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DNA Interactions and Photocleavage by Anthracene, Acridine, and Carbocyanine-Based ChromophoresMapp, Carla 23 September 2013 (has links)
The interaction of small molecules with DNA has been extensively studied and has produced a large catalogue of molecules that non-covalently bind to DNA though groove binding, intercalation, electrostatics, or a combination of these binding modes. Anthracene, acridine, and carbocyanine-based chromophores have been examined for their DNA binding properties and photo-reactivities. Their planar aromatic structures make them ideal chromophores that can be used to probe DNA structural interactions and binding patterns. We have studied DNA binding and photocleavgage properties of a bisacridine chromophore joined by a 2,6-bis(aminomethyl)pyridine copper-binding linker (Chapter II), a series of 9-aminomethyl anthracene chromophores (Chapters III and IV), both under conditions of high and low ionic strength, as well as a series of pentamethine linked symmetrical carbocyanine dyes (Chapter V). In Chapter II we present data showing that high ionic strength efficiently increases copper(II)-dependent photocleavage of plasmid DNA by the bisacridine based chromophore (419 nm, pH 7.0). In Chapters III and IV, using an pyridine N-substituted 9-(aminomethyl)anthracene (Chapter III), a bis-9-(aminomethyl)anthracene, and its mono 9-(aminomethyl)anthracene analogue (Chapter IV), pUC19 plasmid DNA was photo-converted to highly diffuse DNA fragments (350 nm, pH 7.0) in the presence of 150 mM NaCl and 260 mM KCl. Spectroscopic analyses suggest that the combination of salts promotes a change in DNA helical structure that initiate a switch in anthracene binding mode from intercalation to an external or groove binding interactions. The alteration in DNA structure and binding mode leads to an increase in the anthracene-sensitized production of DNA damaging reactive oxygen species. Finally, in Chapter V, pUC19 plasmid DNA is converted to its nicked circular and linear forms following irradiation of a series of pentamethine linked symmetrical carbocyanines (red light, pH 7.0). The data suggest that the relative levels of photocleavage arise from the different substituents on the nitrogen alkyl side chain and the pentamethine linker.
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Shape-Dependent Molecular Recognition of Specific Sequences of DNA by Heterocyclic CationsMiao, Yi 03 August 2006 (has links)
SHAPE-DEPENDENT MOLECULAR RECOGNITION OF SPECIFIC SEQUENCES OF DNA BY HETEROCYCLIC CATIONS by YI MIAO Under the Direction of Dr. W. David Wilson ABSTRACT DB921 and DB911 are biphenyl-benzimidazole-diamidine isomers with a central para- and meta-substituted phenyl group, respectively. Unexpectedly, linear DB921 has much stronger binding affinity with DNA than its curved isomer, DB911. This is quite surprising and intriguing since DB911 has the classical curved shape generally required for strong minor groove binding while DB921 clearly does not match the groove shape. Several biophysical techniques including thermal melting (Tm), circular dichroism (CD), biosensor-surface plasmon resonance (SPR), and isothermal titration calorimetry (ITC) have been utilized to investigate the interactions between these compounds and DNA. The structure of the DB921-DNA complex reveals that DB921 binds to DNA with a reduced twist of the biphenyl for better fit of DB921 into the minor groove. A bound water molecule complements the curvature of DB921 and contributes for tight binding by forming H-bonds with both DNA and DB921. Structure-affinity relationship studies of a series of DB921 analogs show that the benzimidazole group is one of the key groups of DB921 for its strong binding to the minor groove. Thermodynamic studies show that the stronger binding of DB921 is due to a more favorable binding enthalpy compared to DB911 even though the complex formation with DNA for these compounds are all predominantly entropically driven. DB921 also has more negative heat capacity change than DB911. The initial studies of inhibition of the interaction between an AT hook peptide of HMGA proteins and its target DNA by a set of diamidine AT-minor groove binders using biosensor-SPR technique show that the inhibitory ranking order is consistent with that of binding affinity and linear-shaped DB921 still has excellent inhibitory effects. These heterocyclic cations rapidly inhibit the binding of DBD2 peptide to the DNA and may only block the specific AT binding of the peptide without hindering the non-specific binding interaction. The results of this project have shown that DB921 represents a new novel effective minor groove binder that does not fit the traditional model and is a potential inhibitor for DNA/protein complexes. INDEX WORDS: Molecular recognition, DNA binding, Minor groove binding, Linear shape, Compound curvature, Binding affinity, Binding kinetics, Thermodynamics, Surface plasmon resonance, Isothermal titration calorimetry, Inhibition
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Sequence-Specific and Conformation-Specific Targeting of Duplex and Quadruplex DNA Grooves with Small MoleculesNanjunda, Rupesh K 15 December 2010 (has links)
Small molecule mediated chemical intervention of biological processes using nucleic acid targets has proven extremely successful and is continually providing exciting new avenues for the development of anti-cancer agents and molecular probes. Among the alternative DNA confrormations, G-quadruplexes has certainly garnered much recognition due to increase in evidences supporting their involvement in diverse biological process. The grooves of the quadruplexes offer an alternate recognition site for ligand interactions with potentially higher selectivity than the traditional terminal stacking sites. DB832, a bifuryl-phenyl diamidine, was recently reported to selectively recognize human telomeric G-quadruplex, as a stacked species, with significant selectivity over duplex sequences. A series of biophysical studies were conducted to test the groove-binding mode of DB832, along with the selectivity for diverse quadruplex forming sequences. To gain better understanding of quadruplex groove-recognition by DB832, a series of structurally similar heterocyclic diamidines were also evaluated. The unique binding mode of DB832 may allow it to serve as a paradigm for the design of new class of highly selective quadruplex groove-binding molecules. Beyond the alternative secondary structures, it is also becoming increasingly apparent that the structure and dynamics of the canonical Watson–Crick DNA double helix play pivotal roles in diverse biological functions. DB1878, a phenyl-furan-indole diamidine, was shown to recognize a mixed GC/AT motif as a stacked antiparallel dimer, and a detailed structural analysis is reported here. Interestingly, the DNA recognition is completely different from the reported molecules in literature, and represents an entirely new motif for DNA minor groove recognition.
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Spectroscopic Investigation into Minor Groove Binders Designed to Selectively Target DNA SequencesWalton, Joseph 04 December 2015 (has links)
Recently, there has been increasing focus toward the development of small molecules designed to target a specific sequences of double stranded DNA for therapeutic purposes1. Minor groove binding compounds have been shown to be capable of selectivity target GC sites in AT tract DNA2. In this research, binding selectivity was investigated using absorption, fluorescence and circular dichroic properties of selected DB minor groove binders in the presence of two unique DNA sequences. Further insight was gained by comparing the electrostatic potential maps and optimized structures of the compounds of interest. Using the results presented, potential selective minor groove binders can be selected for further investigation and kinetic studies.
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