Development of RNA Microchip for the Detection of Pathogens

Spencer, Sarah M

19 April 2010

Detection of cellular messenger RNA is a useful diagnostic strategy for the detection of patho-gens. A rapid and sensitive method for on-site detection of specific pathogens would be of great use in a number of fields. For example, a simple and inexpensive method for the detection of harmful biological agents in train stations and airports is useful for national security. Rapid detection of pathogenic E. coli strains in food production would also be of great benefit in ensuring the safety and quality of our food supply. Here we present a method for the rapid de-tection of cellular mRNA. This system is based on the 3’-labeling approach in which targeted RNA is simultaneously extended and labeled with the use of biotin labeled-dNTPs and DNA po-lymerase on an immobilized nucleic acid probe. The biotin is subsequently converted to an enzymatic label, which produces a detectable chemiluminescent reaction in the presence of substrate. Detection time of this system is short (approximately 20 minutes) because there is no need for amplification by PCR, transcription, or fluorophore labeling. This novel methodology has been successfully demonstrated by selective detection of lac Z mRNA in a total RNA sample from E. coli.

Nucleic acid based detection

RNA

Pathogen detection

Microchip

Microarray

Chemistry

Roles of Serine 101, Histidine 310 and Valine 464 in the Reaction Catalyzed by Choline Oxidase from Arthrobacter Globiformis

Finnegan, Steffan

05 March 2010

The enzymatic oxidation of choline to glycine betaine is of interest because organisms accumulate glycine betaine intracellularly in response to stress conditions, as such it is of potential interest for the genetic engineering of crops that do not naturally possess efficient pathways for the synthesis of glycine betaine, and for the potential development of drugs that target the glycine betaine biosynthetic pathway in human pathogens. To date, one of the best characterized enzymes belonging to this pathway is the flavin-dependent choline oxidase from Arthrobacter globiformis. In this enzyme, choline oxidation proceeds through two reductive half-reactions and two oxidative half-reactions. In each of the reductive half-reactions the FAD cofactor is reduced to the anionic hydroquinone form (2 e- reduced) which is followed by an oxidative half-reaction where the reduced FAD cofactor is reoxidized by molecular oxygen with formation and release of hydrogen peroxide. In this dissertation the roles of selected residues, namely histidine at position 310, valine at position 464 and serine at position 101, that do not directly participate in catalysis in the reaction catalyzed by choline oxidase have been elucidated. The effects on the overall reaction kinetics of these residues in the protein matrix were investigated by a combination of steady state kinetics, rapid kinetics, pH, mutagenesis, substrate deuterium and solvent isotope effects, viscosity effects as well as X-ray crystallography. A comparison of the kinetic data obtained for the variant enzymes to previous data obtained for wild-type choline oxidase are consistent with the valine residue at position 464 being important for the oxidative half-reaction as well as the positioning of the catalytic groups in the active site of the enzyme. The kinetic data obtained for the serine at position 101 shows that serine 101 is important for both the reductive and oxidative half-reactions. Finally, the kinetic data for histidine at position 310 suggest that this residue is essential for both the reductive and oxidative half-reactions.

Oxygen reactivity

Flavin oxidation

Choline oxidase

Flavoprotein

Proton-transfer network

Chemical mechanism

Chemistry

Design and Synthesis of Boronic Acid-Modified Nucleotides for Fluorescent Sensing and Cell Imaging

Yang, Xiaochuan

17 December 2009

With the rapidly increasing interest in the field of glycomics, which is the comprehensive study of the roles carbohydrates play in a living system, urgent need for developing quick and highly selective carbohydrate sensors is growing. The boronic acid group, with its electron-deficient structure (6 valence electrons with an open shell), acts as a Lewis acid with high intrinsic affinity towards Lewis bases such as fluoride, cyanide and hydroxyl groups. Specifically, formation of a 5- or 6- membered ring between the boronic acid moiety and a1,2- or 1,3-diol in aqueous solution has been fully explored as a strategy of carbohydrate sensor design. Along this line, those binders were termed as ¡°boronolectins¡± because of their similar functions as lectins. One challenge in developing boronic acid-based carbohydrate sensors is to enhance the discriminating ability among various carbohydrate analytes with diverse building blocks and complex linkage patterns. One approach is using polypeptide or oligonucleotide as a backbone or scaffold with functionalized boronic acid moiety to create a molecular library, and then selecting binders with favorable properties. The work presented here includes three general research parts: synthesis of a naphthalimide-based boronic acid-conjugated thymidine triphosphate (NB-TTP), fluorescence property studies of NB-TTP incorporated DNA (NB-DNA), and cellular imaging studies using NB-TTP: 1) 4-Amino-1,4-naphthalimide (Nap) was chosen as the fluorophore because of its relatively long excitation and emission wavelengths, and stability. The synthesis of naphthalimide-based boronic acid (NB) followed similar route as previously published work. Tethering of boronic acid moiety and TTP was accomplished through Cu(I)-catalyzed azide-alkyne cyclization (CuAAC), known as click chemistry. The synthesized NB-TTP showed fluorescence enhancements at long wavelength (¦Ëem: 540 nm) upon sugar addition. 2) NB-TTP was incorporated into DNA through Klenow fragment-catalyzed primer extension reactions. Different DNA sequences were designed with varying number and spacing for NB-TTP incorporation. The preliminary study provided certain insight into several factors that affect the fluorescent properties of different NB -DNA. 3) NB-TTP was added into Hela cell culture medium to study its cell imaging properties. With the observation under fluorescent microscope, it was demonstrated that NB-TTP showed good cell membrane permeability and significant accumulation in cell nucleus.

DNA

Carbohydrate sensor

Cell imaging

Fluorescence

Boronic acid

Chemistry

Diagnosis and Inhibition Tools in Medicinal Chemistry

Akay, Senol

29 May 2009

Cell surface saccharides are involved in a variety of essential biological events. Fluorescent sensors for saccharides can be used for detection, diagnosis, analysis and monitoring of pathological processes. The boronic acid functional group is known to bind strongly and reversibly to compounds with diol groups, which are commonly found on saccharides. Sensors that have been developed for the purpose of saccharide recognition have shown great potential. However, they are very hydrophobic and this lack of essential water-solubility makes them useful in biological applications. The first section of this dissertation details the process of developing water-soluble saccharide sensors that change fluorescent properties upon binding to saccharides. The second section of the dissertation focuses on the development of DNA-minor groove binders as antiparasitical agents. Parasitical diseases comprise some of the world’s largest health problems and yet current medication and treatments for these parasitical diseases are often difficult to administer, costly to the patients, and have disruptive side effects. Worse yet, these parasites are developing drug resistance, thus creating an urgent need for new treatments. Dicationic molecules constitute a class of antimicrobial drug candidates that possess high activity against various parasites. The second section details the development of a series of di-cationic agents that were then screened in in vitro activities against parasitical species.

Carbohydrate sensing

Boronolectins

Benzo[b]thiophene boronic acid

Physiological pH

DNA-minor groove

HAT

DNA-binders

Malaria

Leishmaniasis

Chemistry

Synthesis and Enzymatic Studies of Selenium Derivatized Nucleosides, Nucleotides and Nucleic Acids

Caton-Williams, Julianne Marie

14 June 2009

Nucleoside 5-triphosphates are the building blocks to synthesis of nucleic acids. Nucleic acids (RNA and DNA) participate in many important biological functions in living systems, including genetic information storage, gene expression, and catalysis. Nucleoside 5- triphosphates have many important therapeutic and diagnostic applications. To understand how these triphosphates are utilized in living systems, numerous synthetic mimics have been prepared and used as active metabolites of certain drugs and molecular probes. Over the years, nucleic acids have been modified at the nucleobase, sugar moiety and phosphate backbone with the aim of understanding their structures and functions. We have site-specifically replaced selected oxygen atoms of nucleosides and nucleotides with selenium atom in order to enzymatically synthesize selenium-derivatized DNAs for obtaining insights into the DNA flexibility, duplex recognition and stability. Although triphosphates have important biological and medicinal significance, they are however, very difficult to synthesize and isolate in high purity and yield. There are many approaches to the synthesis of nucleoside 5-triphosphates, but there is no general strategy that allows simple and direct synthesis of nucleoside triphosphates. To face the challenges, we have developed a new approach in the absence of protecting groups to quickly and efficiently synthesized native deoxynucleoside 5-triphosphates and deoxynucleoside 5-(α- P-seleno)- P-seleno)triphosphates. Syntheses of the triphosphates containing selenium-derivatized nucleobases were also successfully accomplished. After replacing the oxygen atoms at the 4-position of thymidine and uridine, and the 6-position of guanosine, we observed most strikingly, a large bathrochromic shift of over 100 nm, relative to their native counterparts of UV absorbance of 260 nm. Consequently, the synthesized selenium base modified triphosphates are yellow. We also synthesized 2-selenothymidine and 5-methylseleno thymidine 5-triphosphates. We conducted stability study on the colored 4-selenothymidine and used the 5- triphosphate analog (4-SeTTP) as substrate for polymerase recognition. The Klenow polymerase incorporated the 4-SeTTP with efficiency equal to that of the native counterpart. Finally, 4-SeTTP was used to demonstrate UVdamage resistance of selenium-derivatized DNAs and plasmid.

Colored 4-selenothymidine

Plasmid

Klenow polymerase

Bathrochromic shift

Stability

Nucleic acids

Nucleoside 5½-triphosphates

Selenium-derivatized DNA

DNA flexibility

Duplex recognition

Chemistry

Design Genetic Fluorescent Probes to Detect Protease Activity and Calcium-Dependent Protein-Protein Interactions in Living Cells

Chen, Ning

25 August 2008

Proteases are essential for regulating a wide range of physiological and pathological processes. The imbalance of protease activation and inhibition will result in a number of major diseases including cancers, atherosclerosis, and neurodegenerative diseases. Although fluorescence resonance energy transfer (FRET)-based protease probes, a small molecular dye and other methods are powerful, they still have drawbacks or limitations for providing significant information about the dynamics and pattern of endogenous protease activation and inhibition in a single living cell or in vivo. Currently protease sensors capable of quantitatively measuring specific protease activity in real time and monitoring activation and inhibition of enzymatic activity in various cellular compartments are highly desired. In this dissertation, we report a novel strategy to create protease sensors by grafting an enzymatic cleavage linker into a sensitive location for changing chromophore properties of enhanced green fluorescent protein (EGFP) following protease cleavage, which can be used to determine protease activity and track protease activation and inhibition with a ratiometric measurement mode in living cells. Our designed protease sensors exhibit large relative ratiometric optical signal change in both absorbance and fluorescence, and fast response to proteases. Meanwhile, these protease sensors exhibiting high enzymatic selectivity and kinetic responses are comparable or better than current small peptide probes and FRET-based protease probes. Additionally, our protease sensors can be utilized for real-time monitoring of cellular enzymogen activation and effects of inhibitors in living cells. This novel strategy opens a new avenue for developing specific protease sensors to investigate enzymatic activity in real time, to probe disease mechanisms corresponding to proteases in vitro and in vivo, and to screen protease inhibitors with therapeutic effects. Strong fluorescence was still retained in the cleaved EGFP-based protease sensors, which stimulated us to identify the EGFP fragment with fluorescence properties for further understanding chromophore formation mechanisms and investigating protein-protein interactions through fluorescence complementation of split EGFP fragments. Through fusing EF-hand motifs from calbindin D9k to split EGFP fragments, a novel molecular probe was developed to simultaneously track the calcium change or calcium signaling pathways and calcium-dependent protein-protein interaction in living cells in real time.

Protein-protein interactions

Calcium-dependent

Fluorescence complementation

EGFP

Ratiometeric measurement

Protease sensor

Chemistry

Biochemical and Spectroscopic Characterization of Tryptophan Oxygenation: Tryptophan 2, 3-Dioxygenase and Maug

Fu, Rong

10 June 2009

TDO utilizes b-type heme as a cofactor to activate dioxygen and insert two oxygen atoms into free L-tryptophan. We revealed two unidentified enzymatic activities of ferric TDO from Ralstonia metallidurans, which are peroxide driven oxygenation and catalase-like activity. The stoichiometric titration suggests that two moles of H2O2 were required for the production of one mole of N-formylkynurenine. We have also observed monooxygenated-L-tryptophan. Three enzyme-based intermediates were sequentially detected in the peroxide oxidation of ferric TDO in the absence of L-Trp including compound I-type and compound ES-type Fe-oxo species. The Fe(IV) intermediates had an unusually large quadrupole splitting parameter of 1.76(2) mm/s at pH 7.4. Density functional theory calculations suggest that it results from the hydrogen bonding to the oxo group. We have also demonstrated that the oxidized TDO was activated via a homolytic cleavage of the O-O bond of ferric hydroperoxide intermediate via a substrate dependent process to generate a ferrous TDO. We proposed a peroxide activation mechanism of the oxidized TDO. The TDO has a relatively high redox potential, the protonated state of the proximal histidine upon substrate binding as well as a common feature of the formation of ferric hydroxide species upon substrate or substrate analogues binding. Putting these together, we have proposed a substrate-based activation mechanism of the oxidized TDO. Our work also probed the role of histidine 72 as an acid-base catalyst in the active site. In H72S and H72N mutants, one water molecule plays a similar role as that of His72 in wild type TDO. MauG is a c-type di-heme enzyme which catalyze the biosynthesis of the protein-derived cofactor tryptophan tryptophylquinone. Its natural substrate is a monohydroxylated tryptophan residue present in a 119-kDa precursor protein of methylamine dehydrogenase (MADH). We have trapped a novel bis-Fe(IV) intermediate from MauG, which is remarkably stable. A tryptophanyl radical intermediate of MADH has been trapped after the reaction of the substrate with the bis-Fe(IV) intermediate. Analysis by high-resolution size-exclusion chromatography shows that MauG can tightly bind to the biosynthetic precursor and form a stable complex, but the mature protein substrate does not.

Site-directed mutagenesis

Protein-substrate complex

Mössbauer spectroscopy

Acid-base catalyst

Protein radical

Ferric hydroxide

Ferric hydroperoxide

Bis-Fe(IV) intermediate

Ferryl species

Hydrogen peroxide

Tryptophan 2 3-dioxygenase

MauG

Chemistry

On the Preorganization of the Active Site of Choline Oxidase for Hydride Transfer and Tunneling Mechanism

Quaye, Osbourne

23 June 2009

Choline oxidase catalyzes the two-step oxidation of choline to glycine betaine, one of limited osmoprotectants, with the formation of betaine aldehyde as an enzyme bound intermediate. Glycine betaine accumulates in the cytoplasm of plants and bacteria as a defensive mechanism to withstand hyperosmolarity and elevated temperatures. This makes the genetic engineering of relevant plants which lack the property of salt accumulation of economic interest, and the biosynthetic pathway of the osmolyte a potential drug target in microbial infections. The reaction of alcohol oxidation occurs via a hydride ion tunneling transfer from the substrate donor to a flavin acceptor within a highly preorganized active site environment in which choline and FAD are in a rigidly close proximity. In this dissertation, factors contributing to the enzyme-substrate preorganization which is required for the hydride ion tunneling reaction mechanism in choline oxidase have been investigated. Crystallographic studies of wild-type choline oxidase revealed a covalent linkage between C8M atom of the FAD isoalloxazine ring and the N(3) atom of the side chain of a histidine at position 99, and a solvent excluded cavity in the substrate binding domain containing glutamic acid at position 312 as the only negatively charged amino acid residue in the active site of the enzyme. The role of the histidine residue and the contribution of the 8á-N(3)-histidyl covalent linkage of the flavin cofactor to the reaction of alcohol oxidation was investigated in a variant form of choline oxidase in which the histidine residue was replaced with an asparagine. The role of the glutamate residue and the importance of the spatial location of the negative charge at position 312 was investigated in variant forms of choline oxidase in which the negatively charged residue was replaced with glutamine and aspartate. Mechanistic data obtained for the variant enzymes and their comparison to previous data obtained for wild-type choline oxidase are consistent with the residues at positions 99 and 312 being important for relative positioning of the hydride ion donor and acceptor. The residues are important for the enzyme-substrate preorganization that is required for the hydride tunneling reaction in choline oxidase.

Hydride ion transfer

Flavoproteins

Flavinylation

Choline oxidase

Quantum mechanical tunneling

Preorganization

Chemistry

Bead Modeling of Transport Properties of Macromolecules in Free Solution and in a Gel

Pei, Hongxia

15 June 2010

On the bead modeling methodology, or BMM, a macromolecule is modeled as a rigid, non-overlapping bead array with arbitrary radii. The BMM approach was pioneered by Kirkwood and coworkers (Kirkwood, J.G., Macromolecules, E.P. Auer (Ed.), Gordon and Breach, New York, 1967; Kirkwood, J.G., Riseman, J., J. Chem. Phys., 1948, 16, 565) and applied to such transport properties as diffusion, sedimentation, and viscosity. With the availability of computers, a number of investigators extended the work to account for the detailed shape of biomolecules in the 1970s. A principle objective of my research has been to apply the BMM approach to more complex transport phenomena such as transport in a gel, electrophoresis (free solution and in a gel), and also transport in more complex media (such as the viscosity of alkanes and benzene). Variables considered by the BMM include the number of beads (N), the radii of the beads, net charge and charge distribution, conformations, salt type, and salt concentration. The BMM has been extended to: (1) account for the existence of a gel; (2) characterize the charge and secondary structure of macromolecules; (3) account more accurately for hydrodynamic interaction (remove the orientationnal preaveraging approximation of hydrodynamic interaction); (4) study the effect of ion relaxation for particles in arbitrary size, shape, and charge; (5) consider the salt dependence of electrokinetic properties; (6) account for the formation of possible complex between guest ions and BGE ions. We also did diffusion constant measurement by NMR for amino acids and short peptides in 10%D2O-90% H2O at room temperature and applied to our modeling study by BMM.

Agarose gel

Bead model

Complex formation

DNA

Effective medium

Hydrodynamic interaction

NMR

Peptide

Relaxation

Salt dependence

Chemistry

Rational Drug Design for Neglected Diseases: Implementation of Computational Methods to Construct Predictive Devices and Examine Mechanisms

Collar, Catharine Jane

18 August 2010

Over a billion individuals worldwide suffer from neglected diseases. This equates to approximately one-sixth of the human population. These infections are often endemic in remote tropical regions of impoverished populations where vectors can flourish and infected individuals cannot be effectively treated due to a lack of hospitals, medical equipment, drugs, and trained personnel. The few drugs that have been approved for the treatments of such illnesses are not widely used because they are riddled with inadequate implications of cost, safety, drug availability, administration, and resistance. Hence, there exists an eminent need for the design and development of improved new therapeutics. Influential world-renowned scientists in the Consortium for Parasitic Drug Development (CPDD) have preformed extensive biological testing for compounds active against parasites that cause neglected diseases. These data were acquired through several collaborations and found applicable to computational studies that examine quantitative structure-activity relationships through the development of predictive models and explore structural relationships through docking. Both of these in silico tools can contribute to an understanding of compound structural importance for specific targets. The compilation of manuscripts presented in this dissertation focus on three neglected diseases: trypanosomiasis, Chagas disease, and leishmaniasis. These diseases are caused by kinetoplastid parasites Trypanosoma brucei, Trypanosoma cruzi, and Leishmania spp., respectively. Statistically significant predictive devices were developed for the inhibition of the: (1) T. brucei P2 nucleoside transporter, (2) T. cruzi parasite at two temperatures, and (3) two species of Leishmania. From these studies compound structural importance was assessed for the targeting of each parasitic system. Since these three parasites are all from the Order Kinetoplastida and the kinetoplast DNA has been determined a viable target, compound interactions with DNA were explored to gain insight into binding modes of known and novel compounds.

Trypanosomiasis

Leishmaniasis

Chagas Disease

3D-QSAR

Molecular Modeling

Docking

Chemistry