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  • About
  • The Global ETD Search service is a free service for researchers to find electronic theses and dissertations. This service is provided by the Networked Digital Library of Theses and Dissertations.
    Our metadata is collected from universities around the world. If you manage a university/consortium/country archive and want to be added, details can be found on the NDLTD website.
21

Two Wavelength High Intensity Irradiation for Effective Crosslinking of DNA to Protein

Guler, Emine 09 April 2004 (has links)
Protein-DNA crosslinking is an important method to study protein-DNA interactions. Crosslinking by short pulsed UV lasers is a potentially powerful tool that results in efficient crosslinking, apparently by a two photon process. However, the major problem in using UV laser crosslinking is that the conditions which lead to high crosslinking efficiency also result in high DNA damage. Previously, it has been shown that a combination of femtosecond laser pulses at two different wavelengths, in the UV (266 nm) and the visible range (400 nm), increases the effective crosslinking yield (i.e. higher crosslinking yields with reduced DNA damage). This new strategy has the advantage that the intensity of the UV pulse for the first excitation step can be kept low, leading to lower UV-induced DNA damage and the second pulse at a visible wavelength can provide enough energy for the UV excited bases to cross their ionization threshold without damaging the DNA. The objective of this thesis project was to develop a novel UV laser cross-linking technique that would permit higher effective crosslinking yields with the commonly used pulses in the nanosecond (ns) range. To serve this purpose we tried to extend the two-wavelength femto second laser irradiation approach to longer duration pulses. We chose MBP-PIF3 protein and its target G-box DNA motif as a model system. Before ultraviolet irradiation of the protein-DNA complexes in vitro, the specific binding interaction of purified MBP-PIF3 protein with the G-box DNA motif was studied by Electrophoretic Mobility Shift Assay (EMSA). We irradiated the PIF3/DNA complexes with different laser systems (i.e. Nd:YAG and Dye lasers) and their combinations. We were expecting to see that the combination of UV laser pulses (260nm) with longer wavelength dye laser pulses (480nm) will produce higher effective crosslink yields relative to the yield from the UV pulses alone.
22

Application of proximity Ligation for Detection of Proteins, Biomolecular Interactions, and Single Copies of Pathogens

Gustafsdottir, Sigrun Margret January 2006 (has links)
<p>Proximity ligation is a recently established technique that can provide answers to questions about the concentration, localization, interactions, modifications and functions of proteins. The method enables sensitive protein measurements with a detection limit in the low femtomolar range in complex biological samples. In proximity ligation, the challenge of detecting specific proteins is converted to the analysis of specific DNA sequences. Proximity probes containing oligonucleotide extensions are designed to bind pairwise to target proteins, and to form amplifiable tag sequences upon ligation when brought in proximity. Protocols for the conversion of monoclonal or polyclonal antibodies into proximity probes through the attachment of oligonucleotide sequences are described in the thesis. In addition, the thesis describes the adaptation of the proximity ligation technology for detection of microbial pathogens, analysis of interactions between proteins and nucleic acids, and of inhibition of receptor-ligand interactions. </p><p>Nucleic acid amplification allows specific detection of pathogens with single-copy sensitivity. There are many circumstances, however, when analysis of pathogen surface antigens or the antibody response can provide increased diagnostic value. Proximity ligation reactions were used to measure numbers of virus and bacteria by detection of viral or bacterial surface proteins. Detection sensitivities similar to those of nuclear acid-based detection reactions were achieved directly in infected samples for a parvovirus and for an intracellular bacterium. </p><p>Biological processes are orchestrated by interactions of proteins with molecules in their environment, and investigations of interactions between proteins and other biomolecules are thus of great importance. Protocols were established for very specific and sensitive homogeneous-phase analysis of interactions between proteins and specific nucleic acid sequences. Finally, the proximity ligation mechanism was used to monitor interactions between VEGF-A and two of its receptors, VEGFR-1 and VEGFR-2, and to characterize the effects of agents disrupting this interaction.</p>
23

Application of proximity Ligation for Detection of Proteins, Biomolecular Interactions, and Single Copies of Pathogens

Gustafsdottir, Sigrun Margret January 2006 (has links)
Proximity ligation is a recently established technique that can provide answers to questions about the concentration, localization, interactions, modifications and functions of proteins. The method enables sensitive protein measurements with a detection limit in the low femtomolar range in complex biological samples. In proximity ligation, the challenge of detecting specific proteins is converted to the analysis of specific DNA sequences. Proximity probes containing oligonucleotide extensions are designed to bind pairwise to target proteins, and to form amplifiable tag sequences upon ligation when brought in proximity. Protocols for the conversion of monoclonal or polyclonal antibodies into proximity probes through the attachment of oligonucleotide sequences are described in the thesis. In addition, the thesis describes the adaptation of the proximity ligation technology for detection of microbial pathogens, analysis of interactions between proteins and nucleic acids, and of inhibition of receptor-ligand interactions. Nucleic acid amplification allows specific detection of pathogens with single-copy sensitivity. There are many circumstances, however, when analysis of pathogen surface antigens or the antibody response can provide increased diagnostic value. Proximity ligation reactions were used to measure numbers of virus and bacteria by detection of viral or bacterial surface proteins. Detection sensitivities similar to those of nuclear acid-based detection reactions were achieved directly in infected samples for a parvovirus and for an intracellular bacterium. Biological processes are orchestrated by interactions of proteins with molecules in their environment, and investigations of interactions between proteins and other biomolecules are thus of great importance. Protocols were established for very specific and sensitive homogeneous-phase analysis of interactions between proteins and specific nucleic acid sequences. Finally, the proximity ligation mechanism was used to monitor interactions between VEGF-A and two of its receptors, VEGFR-1 and VEGFR-2, and to characterize the effects of agents disrupting this interaction.
24

Functional and structural properties of eukaryotic DNA polymerase epsilon

Chilkova, Olga January 2006 (has links)
In eukaryotes there are three DNA polymerases which are essential for the replication of chromosomal DNA: DNA polymerase alpha (Pol alpha), DNA polymerase delta (Pol delta) and DNA polymerase epsilon (Pol epsilon). In vitro studies of viral DNA replication showed that Pol alpha and Pol delta are sufficient for DNA replication on both leading and lagging DNA strands, thus leaving the function of Pol epsilon unknown. The low abundance and the reported protease sensitivity of Pol epsilon were holding back biochemical studies of the enzyme. The aim of this study was to characterize the structural and functional properties of eukaryotic Pol epsilon. We first developed a protocol for over-expression and purification of Pol epsilon from the yeast Saccharomyces cerevisiae. Pol epsilon consists of four subunits: Pol2 (catalytic subunit), Dpb2, Dpb3 and Dpb4. This four-subunit complex was purified to homogeneity by conventional chromatography and the subunit stoichiometry of purified Pol epsilon was estimated from colloidal coomassie-stained gels to be 1:1:1:1. The quaternary structure was determined by sedimentation velocity and gel filtration experiments. Molecular mass (371 kDa) was calculated from the experimentally determined Stokes radius (74.5 Å) and sedimentation coefficient (11.9 S) and was in good agreement with a theoretical molecular mass calculated for a heterotetramer (379 kDa). Analytical sedimentation equilibrium ultracentrifugation experiments supported the proposed heterotetrameric structure of Pol epsilon. By cryo-electron microscopy and single-particle image analysis we determined the structure of Saccharomyces cerevisiae Pol epsilon to 20-Å resolution. The four-subunit complex was found to consist of a globular domain, comprising the Pol2 subunit, flexibly connected to an elongated domain, including Dpb2, Dpb3 and Dpb4 subunits. We found that Pol epsilon requires a minimal length of 40 base pairs of primer-template duplex to be processive. This length corresponds to the dimensions of the elongated domain. To characterize the fidelity by which Pol epsilon synthesizes DNA, we purified wild type and exonuclease-deficient Pol epsilon. Wild type Pol epsilon synthesizes DNA with a very high accuracy. Analysis of the exonuclease-deficient Pol epsilon showed that Pol epsilon proofreads more than 90% of the errors made by its polymerase activity. Exonuclease-deficient Pol epsilon was shown to have a specific spectrum of errors not seen in other DNA polymerases: a high proportion of transversions resulting from T-dTTP, T-dCTP and C-dTTP mispairs. This unique error specificity and amino acid sequence alignment suggest that the structure of the polymerase active site of Pol epsilon differs from those of other members of B family DNA polymerases. With recombinant proteins and circular single-stranded DNA templates, we partially reconstituted DNA replication in vitro, in which we challenged Pol epsilon and Pol delta in side-by-side comparisons regarding functional assays for polymerase activity and processivity, as well as physical interactions with nucleic acids and PCNA. We found that Pol epsilon activity and “on-DNA” PCNA interactions are dependent on RPA-coated template DNA. By the surface plasmon resonance technique, we showed that Pol epsilon has a high affinity for DNA and low affinity for immobilized PCNA. By contrast, Pol delta was found to have low affinity for DNA and high affinity for PCNA. We suggest that a possible function of RPA is to regulate down the DNA synthesis through Pol epsilon, and that the mechanism by which Pol epsilon and Pol delta load onto the template is different due to different properties of the interaction with DNA and PCNA.
25

A Structural and Mechanistic Study of Two Members of Cupin Family Protein

Liu, Fange 18 June 2013 (has links)
is a functionally diverse large group of proteins sharing a jelly roll β-barrel fold. An enzymatic member 3-hydroxyanthranilate-3,4-dioxygenase (HAO) and a non-enzymatic member pirin, which is a human nuclear metalloprotein of unknown function present in all human tissues, were selected for structural and functional studies in this dissertation work. HAO is an important enzyme for tryptophan catabolism and for 2-nitrobenzoic acid biodegradation. In this work, seven catalytic intermediate were captured in HAO single crystals, enabling for the first time a nearly complete structural snapshot viewing of the entire molecular oxygen activation and insertion mechanism in an iron- and O2-depedent enzyme. The rapid catalytic turnover rate was found achieved in large part by protein dynamics that facilitates O2 binding to the catalytic iron, which is bound to the enzyme by a facile 2-His-1-carboxylate ligand motif. An iron storage and chaperon mechanism was also discovered in the bacterial source of this enzyme, which led to a proposed novel biological function of a mononuclear iron-sulfur center. Although human pirin protein shares the same structural fold with HAO, its iron ion is coordinated by a 3-His-1-carboxylate ligand motif. Pirin belongs to a subset of proteins whose members are playing regulatory functions in the superfamily. In this work, pirin is shown to act as a redox sensor for the NF-κB transcription factor, a critical mediator of intracellular signaling that has been linked to cellular responses to pro-inflammatory signals which controls the expression of a vast array of genes involved in immune and stress responses.
26

Structural and Functional Evolution of Human Heat Shock Transcription Factors

Jaeger, Alex M. January 2015 (has links)
<p>Proteotoxic stress is implicated in numerous human diseases including neurodegeneration, cancer, and diabetes. Unfortunately, our mechanistic understanding of the cellular response to proteotoxic stress is limited. A critical feature of the cellular stress response is the activation of Heat Shock Transcription Factors (HSFs) that regulate the expression of numerous genes involved in protein folding, protein degradation, and cellular survival. The studies presented here utilize a diverse array of techniques including yeast genetics, recombinant protein expression and purification, biochemical analysis of protein-DNA interactions, x-ray crystallography, in vitro post-translational modification, and mammalian cell culture to illuminate novel aspects of HSF biology. Critical findings include understanding key principles of HSF-DNA interactions, identification of a novel negative regulator of HSF activity, and identification of structural features of HSF paralogs that enable precise combinatorial regulation. These unique insights lay the foundation for a greater understanding of HSF in specific cellular contexts and disease states.</p> / Dissertation
27

The Facilitation of Protein-DNA Search and Recognition by Multiple Modes of Binding

Leith, Jason 21 December 2012 (has links)
The studies discussed in this thesis unify experimental and theoretical techniques, both established and novel, in investigating the problem of how a protein that binds specific sites on DNA translocates to, recognizes, and stably binds to its target site or sites. The thesis is organized into two parts. Part I outlines the history of the problem and the theory and experiments that have addressed the problem and presents an apparent incompatibility between efficient search and stable, specific binding. To address this problem, we elaborate a model of protein-DNA interaction in which the protein may bind DNA in either a search (S) mode or a recognition (R) mode. The former is characterized by zero or weak sequence-dependence in the binding energy, while the latter is highly sequence-dependent. The protein undergoes a random walk along the DNA in the S mode, and if it encounters its target site, must undergo a conformational transition into the R mode. The model resolves the apparent paradox, and accounts for the observed speed, specificity, and stability in protein-DNA interactions. The model shows internal agreement as regards theoretical and simulated results, as well as external agreement with experimental measurements. Part II reports on research that has tested the applicability of the two-mode model to the tumor suppressor transcription factor p53. It describes in greater depth the experimental techniques and findings up to the present work, and introduces the techniques and biological system used in our research. We employ single-molecule optical microscopy in two projects to study the diffusional kinetics of p53 on DNA. The first project measures the diffusion coefficient of p53 and determines that the protein satisfies a number of requirements for the validity of the two-mode model and for efficient target localization. The second project examines the sequence-dependence in p53's sliding kinetics, and explicitly models the energy landscape it experiences on DNA and relates features of the landscape to observed local variation in diffusion coefficient. The thesis closes with proposed extensions and complements to the projects, and a discussion of the implications of our work and its relation to recent developments in the field.
28

The Protein Binding Potential of C2H2 Zinc Finger Domains

Brayer, Kathryn Jo January 2008 (has links)
Cys2-His2 (C2H2) zinc finger domains were originally identified as DNA binding domains, and uncharacterized domains are typically assumed to bind DNA. However, a growing body of evidence suggests an important and widespread role for these domains in protein binding. Over 100 C2H2 zinc finger-protein interactions have been described. This study uses common bioinformatics tools to identify sequence features that predict a DNA- or protein-binding function. Several issues, including uncertainties about the full functional capabilities of the zinc fingers, complicated these efforts. Therefore, an unbiased approach which directly examined the potential for zinc fingers to facilitate DNA or protein interactions was used to determine the full functional capabilities of the C2H2 domains in two model proteins, human OLF-1/EBF associated zinc finger (OAZ) protein and Zif268. OAZ contains 30 zinc fingers in six clusters, some of which have been previously indicated in DNA or protein interactions. Zif268 is a well-known DNA binding protein with three C2H2 domains. DNA binding was assessed using a target site selection (CAST) assay, and protein binding was assessed using a yeast two-hybrid assay. Results indicate that clusters known to bind DNA could facilitate specific protein interactions, but clusters known to bind protein did not facilitate specific DNA interactions, indicating that DNA binding is a more restricted function of zinc fingers than has previously been recognized. These results also suggest that the role of C2H2 zinc finger domains in protein interactions has probably been underestimated. The implication of these findings for the prediction of zinc finger function is discussed.
29

Investigation of Interactions between Homeodomain Proteins and DNA / Untersuchung der Wechselwirkungen zwischen Homeodomän-Proteinen und DNS

Vainius, Darius 18 May 2004 (has links)
No description available.
30

Restrikcijos endonukleazės BpuJI struktūriniai ir funkciniai tyrimai / Structural and functional studies of the restriction endonuclease BpuJI

Sukackaitė, Rasa 15 December 2009 (has links)
II tipo restrikcijos endonukleazės atpažįsta specifines DNR sekas ir kerpa DNR šiose sekose arba šalia jų. BpuJI, atpažįstanti 5’-CCCGT seką, skiriasi nuo kitų fermentų tuo, kad jos kirpimo vieta yra labai variabili. Čia parodoma, kad BpuJI yra dimeras, sudarytas iš dviejų monomerų, kurie turi po du atskirus domenus. BpuJI N domenas atpažįsta taikinį kaip monomeras, o C-domenas pasižymi nukleaziniu aktyvumu ir dimerizuojasi. Apo-fermento nukleazinis aktyvumas yra nuslopintas. N-domenams atpažinus taikinį, aktyvuojamas C-domenas, kuris perkerpa DNR šalia taikinio. Be to, aktyvuotas C-domenas yra nespecifinė nukleazė, linkusi nukirpti ~3 nt nuo buko dvigrandės DNR galo. Taigi, BpuJI DNR karpymo pobūdis yra labai sudėtingas. Bioinformatinė analizė ir kryptinga mutagenezė parodė, kad BpuJI C-domenas turi PD-(D/E)XK struktūrinę sanklodą ir yra panašus į archėjų Holidėjaus jungtis karpančias nukleazes. Išsprendus 1,3 Å skiriamosios gebos BpuJI N-domeno/DNR komplekso erdvinė struktūrą, paaiškėjo, kad šį domeną sudaro du „sparnuotą“ spiralė-linkis-spiralė motyvą turintys subdomenai. BpuJI taikinį atpažįsta aminorūgštys, esančios N-rankoje ir abiejų spiralė-linkis-spiralė motyvų atpažinimo spiralėse. BpuJI N-domenas yra labiausiai panašus į Nt.BspD6I nukleazę, kerpančią vieną DNR grandinę. Nt.BspD6I/DNR komplekso struktūros modelis rodo, kad Nt.BspD6I ir BpuJI taikinį atpažįstantys struktūriniai elementai yra panašūs. / Type II restriction endonucleases recognize specific DNA sequences and cleave DNA at fixed positions within or close to this sequence. BpuJI recognizes the 5’-CCCGT sequence, but in contrast to other enzymes its cleavage site is very variable. This study shows that BpuJI is a dimer in solution and consists of two separate domains. The N-domain binds to the target sequence as a monomer, while the C-domain is responsible for nuclease activity and dimerization. The nuclease activity is repressed in the apo-enzyme and becomes activated upon specific DNA binding by the N-domains. The activated C-domain cleaves DNA near the target site. In addition, it possesses an end-directed nuclease activity and preferentially cuts ~3 nt from the 3’ terminus. This leads to a very complicated pattern of DNA cleavage. Bioinformatics and mutational analysis revealed that the BpuJI C-domain harbours a PD (D/E)XK active site and is structurally related to archaeal Holliday junction resolvases. The crystal structure of the BpuJI N-domain bound to cognate DNA was solved at 1.3 Å resolution. It revealed two winged-helix subdomains, D1 and D2. The recognition of the target sequence is achieved the amino acid residues located on both the HTH motifs and an N-terminal arm. The BpuJI DNA recognition domain is most similar to the nicking endonuclease Nt.BspD6I. The modelling suggests that Nt.BspD6I could share the specificity-determining regions with BpuJI.

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