Synthesis of Fused Heterocyclic Diamidines for the Treatment of Human African Trypanosomiasis and Fluorescence Studies of Selected Diamidines

Brown Barber, Jennifer Crystal

20 April 2010

A class of linear diamidines was synthesized for the evaluation as a treatment of Human African Trypanosomiasis. These fused heterocyclic compounds are thiazole[5,4-d]thiazoles and are of interest because the parent compound, 2,5-Bis(4-amidinophenyl)-thiazolo[5,4-d]thiazole HCl salt, which is also called DB 1929, has exhibited a low nanomolar IC50 value against Trypanosoma brucei rhodesiense and has shown selectivity for binding to the human telomere G-quadruplex over that of DNA duplex. A fluoro and a methoxy derivative have been synthesized and are currently undergoing testing for activity and binding affinity. In addition, fluorescence studies of selected diamidines were done to study the effect of structural variation on fluorescence. This data is useful since it can determine what types of moieties are needed to yield a compound that will fluoresce in the higher wavelengths (500 nm and above) of the visible spectrum, which would be advantageous in determining the uptake of the drug in the trypanosome within the endemic areas of Africa with a simple microscope.

Organic synthesis

Heterocyclic chemistry

Human African Trypanosomiasis

Sleeping sickness

Fused heterocycles

Linear diamidines

UV-Visible spectroscopy

Fluorescence spectroscopy

Trypanosoma brucei gambiense

Trypanosoma brucei rhodesiense

Chemistry

Design, Synthesis and Mechanistic Studies of Small Molecule Inhibitors of the Hypoxia Inducible Factor Pathway

Mooring, Suazette Reid

20 April 2010

Cancer accounts for nearly one-quarter of deaths in the United States, exceeded only by heart diseases. In 2006, there were 559,888 cancer deaths in the US. Finding effective treatments for cancer is a major challenge among researchers. In solid tumor, hypoxia increases the progression of malignancy and metastasis by promoting angiogenesis. The transcription factor HIF-1 is responsible for the regulation of cellular processes, including glycolysis and angiogenesis. Clinical evidence has determined that expression of HIF-1 is strongly associated with poor patient prognosis. Also, activation of HIF-1 contributes to malignant behavior and therapeutic resistance. In view of these observations, there is a need for anti-cancer treatments that addresses hypoxic related tumors. HIF-1 presents a viable target for inhibition of tumor growth with small molecules. Herein, we describe the design and synthesis of small molecules that inhibit the HIF-1 pathway, as well as mechanistic studies involved in the investigation of the mode of action of these compounds.

Hypoxia

HIF-1

Small-molecule inhibitors

Chemistry

Design and Synthesis of Novel Serotonin Receptor Ligands

Klenc, Jeffrey D

18 August 2010

Novel and potent ligands to the serotonin7 (5-HT7) receptor have been synthesized. The synthesized compounds include a set of substituted pyrimidines which show high affinity to the 5-HT7 receptor, synthesized by previously described methods [1,2] in high yield. Comparing the affinities of substituted pyrimidines to previously calculated models [3,4] yielded new hypotheses about the nature of interaction between the pyrimidine ligands and the 5-HT7 binding site. Several new series of compounds were synthesized by various methods to validate these hypotheses, including a conjugate addition to vinylpyrimidines [5]. These compounds include benzofurans, oximes, hydrazones, as well as a group of substituted piperazines. All series of compounds show affinity to the 5-HT7 receptor comparable to previously synthesized 5-HT7 ligands. Several of the synthesized ligands show affinity which exceeds that of currently available ligands. The synthesized compounds were evaluated quantitatively by calculating a three-dimensional quantitative structure-affinity relationship (3D-QSAR) for the 5-HT7 receptor. Evaluation of the calculated model validated qualitative assumptions about the data set as well as described regions of interaction in greater detail than previously available. These observations give further insight on the nature of ligand-binding site interactions with highly potent ligands such as 4-(3-furyl)-2-(N-methylpiperazino)pyrimidine which will lead to more potent 5-HT7 receptor ligands. Additionally, a model was calculated for affinity to the 5-HT2a receptor. Comparing this model to that calculated for affinity to the 5-HT7 receptor identified two regions which may be exploited in future sets of ligands to increase selectivity to the 5HT7 receptor.

Serotonin

5-HT

Depression

Schizophrenia

Pyrimidine

1-4 Addition

3D-QSAR

Molecular modeling

5-HT7 receptor

5-HT7 ligands

5-HT1a

5-HT2a

Pharmacophore

Chemistry

Detection and Quantification of Organophosphate Pesticides in Human Serum

Kuklenyik, Peter

15 July 2009

The United States Environmental Agency permits the use of 39 organophosphate pesticides. Many of these pesticides are acutely toxic and have lasting effect on human health. Organophosphates quickly metabolize in the body, therefore currently human exposure is studied by measuring the metabolic products in urine. In this work a suite of analytical methods was developed to determine the presence of un-metabolized organophosphate pesticides in human serum. First mass spectroscopic detection methods were evaluated. Gas chromatograph coupled tandem mass spectrometer was used to compare the detection limits using chemical and electron impact ionization. Positive chemical ionization was selected, because it provided better detection limits for this set of analytes. Liquid chromatograph coupled tandem mass spectrometry was also evaluated and was found advantageous over the gas chromatographic method for approximately 50% of the compounds. Positive atmospheric pressure chemical ionization was chosen for this group of compounds. Once the analytes were separated by detection methods, analytical separation methods were compared: column and eluent was selected for liquid chromatography, column alone was selected for gas chromatography. Last step of the method development was to produce a suitable sample cleanup process. Solid phase extraction was not suitable because the very wide range of solubility characteristics and hydrolytic stability of the analytes. Lyophilization, liquid-liquid extraction methods were tested and compared. A multi step cleanup method was produced, which starts with liquid-liquid extraction using high pressure ethyl acetate in accelerated solvent extractor, solvent exchange and a lipid removal step. The concentrated extract then injected in a HPLC-MS-MS system then the same extract either directly injected in GC-MS-MS or further purified using headspace solid phase micro extraction before the GC-NS-MS step. The method was used with good results for analyzing samples collected from farm workers using OP pesticides.

Toxicology

Organophosphate

mass spectrometry

Chemistry

On the Biochemistry, Mechanism and Physiological Role of Fungal Nitronate Monooxygenase

Francis, Kevin

27 April 2011

Nitronate monooxygenase (E.C. 1.13.11.16), formerly known as 2-nitropropane dioxygenase (EC 1.13.11.32), is a flavin dependent enzyme that catalyzes the oxidation of nitronates to their corresponding carbonyl compounds and nitrite. Despite the fact that the enzyme was first isolated from Neurospora crassa 60 years ago, the biochemical and physiological properties of nitronate monooxygenase have remained largely elusive. This dissertation will present the work that established both the catalytic mechanism and physiological role of the fungal enzyme. The biological and biochemical properties of propionate-3-nitronate, the recently discovered physiological substrate for nitronate monooxygenase, will be extensively reviewed. The nitronate is produced by a variety of variety leguminous plants and fungi and is a potent and irreversible inhibitor of succinate dehydrogenase. Nitronate monooxygenase allows N. crassa to overcome the toxicity of propionate-3-nitronate as demonstrated by in vivo studies of the yeast, which showed that the wild-type can grow in the presence of the toxin whereas a knock out mutant that lacks the gene encoding for the enzyme could not. In addition to establishing the physiological role of nitronate monooxygenase, the work presented here demonstrates that the catalytic mechanism of the enzyme involves the formation of an anionic flavosemiquinone intermediate. This intermediate is stabilized by the protonated form of an active site histidine residue (His-196) that acts as an electrostatic catalyst for the reaction as demonstrated by pH studies of the reductive half reaction of the enzyme. Histidine 196 also serves as the catalytic base for the reaction of the enzyme with nitroethane as substrate as revealed through mutagenesis studies in which the residue was replaced with an asparagine. The kinetic implications of branching of reaction intermediates in enzymatic catalysis are also demonstrated through studies of the kinetic isotope effects of nitronate monooxygenase with 1,1-[2H2]-nitroethane as substrate. Finally the use of competitive inhibitors as a probe of enzyme structure will be presented through a study of the inhibition of nitronate monooxygenase with mono-valent inorganic ions. The dissertation will close with unpublished work on the enzyme and concluding remarks concerning the biochemistry and physiology of nitronate monooxygenase.

Nitronate monooxygenase

2-Nitropropane dioxygenase

Kinetic isotope and pH effects

Flavin semiquinone

Nitroalkanes

3-Nitropropionate

Propionate-3-nitronate

Chemistry

I. Synthesis Of Anthraquinone Derivatives For Electron Transfer Studies In DNA. II. Characterization Of The Interaction Between Heme And Proteins.

Cao, Yu

11 August 2011

Anthraquinone (AQ) derivatives with relatively high reduction potentials have been synthesized to afford good candidates for electron transfer studies in DNA. Electron withdrawing groups on the anthraquinone ring gave derivatives with less negative reduction potentials. The anthraquinone imide (AQI) derivatives had reduction potentials less negative than AQ derivatives. The AQI ring system was subject to base-induced hydrolysis. Water-soluble sulfonated tetraarylporphyrins have been studied in a wide variety of contexts. Herein, we report the first synthesis of a pentasulfonated porphyrin bearing an internal cyclic sulfone ring. Treatment of 5,10,15,20-tetrakis(4-sulfonatophenyl)porphyrin (TPPS4) with fuming H2SO4 gave a structure consistent with initial sulfonation followed by dehydration to give a sulfone bridge between an ortho-position of one of the phenyl groups and a β-pyrrole position on the porphine ring (TPPS4Sc). The structure was established by ESI-MS and 1HNMR. The Soret absorption is red shifted by about 32 nm compared to that of TPPS4. Streptococcus pyogenes obtains iron by taking up heme from the environment during infection. One of the heme uptake pathways is the Sia or Hts pathway. The initial protein in this pathway is Shr, which has two heme-binding NEAT domains, NEAT1 nearer the N-terminus, and NEAT2 nearer the C-terminus. We report biophysical characteristics of these two NEAT domains. To assess stability of this domain towards heme release, denaturation studies of the Fe(II) and Fe(III) forms were performed. For each domain, both the Fe(II) and the Fe(III) forms behave similarly in thermal denaturation and guanidinium denaturation. Overall, NEAT2 is more stable than NEAT1. Spectral signatures, sequence alignment and homology modeling for both domains suggest that one of the axial ligands is methionine. NEAT2 autoreduces as the pH increases and autooxidizes as the pH decreases. Heme uptake from the host environment is the only iron acquisition pathway in S. pyogenes; inhibition of this pathway might be an approach to infection control. Compounds that might inhibit the heme uptake pathway were selected via virtual screening.

Anthraquinone imide

Water-soluble porphyrin

Streptococcus pyogenes ShrNEAT

Unfolding

Ligand

Virtual screening

Chemistry

Synthesis and Characterization of Metal Nanoclusters Stabilized by Dithiolates

Robinson, Donald A, III

19 July 2011

Rapidly expanding research in nanotechnology has led to exciting progress in a versatile array of applications from medical diagnostics to photocatalytic fuel cells. Such success is due to the ability of researchers to manipulate the desired properties of nanomaterials by controlling their size, shape, and composition. Among the most thriving areas of nanoparticle research has been the synthesis and characterization of stable metallic nanoclusters capped by thiolate ligands. Our group has extended this research to study copper, silver, and gold clusters with remarkable stability and energetics, which was achieved by using dithiolates as the ligand stabilizers. In addition to the enhanced stability offered by the chelate effect, the use of dithiolate ligands instead of monothiolates is proposed to provide an alternate interfacial bond structure that is shown to strongly influence energetic properties of nanoclusters, with strong evidence of metal-ligand charge transfer. Energetic properties were characterized by spectroscopic and electrochemical methods.

Electrochemistry

Nanocluster

Dithiolate

Gold

Silver

Copper

On the Mechanistic Roles of the Protein Positive Charge Close to the N(1)Flavin Locus in Choline Oxidase

Ghanem, Mahmoud

12 June 2006

Choline oxidase catalyzes the oxidation of choline to glycine betaine. This reaction is of considerable medical and biotechnological applications, because the accumulation of glycine betaine in the cytoplasm of many plants and human pathogens enables them to counteract hyperosmotic environments. In this respect, the study of choline oxidase has potential for the development of a therapeutic agent that can specifically inhibit the formation of glycine betaine, and therefore render pathogens more susceptible to conventional treatment. The study of choline oxidase has also potential for the improvement of the stress resistance of plant by introducing an efficient biosynthetic pathway for glycine betaine in genetically engineered economically relevant crop plant. In this study, codA gene encoding for choline oxidase was cloned. The cloned gene was then used to express and purify the wild-type enzyme as well as to prepare selected mutant forms of choline oxidase. In all cases, the resulting enzymes were purified to high levels, allowing for detailed characterizations. The biophysical and biochemical analyses of choline oxidase variants in which the positively charged residue close to the flavin N(1) locus (His466) was removed (H466A) or reversed (H466D) suggest that in choline oxidase, His466 modulates the electrophilicity of the bound flavin and the polarity of the active site, and contributes to the flavinylation process of the covalently bound FAD as well as to the stabilization of the negative charges in the active site. Biochemical, structural, and mechanistic relevant properties of selected flavoproteins with special attention to flavoprotein oxidases, as well as the biotechnological and medical relevance of choline oxidase, are presented in Chapter I. Chapter II summarizes all the experimental techniques used in this study. Chapter III-VII illustrate my studies on choline oxidase, including cloning, expression, purification and preliminary characterizations (Chapter III), spectroscopic and steady state kinetics (Chapter IV), the catalytic roles of His466 and the effects of reversing the protein positive charge close to the flavin N(1) locus (Chapter V and VI), and the roles of His310 with a special attention to its involvement in a proton-transfer network (Chapter VII). Chapter VIII presents a general discussion of the data presented.

Active Site Base

Flavin N(1) Locus

Proton-Transfer Network

Chemical Mechanism

Flavoprotein

Choline Oxidase

Chemistry

Shape-Dependent Molecular Recognition of Specific Sequences of DNA by Heterocyclic Cations

Miao, Yi

03 August 2006

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

small molecule

minor groove binding

energetics

binding entropy

binding free energy

binding enthalpy

Chemistry

Design of Novel Molecular Micelles for Capillary Electrophoresis

Rizvi, Syed Asad Ali

29 August 2006

The research presented in this dissertation involves the synthesis, characterization, and application of novel anionic and cationic chiral molecular micelles in capillary electrophoresis (CE) for the separation of diverse chiral compounds. Chapter 1 presents brief overview of the surfactants, micelle polymer, CE and micellar electrokinetic chromatography (MEKC). Chapter 2 describes the simultaneous enantioseparation of eight single chiral center â-blockers using two novel leucine and isoleucine based polymeric surfactants. The simultaneous enantioseparation of multichiral center bearing â-blockers, nadolol and labetalol is described in chapter 3. A synergistic approach, using a combination of polysodium N-undecenoxycarbonyl-L-isoleucinate (poly-L-SUCIL) and sulfated â-CD showed dramatic enantioseparation of four stereoisomers of nadolol. On the other hand for labetalol, enantiomeric separation remains unaffected using the dual chiral selector system. Chapter 4 deals with the enantiomeric separation of the binaphthyl derivatives that was found to be influenced by pH, type and concentration of the background electrolyte as well as concentration of the polymeric surfactant. In chapter 5, characterization of five alkenoxy leucine-based surfactants with variations in chain length (C8-C11), polymerization concentration and degree of polymerization showed significant effects on the chiral resolution and efficiency of hydrophobic â-blockers. The synthesis and characterization of two positively charged amino acid derived chiral ionic liquids (ILs) and their corresponding polymers is presented in chapter 6. Chiral separation of two acidic analyte (difficult to resolve with anionic micelles) can be achieved with both monomers and polymers of ILs. In chapter 7, the synthesis and detailed characterization of three pH independent amino acids derived (L-leucinol, L-isoleucinol and L-valinol) sulfated chiral polymeric surfactants is presented. These chiral sulfated surfactants are thoroughly characterized and the morphological behavior of polymeric sulfated surfactants is revealed using cryogenic high-resolution electron microscopy. The work clearly demonstrates for the first time the superiority of chiral separation in MEKC coupled to mass spectrometry at low pH. Finally, in chapter 8, six amino acid derived chiral surfactants with carboxylate and sulfate head groups were compared for enantioseparation of broad range of structurally diverse racemic compounds at neutral and basic pH conditions.

Hydrophobic Chain Length

Polar head Group

Molecular Micelles

Chiral Separations

Chemistry