Theses and Dissertations at Montana State University (MSU)
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Item Fluorescence quenching in 2-aminopurine-labeled model DNA systems(Montana State University - Bozeman, College of Letters & Science, 2019) Remington, Jacob Michael; Chairperson, Graduate Committee: Patrik R. Callis; Abbey M. Philip, Mahesh Hariharan and Bern Kohler were co-authors of the article, 'On the origin of multiexponential fluorescence decays from 2-aminopurine labeled dinucleotides' in the journal 'The journal of chemical physics' which is contained within this thesis.; Martin McCullagh and Bern Kohler were co-authors of the article, 'Molecular dynamics simulations of 2-aminopurine-labeled dinucleoside monophosphates reveal multiscale stacking kinetics' in the journal 'Journal of physical chemistry B' which is contained within this thesis.For the last 50 years changes to the fluorescence properties of 2-aminopurine have been used to probe the structure and dynamics of DNA. 2-Aminopurine's utility has arisen from the quenching of its emission when pi-stacked with neighboring nucleobases. In the time-domain, the emission decay profile of 2-aminopurine requires multiple exponential decay components to model. Despite its extensive usage, the microscopic origin of the decay heterogeneity is not clear. In this thesis, steady-state absorption, fluorescence, and time-resolved fluorescence results are compared to multiple microsecond molecular dynamics simulations of 2-aminopurine-labeled adenine containing single-stranded DNA oligomers of varying length and position of the 2-aminopurine probe. First, previous reports of ultrafast electron transfer in pi-stacked adenine oligomers are used to build a new model for quenching of 2-aminopurine that is pi-stacked with adenine. For dinucleotides, a static distribution of unstacked structures combined with a distance dependent electron transfer mechanism is posited to explain the disperse emission decay timescales. Investigating the dinucleotides with molecular dynamics simulations analyzed with Markov state models quantify the structural heterogeneity of the dinucleotides. At least seven structures are sampled that could alter the quenching of 2-aminopurines's fluorescence. The Markov state models also demonstrate the timescales for transitions between these structures range from 1.6 to 25 ns, suggesting 2-aminopurine, with its monomer-like lifetime of 10 ns, is sensitive to the conformational dynamics of the dinucleotides as well. This dual fluorescence quenching and molecular dynamics simulation approach is extended to 2-aminopurine labeled trinucleotides and 15 base oligomers to interrogate the position dependent structural heterogeneity and conformational dynamics in these systems. Both shifts in the experimental absorption spectra, and molecular dynamics simulations agree that the interior base is more likely to be stacked than the exterior bases. Time-resolved emission experiments reveal emission from 2-aminopurine is quenched faster on the 5' end relative to the 3' end, in agreement with the faster stacking kinetics observed for bases on the 5' end relative to the 3' end obtained from molecular dynamics simulation. These results suggest that the time-resolved emission from 2-aminopurine may serve as an experimental observable for calibration of the dynamical properties predicted by molecular dynamics simulation.Item Excited-state dynamics of biological molecules in solution: photoinduced charge transfer in oxidatively damaged DNA and deactivation of violacein in viscous solvents(Montana State University - Bozeman, College of Letters & Science, 2017) Beckstead, Ashley Ann; Chairperson, Graduate Committee: Robert WalkerUV radiation from the sun is strongly absorbed by DNA, and the resulting electronic excited states can lead to the formation of mutagenic photoproducts. Decades of research have brought to light the excited-state dynamics of single RNA and DNA nucleobases, but questions remain about the nature of excited states accessed in DNA strands. In this thesis, I present ultrafast spectroscopic observations of photoinduced electron transfer from the oxidatively damaged bases, 8-oxo-7,8-dihydro-2'-deoxyguanosine, 5-hydroxy-2'-deoxycytidine and 5-hydroxy-2'-deoxyuridine, to adenine in three dinucleotides. The results reveal that charge transfer states are formed on a timescale faster than our instrumental resolution (<0.5 ps), and back electron transfer efficiently returns the excited-state population to the ground state on timescales from tens to hundreds of ps. In addition to recent spectroscopic observations of charge transfer state species in DNA by other groups, our results have augmented understanding of the long-lived transient signals observed in DNA strands. The observation of photoinduced electron transfer in these oxidatively damaged nucleobases also supports a recent proposal regarding the role of oxidative products in pre-RNA catalysis. I discuss these observations in the contexts of fundamental DNA excited-state dynamics and prebiotic chemical evolution. In this thesis, I also present the first ultrafast spectroscopic investigation of violacein, a pigment isolated from Antarctic bacteria. Despite claims for the photoprotective role of this pigment, there has never been a spectroscopic analysis of excited-state deactivation in violacein. Emission spectra, fluorescence quantum yields and excited-state lifetimes of violacein in various solvents were measured for the first time. Both the fluorescence quantum yield and excited-state lifetime of violacein increase in increasingly viscous solvents, suggesting a large-scale motion mediates excited-state deactivation. I compare these results to similar observations of viscosity-dependent excited-state decay rates in other molecules. I also consider the relevance of violacein's excited-state properties to the hypothesized sunscreening role of violacein. Overall, the studies presented in this dissertation illustrate how ultrafast spectroscopic techniques can be used to unravel complex biomolecular excited-state dynamics in solution.Item Subnanosecond emission from model DNA oligomers characterized through time-correlated single-photon counting spectroscopy(Montana State University - Bozeman, College of Letters & Science, 2017) Skowron, David John; Chairperson, Graduate Committee: Robert Walker; Yuyuan Zhang, Ashley A. Beckstead, Jacob M. Remington, Madison Strawn and Bern Kohler were co-authors of the article, 'Subnanosecond emission dynamics of AT DNA oligonucleotides' in the journal 'Journal of chemical physics and physical chemistry' which is contained within this thesis.Exposure of DNA to UV radiation creates electronic excited states that can decay to mutagenic photoproducts. Excited states can return to the electron ground state through deactivation pathways, preventing photochemical damage. Understanding has significantly advanced over the last decade through the applications of time-resolved techniques capable of picosecond and femtosecond time-resolution. While significant strides have been made towards understanding monomeric deactivation pathways, unraveling the complex photophysics of base multimers still presents a significant challenge. This report uses time-resolved fluorescence and ultrafast transient absorbance to analyze model DNA oligomers to understand how fundamental interactions between monomeric constituents influences the dynamics of base multimers. Model single- and double-stranded DNA oligomers were investigated using the time correlated single photon counting technique to address the uncertainty over how to compare results from time-resolved fluorescent and transient absorption techniques. Emission lifetimes ranging from 50 to 200 ps quantitatively agree with lifetimes measured from transient absorption experiments indicating emission observed on timescales greater than a few picoseconds is the result of excimer or charge recombination luminescence. In attempts to further characterize the time-resolved emission from model oligomers adenine oligomers consisting of 2 and 18 base constituents were examined in aqueous water and heavy water solutions. Differences in dynamics between the two oligomers revealed the average number of bases present within a stacked domain influence the dynamics of these systems. Lifetimes of the emission decays were assigned excimer-like states with various degrees of charge-transfer character. Finally, to further demonstrate the importance of base stacking domain length on the dynamics of these systems, time-resolved emission and absorption of the adenine dinucleotide and 18-mer where examined at temperatures ranging from 7 °C - 80 °C. It was observed that the kinetics between the oligomers was noticeably different at lower temperatures, but not at higher temperatures. It was concluded the domain length of the 18-mer was similar to the domain length of the dinucleotide at high temperatures, but not at low temperatures, demonstrating the domain length significant impacts theS photophysics of DNA.Item A dehydrogenase linked assay of DNA ligase activity(Montana State University - Bozeman, College of Letters & Science, 1986) Morgan, Jerold RandallItem Molecular cloning and sequencing of a cDNA from the grasshopper Melanoplus differentialis(Montana State University - Bozeman, College of Letters & Science, 1991) Rognlie, Matthew CraigItem Polarized one- and two-photon fluorescence excitation spectroscopy on selected nucleic acid bases(Montana State University - Bozeman, College of Letters & Science, 1989) Williams, Scott AllanItem The room temperature fluorescence of DNA(Montana State University - Bozeman, College of Letters & Science, 1982) Aoki, Timothy IsamuItem NMR solution structure and biological activity of E73, a DNA binding protein from Sulfolobus spindle virus Ragged Hills(Montana State University - Bozeman, College of Letters & Science, 2011) Schlenker, Casey James; Chairperson, Graduate Committee: Valerie CopieSulfolobus solfataricus, a model organism for Archaea, lives in extreme thermal and acidic environments such as the hot springs of Yellowstone National Park, and is host to diverse archaeal viruses including Sulfolobus spindle shaped virus-1 (SSV1) and Sulfolobus spindle shaped virus-Ragged Hills (SSV-RH). SSV viruses exhibit remarkable morphology and genetic diversity, but are poorly understood as many proteins encoded by their genomes have very little sequence homology to proteins of known functions. Detailed structure-function studies have been undertaken to better understand the role played by SSV proteins in regulating viral gene expression, viral life cycle, and in mediating virus-host interactions. Herein, we report the 3D solution structure of E73, a 73-residue, homodimeric protein encoded within the SSV-RH genome and demonstrate its dsDNA binding capabilities. We find that E73 is comprised of an extended ribbon-helix-helix (RHH) structural domain, which is structurally homologous to the RHH domains of numerous proteins involved in regulation of gene transcription. The N-terminal beta strands of E73's protomers assemble into an anti-parallel beta-sheet, which, based on structural homology with other RHH proteins, form base-specific interactions with dsDNA. E73 is notably distinct from known RHH proteins however as it contains a third helix which forms a positively charged structural cleft that we postulate is involved in protein-protein interactions. These findings are discussed in the context of E73's potential role in regulating SSV-RH genome transcription and replication in its Sulfolobus host.