UMD Theses and Dissertations

Permanent URI for this collectionhttp://hdl.handle.net/1903/3

New submissions to the thesis/dissertation collections are added automatically as they are received from the Graduate School. Currently, the Graduate School deposits all theses and dissertations from a given semester after the official graduation date. This means that there may be up to a 4 month delay in the appearance of a given thesis/dissertation in DRUM.

More information is available at Theses and Dissertations at University of Maryland Libraries.

Browse

Subject: search.filters.subject.Chemistry, Biochemistry

Search Results

Now showing 1 - 10 of 63
  • Thumbnail Image
    Item
    A Comparative Analysis of the Binding Affinity of HIV-1 Reverse Transcriptase to DNA vs. RNA Substrates
    (2010) Olimpo, Jeffrey T.; DeStefano, Jeffrey J; Cell Biology & Molecular Genetics; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    Human immunodeficiency virus reverse transcriptase (HIV-RT) binds more stably in binary complexes with RNA-DNA versus DNA-DNA. Current results indicate that only the -2 and -4 RNA nucleotides (-1 hybridized to the 3´ recessed DNA base) are required for stable binding to RNA-DNA, and even a single RNA nucleotide conferred significantly greater stability than DNA-DNA. Replacing 2´- hydroxyls on pivotal RNA bases with 2´-O-methyls did not affect stability, indicating that interactions between hydroxyls and RT amino acids do not stabilize binding. Avian myeloblastosis and Moloney murine leukemia virus RTs also bound more stably to RNA-DNA, but the difference was less pronounced than with HIV-RT. We propose that the H- versus B-form structures of RNA-DNA and DNA-DNA, respectively, allow the former to conform more easily to HIV-RT's binding cleft, leading to more stable binding. Biologically, this may aid in degradation of RNA fragments that remain after DNA synthesis.
  • Thumbnail Image
    Item
    THERMODYNAMIC PROPERTIES OF THE UNFOLDED ENSEMBLE OF PROTEINS
    (2010) DESAI, TANAY MAHESH; MUNOZ, VICTOR; Biochemistry; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    A random coil, whose size is determined by its excluded volume, and net energetic interactions with its environment, has served as a representation of the unfolded ensemble of proteins. The work in this thesis involves equilibrium, nuclear magnetic resonance and time-resolved kinetics spectroscopic studies on the unfolded ensemble of BBL, a globally downhill folding 40-residue protein involved the Krebs cycle of E. coli, in its acid-denatured state, and on a sequence-randomized version of this protein. The effect of variability in thermodynamic conditions, such as temperature and the presence of added chaotropes or kosmotropes, on the equilibrium properties and reconfiguration dynamics of the unfolded state, have been deduced in the absence of competition with folding events at low pH. The unfolded ensemble experiences expansion and collapse to varying degrees in response to changes in these conditions. Individual interactions of residues of the protein with the solvent and the cosolvent (direct interactions), and the properties of the solution itself (indirect interactions) are together critical to the unfolded chain's properties and have been quantitatively estimated. Unfolded, protonated BBL can be refolded by tuning the properties of the solvent by addition of kosmotropic salts. Electrostatic interactions turn out to be essential for folding cooperativity, while solvent-mediated changes in the hydrophobic effect can promote structure formation but cannot induce long-range thermodynamic connectivity in the protein. The effect of sequence on the properties of heteropolymers is also tested with a randomized version of BBL's sequence. Chain radii of gyration, and the degree and rate of hydrophobic collapse depend on the composition of the sequence, viz. hydrophilic versus hydrophobic content. However, the ability to maximize stabilizing interactions and adopt compact conformations is more evident in naturally selected protein sequences versus designed heteropolymers. Chain reconfiguration of unfolded BBL takes place in ∼1/(100 ns), in agreement with theoretical estimates of homopolymer collapse rates. The refolding dynamics of salt-refolded BBL in the range of 1/(6 μs) at 320 K, emerge as being independent of the degree of folding or protonation of the chain, a result in keeping with the description of dynamics in BBL as oscillations in a single, smooth harmonic potential well, which only varies in its position and curvature with varying thermodynamic conditions.
  • Thumbnail Image
    Item
    Top-Down Analysis of Bacterial Proteins by High-Resolution Mass Spectrometry
    (2010) Wynne, Colin Michael; Fenselau, Catherine; Chemistry; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    In the biodefense and medical diagnostic fields, MALDI mass spectrometry-based systems are used for rapid characterization of microorganisms generally by detecting and discriminating the highly abundant protein mass-to-charge peaks. It is important that these peaks eventually are identified, but few bacteria have publicly available, annotated genome or proteome from which this identification can be made. This dissertation proposes a method of top-down proteomics using a high-resolution, high mass accuracy analyzer coupled with bioinformatics tools to identify proteins from bacteria with unavailable genome sequences by comparison to protein sequences from closely-related microorganisms. Once these proteins are identified and a link between the unknown target bacteria and the annotated related bacteria is established, phylogenetic trees can be constructed to characterize where the target bacteria relates to other members of the same phylogenetic family. First, the top-down proteomic approach using an Orbitrap mass analyzer is tested using a well known, well studied single protein. After this is demonstrated to be successful, the approach is demonstrated on a bacterium without a sequenced genome, only matching proteins from other organisms which are thought to have 100% homology with the proteins studied by the top-down approach. Finally, the proposed method is changed slightly to be more inclusive and the proteins from two other bacteria without publicly available genomes or proteomes are matched to known proteins that differ in mass and may not be 100% homologous to the proteins of the studied bacteria. This more inclusive method is shown to also be successful in phylogenetically characterizing the bacteria lacking sequence information. Furthermore, some of the mass differences are localized to a small window of amino acids and proposed changes are made that increase confidence in identification while lowering the mass difference between the studied protein and the matched, homologous, known protein.
  • Thumbnail Image
    Item
    Kinetic and Structual Characterization of Glutamine-Dependent NAD Synthetases
    (2010) Resto, Melissa; Gerratana, Barbara; Chemistry; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    Multifunctional enzymes catalyzing successive reactions have evolved several mechanisms for the transport of intermediates between active sites. One mechanism, substrate channeling, allows the transport of the intermediate without releasing it into the solvent. Members of the glutamine amidotransferase (GAT) family often utilize substrate channeling for the transport of intermediates. GAT enzymes hydrolyze glutamine to ammonia, which is transported to an acceptor domain preventing wasteful hydrolysis of glutamine and increasing the efficiency of the reaction. Many GAT enzymes utilize molecular tunnels to shuttle ammonia between active sites. Often GAT enzymes synchronize the active site through conformational changes that occur during catalysis. Glutamine-dependent NAD synthetases are GAT enzymes and catalyze the last step in the biosynthesis of NAD, utilizing nicotinic acid adenine dinucleotide (NaAD), ATP and glutamine. Steady-state kinetic characterizations and stoichiometric analysis of NAD synthetase from Mycobacterium tuberculosis (NAD synthetaseTB) revealed a substrate channeling mechanism for ammonia transport and tight coordination of the active sites resulting in an enzyme that is highly efficient in the use of glutamine. The crystal structure of NAD synthetaseTB has revealed a 40 Å tunnel that connects the active sites and is postulated to play a role in the synchronized activities. Several regions of the enzyme were identified that may be important for regulation, such as the YRE loop which contacts the glutamine active site and key regions of the tunnel. Mutations of tunnel residues, such as D656A, show that interruption of important interactions can result in compromise in transfer of ammonia or active site communication. Phylogenetic analysis revealed that glutamine-dependent NAD synthetases have different levels of regulation. Three groups of enzymes were identified represented by NAD synthetase from M. tuberculosis, S. cerevisiae (NAD synthetaseYeast) and Thermotoga maritima (NAD synthetaseTM). Steady-state kinetic characterizations and stoichiometric analysis of NAD synthetaseTM has revealed a compromised coordination of the active sites compared to the highly synchronized NAD synthetaseTB and the moderate synchronization of NAD synthetaseYeast. Sequence alignment of these groups has allowed identification of residues that line the tunnel that may be responsible for the differences observed in active site coordination and are, therefore, important for active site communication.
  • Thumbnail Image
    Item
    Protein-Protein Docking Using Long Range Nuclear Magnetic Resonance Constraints
    (2010) Berlin, Konstantin; O'Leary, Dianne P; Fushman, David; Computer Science; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    One of the main methods for experimentally determining protein structure is nuclear magnetic resonance (NMR) spectroscopy. The advantage of using NMR compared to other methods is that the molecule may be studied in its natural state and environment. However, NMR is limited in its facility to analyze multi-domain molecules because of the scarcity of inter-atomic NMR constraints between the domains. In those cases it might be possible to dock the domains based on long range NMR constraints that are related to the molecule's overall structure. We present two computational methods for rigid docking based on long range NMR constraints. The first docking method is based on the overall alignment tensor of the complex. The docking algorithm is based on the minimization of the difference between the predicted and experimental alignment tensor. In order to efficiently dock the complex we introduce a new, computationally efficient method called PATI for predicting the molecular alignment tensor based on the three-dimensional structure of the molecule. The increase in speed compared to the currently best-known method (PALES) is achieved by re-expressing the problem as one of numerical integration, rather than a simple uniform sampling (as in the PALES method), and by using a convex hull rather than a detailed representation of the surface of a molecule. Using PATI, we derive a method called PATIDOCK for efficiently docking a two-domain complex based solely on the novel idea of using the difference between the experimental alignment tensor and the predicted alignment tensor computed by PATI. We show that the alignment tensor fundamentally contains enough information to accurately dock a two-domain complex, and that we can very quickly dock the two domains by pre-computing the right set of data. A second new docking method is based on a similar concept but using the rotational diffusion tensor. We derive a minimization algorithm for this docking method by separating the problem into two simpler minimization problems and approximating our energy function by a quadratic equation. These methods provide two new efficient procedures for protein docking computations.
  • Thumbnail Image
    Item
    Kinetic Characterization and Domain Analysis of the helicase RecD2 from Deinococcus radiodurans
    (2010) Shadrick, William Robert; Julin, Douglas A; Biochemistry; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    The gram positive bacterium D. radiodurans is known for its extreme resistance to radiation and an extraordinary ability to reconstitute its genome after sustaining large numbers of double strand breaks (DSB's). Genome analysis does not immediately reveal a biochemical basis for this incredible DNA repair ability. In E. coli, DSB's are mainly repaired through the RecBCD pathway via homologous recombination. The D. radiodurans genome contains no known homologues of RecB or RecC, but sequence analysis has identified a homologue of RecD, termed RecD2. The function of RecD2 in D. radiodurans is unknown, as RecD elsewhere has only been found as a component of the RecBCD complex. Our research has focused on biochemical characterization of RecD2. Previous work in our lab established that RecD2 is a DNA helicase with limited processivity and a preference for forked substrates. We have studied the unwinding mechanism of the enzyme, as measured by rates of DNA unwinding and behavior on various substrates. Reactions conducted under single turnover conditions have allowed us to determine the processivity and the step size of RecD2. RecD2 pre-bound to dsDNA substrate is capable of unwinding 12 bp, but not 20 bp, when excess ssDNA is added to prevent rebinding of enzyme to substrate. Unwinding of the 12 bp substrate under single turnover conditions could be modeled using a two step mechanism, with kunw = 5.5 s-1 and dissociation from partially unwound substrate koff = 1.9 s-1. Results derived from these rate constants indicate an unwinding rate of 15-20 bp/ sec, with relatively low processivity (P = 0.74). Glutaraldehyde cross-linking showed formation of multimers of RecD2 in the absence of DNA, but this was not detectable by size exclusion chromatography. We were able to separate the N-terminal region from the helicase core of RecD2 using limited proteolysis. It was not possible to characterize the C-terminal helicase domain due to its low solubility upon overexpression in E. coli.
  • Thumbnail Image
    Item
    The Development of New Tools for the Investigation of Protein Function Using Photo-Reactive Unnatural Amino Acids
    (2010) Wilkins, Bryan Jason; Cropp, Ashton; Gerratana, Barbara; Biochemistry; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    Reported here is the direct synthesis and application of unnatural amino acids for the development of exploratory tools for protein studies. This work takes advantage of an expanded genetic code to extract a more precise chemical understanding of protein function with novel additions to the unnatural amino acid catalogue, as well as the expansion of techniques with previously developed compounds. The photochemical crosslinker, [D11]-p-benzoylphenylalanine (pBpa), is synthesized for isotopic labeling in proteins. When [D11]-pBpa is co-incorporated into protein with [D0]-¬pBpa it is a mass spectral tool for rapid and conclusive identification of crosslinked fragments. Following enzymatic digestion the fingerprint of M, M+ 11 is readily identified allowing for rapid peak identification and the determined site of crosslink formation with single amino acid accuracy. In a means to extract a level of spatiotemporal control over fluorescent labeling of protein, the photo-protected unnatural amino acid, o-nitrobenzyl cysteine (ONBC), is introduced to a small amino acid tag sequence CCPGCC. This tag is required and specifically binds the pro-fluorescent compound 5-bis(1,3,2-dithiasolan-2-yl)fluorescein (FlAsH). This work takes advantage of the inability of FlAsH to bind the cysteine-tag motif in the presence of an ONBC mutation. The photo-protected amino acid is deprotected with light, affording natural cysteine and the successful binding of FlasH to the tetracysteine tag only following ultraviolet irradiation. Finally, fluorinated tyrosine derivatives are synthetically modified to contain photo-protecting groups, which act as a disguise during unnatural amino acid mutagenesis techniques. Fluorinated tyrosines are recognized by endogenous tyrosyl-tRNA synthetases and incorporated globally throughout a protein at tyrosine positions. To circumvent this problem the o-nitrobenzyl photo-protecting group is installed on the tyrosine derivatives 2-fluorotyrosine, 3-fluorotyrosine, and 2,6-difluorotyrosine. The directed evolution of an orthogonal amber-tRNA synthetase, specific for these unnatural amino acids, is performed, providing the translational machinery for site-specific incorporation of these compounds. Following expression of protein with the protected tyrosine derivatives, protein exposed to ultraviolet irradiation subsequently loses the protecting group affording the site-specific incorporation of fluorinated tyrosine. Fluorinated tyrosines are introduced to the critical trysoine residue in the chromophore of super-folder green fluorescent protein to determine how the altered pKa affects its fluorescent properties.
  • Thumbnail Image
    Item
    CHEMICAL INDUCTION OF SETTLEMENT IN LARVAE OF THE EASTERN OYSTER CRASSOSTREA VIRGINICA (GMELIN)
    (2009) Grant, Melissa; Meritt, Donald W.; Marine-Estuarine-Environmental Sciences; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    Although numerous studies have been conducted to examine the effects of neuroactive compounds on bivalve larvae, few have identified chemicals capable of inducing settlement behavior in the eastern oyster Crassostrea virginica. In this study, I treated competent C. virginica larvae with select chemicals to identify those which are capable of inducing settlement behavior at an average salinity of 9.6 (±0.1). The compounds γ-aminobutyric acid and acetylcholine chloride, both at 10-4M, did not significantly increase the percentage of larvae exhibiting settlement behavior. As compared with the control, a significant increase in settlement behavior was induced by treatment with 3-isobutyl-1-methylxanthine, 5-hydroxytryptamine, and L-3, 4-dihydroxyphenylalanine all at 10-4M, as well as ammonia as a solution of 7.9mM NH4Cl (pH=8.0). These findings differ somewhat from the results of similar studies involving other species in the Crassostrea genus and may be of value to hatchery personnel or researchers interested in the chemical induction of settlement behavior in the eastern oyster.
  • Thumbnail Image
    Item
    Development and applications of codon scanning mutagenesis: A novel mutagenesis method that facilitates in-frame codon mutations
    (2009) Daggett, Kelly Anne; Cropp, Ashton; Chemistry; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    The ability to create protein variants is a very valuable tool in biochemistry. Information about mechanistic roles of amino acid side chains, protein topology and binding can all be obtained. Methodologies to mutate proteins also allow for new catalytic activity to be achieved. While the routinely used methods to alter a protein sequence have proven to be useful, to some degree each of these methods requires some knowledge of protein structure to determine the site of mutation. Further, the routinely used methods also only allow for a specified site to be changed to a pre-determined residue (directed by oligonucleotides) or for multiple random sites to be changed to a non-specified residue. This dissertation focuses on the development of a method that allows for a new defined amino acid to replace a native amino acid at a random location within in the protein. To introduce mutations at random locations within a protein coding sequence, three steps need to be accomplished. First, the coding sequence needs to be randomly digested on both strands; second, three nucleotides (a codon) at the digestion site need to be removed; and last, a new specified codon inserted. This process results in the replacement of a random codon with the new defined codon. To direct a mutation at a random location, the unique properties of a transposase/transposon are used to create both the double strand break and removal of three nucleotides. The insertion of the new defined codon is introduced using a linker sequence that when inserted in the correct reading frame a selectable phenotype is produced. This process has been termed Codon Scanning Mutagenesis (CSM). The advantages of this method over current mutagenesis methods are (1) knowledge of structural information is not required, (2) oligonucleotides are not required to introduce the mutation and (3) the mutagenesis method allows for every amino acid to be mutated regardless of the DNA sequence. Further, this method allows for any natural and unnatural amino acid to be inserted at the mutation site, as well as the ability to create mutational mixtures or introduce multiple user defined mutations.
  • Thumbnail Image
    Item
    DENSITY FUNCTIONAL CALCULATIONS OF BACKBONE 15N CHEMICAL SHIELDINGS IN PEPTIDES AND PROTEINS
    (2009) Cai, Ling; Fushman, David; Kosov, Daniel S; Chemical Physics; Digital Repository at the University of Maryland; University of Maryland (College Park, Md.)
    In this dissertation, we describe computational and theoretical study of backbone 15N chemical shieldings in peptides and proteins. Comprehensive density functional calculations have been performed on systems of different complexity, ranging from model dipeptides to real proteins and protein complexes. We begin with examining the effects of solvation, hydrogen bonding, backbone conformation, and the side chain identity on 15N chemical shielding in proteins by density functional calculations. N-methylacetamide (NMA) and N-formyl-alanyl-X (with X being one of the 19 naturally occurring amino acids excluding proline) were used as model systems for this purpose. The conducting polarizable continuum model was employed to include the effect of solvent in the calculations. We show that the augmentation of the polarizable continuum model with the explicit water molecules in the first solvation shell has a significant influence on isotropic 15N chemical shift but not as much on the chemical shift anisotropy. The difference in the isotropic chemical shift between the standard &beta-sheet and standard &alpha-helical conformations ranges from 0.8 ppm to 6.2 ppm depending on the residue type, with the mean of 2.7 ppm. This is in good agreement with the experimental chemical shifts averaged over a database of 36 proteins containing >6100 amino acid residues. The orientation of the 15N chemical shielding tensor as well as its anisotropy and asymmetry are also in the range of values experimentally observed for peptides and proteins. Having applied density functional calculation successfully to model peptides, we develop a computationally efficient methodology to include most of the important effects in the calculation of chemical shieldings of backbone 15N in a protein. We present the application to selected &alpha-helical and &beta-sheet residues of protein G. The role of long-range intra-protein electrostatic interactions by comparing models with different complexity in vacuum and in charge field is analyzed. We show that the dipole moment of the &alpha-helix can cause significant deshielding of 15N; therefore, it needs to be considered when calculating 15N chemical shielding. We emphasize the importance of including interactions with the side chains that are close in space when the charged form for ionizable side chains is adopted in the calculation. We also illustrate how the ionization state of these side chains can affect the chemical shielding tensor elements. For &alpha-helical residues, chemical shielding calculations using a 8-residue fragment model in vacuum and adopting the charged form of ionizable side chains yield a generally good agreement with experimental data. We also performed computational modeling of the chemical shift perturbations occurring upon protein-protein or protein-ligand binding. We show that the chemical shift perturbations in ubiquitin upon dimer formation can be explained qualitatively through computation. This dissertation hence demonstrates that quantum chemical calculations can be successfully used to obtain a fundamental understanding of the relationship between chemical shielding and the surrounding protein environment for the elusive case of 15N and therefore enhance the role of 15N chemical shift measurements in the analysis of protein structure and dynamics.