Toward the Development of Nucleic Acid Assays Using Fluorescence Resonance Energy Transfer (FRET) and a Novel Label Free Molecular Switching Construct

Massey, Melissa

06 December 2012

The research presented in this thesis introduces design criteria for development of a new type of self-contained optical biosensor. The study begins with evaluation of a dual label, fluorescence resonance energy transfer (FRET) bioassay format, and then goes on to demonstrate a signalling platform that uses an immobilized fluorescent intercalating dye so as to avoid labelling of both the target and probe strands. An extensive survey of FRET pairs that can be used to monitor hybridization events in solution and at solid interfaces was conducted in solution to provide a set of calculated Förster distances for the extrinsic labels Cyanine 3 (Cy3), Cyanine 5 (Cy5), Carboxytetramethylrhodamine (TAMRA), Iowa Black Fluorescence Quencher (IabFQ) and Iowa Black RQ (IabRQ). FRET parameters using thiazole orange (TO) intercalating dye as a FRET donor for various acceptor dye-labelled DNA conjugates in solution were determined. Limitations associated with quenching mechanisms other than those mediated by FRET motivated the development of a molecular switch that contained intercalating dye. The four binding sites associated with Neutravidin served for assembly of the switch using biotin interactions. One binding site was used to immobilize an unlabelled oligonucleotide probe. The adjacent site was used to immobilize a novel biotinylated TO derivative that could physically reach the probe. On hybridization of the probe with target, the intercalating dye was captured by the hybrid, leading to a change of fluorescence. This reversible signalling mechanism offers a method without nucleic acid labelling to detect nucleic acid association at an interface. A SNP discrimination strategy involving TO and formamide was investigated, and SNP discrimination without the requirement of thermal denaturation was achieved for multiple target lengths, including a 141-base pair PCR amplicon in solution. It was determined that formamide could also provide improvements of signal-to-noise when using thiazole orange to detect hybridization.

fluorescence

molecular switch

nucleic acid

thiazole orange

0486

A Method for Selective Concentrating of DNA Targets by Capillary Affinity Gel Electrophoresis

Chan, Andrew

02 August 2013

A method for the selective concentrating of DNA targets using capillary affinity gel electrophoresis is presented. Complementary ssDNA targets are retained through hybridization with oligonucleotide probes immobilized within polyacrylamide gels while non-complementary targets are removed. The captured DNA targets were concentrated by step elution, where a localized thermal zone was applied in small steps along the capillary. Evaluation of the selective capture of a 150 nt DNA target in a complicated mixture was carried out by factorial analysis. Gels with a smaller average pore size were found to retain a higher amount of complementary targets. This was thought to be due to the ssDNA target migrating through the gel by reptation, eliminating hairpin structures, making the complementary region of the target available for hybridization. This method was applied to a series of DNA targets of different lengths, 19 nt, 150 nt, 250 nt and 400 nt. The recovery of the method ranged from 0.5 to 4% for the PCR targets, and 13 to 18% for the 19 nt oligonucleotide target. The purity was calculated to be up to 44% for the PCR targets and up to 86% for the 19 nt target. This was an improvement in purity of up to 15 times and 1100 times in comparison to the original samples for the PCR targets and 19 nt oligonucleotide, respectively. The 19 nt targets were selective concentrated and delivered into a microfluidic based DNA biosensing platform. The purity of the sample improved from 0.01% to 50% while recovery decreased from 100% to 20% for a sample with 0.5 nM complementary and 1 μM non-complementary targets. An improvement in the response of the sensing platform was demonstrated on 19 nt oligonucleotide targets delivered by selective concentration versus concentration alone into the microfluidic biosensing system.

Capillary Affinity Gel Electrophoresis

DNA Purification

Sample Enrichment

0486

Hydrolysis and Atmospheric Oxidation Reactions of Perfluorinated Carboxylic Acid Precursors

Jackson, Derek Andrew

08 August 2013

This dissertation explores a number of different environmentally relevant reactions that lead to the production of perfluorocarboxylic acids (PFCAs), a family of environmental pollutants that does not undergo any further degradation pathways. The compound perfluoro-2-methyl-3-pentanone (PFMP) is a new fire fighting fluid developed by 3M that is designed as a Halon replacement. The environment fate of PFMP with regards to direct photolysis, abiotic hydrolysis and hydration was determined using a combination of laboratory experiments and computational modeling. PFMP was found to undergo direct photolysis giving a lifetime of 4-14 days depending on latitude and time of year. Offline samples confirmed PFCA products and a mechanism was proposed. Polyfluorinated amides (PFAMs) are a class of chemicals produced as byproducts of polyfluorinated sulfonamide synthesis via electrochemical fluorination (ECF). Using synthesized standards of four model compounds, PFAMs were detected and quantified in a variety of legacy commercial materials synthesized by ECF. PFAMs were hypothesized to undergo biological hydrolysis reactions, suggesting their importance as historical PFOA precursors. The PFAMs were also investigated with regards to their environmental fate upon atmospheric oxidation. Using a smog chamber, the kinetics and degradation mechanisms of N-ethylperfluorobutyramide (EtFBA) were elucidated. The lifetime of EtFBA to oxidation by OH was found to be approximately 4 days. Using offline sampling, PFAMs were shown to give PFCAs upon atmospheric oxidation and a plausible mechanism was proposed involving an initial N-dealkylation step followed by loss of isocyanic acid to give a perfluorinated radical. The perfluorinated radical then produces PFCAs by a series of known atmospheric reactions. Finally, the biological hydrolysis of the polyfluoroalkyl phosphate monoesters (monoPAPs) were studied in vitro using a bovine alkaline phosphatase enzyme. Michaelis-Menten kinetic parameters were measured and compared to hexyl phosphate. It was discovered that monoPAPs hydrolyzed on average 100 times faster than hexyl phosphate due to the electron withdrawing fluorine substituents. The results were also used to rationalize the results of a previous in vivo study which suggested monoPAPs were rapidly hydrolyzed in the small intestines of rats following a high dose by oral gavage.

environmental

chemistry

analytical

transformation

fluorinated

PFCA

atmospheric

hydrolysis

0486

Direct and Indirect Sources of Human Exposure to Perfluorinated Carboxylates: Investigating the Significance of Perfluorinated Carboxylate Reactive Precursor Metabolites

Rand, Amelia

09 August 2013

Perfluorinated carboxylates (PFCAs) are persistent and ubiquitous in the environment. Humans are exposed to PFCAs through direct and indirect sources, although the relative importance of each is uncertain. Direct sources of PFCAs have been attributed to two primary fluorochemical manufacturing processes: electrochemical fluorination (ECF) and telomerization. A focus of this thesis was to elucidate an additional direct source of PFCAs resulting from the direct fluorination of polyolefin materials. High density polyethylene bottles with varying levels of fluorination were observed to contain significant amounts of PFCAs, particularly those with carbon chain-lengths ≤ C6, marking an unexplored source of PFCA exposure. PFCAs are also produced indirectly from the biotransformation of fluorotelomer-based compounds, such as polyfluoroalkyl phosphate esters (PAPs) and fluorotelomer alcohols (FTOHs). During this transformation process, two predominant classes of metabolic intermediates are formed: the fluorotelomer unsaturated aldehydes (FTUALs) and the fluorotelomer unsaturated carboxylic acids (FTUCAs). Another focus of this thesis was to examine the reactivity of FTUALs and FTUCAs with endogenous nucleophiles such as glutathione (GSH), select amino acids, and model proteins. FTUALs formed adducts with all nucleophiles examined, where those having shorter carbon chain lengths (i.e. 6:2 and 8:2 FTUAL) were more reactive than longer carbon chains (i.e. 10:2 FTUAL). By contrast, FTUCAs had comparably limited reactivity; although FTUCAs showed mild reactivity with GSH, they did not react with any other nucleophiles. In vitro and in vivo experiments were carried out to determine the extent of protein binding formed from the biotransformation of fluorotelomer-based compounds, including the 8:2 FTOH and the 6:2 PAP diester. A significant portion of these biotransformations yielded covalent protein binding at nmol/mg protein concentrations. Protein adducts were observed predominantly in rat liver and also in plasma and kidney. The formation of reactive intermediates may be toxicologically important through protein deactivation. Cellular toxicity of FTUALs was significantly higher compared to PFCAs and the acid metabolic intermediates (i.e. FTUCAs). The EC50 values calculated from dose-response incubations were dependant on chain length and functional group. The work in this thesis examined an unexplored consequence of indirect exposure to PFCAs, potentially impacting the relative importance of PFCA exposure sources.

Environmental Chemistry

Perfluorinated Carboxylates

Fluorotelomer

Reactivity

Biotransformation

Persistent

0486

0485

Intrinsic Properties of Rhodamine B and Fluorescein Gas-phase Ions Studied using Laser-Induced Fluorescence and Photodissociation in a Quadrupole Ion Trap Mass Spectrometer

Sagoo, Sandeep K.

25 August 2011

Studying the intrinsic properties of molecules in the gas-phase is advantageous, since it reduces the complexity present in solution that arises from interactions between the molecule of interest and other species present in the local environment, including those with the solvent itself. In this report, the photophysical properties of gaseous cationic rhodamine B (RBH+) were determined and photodissociation reaction kinetics and power dependence of three prototropic forms of fluorescein; the cation ([F + H]+), monoanion ([F - H]-), and dianion ([F – 2H]-2), each of which possesses their own distinct spectral properties, were measured. The analyte ions of interest were formed via electrospray ionization, mass-selected and stored in a quadrupole ion trap mass spectrometer which has been customized to enable gas-phase spectroscopic studies. Knowledge of the intrinsic photophysical properties of such chromophores in the gas-phase will enable a better understanding of how the local environment of the molecule alters its properties.

Analytical

Chemistry

Mass Spectrometry

Laser-induced fluorescence

Photodissociation

0486

Sources and Fate of Organochlorine Pesticides in North America and the Arctic

Jantunen, Liisa M.

21 April 2010

Atmospheric transport and air-water exchange of organochlorine pesticides (OCPs) were investigated in temperate North America and the Arctic. OCPs studied were hexachlorocyclohexanes (HCHs, a-, b- and g-isomers), components of technical chlordane (trans- and cis-chlordane, trans-nonachlor), dieldrin, heptachlor exo-epoxide and toxaphene. Air and water samples were taken on cruises in the Great Lakes and Arctic to determine concentrations and gas exchange flux direction and magnitude. The Henry’s law constant, which describes the equilibrium distribution of a chemical between air and water, was determined for several OCPs as a function of temperature and used to assess the net direction of air-water exchange. Air samples were collected in Alabama to investigate southern U.S. sources of OCPs. Chemical markers (isomers, and enantiomers of chiral OCPs) were employed to infer sources and trace gas exchange. Elevated air concentrations of toxaphene and chlordanes were found in Alabama relative to the Great Lakes, indicating a southern U.S. source. Profiles of toxaphene compounds in air were similar to those in soil by being depleted in easily degraded species, suggesting that soil emissions control air concentrations. Gas exchange fluxes in the Great Lakes indicated near-equilibrium between air and water with excursions to net volatilization or deposition. Net volatilization of a-HCH from the Arctic Ocean was traced by evasion of non-racemic a-HCH into the atmosphere.

organochlorine pesticides

air-water gas exchange

toxaphene

hexachlorocyclohexanes

0486

Molecular Modeling of Immobilized Single and Double Stranded Oligonucleotides in Mixture with Oligomers

Al-Sarraj, Taufik

14 January 2011

Interactions between single and double stranded oligonucleotides with SiO2 surfaces and the interactions between oligonucleotides and immobilized oligomers have been studied computationally. The oligonucleotide is the 18-base-pair sequence for the survival motor neuron gene SMN1. The oligomer consisted of a 50 unit 2-hydroxyethyl methacrylate (PHEMA) molecule. A linker used to tether the oligonucleotide was either a 10 Å or a 30 Å long succinimdyl 4-[N-maleimidomethyl]cyclohexane-1-caroxylate (sulfo-SMCC-Cn). The surface consisted of a SiO2 crystal that was 50 Å long and 50 Å wide, one unit thick and covered with modified-(3-aminopropyl)trimethoxysilane (m-APTMS) molecules. It was determined that explicit water, sodium counterions and excess salt were necessary to produce computationally stable oligonucleotide structures on surfaces. Artificial partial charges were introduced to the surface, and linkers, oligomers and oligonucleotides were immobilized and studied. The linkers collapsed onto a positive but not onto a negative surface. Oligomers moved closer to the SiO2 surface regardless of the surface charge. Immobilized oligonucleotides tilted significantly from an initial upright position but did not collapse completely onto the surfaces. The interactions between immobilized oligonucleotides and oligomers were examined. The number of oligomers surrounding the oligonucleotide was varied between two and four. Single stranded oligonucleotides were prevented from interacting with the surface as they were inhibited by the presence of oligomers. Double stranded oligonucleotides collapsed onto the surface when only two oligomers were present but remained upright when four oligomers were present. This was due to the four oligomers interacting with one another and effectively shielding the surface. The oligomers interacted with the bases in the single stranded oligonucleotides, making them energetically accessible. Presence of a high density of oligomers prevented the dsDNA from collapsing onto the surface. These results suggest design criteria for preparation of mixed oligonucleotide and oligomer films for use in biosensors.

Molecular Modelling

Biosensors

AMBER

DNA

Silica surfaces

computational Chemistry

0486

Toward the Development of Nucleic Acid Assays Using Fluorescence Resonance Energy Transfer (FRET) and a Novel Label Free Molecular Switching Construct

Massey, Melissa

06 December 2012

The research presented in this thesis introduces design criteria for development of a new type of self-contained optical biosensor. The study begins with evaluation of a dual label, fluorescence resonance energy transfer (FRET) bioassay format, and then goes on to demonstrate a signalling platform that uses an immobilized fluorescent intercalating dye so as to avoid labelling of both the target and probe strands. An extensive survey of FRET pairs that can be used to monitor hybridization events in solution and at solid interfaces was conducted in solution to provide a set of calculated Förster distances for the extrinsic labels Cyanine 3 (Cy3), Cyanine 5 (Cy5), Carboxytetramethylrhodamine (TAMRA), Iowa Black Fluorescence Quencher (IabFQ) and Iowa Black RQ (IabRQ). FRET parameters using thiazole orange (TO) intercalating dye as a FRET donor for various acceptor dye-labelled DNA conjugates in solution were determined. Limitations associated with quenching mechanisms other than those mediated by FRET motivated the development of a molecular switch that contained intercalating dye. The four binding sites associated with Neutravidin served for assembly of the switch using biotin interactions. One binding site was used to immobilize an unlabelled oligonucleotide probe. The adjacent site was used to immobilize a novel biotinylated TO derivative that could physically reach the probe. On hybridization of the probe with target, the intercalating dye was captured by the hybrid, leading to a change of fluorescence. This reversible signalling mechanism offers a method without nucleic acid labelling to detect nucleic acid association at an interface. A SNP discrimination strategy involving TO and formamide was investigated, and SNP discrimination without the requirement of thermal denaturation was achieved for multiple target lengths, including a 141-base pair PCR amplicon in solution. It was determined that formamide could also provide improvements of signal-to-noise when using thiazole orange to detect hybridization.

fluorescence

molecular switch

nucleic acid

thiazole orange

0486

Electrochemical Studies of DNA Films on Gold Surfaces

Shamsi, Mohtashim Hassan

07 January 2013

DNA-metal ion interactions are critical for stabilizing conformations of double stranded (ds) DNA and through specific binding sites will influence the interaction of DNA with other molecules. It has been shown that different metal ions bind to different sites within nucleic acids. Work in this thesis exploits the interactions of Zn2+ with nucleic acids that are linked to surfaces. Zn2+ can interact with the phosphodiester backbone and engage in interactions with the purine nucleobases. Electrochemical studies of ds-DNA films have demonstrated that in the presence of Zn2+ films containing a single nucleotide mismatch give rise to a specific electrochemical signature. Electrochemical impedance spectroscopy (EIS) allows the discrimination of mismatched DNA films from those that are fully matched by monitoring differences in the resistance of charge transfer. Scanning electrochemical microscopy (SECM) allows multiplexing of the data acquisition and monitoring of the current response I, which is attenuated as a function of mismatch. In this thesis, various potential factors were explored in detail that may impact the discrimination of nucleotide mismatches in ds-DNA films by EIS and SECM. These factors include the position of the mismatch, its type, the number of mismatches, the length of the DNA duplex, and the length of target sequences. In particular, when the two strands are of unequal length, the resulting nucleotide overhang may mask the mismatch signature. Such overhangs are expected in real biosensor applications, in which the DNA is isolated from cellular targets. Results presented here clearly demonstrate that mismatches are readily distinguished from fully matched strands even in overhang systems, suggesting that this approach has promise for realistic sensor applications.

Electrochemical

Label free

Biosensor

DNA

Single nucleotide mismatch

Detection

0486

A Method for Selective Concentrating of DNA Targets by Capillary Affinity Gel Electrophoresis

Chan, Andrew

02 August 2013

A method for the selective concentrating of DNA targets using capillary affinity gel electrophoresis is presented. Complementary ssDNA targets are retained through hybridization with oligonucleotide probes immobilized within polyacrylamide gels while non-complementary targets are removed. The captured DNA targets were concentrated by step elution, where a localized thermal zone was applied in small steps along the capillary. Evaluation of the selective capture of a 150 nt DNA target in a complicated mixture was carried out by factorial analysis. Gels with a smaller average pore size were found to retain a higher amount of complementary targets. This was thought to be due to the ssDNA target migrating through the gel by reptation, eliminating hairpin structures, making the complementary region of the target available for hybridization. This method was applied to a series of DNA targets of different lengths, 19 nt, 150 nt, 250 nt and 400 nt. The recovery of the method ranged from 0.5 to 4% for the PCR targets, and 13 to 18% for the 19 nt oligonucleotide target. The purity was calculated to be up to 44% for the PCR targets and up to 86% for the 19 nt target. This was an improvement in purity of up to 15 times and 1100 times in comparison to the original samples for the PCR targets and 19 nt oligonucleotide, respectively. The 19 nt targets were selective concentrated and delivered into a microfluidic based DNA biosensing platform. The purity of the sample improved from 0.01% to 50% while recovery decreased from 100% to 20% for a sample with 0.5 nM complementary and 1 μM non-complementary targets. An improvement in the response of the sensing platform was demonstrated on 19 nt oligonucleotide targets delivered by selective concentration versus concentration alone into the microfluidic biosensing system.

Capillary Affinity Gel Electrophoresis

DNA Purification

Sample Enrichment

0486