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Bei der UV-Bestrahlung von Uracil-[5.6-3H] bilden sich je nach eingestrahlter Energie dimeres Uracil und Uracil-Wasseranlagerungsprodukt [5.6-Dihydro-6-hydroxyuracil] als radioaktive Photoprodukte. Während bei der Synthese des Wasseranlagerungsproduktes ein beträchtlicher sekundärer Isotopeneffekt wirksam wird, verändert sich die Radioaktivität des dimeren Uracils gegenüber der des Ausgangsuracils kaum.
Wird das Wasseranlagerungsprodukt durch Erwärmen zu Uracil zurückgewandelt, so dehydratisiert das Molekül ebenfalls unter Mitwirkung eines Isotopeneffektes. Wird das Uracildimere zu Uracil rückgewandelt, so beobachtet man keinen Isotopeneffekt.
Bei der Bestrahlung von Uracil in Tritium-haltigem Wasser werden nur sehr geringe Radioaktivitäten in die Photoprodukte eingebaut. Der Isotopeneffekt beträgt ca. 8. — Durch Synthese der Photoprodukte aus spezifisch an C-5 oder C-6 Tritium-markiertem Uracil bzw. durch Bromierung von 5.6-Tritium-markiertem Uracil bzw. dessen Photoprodukten zu den 5-Brom-Derivaten erhält man Hinweise, daß der Geschwindigkeits-bestimmende Schritt der Wasseraddition an C-6 des Uracils verläuft. Die inversen sekundären Isotopeneffekte betragen für Tritium an C-6 etwa 0,65, für Tritium an C-5 dagegen nur 0,95.
Multiple resistance and pH adaptation (Mrp) cation/proton antiporters are essential for growth of a variety of halophilic and alkaliphilic bacteria under stress conditions. Mrp-type antiporters are closely related to the membrane domain of respiratory complex I. We determined the structure of the Mrp antiporter from Bacillus pseudofirmus by electron cryo-microscopy at 2.2 Å resolution. The structure resolves more than 99% of the sidechains of the seven membrane subunits MrpA to MrpG plus 360 water molecules, including ~70 in putative ion translocation pathways. Molecular dynamics simulations based on the high-resolution structure revealed details of the antiport mechanism. We find that switching the position of a histidine residue between three hydrated pathways in the MrpA subunit is critical for proton transfer that drives gated trans-membrane sodium translocation. Several lines of evidence indicate that the same histidine-switch mechanism operates in respiratory complex I.
Multiple resistance and pH adaptation (Mrp) cation/proton antiporters are essential for growth of a variety of halophilic and alkaliphilic bacteria under stress conditions. Mrp-type antiporters are closely related to the membrane domain of respiratory complex I. We determined the structure of the Mrp antiporter from Bacillus pseudofirmus by electron cryo-microscopy at 2.2 Å resolution. The structure resolves more than 99% of the sidechains of the seven membrane subunits MrpA to MrpG plus 360 water molecules, including ∼70 in putative ion translocation pathways. Molecular dynamics simulations based on the high-resolution structure revealed details of the antiport mechanism. We find that switching the position of a histidine residue between three hydrated pathways in the MrpA subunit is critical for proton transfer that drives gated transmembrane sodium translocation. Several lines of evidence indicate that the same histidine-switch mechanism operates in respiratory complex I.
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.
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The vascular endothelium is a monolayer of endothelial cells that builds the inner lining of the blood vessels and constitutes a regulatory organ within the physiological system to sustain homeostasis. Endothelial cells participate in physiological processes including inflammation and angiogenesis. Dysregulation of these processes, however, can evoke or maintain pathological disorders, including cardiovascular and chronic inflammatory diseases or cancer. Although pathological inflammation and angiogenesis represent treatable conditions, current pharmacotherapeutic approaches are frequently not satisfying since their long-term application can evoke therapy resistance and thus reduced clinical efficacy. Consequently, there is an ongoing demand for the discovery of new therapeutic targets and drug leads. Considering that endothelial cells play a critical role in both angiogenesis and inflammation, the vascular endothelium represents a promising target for the treatment of diseases.
Vioprolide A is a secondary metabolite isolated from the myxobacterium Cystobacter violaceus Cb. vi35. Recently, vioprolide A was identified to interact with NOP14, a nucleolar protein involved in ribosome biogenesis. Ribosome biogenesis is an indispensable cellular event that ensures adequate homeostasis. Abnormal alterations in the ribosome biogenesis, referred to as ribosomopathies, however, can lead to an overall increase in the risk of developing cancer. Accordingly, several studies have outlined the involvement of NOP14 in cancer progression and metastasis, and vioprolide A has been demonstrated to exert anti-cancer effects in vitro. However, the impact of vioprolide A and NOP14 on the endothelium has been neglected so far, although endothelial cells are crucially involved in inflammation and angiogenesis under both physiological and pathological conditions.
In the present study, the effect of vioprolide A on inflammatory and angiogenic actions was analysed. In vivo, the laser-induced choroidal neovascularization (CNV) assay outlined a strong inhibitory effect of vioprolide A on both inflammation and angiogenesis. Furthermore, intravital microscopy of the cremaster muscle in mice revealed that vioprolide A strongly impaired the TNF-induced leukocyte-endothelial cell interaction in vivo.
In further experiments, the specific effect of vioprolide A on activation processes of primary human umbilical vein endothelial cells (HUVECs) was examined. According to the in vivo results, vioprolide A decreased the leukocyte-endothelial cell interaction in vitro through downregulating the cell surface expression and total protein expression of ICAM-1, VCAM-1 and E-selectin. Vioprolide A evoked its anti-inflammatory actions via a dual mechanism: On the one hand, the expression of pro-inflammatory proteins, including TNFR1 and cell adhesion molecules, was lowered through a general downregulation of de novo protein synthesis. The inhibition of de novo protein synthesis is most likely linked to the interaction with and inhibition of NOP14 by vioprolide A in HUVECs. On the other hand, the natural product prevented the nuclear translocation and promotor activity of the pro-inflammatory transcription factor NF-ĸB. Interestingly, most anti-inflammatory compounds that interfere with the NF-ĸB signaling pathway prevent NF-ĸB nuclear translocation through recovering or stabilizing the inhibitory IĸB proteins. Vioprolide A, however, decreased rather than stabilized the IĸB proteins and prevented NF-ĸB nuclear translocation through interfering with its importin-dependent nuclear import. By performing siRNA-mediated knockdown experiments, we evaluated the role of NOP14 in inflammatory processes in HUVECs and could establish a causal link between the anti-inflammatory actions of vioprolide A and the deletion of NOP14.
Besides exerting anti-inflammatory actions, we found that vioprolide A potently decreased the angiogenic key features proliferation, migration and sprouting of endothelial cells. Mechanistically, the natural product interfered with pro-angiogenic signaling pathways. Vioprolide A reduced the protein level of growth factor receptors, including VEGFR2, which is the most prominent receptor responsible for angiogenic signaling in endothelial cells. This effect was based on the general inhibition of de novo protein synthesis by the natural product. Downregulation of growth factor receptors impaired the activation of downstream signaling intermediates, including the MAPKs ERK, JNK and p38. To our surprise, however, activation of Akt, another downstream effector of VEGFR2, was increased rather than decreased. Furthermore, vioprolide A lowered the nuclear translocation of the transcriptional coactivator TAZ, which is regulated by the evolutionary conserved Hippo signaling pathway. Interestingly, however, and in contrast to NF-ĸB, TAZ nuclear translocation in mammalian cells seems to be independent of importins. In this context, we found that vioprolide A reduced both the protein level and nuclear localization of MAML1, which is needed to retain TAZ in the nucleus after its successful translocation.
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Pretubulysin (PT), a biosynthetic precursor of the myxobacterial compound tubulysin D, was recently identified as a novel microtubule-targeting agent (MTA) causing microtubule destabilization. MTAs are the most frequently used chemotherapeutic drugs. They are well studied regarding their direct cytotoxic effects against various tumors as well as for their anti-angiogenic and vascular-disrupting action addressing endothelial cells of the tumor vasculature. However, the impact of MTAs on endothelial cells of the non-tumor vasculature has been largely neglected, although tumor cell interactions with the healthy endothelium play a crucial role in the process of cancer metastasis. Besides their use as potent anti-cancer drugs, some MTAs such as colchicine are traditionally used or recommended for the therapy of inflammatory diseases. Here, too, the role of endothelial cells has been largely neglected, although the endothelium is crucially involved in regulating the process of inflammation.
In the present study, the impact of PT on tumor-endothelial cell interactions was therefore analyzed in vitro to gain insights into the mechanism underlying its anti-metastatic effect that was recently confirmed in vivo. In the second part of this work, the influence of PT and other MTAs, namely the microtubule-destabilizing compounds vincristine (VIN) and colchicine (COL) and the microtubule-stabilizing drug paclitaxel (PAC), on leukocyte-endothelial cell interactions was investigated in vitro and in vivo (only PT). It is important to mention that in all in vitro experiments solely endothelial cells and not tumor cells or leukocytes were treated with the MTAs to strictly focus on the role of the endothelium in the action of these compounds.
The impact of PT on tumor-endothelial cell interactions was analyzed in vitro by cell adhesion and transendothelial migration assays as well as immunocytochemistry using the breast cancer cell line MDA-MB-231 and primary human umbilical vein endothelial cells (HUVECs). The treatment of HUVECs with PT increased the adhesion of MDA cells onto the endothelial monolayer, whereas their transendothelial migration was reduced by the compound. Thereafter, the influence of PT on the endothelial cell adhesion molecules (CAMs) E-selectin, N-cadherin, ICAM-1, VCAM-1 and galectin-3 and on the CXCL12/CXCR4 chemokine system was examined, since they might be involved in the PT-triggered tumor cell adhesion. Interestingly, although PT induced the upregulation of ICAM-1, VCAM-1, N-cadherin and CXCL12, cell adhesion assays using neutralizing antibodies or the CXCL12 inhibitor AMD3100 revealed that all these molecules were dispensable for the PT-evoked tumor cell adhesion. As PT induces the formation of interendothelial gaps and MDA cells might adhere onto components of the underlying extracellular matrix (ECM), the precise location of MDA cells attached to the PT-treated endothelial monolayer was investigated. Instead of a direct interaction between tumor and endothelial cells, this work showed that MDA cells preferred to adhere to the ECM component collagen that was exposed within PT-triggered endothelial gaps. Both the PT-evoked increase in tumor cell adhesion onto and the decrease in trans-endothelial migration were completely abolished when β1-integrins were blocked on MDA cells. Similar results were obtained when endothelial cells were treated with VIN and COL but not PAC, indicating that the observed effects of PT depend on its microtubule-destabilizing activity.
The impact of PT, VIN, COL and PAC on leukocyte-endothelial cell interactions was analyzed in vivo (only PT) by intravital microscopy of the mouse cremaster muscle and in vitro by cell adhesion assays using the monocyte-like cell line THP-1 and TNFα-activated human dermal microvascular endothelial cells (HMEC-1). While PT did not affect the rolling of leukocytes on the endothelium, their firm adhesion onto and transmigration through the activated endothelium was reduced by PT in vivo. In accordance, the treatment of HMEC-1 with PT, VIN and COL decreased the TNFα-induced adhesion of THP-1 cells onto the endothelial monolayer, whereas PAC had no influence on this process. Thereafter, the influence of PT, VIN, COL and PAC on endothelial ICAM-1 and VCAM-1 was examined, since these molecules are substantially involved in the firm adhesion of leukocytes onto the endothelium. The cell surface protein expression of ICAM-1 and VCAM-1 was reduced by PT, VIN and COL in activated endothelial cells, whereas PAC did only slightly affect the TNFα-induced upregulation of VCAM-1. As the pro-inflammatory transcription factor NFκB plays a crucial role in the TNFα-induced expression of these CAMs, the impact of the MTAs on the NFκB promotor activity was investigated. While PT, VIN and COL decreased the activation of NFκB in activated endothelial cells, PAC did not affect this process. However, in contrast to the strong effects regarding the cell surface protein expression of ICAM-1 and VCAM-1, the effects of PT, VIN and COL on the NFκB activity was rather low. Thus, the used MTAs might also affect other relevant signaling pathways and/or the intracellular transport of CAMs might be influenced by the impact of the MTAs on the microtubule network.
Taken together, the current study provides – at least in part – an explanation for the anti-metastatic potential of PT and gives first insights into the use of PT and VIN as anti-inflammatory drugs. Moreover, this work highlights the endothelium as an attractive target for the development of new anti-cancer and anti-inflammatory drugs.
This dissertation contains two chapters. Each chapter covers a unique topic within RNA sci-ence 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 mech-anistic 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 se-quences with single nucleotide precision triggered by an external stimulus. This design strat-egy was used to establish a ROI release system and its powerful performance in in vitro and in vivo applications was shown.
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.
Investigation of co-translational protein folding using cryo-EM and solid-state NMR enhanced by DNP
(2020)
Die zelluläre Proteinbiosynthese findet am Peptidyltransferase-Zentrum innerhalb der großen ribosomalen Untereinheit statt. Die neu synthetisierte Polypeptidkette passiert den ribosomalen Exit-Tunnel, der 80-100 Å lang und 10-20 Å breit ist. Proteinfaltung findet kotranslational statt, während die Peptidkette durch den ribosomalen Tunnel geschleust wird. Zu welchem Ausmaß die Proteine ihre native Struktur noch am Ribosom gebunden annehmen, steht im Fokus aktueller Studien. Verschiedene Methoden, die naszierende Proteinkette am Ribosom zu arretieren und die Faltung des Proteins untersuchen zu können, wurden entwickelt. Zur Herstellung von Ribosom naszierenden Proteinkomplexen (RNCs) in vivo werden Arrestierungspeptide (APs) verwendet. Ein oft genutztes AP ist die 17 Aminosäuren lange SecM Sequenz des E. coli Sekretionsmonitors, das C-Terminal an das zu untersuchende Protein kloniert werden kann und dadurch die Peptidkette am Ribosom behält. RNCs wurden mittels verschiedener Methoden untersucht, einschließlich Proteolyse-Experimenten, enzymatischen Aktivitätsmessungen, FRET, Cryo-EM und NMR-Spektroskopie. Alle Methoden zeigten auf, dass sich die Proteine kotranslational falten und auch am Ribosom eine funktionale Struktur annehmen können. Außerdem konnte eine Peptidkette eine α-Helix innerhalb des Ribosoms ausbilden. Ebenso wurden nicht-native kompakte Strukturen innerhalb der Vestibule detektiert.
Die Translation ist ein nicht-uniformer Prozess und der genetische Code degeneriert mit bis zu sechs Codons, die eine einzelne Aminosäure kodieren. Die Verteilung dieser synonymen Codons ist nicht zufällig und sie werden mit verschiedenen Frequenzen innerhalb eines ORFs verwendet. Codons mit einer höheren tRNA Häufigkeit werden schneller eingebaut als Codons, die seltener verwendet werden. Diese seltenen Codons sind häufig zwischen Proteindomänen oder Sekundärstrukturelementen platziert und könnten daher zur Separierung von Faltungsevents dienen. Dass der Austausch von synonymen Codons nicht ohne Folgen ist, zeigten verschiedene Studien. Buhr et al. (2016) zeigte, dass der synonyme Austausch die Translationsgeschwindigkeit, aber auch die Proteinkonformation des bovinen Augenlinsenproteins γB crystallin (GBC) beeinflusst. Während die unmodifizierte Gensequenz aus B. taurus in E. coli langsamer translatiert wurde und zu einem vollständig reduzierten GBC Protein (U) führte, wurde die harmonisierte Genvariante, die der Codon-Verwendung in E. coli angepasst war, schneller exprimiert und resultierte in einem teilweise oxidierten GBC Protein (H). Dieser Befund war der Ausgangspunkt für diese Doktorarbeit.
Die gemessenen Oxidationsunterschiede basieren auf der unterschiedlichen Translationsgeschwindigkeit der beiden Gensequenzen. Die N-terminale Domäne (NTD) des Zweidomänen-Proteins GBC enthält sechs der insgesamt sieben Cysteinreste. Nur in dieser Domäne wurde Oxidation detektiert und die drei Cysteine Cys18, Cys22 und Cys78 bilden eine Ansammlung mit einem Abstand von 5.4-6.4 Å. Um zu untersuchen, ob die Unterschiede bereits nach der Translation der NTD ausgebildet werden, wurde ein Ein-Domänen-Konstrukt hergestellt. Dieses Konstrukt beinhaltete die Aminosäuren 1-82, aber nicht den Peptidlinker, der beide Domänen verbindet. Allerdings wurden bei der Translation der ersten 70 Aminosäuren die meisten Translationspausen detektiert. Das 2D 1H-15N HSQC wies anhand der unterschiedlichen chemischen Verschiebung der Signale auf eine gefaltete Proteinstruktur hin. Daher konnte sich die NTD ohne Beteiligung der CTD eigenständig falten. Zugabe von DTT zu beiden Proteinvarianten U und H führte zu keinem messbaren Effekt. Im Gegensatz zu dem Volllängen-Protein, in dem die Variante H teilweise oxidiert war, war die NTD der Variante H vollständig reduziert.
Zusätzlich sollte geklärt werden, ob auch mögliche Disulfidbrücken im Inneren des Ribosoms ausgebildet werden können. Dann könnte in beiden Genvarianten eine anfängliche Disulfidbrücke ausgebildet werden und durch die unterschiedliche Translationsgeschwindigkeit die Disulfidbrücke in der langsamen Genvariante im E. coli Zytosol reduziert werden, während diese in der schneller translatierten Variante von der CTD geschützt wird. Um zu untersuchen, ob in der Tat Disulfidbrücken im ribosomalen Tunnel ausgebildet werden können, wurden GBC-Fragmente mittels der SecM Sequenz an das Ribosom arretiert und diese RNCs mittels theoretischer Simulation, Festkörper-NMR, Massenspektrometrie und Cryo-EM gemessen.
Theoretische Simulation mittels flexible-mecanno zeigten, dass der ribosomale Tunnel groß genug für die Ausbildung verschiedenster Disulfidbrücken ist. In einem U32SecM Konstrukt, das vier Cysteine und die SecM Sequenz beinhaltet, konnten alle theoretisch möglichen Disulfidbrücken gebildet werden.
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