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201	Insights into Sulfonated Phthalocyanines; Insights into Anionic Tetraaryl Porphyrins; Irradiation of Cationic Metalloporphyrins Bound to DNA Gill, Anila Fiaz 04 December 2006 (has links) Sulfonated porphyrins and phthalocyanines have been under consideration as microbicides, compounds which, when used in a topical formulation, can prevent transmission of the human immunodeficiency virus. Our studies have been directed toward the characterization of members of these classes. For the sulfonated phthalocyanines, matrix-assisted laser desorption/ionization (MALDI) mass spectrometry was helpful in determining the extent of sulfonation. We present the first report of spectroscopic characterization of a pentasulfonated phthalocyanine. Capillary electrophoresis data were sensitive to the concentration of the compounds (Chapter 1). Mass spectrometry was also very useful for establishing the extent of sulfonation in series of sulfonated porphyrins. Capillary electrophoresis was very useful in separating mixtures of these species. A study on sulfonation of a series of tetra(difluorophenyl)porphyrins showed that species with red-shifted Soret peaks were being formed. Data were consistent with an intramolecular sulfone bridge from the phenyl substituent to the porphyrin core. Sulfonation of the tetranaphthylporphyrins ring readily gave more than one sulfonic acid group per naphthyl side chain (Chapter 2). In cancer chemotherapy of solid tumors, it is desired to kill the tumor cells with minimal damage to the surrounding tissue. Brachytherapy seeds have been a considerable help in this regard for some tumors. In further developing approaches to selective tumor damage, we have evaluated a technique, Auger Electron Therapy (AET) in which one introduces a compound that is expected to bind to DNA, absorb the radiation, and then catalyze clustered DNA damage via release of a series of Auger electrons. We chose a series of metals (silver, indium, molybdenum, palladium, platinum, ruthenium, silver and zirconium) with appropriate energy levels to absorb an x-ray photon from the brachytherapy seed and used the tetracationic porphyrin 5,10,15,20-tetrakis(1-methylpyridinium-4-yl) porphyrin (TMPyP4) as a scaffold. The amount of clustered DNA damage was quantitated by a plasmid assay. Experiments evaluated the effect of buffer, concentration of glycerol, irradiation time, and concentration of the porphyrin. No metal studied gave significant double stranded (localized) DNA damage. Significant single stranded DNA damage was observed, however, in the order zirconium >> ruthenium > palladium > platinum > silver ~ indium (Chapter 3). Sulfonated Phthalocyanines Anionic Porphyrins Cationic Porphyrins Auger Electron Therapy (AET) Capillary Electrophoresis Mass Spectrometry. Chemistry
202	Selective Recognition of Quadruplex DNA by Small Molecules White, Elizabeth W. 04 December 2006 (has links) Structure-specific recognition of nucleic acids is a promising method to reduce the size of the recognition unit required to achieve the necessary selectivity and binding affinity for small molecules. It has been demonstrated recently that G-quadruplex DNA structures can be targeted by organic cations in a structure-specific manner. Structural targets of quadruplexes include the planar end surfaces of the G-tetrad stacked columns as well as four grooves. The significant structural differences between quadruplex DNA and duplex DNA make quadruplex DNA a very attractive target for highly selective, structure-specific drug design. We have used a variety of biophysical techniques including circular dichroism, surface plasmon resonance, thermal melting and absorbance spectroscopy to investigate small molecules that can selectively bind to the ends of human telomeric DNA as well as the ends of the G-quadruplex structure formed by the purine-rich promoter region of the c-MYC oncogene. We have also screened a library of heterocyclic diamidines, and identified one that binds selectively in the grooves of human telomeric quadruplex DNA. This compound is an excellent starting point for the design of new anti-cancer and anti-parasitic compounds with high affinity and selectivity for human telomeric DNA. circular dichroism quadruplex DNA surface plasmon resonance telomerase telomeres Chemistry
203	The Extent of Perturbation of Skin Models by Transdermal Penetration Enhancers Investigated by 31P NMR and Fluorescence Spectroscopy Burch, Charmita Patricia 02 May 2007 (has links) The molecular basis of the potent transdermal enhancement activity of a series of iminosulfuranes, structure provided where X = H, Cl, Br, and I, is being investigated skin models. It has been shown (J. Lipid Res. 46(2005), 2192-2201.) that correlations exist between the activity of the aforementioned transdermal penetration enhancers (TPE) and the extent to which these agents bind to DMPC vesicles and perturb the gel to liquid crystal phase transition measured by calorimetry. The degree to which the perturbation of these compounds extends into the bilayer interior in contrast to surface activity is unclear. To gain insight into this issue, the 31P NMR resonance from DMPC and DMPC-cholesterol unilamellar vesicles have been split by the slowly penetrating paramagnetic metal ion Pr+3. The extent to which this perturbation is attenuated by transdermal penetration enhancers has been investigated as a function of Pr+3 exposure time and iminosulfurane concentration. The effect of these iminosulfuranes on bilayer integrity is also being explored by monitoring the induced release of carboxyfluorescein from DMPC and DMPC- cholesterol unilamellar vesicles. shift reagents transdermal penetration enhancers iminosulfurane DMPC NMR carboxyfluorescein fluorescence Chemistry
204	Capillary Electrochromatography-Mass Spectrometry (CEC-MS) of Surfactants Norton, Dean Stephen 06 August 2007 (has links) This research presents advancements in the coupling of capillary electrochromatography (CEC) to mass spectrometry (MS) for the analysis of different chemical classes of surfactants. Chapter 1 provides a brief introduction that summarizes the mechanics and fundamentals of CEC, including instrumentation and applications for CEC-MS. Chapter 2 describes the on-line hyphenation of a packed CEC column with an internally tapered tip coupled to electrospray ionization-mass spectrometry (ESI-MS) and atmospheric pressure chemical ionization-mass spectrometry (APCI-MS) for the analysis of betaine-type amphoteric or zwitterionic surfactants (Zwittergent®). The interesting aspects include CEC-MS column manufacture and charaterization, as well as a comparison between the CEC-ACPI-MS and CEC-ESI-MS ionization pattern of zwittergents. In Chapter 3, the CEC-MS of alkyltrimethyl-ammonium ions (ATMA+) with chain length ranging from C1-C18 is optimized using an internally tapered CEC-MS column packed with mixed mode C6/strong cation exchange stationary phase and coupled to an ESI source. In addition, the optimized CEC-ESI-MS protocol is applied for the challenging analysis of commercial sample Arquad S-50 ATMA+ containing cis-trans unsaturated and saturated soyabean fatty acid derivatives. In Chapter 4, a novel CEC-UV method for separation of the various Triton X-100 oligomers is presented. A systematic mobile phase tuning and comparison of monomeric vs. polymeric stationary phases was conducted. In Chapter 5, we present the first application of CEC coupled to MS for analysis of Triton X (TX-) series surfactants. A characterization from the viewpoint of the ion and adduct formation for TX-series nonionic surfactants with a variable number of ethoxy units (n=1.5-16) in the scan mode are first discussed. Next, utilizing the TX-series as model alkylphenolpolyethoxylates (APEOs), a detailed investigation of the chromatographic separation and MS detection are performed followed by analysis of very long chain TX series with n=30-70. In Chapter 6, CEC-MS utilizing full scan positive ion mode of ESI was employed to study the effect of fragmentor voltage on the in-source collision induced dissociation (IS-CID) of several APEO nonionic surfactants. Finally, in Chapter 7, the preparation and characterization of a novel liquid crystalline stationary phase suitable for separation of neutral and charged compounds in packed column CEC is evaluated. Lithocholic Acid Stationary Phase Triton X-Series Amphoteric Zwitterionic Cationic Nonionic Surfactants Internal Taper Chemistry
205	Binding Studies of Near Infrared Cyanine Dyes with Human Serum Albumin and Poly-L-Lysine Using Optical Spectroscopy Methods Watson, Amy Dawn 07 January 2008 (has links) The sensitivity of biological studies performed between 190 and 650 nm is greatly reduced due to the autofluorescence of biomolecules and impurities in this region. Therefore, the enhanced signal-to-noise ratios encountered at longer wavelengths makes biological analysis within the near infrared (NIR) region from 650 nm to 1100 nm far more advantageous. This dissertation describes the noncovalent binding interactions of near-infrared (NIR) carbocyanine dyes with human serum albumin (HSA) and poly-L-lysine (PLL) using UV-Vis/NIR absorption spectroscopy, emission spectroscopy, circular dichroism (CD), and fluorescence detected circular dichroism (FDCD). The optical spectroscopy methods used in this work are described in detail in Chapter 1. The various applications of NIR dyes in protein analysis are introduced in Chapter 2. In general, the sensitivity of cyanines to the polarity of their local environment makes them quite suitable for protein labeling schemes. In aqueous media, cyanines have a high propensity for self-association. Yet in the hydrophobic binding sites of globular proteins, these aggregates often dissipate. Absorption and emission spectroscopy can be utilized to observe the differential spectral properties of monomer, intra-molecular and intermolecular aggregates. In Chapter 3, the photophysical properties of bis(cyanine) NIR dyes containing di-, tri-, and tetraethylene glycol linkers were each examined in the presence of HSA are discussed. Variations in chain length as well as probe flexibility were demonstrated through distinct differences in absorption and emission spectra. The observed changes in the spectral properties of the NIR dyes in the presence and absence of HSA were correlated to the physical parameters of the probes' local environment (i.e., protein binding sites and self-association). All three bis-cyanines examined exhibited enhanced fluorescence in the presence of HSA. The bis-cyanine dye containing the tri(ethylene glycol) spacer allowed for a complete overlap of the benzene rings, to form π-π interactions which were observed as intra-molecular H-aggregate bands. The dye exhibited no fluorescence in buffer, owing to the H-aggregation observed in the absorption data. In the presence of HSA, the intra-molecular dimers were disrupted and fluorescence was then detected. The "cut-on" fluorescence displayed by the dye in the presence of HSA made it ideal for noncovalent labeling applications. The utility of several NIR dyes for use as secondary structural probes was investigated in Chapter 4. NIR dyes were screened thoroughly using UV-Vis/NIR absorption spectroscopy dyes with spectral properties which were sensitive to protein secondary structure models of such as PLL in basic solution. Two NIR dyes were found to be quite sensitive to the structural features of uncharged α- and β-PLL. The chiral discrimination of these probes for basic protein secondary structures was also evaluated through CD measurements within the NIR probes' absorption bands. poly-L-lysine near infrared (NIR) Circular dichroism (CD) noncovalent labeling albumin cyanine dyes Chemistry
206	Using Protein Design to Understand the Role of Electrostatic Interactions on Calcium Binding Affinity and Molecular Recognition Jones, Lisa Michelle 04 August 2008 (has links) Calcium regulates many biological processes through interaction with proteins with different conformational, dynamic, and metal binding properties. Previous studies have shown that the electrostatic environment plays a key role in calcium binding affinity. In this research, we aim to dissect the contribution of the electrostatic environment to calcium binding affinity using protein design. Many natural calcium binding proteins undergo large conformational changes upon calcium binding which hampers the study of these proteins. In addition, cooperativity between multiple calcium binding sites makes it difficult to study site-specific binding affinity. The design of a single calcium binding site into a host system eliminates the difficulties that occur in the study of calcium binding affinity. Using a computer algorithm we have rationally designed several calcium binding sites with a pentagonal bipyramidal geometry in the non-calcium dependent cell adhesion protein CD2 (CD2-D1) to better investigate the key factors that affect calcium binding affinity. The first generation proteins are all in varying electrostatic environments. The conformational and metal binding properties of each of these designed proteins were analyzed. The second generation designed protein, CD2.6D79, was designed based on criteria learned from the first generation proteins. This protein contains a novel calcium binding site with ligands all from the â-strands of the non-calcium dependent cell adhesion protein CD2. The resulting protein maintains native secondary and tertiary packing and folding properties. In addition to its selectivity for calcium over other mono and divalent metal ions, it displays strong metal binding affinities for calcium and its analogues terbium and lanthanum. Furthermore, our designed protein binds CD48, the ligand binding partner of CD2, with an affinity three-fold stronger than CD2. The electrostatic potential of the calcium binding site was modified through mutation to facilitate the study of the effect of electrostatic interactions on calcium binding affinity. Several charge distribution mutants display varying metal binding affinities based on their charge, distance to the calcium binding site, and protein stability. This study will provide insight into the key site factors that control calcium binding affinity and calcium dependent biological function. electrostatic potentials protein design calcium binding affinity calcium binding proteins protein stability protein folding Chemistry
207	Exploring the Role of Calcium Ions in Biological Systems by Computational Prediction and Protein Engineering Zhou, Yubin 28 November 2007 (has links) Ca2+, a signal for death and life, is closely involved in the regulation of numerous important cellular events. Ca2+ carries out its function through its binding to Ca2+-receptors or Ca2+-binding proteins. The EF-hand protein, with a helix-loop-helix Ca2+-binding motif, constitutes one of the largest protein families. To facilitate our understanding of the role of Ca2+ in biological systems (denoted as calciomics) using genomic information, an improved pattern search method (http://www.chemistry.gsu.edu/faculty/Yang/Calciomics.htm) for the identification of EF-hand and EF-like Ca2+-binding proteins was developed. This fast and robust method allows us to analyze putative EF-hand proteins at the genome-wide level and further visualize the evolutionary scenario of the EF-hand protein family. This prediction method further enables us to locate a putative viral EF-hand Ca2+-binding motif within the rubella virus nonstructural protease that cleaves the nonstructural protein precursor into two active replicase components. A novel grafting approach has been used to probe the metal-binding properties of this motif by engineering the predicted 12-residue Ca2+-coordinating loop into a non-Ca2+-binding scaffold protein, CD2 domain 1. Structural and conformational studies were further performed on a purified, bacterially-expressed NS protease minimal metal-binding domain spanning the Zn2+- and EF-hand Ca2+-binding motif. It was revealed that Ca2+ binding induced local conformational changes and increased thermal stability. Furthermore, functional studies were carried out using RUB infectious cDNA clone and replicon constructs. Our studies have shown that the Ca2+ binding loop played a structural role in the NS protease and was specifically required for optimal stability under physiological conditions. In addition, we have predicted and characterized a calmodulin-binding domain in the gap junction proteins connexin43 and connexin44. Peptides encompassing the CaM binding motifs were synthesized and their ability to bind CaM was determined using various biophysical approaches. Transient expression in HeLa cells of two mutant Cx43-EYFP constructs without the putative CaM-binding site eliminated the Ca2+-dependent inhibition of gap junction permeability. These results provide the first direct evidence that CaM binds to a specific region of the ubiquitous gap junction protein Cx43 and Cx44 in a Ca2+-dependent manner, providing a molecular basis for the well-characterized Ca2+-dependent inhibition of Cx43-containing gap junctions. gap junction connexin CD2 prediction calmodulin EF-hand pattern search protein engineering rubella virus calcium Chemistry
208	Electrokinetic Modeling of Free Solution Electrophoresis Xin, Yao 28 November 2007 (has links) Modeling electrophoresis of peptides, proteins, DNA, blood cells and colloids is based on classical electrokinetic theory. The coupled field equations-Poisson, Navier-Stokes or Brinkman, and ion transport equations are solved numerically to calculate the electrophoretic mobilities. First, free solution electrophoretic mobility expressions are derived for weakly charged rigid bead arrays. Variables include the number of beads (N), their size (radius), charge, distribution (configuration), salt type, and salt concentration. We apply these mobility expressions to rings, rigid rods, and wormlike chain models and then apply the approach to the electrophoretic mobilities and translational diffusion constants of weakly charged peptides. It is shown that our bead model can predict the electrophoretic mobilities accurately. In order to make the method applicable at higher salt concentrations and/or to models consisting of larger sized subunits, account is taken of the finite size of the beads making up the model structure. For highly charged particles, it is also necessary to account for ion relaxation. This ion relaxation effect is accounted for by correcting "unrelaxed" mobilities on the basis of model size and average electrostatic surface, or "zeta" potential. With these corrections our model can be applied to the system with absolute electrophoretic mobilities exceeding approximately 0.20 cm2/kV sec and also models involving larger subunits. This includes bead models of duplex DNA. Along somewhat different lines, we have investigated the electrophoresis of colloidal particles with an inner hard core and an outer diffusive layer ("hairy" particles). An electrokinetic gel layer model of a spherical, highly charged colloid particle developed previously, is extended in several ways. The charge of the particle is assumed to arise from the deprotonation of acidic groups that are uniformly distributed over a portion (or all) of the gel layer. Free energy considerations coupled with Poisson-Boltzmann theory is used to calculate the change of the local pKa of the acidic groups depending on the local electrostatic environment. Based on the modeling of electrophoresis and viscosity, we predict that the thickness of the gel layer decreases as the salt concentration increases. And only the outermost portion of the gel layer is charged. Free solution electrophoresis Peptides Bead model Gel layer Electrokinetic modeling Chemistry
209	I. Characterization of Sulfonated Phthalocyanines by Mass Spectrometry. II. Characterization of SIAA, a Streptococcal Heme-Binding Protein Associated with a Heme ABC Transport System Sook, Brian R 22 April 2008 (has links) Sulfonated phthalocyanines were characterized using capillary electrophoresis and mass spectrometry. Derivatives investigated included the copper, cobalt, zinc and metal-free sulfonated phthalocyanines. The electropherograms of commercially available copper phthalocyanine-3,4',4'',4'''-tetrasulfonic acid and 4,4',4'',4'''-tetrasulfonic acid were very different, consistent with the latter compound having a structure that is not fully sulfonated. Matrix-assisted laser desorption/ionization (MALDI) and electrospray ionization (ESI) were used to characterize the sulfonated phthalocyanines. Mass spectral evidence was obtained for a pentasulfonated species of both the metal-free phthalocyanine and zinc phthalocyanine when these species were made by sulfonation of the metal-free phthalocyanine (followed by zinc insertion in the latter case). Many pathogenic bacteria require heme and obtain it from their environment. Heme transverses the cytoplasmic membrane via an ATP binding cassette (ABC) pathway. Although a number of heme ABC transport systems have been described in pathogenic bacteria, there is as yet little biophysical characterization of the proteins in these systems. The sia (hts) gene cluster encodes a heme ABC transporter in the Gram positive Streptococcus pyogenes. The heme binding protein (HBP) of this transporter is SiaA (HtsA). Several biophysical techniques were used to determine the coordination state, and spin state of both the ferric and ferrous forms of this protein. Identifiers from these techniques suggested that the heme is six-coordinate and low spin in both oxidation states of the protein, with methionine and histidine as axial ligands. The pKa of SiaA was determined, as were the reductive and oxidative midpoint potentials. Guanidinium titration studies of wild-type SiaA showed that the ferric state is less stable than the ferrous state. Free energy of unfolding values [ÄG(H2O)] for the oxidized and reduced proteins were 7.3 ± 0.8 and 16.0 ± 3.6 kcal mol−1, respectively. Denaturation of the histidine mutant H229A was not able to be followed via absorbance spectrometry, possibly due to the large amount of apoprotein present or to non-specific binding of the heme in the binding pocket. The biophysical characterization described herein will significantly advance our understanding of structure-function relationships in HBP. Phthalocyanine Porphyrin Sulfonated Capillary electrophoresis Mass spectrometry Streptococcus pyogenes SiaA HtsA Heme Heme uptake Gram positive Resonance Raman Magnetic circular dichroism Axial ligand Nuclear magnetic resonance ABC transporter Denaturation Chemistry
210	Application of Computer-Aided Drug Discovery Methodologies Towards the Rational Design of Drugs Against Infectious Diseases Athri, Prashanth 30 April 2008 (has links) Computer-aided drug discovery involves the application of computer science and programming to solve chemical and biological problems. Specifically, the QSAR (Quantitative Structure Activity Relationships) methodology is used in drug development to provide a rational basis of drug synthesis, rather than a trial and error approach. Molecular dynamics (MD) studies focus on investigating the details of drug-target interactions to elucidate various biophysical characteristics of interest. Infectious diseases like Trypanosoma brucei rhodesiense (TBR) and P. falciparum (malaria) are responsible for millions of deaths annually around the globe. This necessitates an immediate need to design and develop new drugs that efficiently battle these diseases. As a part of the initiatives to improve drug efficacy QSAR studies accomplished the formulation of chemical hypothesis to assist development of drugs against TBR. Results show that CoMSIA 3D QSAR models, with a Pearson’s correlation coefficient of 0.95, predict a compound with meta nitrogens on the phenyl groups, in the combinatorial space based on a biphenyl-furan diamidine design template, to have higher activity against TBR relative to the existing compound set within the same space. Molecular dynamics study, conducted on a linear benzimidazole-biphenyl diamidine that has non-classical structural similarity to earlier known paradigms of minor groove binders, gave insights into the unique water mediated interactions between the DNA minor groove and this ligand. Earlier experiments suggested the interfacial water molecules near the terminal ends of the ligand to be responsible for the exceptianlly high binding constant of the ligand. Results from MD studies show two other modes of binding. The first conformation has a single water molecule with a residency time of 6ns (average) that is closer to the central part of the ligand, which stabilizes the structure in addition to the terminal water. The second conformation that was detected had the ligand completely away from the floor of the minor groove, and hydrogen bonded to the sugar oxygens. Molecular Dynamics CoMSIA 3D- QSAR Trypanosoma brucei rhodesiense Interfacial water Water mediated Interactions DNA minor groove binders Chemistry

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