Global ETD Search

101	Developing a Model System to Probe Biological Mechanisms of Post-Translational Modifications that Destabilize the Nucleosome Beasley, Miranda L. January 2014 (has links) No description available. Biochemistry Histones post-translational modifications nucleosomes retrovrial integration prototype foamy virus
102	Bioinformatics Pipeline for Improving Identification of Modified Proteins by Neutral Loss Peak Filtering Garcia, Krystine January 2015 (has links) No description available. Biomedical Engineering Bioinformatics Computer Science Biochemistry post-translational modifications mass spectrometry bioinformatics peptide peak filtering proteins
103	Proteomic Based Approaches for Differentiating Tumor Subtypes Wang, Linan 23 May 2017 (has links) No description available. Biomedical Research Proteomics Mass Spectrometry Thymus Thymoma Histones Biomarker Cancer Pathology Post- Translational Modification Acetylation
104	Characterizing interactions of HIV-1 integrase with viral DNA and the cellular cofactor LEDGF McKee, Christopher J. 31 August 2010 (has links) No description available. Biochemistry Cellular Biology Virology HIV-1 integrase LEDGF mass spectrometric footprinting histone post-translational modifications
105	Synthetic Tools for the Preparation of Modified Histones Shimko, John C. 19 December 2011 (has links) No description available. Biochemistry histone post-translational modification peptide synthesis native chemical ligation total synthesis
106	Mass Spectrometric Analysis of Tyrosine Metabolic Enzymes Vavricka, Christopher John 25 August 2009 (has links) The metabolism of tyrosine is essential for many critical biochemical events including catecholamine synthesis, melanogenesis and insect cuticle sclerotization. These pathways are highly regulated in both insects and mammals by many well-characterized enzymes including dopa decarboxylase and tyrosine hydroxylase. On the other hand, there are still many enzymes involved in these processes that we know very little about. Dopachrome tautomerase (DCT), dopachrome conversion enzyme (DCE) and α-methyldopa resistant protein (AMD) fall into the category of the less characterized enzymes. Dopachrome is a pivotal intermediate in melanogenesis. Mammalian DCT and insect DCE both use dopachrome as a substrate. DCE catalyzes a decarboxylative structural rearrangement of dopachrome to 5,6-dihydroxyindole (DHI), whereas DCT mediates the isomerization/tautomerization of dopachrome to 5,6-dihydroxyindole-2-carboxylic acid (DHICA). DHI is oxidized easily, leading to the production of melanin, as well as reactive oxygen species (ROS). DHICA is less reactive, relative to DHI, and consequently produces less toxic byproducts during melanogenesis; therefore DCT plays an important role in detoxification of DHI and ROS. Purification and MS analysis of DCE and DCT determined that N-glycosylation is a primary post-translational modification. Q-TOF mass spectrometry was used to determine N-glycosylation patterns from Aedes aegypti DCE and MALDI-TOF/TOF was used to determine multiple glycosylation sites in DCT. N-glycosylation is critical for the folding and trafficking of secreted proteins in the endomembrane system. The analysis of glycosylation sites in DCE and DCT therefore is essential toward achieving a comprehensive understanding of their structure and function. Like DCT, AMD also plays a protective role. The AMD protein was originally identified in Drosophila mutants hypersensitive to α-methyldopa, an inhibitor of dopa decarboxylase (DDC). Production of dopamine by DDC is critical for developing insects because dopamine conjugates are used as crosslinking agents for cuticle sclerotization. Although there has been much discussion into the function of AMD, what exactly this protein does has been unknown. AMD shares 48% sequence identity with DDC, however we have found that AMD is an enzyme, which possesses a different catalytic activity. GC-MS analysis of AMD enzymatic reaction components revealed that AMD catalyzes the oxidative decarboxylation of L-DOPA to DOPAL, and also the oxidative decarboxlation of α-methyldopa to 3,4-dihydroxyphenylacetone. In summary, multiple N-glycosylation sites were characterized in DCT and DCE, furthermore a new protein function has been demonstrated for AMD. These experiments were performed using classical biochemistry techniques in combination with mass spectrometry. / Ph. D. tyrosine metabolism mass spectrometry proteomics dopamine alpha-methyldopa melanogenesis dopachrome glycosylation post-translational modification
107	Loss of Tiparp results in aberrant layering of the cerebral cortex Grimaldi, Giulia, Vagaska, B., Ievglevskyi, O., Kondratskaya, E., Glover, J.C., Matthews, J. 11 August 2019 (has links) Yes / 2,3,7,8-tetrachlorodibenzo-p-dioxin (TCDD)-inducible poly-ADP-ribose polymerase (TIPARP) is an enzyme that adds a single ADP-ribose moiety to itself or other proteins. Tiparp is highly expressed in the brain; however, its function in this organ is unknown. Here, we used Tiparp–/– mice to determine Tiparp’s role in the development of the prefrontal cortex. Loss of Tiparp resulted in an aberrant organization of the mouse cortex, where the upper layers presented increased cell density in the knock-out mice compared with wild type. Tiparp loss predominantly affected the correct distribution and number of GABAergic neurons. Furthermore, neural progenitor cell proliferation was significantly reduced. Neural stem cells (NSCs) derived from Tiparp–/– mice showed a slower rate of migration. Cytoskeletal components, such as α-tubulin are key regulators of neuronal differentiation and cortical development. α-tubulin mono-ADP ribosylation (MAR) levels were reduced in Tiparp–/– cells, suggesting that Tiparp plays a role in the MAR of α-tubulin. Despite the mild phenotype presented by Tiparp–/– mice, our findings reveal an important function for Tiparp and MAR in the correct development of the cortex. Unravelling Tiparp’s role in the cortex, could pave the way to a better understanding of a wide spectrum of neurological diseases which are known to have increased expression of TIPARP. / European Union Seventh Framework Program (FP7-PEOPLE-2013-COFUND) Grant n609020-Scientia Fellows (to G.G.) and by the Johan Throne Holst Foundation and the University of Oslo (J.M.). Cortex Cortex layering Mono-ADP ribosylation PARP Post-translational modification Tiparp
108	<b>Development of Chemical Probes to Study Protein Guanosine Monophosphorylation</b> Sara Sedky Elshaboury (19200796) 25 July 2024 (has links) <p dir="ltr">Post-translational modifications (PTMs) play a crucial role in regulating protein function and location. Protein AMPylation, the addition of adenosine monophosphate (AMP), significantly influences protein trafficking, stability, and pathogenic virulence. The Fic Domain family of proteins targets hydroxyl-containing amino acid residues (Ser, Thr, or Tyr), catalyzing the addition of various phosphate-containing moieties such as nucleoside monophosphates (NMPs), phosphocholine, and phosphate. Using gene mining techniques, Dr. Seema Mattoo’s group has identified a clade of Fic domain containing proteins typified by the enzyme originating from <i>Bordetella bronchiseptica</i> (BbFic) which prefers utilizing guanosine triphosphate (GTP) as a substrate over other nucleotides. To understand the physiological role of GMPylation, identifying the proteins modified by BbFic is a first critical step and can be accomplished via mass spectrometry-based proteomics. For a low stoichiometry PTM like GMPylation, however, there is a need to develop chemical tools that enable the targeted enrichment of modified protein. Identifying key interactions between substrate proteins and the BbFic nucleotide binding site will enable development of highly specific molecular tags for Fic substrates.</p><p dir="ltr">The goal of this research project, therefore, is to design chemical probes to tag Fic enzyme substrates, thereby facilitating the identification of GMPylated proteins in chemical proteomics workflows. A set of ATP and GTP analogues carrying either alkyne or azide handles were proposed as possible probes. While 8-azido guanosine showed a high docking score in our in-silico study, literature reports highlight its chemical instability upon exposure to air and light. An alternative probe, the 8-ethynyl guanosine, also showed a high docking score and docks in the same position and orientation as guanosine (the natural ligand) but necessitates synthetically challenging via cross-coupling reactions.</p><p dir="ltr">We considered multiple GMP analogues as potential molecular tags with the assistance of molecular docking with the BbFic enzyme. With predicted binding affinities in hand, we prioritized candidate GTP analogs for synthesis to probe the BbFic-mediated protein GMPylation process. While N6 propargyl guanosine serves as a lead probe for AMPylation, computational analysis reveals challenges with O6 due to its altered hydrogen bond donor/acceptor presentation. The distinctive chemical properties of guanosine, compared to adenosine, require a thorough evaluation of protective group strategies, as not all synthetic methodologies used for ATP analogue synthesis are applicable to GTP analogues. Isolating the triphosphate analogue proved challenging, although purification of the monophosphorylated counterpart is feasible. The Protide analogue benefits from phosphate charge masking, which facilitates purification. While much work remains until the physiological role of GMPylation can be determined, important progress has been made in the design and synthesis of chemical tools for studying this newly discovered PTM.</p> Biologically active molecules Organic chemical synthesis Post-translational modifications Protein AMPylation Chemical biology Small molecule probes
109	Identifying, Targeting, and Exploiting a Common Misfolded, Toxic Conformation of SOD1 in ALS: A Dissertation Rotunno, Melissa S. 11 June 2015 (has links) Amyotrophic lateral sclerosis (ALS) is a neurodegenerative disease characterized by a loss of voluntary movement over time, leading to paralysis and death. While 10% of ALS cases are inherited or familial (FALS), the majority of cases (90%) are sporadic (SALS) with unknown etiology. Approximately 20% of FALS cases are genetically linked to a mutation in the anti-oxidizing enzyme, superoxide dismutase (SOD1). SALS and FALS are clinically indistinguishable, suggesting a common pathogenic mechanism exists for both types. Since such a large number of genetic mutations in SOD1 result in FALS (>170), it is reasonable to suspect that non-genetic modifications to SOD1 induce structural perturbations that result in ALS pathology as well. In fact, misfolded SOD1 lacking any genetic mutation was identified in end stage spinal cord tissues of SALS patients using misfolded SOD1-specific antibodies. In addition, this misfolded WT SOD1 found in SALS tissue inhibits axonal transport in vitro, supporting the notion that misfolded WT SOD1 exhibits toxic properties like that of FALS-linked SOD1. Indeed, aberrant post-translational modifications, such as oxidation, cause WT SOD1 to mimic the toxic properties of FALS-linked mutant SOD1. Based on these data, I hypothesize that modified, misfolded forms of WT SOD1 contribute to SALS disease progression in a manner similar to FALS linked mutant SOD1 in FALS. The work presented in this dissertation supports this hypothesis. Specifically, one common misfolded form of SOD1 is defined and exposure of this toxic region is shown to enhance SOD1 toxicity. Preventing exposure, or perhaps stabilization, of this “toxic” region is a potential therapeutic target for a subset of both familial and sporadic ALS patients. Further, the possibility of exploiting this misfolded SOD1 species as a biomarker is explored. For example, an over-oxidized SOD1 species was identified in peripheral blood mononuclear cells (PBMCs) from SALS patients that is reduced in controls. Moreover, 2-dimensional gel electrophoresis revealed a more negatively charged species of SOD1 in PBMCs of healthy controls greatly reduced in SALS patients. This species is hypothesized to be involved in the degradation of SOD1, further implicating both misfolded SOD1 and altered protein homeostasis in ALS pathogenesis. Amyotrophic Lateral Sclerosis Biological Markers Mutation Superoxide Dismutase Post-Translational Protein Processing Proteostasis Deficiencies Dissertations, UMMS Protein Processing, Post-Translational Genetics and Genomics Nervous System Diseases Neuroscience and Neurobiology
110	Regulation of E2F-1 by methylation and NEDDylation Loftus, Sarah Jane January 2012 (has links) E2F-1 has a central role in cell cycle orchestration, and its activity is tightly regulated. One of the ways E2F-1 activity is controlled is by direct modification by post translational modifications such as acetylation, ubiquitination and phosphorylation. Here it was demonstrated that E2F-1 is targeted by two novel modifications, namely methylation by Set7/9 and NEDDylation, both within the DNA binding and heterodimerisation domain of the protein. NEDDylation and methylation of E2F-1 both decrease the stability and diminish the transcriptional activity of E2F-1. Lysine residues in E2F-1 involved in NEDDylation are also targeted by methylation, allowing the potential for interplay between these modifications. Methylation of E2F-1 was demonstrated to be a prerequisite for its NEDDylation and the multi-domain protein UHRF1 implicated in mediating this effect. The results define a new level of control on E2F-1 and suggest a protein code with pleiotropic effects involved in E2F-1 regulation. 571.6

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