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G-quadruplexes (G4s) have been in the focus of research in the last decades for their regulatory roles in vivo and for their use in nano- and biotechnology. However, an understanding of the various factors that drive a particular quadruplex fold remains limited, challenging rational therapeutic targeting and design of these tetrahelical structures. In this regard, insights from modified G-quadruplexes may help to deepen our knowledge of G-quadruplex structure. In this dissertation, sugar-modified guanosine analogs are exploited for their altered conformational preferences regarding both glycosidic bond angle and sugar pucker by their incorporation into different syn positions of the G-core of a model G-quadruplex. Induced structural perturbations as characterized by NMR spectroscopy range from a local change in tetrad polarity to a complete refolding into an unusual structure with a V-shaped loop, a unique G4 structural element in the focus of this work. Detailed conformational analysis of the introduced G analogs and high-resolution structures of the modified quadruplexes reveal a complex interplay of glycosidic torsion angle, sugar pucker preferences and local interactions, which may all play a leading role in driving G4 folding.
The soluble blood protein beta2-glycoprotein I (beta2GPI; 326 aa, MW: 48 kDa, 5 domains) is one of the most abundant proteins in human serum and exhibits two main conformational states: the circular or closed conformation, where the first domain (DI) is bound to the last domain (DV) of the protein, and the linear or open conformation. The defined physiological function of beta2GPI is still unknown, though several roles in pro- and anticoagulation as well as oxidative stress protection were discovered. The open form is considered to play a crucial role in the systemic autoimmune disease antiphospholipid syndrome (APS), which is an acquired thrombophilia characterized by recurring thrombotic events and pregnancy morbidity. Beta2GPI constitutes the main antigen for APS autoantibodies which are supposed to bind a cryptic epitope within DI after a conformational change from closed to open form. However, the pathophysiological mechanism of APS is poorly understood. Therefore, investigating the structural dynamics of this protein in relation to its antigenicity is of high interest.
Post-translational modifications (PTM) of a target protein often show an impact on the formation of neoantigens, for instance in the autoimmune-mediated diseases type 1 diabetes mellitus, rheumatoid arthritis, or multiple sclerosis. Such modified antigens may lead to immune tolerance breakdown as they are unknown to the immune system, which therefore could mistakes self for non-self proteins. In this thesis, two frequently occurring PTM were introduced to beta2GPI and their impact on the protein conformation was studied by biophysical tools (i.e. atomic force microscopy (AFM) imaging, transmission electron microscopy (TEM) imaging, dynamic light scattering (DLS), and circular dichroism (CD) spectroscopy). In order to examine immunopathophysiological relevance of these PTM, additional insights were gained from ELISA which was used to examine binding of anti-DI autoantibodies purified from the blood of APS patients to the modified beta2GPI species.
A characteristic feature of beta2GPI is the high content of lysine residues. Previously, opening of beta2GPI was found to be triggered by a drastic shift in pH and salt concentration (pH 11.5 and 1.15 M NaCl), which results in reversible uncharging of the lysine residues. The aim of this study was to investigate the beta2GPI conformation after lysine acetylation as a model system, to elucidate the role of lysine residues on the conformational dynamics of this protein, and to examine anti-DI autoantibody binding to both the untreated as well as acetylated species.
A strategy to permanently open up the closed form under physiological conditions by chemical acetylation of lysine residues utilizing the sensitive acetylation agent acetic acid N-hydroxysuccinimide ester (NHS-Ac) was established. Complete and specific lysine acetylation was verified by quantification of primary amines exerting a fluoraldehyde o-phthaldialdehyde (OPA) reagent assay, as well as by native PAGE and western blot analysis with an anti-acetylated lysine antibody. Beta2GPI acetylation revealed a partial opening of beta2GPI molecules. Compared to untreated, i.e. native beta2GPI which exhibited 93% of the molecules in closed and 7% in open form, complete lysine residue acetylation generated 39% of beta2GPI in closed and 61% in open conformation as shown by AFM high-resolution imaging. pH 11.5-treated beta2GPI was used as a reference in the applied methods and revealed 38% of the protein in closed and 62% in open conformation. Thus, a significant shift in beta2GPI conformation occurred upon lysine residue acetylation as well as basic pH-treatment. The data indicate that lysine residue acetylation destabilizes the closed form, leading to a facilitated opening of the structure. The closed conformation might be predominantly stabilized by electrostatic interactions of lysine residues, which potentially control the conformational dynamics of this glycoprotein. ELISA confirmed that anti-DI autoantibodies do not bind to untreated (closed) beta2GPI. Although acetylated beta2GPI was shown to have a substantial portion of open proteins, no binding of anti-DI autoantibodies to the acetylated species was found either. Hence, acetylated lysine residues may disrupt the immunorelevant epitope in DI which prevents antibody binding. This finding reveals a new hint for epitope organization. However, further detailed epitope mapping has to be performed.
Beta2GPI carries two structural disulfide bonds per domain, whereas an additional disulfide bond Cys288/Cys326 is located at the C-terminus of DV near the putative contact interface of DI and DV in the closed conformation. It was previously shown that beta2GPI is a substrate of thiol oxidoreductases, including human thioredoxin-1 (Trx-1) generating different redox states of disulfide bond Cys288/Cys326, which might serve as a scavenger in oxidative stress protection in the blood stream. In APS patients, anti-DI antibody titers as well as an enhanced risk for thrombotic events are associated with an increase in the oxidized state of the protein. Hitherto, no structural study has been performed in order to prove a correlation of the redox state and the conformation of beta2GPI. Therefore, investigations of beta2GPI conformation in different redox states of disulfide bond Cys288/Cys326 were carried out. In addition, binding of anti-DI autoantibodies to the untreated (native) as well as reduced protein should be explored.
At first, cysteine residues of untreated, i.e. native beta2GPI were confirmed to be completely in oxidized state using Ellman’s reagent assay and the absence of binding of a thiol-specific agent. Statistical analyses of AFM images revealed that untreated beta2GPI was mainly in closed conformation (80% in closed and 20% in open conformation) in the respective system. In this study, an optimized protocol for enzymatic reduction of disulfide bond Cys288/Cys326 was established. The agent TCEP was used to reduce human Trx-1, which in turn enzymatically reduced beta2GPI. To block reoxidation of free thiols and to facilitate product analysis, cysteine residues of reduced beta2GPI were subsequently labeled with the sensitive and thiol-specific reagent 3-(N-maleimidopropionyl) biocytin (MPB), which carries a biotin function. During protocol establishment, complete and specific reduction of disulfide bond Cys288/Cys326 was confirmed utilizing SDS-PAGE, streptavidin western blot, mass spectrometry (MS) analyses, and a biotin quantification assay. Protocol improvements constituted a homogenous system with remarkable decrease of unspecifically reduced beta2GPI. Upon beta2GPI reduction, AFM imaging revealed no significant shift in protein conformation (75% in closed and 25% in open conformation). These results were qualitatively confirmed by TEM imaging. Therefore, reduction of beta2GPI disulfide bond Cys288/Cys326 did not result in a major conformational change of the protein. Upon in vitro reduction, the closed form is still the main conformation and a direct correlation of beta2GPI redox state and conformation must be refused. Furthermore, beta2GPI reduction led to a strong and statistically highly significant increase in anti-DI autoantibody binding compared to untreated beta2GPI. Thus, the reduced form might be the antigenic form of the protein. In contrast to previous knowledge, these findings suggest that anti-DI autoantibodies may also bind to the closed conformation under certain conditions. Hypothetically, reduction of beta2GPI could induce a minor structural change in DV that might facilitate the binding of APS autoantibodies.
Overall, this study reveals that PTM of beta2GPI may lead to a critical level of destabilization of the closed conformation (as in the case of acetylated beta2GPI) or significantly increase the binding of APS autoantibodies (as in the case of reduced beta2GPI), both of which could have a large impact on APS disease. However, further investigations are necessary to put these new findings in the context of APS immunopathophysiology.
This dissertation explores and tries to unravel the fundamental basis of G-quadruplex end-folding as well as G-quadruplex interactions with small molecules by thermodynamic and structural approaches. Selective targeting of G-quadruplexes with ligands remains elusive, either because the ligand has
considerable binding affinity for other DNA structures or because it fails to discriminate between different G-quadruplex topologies. Unique structural motifs on the G-quadruplex may enhance or inhibit ligand binding to the G-quadruplex. For such aspects, it is necessary to understand the effect of G-quadruplex motifs or elements on the end-folding in order to better tune certain G-quadruplex topologies as model systems. Importantly for targeting G-quadruplex with ligands, motifs called Quadruplex-duplex (QD) junctions and interfaces are shown to be a binding hotspot
for various G-quadruplex ligands containing an intercalator motif. Binding affinity and selectivity of the ligands are discussed with the support of the NMR structures.
G-Quadruplexe (G4) sind alternative Sekundärstrukturen, die von Guanosin-reichen DNA- oder RNA-Sequenzen ausgebildet werden können. In den letzten Jahren rückten diese tetrameren Konstrukte aufgrund ihres erst kürzlichen Nachweises in lebenden Humanzellen und ihrem Vorkommen in bestimmten funktionellen Genombereichen wie den Promotorregionen von Protoonkogenen oder den Telomeren zunehmend in den Fokus der Nukleinsäureforschung. Insbesondere ihre starke Korrelation mit Krebs macht Quadruplexstrukturen als Zielmotiv für die Entwicklung antikanzerogener Wirkstoffe höchst interessant. Um jedoch niedermolekulare Moleküle für therapeutische Zwecke nutzen zu können, muss zunächst auf molekularer Ebene ein grundlegendes Verständnis für die Ligand-Quadruplex-Interaktion geschaffen und anhand dieser Informationen Optimierungsmöglichkeiten für G4-bindende Liganden ergründet werden.
Ziel dieser Dissertation war die ausführliche Analyse der Bindung biologisch aktiver, Phenyl-substituierter Indolochinoline an Quadruplexstrukturen mittels diverser spektroskopischer und kalorimetrischer Methoden. Um simultan den Einfluss verschiedener Ligandstrukturelemente auf die G4-Anbindung für ein zukünftiges, rationales Wirkstoffdesign zu erforschen, wurde im Rahmen dieser Arbeit zunächst unterschiedlich modifizierte Indolochinolinderivate synthetisch hergestellt. In ersten spektroskopischen Experimenten sollten diese Moleküle anschließend nicht nur auf ihre generelle Interaktion mit verschiedenen G4-Topologien hin untersucht, sondern auch die Selektivität, die Bindungsaffinität und der Interaktionsmodus der Liganden ermittelt werden. Besonders die Indolochinoline mit basischen Seitenketten und einer N5-Methylierung zeigten eine hohe Affinität und Präferenz gegenüber parallelen Quadruplexstrukturen. Um detailliertere Informationen über diese Ligand-DNA-Wechselwirkung zu erhalten, erfolgten umfassende thermodynamische Bindungsstudien mittels isothermaler Titrationskalorimetrie. Anhand dieser Daten erfolgte eine Separation der Freien Bindungsenthalpie, die in dieser Form erstmalig für ein G4-bindendes Molekül beschrieben wurde. Hierbei zeigte sich, dass die Anbindung der Phenyl-substituierten Indolochinoline nicht nur durch hydrophobe Effekte, sondern vor allem durch spezifische molekulare Wechselwirkungen zwischen dem Ligand und der Quadruplex vorangetrieben wird.
Central to this thesis are so-called G-quadruplex (G4) nucleic acids. These unusual structures have recently moved into the scientific limelight - mostly due to their prevalence in the human genome. Incidentally, the vast majority of G4-prone sequences is found in telomeric regions and in the promoter sequences of a large number of cancer-related genes.
Furthermore, recent studies suggest a wide applicability of these structures as therapeutic and functional agents, though the technology is still in its infancy with only a few oligonucleotides in clinical trials. Notably, G-quadruplexes are highly polymorphous, exhibiting different topologies and conformations based on sequence, solution condition and molecularity. Therefore, rational design of such structures with specific, topology-encoded functions demands a comprehensive understanding of the underlying folding parameters.
As the folding process is the result of a whole orchestra of parameters with synergistic effects, the herein proposed approach to understand the G4 structural arrangement concentrates on native G4-forming sequences with well-defined topologies. Perturbations of these structures by rational nucleotide substitutions allow for the observation of discrete effects on the folding pathway and on the resulting overall topology.
The method chosen for primary investigation in the following studies on G4 architectures was Nuclear Magnetic Resonance (NMR) as it is the most powerful tool for structure elucidation in liquids. Unique to this technique, it permits the observation of discrete species in mixtures by distinct perturbations at the atomic level as well as valuable insights into the molecular dynamics.
The included publications study the effects of site-specific bromine substitutions on native quadruplex scaffolds, thereby successfully inducing new structures. These expand the G4 structural landscape but also enhance our understanding of the driving forces in G4 folding.