Spelling suggestions: "subject:"DNA -- conformation"" "subject:"DNA -- konformation""
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DFT and NMR study of J-coupling in DNA nucleosides and nucleotides.January 2001 (has links)
Au Yuen-yee. / Thesis (M.Phil.)--Chinese University of Hong Kong, 2001. / Includes bibliographical references (leaves 140-152). / Abstracts in English and Chinese. / Abstract --- p.iii / Acknowledgements --- p.v / Chapter Chapter One: --- General Background and Introduction --- p.1 / Chapter 1 -1 --- Introduction --- p.1 / Chapter 1-2 --- Three-Bond Coupling Constants (3J) --- p.1 / Chapter 1-2-1 --- Development of the Karplus Equation --- p.1 / Chapter 1-2-2 --- Application of3J in the Conformational Analysis of Nucleic Acid --- p.4 / Chapter 1-2-3 --- Problem of Accuracy for3 J Measurement --- p.7 / Chapter 1-3 --- Two-Bond Coupling Constants (2J) --- p.7 / Chapter 1-3-1 --- The Use of the Projection Method --- p.7 / Chapter 1-3-2 --- 2J Coupling Constant Involving Hydrogen Bonds --- p.8 / Chapter 1-4 --- One-Bond Coupling Constants (1J) --- p.10 / Chapter 1-5 --- Conclusion --- p.11 / Chapter Chapter Two: --- Experimental Section / Chapter 2-1 --- Introduction --- p.12 / Chapter 2-2 --- Heteronuclear Multiple-Quantum Coherence (HMQC) Experiment --- p.12 / Chapter 2-3 --- Experimental Section --- p.15 / Chapter 2-3-1 --- Sample Preparation --- p.15 / Chapter 2-3-2 --- NMR Spectroscopy --- p.16 / Chapter Chapter Three: --- Theory of Nuclear Spin-Spin Coupling Constants --- p.18 / Chapter 3-1 --- Introduction --- p.18 / Chapter 3-2 --- Application of Finite Perturbation Theory on Nuclear Spin-Spin Coupling --- p.18 / Chapter 3-3 --- Methodology --- p.22 / Chapter Chapter Four: --- DFT and NMR Study of1JCH Coupling Constants --- p.28 / Chapter 4-1 --- Introduction --- p.28 / Chapter 4-2 --- Nomenclature and Definition of Structural Parametersin DNA and RNA --- p.28 / Chapter 4-2-1 --- "Nomenclature, Symbols and Atomic Numbering Schemes" --- p.28 / Chapter 4-2-2 --- Definition of Torsion Angles and their Rangesin Nucleotides --- p.31 / Chapter 4-2-3 --- Description of the Furanose Ring --- p.31 / Chapter 4-3 --- Results and Discussion --- p.37 / Chapter 4-3-1 --- Basis Set Effect --- p.37 / Chapter 4-3-2 --- Relative Conformational Energy Profiles --- p.37 / Chapter 4-3-3 --- Comparison of the Dependence of 1JCH Coupling Constants on Conformational Changes With and Without the DNA Backbone --- p.40 / Chapter 4-3-4 --- Effect of Backbone 3'- and 5'-Phosphate --- p.42 / Chapter 4-3-5 --- Effect of Glycosidic Torsion Anglex --- p.49 / Chapter 4-3-6 --- Effect of Ring Conformation with Fixed Glycosidic Torsion Anglex --- p.52 / Chapter 4-3-7 --- Effect of Torsion Angle α --- p.52 / Chapter 4-3-8 --- Effect of Torsion Angle β --- p.53 / Chapter 4-3-9 --- Effect of Torsion Angle γ --- p.56 / Chapter 4-3-10 --- Effect of Torsion Angle ε --- p.59 / Chapter 4-3-11 --- Effect of Torsion Angle ζ --- p.61 / Chapter 4-3-12 --- Effect of Base Pairing --- p.65 / Chapter 4-3-13 --- Effect of Base Stacking from the (n-1) and (n+1) Base --- p.65 / Chapter 4-3-14 --- Comparison of Experimental and Theoretical Data --- p.68 / Chapter 4-4 --- Conclusion --- p.74 / Chapter Chapter Five: --- DFT Study of 2JCH and 3JCH Coupling Constants --- p.79 / Chapter 5-1 --- Introduction --- p.79 / Chapter 5-2 --- Results and Discussion on 2JCH Coupling Constants --- p.79 / Chapter 5-2-1 --- Effect of Backbone 3'- and 5'-Phosphate --- p.79 / Chapter 5-2-2 --- Effect of Ring Conformation with Fixed Glycosidic Torsion Anglex --- p.82 / Chapter 5-2-3 --- Effect of Glycosidic Torsion Anglex --- p.87 / Chapter 5-2-4 --- Effect of Torsion Angleγ --- p.87 / Chapter 5-2-5 --- Effect of Torsion Angle ε --- p.90 / Chapter 5-2-6 --- Effect of Base Pairing --- p.90 / Chapter 5-2-7 --- Effect of Base Stacking from the (n-1) and (n+1) Base --- p.90 / Chapter 5-3 --- Results and Discussion on 3JCH Coupling Constants --- p.95 / Chapter 5-3-1 --- Effect of Backbone 3'- and 5'-Phosphate --- p.95 / Chapter 5-3-2 --- Effect of Ring Conformation with Fixed Glycosidic Torsion Anglex --- p.95 / Chapter 5-3-3 --- "Effect of Different Torsion Angles (X,α,β,γ,ε,and ζ)" --- p.100 / Chapter 5-3-4 --- Effect of Base Pairing --- p.100 / Chapter 5-3-5 --- Effect of Base Stacking from the (n-1) and (n+1) Base --- p.105 / Chapter 5-4 --- Conclusion --- p.105 / Chapter Chapter Six: --- Conclusion --- p.111 / Appendix A Product Operator Formalism on HMQC Pulse Scheme --- p.113 / Appendix B Finite Perturbation Theory --- p.115 / Appendix C Supplementary Figures of Chapter Four --- p.118 / Appendix D Some of the NMR Spectra --- p.134 / References --- p.140
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Stabilization of Z-DNA by demethylation of thymine bases : a crystallization and thermo-dynamic study of d(m⁵CGUAm⁵CG)Zhou, Guangwen 16 September 1991 (has links)
Graduation date: 1992
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Investigation of DNA conformation and enzyme-DNA systems using fluorescence techniquesMa, Long January 2012 (has links)
As a structural analogue of adenine (6-aminopurine), 2-aminopurine (2AP) is a powerful fluorescent probe, when substituted in DNA in place of the natural adenine. Time-resolved fluorescence measurements of 2AP-labeled oligonucleotides, together with steady-state spectroscopy give us an in-depth view of DNA-enzyme interactions, especially the conformational dynamics in solution phase. Herein, this technique has been extended to the study of the transient unzipping of DNA bases, to investigate the structure of three-way junction (3WJ), and the role of base unzipping in the mechanism of human flap endonuclease (FEN). Seven 2AP-labelled 3WJs were investigated, each containing only one 2AP base in place of adenine. In four of the 3WJs, 2AP was placed in the long duplex region of an arm; while in the other three 3WJs, 2AP was placed near or in the branch point. Comparative time-resolved fluorescence measurements on the 3WJs and corresponding ssDNA and dsDNA controls were made to study the base dynamics, in particular the possibility of unzipping in the vicinity of the branch point. In combination with single-molecule FRET measurements and molecular dynamics simulations, the local and global structure of a DNA 3WJ in solution could be unraveled. It was found to adopt a Y-shaped, pyramidal structure, in which the bases adjacent to the branch point are unzipped, despite the full Watson-Crick complementarity of the molecule. Human flap endonuclease (hFEN) is divalent metal ion-dependent phosphodiesterase. hFEN carries out structure-specific hydrolysis of 5’ bifurcated DNA endonucleolytically. Cleavage occurs at a position one nucleotide into the downstream duplex region. Previous structural, biochemical and modeling studies suggested a double-nucleotide unzipping mechanism at single/double strand junctions for scissile phosphate placement. To confirm this mechanism, 2AP time-resolved fluorescence spectroscopy was used to investigate nucleotide unzipping in hFEN substrates. 2AP was substituted at positions +1 and -1 (relative to the scissile phosphodiester) respectively, in double flap substrates. A series of hFEN mutants including Y40A, R100A, K93A, were used in this study. In the experiments, ssDNA, dsDNA substrates, DNA substrate-enzyme complexes were investigated in order to elucidate the enzyme-induced distortion of the substrate at the +1 and -1 positions. TseI is a thermophilic type II restriction enzyme which has ideal activity at an elevated temperature. It is able to recognise and cut the 5 bp palindromic sequence of 5’-GCWGC-3’ (W=A or T). A range of biophysical methods have been applied to investigate this enzyme, including size-exclusion chromatography; fluorescence anisotropy (Kd value determination); denaturing HPLC for DNA cleavage analysis on matched and mismatched substrates; fluorescence-based activity assay (KM, Vmax, kcat, specificity constant values determination); steady-state fluorescence measurements (DNA-enzyme interaction study). The DNA cleavage characteristics of TseI were fully studied and it was found that it cuts A:A and T:T mismatches in CAG and CTG repeats. This potentially makes it a useful tool for exploring unusual DNA structures containing super-long CAG and CTG repeats which are involved in the aetiology of some neurodegenerative diseases, such as Huntington’s disease (HD). EcoP15I is a type III restriction-modification enzyme whose recognition sequence is 5-CAGCAG-3’. Methyltransferase EcoP15I (M.EcoP15I) adds a methyl group to the second adenine, in the presence of cofactor S-adenosyl methionine (SAM). SDS-PAGE, densitometry and size-exclusion HPLC were applied to confirm that EcoP15I adopts a Res1Mod2 stoichiometry in solution. The large structural distortion of its substrate (base flipping) by M.EcoP15I was investigated by both steady-state and time-resolved fluorescence. Also, nine 120 mer DNA duplexes, each containing two reversely oriented recognition sites were used to study matched and mismatched sequence cleavage by R.EcoP15 and a cleavage pattern was revealed.
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Biophysical investigation of M-DNAWood, David Owen 31 May 2005
M-DNA is a complex formed between normal double-stranded DNA and the transition metal ions Zn2+, Ni2+, and Co2+ that is favoured by an alkaline pH. Previous studies have suggested that M-DNA formation involves replacement of the imino protons of G and T bases by the transition metal ions involved in forming the complex. Owing to the conductive properties of this unique DNA conformation, it has potential applications in nanotechnology and biosensing. This work was aimed at improving existing methods and developing new methods of characterizing M-DNA. The effects of base substitutions, particularly those of G and T, were evaluated in light of the proposed structure. Differences between M-DNA conformations induced by Zn2+ and Ni2+ were also investigated with a variety of techniques and compared to the effects of Cd2+ and Mg2+ on double-stranded DNA.
M-DNA formation and stability were studied with an ethidium bromide (EtBr) based assay, M-DNA induced fluorescence quenching of DNA labelled with fluorescein and a compatible quenching molecule, isothermal titration calorimetry (ITC), and surface plasmon resonance (SPR). Production of monoclonal antibodies against the conformation was also attempted but was unsuccessful. The EtBr-based assay showed Ni(II) M-DNA to be much more stable than Zn(II) M-DNA as a function of pH and in the presence of ethylenediaminetetraacetic acid. Sequence-dependency and the effect of base substitutions were measured as a function of pH. With regards to sequence, d(G)nd(C)n tracts were found to form the conformation most easily. Base substitutions with G and T analogues that lowered the pKa of these bases were found to stabilize M-DNA more strongly than other base substitutions. A combination of temperature-dependant EtBr and ITC assays showed M-DNA formation to be endothermic, and therefore entropy driven. The SPR studies demonstrated many qualitative differences between Zn(II) and Ni(II) M-DNA formation, allowed characterization of Zn2+, Ni2+, Cd2+, and Mg2+ complexes with single-stranded DNA, and provided unambiguous evidence that M-DNA formation results in very little denaturation of double-stranded DNA. Specifically, the SPR study showed Ni(II) M-DNA to be more stable than Zn(II) M-DNA in the absence of transition metal ions, but also showed that Ni(II) M-DNA required higher concentrations of Ni2+ than Zn2+ to fully form the respective M-DNA conformations. Finally, quenching studies demonstrated Zn(II) M-DNA formation over a pH range from 6.5 to 8.5 provided that a Zn2+:H+ ratio of roughly 105 was maintained. The Keq for this interaction was 1.3 x 10-8 with 1.4 H+ being liberated per base bair of M-DNA formed.
These results support the proposed structural model of M-DNA, as lowering the pKa of the bases having titratable protons over the pH range studied facilitated M-DNA formation. The fact that Zn(II) M-DNA formation was observed by fluorescence quenching at any pH provided that a constant ratio of Zn2+:H+ was maintained was consistent with a simple mass-action interaction for M-DNA formation. The differences between Zn(II) and Ni(II) M-DNA formation show that although it requires a higher pH or transition metal ion concentration, Ni(II) M-DNA is more stable than Zn(II) M-DNA once formed. This difference could play an important role in applications of M-DNA which required modulation in the stability of the M-DNA conformation.
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Biophysical investigation of M-DNAWood, David Owen 31 May 2005 (has links)
M-DNA is a complex formed between normal double-stranded DNA and the transition metal ions Zn2+, Ni2+, and Co2+ that is favoured by an alkaline pH. Previous studies have suggested that M-DNA formation involves replacement of the imino protons of G and T bases by the transition metal ions involved in forming the complex. Owing to the conductive properties of this unique DNA conformation, it has potential applications in nanotechnology and biosensing. This work was aimed at improving existing methods and developing new methods of characterizing M-DNA. The effects of base substitutions, particularly those of G and T, were evaluated in light of the proposed structure. Differences between M-DNA conformations induced by Zn2+ and Ni2+ were also investigated with a variety of techniques and compared to the effects of Cd2+ and Mg2+ on double-stranded DNA.
M-DNA formation and stability were studied with an ethidium bromide (EtBr) based assay, M-DNA induced fluorescence quenching of DNA labelled with fluorescein and a compatible quenching molecule, isothermal titration calorimetry (ITC), and surface plasmon resonance (SPR). Production of monoclonal antibodies against the conformation was also attempted but was unsuccessful. The EtBr-based assay showed Ni(II) M-DNA to be much more stable than Zn(II) M-DNA as a function of pH and in the presence of ethylenediaminetetraacetic acid. Sequence-dependency and the effect of base substitutions were measured as a function of pH. With regards to sequence, d(G)nd(C)n tracts were found to form the conformation most easily. Base substitutions with G and T analogues that lowered the pKa of these bases were found to stabilize M-DNA more strongly than other base substitutions. A combination of temperature-dependant EtBr and ITC assays showed M-DNA formation to be endothermic, and therefore entropy driven. The SPR studies demonstrated many qualitative differences between Zn(II) and Ni(II) M-DNA formation, allowed characterization of Zn2+, Ni2+, Cd2+, and Mg2+ complexes with single-stranded DNA, and provided unambiguous evidence that M-DNA formation results in very little denaturation of double-stranded DNA. Specifically, the SPR study showed Ni(II) M-DNA to be more stable than Zn(II) M-DNA in the absence of transition metal ions, but also showed that Ni(II) M-DNA required higher concentrations of Ni2+ than Zn2+ to fully form the respective M-DNA conformations. Finally, quenching studies demonstrated Zn(II) M-DNA formation over a pH range from 6.5 to 8.5 provided that a Zn2+:H+ ratio of roughly 105 was maintained. The Keq for this interaction was 1.3 x 10-8 with 1.4 H+ being liberated per base bair of M-DNA formed.
These results support the proposed structural model of M-DNA, as lowering the pKa of the bases having titratable protons over the pH range studied facilitated M-DNA formation. The fact that Zn(II) M-DNA formation was observed by fluorescence quenching at any pH provided that a constant ratio of Zn2+:H+ was maintained was consistent with a simple mass-action interaction for M-DNA formation. The differences between Zn(II) and Ni(II) M-DNA formation show that although it requires a higher pH or transition metal ion concentration, Ni(II) M-DNA is more stable than Zn(II) M-DNA once formed. This difference could play an important role in applications of M-DNA which required modulation in the stability of the M-DNA conformation.
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Structure and Stability of Oxygen-Linked DNA Adducts Derived from Phenolic ToxinsKuska, Michael S. 17 May 2013 (has links)
A significant focus of nucleic acids research is on the reactivity of electrophilic species with DNA to form addition products (adducts). Phenols are known to be able to form adducts at the C8 site of deoxyguanosine (dG). This dissertation studies the oxygen (O)-linked class of phenolic dG adducts for their hydrolytic stability as well as their structural impact on the DNA duplex. To determine the effect of C8 O-linked phenolic dG adducts on glycosidic bond stability spectrophotometric determination of hydrolysis kinetics was performed. The kinetics establish the adducts to be less stable than native dG in acid, but surprisingly stable under physiological conditions. Then to assess the modified duplex structure, a C8 O-linked phenolic dG adduct was incorporated into a DNA duplex. Thermal melting analysis establish the adduct as having a destabilizing effect on the regularly paired duplex and the conformational analysis suggests the phenolic lesion to be weakly mutagenic. / NSERC
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Etude de l'immobilisation et de la détection de la reconnaissance moléculaire d'acides nucléiques sur électrodes d'or / Study of the immobilization and the detection of the molecular recognition of nucleic acids on gold electrodesSteichen, Marc 06 March 2008 (has links)
Ce travail s’inscrit dans le cadre de la recherche relative au développement de biosenseurs à ADN électrochimiques. Des aspects fondamentaux, ainsi que des aspects d’application de la détection d’hybridation d’ADN sont envisagés.<p>Dans un premier temps, le comportement interfacial et le processus d’hybridation d’oligonucléotides d’ADN linéaires et ADN hairpin (structure en épingle à cheveux) nonmarqués sont étudiés en formant des monocouches auto-assemblées mixtes de monobrins d’ADN (ssADN) thiolés et d’un hydroxyalcanethiol (4-mercaptobutan-1-ol) par coadsorption spontanée sur des électrodes d’or polycristallin. L’immobilisation de monocouches mixtes ssADN/MCB est caractérisée par voie électrochimique et par spectroscopie des photoélectrons X. Des mesures de chronocoulométrie, en présence de [Ru(NH3)6]3+ (RuHex), permettent de déterminer la quantité d’ADN dans la monocouche mixte formée. Les résultats montrent que l’excès superficiel d’ADN linéaire est plus important que l’excès superficiel d’ADN hairpin sous des conditions de formation identiques.<p>La réaction de reconnaissance moléculaire d’hybridation est détectée par des mesures d’impédance en présence de [Fe(CN)6]3-/4-. L’hybridation se traduit dans le cas de l’ADN linéaire par une augmentation de la résistance au transfert d’électron Rct tandis que dans le cas de l’ADN hairpin, Rct diminue. Ces différences sont dues au plus faible recouvrement et au changement de conformation des molécules d’ADN hairpin lors de l’hybridation. Des mesures de réflectivité de neutrons nous ont permis de mettre en évidence l’augmentation de l’épaisseur du film d’ADN hairpin et de confirmer le changement conformationel ces sondes lors de la reconnaissance moléculaire.<p>Dans la seconde partie, nous présentons une nouvelle méthode électrochimique de détection d’hybridation, basée sur les interactions électrostatiques entre le complexe cationique RuHex et les groupements phosphates de l’ADN. Afin d’améliorer la détection des molécules de PNA (peptide nucleic acid) ont été immobilisées comme sondes de reconnaissance moléculaire. Après hybridation des sondes PNA avec le brin complémentaire, RuHex s’adsorbe sur l’ADN hybridé et un signal de réduction de ces complexes redox, enregistré par voltampérométrie alternative, constitue une signature claire de l’hybridation d’ADN à l’interface modifiée. Les interactions RuHex/PNA-ADN ont été étudiées. La constante d’adsorption de RuHex sur l’électrode modifiée PNA/MCB après hybridation est évaluée à 2,9 (±0,3) 105 M-1 en milieu Tris-HCl 0,01M, selon une isotherme de Langmuir.<p>Les performances analytiques de la méthode de détection (sensibilité, sélectivité et reproductibilité) ont été évaluées et optimisées pour la détection des séquences d’ADN du gène de l’ARNr 23S d’Helicobacter pylori. La méthode de détection électrochimique présentée est assez sélective pour permettre de discriminer les mutations ponctuelles A2143G et A2144C de la séquence de type sauvage. La diminution significative des signaux d’admittance enregistrés en présence des séquences mutées est attribuée à la capacité accrue de discrimination de mutations ponctuelles des molécules PNA.<p>La réponse de détection est linéaire en fonction du logarithme de la concentration de la cible d’ADN sur plus de quatre ordres de grandeur (10-6 M à 10-10 M). La limite de détection de l’oligonucléotide d’ADN complémentaire de 80 pM est très bonne. La méthode a été appliquée avec succès à la détection de fragments PCR complémentaires de 100 et 400 paires de bases, amplifiés à partir de souches SS1 d’H.pylori. / Doctorat en Sciences / info:eu-repo/semantics/nonPublished
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