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Roles for the Cohibin Complex and its Associated Factors in the Maintenance of Several Silent Chromatin Domains in S. cerevisiaePoon, Betty Po Kei 26 November 2012 (has links)
In Saccharomyces cerevisiae, the telomeres and rDNA repeats are repetitive silent chromatin domains that are tightly regulated to maintain silencing and genome stability. Disruption of the Cohibin complex, which maintains rDNA silencing and stability, also abrogates telomere localization and silencing. Cohibin-deficient cells have decreased Sir2 localization at telomeres, and restoring telomeric Sir2 concentrations rescues the telomeric defects observed in Cohibin-deficient cells. Genetic and molecular interactions suggest that Cohibin clusters telomeres to the nuclear envelope by binding inner nuclear membrane proteins. Futhermore, telomeric and rDNA sequences can form G-quadruplex structures. G-quadruplexes are non-canonical DNA structures that have been linked to processes affecting chromosome stability. Disruption of the G-quadruplex stabilizing protein Stm1, which also interacts with Cohibin, increases rDNA stability without affecting silent chromatin formation. In all, our findings have led to the discovery of new processes involved in the maintenance of repetitive silent chromatin domains that may be conserved across eukaryotes.
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Cyanine Dyes Targeting G-quadruplex DNA: Significance in Sequence and Conformation SelectivityHuynh, Hang T 16 December 2015 (has links)
Small molecules interacting with DNA is an emerging theme in scientific research due to its specificity and minimal side-effect. Moreover, a large amount of research has been done on finding compounds that can stabilize G-quadruplex DNA, a non-canonical secondary DNA structure, to inhibit cancerous cell proliferation. G-quadruplex DNA is found in the guanine-rich region of the chromosome that has an important role in protecting chromosomes from unwinding, participate in gene expression, contribute in the control replication of cells and more. In this research, rationally designed, synthetic cyanine dye derivatives, which were tested under physiologically relevant conditions, were found to selectively bind to G-quadruplex over duplex DNA and are favored to one structure over another. The interactions were observed using UV-Vis thermal melting, fluorescence titration, circular dichroism titration, and surface plasmon resonance analysis. For fluorescence and selectivity properties, cyanine dyes, therefore, have the potential to become the detections and/or therapeutic drugs to target cancers and many other fatal diseases.
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Characterization and Molecular Targeting of a Mechanosensor Mechanism Controlled By the G-Quadruplex/I-Motif Molecular Switch in the MYC Promoter NHE III₁Sutherland, Caleb Daniel January 2015 (has links)
MYC is overexpressed in most types of tumors, but a means to selectively decrease its expression is yet to be found. Our recent findings on modulation of BCL2 gene expression through protein interactions with the BCL2 i-motif have provided a basis for further investigation of MYC gene control. It is proposed that the MYC i-motif could function by a similar molecular switch mechanism as in BCL2.Binding sites for heterogeneous nuclear ribonucleoprotein K (hnRNP K) within the MYC promoter also exist in the i-motif-forming sequence. Circular dichroism and bromine footprinting confirmed that this DNA sequence is able to form an i-motif, and systematic mutation of the cytosine residues in this sequence has revealed a 5:5:5 loop configuration. Indeed, all loops of the i-motif, when folded into a 5:5:5 loop configuration, contain the hnRNP K consensus sequence (CCCT). Previous studies show that hnRNP K binds to this i-motif-forming sequence, but it was assumed to be single-stranded. Binding studies revealed that hnRNP K has more binding affinity to its consensus sequence in the i-motif compared to a mutant sequence where the i-motif cannot form. Further investigation of the MYC promoter revealed an additional two runs of cytosine seven bases downstream of the MYC i-motif. Biophysical studies showed that the additional two runs were not involved in i-motif formation, however recent studies describe their importance for transcriptional activation. We found that hnRNP K preferred the longer 5CT sequence compared to the i-motif forming 4CT sequence when using a competitive binding assay. Utilizing luciferase reporters containing either the 4CT or 5CT sequence validated that hnRNP K required both the i-motif and 5th CT element for maximum transcriptional activation. Competition binding studies and bromine footprinting showed that hnRNP K bound to the downstream 5th CT element and the central and lateral loops of the i-motif.Additionally, we found that co-overexpression of Sp1 and hnRNP K induced a 10-fold increase in luciferase activity in the 5CT reporter only. We hypothesize that Sp1 continuously primes the promoter to initiate transcription inducing more negative superhelicity and increasing the melting of duplex DNA. This increased melting grants hnRNP K’s three KH domains access to the i-motif loops and the 5Th CT element. Confirmation by ChIP analysis validated that Sp1 overexpression causes an increase in hnRNP K occupancy at the MYC promoter. These findings provide new insight into the mechanisms of MYC transcriptional control by the i-motif and G-quadruplex.Recently, our group has demonstrated that two small molecules IMC-48 and IMC-76 can interact with the i-motif and can be an effective means to modulate BCL2 expression. Based on these results with the BCL2 i-motif, we employed a similar strategy and screened and identified small drug-like molecules that interact with MYC i-motif, using a FRET high-throughput assay. We then further validated that IMC-16 stabilizes the MYC i-motif through the interactions with the loops of the i-motif. No stabilization by IMC-16 treatment was observed with the MYC G-quadruplex and the BCL2 and PDGFRβi-motifs demonstrating selectivity for the MYC i-motif.Finally, we investigated the effects of IMC-16 on MYC expression in three lymphoma cell lines all expressing different levels of MYC. In the case of both Daudi and RAJI Burkitt’s lymphoma cell lines we demonstrated that selectively stabilizing the i-motif by IMC-16 could increase MYC expression. Furthermore, we demonstrated that the MYC G-quadruplex stabilizing compound GQC-05 and IMC-16, which stabilizes the MYC i-motif, have antagonistic effects on MYC expression, providing further evidence of a molecular switch mechanism in the NHEIII1. Directly targeting MYC expression through the i-motif offers advantages over targeting the G-quadruplex, because of the reduced stability and dynamic nature of the i-motif, additionally the i-motif is only found in DNA. The use of such i-motif interactive compounds is the first step into the development of new innovative approaches to treat cancers.
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Molecular and Functional Consequences of Genetic Variability in the Ornithine Decarboxylase Gene in Colorectal CancerPrieto, Jenaro Garcia-Huidobro January 2013 (has links)
Dysregulation of cellular metabolism is associated with multiple diseases including cancer. Polyamines are organic cations shown to control gene expression at the transcriptional, post-transcriptional, and translational level. The activity of ornithine decarboxylase (ODC), the first enzyme in polyamine synthesis, is associated with normal and neoplastic growth. A single nucleotide polymorphism (SNP, rs2302615, SNP +316 nucleotides 3' of the transcriptional start site) in the ODC1 gene has been found to be both functional and prognostic for risk of colorectal carcinogenesis. A comprehensive investigation of genetic variability in ODC1 gene was performed. We confirmed frequencies of 12 SNPs occurring in participants of a clinical cancer prevention trial. We identified haplotypes accounting for over 90% of the genetic diversity in the ODC1 gene. Mechanistically, we addressed two of them, which account for more than half of the participants in the clinical trial. Two ODC1 intron 1 SNPs, rs2302616 (SNP +263 nucleotides 3' of the transcriptional start site) and rs2302615, were found to be associated with disease processes. Both of them predicted metachronous adenoma and response to agents targeting the polyamine pathway in participants of the clinical trial. The rs2302616 functionally modulate a DNA G-quadruplex structure and predicted the ODC1 rate-limiting product putrescine by genotype. Both SNPs cooperate to modulate ODC1 transcriptional activity involving both a G-quadruplex structure and Sp1 binding site at rs2302616, and rs2302615 flanked MYC-binding E-boxes. Haplotype analysis, using both these SNPs, might provide better discrimination of both disease prognosis and treatment prediction in cancer chemoprevention clinical trials.
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The Regulatory Significance and Molecular Targeting of Novel Non-B-DNA Secondary Structures Formed from the PDGFR-Beta Core Promoter Nuclease Hypersensitivity ElementBrown, Robert Vincent January 2014 (has links)
Herein we describe the regulatory significance and molecular targeting of novel non-B-DNA secondary structures formed from the PDGFR-Beta core promoter nuclease hypersensitivity element.
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Roles for the Cohibin Complex and its Associated Factors in the Maintenance of Several Silent Chromatin Domains in S. cerevisiaePoon, Betty Po Kei 26 November 2012 (has links)
In Saccharomyces cerevisiae, the telomeres and rDNA repeats are repetitive silent chromatin domains that are tightly regulated to maintain silencing and genome stability. Disruption of the Cohibin complex, which maintains rDNA silencing and stability, also abrogates telomere localization and silencing. Cohibin-deficient cells have decreased Sir2 localization at telomeres, and restoring telomeric Sir2 concentrations rescues the telomeric defects observed in Cohibin-deficient cells. Genetic and molecular interactions suggest that Cohibin clusters telomeres to the nuclear envelope by binding inner nuclear membrane proteins. Futhermore, telomeric and rDNA sequences can form G-quadruplex structures. G-quadruplexes are non-canonical DNA structures that have been linked to processes affecting chromosome stability. Disruption of the G-quadruplex stabilizing protein Stm1, which also interacts with Cohibin, increases rDNA stability without affecting silent chromatin formation. In all, our findings have led to the discovery of new processes involved in the maintenance of repetitive silent chromatin domains that may be conserved across eukaryotes.
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Targeted Knockdown of MYC in AML Cells Using G-quadruplex Interacting Small MoleculesJanuary 2017 (has links)
abstract: Acute Myeloid Leukemia (AML) is a disease that occurs when genomic changes alter expression of key genes in myeloid blood cells. These changes cause them to resume an undifferentiated state, proliferate, and maintain growth throughout the body. AML is commonly treated with chemotherapy, but recent efforts to reduce therapy toxicity have focused on drugs that specifically target and inhibit protein products of the cancer’s aberrantly expressed genes. This method has proved difficult for some proteins because of structural challenges or mutations that confer resistance to therapy. One potential method of targeted therapy that circumvents these issues is the use of small molecules that stabilize DNA secondary structures called G-quadruplexes. G-quadruplexes are present in the promoter region of many potential oncogenes and have regulatory roles in their transcription. This study analyzes the therapeutic potential of the compound GQC-05 in AML. This compound was shown in vitro to bind and stabilize the regulatory G-quadruplex in the MYC oncogene, which is commonly misregulated in AML. Through qPCR and western blot analysis, a GQC-05 mediated downregulation of MYC mRNA and protein was observed in AML cell lines with high MYC expression. In addition, GQC-05 is able to reduce cell viability through induction of apoptosis in sensitive AML cell lines. Concurrent treatment of AML cell lines with GQC-05 and the MYC inhibitor (+)JQ1 showed an antagonistic effect, indicating potential competition in the silencing of MYC. However, GQC-05 is not able to reduce MYC expression significantly enough to induce apoptosis in less sensitive AML cell lines. This resistance may be due to the cells’ lack of dependence on other potential GQC-05 targets that may help upregulate MYC or stabilize its protein product. Three such genes identified by RNA-seq analysis of GQC-05 treated cells are NOTCH1, PIM1, and RHOU. These results indicate that the use of small molecules to target the MYC promoter G-quadruplex is a viable potential therapy for AML. They also support a novel mechanism for targeting other potentially key genetic drivers in AML and lay the groundwork for advances in treatment of other cancers driven by G-quadruplex regulated oncogenes. / Dissertation/Thesis / Masters Thesis Molecular and Cellular Biology 2017
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Oligonucléotides comme modulateurs de l'expression génique / Oligonucleotides as gene expression modulatorsRouleau, Samuel January 2017 (has links)
L’ARN est sans aucun doute la molécule biologique la plus versatile qui soit. Tout comme l’ADN, il peut contenir et transmettre de l’information génétique. Tout comme les protéines, il peut accomplir une multitude de fonctions biologiques. De plus, son rôle le plus connu demeure celui d’intermédiaire entre l’ADN et les protéines. L’ARN est donc au cœur d’un bon nombre de processus biologiques. Ceci lui confère un immense potentiel thérapeutique qui jusqu’à présent demeure largement inexploité. Pour accomplir ses fonctions, l’ARN doit adopter une structure tridimensionnelle précise qui est dépendante à la fois de sa séquence et de son environnement. Ainsi, en modifiant la structure d’un ARN, il est possible d’en moduler sa fonction. C’est l’objectif global des travaux présentés dans cette thèse. Pour y parvenir, de courts oligonucléotides antisens (OA) ont été utilisés. Cette stratégie revêt plusieurs avantages. Comme les OA s’apparient à leur cible en formant des paires de bases Watson-Crick, ils offrent une grande spécificité et leur design est facile. De plus, en se fiant aux données structurales et aux logiciels de prédictions de structures des ARN, on peut aisément identifier les régions à cibler avec les OA. Enfin, cette technique est versatile puisqu’on peut cibler différents motifs d’ARN. La première cible a été le ribozyme du virus de l’hépatite D. Cet ARN, qui catalyse une réaction d’auto-coupure, a été modifié afin que son activité devienne dépendante à la liaison d’OA. Plusieurs modules ont ainsi été créés et combinés afin d’obtenir des ribozymes qui répondaient à la présence d’un ou plusieurs OA. En insérant ces interrupteurs moléculaires dans les régions non traduites d’un ARNm, nous avons ainsi modulé l’expression de ce gène avec les OA. Cet outil a des applications intéressantes pour la régulation de gènes en biologie synthétique. Un autre motif ciblé a été le G-quadruplex (G4). Cette structure non canonique exerce de nombreuses fonctions biologiques et représente donc une cible thérapeutique intéressante. Lorsque présent dans la région 5’ non traduite d’un ARNm, le G4 mène généralement à une diminution de la traduction. En utilisant des OA qui empêchent la formation du G4, nous avons été en mesure d’augmenter la traduction du gène ciblé. De plus, il a été possible de développer des OA qui favorisent la formation d’un G4 dans le but de diminuer l’expression de la cible. Finalement, dans le dernier chapitre de cette thèse, il est démontré que les G4 présents dans les microARN primaires influencent leur maturation en microARN matures. Des OA ciblant ces G4 ont été utilisés afin de favoriser la maturation de microARN suppresseurs de tumeurs, ce qui présente un potentiel thérapeutique intéressant. En bref, les travaux présentés dans cette thèse démontrent clairement que les OA sont un outil de choix pour cibler et modifier la structure de motifs d’ARN spécifiques. / Abstract : RNA is a versatile biological molecule. Like DNA, it can contain and transmit genetic
information. Like proteins, it can accomplish multiple biological functions. Also, its most
known role remains that of intermediary between DNA and proteins. RNA is thus a key
player in many biological processes. This gives it an immense therapeutic potential which
remains largely untapped. To fulfill its functions, RNA must adopt a precise threedimensional
structure that is dependent on both its sequence and its environment. Thus, by
modifying the structure of an RNA, it is possible to modulate its function. This is the
overall objective of the work presented in this thesis. To achieve this, small antisense
oligonucleotides (ASO) have been used. This strategy has several advantages. As ASO
bind their target with Watson-Crick base pairs, they offer great specificity and their design
is easy. Moreover, reliance on structural data and RNA structure prediction softwares
makes it easy to identify the regions to be targeted with ASO. Finally, this technique is
versatile since it is possible to target different RNA motifs. The first target was the HDV
self-cleaving motif. This RNA, which catalyzes a self-cleaving reaction, has been modified
so that its activity became dependent on the binding of ASO. Several modules were thus
created and combined in order to obtain ribozymes which responded to the presence of one
or more ASO. By inserting these molecular switches into an mRNA’s UTR, the expression
of this gene was modulated with the ASO. This has interesting applications for the
regulation of genes in synthetic biology. Another target motif was the G-quadruplex (G4).
This non-canonical structure exerts many biological functions and therefore represents an
interesting therapeutic target. When present in the mRNA’s 5’UTR, G4 generally lead to a
decrease in translation. Using ASO that prevent G4 formation, we were able to increase the
translation of the target gene. In addition, it has been possible to develop ASO which
promote the formation of a G4 in order to decrease the expression of the target. Finally, in
the last chapter of this thesis, it is demonstrated that the G4 present in the primary
microRNAs influence their maturation in mature microRNAs. ASO targeting these G4
have been used in order to promote the maturation of tumor suppressor microRNAs, which
has an interesting therapeutic potential. The work presented in this thesis clearly
demonstrates that ASO are ideal for targeting and altering the structure of specific RNA
motifs.
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Benzimidazole Based Novel Ligands For Specific Recognition Of Duplex And G-Quadruplex DNAPaul, Ananya 02 1900 (has links) (PDF)
The thesis entitled “Benzimidazole based Novel Ligands for Specific Recognition of Duplex and G-Quadruplex DNA” deals with the design, synthesis and modeling of several benzimidazole based molecules and their interaction with duplex and G-quadruplex DNA structures. It also elucidates the inhibition effect of the ligands on the activity of Topoisomerase I and Telomerase. The work has been divided into six chapters.
Chapter 1. DNA Interacting Small Organic Molecules: Target for Cancer Therapy
This first chapter presents an overview on the various types of small molecules that interact with duplex and G-quadruplex structures of DNA or interfere with the activity of DNA targeted enzymes like topoisomerase and telomerase. The importance of such molecules as chemotherapeutic agents is highlighted.
Chapter 2. DNA Recognition: Conformational Switching of Duplex DNA by Mg2+ ion Binding to Ligand
Bis-benzimidazoles like Hoechst 33258 are well known ligands that bind to duplex DNA (ds-DNA) minor grooves. Here a series of dimeric bisbenzimidazole based ligands in which two Hoechst units are connected via oxyethylene based hydrophilic [Ho-4ox-Ho (1), Ho-3ox-Ho (2)] or via hydrophobic oligomethylene [Ho-(CH2)8-Ho (3)](Figure 1) spacers have been synthesized. The aim of this investigation is to examine the binding property of these dimers on the ds-DNA to explore whether the variation in the length of the spacer has any effect on DNA binding properties particularly in presence of selected metal ions. The changes of individual dimers in DNA binding efficiency was studied in detail by fluorescence, circular dichroism spectral titrations and thermal denaturation experiment with selected duplex DNA formed from appropriate oligonucleotides. We have also examined the changes that occur in geometry of the molecules from linear to hairpin motif in presence of Mg2+ ion. A large difference was observed in [ligand]/ [DNA] ratio and binding efficiency with ds-DNA upon change in the ligand geometry from linear to hairpin motif. The experimental results were then substantiated using docking and molecular dynamics simulations using a model ds-DNA scaffold. Both experimental and theoretical studies indicate that the DNA binding is highly dependent on the spacer type and length between the two monomeric Hoechst units. The spacer length actually helps to achieve shape complimentarity with the double-helical DNA axis.
Figure1: Chemical structures of the dimeric ligands Ho-4ox-Ho, Ho-3ox-Ho, Ho-(CH2)8-Ho and Hoechst 33258 (Ho) used in this study.
Chapter 3. DNA Binding and Topoisomerase I Inhibiting Properties of New Benzimidazole Substituted Polypyridyl Ruthenium (II) Mixed-Ligand Complexes
In this study, we have synthesized and fully characterized three new Ru(II)
based polypyridyl and benzimidazole mixed complexes: (1) [Ru(bpy)2(PMI)], 2+
(2) [Ru(bpy)2(PBI)]2+ and (3) [Ru(bpy)2(PTI)]2+ (Figure 2) . The affinities of these complexes toward duplex DNA were investigated. In addition, the photocleavage reaction of DNA and topoisomerase I inhibition properties of these metal complexes were also studied. The DNA binding efficiency of individual complexes was studied in detail by absorbance, fluorescence spectral titrations and thermal denaturation experiment using natural calf-thymus DNA. Upon irradiation at 365 nm, all three Ru(II) complexes were found to promote the cleavage of plasmid DNA from negatively supercoiled to nicked circular and subsequently to linear DNA. The inhibition of topoisomerase I mediated by these Ru(II) complexes was also examined. These experiments demonstrate that each complex serves as an efficient inhibitor toward topoisomerase I and such inhibition activity is consistent with interference with the DNA religation step catalyzed by topoisomerase.
Figure 2. Chemical structures of the metal complexes used in this present study.
Chapter 4. Synthesis and Evaluation of a Novel Class of G-Quadruplex-Stabilizing small molecules based on the 1,3-Phenylene-bis (piperazinyl benzimidazole) syatem
Achieving stabilization of telomeric DNA in the G-quadruplex conformation by various organic compounds is an important goal for the medicinal chemists seeking to develop new anticancer agents. Several compounds are known to stabilize the G-quadruplexes. However, relatively few are known to induce their formation and/or alter the topology of the pre-formed G-quadruplex DNA.
Herein, four compounds having the 1,3-phenylene-bis(piperazinyl benzimidazole) (Figure 3) unit as a basic skeleton have been synthesized, and their interactions with the 24-mer telomeric DNA sequences from Tetrahymena thermophilia d(T2G4)4 have been investigated using high-resolution techniques such as circular dichroism (CD) spectropolarimetry, CD melting, emission spectroscopy, and polyacrylamide gel electrophoresis. The data obtained, in the presence of one of three ions (Li+, Na+ or K+), indicate that all the new compounds have a high affinity for G-quadruplexDNA, and the strength of the binding with G-quadruplex depends on (i) phenyl ring substitution, (ii) the piperazinyl side chain, and (iii) the type of monovalent cation present in the buffer. Results further suggest that these compounds are able to abet the conversion of the intramolecular G-quadruplex DNA into parallel stranded intermolecular G-quadruplex DNA. Notably, these compounds are also capable of inducing and stabilizing the parallel stranded G-quadruplex DNA from randomly structured DNA in the absence of any stabilizing cation. The kinetics of the structural changes induced by these compounds could be followed by recording the changes in the CD signal as a function of time.
Figure 3. Chemical structures of the ligands used in this study.
Chapter 5A. The Spacer Segment in the Dimeric 1,3-phenylene-bis (piperazinyl benzimidazole) has a Dramatic Influence on the Binding and Stabilization of Human Telomeric G-Quadruplex DNA
Ligand-induced stabilization of G-quadruplex structures formed by human telomeric DNA is an active area of basic and clinical research. The compounds which stabilize the G-quadruplex structures lead to suppression of telomerase activity. Herein, we present the interaction of a series of monomeric and dimeric compounds having 1,3-phenylene-bis(piperazinyl benzimidazole) (Figure 4) as basic pharmacophore unit with G-quadruplex DNA formed by human telomeric repeat d[(G3T2A)3G3]. These new compounds provide an excellent stabilization property to the pre-formed G-quadruplex DNA in the presence of one of three ions (100 mM Li+, Na+ or K+ ions). Also the G-quadruplex DNA formed in the presence of low concentrations of ligands in 100 mM K+, adopts a parallel-stranded conformation which attains an unusual thermal stability. The dimeric ligands having oxyethylene based spacer provide much higher stability to the pre-formed G-quadruplex DNA and the G-quadruplexes formed in presence of the dimeric compounds than the corresponding monomeric counterparts. Consistent with the above observation, the dimeric compounds exert significantly higher telomerase inhibition activity than the monomeric compounds. The ligand induced G-quadruplex DNA complexes were further investigated by computational molecular modeling, which provide useful information on their structure-activity relationship.
Figure 4. Chemical structures of the monomeric and dimeric ligands used in this study.
Chapter 5B. Role of Spacer in Symmetrical Gemini bisbenzimidazole based Ligands on the Binding and Stabilization of Dimeric G-Quadruplex DNA derived from Human Telomeric Repeats
The design and development of anticancer agents that act via stabilization of the telomeric G-quadruplex DNA is an active area of research because of its importance in the negative regulation of telomerase activity. Several classes of G-quadruplex DNA binding ligands have been developed so far, but they mainly act on the DNA sequences which are capable of forming a single Gquadruplex unit. In the present work, we have developed few new dimeric (Gemini) bisbenzimidazole ligands (Figure 5), in which the spacer joining the two bisbenzimidazole units have been varied using oligooxyethylene units of different length. Herein we show the interaction of each of these ligands, with the G-quadruplex DNA, derived from oligodeoxynucleotides d(T2AG3)4 and d(T2AG3)8, which fold into a monomeric and dimeric (having two folded G-tetrad units) G-quadruplex DNA, respectively. We also present evidence that the G-quadruplex DNA structure formed by these sequences in K+ solution in presence of the ligands is parallel, with unusual stability, and the spacer length between the two bisbenzimidazole units has critical role on the G-quadruplex stability, particularly on the G-quadruplex structures formed by the 48-mer sequence. The computational aspects of the ligand-G-quadruplex DNA association have also been analyzed. Interestingly, the gemini ligand having longer spacer was highly potent in the inhibition of telomerase activity than the corresponding gemini ligands having shorter spacer or the monomeric ligand. Also, the dimeric ligands are more cytotoxic toward the cancer cells than normal cells.
Figure 5. Chemical structures of the monomeric and gemini ligands used in this study.
Chapter 6. Stabilization and Structural Alteration of G-Quadruplex DNA made from Human Telomeric Repeat Mediated by Novel Benzimidazole Derivatives based on Tröger’s Base
Ligand-induced stabilization of G-quadruplex formation by the telomeric DNA single stranded 3'-overhang is a nice strategy to inhibit telomerase from catalyzing telomeric DNA synthesis and form capping telomeric ends. Herein we present the first report of the interactions of two novel bisbenzimidazoles (TBBz1 and TBBz2)(Figure 6) based on the Tröger’s base skeleton with the G-quadruplex DNA. These molecules stabilize the G-quadruplex DNA derived from a human telomeric sequence. Significantly strong binding affinity of these molecules to G-quadruplex DNA relative to duplex DNA was observed by CD spectroscopy, thermal denaturation and UV-vis titration studies. The above results obtained are in excellent agreement with the biological activity, measured in vitro using a modified TRAP assay. Additionally exposure of cancer cells to these compounds showed a remarkable decrease in the population growth. Also, it has been observed that the ligands are selectively more cytotoxic toward the cancerous cells than the corresponding noncancerous cells. To understand further, the ligand-G-quadruplex DNA complexes were investigated by computational molecular modeling. This provided additional insights on the structure activity relationship. Computational studies suggest that the adaptive scaffold not only allows these ligands to occupy the G-quartet but also binds with the grooves of the G-quadruplex DNA.
Figure 6. Chemical structures of the ligands, TBBz1 and TBBz2 used in this study,
(For structural formula pl see the abstact.pdf file.)
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Réplication et maintenance des télomères chez Schizosaccharomyces pombe : Rôle du complexe RPA dans la prévention ou la résolution de structures secondaires de type G-quadruplexes / Replication and maintenance of telomeres : Role of RPA to prevent or resolve secondary structures like G-quadruplexes in Schizosaccharomyces pombeAudry, Julien 24 April 2015 (has links)
Les télomères sont des structures nucléoprotéiques protégeant l’extrémité des chromosomes de la dégradation et assurant la réplication de l’ADN terminal. En effet, de nombreuses protéines de réplication sont impliquées dans le maintien de ces structures, comme le complexe RPA (Replication Protein A). Ce complexe très conservé chez les eucaryotes se fixe à l’ADN simple brin et est impliqué dans la réplication, les mécanismes de recombinaison et la réparation de l’ADN. Chez S.pombe, la mutation ponctuelle de la sous-unité RPA1 (Rpa1-D223Y) provoque le raccourcissement des télomères. Dans cette étude, nous montrons que cette mutation provoque l’accumulation de structures aberrantes de haut poids moléculaire aux télomères corrélant avec une présence persistante de Polα aux télomères suggérant une accumulation de structures sur le brin riche en G. Nous avons pu mettre en évidence que la surexpression d’hélicases de la famille Pif1 incluant S.cerevisiae Pif1 et PIF1 humain ainsi que Pfh1 (S.pombe) sont capable de restaurer une longueur de télomères sauvage dans mutant rpa1-D223Y. Ces résultats suggèrent que RPA pourrait empêcher l’accumulation de G4 au niveau du brin retardé télomérique afin de faciliter l’élongation des télomères par la télomérase. De plus, des expériences in vitro ont montré que la mutation correspondante de RPA1 humain réduisait spécifiquement l’affinité de RPA pour le simple brin télomérique humain dans les conditions ou il forme des G4.Enfin l’étude de la stabilité de séquences répétées formant des G4 (minisatellite CEB25), chez S.pombe, a permis de renforcer l’hypothèse selon laquelle RPA pourrait empêcher la formation ou aiderait à la résolution de G4. / Telomeres are nucleoprotein structures that protect chromosome ends from degradation and ensure replication of the terminal DNA. In fact, many of replication proteins are involved in telomere maintenance, like RPA (Replication Protein A). RPA is a highly conserved heterotrimeric single-stranded DNA-binding protein involved in DNA replication, recombination and repair. In S. pombe a mutation in the largest RPA subunit (Rpa1-D223Y) leads to substantial telomere shortening. In this study, we found that the D223Y mutation leads to the accumulation of aberrant secondary structures at telomeres. The presence of these secondary DNA structures correlates with a high association of Polα with telomeres suggesting that this mutation impairs lagging strand (G-rich) telomere replication. Strikingly, heterologous expression of the budding yeast Pif1 known to efficiently unwind G-quadruplex, human PIF1 and Phf1 (homolog of Pif1 in S.pombe) rescue the telomeric length defects of the D223Y cells. Furthermore, in vitro data show that the identical D to Y mutation in human RPA specifically affects its ability to bind G-quadruplex. We propose that RPA prevents the formation of G-quadruplex structures at lagging strand telomeres to facilitate telomerase action at telomeres. Furthermore, the study, in S.pombe, of the stability of G-rich repeat sequences (minisatellite CEB25) as known to form G4 enforce the hypothesis that RPA can prevents the formation of G4 or helps to solve this structure.
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