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Synthesis of photochemically active complexes for DNA recognition and bindingLuo, JINGWEI 01 September 2009 (has links)
The objective of this thesis is to synthesize and examine the photophysical and structural properties of 3-(pyridin-2-yl)imidazo[1,5-a]pyridine (P) and 3-(pyridin-2-yl)imidazo [1,5-a]pyridine (IQ) based cations and their potential use as DNA binding agents. The P ligand was aimed to compare with the IQ ligand as they have similar structures. Two series of compounds were synthesized; one series comprising organic cations, including PC2, PC3, PC4, IQC2 and IQC3. The other one contains ruthenium complexes Ru(bpy)2P, Ru(bpy)2IQ and Ru(P)3). Compounds were prepared as Cl-, Br- and/or PF6- salts. All compounds were characterized by NMR, UV-vis, luminescescence and electrochemistry, when applicable. The results show that P and IQ based organic cations have similar electrochemical properties, and may be candidates for guanine photo-oxidation. However, [Ru(bpy)2P](PF6)2, [Ru(bpy)2IQ](PF6)2 and [Ru(P)3](PF6)2 do not seem to have reduction potentials in the excited states that are appropriate for nucleic base photo-oxidation. / Thesis (Master, Chemistry) -- Queen's University, 2009-09-01 11:58:42.728
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Recognition domains of type I restriction enzymesGann, Alexander Anthony Frank January 1988 (has links)
No description available.
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Biarylpyrimidines: a new class of ligand for high-order DNA recognitionMurphy, Peter M., Phillips, Victoria A., Jennings, Sharon A., Garbett, N.C., Chaires, J.B., Jenkins, Terence C., Wheelhouse, Richard T. January 2003 (has links)
No / Biarylpyrimidines bearing ω-aminoalkyl substituents have been designed as ligands for high-order DNA structures: spectrophotometric, thermal and competition equilibrium dialysis assays showed that changing the functional group for substituent attachment from thioether to amide switches the structural binding preference from triplex to tetraplex DNA; the novel ligands are non-toxic and moderate inhibitors of human telomerase.
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DNA stucture, dynamics and recognitionBostock-Smith, Clare E. January 1999 (has links)
No description available.
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Synthesis and DNA-binding of Metallocyclic ArchitecturesSchilter, David January 2009 (has links)
PhD / A new family of cationic N-heterocyclic ligand derivatives was prepared and characterised. Among these compounds are halide salts of the dications [Y(spacer)Y]2+, each of which comprise two N heterocyclic donor groups (Y = 4,4′-bipy, pyz, apyz, apym) linked by a conformationally flexible spacer such as (CH2)n, α,α′-xylylene, 2,6-lutidylene or thiabicyclo[3.3.1]nonane-2,6 diyl. The diquaternary halide salts were converted to NO3- and PF6- salts, and interaction of these bridging ligands with labile palladium(II) and platinum(II) precursors afforded several multinuclear complexes. Bis(4,4′-bipyridinium) dications were incorporated into the dinuclear macrocycles [M2(2,2′ bipy)2{4,4′ bipy(CH2)n4,4′-bipy}2]8+ (M = Pd, Pt; n = 4, 6), cis [Pd2Cl4{4,4′ bipy(CH2)34,4′-bipy}2]4+, [Pt2(dppp)2{4,4′-bipy(1,2-xylylene)4,4′-bipy}2]8+ and cis-[Pt2Cl4{4,4′-bipy(1,2-xylylene)4,4′-bipy}2]4+. While bis(pyrazinium) analogues were unreactive towards the palladium(II) and platinum(II) precursors, the doubly deprotonated bis(3 aminopyrazinium) and bis(2 aminopyrimidinium) derivatives served as charge-neutral quadruply-bridging ligands in the complexes [Pt4(2,2′ bipy)4{apyz(CH2)6apyz–2H}2]8+ and [Pt4(2,2′ bipy)4{apym(CH2)5apym–2H}2]8+, both of which feature Pt(II). Pt(II) interactions. Larger species formed when the diamine O,O′-bis(2-aminoethyl)octadeca(ethylene glycol) (PEGda) was treated with cis dinitratopalladium(II) and platinum(II) precursors. The resulting complexes [M(N,N)(PEGda)]2+ (M = Pd, Pt; N,N = 2,2′-bipy, en, tmeda) possessed great size (62 membered chelate rings) and aqueous solubility. DNA-binding studies were conducted with selected complexes in order to investigate the types of interactions these species might participate in. Equimolar mixtures containing either the 16mer duplex DNA D2 or the single strand D2a and palladium(II)/platinum(II) complexes were prepared and analysed by negative-ion ESI MS. Studies of D2/Pd(II) mixtures suggested extensive fragmentation was occuring, and the use of [Pd(tmeda)(PEGda)]2+ and [Pd2(2,2′-bipy)2{4,4′-bipy(CH2)44,4′-bipy}2]8+ resulted in D2 adducts of [Pd(tmeda)]2+ and [4,4′-bipy(CH2)44,4′-bipy]2+, respectively. Decomposition also occurred when D2a was used, although 1 : 1 adducts were observed with [Pd(tmeda)(PEGda)]2+, [Pd(2,2′ bipy)(PEGda)]2+ and [Pd2(2,2′-bipy)2{4,4′-bipy(CH2)44,4′-bipy}2]8+. The low intensities of these adducts indicated that they are unstable towards ESI MS. Analogous ESI-MS experiments using platinum(II) derivatives were performed and, in contrast to those with palladium(II), indicated that the complexes remained largely intact. ESI-MS analysis of D2/Pt(II) mixtures allowed for the detection of 1 : 1 D2 adducts of [Pt(en)(PEGda)]2+, [Pt(tmeda)(PEGda)]2+ and [Pt2(2,2′-bipy)2{4,4′-bipy(CH2)44,4′-bipy}2]8+. Intensities of the adduct ions suggested the greater charge and aryl surface area allow the dinuclear species to bind D2 most strongly. Both [Pt(2,2′-bipy)(Mebipy)2]4+ and [Pt(2,2′ bipy)(NH3)2]2+ gave rise to 1 : 2 adducts of D2, although the latter was found to be a weaker binder, perhaps owing to its lower charge. Data obtained using 1 : 5 (D2 : complex) mixtures were consistent with the results above and suggested that D2 can bind more molecules of daunomycin than any of the platinum(II) species. Analyses of D2a/Pt(II) mixtures gave results similar to those obtained with D2, although fragmentation was more pronounced, indicating that the nucleobases in D2a play more significant roles in mediating decomposition than those in D2, in which they are paired in a complementary manner. Investigations into the effects of selected platinum(II) complexes on the thermal denaturation of calf-thymus DNA (CT-DNA) in solution were conducted. Both [Pt2(2,2′ bipy)2{4,4′-bipy(CH2)64,4′-bipy}2]8+ and [Pt(2,2′-bipy)(Mebipy)2]4+ greatly stabilised CT-DNA, most likely by intercalation. In contrast, [Pt(tmeda)(PEGda)]2+ and [Pt(en)(PEGda)]2+ (as well as PEGda) caused negligible changes in melting temperature (∆Tm), suggesting that these interact weakly with CT-DNA. Data for [Pt(2,2′ bipy)(PEGda)]2+ and [Pt(2,2′-bipy)(NH3)2]2+ indicated that these species perhaps intercalate CT-DNA, with similar ∆Tm values for both complexes implying that PEGda does not play a major role in binding. While findings from ESI-MS experiments were similar to those from the thermal denaturation experiments, discrepancies between results from the two methods could be found. In particular, fragmentation of cyclic species during ESI-MS caused the binding strength of the species to be underestimated when this method was employed.
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DNA target site recognition by the Ll.LtrB group II intron RNPWhitt, Jacob Tinsley 07 November 2011 (has links)
Mobile group II introns are retroelements that site-specifically insert into DNA target sequences. The group II intron mobility pathway is mediated by a ribonucleoprotein particle (RNP) composed of excised intron RNA and an intron-encoded protein (IEP). The intron lariat inserts at a specific DNA target sequence and is then reverse transcribed by the IEP. Both the intron RNA and IEP are required for DNA target site recognition. I have identified the contact sites within the IEP responsible for recognition of two key positions in the DNA target, T+5 and T-23. IEP recognition of T+5 in the 3'-exon is required for endonuclease cleavage of the bottom-strand of the DNA target site, which generates a primer used for initiation of reverse transcription of the intron. The T+5 base is contacted by G498 in the LtrA DNA-binding domain and nearby residues, particularly K499, potentially bolster this interaction. Recognition of T-23 in the distal 5'-exon is required for initial recognition of the DNA target site by the RNP. The T533 side-chain contacts the T-23 base and the L534 side-chain may also contribute to recognition through hydrophobic interactions with the C5 methyl group. A mutant, L534H, that switches target site specificity to T-23G has been characterized. In order for the RNP to make these and other contacts in the 5'- and 3'-exons simultaneously, the DNA must be bent. I have dissected the role of DNA bending in the intron mobility pathway and found that the DNA is bent at two progressively larger angles as the reaction proceeds. The predominant bend angle at earlier time points places the bottom-strand DNA cleavage site at the protein endonuclease active site. The predominant bend angle of later time points places the cleaved DNA site at the RT domain active site for initiation of reverse transcription of intron cDNA. Finally, in a practical application of group II intron mobility, I have used reprogrammed group II introns ("targetrons") to target two genes in Bacillus subtilis to demonstrate the suitability of targetron technology for gene targeting in the Gram-positive Bacillus genus. / text
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Synthesis and DNA-binding of Metallocyclic ArchitecturesSchilter, David January 2009 (has links)
PhD / A new family of cationic N-heterocyclic ligand derivatives was prepared and characterised. Among these compounds are halide salts of the dications [Y(spacer)Y]2+, each of which comprise two N heterocyclic donor groups (Y = 4,4′-bipy, pyz, apyz, apym) linked by a conformationally flexible spacer such as (CH2)n, α,α′-xylylene, 2,6-lutidylene or thiabicyclo[3.3.1]nonane-2,6 diyl. The diquaternary halide salts were converted to NO3- and PF6- salts, and interaction of these bridging ligands with labile palladium(II) and platinum(II) precursors afforded several multinuclear complexes. Bis(4,4′-bipyridinium) dications were incorporated into the dinuclear macrocycles [M2(2,2′ bipy)2{4,4′ bipy(CH2)n4,4′-bipy}2]8+ (M = Pd, Pt; n = 4, 6), cis [Pd2Cl4{4,4′ bipy(CH2)34,4′-bipy}2]4+, [Pt2(dppp)2{4,4′-bipy(1,2-xylylene)4,4′-bipy}2]8+ and cis-[Pt2Cl4{4,4′-bipy(1,2-xylylene)4,4′-bipy}2]4+. While bis(pyrazinium) analogues were unreactive towards the palladium(II) and platinum(II) precursors, the doubly deprotonated bis(3 aminopyrazinium) and bis(2 aminopyrimidinium) derivatives served as charge-neutral quadruply-bridging ligands in the complexes [Pt4(2,2′ bipy)4{apyz(CH2)6apyz–2H}2]8+ and [Pt4(2,2′ bipy)4{apym(CH2)5apym–2H}2]8+, both of which feature Pt(II). Pt(II) interactions. Larger species formed when the diamine O,O′-bis(2-aminoethyl)octadeca(ethylene glycol) (PEGda) was treated with cis dinitratopalladium(II) and platinum(II) precursors. The resulting complexes [M(N,N)(PEGda)]2+ (M = Pd, Pt; N,N = 2,2′-bipy, en, tmeda) possessed great size (62 membered chelate rings) and aqueous solubility. DNA-binding studies were conducted with selected complexes in order to investigate the types of interactions these species might participate in. Equimolar mixtures containing either the 16mer duplex DNA D2 or the single strand D2a and palladium(II)/platinum(II) complexes were prepared and analysed by negative-ion ESI MS. Studies of D2/Pd(II) mixtures suggested extensive fragmentation was occuring, and the use of [Pd(tmeda)(PEGda)]2+ and [Pd2(2,2′-bipy)2{4,4′-bipy(CH2)44,4′-bipy}2]8+ resulted in D2 adducts of [Pd(tmeda)]2+ and [4,4′-bipy(CH2)44,4′-bipy]2+, respectively. Decomposition also occurred when D2a was used, although 1 : 1 adducts were observed with [Pd(tmeda)(PEGda)]2+, [Pd(2,2′ bipy)(PEGda)]2+ and [Pd2(2,2′-bipy)2{4,4′-bipy(CH2)44,4′-bipy}2]8+. The low intensities of these adducts indicated that they are unstable towards ESI MS. Analogous ESI-MS experiments using platinum(II) derivatives were performed and, in contrast to those with palladium(II), indicated that the complexes remained largely intact. ESI-MS analysis of D2/Pt(II) mixtures allowed for the detection of 1 : 1 D2 adducts of [Pt(en)(PEGda)]2+, [Pt(tmeda)(PEGda)]2+ and [Pt2(2,2′-bipy)2{4,4′-bipy(CH2)44,4′-bipy}2]8+. Intensities of the adduct ions suggested the greater charge and aryl surface area allow the dinuclear species to bind D2 most strongly. Both [Pt(2,2′-bipy)(Mebipy)2]4+ and [Pt(2,2′ bipy)(NH3)2]2+ gave rise to 1 : 2 adducts of D2, although the latter was found to be a weaker binder, perhaps owing to its lower charge. Data obtained using 1 : 5 (D2 : complex) mixtures were consistent with the results above and suggested that D2 can bind more molecules of daunomycin than any of the platinum(II) species. Analyses of D2a/Pt(II) mixtures gave results similar to those obtained with D2, although fragmentation was more pronounced, indicating that the nucleobases in D2a play more significant roles in mediating decomposition than those in D2, in which they are paired in a complementary manner. Investigations into the effects of selected platinum(II) complexes on the thermal denaturation of calf-thymus DNA (CT-DNA) in solution were conducted. Both [Pt2(2,2′ bipy)2{4,4′-bipy(CH2)64,4′-bipy}2]8+ and [Pt(2,2′-bipy)(Mebipy)2]4+ greatly stabilised CT-DNA, most likely by intercalation. In contrast, [Pt(tmeda)(PEGda)]2+ and [Pt(en)(PEGda)]2+ (as well as PEGda) caused negligible changes in melting temperature (∆Tm), suggesting that these interact weakly with CT-DNA. Data for [Pt(2,2′ bipy)(PEGda)]2+ and [Pt(2,2′-bipy)(NH3)2]2+ indicated that these species perhaps intercalate CT-DNA, with similar ∆Tm values for both complexes implying that PEGda does not play a major role in binding. While findings from ESI-MS experiments were similar to those from the thermal denaturation experiments, discrepancies between results from the two methods could be found. In particular, fragmentation of cyclic species during ESI-MS caused the binding strength of the species to be underestimated when this method was employed.
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Reconnaissance de l'ADN par des complexes peptidiques des lanthanides / DNA recognition by lanthanides peptides complexesAncel, Laëtitia 22 November 2013 (has links)
L'auteur n'a pas fourni de résumé en français / L'auteur n'a pas fourni de résumé en anglais
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Protein–DNA Recognition : <i>In Vitro</i> Evolution and Characterization of DNA-Binding ProteinsNilsson, Mikael January 2004 (has links)
<p>DNA-recognizing proteins are involved in a multitude of important life-processes. Therefore, it is of great interest to understand the underlying mechanisms that set the rules for sequence specific protein–DNA interactions. Previous attempts aiming to resolve these interactions have been focused on naturally occurring systems. Due to the complexity of such systems, conclusions about structure–function relationship in protein–DNA interactions have been moderate. </p><p>To expand the knowledge of protein–DNA recognition, we have utilized<i> in vitro</i> evolution techniques. A phage display system was modified to express the DNA-binding, helix-turn-helix protein Cro from bacteriophage λ. A single-chain variant of Cro (scCro) was mutated in the amino acid residues important for sequence-specific DNA-binding. Three different phage-libraries were constructed. </p><p>Affinity selection towards a synthetic ORas12 DNA-ligand generated a consensus motif. Two clones containing the motif exhibited high specificity for ORas12 as compared to control ligands. The third library selection, based on the discovered motif, generated new protein variants with increased affinity for ORas-ligands. Competition experiments showed that Arg was important for high affinity, but the affinity was reduced in presence of Asp or Glu. By measuring <i>K</i><sub>D</sub> values of similar variant proteins, it was possible to correlate DNA-binding properties to the protein structure.</p><p>mRNA display of scCro was also conducted. The system retained the wild-type DNA-binding properties and allowed for functional selection of the mRNA–scCro fusion. Selected species was eluted and the gene encoding the scCro was recovered by PCR. </p><p>The two <i>in vitro</i> selection methods described in this thesis can be used to increase the knowledge of the structure–function relationship regarding protein–DNA recognition. Furthermore, we have also shown that new helix-turn-helix proteins exhibiting novel DNA-binding specificity can be constructed by phage display. The ability to construct proteins with altered DNA-specificity has various important applications in molecular biology and in gene therapy.</p>
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Protein–DNA Recognition : In Vitro Evolution and Characterization of DNA-Binding ProteinsNilsson, Mikael January 2004 (has links)
DNA-recognizing proteins are involved in a multitude of important life-processes. Therefore, it is of great interest to understand the underlying mechanisms that set the rules for sequence specific protein–DNA interactions. Previous attempts aiming to resolve these interactions have been focused on naturally occurring systems. Due to the complexity of such systems, conclusions about structure–function relationship in protein–DNA interactions have been moderate. To expand the knowledge of protein–DNA recognition, we have utilized in vitro evolution techniques. A phage display system was modified to express the DNA-binding, helix-turn-helix protein Cro from bacteriophage λ. A single-chain variant of Cro (scCro) was mutated in the amino acid residues important for sequence-specific DNA-binding. Three different phage-libraries were constructed. Affinity selection towards a synthetic ORas12 DNA-ligand generated a consensus motif. Two clones containing the motif exhibited high specificity for ORas12 as compared to control ligands. The third library selection, based on the discovered motif, generated new protein variants with increased affinity for ORas-ligands. Competition experiments showed that Arg was important for high affinity, but the affinity was reduced in presence of Asp or Glu. By measuring KD values of similar variant proteins, it was possible to correlate DNA-binding properties to the protein structure. mRNA display of scCro was also conducted. The system retained the wild-type DNA-binding properties and allowed for functional selection of the mRNA–scCro fusion. Selected species was eluted and the gene encoding the scCro was recovered by PCR. The two in vitro selection methods described in this thesis can be used to increase the knowledge of the structure–function relationship regarding protein–DNA recognition. Furthermore, we have also shown that new helix-turn-helix proteins exhibiting novel DNA-binding specificity can be constructed by phage display. The ability to construct proteins with altered DNA-specificity has various important applications in molecular biology and in gene therapy.
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