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Studies on the Non-covalent Interactions (Stereoelectronics, Stacking and Hydrogen Bonding) in the Self-assembly of DNA and RNAAcharya, Parag January 2003 (has links)
This thesis is based on ten publications (Papers I-X). The phosphodiester backbone makes DNA or RNA to behave as polyelectrolyte, the pentose sugar gives the flexibility, and the aglycones promote the self-assembly or the ligand-binding process. The hydrogen bonding, stacking, stereoelectronics and hydration are few of the important non-covalent forces dictating the self-assembly of DNA/RNA. The pH-dependent thermodynamics clearly show (Papers I and II) that a change of the electronic character of aglycone modulates the conformation of the sugar moiety by the tunable interplay of stereoelectronic anomeric and gauche effects, which are further transmitted to steer the sugar-phosphate backbone conformation in a cooperative manner. 3'-anthraniloyl<b> </b>adenosine<b> </b>(a mimic of 3'-teminal CC<u>A</u>OH of the aminoacyl-tRNAPhe) binds to EF-Tu*GTP in preference over 2'-anthraniloyl<b> </b>adenosine<b>, </b>thereby showing (Paper III) that the 2’-endo sugar conformation is a more suitable mimic of the transition state geometry than the 3’-endo conformation in discriminating between correctly and incorrectly charged aminoacyl-tRNAPhe by EF-Tu during protein synthesis. The presence of 2'-OH in RNA distinguishes it from DNA both functionally as well as structurally. This work (Paper IV) provides straightforward NMR evidence to show that the 2'-OH is intramolecularly hydrogen bonded with the vicinal 3'-oxygen, and the exposure of the 3'-phosphate of the ribonucleotides to the bulk water determines the availability of the bound water around the vicinal 2'-OH, which then can play various functional role through inter- or intramolecular interactions. The pH-dependent 1H NMR study with nicotinamide derivatives demonstrates (Paper V) that the cascade of intramolecular cation (pyridinium)-π(phenyl)-CH(methyl) interaction in edge-to-face geometry is responsible for perturbing the pKa of the pyridine-nitrogen as well as for the modulation of the aromatic character of the neighboring phenyl moiety, which is also supported by the T1 relaxation studies and ab initio calculations. It has been found (Papers VI-IX) that the variable intramolecular electrostatic interaction between electronically coupled nearest neighbor nucleobases (steered by their respective microenvironments) can modulate their respective pseudoaromatic characters. The net result of this pseudoaromatic cross-modulation is the creation of a unique set of aglycones in an oligo or polynucleotide, whose physico-chemical properties are completely dependent upon the propensity and geometry of the nearest neighbor interactions (extended genetic code). The propagation of the interplay of these electrostatic interactions across the hexameric ssDNA chain is considerably less favoured (effectively up to the fourth nucleobase) compared to that of the isosequential ssRNA (up to the sixth nucleobase). The dissection of the relative strength of basepairing and stacking in a duplex shows that stability of DNA-DNA duplex weakens over the corresponding RNA-RNA duplexes with the increasing content of A-T/U base pairs, while the strength of stacking of A-T rich DNA-DNA duplex increases in comparison with A-U rich sequence in RNA-RNA duplexes (Paper X).
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Efficient Carbohydrate Synthesis By Intra- and Supramolecular ControlDong, Hai January 2009 (has links)
The Lattrell-Dax method of nitrite-mediated substitution of carbohydrate triflates is an efficient method to generate structures of inverse configuration. In this study, the effects of the neighboring group on the Lattrell-Dax inversion were explored. A new carbohydrate/anion host-guest system was discovered and the ambident reactivity of the nitrite anion was found to cause a complicated behavior of the reaction. It has been demonstrated that a neighboring equatorial ester group plays a highly important role in this carbohydrate epimerization reaction, restricting the nitrite N-attack, thus resulting in O-attack only and inducing the formation of inversion compounds in good yields. Based on this effect, efficient synthetic routes to a range of carbohydrate structures, notably β-D-mannosides and β-D-talosides, were designed by use of double parallel and double serial inversion. A supramolecularly activated, triggered cascade reaction was also developed. This cascade reaction is triggered by a deprotonation process that is activated by anions. It was found that the anions can activate this reaction following their hydrogen bonding tendencies to the hydroxyl group in aprotic solvents. / QC 20100709
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Chemoenzymová synthesa antivirálních profarmak / Chemo-enzymatic synthesis of antiviral prodrugsTupec, Michal January 2015 (has links)
Lipases have been widely applied in the manufacture of food products and in some areas of the industry, nowadays they are used in synthetic organic chemistry catalyzing the hydrolytic/esterification reactions under very mild conditions in the field of protecting groups or enantiomer resolution. In this study, the commercial lipase from bacterium Pseudomonas fluorescens was immobilized using the sol-gel process into organosilicate materials with propyl, octyl or phenyl substituents. The highest hydrolytic activity was found in the enzyme on the octyl-derived carrier. The immobilized enzymes differ in their hydrolytic activities on 4-nitrophenyl esters of various lengths. Subsequent experiments revealed quite good pH stability of the enzymes in a buffer (incubations in pH 3 through pH 11), as well as good temperature stability in isooctane (incubations at up to 100 řC). The majority of organic solvents seem to have no substantial effect on the lipase activity. The biocatalytic properties were studied on a model compound from the group of the acyclic nucleoside analogues - 9-(2',3'-dihydroxypropyl)adenine (DHPA). It was found for example that the best acyl donors are vinyl esters, that the lipase shows a preference towards longer vinyl esters, that the reaction proceeds faster in non-polar solvents or that it...
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Aspects of Antisense and Antigene Chemistry of Oligonucleotides Tethered to IntercalatorsOssipov, Dimitri January 2002 (has links)
<p>Synthetic and physicochemical studies on appropriately functionalized ODN-conjugates have been performed to evaluate their abilities to act as antisense agents against RNA or as intramolecular DNA cross-linking agents. Intercalating aromatic systems [phenazine (Pnz), dipyridophenazine (DPPZ)] and metallointercalators such as Ru<sup>2+</sup>(phen)<sub>2</sub>(DPPZ) and Ru<sup>2+</sup>(tpy)(DPPZ)<b>L</b> [where <b>L</b> = chemically or photochemically labile ligand, phen = phenanthroline, tpy = terpyridine], which are covalently tethered to the oligo-deoxynucleotides (ODNs), have been chosen for this purpose. The ODN-conjugates were typically prepared by automated solid phase synthesis using phosphoramidite building blocks, or on solid supports, both functionalized with the chromophore groups. The photosensitive metal complex, Ru<sup>2+</sup>(tpy)(DPPZ)(CH<sub>3</sub>CN), has been incorporated by post-synthetic coupling to the amino-linker modified ODNs <i>via</i> an amide bond. The intercalating ability of the tethered chromophores gave enhanced stability of the duplexes and triplexes formed with ODN-conjugates and their complementary targets: DNA, RNA, or double-stranded DNA. The conjugation of DPPZ chromophore to ODN (at 3', 5' or at the middle) led us to incorporate Ru<sup>2+</sup>(phen)<sub>2</sub>(DPPZ) through the DPPZ ligand, for the first time. The corresponding (Ru<sup>2+</sup>-ODN)•DNA duplexes showed dramatic stabilization (ΔT<sub>m</sub> = 19.4 – 22.0ºC). The CD and DNase I footprinting experiments suggest that the stabilization is owing to metallointercalation by threading of the Ru<sup>2+</sup>(phen)<sub>2</sub> moiety through the ODN•DNA duplex core, thus "stapling" the two helical strands from the minor to major groove. On the other hand, Ru<sup>2+</sup>(tpy)(DPPZ)(CH<sub>3</sub>CN)-ODN conjugates represent a new class of oligonucleotides containing the photoactivatible Ru<sup>2+</sup> complexes, which can successfully crosslink to the complementary strand. The mechanism of cross-linking upon photoirradiation of [Ru<sup>2+</sup>(tpy)(DPPZ)(CH<sub>3</sub>CN)-ODN]•DNA involves <i>in situ</i> conversion to the reactive [Ru<sup>2+</sup>(tpy)(DPPZ)(H<sub>2</sub>O)-ODN]•DNA which are subsequently cross-linked through the G residue of the complementary DNA strand. All starting materials and products have been purified by HPLC and/or by PAGE and subsequently characterized by MALDI-TOF as well as ESI mass spectroscopy. Terminal conjugation of the planar Pnz and DPPZ groups through the flexible linkers were also shown to improve thermal stability of the ODN•RNA hybrid duplexes without alteration of the initial AB-type global helical structure as revealed from CD experiments. As a result, RNase H mediated cleavage of the RNA strand in the intercalator-tethered ODN•RNA duplexes was more efficient compared to the natural counterpart. The RNase H cleavage pattern was also found to be dependent on the chemical nature of the chromophore. It appeared that introduction of a tether at the 3'-end of the ODN can be most easily tolerated by the enzyme regardless of the nature of the appending chromophore. The tethered DPPZ group has also been shown to chelate Cu<sup>2+</sup> and Fe<sup>3+</sup>, like phenanthroline group, followed by the formation of redox-active metal complex which cleaves the complementary DNA strand in a sequence-specific manner. This shows that the choice of appropriate ligand is useful to (i) attain improved intercalation giving Tm enhancement, and (ii) sequence-specifically inactivate target RNA or DNA molecules using multiple modes of chemistry (RNase H mediated cleavage, free-radical, oxidative pathways or photocross-linkage).</p>
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Studies on Nucleic Acids – Structure and DynamicsIsaksson, Johan January 2005 (has links)
<p>This thesis is based on six papers, Papers I-VI, focusing on the interplay between the stabilizing elements of nucleic acids self-assembly; hydrogen bonding, stacking and solvent effects. In Paper I we investigate how the substitution of the O4' for CH<sub>2</sub> in the sugar moiety of adenosine (2'-deoxyaristeromycin) at the A<sup>6</sup> position of the Dickerson-Drew dodecamer makes the two modified bases exist in a dynamic equilibrium between Hoogsteen and Watson-Crick base pairing in the NMR time scale. Paper II is a structural study of the incorporation of 1-(1',3'-<i>O</i>-anhydro-<i>β</i>-D-psicofuranosyl)thymine in the T<sup>7</sup> position of the Dickerson-Drew dodecamer. NMR constrained molecular dynamics and hydration studies show the base-base distortions caused by the introduction of a North-type locked sugar in an otherwise B-type DNA•DNA duplex. Paper III shows that the stacking distortion caused by the 1-(1',3'-<i>O</i>-anhydro-<i>β</i>-D-psicofuranosyl)thymine building block perturbs the charge transfer similar to a DNA mismatch. Paper IV highlights how the sequence context affects the physico-chemical properties, monitored by the p<i>K</i><i>a</i> of guanine itself as well as how the charge perturbation is experienced by the neighboring bases, in ssDNA and ssRNA. Paper V focuses on the differences between the structural equilibria of single-stranded ssDNA and ssRNA. Directional differences in single-stranded stacking between ssDNA and ssRNA are identified and provide a basis to explain directional differences in p<i>K</i><i>a</i> modulation and dangling-end stabilization. In Paper VI the thermodynamic gains of dangling ends on DNA and RNA core duplexes are found to correlate with the X-ray geometries of dangling nucleobases relative to the hydrogen bonds of the closing base pairs.</p>
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Aspects of Antisense and Antigene Chemistry of Oligonucleotides Tethered to IntercalatorsOssipov, Dimitri January 2002 (has links)
Synthetic and physicochemical studies on appropriately functionalized ODN-conjugates have been performed to evaluate their abilities to act as antisense agents against RNA or as intramolecular DNA cross-linking agents. Intercalating aromatic systems [phenazine (Pnz), dipyridophenazine (DPPZ)] and metallointercalators such as Ru2+(phen)2(DPPZ) and Ru2+(tpy)(DPPZ)<b>L</b> [where <b>L</b> = chemically or photochemically labile ligand, phen = phenanthroline, tpy = terpyridine], which are covalently tethered to the oligo-deoxynucleotides (ODNs), have been chosen for this purpose. The ODN-conjugates were typically prepared by automated solid phase synthesis using phosphoramidite building blocks, or on solid supports, both functionalized with the chromophore groups. The photosensitive metal complex, Ru2+(tpy)(DPPZ)(CH3CN), has been incorporated by post-synthetic coupling to the amino-linker modified ODNs via an amide bond. The intercalating ability of the tethered chromophores gave enhanced stability of the duplexes and triplexes formed with ODN-conjugates and their complementary targets: DNA, RNA, or double-stranded DNA. The conjugation of DPPZ chromophore to ODN (at 3', 5' or at the middle) led us to incorporate Ru2+(phen)2(DPPZ) through the DPPZ ligand, for the first time. The corresponding (Ru2+-ODN)•DNA duplexes showed dramatic stabilization (ΔTm = 19.4 – 22.0ºC). The CD and DNase I footprinting experiments suggest that the stabilization is owing to metallointercalation by threading of the Ru2+(phen)2 moiety through the ODN•DNA duplex core, thus "stapling" the two helical strands from the minor to major groove. On the other hand, Ru2+(tpy)(DPPZ)(CH3CN)-ODN conjugates represent a new class of oligonucleotides containing the photoactivatible Ru2+ complexes, which can successfully crosslink to the complementary strand. The mechanism of cross-linking upon photoirradiation of [Ru2+(tpy)(DPPZ)(CH3CN)-ODN]•DNA involves in situ conversion to the reactive [Ru2+(tpy)(DPPZ)(H2O)-ODN]•DNA which are subsequently cross-linked through the G residue of the complementary DNA strand. All starting materials and products have been purified by HPLC and/or by PAGE and subsequently characterized by MALDI-TOF as well as ESI mass spectroscopy. Terminal conjugation of the planar Pnz and DPPZ groups through the flexible linkers were also shown to improve thermal stability of the ODN•RNA hybrid duplexes without alteration of the initial AB-type global helical structure as revealed from CD experiments. As a result, RNase H mediated cleavage of the RNA strand in the intercalator-tethered ODN•RNA duplexes was more efficient compared to the natural counterpart. The RNase H cleavage pattern was also found to be dependent on the chemical nature of the chromophore. It appeared that introduction of a tether at the 3'-end of the ODN can be most easily tolerated by the enzyme regardless of the nature of the appending chromophore. The tethered DPPZ group has also been shown to chelate Cu2+ and Fe3+, like phenanthroline group, followed by the formation of redox-active metal complex which cleaves the complementary DNA strand in a sequence-specific manner. This shows that the choice of appropriate ligand is useful to (i) attain improved intercalation giving Tm enhancement, and (ii) sequence-specifically inactivate target RNA or DNA molecules using multiple modes of chemistry (RNase H mediated cleavage, free-radical, oxidative pathways or photocross-linkage).
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Studies on Nucleic Acids – Structure and DynamicsIsaksson, Johan January 2005 (has links)
This thesis is based on six papers, Papers I-VI, focusing on the interplay between the stabilizing elements of nucleic acids self-assembly; hydrogen bonding, stacking and solvent effects. In Paper I we investigate how the substitution of the O4' for CH2 in the sugar moiety of adenosine (2'-deoxyaristeromycin) at the A6 position of the Dickerson-Drew dodecamer makes the two modified bases exist in a dynamic equilibrium between Hoogsteen and Watson-Crick base pairing in the NMR time scale. Paper II is a structural study of the incorporation of 1-(1',3'-O-anhydro-β-D-psicofuranosyl)thymine in the T7 position of the Dickerson-Drew dodecamer. NMR constrained molecular dynamics and hydration studies show the base-base distortions caused by the introduction of a North-type locked sugar in an otherwise B-type DNA•DNA duplex. Paper III shows that the stacking distortion caused by the 1-(1',3'-O-anhydro-β-D-psicofuranosyl)thymine building block perturbs the charge transfer similar to a DNA mismatch. Paper IV highlights how the sequence context affects the physico-chemical properties, monitored by the pKa of guanine itself as well as how the charge perturbation is experienced by the neighboring bases, in ssDNA and ssRNA. Paper V focuses on the differences between the structural equilibria of single-stranded ssDNA and ssRNA. Directional differences in single-stranded stacking between ssDNA and ssRNA are identified and provide a basis to explain directional differences in pKa modulation and dangling-end stabilization. In Paper VI the thermodynamic gains of dangling ends on DNA and RNA core duplexes are found to correlate with the X-ray geometries of dangling nucleobases relative to the hydrogen bonds of the closing base pairs.
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Chemically Modified Oligonucleotides: Synthesis, Physicochemical and Biochemical Properties of their Duplexes with DNA and RNAPradeepkumar, Pushpangadan Indira January 2004 (has links)
<p>This thesis is based on 9 papers dealing with the synthesis, physicochemical and biochemical properties of two types of chemically modified oligonucleotides which have the potential to down-regulate gene expression: (i) The first set is comprised of antisense oligonucleotides (AONs) conjugated with different chromophores of varying size, charge and π-electron density. Conjugation of the chromophores at the 3'- or 5'-end enhanced the target RNA binding affinity and RNase H recruitment capabilities compared to the native counterpart without changing the global helical conformation of their AON/RNA hybrid duplexes. The 3'-dipyridophenazine (DPPZ) has emerged as the most promising non-toxic chromophore in this series. (ii) The second set encompasses a new class of AONs containing <i>North</i>-<i>East</i> conformationally constrained 1',2'-oxetane-nucleosides. The introduction of oxetane-<b>T</b> and -<b>C</b> units imparts lowering of the T<sub>m</sub> by ~ 6º and ~ 3 ºC/modification, respectively, of the AON/RNA hybrids, whereas the incorporation of the corresponding oxetane-<b>A</b> and-<b>G</b> units into AONs did not alter the thermostability in comparison with that of the native hybrid duplex. The oxetane-modified AONs have been found to possess enhanced serum stability compared to that of the native, whereas oxetane-<b>T</b> and -<b>C</b> containing AONs were more endonuclease-resistant than oxetane-<b>A</b> and-<b>G</b> modified AONs. All oxetane-modified mixmer AON/ RNA hybrid duplexes were, however, found to be excellent substrates for RNase H cleavage, which has been analyzed by Michaelis-Menten kinetics. The oxetane-modified mixmer AONs have shown effective down-regulation of the proto-oncogene c-myb mRNA in the K562 human leukemia cells, which was analyzed by QRT-PCR and Western Blot. Based on the amount of AON uptake after delivery, determined by slot blot, it was apparent that the oxetane-modified AONs are 5-6 times more effective antisense agents than the corresponding isosequential phosphorothioate analogues. The electrochemical assay based on sensitive nucleic acid mediated charge transport (CT) has revealed that the presence of oxetane-<b>T</b> unit causes more stacking perturbations in a DNA/DNA duplex than in a DNA/RNA duplex. </p>
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Chemically Modified Oligonucleotides: Synthesis, Physicochemical and Biochemical Properties of their Duplexes with DNA and RNAPradeepkumar, Pushpangadan Indira January 2004 (has links)
This thesis is based on 9 papers dealing with the synthesis, physicochemical and biochemical properties of two types of chemically modified oligonucleotides which have the potential to down-regulate gene expression: (i) The first set is comprised of antisense oligonucleotides (AONs) conjugated with different chromophores of varying size, charge and π-electron density. Conjugation of the chromophores at the 3'- or 5'-end enhanced the target RNA binding affinity and RNase H recruitment capabilities compared to the native counterpart without changing the global helical conformation of their AON/RNA hybrid duplexes. The 3'-dipyridophenazine (DPPZ) has emerged as the most promising non-toxic chromophore in this series. (ii) The second set encompasses a new class of AONs containing North-East conformationally constrained 1',2'-oxetane-nucleosides. The introduction of oxetane-<b>T</b> and -<b>C</b> units imparts lowering of the Tm by ~ 6º and ~ 3 ºC/modification, respectively, of the AON/RNA hybrids, whereas the incorporation of the corresponding oxetane-<b>A</b> and-<b>G</b> units into AONs did not alter the thermostability in comparison with that of the native hybrid duplex. The oxetane-modified AONs have been found to possess enhanced serum stability compared to that of the native, whereas oxetane-<b>T</b> and -<b>C</b> containing AONs were more endonuclease-resistant than oxetane-<b>A</b> and-<b>G</b> modified AONs. All oxetane-modified mixmer AON/ RNA hybrid duplexes were, however, found to be excellent substrates for RNase H cleavage, which has been analyzed by Michaelis-Menten kinetics. The oxetane-modified mixmer AONs have shown effective down-regulation of the proto-oncogene c-myb mRNA in the K562 human leukemia cells, which was analyzed by QRT-PCR and Western Blot. Based on the amount of AON uptake after delivery, determined by slot blot, it was apparent that the oxetane-modified AONs are 5-6 times more effective antisense agents than the corresponding isosequential phosphorothioate analogues. The electrochemical assay based on sensitive nucleic acid mediated charge transport (CT) has revealed that the presence of oxetane-<b>T</b> unit causes more stacking perturbations in a DNA/DNA duplex than in a DNA/RNA duplex.
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The development of novel biocatalytic routes for the synthesis of enantiomerically-pure chiral aminesHussain, Shahed January 2017 (has links)
Chiral amines represent a pervasive structural motif found in various natural products, pharmaceuticals, agrochemicals and fine chemicals. Their preparation in single-enantiomer form continues to attract significant research attention and although many advances have been made in the area of synthetic organic chemistry to increase the scope of the routes to these moieties, there remains an ever-growing need of general strategies for the assembly of structurally-diverse amines which also conform to the efficiency and environmental requirements of modern manufacturing processes. This report investigates biocatalytic routes as a means for constructing chiral amine scaffolds, which offer a more environmentally benign approach when compared with traditional chemocatalysed processes. Probing the catalysts available in the biocatalytic toolbox of enzymes, several routes were examined in more detail. Imine reductases (IREDs) represent a recent addition to the toolbox, enzymes which by definition are able to reduce pre-formed imines to their corresponding amines with high selectivity. This report analyses the (R)-imine reductase [(R)-IRED] from Streptomyces sp. GF3587, one of the first imine reductases identified for its biocatalytic potential, in greater depth. The enzyme was found to catalyse the reduction of a broad range of cyclic imines while displaying high levels of activity and selectivity, thereby offering a direct route of access to chiral secondary and tertiary amines. Substrate kinetic parameters were established for the enzyme in order to understand its substrate preferences and the enzymeâs catalytic mechanism was probed through the generation of mutant (R)-IREDs. Owing to their operation under physiological conditions as well as the orthogonal nature of their reactions, it is possible to combine multiple enzyme reactions to enable cascades. This report examines a multi-enzyme reaction combining Ï-transaminases (ATAs) with imine reductases, for the synthesis of chiral disubstituted piperidines from simple diketone substrates. The cascade was then taken a step further by the inclusion of the carboxylic acid reductase (CAR) enzyme, for the synthesis of the nitrogen-containing heterocycles morpholine and thiomorpholine from ketoacid compounds. Finally, the well-established deracemisation technique, employing a selective amine oxidase (AO) with either a non-selective chemical reducing agent or a biocatalytic reductant (IRED), was explored in more detail by encompassing new substrate motifs. As biocatalysis becomes more readily accepted as a general technique in the synthetic chemistâs repertoire, the concept of carrying out enzymatic reactions in constant flow was explored as a means for applying this methodology with increased production and decreased processing rates.
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