Global ETD Search

11	The Effect of Molecular Crowding on the Stability of Human c-MYC Promoter Sequence i-motif at Neutral pH Cui, Jingjing 17 August 2013 (has links) The oncogene c-MYC has guanine-rich and complementary cytosine-rich sequences in its P1 promoter region. The P1 promoter is responsible for over 90% of the c-MYC expression. Downregulation of c-MYC expression represents a novel therapeutic approach to more than 50% of all cancers. A stable i-motif formed by the c-MYC C-rich sequence would be an attractive target for cancer treatment. We have previously shown that c-MYC promoter sequences can form stable i-motifs in acidic solution (pH 4.5-5.5). The question is whether c-MYC promoter sequence i-motif will be stable at physiological pH. In this work, we have investigated the stability of mutant c-MYC i-motif in solutions having pH values from 4 to 7 and containing co-solutes or molecular crowding agents. The crowded nuclear environment was modeled by the addition of polyethylene glycol (PEG, having molecular weights from 200 to 12000 g/mol) at concentrations of 10% to 40% w/w. Circular dichroism spectroscopy (CD) and differential scanning calorimetry (DSC) were used to establish the presence and stability of c-MYC i-motifs in buffer solutions having pH values of 4 to 7. The results of these studies are: 1) the addition of up to 20% w/w glycerol does not increase i-motif stability, 2) the addition of 30% PEG results in an increase in i-motif stability to pH values as high as 6.7, 3) i-motif stability is increased with increased PEG concentration and increased PEG molecular weight, and 4) the effects of PEG size and concentration are not linear, with larger PEGs forming DNA/PEG complexes, which destabilize the i-motif. In summary, we have shown that the c-MYC i-motif can exist as a stable structure at pH as high as 6.7 in a crowded environment. Molecular crowding, largely an excluded volume effect, drives the formation of the more compact i-motif, even at higher pH values where the cytosine imino-nitrogen is deprotonated and neutral C-C pairs can form only two H-bonds. Based on this research, it seems possible that a stable c-MYC promoter sequence i-motif could form at physiological pH and would be a reasonable drug target for new cancer therapies. DSC CD c-MYC molecular crowding PEG polyethylene glycol co-solute i-motif
12	Synthèse et étude d'ADN et d'ARN G-quadruplexes à topologies contrôlées. Applications pour la caractérisation et la sélection de ligands / Synthesis and study of topologically controlled DNA and RNA G-quadruplexes. Applications for the characterization and the selection of ligands Bonnat, Laureen 19 December 2017 (has links) Les acides nucléiques riches en guanines ou en cytosines peuvent se replier sur eux-mêmes et former des systèmes tétramériques tels que les G-quadruplexes (G4) ou les i-motifs. Ces motifs, abondamment représentés dans certaines régions du génome humain semblent contribuer à la régulation cellulaire et suscitent depuis plusieurs années un intérêt grandissant. Ils sont notamment présents dans la région télomérique, mais aussi dans les promoteurs d’oncogènes ou au sein des génomes viraux et sont impliqués dans certaines pathologies humaines. Ils représentent ainsi des cibles thérapeutiques et diagnostiques potentielles. Cependant, les G4 adoptent in-vitro des topologies variées qui compliquent le développement de ligands spécifiques et affins. Dans ce contexte, le laboratoire a développé le concept du TASQ pour ‘‘Template Assembled Synthetic G-Quadruplex’’ dans le but d'accéder à des G4 se structurant en une topologie définie.Le premier chapitre décrit l’assemblage de mimes de motifs G4 contraints en une topologie unique. En utilisant un gabarit cyclodécapeptide rigide et différentes méthodes de conjugaison, nous avons assemblé des motifs G4 ARN parallèle et hybride ADN/ARN dérivant de la séquence télomérique ainsi qu’un motif G4 d’ADN présent dans la séquence promotrice du VIH-1. L’utilisation du concept TASQ nous a également permis de préparer un motif G-triplexe (G3), intermédiaire à la formation des motifs G4. Nous avons montré une forte stabilisation de tous les édifices G4 contraints ainsi préparés.Le second chapitre concerne les études de caractérisation et de sélection de ligands vis-à-vis des motifs G4 et G3 contraints. La caractérisation repose sur l’évaluation de l’affinité et de la sélectivité de différentes familles de ligands pour ces édifices, par résonance plasmonique de surface ou par interférométrie bio-couche. La sélection de ligands a été réalisée par la méthode SELEX dans le but d’obtenir des aptamères affins et spécifiques d’un motif G4 contraint. / Guanines or cytosines rich nucleic acids can fold into tetrameric G-quadruplexes (G4) or i-motifs structures. G4 motifs are found within the human genome and should contribute to cellular regulation. In particular G4 are found at telomeric region and also in promoters of oncogenes or within viral genomes. They are suspected of participating in the regulation of human pathologies and have therefore been envisioned as potential therapeutic and diagnostic targets. However, the intrinsic conformational polymorphism of G4 motifs complicates the development of specific and affine ligands. In this context, the laboratory has developed the TASQ concept for "Template Assembled Synthetic G-Quadruplex" with the aim to obtain a defined G4 topology.The first chapter reports on the assembly on the peptide template of RNA and DNA:RNA hybrid G4 structures that derive from the human telomeric sequence as well as of DNA G4 structure found within the HIV virus promoter. G-triplex (G3) motif which is supposed to be an intermediate during the formation of the G4 motifs has also been prepared. By using appropriate ligations of the oligonucleotide strands on the peptide template we were able to control the folding of G-quadruplex motifs and stabilize them.The second chapter reports the studies for the characterization and the selection of ligands against G4 and G3 motifs. The evaluation of the affinity and selectivity of different families of ligands for these constrain motifs was performed by using surface plasmon resonance or by bio-layer interferometry. The selection of ligands was carried out by the SELEX method in order to obtain affine and specific aptamers of a constrained G4 motif. ADN ARN G-quadruplexe G-triplexe G-Quadruplex G-triplex I-motif Chemoselective ligation Cyclodecapeptidic scaffold SPR SELEX 540
13	Folding Based DNA Sensor and Switch:Responsive Hairpin, Quadruplex and i-Motif Structures Chen, Kuan-liang 03 August 2010 (has links) The study for surfaced-immobilized nucleic acid probes in nanometer region in response to hybridization and to discrimination ofdifferent target nuclei acids. The hairpin locked nucleic acid (LNA-HP) isselected to be the probe molecule, and target molecules include perfect complementary (PC) and single mismatch (1MM). The self-assembledLNA-HP molecular nanospot is successfully prepared by liquid phaseAFM (Atomic Force Microscope)-based nanolithography technique, then in situ hybridization is carried out by using different targets (PC/1MM).To obtain the information of structure change, we use AFM to analyze therelative heights in the process of hybridization. The experimental results point out that (1) the structure changes of surface probe molecules maycorrelate with the AFM signal when target sequence hybridizes to the probe, (2) miniaturization of the size of the nucleic acid probe may promote hybridization efficiency and enhance the discrimination between PC and 1MM. Studies on whether the different chemical impetus in solution can affect conformation of the human telomeric DNA of sequence is conducted. A human talomeric DNA composed of ( 5¡¦-TTAGGG-3¡¦:5¡¦-CCCTAA-3¡¦ ) repeats, with a 100-200 nt ( T2AG3 ) repetitive unit overhang at 3¡¦ ends is chosen. This extended single-stranded sequence is called G-rich DNA, which forms the special G-quadruplex structure in solution containing sodium ions or potassium ions. The single-stranded sequence composed of ( C3TA2 ) repetitive units called C-rich DNA displays the i-motif folded structure in the low pH environment. These biomimetic DNA¡¦s are thiol-modified to self-assemble on gold surfaces. Separate measurements with AFM (the molecular thickness and rootmean- square roughness of the self-assembly monolayer of DNA ) and CD( circular dichroism ) ( structure characterization ) confirm the conformational changes of G-rich and C-rich DNA¡¦s on gold surface are indeed dependent of the presence of cations and protons. quadruplex structure atomic force microscope DNA hybridization hairpin locked nucleic acid circular dichroism human telomeric DNA single mismatch i-motif structure
14	Synthèse et utilisation de mimes de quadruplexes pour l'évaluation de ligands Bonnet, Romaric 17 December 2012 (has links) (PDF) Synthèse et utilisation de mimes de quadruplexes contraints pour l'évaluation de ligands II est maintenant bien connu que l'ADN simple brin peut s'associer sous différentes conformations telles que la double hélice, les triplexes, les i-motifs ou bien encore les G-quadruplexes. Ces dernières années les structures de type quadruplexes (G-quadruplexes et i-motif) ont suscité un certain intérêt notamment pour leur implications au niveau cellulaire (maintenance des télomères, activation de gènes...). C'est pourquoi de nombreuses équipes travaillent sur le développement de ligands affins pour ces structures qui pourraient agir en tant qu'anticancéreux. Cependant, le fait que les quadruplexes présentent un polymorphisme important(variabilité du nombre de brins dans la structure, des différents types de boucles et de l'orientation des brins) rend la compréhension des interactions entre un ligand et le quadruplexe plus difficile. Dans ce contexte, l'équipe développe un nouveau concept, " Template Assisted Synthesis of Quadruplexes " (TASQ) dont le but est d'obtenir un quadruplexe ne présentant qu'une topologie de façon contrôlée afin de permettre des études plus précises sur la façon dont un ligand pourrait interagir avec les quadruplexes. La première partie de ce manuscrit reporte l'évaluation par résonnance plasmonique de surface de complexes métalliques en tant que ligands de G-quadruplexe. Ces études reposent sur l'utilisation d'un premier mime de G-quadruplexe parallèle sur lequel deux séries de complexes sont testées : des métalloporphyrines et des ligands de type salphen. La seconde partie du manuscrit décrit la synthèse de mimes de G-quadruplexes antiparallèle. Elle repose sur l'utilisation du gabarit peptidique qui relié aux séquences spécifiques d'oligonucléotides de façon adéquat contraint la structure. Pour se faire, deux réactions chimiosélectives ont été utilisées : la cycloaddition 1,3 dipolaire de Huisgen et la ligation oxime. Les travaux reportés concernent trois types de structure mimant un i-motifs, des G-quadruplexes tétramoléculaires ou bimoléculaires. G-quadruplexe I-motif SPR Gabarit peptidique Réactions chimiosélectives Chimie supramoléculaire
15	The Elucidation of the Mechanism of Meiotic Chromosome Synapsis in Saccharomyces Cerevisiae : Insights into the Function of Synaptonemal Complex, Hop1 and Red1, Proteins and the Significance of DNA Quadruplex Structures Kshirsagar, Rucha January 2016 (has links) (PDF) Meiosis is a specialized type of cell division where two rounds of chromosome segregation follow a single round of DNA duplication resulting in the formation of four haploid daughter cells. Once the DNA replication is complete, the homologous chromosomes pair and recombine during the meiotic prophase I, giving rise to genetic diversity in the gametes. The process of homology search during meiosis is broadly divided into recombination-dependent (involves the formation of double-strand breaks) and recombination-independent mechanisms. In most eukaryotic organisms, pairing of homologs, recombination and chromosome segregation occurs in the context of a meiosis-specific proteinaceous structure, known as the synaptonemal complex (SC). The electron microscopic visualization of SC has revealed that the structure is tripartite with an electron-dense central element and two lateral elements that run longitudinally along the entire length of paired chromosomes. Transverse filaments are protein structures that connect the central region to the lateral elements. Genetic analyses in budding yeast indicate that mutations in SC components or defects in SC formation are associated with chromosome missegregation, aneuploidy and spore inviability. In humans, defects in SC assembly are linked to miscarriages, birth defects such as Down syndrome and development of certain types of cancer. In Saccharomyces cerevisiae, genetic screens have identified several mutants that exhibit defects in SC formation culminate in a decrease in the frequency of meiotic recombination, spore viability and improper chromosome segregation. Ten meiosis-specific proteins, viz. Hop1, Red1, Mek1, Hop2, Pch2, Zip1, Zip2, Zip3, Zip4 and Rec8, have been shown to be the bona fide components of SC and/or associated with SC function. S. cerevisiae HOP1 (HOmolog Pairing) gene was isolated in a genetic screen for mutants that showed defects in homolog pairing and, consequently, reduced levels of interhomolog recombination (10% of wild-type). Amino acid sequence alignment together with genetic and biochemical analyses revealed that Hop1 is a 70 kDa protein with a centrally embedded essential zinc-finger motif (Cys2/Cys2) and functions in polymeric form. Previous biochemical studies have also shown that Hop1 is a structure-specific DNA binding protein, which exhibits high affinity for the Holliday junction (HJ) suggesting a role of this protein in branch migration of the HJ. Furthermore, Hop1 displays high affinity for G-quadruplex structures (herein after referred to as GQ) and also promotes the formation of GQ from unfolded G-rich oligonucleotides. Strikingly, Hop1 promotes pairing between two double-stranded DNA molecules via G/C-rich sequence as well as intra- and inter-molecular pairing of duplex DNA molecules. Structure-function analysis suggested that Hop1 has a modular organization consisting of a protease-sensitive N-terminal, HORMA domain (characterized in Hop1, Rev7, Mad2 proteins) and protease-resistant C-terminal domain, called Hop1CTD. Advances in the field of DNA quadruplex structures suggest a significant role for these structures in a variety of biological functions such as signal transduction, DNA replication, recombination, gene expression, sister chromatid alignment etc. GQs and i-motif structures that arise within the G/C-rich regions of the genome of different organisms have been extensively characterized using biophysical, biochemical and cell biological approaches. Emerging studies with guanine- and cytosine-rich sequences of several promoters, telomeres and centromeres have revealed the formation of GQs and i-motif, respectively. Although the presence of GQs within cells has been demonstrated using G4-specific antibodies, in general, the in vivo existence of DNA quadruplex structures is the subject of an ongoing debate. However, the identification and isolation of proteins that bind and process these structures support the idea of their in vivo existence. In S. cerevisiae, genome-wide survey to identify conserved GQs has revealed the presence of ~1400 GQ forming sequences. Additionally, these potential GQ forming motifs were found in close proximity to promoters, rDNA and mitosis- and meiosis-specific double-strand break sites (DSBs). Meiotic recombination in S. cerevisiae as well as humans occurs at meiosis-specific double-strand break (DSBs) sites that are embedded within the G/C-rich sequences. However, much less is known about the structural features and functional significance of DNA quadruplex motifs in sister chromatid alignment N during meiosis. Therefore, one of the aims of the studies described in this thesis was to investigate the relationship between the G/C-rich motif at a meiosis-specific DSB site in S. cerevisiae and its ability to form GQ and i-motif structures. To test this hypothesis, we chose a G/C-rich motif at a meiosis-specific DSB site located between co-ordinates 1242526 to 1242550 on chromosome IV of S. cerevisiae. Using multiple techniques such as native gel electrophoresis, circular dichroism spectroscopy, 2D NMR and chemical foot printing, we show that G-rich motif derived from the meiosis-specific DSB folds into an intramolecular GQ and the complementary C-rich sequence folds into an intramolecular i-motif, the latter under acidic conditions. Interestingly, we found that the C-rich strand folds into i-motif at near neutral pH in the presence of cell-mimicking molecular crowding agents. The NMR data, consistent with our biochemical and biophysical analyses, confirmed the formation of a stable i-motif structure. To further elucidate the impact of these quadruplex structures on DNA replication in vitro, we carried out DNA polymerase stop assay with a template DNA containing either the G-rich or the C-rich sequence. Primer extension assays carried out with Taq polymerase and G-rich template blocked the polymerase at a site that corresponded to the formation of an intramolecular GQ. Likewise, primer extension reactions carried out with KOD-Plus DNA polymerase and C-rich template led to the generation of a stop-product at the site of the formation of intramolecular I -motif under acidic conditions (pH 4.5 and pH 5.5). However, polymerase stop assay performed in the presence of single-walled carbon nanotubes (SWNTs) that stabilize I -motif at physiological pH blocked the polymerase at the site of intramolecular I -motif formation, indicating the possible existence of i-motif in the cellular context. Taken together, these results revealed that the G/C-rich motif at the meiosis-specific DSB site folds into GQ and i-motif structures in vitro. Our in vitro analyses were in line with our in vivo analysis that examined the ability of the G/C-rich motif to fold into quadruplex structures in S. cerevisiae cells. Qualitative microscopic analysis and quantitative analysis with plasmid constructs that harbour the GQ or i-motif forming sequence revealed a significant decrease in the GFP expression levels in comparison to the control. More importantly, all the assays performed with the corresponding mutant sequences under identical experimental conditions did not yield any quadruplex structures, suggesting the involvement of contagious guanine and cytosine residues in the structure formation. Prompted by our earlier results that revealed high binding affinity of Hop1 for GQ, we wished to understand the role of the GQ and i-motif structures during meiosis by analysing their interaction with Hop1 and its truncated variants (HORMA and Hop1CTD). In agreement with our previous observations, Hop1 and Hop1CTD associated preferentially with GQ DNA. Interestingly, whereas the full-length Hop1 showed much weaker binding affinity for i-motif DNA, Hop1 C-terminal fragment but not its N-terminal fragment exhibited robust i-motif DNA binding activity. We have previously demonstrated that Hop1 promotes intermolecular synapsis between synthetic duplex DNA molecules containing a G/C-rich sequence. Hence, to understand the functional role of the quadruplex structures formed at the meiosis-specific G/C-rich motif, we examined the ability of Hop1 to promote pairing between linear duplex DNA helices containing the G/C-rich motif. DNA pairing assay indicated that binding of Hop1 to the G/C-rich duplex DNA resulted in the formation of a side-by-side synapsis product. Under similar conditions, Hop1 was unable to pair mutant duplex DNA molecules suggesting the involvement of the G/C-rich motif in the formation of the synapsis product. Our results were substantiated by the observation that yeast Rad17 failed to promote pairing between duplex DNA molecules with a centrally embedded G/C-rich motif. Altogether, these results provide important structural and functional insights into the role of quadruplex structures in meiotic pairing of homologous chromosomes. The second part of the thesis focuses on the biochemical and functional properties of Red1 protein, a component of S. cerevisiae lateral element. RED1 was identified in a screen for meiotic lethal, sporulation proficient mutants. Genetic, biochemical and microscopic analyses have demonstrated the physical interaction between Hop1 and Red1. Given this, hop1 and red1 mutants display similar phenotypes such as chromosome missegregation and spore inviability and thus are placed under the same epistasis group. However, unlike hop1 mutants, red1 mutants show complete absence of SC. RED1 overexpression suppressed certain non-null hop1 phenotypes, indicating that these proteins may have partially overlapping functions. Further, although the functional significance is unknown, chromatin immunoprecipitation studies have revealed the localization of Red1 to the GC-rich regions (R-bands) in the genome, considered to be meiotic recombination hotspots. Although the aforementioned genetic studies suggest an important role for Red1 in meiosis, the exact molecular function of Red1 in meiotic recombination remains to be elucidated. To explore the biochemical properties of Red1, we isolated the S. cerevisiae RED1 gene, cloned, overexpressed, and purified the protein to near homogeneity. Immunoprecipitation assays using meiotic cells extracts suggested that Red1 exists as a Homodimer linked by disulphide-bonds under physiological conditions. We characterized the DNA binding properties of Red1 by analysing its interaction with recombination intermediates that are likely to form during meiotic recombination. Protein-DNA interaction assays revealed that Red1 exhibits binding preference for the Holliday junction over replication fork and other recombination intermediates. Notably, Red1 displayed ~40-fold higher binding affinity for GQ in comparison with HJ. The observation that Red1 binds robustly to GQs prompted us to examine if Red1 could promote pairing between duplex DNA helices with the G/C-rich sequences similar to Hop1. Interestingly, we found that Red1 failed to promote pairing between dsDNA molecules but potentiated Hop1 mediated pairing between duplex DNA molecules. Our AFM studies with linear and circular DNA molecules along with Red1 suggested a possible role of Red1 in DNA condensation, bridging and pairing of double-stranded DNA helices. Bioinformatics analysis of Red1 indicated the lack of sequence or structural similarity to any of the known proteins. To elucidate structure-function relationship of Red1, we generated several N- and C-terminal Red1 truncations and studied their DNA binding properties. Our results indicated that the N-terminal region comprising of 678 amino acid residues constitutes the DNA-binding region of Red1. The N-terminal region, called RNTF-II, displayed similar substrate specificity comparable to that of full-length Red1. Interestingly, site-directed mutagenesis studies with the Red1 C-terminal region revealed the involvement of two cysteine residues at position 704 and 707 in the disulfide bond mediated intermolecular dimer formation. Finally, to understand the functional significance of Red1 truncations we analyzed the subcellular localization of Red1 and its truncations. We made translation fusions of RED1 and its truncations by placing their corresponding nucleotide sequences downstream of GFP coding sequence in yeast expression vector. Confocal microscopy studies with S. cerevisiae cells transformed with the individual plasmid constructs indicated that the N-terminal variants localized to the nucleus, whereas the C-terminal variants did not localize to the nucleus. These results suggest that NLS-like motifs are embedded in the N-terminal region of the protein. Furthermore, other results indicated that the N-terminal region contains functions such as DNA-binding and intermolecular bridging of non-contiguous DNA segments. Altogether, these findings, on the one hand, provide insights into the molecular mechanism underlying the functions of Hop1 and Red1 proteins and, on the other, support a role for DNA quadruplex structures in meiotic chromosome synapsis and recombination. DNA Guadruplex Structure Red1 Protein Hop1 Protein Synaptonemal Complex Synaptonemal Complex Proteins Holliday Junction (HJ) G-quadruplex i-motif Biochemistry
16	Excited State Dynamics of Bioinspired Materials: Triplet Formation in Silver(I) Mediated Cytosine Base Pairs and Chemical Disorder in DOPA Melanin Kohl, Forrest Robert January 2021 (has links) No description available. Physical Chemistry Biophysics DNA Melanin Silver i-motif Triplets Excimer Photoprotection self-assembly radicals chemical disorder transient absorption infrared spectroscopy
17	Molecular Population Dynamics of DNA Tetraplexes using Magneto-Optical Tweezers Selvam, Sangeetha 22 February 2018 (has links) No description available. Analytical Chemistry Biochemistry Biophysics Chemistry DNA Supercoil single-molecule optical tweezers magneto-optical tweezers G-quadruplex i-motif torsionally constrained DNA
18	Structure Function Studies Of Biologically Important Simple Repetitive DNA Sequences Pataskar, Shashank S. 01 1900 (has links) The recent explosion of DNA sequence information has provided compelling evidence for the following facts. (1) Simple repetitive sequences-microsatellites and minisatellites occur commonly in the human genome and (2) these repetitive DNA sequences could play an important role in the regulation of various genetic processes including modulation of gene expression. These sequences exhibit extensive polymorphism in both length and the composition between species and between organisms of the same species and even cells of the same organism. The repetitive DNA sequences also exhibit structural polymorphism depending on the sequence composition. The functional significance of repetitive DNA is a well-established fact. The work done in many laboratories including ours has conclusively documented the functional role played by repetitive sequences in various cellular processes. Structural studies have established the sequence requirement for various non-B DNA structures and the functional significance of these unusual DNA structures is becoming increasingly clear. The structures that were characterised earlier purely from conformation point of view have aroused interest after the recent realisation that these structures could be formed in vivo when cloned in a supercoiled plasmid. The discovery of novel type of dynamic mutations where intragenic amplifications of trinucleotide repeats is associated with phenotypic changes causing many neurodegenerative disorders has provided the most compelling evidence for the importance of simple repeats in the etiology of these disorders. Secondary structures adopted by these simple repeats is a common causative factor in the mechanism of expansion of these repeats. This realisation prompted many investigations into the relationship between the DNA sequence, structure and molecular basis of dynamic mutation. Many experimental evidences have implicated paranemic DNA structures in various biological processes, especially in the regulation of gene expression. Earlier work done in our laboratory on the structure function relationship of repetitive DNA sequences provided experimental evidence for the role of paranemic DNA structure in the regulation of gene expression. It was demonstrated that intramolecular triplex potential sequences within a gene downregulate its expression in vivo (Sarkar and Brahmachari (1992) Nucleic Acids Res., 20, 5713-5718). Similarly the effect of cruciform structure forming sequences on gene expression was also documented. Sequence specific alterations in DNA structures were studied in our laboratory using a variety of biophysical and biochemical techniques. An intramolecular, antiparallel tetraplex structure was proposed for human telomeric repeat sequences (Balagurumoorthy, et al., (1994) J. Biol. Chem., 269, 21858-21869). The telomeric repeats are not only present at the end of chromosomes but they are also present at many interstitial sites in the human genome. Database search reveals that the human telomeric sequences as well as similar sequences with minor variations are present at many locations in the human genome. Telomeric repeats are GC rich sequences with the G rich strand protruding as a 3' end overhang at the end of chromosomes. When human telomeric repeats are cloned in a supercoiled plasmid, the C rich strand adopts a hairpin like conformation where as the G-rich strand extrudes into a quadruplex structure. However, the biological significance of these structures in vivo still remains to be elucidated completely. The role of a putative tetraplex DNA structure in the insulin gene linked polymorphic region of the human insulin gene in vivo in the regulation of expression of the insulin gene has been suggested. In this context, we have addressed the question whether the telomeric repeats when present within a gene affect its expression in vivol If so, what would be the possible mechanism? An attempt has been made to understand the effect of presence of telomeric repeats within a gene on its expression. The details of these studies have been presented in Chapter 2 of this thesis. Contrary to telomeric repeats which provide stability to the chromosomes, recently expansion of a GC rich dodecamer repeat upstream of cystatin B gene (chromosome 21q) has been shown to be the most common mutation associated with Progressive Myoclonus Epilepsy (EPM1) of Unverricht-Lundberg type. Two to three copies of the repeat (CCCCGCCCCGCG)n are present in normal individuals whereas the affected individuals have 30-75 copies of this repeat. The expression of cystatin B gene is reduced in patients in a cell specific manner. The repeat also shows intergenerational variability. The exact mechanism of expansion of this repeat is not known. In the case of trinucleotide repeat expansion, it is shown that the structure adopted by the repeat plays an important role in the mechanism of expansion and that some of the secondary structures adopted by trinucleotide repeats could be inherently mutagenic conformations. In order to understand the mechanism of expansion EPM1 dodecamer repeat, the work reported in this thesis was carried out with the following objectives. • To understand the structure of G rich and C-rich strands of EPM1 repeat. • To understand the variations in the structure with the increase in the length and its possible implications in the mechanism of expansion of EPM 1 repeat. Studies aimed with these objectives are presented in chapters 3, 4 and 5 of the thesis. Chapter 1 provides a general introduction to repetitive DNA, the various structures adopted by repetitive DNA sequences in the genome, the functional significance of the various simple repetitive DNA sequences in the genome has been presented. An account of trinucleotide repeat expansion and associated disorders, non-trinucleotide repeat expansions and associated disorders has been presented. The various non B-DNA structures adopted these repeats and their implications in the mechanism of expansion have been discussed. Chapter 2 describes in frame cloning of human telomeric repeats d(G3T2A)3G3 in the N-terminal region of β-galactosidase gene. The effect of such repeat Sequences on transcription elongation in vivo has been studied using E.coli as a model system. The 3.5 copies of human telomeric repeat sequences were cloned in the sense strand of plasmid pBluescriptllSK+ so as to create plasmid clone pSBQ8 and in the template strand of plasmid pBluescriptHKS+ so as to create clone pSBRQ8. One dimensional chloroquine gel shift assay indicated presence of an unwound structure in pSBQ8 and pSBRQ8. β-galactosidase activity assay suggested downregulation of the gene in vivo. In the case of plasmid pSBQ8 the difference in β-galactosidase activity was approximately 6 fold as compared to the parent plasmid pBluescriptIISK+ whereas in the case of pSBRQ8 the difference in β-galactosidase activity was approximately 8 fold as compared to the control pBluescriptIIKS+. The analysis of β-galactosidase transcript showed that full length transcript was formed in the case of pSBQ8. Full length transcript was not formed in the case of pSBRQ8. We propose that in the case of pSBQ8 the gene expression is inhibited in steps subsequent to transcription elongation. In the case of pSBRQ8, we propose that quadruplex structure may be formed by the template strand at the DNA level thereby blocking transcription elongation step. Chapter 3 describes studies aimed at understanding the structure of G-rich strand (referred to as G strand) of Progressive Myoclonus Epilepsy (EPM1) repeat. The sequence of the G strand of dodecamer EPM1 repeat is d(GGGGCGGGGCGC)n. Oligoucleotides containing one (12mer), two (24mer) and three(36mer) were synthesised. These oligonucleotides are referred to as dG12, dG24 and dG36 respectively. Structural studies were carried out using CD spectroscopy, UV melting, non-denaturing gel electrophoresis and chemical and enzymatic probing. The G strand oligonucleotides showed enhanced gel elecrophoretic mobility in the presence of monovalent cations KCl and NaCl. Oligonucleotide dG12 also showed retarded species on non-denaturing gel in the presence of 70mM KCl indicating intermolecular associations. Oligonucleotides dG24 and dG36 predominantly formed intramolecular structures which migrated anomalously faster than the expected size. The CD spectrum for dG12 showed an intense positive band at 260nm and a negative band at 240nm in the presence of KCl indicative of an intermolecular, parallel G quartet structure. The CD spectra of dG24 and dG36 showed 260nm positive peak, 240nm negative peak along with a positive band around 290nm. This is indicative of folded back structure. These findings support the results of non-denaturing gel electrophoresis of G strand oligonucleotides. The UV melting profiles suggested increase in the stability with the increase in the length. These structures were further characterised by PI nuclease and chemical probing using DMS and DEPC. The structural studies with G-rich strand of EPM1 dodecamer repeat showed that this repeat motif adopts intramolecularly folded structures with increase in the length of the repeat thereby favouring slippage during replication. Chapter 4 deals with the studies aimed at understanding the structure at acidic pH of C-rich strand (referred to as C strand) of Progressive Myoclonus Epilepsy (EPM1) repeat. The sequence of the C strand of dodecamer EPM1 repeat is d(CCCCGCCCCGCG)n. The C rich oligonucleotides are known to form a four stranded structure called i-motif at acidic pH involving intercalated base pairs. The i-motif consists of two parallel stranded, base paired duplexes are arranged in an antiparallel orientation. Since, the base pairs of one base paired duplex intercalate into those of the other duplex, the structure is called as i-motif. We have investigated structure of C strand of EPM1 repeat by circular dichroism (CD), native polyacrylamide gel electrophoresis and UV melting. Oligonucleotide dC12 showed two bands of which the major band was retarded on the native gel (pH 5.0) at low temperature suggesting that dC12 predominantly formed intermolecular structure, Oligonucleotides dC24 and dC36 migrated anomalously faster than the expected size indicating formation of compact, intramolecularly folded structures. Circular dichroism studies indicate that, all the oligonucleotides displayed an intense positive band near 285nm, a negative band around 260nm with a cross over at 270nm, This is a characteristic CD signature for an i-motif structure and reflects the presence of secondary structure due to formation of hydrogen bonded pairs between protonated cytosines. All the C strand oligonucleotides showed hyperchromism at 265nm, which is an isobestic wavelength for C protonation. Studies described in this chapter suggest an intramolecular i-motif structure for dC24 and dC36 and an intermolecular i-motif for oligonucleotide dC12. In addition, it was interesting to note that inspite of the presence of G residues, the stretch of C residues could adopt i-motif structure. Although these structures are formed at an acidic pH, it is indicative of formation of possible intramolecularly folded structure. Many reports have suggested the possibility of cytosine rich sequences adopting i-motif structure even at neutral pH. In order to test this possibility, structural studies were carried out on the C strand EPM1 oligonucleotides at pH 7.2 in the presence of 70mM NaCl. These studies have been described in Chapter 5. The investigations were done using CD spectroscopy, UV melting, native polyacrylamide gel electrophoresis, and chemical probing using hydroxylamine and PI nuclease. These studies indicate that all the C strand oligonucleotides form intramolecular, hairpin structure at physiological pH. All the three C strand oligonucleotides migrated anomalously faster on the native gel indicating the presence of a compact structure. The CD spectra at pH 7.2 showed a blue shift as compared to those at pH 5.0. This indicated absence of base pairs. The hydroxylamine chemical probing suggested presence of G-C Watson-Crick base pairs. The loop residues of the folded back hairpin structures were probed with PI nuclease. The C strand oligonucleotides showed possibility of formation of multiple hairpin structures with the increase in the length of the repeat. The propensity to form hairpin structures suggests a possibility of formation of slip loop structures during the replication process thereby promoting expansion of this repeat. Formation of folded back hairpin like structures is significant in terms of mechanism of expansion of this repeat. Chapter 6 is devoted to concluding remarks highlighting the significance of the experimental results presented in this thesis and their possible biological implications in the light of contemporary research. Biophysics DNA Structure Genomic Stability Slipped Strand DNA Repetitive Sequences Oligonucleotides Z-DNA Progressive Myoclonus Epilepsy (EPM1) Human Telomeric Repeats Hairpin Genome Gene Expression Dynamic Mutation Slipped Loop Structure i-motif Structure Dynamic Mutation Enhanced Myoclonus Epilepsy
19	Single Molecule Fluorescence and Force Measurements on Non-Canonical DNA Structures Mustafa, Golam 17 March 2022 (has links) No description available. Biophysics Physics

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