, not just the development of new generation of cells with advanced functions, but it will help us to elucidate new mechanisms and pathways of important cellular processes, by modifying cell function and cell interactions.
All lifeforms have to sense changes in their environment and adapt to possibly detrimental conditions. On a cellular level, the highly elaborate proteostasis network (PN) consisting of housekeeping and stress-induced proteins, confers this tolerance against stress and maintains cellular protein homoestasis. This is essential for survival, as an accumulation of stress-induced protein aggregation will eventually affect the functionality of crucial cellular components and ultimately lead to cell death. The guardians of this balance are the molecular chaperones and their activity-regulating co-haperones. They are engaged in all aspects of protein biogenesis, maintenance and degradation, especially during stress.
The heat shock proteins (HSPs) are the major chaperones in mammals and encompass constitutive and stress-induced isoforms. Among them, the HSP70 and the HSP90 family are the most abundant HSPs and their activity is involved in a great variety of homoestasis and stress-induced tasks.
As part of the protein triage the E3 ligase CHIP (C-terminal HSC70-interacting protein) is an essential activity regulating co-chaperone of HSP70 and HSP90 which provides a link between chaperone mediated protein-folding and various degradation pathways. Due to its decisive function, CHIP is involved in a wide array of cellular processes, especially in clearing misfolded HSP70 client proteins that are prone to aggregate. As a consequence, CHIP was reported to confer protection against many aggregation-induced pathologies of the neuronal system. Additionally, CHIP has been identified as a critical factor in various types of cancer and is implied to affect the development and the longevity of mammals.
Despite the significant progress in the understanding of CHIP’s structure and function, many aspects surrounding its chaperone dependency and its substrate recognition remain unclear. Moreover, due to the variety of substrates in diverse cellular pathways, there are yet many connections to elucidate between CHIP and components of the cellular proteostasis network.
The work of this thesis was focused on the role of CHIP in acute stress response and the corresponding status of chaperone association. Moreover, it was investigated if CHIP, as the connecting ligase of folding and degradation systems, might also provide a link between the PN and the reorganisation of the cellular architecture upon stress exposure.
This has become of increasing interest as recent reports highlight the importance of spatial sequestration in protein quality control.
To this end, subcellular distribution of CHIP was analysed by live-cell microscopy during heat stress. It became obvious that during the heat-induced challenge of the chaperone system, CHIP migrated to new cellular sites. Further experiments suggested that the observed migration to the plasma membrane is a chaperone-independent process and in vitro reconstitution of membrane association confirmed the competitive nature of membranes and chaperones for CHIP binding. A detailed in vivo and in vitro analysis of the newly observed membrane association of CHIP revealed a distinct lipid specificity and a novel direct association with lipids. Binding experiments with recombinantly purified deletion mutants of CHIP identified the TPR domain and a positive patch in the coiled-coil domain as main determinants for the lipid association. Through biochemical and biophysical approaches, the structural integrity and functionality of CHIP upon membrane binding was confirmed and further characterised.
Moreover, mass spectrometry analysis provided a high confidence identification of chaperone-free interactors of CHIP at the plasma membrane and other membranous compartments.
In accordance with the lipid specificity, the Golgi apparatus was one of these sites. Only chaperone-free CHIP had a significant effect on the morphology of the organelle, again confirming the competitive role of chaperones and lipids. With respect to the physiological consequences of the changed localisation of CHIP, preliminary results indicated increased cell death when the ligase localises to cellular membranes. The results lead to the conclusion that CHIP acts as an initiator of early stress adaptation and as a sensor for the severity and strength of the stress reaction.
Viele Studien konnten in den letzten Jahren aufzeigen, dass Stickstoffmonoxid (NO)/cGMP-Signaling eine wichtige Rolle in der Verarbeitung chronischer Schmerzprozesse einnimmt. Bei Verletzung peripherer Nerven oder Entzündung im Gewebe wird NO gebildet, das durch Stimulation der NO-sensitiven Guanylatzyklase (NO-GC) die cGMP-Bildung katalysiert. Seit einigen Jahren ist bekannt, dass zwei Isoformen dieses Enzyms existieren, NO-GC1 und NO-GC2. Das Expressionsmuster der beiden Isoformen im nozizeptiven System und der jeweilige Einfluss auf die Schmerzverarbeitung ist jedoch bisher völlig unbekannt. In dieser Arbeit wurde die Expression der NO-GC1 und NO-GC2 in den Spinalganglien (DRGs) und im Rückenmark von Mäusen charakterisiert und das Verhalten von NO-GC1 und NO-GC2 Knockout (KO)-Mäusen in verschiedenen Schmerzmodellen untersucht. Mit Immunfluoreszenzfärbungen und In-situ-Hybridisierungen wurde in dieser Arbeit dargestellt, dass die zwei Isoformen in Interneuronen des Rückenmarks lokalisiert sind, wobei die NO-GC1 vorwiegend in inhibitorischen Interneuronen exprimiert wird. In den DRGs konnte die Expression in nicht-neuronalen Zellen nachgewiesen werden, wobei nur die NO-GC2 in Satellitenzellen detektiert werden konnte. Die NO-GC1 KO-Mäuse zeigten eine verringerte mechanische Hypersensitivität in neuropathischen Schmerzmodellen, aber ein normales Verhalten in Modellen inflammatorischer Schmerzen. Im Gegensatz zu diesen Ergebnissen zeigten die NO-GC2 KO-Mäuse ein erhöhtes Schmerzverhalten in Entzündungsmodellen, aber kein verändertes Verhalten in Modellen neuropathischer Schmerzen. Die gezielte Deletion der NO-GC1 und NO-GC2 in Interneuronen des Rückenmarks führte in den entsprechenden Tieren zu Verhaltensänderungen in der Schmerzwahrnehmung, die den Phänotypen der globalen NO-GC KO-Tieren in Schmerzmodellen ähnelte. Zusammengefasst zeigen die Daten dieser Arbeit, dass die NO-GC1- oder NO-GC2-vermittelte cGMP-Produktion in Interneuronen des Rückenmarks sehr wichtige, und teilweise gegensätzliche Funktionen bei der Verarbeitung chronischer Schmerzsignale einnimmt.
Im Rahmen dieser Arbeit sollte der tonische BZR-Signalweg im Burkitt Lymphom näher untersucht werden. Ziel war die Identifizierung von Zielstrukturen, die für die Zellen essentiell für die Aufrechterhaltung des tonischen Signalwegs sind und gleichzeitig die Viabilität der Zellen fördern. Durch die Identifizierung noch unbekannter Zielstrukturen wäre man in der Lage, neue Behandlungsstrategien zu entwickeln oder bereits bestehende zu optimieren. Des Weiteren sollte die Signaltransduktion in der B-ALL, die über einen Vorläufer des BZRs, dem prä-BZR vermittelt wird, hinsichtlich eines tonischen Überlebenssignals untersucht werden.
Durch massenspektrometrische Analysen der tonischen BZR-Signaltransduktion im Burkitt Lymphom, die für die Viabilität der Zellen essentiell ist und die Ergebnisse eines Inhibitorscreens konnte HSP90 als potenzielle neue Zielstruktur im Burkitt Lymphom identifiziert werden.
So konnte gezeigt werden, dass Burkitt-Lymphom-Zellen nach Inhibition der Chaperonfunktion von HSP90 durch zwei auf dem Markt bereits verfügbare Inhibitoren einen Zellzyklusarrest erfahren, der letztlich zur Apoptose der Zellen führt. Dieser Effekt wurde auf einen Verlust des (tonischen) BZR-Signals zurückgeführt, der überwiegend durch den aktiven lysosomalen Abbau von SYK nach HSP90-Inhibition zustande kommt. Demnach führte die Überexpression einer HSP90-resistenten Variante von SYK (TEL-SYK) zu einer Aufhebung der apoptotischen Effekte nach HSP90-Inhibition. Zudem wurde SYK als Interaktionspartner von HSP90 (HSP90-Klientprotein) im Burkitt Lymphom und die für die Interaktion essentielle Phosphorylierungsstelle (pY197 in HSP90α bzw. pY192 in HSP90β) identifiziert bzw. validiert.
Das therapeutische Potenzial der HSP90-Inhibitoren im Burkitt Lymphom offenbarte sich ferner durch den Vergleich der Wirkungseffektivität in gesunden B-Zellen mit der in Tumorzellen. So zeigten HSP90-Inhibitoren eine erhöhte Affinität zu Tumorzellen. Bei verwendeten Konzentrationen der Inhibitoren, die bereits eine apoptotische Wirkung in Tumorzellen hervorriefen, waren gesunde B-Zellen resistent.
In der B-ALL konnte durch den Knockdown von CD79a und der Inhibition von SYK eine tonische Antigenrezeptor-Signalleitung identifiziert werden, die wie im Burkitt Lymphom über den PI3K/AKT-Signalweg vermittelt wird. Durch die Kombination der im Rahmen dieser Arbeit gewonnen Erkenntnisse und weiterführende Analysen (wie zum Beispiel durch Inhibitor- oder CRISPR/Cas-Screens) kann so eine Identifizierung von potenziellen Zielstrukturen mit therapeutischem Nutzen in der B-ALL erfolgen.
Zur Behandlung von chronisch entzündlichen Erkrankungen besteht nach wie vor ein dringendes medizinisches Bedürfnis, da die bisher eingesetzten Medikamente gerade in der Langzeittherapie zu schwerwiegenden Nebenwirkungen führen können. Um chronisch entzündliche Erkrankungen in Zukunft adäquat therapieren zu können, sind bereits verschiedene neuartige Ansätze in klinischer bzw. präklinischer Entwicklung. Ein möglicher Ansatz besteht in einer dualen Hemmung der mikrosomalen Prostaglandin E2 Synthase-1 (mPGES-1) und der 5-Lipoxygenase (5-LO). Im Rahmen dieser Arbeit wurden die Struktur-Wirkungs-Beziehungen (SAR) von zwei verschiedenen Leitstrukturen an der 5 LO und der mPGES 1 untersucht. Die erste Leitstruktur entstammt aus den Arbeiten von Waltenberger et al. und besitzt im Grundgerüst eine Sulfonamidstruktur. In dieser Arbeit ist es gelungen, durch eine gezielte Untersuchung der Struktur-Wirkungsbeziehungen, die Leitstruktur I an der 5 LO und der mPGES-1 in ihrer Potenz zu optimieren. Die Leitstruktur (IC50: 5-LO (zellfrei) = 5.7 µM, IC50: 5 LO (PMNL) = 3.7 µM, IC50: mPGES-1 = 4.5 µM) konnte durch Variation in allen drei Positionen modifiziert werden, so dass die optimierte Struktur 170 (IC50: 5-LO (zellfrei) = 2.3 µM, IC50: 5-LO (PMNL) = 0.4 µM, IC50: mPGES-1 = 0.7 µM) entstanden ist. Für die Verbindung 170 wurden die pharmakokinetischen Eigenschaften, wie Löslichkeit und metabolische Stabilität, sowie der Wirkmechanismus auf molekularer Ebene bestimmt. Ebenso konnte für Verbindung 170 auch in vivo anti-entzündliche Eigenschaften festgestellt werden.
Die zweite Leitstruktur stammt ebenfalls aus den Arbeiten von Waltenberger et al. und besitzt im Grundgerüst eine Mercaptobenzothiazol-Grundstruktur. Aufgrund der Ähnlichkeit zu den bekannten Pirinixinsäurederivaten wurde auch hier für die Untersuchung der Struktur-Wirkungs-Beziehungen zunächst eine Kettenverlängerung an der Alkylkette vorgenommen. Es ließ sich auch hier durch eine gezielte SAR, die Leitstruktur bis hin zum submikromolaren Bereich in Verbindung 219 optimieren. Gleichzeitig ist es gelungen in Verbindung 219 einer der am potentesten dual ausgeglichensten dualen 5 LO/mPGES-1 Inhibitoren zu identifizieren.
Zusammenfassend lässt sich sagen, dass in dieser Arbeit es gelungen ist durch gezielte Untersuchungen der Struktur-Wirkungs-Beziehungen zwei verschiedene Substanzklassen zu dualen 5-LO/mPGES-1 Inhibitoren zu optimieren. Ebenso konnte für Substanz 170 auch in vivo anti-entzündliche Eigenschaften festgestellt werden. Diese Arbeit soll dazu beitragen, das therapeutische Potential von dualen 5-LO/mPGES-1 Inhibitoren als anti-entzündliche Wirkstoffe in Zukunft besser einschätzen zu können.
Translation is a universal process in all kingdoms of life and organized in a cycle that requires ribosomal subunits (40S and 60S), messenger RNA (mRNA), aminoacylated transfer RNAs (tRNAs), and a myriad of regulatory factors. As soon as translation reaches a stop codon or stalls, a termination or surveillance process is launched via release factors eRF1 or Pelota (Dom34), respectively. The ATP-binding cassette (ABC) protein ABCE1 interacts with release factors at the ribosomal A-site and coordinates the recycling process in Eukarya and Archaea. Two asymmetric nucleotide-binding sites (NBSs) control and execute the ribosome splitting upon dimerization and closure of the two nucleotide-binding domains (NBDs).
Ribosome nascent chain complexes (RNCs), ABCE1, and Dom34 from S. cerevisiae were produced for the reconstitution of splitting assays in order to probe for ABCE1’s actions in the splitting process with its native substrate. Translating ribosomes were stalled in vivo in a no-go situation on truncated mRNAs by a 3´-ribozyme motif that generates truncated mRNAs. The initiated decay mechanisms were circumvented by genomic deletion of the release factor Dom34 (Pelota) of the no-go decay machinery. The mRNA coded for an N terminal affinity purification tag (His-tag) and the green fluorescent protein (GFP) as a reporter of the translated nascent chain in the ribosomal complexes. RNCs were successfully in vivo stalled, enriched, and purified. In native gels, the reconstituted splitting experiments were analyzed by separation of RNCs, ribosomal subunits, and nascent chain-tRNA complexes based on the fluorescence readout of the GFP reporter. In addition, the anti-association factor eIF6 was added in the splitting reaction because it blocks the immediate re-association of ribosomal subunits after splitting. The anti-association activity of eIF6 was probed by an anti-/re-association assay, in which ribosomes are anti-associated by high salt and low magnesium conditions and in a second step re-associated. The re-association can be blocked by binding of eIF6 and other anti-associating factors to the ribosomal intersubunit sites. This approach allowed for the discovery of an anti-association activity of ABCE1 that was dependent on the non-hydrolysable ATP analog AMP-PNP. In addition, the formed complex between 40S and ABCE1 represented formally a post-splitting intermediate.
In collaboration with the Beckmann lab, the structure of the post-splitting complex was reconstructed at 3.9 Å. The ABC system of ABCE1 is fully closed and its N-terminal iron-sulfur (FeS) cluster domain is rotated by 150-degree to a cleft at helix 44 and uS12. The FeS cluster domain is stabilized by interactions of Pro30 to uS12, Arg7 to helix 5, and the cantilever arm that links it to NBD1. Tyr301 of NBD1 stabilizes the FeS cluster domain in the rotated position by interaction to the backbone of the cantilever arm. Upon transition to the post-splitting state, the FeS cluster domain must clash with the release factor and push it in between the ribosomal subunits like a wedge and split the ribosome. In addition, in the post-splitting state, the FeS cluster domain would putatively clash with uL14 of the large ribosomal subunit, and this is the structural explanation for the anti-association effect of ABCE1. In Archaea, a similar conformation of the post-splitting complex was reconstructed in collaboration with the Beck and Beckmann labs and Kristin Kiosze-Becker and Elina Nürenberg-Goloub. Based on the high-resolution structure of the post-splitting complex, the post-splitting state of ABCE1 was identified in the 43S initiation complex 40S–ABCE1–tRNA–eIF2–eIF3. Subsequently, we proposed the post-splitting complex as a platform for initiation.
In the quest to elucidate conformational dynamics of ABCE1, a reconstituted system was established to study conformational dynamics in real-time. Single-molecule Förster resonance energy transfer (smFRET) was used for the relative distance detection between a donor and acceptor fluorophore. A cysteine-less ABCE1 variant was engineered with additional cysteines for fluorescent labeling by thiol-maleimide-coupling. In collaboration with Philipp Höllthaler, the double-cysteine variants were labeled for smFRET studies and alternating-laser excitation (ALEX) smFRET measurements were performed with ABCE1 and the small ribosomal subunit. ABCE1’s nucleotide-dependent NBD dimerization and FeS cluster domain rotation was determined in real-time. Finally, a higher opening and closing frequency of the NBDs was discovered than the determined ATPase rate. This observation could be explained by the hypothesis of elastic dimerization that is not immediately connected to ATP hydrolysis.
The multistep-processes leading to the formation of tumors have been extensively studied in the past decades, leading to the identification of “hallmarks of cancer”. They are characteristic changes in biological processes that discriminate tumor cells from healthy cells. Increasing knowledge on the molecular structures associated with tumorigenesis allowed their specific inhibition in targeted anti-cancer therapy. However, successful targeted anti-cancer therapy is only available for a limited subset of diseases, so the continuous investigation of tumorigenic mechanisms is required to tackle the immense diversity of neoplastic entities.
AVEN and FUSE binding protein 1 (FUBP1) display the ability to regulate apoptosis and cell cycle progression. Thus, the proteins are associated with hallmarks of cancer (resisting cell death and uncontrolled proliferation). Indeed, aberrant expression of AVEN and FUBP1 could be demonstrated in multiple cancers. In contrast, there is only little knowledge on the physiological function of AVEN and FUBP1. The lack of knowledge results in part from the embryonic lethality of the homozygous knockout of Aven and Fubp1 in mouse models, limiting the gain of information by analyzing these animals.
In this study, I generated conditional Aven and Fubp1 knockout mice to investigate their physiological function.
By analyzing reporter mice expressing β-galactosidase under the control of the endogenous Aven promoter, I identified Aven promoter activity to be both tissue- and cell type-specific and dependent on the developmental stage. Detecting apoptotic cell death by immunohistochemistry did not reveal increased apoptosis in Aven knockout mice, suggesting a functional role of AVEN besides apoptosis inhibition during embryogenesis.
Basing on the significant Aven promoter activity detected in the adult brain and in the mammary gland, I generated and characterized conditional Aven knockout mice with Aven deletion restricted to cells within the brain or the mammary gland. AVEN depletion in these tissues was not embryonic lethal and the affected tissues displayed a normal histology.
Since aberrant Aven expression had been associated with hematologic malignancies, I also analyzed mice with an Aven knockout in the hematopoietic system. Depletion of AVEN in the blood cells had no effect on hematopoietic stem and progenitor cell frequencies. Consequently, AVEN seems to be dispensable for the maintenance and differentiation of stem, progenitor and mature blood cells, at least as far as the expression of particular differentiation markers was concerned.
As loss of AVEN in the analyzed tissues did not affect the viability of mice and did not produce any other obvious phenotype, the exact role of AVEN that is essential for embryo survival remains to be identified.
To study the oncogenic potential of AVEN, I investigated the role of AVEN in a mouse model for breast carcinogenesis. While AVEN expression seemed to be increased in breast tumors, tumor onset and progression were not altered in mice with depleted AVEN expression in the mammary gland. Consistently, Aven knockout tumor cells were neither less proliferative nor more prone to undergo apoptosis than Aven wildtype tumor cells. Cell culture experiments demonstrated that AVEN expression is upregulated by estrogen. Knockdown of AVEN in the breast cancer cell line MCF-7 slightly increased UV irradiation-induced apoptosis and accelerated metabolism. So while AVEN does not promote development or progression of breast tumors, enhanced AVEN expression in ER+ breast cancers might contribute to chemotherapy resistance.
To study the physiological role of FUBP1, I generated a conditional Fubp1 knockout mouse model. While the insertion of loxP sites into the Fubp1 locus was occasionally embryonic lethal, some mice with a cell type-specific deletion of Fubp1 in hematopoietic cells or EPO receptor expressing cells were born alive. In these mice, frequencies of hematopoietic stem and progenitor cells as well as erythrocytes were unaltered. These results conflict with previous publications. However, compensating mechanisms might be responsible for the discrepancies between the observed phenotypes and reported FUBP1 function.
In cell culture studies, I could demonstrate that the previously reported upstream regulation of FUBP1 by TAL1 depended on an intact GATA motif in the FUBP1 promoter and that binding of GATA1 to the FUBP1 promoter increased during erythropoiesis.
To identify new FUBP1 target genes with relevance for erythropoiesis, I performed differential gene expression analysis in cells with wildtype and depleted FUBP1 expression. RNA-sequencing and PCR-arrays revealed only moderate differences in the expression of genes that are components of the EPO receptor signaling pathway as well as genes associated with apoptosis and proliferation of hematopoietic cells. By regulating the transcription of these genes, FUBP1 could contribute to efficient erythropoiesis.
Die Steuerung biochemischer Prozesse oder die Verbesserung von Materialien erfordert zunächst ein tiefgründiges Verständnis über die zugrundeliegenden Systeme. Zur Untersuchung eignet sich Licht als ideales Werkzeug, da hiermit nützliche Informationen über die chemische Struktur, ihre Eigenschaften sowie den zusammenhängenden, schnellen Reaktionsabläufen erhalten werden können. Um die Aufklärung zu erleichtern können kleine, chemische Verbindungen eingeführt werden, welche beispielsweise ein Fluoreszenzmarker, eine photolabile Schutzgruppe oder eine photoschaltbare Verbindung sein können. Von jeweils einem Vertreter dieser Moleküle wurden unterschiedliche Studien durchgeführt, dessen Ergebnisse in dieser Arbeit in insgesamt drei Projekten zusammengefasst werden.
Zunächst wurde die Funktionalität der Helikase RhlB untersucht, die der Familie der DEAD-Box Proteine zugeordnet wird, und RNA-Duplexe in ihre Einzelstränge entwindet. Als RNA-Modellduplex diente JM2h, an dem ein RNA-Einzelstrang fluoreszenzmarkiert war (M2AP6). Die Einführung dieses Markers ermöglichte die Durchführung von statischen Fluoreszenzmessungen sowie von Mischexperimenten, die mit Hilfe der stopped-flow-Technik durchgeführt wurden. In den einleitenden Studien wurde die Helikase weggelassen, wodurch der Fokus auf den Fluoreszenzeigenschaften der RNA gelegt wurde. Die Ergebnisse hierzu zeigten, dass die Fluoreszenzintensität des Einzelstrangs durch Zugabe des komplementären Strangs deutlich abnimmt, wobei das Minimum bei einem äquimolaren Verhältnis erreicht wird. Die dazugehörigen stopped-flow-Messungen zeigten eine Beschleunigung der Hybridisierungsreaktion, wenn höhere Konzentrationen des Gegenstrangs in der Lösung vorhanden waren. Nach anschließender Zugabe der Helikase zur Lösung wurde ein Anstieg der Fluoreszenzintensität erwartet, der vom separierten Einzelstrang M2AP6 herrühren sollte. Dieser Anstieg wurde jedoch erst nach weiterer Zugabe von ATP beobachtet, der auf eine ATP-Abhängigkeit der Entwindungsreaktion von RhlB hindeutet. Diese Abhängigkeit wurde auch bereits für andere Helikasen der DEAD-Box Familie entdeckt. Die korrekte Funktionalität sowie die ATP-Abhängigkeit wurden in stopped-flow-Messungen verfiziert, bei denen der Fluoreszenzanstieg auch zeitaufgelöst betrachtet werden konnte. Für die spektralen Korrekturen der Fluoreszenzspektren wurde ein selbstgeschriebenes MATLAB-Programm namens FluCY verwendet (engl.: Fluorescence Correction & Quantum yield), welches eine schnelle und fehlerfreie Verarbeitung des Datensatzes ermöglichte.
Die zwei im folgenden beschriebenen Projekte handeln von photoaktivierbaren Molekülen. Zum einen photolabile Verbindungen, welche die Funktion z.B. eines Biomoleküls durch eine chemische Modifikation deaktivieren können. Durch eine lichtinduzierte Reaktion kommt es zur Abspaltung der Modifikation und die Funktion ist wiederhergestellt. In dieser Arbeit wurden verschiedene photolabile Schutzgruppen untersucht, die denselben Chromophor BIST (BIsStyryl-Thiophen) tragen. Durch die Einführung dieses Chromophors absorbierten sämtliche untersuchte Verbindungen sehr effizient sichtbares Licht (epsilon(445)=55.700 M^(-1) cm^(-1)), wodurch der photoinduzierte Bindungsbruch mit Wellenlängen durchgeführt werden, die bei einer biologischen Anwendungen keinen Schaden an der Zelle anrichten würden. Hieraufhin wurden in statischen und zeitaufgelösten Absorptionsmessungen Teilschritte der Freisetzungsreaktion untersucht, indem nach Photoanregung die Absorptionsänderungen auf verschiedenen Zeitskalen analysiert wurden. Die ultraschnelle Dynamik im Piko- bis Nanosekundenbereich (10^(-12)-10^(-9) s) wird durch eine spektral breite, positive Absorptionsänderng dominiert. Diese impliziert, dass die Deaktivierung über den Triplettpfad abläuft, der die vergleichsweise niedrigen Freisetzungsausbeuten erklärt (phi(u) < 5). Aufgrund des hohen Extinktionskoeffizienten reichen dennoch bereits niedrige Strahlungsdosen aus, um eine Freisetzung zu initiieren. Der geschwindigkeitsbestimmende Schritt dieser Reaktion ist dem Zerfall des aci-nitro Intermediats zugeordnet. Für ein sekundäres Amin, welches mit BIST geschützt wurde, ist eine Lebensdauer des Intermediats von 71 µs gefunden worden.
In einigen Fällen ist es erwünscht, eine vorliegende Aktivität nicht nur ein-, sondern auch ausschalten zu können, wofür photochrome Verbindungen (oder Photoschalter) verwendet werden. Die in dieser Arbeit untersuchte Verbindung ceCAM ist ein Alken-Photoschalter und vollführt bei Bestrahlung mit Licht eine cis/trans-Isomerisierung. ceCAM ist das Cyanoester-Derivat (ce) von Cumarin-substituierten Allylidenmalonat, von denen beide Konformere sehr effizient sichtbares Licht absorbieren trans: epsilon(489)=50.300 M^(-1) cm^(-1); cis: epsilon(437)=18.600 M^(-1) cm^(-1)). Andere photophysikalische Eigenschaften umfassen u.a. hohe thermische und photochemische Stabilität. Letztere wurde über ein Experiment nachgewiesen, bei dem die lichtinduzierte Isomerisierung alternierend durchgeführt wurde und selbst bei über 250 Zyklen keine signifikate Abnahme der Absorption beobachtet werden konnte. Des Weiteren konnte die Reaktion mit Quantenausbeuten von 39% (trans) und 42% (cis) induziert werden, wobei im photostationären Gleichgewicht auch hohe Isomerenverhältnisse mit bis zu 80% (trans) und 96% (cis) akkumuliert werden konnten. Die Geschwindigkeit der Reaktion wurde mit Hilfe der Ultakurzzeit-Spektroskopie untersucht. Die Dynamik im Zeitbereich von ps-ns zeigte, dass die trans/cis-Isomerisierung unterhalb von 0,5 ns und die umgekehrte Reaktion noch viel schneller (wenige ps) abgeschlossen ist. Durch die Untersuchungen in dieser Arbeit an den BIST-Verbindungen und ceCAM sind viele vorteilhafte, photophysikalische Eigenschaften charakterisiert worden, wodurch sie als verbesserte Alternative zu den bisher bekannten photolabilen Schutzgruppen oder Photoschaltern anzusehen sind.