Onkogenní promotor c-myc jako cíl pro nový typ heterocyklických dikationtů stabilizujících G-kvadruplex. / The promoter of c-myc oncogene as a target for a novel type of heterocyclic cations stabilizing G-quadruplex.

Pohlová, Lenka

January 2015

Targeting oncogene promoters: a novel heterocyclic cations as G-quadruplex stabilizing ligands Lenka Pohlová Abstract: The diploma thesis studies an effect of newly synthesized group of compounds - helquats - on the expression of c-myc as a major player in malignant transformation and tumorigenesis via the stabilization of G-quadruplex in c-myc promotor. The G-quadruplex c-myc stabilization ability was tested for 101 helquats using dual luciferase reporter assay. The G-quadruplex c-myc stabilization ability was found for 13 helquats by this method. 8 successful helquats was selected by a comparison of the results from dual luciferase reporter assay and FRET melting assay. Effect on cell viability of tumor (HeLa S3) and non-tumor (HUVEC) cell lines was evaluated for these 8 helquats. Three of them exhibited cytotoxic effect on tumor cells but no effect was observed on viability of non-tumor cells. Moreover, an effect of these 3 helquats on c-myc expression on both mRNA and protein level, where significant effect on c-myc mRNA expression was not found for most of incubation periods. The 30% decrease in mRNA level was observed only for 24 hours incubation period for two helquats (LS702 and MJ656). The decrease in the expression on protein level was observed for all tested helquats, and helquat LS702 had the...

Replication Protein A Mediated G-Quadruplex Unfolding - A Single Molecule FRET Study

Qureshi, Mohammad Haroon

January 2013

No description available.

Biophysics

Biology

Biochemistry

Fluorescence resonance energy transfer

FRET

Replication Protein A

RPA

G-Quadruplex

G-Quartet

Thermal Stability

G-Quadruplex layers

Loop length

Selective incorporation of the C-F bond as a conformational tool in quadruplex DNA ligand design

Smith, Daniel L.

January 2012

Chapter 1 provides a general introduction to organofluorine chemistry and focuses on recent developments in fluorination techniques. It also details how the C–F bond influences conformational and physiochemical properties of organic molecules. Chapter 2 highlights the biological role of the telomere, telomerase and quadruplex DNA in cells. It discusses the inhibition of telomerase with small molecules that stabilise quadruplex DNA as a treatment for cancer. An overview of the development of structurally related telomerase inhibitors and recent X-ray crystallographic structural data with BSU6039 and BRACO-19 telomeric DNA is presented. Chapter 3 discusses the synthesis of fluorinated BSU6039 analogues for the investigation of the conformational effects of fluorine in 5-membered rings and its influence on binding with quadruplex DNA. These compounds have been successfully co-crystallised with telomeric DNA and their relative stabilisation of telomeric DNA has been assessed. The latter half of this chapter focuses on the co-crystal structures between (S,S)- and (R,R)-144 with Oxytricha nova telomeric DNA, discussing the key differences between the two stereoisomers. Chapter 4 details the synthesis of fluorinated BRACO-19 analogues. The syntheses of such fluorinated analogues were achieved through a base mediated coupling between 3,6-diaminoacridone and an α-fluorinated-β-amino ester. The α-fluorinated-β-amino ester was synthesised through a deoxyfluorination-mediated approach, using the stereochemistry of natural amino acids. Chapter 5 describes the stereo- and regio- selectivity of deoxyfluorination reactions with dipeptides bearing the β-amino alcohol functionality. Understanding this selectivity enabled the development of a method towards α-fluorination of tertiary amides. The application of this fluorination method with an orthogonally protected tertiary amide is described.

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Dna Glycosylases Remove Oxidized Base Damages From G-Quadruplex Dna Structures

Zhou, Jia

01 January 2015

The G-quadruplex DNA is a four-stranded DNA structure that is highly susceptible to oxidation due to its G-rich sequence and its structure. Oxidative DNA base damages can be mutagenic or lethal to cells if they are left unrepaired. The base excision repair (BER) pathway is the predominant pathway for repair of oxidized DNA bases. DNA glycosylases are the first enzymes in BER and are responsible for removing base lesions from DNA. How DNA glycosylases remove base lesions from duplex and single-stranded DNA has been intensively studied, while how they act on G-quadruplex DNA remains to be explored. In Chapter II of this dissertation, we studied the glycosylase activity of the five mammalian DNA glycosylases (OGG1, NTH1, NEIL1, NEIL2 and mouse Neil3) on G-quadruplex DNA formed by telomere sequences that contain a single base lesion. We found that telomeric sequences that contain thymine glycol (Tg), 8-oxo-7,8-dihydroguanine (8-oxoG), guanidinohydantoin (Gh) or spiroiminodihydantoin (Sp) all formed the basket form of an antiparallel G-quadruplex DNA structure in Na+ solution. We also showed that no glycosylase was able to remove 8-oxoG from quadruplex DNA, while its further oxidation products, Sp and Gh, were good substrates for mNeil3 and NEIL1 in quadruplex DNA. In addition, mNeil3 is the only enzyme that removes Tg from quadruplex DNA and the glycosylase strongly prefers Tg in the telomere sequence context in both single-stranded and double-stranded DNA. In Chapter III, we extended our study to telomeric G-quadruplex DNA in K+ solution and we also studied quadruplex DNA formed by promoter sequences. We found that 8-oxoG, Gh and Sp reduce the thermostability and alter the folding of telomeric quadruplex DNA in a location-dependent manner. Also, the NEIL1 and NEIL3 DNA glycosylases are able to remove hydantoin lesions but none of the glycosylases, including OGG1, are able to remove 8-oxoG from telomeric quadruplex DNA in K+ solution. Interestingly, NEIL1 or NEIL3 do not efficiently remove hydantoin lesions at the site that is most prone to oxidation in quadruplex DNA. However, hydantoin lesions at the same site in quadruplex DNA are removed much more rapidly by NEIL1, NEIL2 and NEIL3, when an extra telomere TTAGGG repeat is added to the commonly studied four-repeat quadruplex DNA to make it a five-repeat telomere quadruplex DNA. We also show that APE1 cleaves furan in selected positions in Na+-coordinated telomeric quadruplex DNA structures. We use promoter sequences of the VEGF and c-MYC genes as models to study promoter G-quadruplex DNA structures, and show that the NEIL glycosylases primarily remove Gh from Na+-coordinated antiparallel quadruplex DNA but not from K+-coordinated parallel quadruplex DNA containing VEGF or c-MYC promoter sequences. Taken together, our data show that the NEIL DNA glycosylases may be involved in both telomere maintenance and gene regulation.

base damage

base excision repair (BER)

DNA glycosylase

promoter

quadruplex DNA

telomere

Biochemistry

Molecular Biology

Studium struktury guaninových kvadruplexů pomocí neresonanční Ramanovy spektroskopie / Non-resonant Raman Spectroscopic Study of Guanine Quadruplex Structures

Golan, Martin

January 2013

Parts of human telomere sequences containing at least 4 guanine subsequences show the ability to form intrastrand quadruplexes of remarkable conformational diversity. Former studies using conventional Raman spectroscopy have revealed that the sequence G3(TTAG3)3 at milimolar concentrations in phosphate buffer solution doped with Na+ ions (ionic strength 150 mM) adopts antiparallel conformation regardless of the length of standing at room temperature or annealing, whereas K+ ions cause gradual transition to "3+1" or even parallel conformation. On the other hand, measurements carried out upon sequence AG3(TTAG3)3 at similar concentrations using Photonic Crystal Fibre-enhanced Raman Spectroscopy (PCFRS) suggest that in the respective presence of both Na+ and K+ (ionic strength 100 mM), a parallel structure is adopted. The hereby presented work employs conventional Raman spectroscopy and Drop Coating Deposition Raman spectroscopy to examine the sequence AG3(TTAG3)3 at concentrations ranging from units to hundreds of milimoles in strands. It concludes that the structure adopted in the presence of Na+, resp. K+ ions is antiparallel, resp. "3+1", and doesn't change over time despite both long standing and annealing. Two hypotheses about the cause of the differences between the results obtained by PCFRS and...

Cu (II) Catalyzed Gateways In The Synthesis of Acridine Derivatives and Their Biological Evaluation as Anti-Cancer Drugs

Komati, Rajesh

16 May 2014

Telomeres are nucleoprotein complexes found at the ends of linear eukaryotic chromosomes. Telomeres consist of a short sequence of repetitive double stranded DNA, TTAGGG repeats in humans (and all mammals), and a complex of 6 proteins, termed the shelterin complex. The length of the telomeres varies greatly between species, from approximately 300 base pairs in yeast to many 10-15 kilo bases in humans, because of the end replication problem this length get shorten with each cell division and ultimately leads to cell death. However the immortal eukaryotic cells and some transformed human cells over come this incomplete end replication problem with the use of enzyme called Telomerase. Telomerase is a ribonucleoprotein enzyme that adds a specific DNA sequence repeats (TTAGGG) to the 3¢ end of DNA strands in the telomere regions. However from the telomerase activity studies, it was concluded that telomerase is active in almost 90% of human cancers but not in normal somatic tissues. Finally, the low or transient expression of telomerase in normal tissues, including normal stem cells, and the generally longer telomeres in normal cells versus tumor cells provide a degree of tumor specificity to telomerase-based drugs and reduce the probability of toxicity to normal tissue. All of these factors suggest that cancer drugs based on telomerase might have a broad therapeutic window. This dissertation focusing on the synthesis of acridine derivatives that have the capability to inhibit the enzyme telomerase. Several N-acridyl maleimide (NAM), N-acridyl succinimide (NAS) and N-acridyl phthalimide (NAP) derivatives have been synthesized and evaluated for their anti cancer activity against various cancer cell lines. While synthesizing acridine derivatives it was required to form the C-N bonds at various stages. Developed a copper-nicotinic acid complex, which catalyzes the coupling of aryl halides with N-formyl amines and cyclic imides to form C-N bond. Explored Cu (II) catalyzed formation of C-N bond by coupling aryl halides with various N-nucleophiles such as formamide, N,N-dimethyl formamide, N-formyl amines and various cyclic imides.

Medicinal-Pharmaceutical Chemistry

Organic Chemistry

DNA-based logic

Bader, Antoine

January 2018

DNA nanotechnology has been developed in order to construct nanostructures and nanomachines by virtue of the programmable self-assembly properties of DNA molecules. Although DNA nanotechnology initially focused on spatial arrangement of DNA strands, new horizons have been explored owing to the development of the toehold-mediated strand-displacement reaction, conferring new dynamic properties to previously static and rigid structures. A large variety of DNA reconfigurable nanostructures, stepped and autonomous nanomachines and circuits have been operated using the strand-displacement reaction. Biological systems rely on information processing to guide their behaviour and functions. Molecular computation is a branch of DNA nanotechnology that aims to construct and operate programmable computing devices made out of DNA that could interact in a biological context. Similar to conventional computers, the computational processes involved are based on Boolean logic, a propositional language that describes statements as being true or false while connecting them with logic operators. Numerous logic gates and circuits have been built with DNA that demonstrate information processing at the molecular level. However, development of new systems is called for in order to perform new tasks of higher computational complexity and enhanced reliability. The contribution of secondary structure to the vulnerability of a toehold-sequestered device to undesired triggering of inputs was examined, giving new approaches for minimizing leakage of DNA devices. This device was then integrated as a logic component in a DNA-based computer with a retrievable memory, thus implementing two essential biological functions in one synthetic device. Additionally, G-quadruplex logic gates were developed that can be switched between two topological states in a logic fashion. Their individual responses were detected simultaneously, establishing a new approach for parallel biological computing. A new AND-NOT logic circuit based on the seesaw mechanism was constructed that, in combination with the already existing AND and OR gates, form a now complete basis set that could perform any Boolean computation. This work introduces a new mode of kinetic control over the operation of such DNA circuits. Finally, the first example of a transmembrane logic gate being operated at the single-molecule level is described. This could be used as a potential platform for biosensing.

Exploring genetic interactions with G-quadruplex structures

Mulhearn, Darcie Sinead

January 2019

G-quadruplexes are non-canonical nucleic acid secondary structures of increasing biological and medicinal interest due to their proposed physiological functions in transcription, replication, translation and telomere biology. Aberrant G4 formation and stabilisation have been linked to genome instability, cancer and other diseases. However, the specific genes and pathways involved are largely unknown, and the work within this thesis aims to investigate this. Stabilisation of G4s by small molecules can perturb G4-mediated processes and initial studies suggest that this approach has chemotherapeutic potential. I therefore also aimed to identify cell genotypes sensitive to G4-ligand treatment that may offer further therapeutic opportunities. To address these aims, I present the first unbiased genome-wide genetic screen in cells where genes were silenced via short-hairpin RNAs (shRNAs) whilst being treated with either PDS or PhenDC3, two independent G4-stabilising small molecules. I explored gene deficiencies that enhance cell death (sensitisation) or provide a growth advantage (resistance) in the presence of these G4-ligands. Additionally, I present a validation screen, comprising hits uncovered via genome-wide screening, and also the use of this in another cell line of different origin. Sensitivities were enriched in DNA replication, cell cycle, DNA damage repair, splicing and ubiquitin-mediated proteolysis proteins and pathways. Ultimately, I uncovered four synthetic lethalities BRCA1, TOP1, DDX42, GAR1, independent of cell line and ligand. These were validated with three G4-stabilising ligands (PDS, PhenDC3 and CX-5461) using an independent siRNA approach. The latter siRNA methodology was used to screen 12 PDS derivatives with improved medicinal chemistry properties and ultimately identified SA-100-128, as a lead compound. The mechanism behind synthetic lethality with G4-stabilising ligands was explored further for DDX42, which I show has in vitro affinity for both RNA- and DNA-G4s and may represent a previously unknown G4-helicase. Also within this thesis, gene deficiencies that provided a growth advantage to PDS and/or PhenDC3 as uncovered by genome-wide and focused screening were explored. These showed enrichment in transcription, chromatin and lysosome-associated genes. The resistance phenotype of three gene deficiencies, TAF1, DDX39A and ZNF217 was further supported by additional siRNA experiments. Overall, I satisfied the primary aims and established many novel synthetic lethal and resistance interactions that may represent new therapeutic possibilities. Additionally, the results expand our knowledge of G4-biology by identifying genes, functions and subcellular locations previously not known to involve or regulate G4s.

Rôle des protéines de liaison à l'ARN hnRNP H et hnRNP F dans les régulations traductionnelles dans les glioblastomes / Role of the RNA binding proteins hnRNP H and hnRNP F in translational regulation in glioblastoma

Le Bras, Morgane

15 November 2018

Le glioblastome multiforme (GBM) est une tumeur cérébrale extrêmement agressive associée à un mauvais pronostic. C'est pourquoi, il apparaît nécessaire d'identifier les mécanismes moléculaires participant au développement des GBM ainsi qu'à leurs résistances aux traitements afin de développer de nouvelles approches thérapeutiques. Récemment, il a été montré que les régulations traductionnelles jouent un rôle fondamental dans les propriétés agressives du GBM. Les protéines de liaison à l'ARN (RBP) sont des acteurs majeurs de ces régulations dont l'expression/activité est altérée dans les GBM. Les RBP hnRNP HF (HF) font partie des RBP les plus surexprimées dans les GBM et leur contribution dans la régulation traductionnelle des GBM n'a encore jamais été investiguée. Nous avons émis l'hypothèse que hnRNP H et hnRNP F soient au centre d'un réseau de régulations post-transcriptionnelles impactant la machinerie traductionnelle qui contrôle le développement tumoral et la résistance aux traitements des GBM. Nos résultats montrent qu'HF régulent la prolifération et la réponse aux traitements car leur perte d'expression (i) diminue la prolifération des GBM (modèle cellulaire, sphéroïde et xénogreffes in vivo), (ii) active les voies de réponse aux dommages à l'ADN et (iii) sensibilise les cellules de GBM aux irradiations. De plus, nous avons identifié un nouveau rôle pour HF en tant que régulateurs de la traduction. En effet, nos données montrent que les hnRNP HF contrôlent la traduction d'un ensemble d'ARNm en régulant l'expression et l'activité de facteurs d'initiation ainsi qu'en collaborant avec des ARN hélicases partenaires en ciblant des ARNm impliqués dans des processus reliés au développement tumoral et la résistance aux traitements possédant des structures secondaires G-quadruplexe dans leurs 5'UTR. Les données que nous avons générées suggèrent que hnRNP H et hnRNP F sont des régulateurs traductionnels essentiels au développement tumoral et à la résistance aux traitements des GBM. / Glioblastoma multiforme (GBM) is one of the most aggressive brain tumors with poor prognosis. Understanding the molecular mechanisms involved in the development and resistance to treatments of gliomas could improve treatment efficiency. Recently, it has been demonstrated that translational regulations play a key role in the GBM aggressivity. RNA binding proteins (RBP) are major regulators of these processes and have altered expression / activity in GBM. The RBP hnRNP H and hnRNP F (HF) are among the most overexpressed RBP in GBM and their role in GBM translational regulation has never been investigated yet. We hypothesize that HF are at the core of a post-transcriptional regulation network which impacts the translational machinery that controls GBM tumor development and resistance to treatment. We have demonstrated that hnRNP H and hnRNP F regulate proliferation and response to treatment because their depletion (i) decreases the GBM proliferation (cell line model, spheroid and in vivo xenografts), (ii) activates the DNA damage response pathways and (iii) sensitizes the GBM cells to irradiation. We have identified HF as new regulators of GBM translation. Indeed, our data show that hnRNP H and hnRNP F control mRNA translation by regulating expression/activity of initiation factors and in collaboration with RNA helicases by targeting mRNA involved in oncogenic processes and containing secondary structures called G-quadruplex in their 5'UTR. The data that we have generated suggest that HF are essential translational regulators involved in tumor development and resistance to treatment in GBM.

Traduction

Protéine de liaison à l'ARN

G-quadruplexe

Glioblastome

Translation

RNA binding protein

G-quadruplex

Glioblastoma

Crystallographic studies of interactions between ligands and DNA oligonucleotides

Pytel, Patrycja Dominika

January 2009

This thesis consists of two major chapters, each with its own introduction, experimental section and discussion. The TG4T/daunomycin and G4/daunomycin complexes described in Chapter One are two out of only five crystallographic quadruplex/ligand structures reported to date. In both structures daunomycin molecules stack onto a terminal G quartet preventing the G4 quadruplex from destacking and unwinding. The number of interacting ligand molecules depends on the quadruplex structure itself. The G4 quadruplex can accommodate four daunomycin molecules within one layer, while the TG4T tetraplex only accommodates three. In both structures daunosamine moieties form hydrogen bonds with the quadruplex but only daunosamine moieties from the TG4T/daunomycin structure make slight incursions into the quadruplex grooves. Both structures are stabilised by π-π interactions, hydrogen bonds, Van der Waals contacts and electrostatic interactions. The daunomycin/TG4T complex is the first ever reported and the only structure where a ligand interacts directly with the quadruplex groove. Chapter Two describes nine crystal structures of Hoechst 33258 analogues with d(CGCAAATTTGCG)2 and d(CGCGAATTCGCG)2 oligonucleotides, and is divided into two sections. Section A includes seven structures with Halogenated Hoechst 33258 analogues that are potential agents in radiotherapy, phototherapy, radioimmunotherapy or photoimmunotherapy, and the structure of the precursor. In all of the examined complexes the ligand binds to the minor groove but not all halogen substituents refine to 100% occupancy. The refined occupancies of the halogen atoms reveal that the degree of carbon-halogen cleavage is highest for ortho and lowest for para substitution. Among meta substituents pointing outside the minor groove, bromine atoms had a higher occupancy than the larger iodines. The position of the halogen atom in the minor groove is influenced by additional substituents on the phenyl ring. In most cases the bulky halogen atom is facing outside of the minor groove. Only in the 3-iodo-5-isopropylHoechst complex is iodine positioned towards the floor of the groove allowing the big isopropyl group to face outside. Section B describes the structure of a carborane-containing ligand (JW-B) bound to the minor groove of d(CGCAAATTTGCG)2. The analysis shows that is possible to position boron-rich moieties close to the cell nucleus, and JW-B may have potential in Boron Neutron Capture Therapy. / Data file restricted at the request of the author, but available by individual request, use the feedback form to request access.

Quadruplex

DNA

X-ray

Structure

Crystal

Daunomycin

Anti-cancer drug

Hoechst 33258

Phototherapy

Dehalogenation

Ligand