Global ETD Search

31	Simple Physical Approaches to Complex Biological Systems Fenley, Andrew Townsend 23 July 2010 (has links) Properly representing the principle physical interactions of complex biological systems is paramount for building powerful, yet simple models. As an in depth look into different biological systems at different scales, multiple models are presented. At the molecular scale, an analytical solution to the (linearized) Poisson-Boltzmann equation for the electrostatic potential of any size biomolecule is derived using spherical geometry. The solution is tested both on an ideal sphere relative to an exact solution and on a multitude of biomolecules relative to a numerical solution. In all cases, the bulk of the error is within thermal noise. The computational power of the solution is demonstrated by finding the electrostatic potential at the surface of a viral capsid that is nearly half a million atoms in size. Next, a model of the nucleosome using simplified geometry is presented. This system is a complex of protein and DNA and acts as the first level of DNA compaction inside the nucleus of eukaryotes. The analytical model reveals a mechanism for controlling the stability of the nucleosome via changes to the total charge of the protein globular core. The analytical model is verified by a computational study on the stability change when the charge of individual residues is altered. Finally, a multiple model approach is taken to study bacteria that are capable of different responses depending on the size of their surrounding colony. The first model is capable of determining how the system propagates the information about the colony size to those specific genes that control the concentration of a master regulatory protein. A second model is used to analyze the direct RNA interference mechanism the cell employs to tune the available gene transcripts of the master regulatory protein, i.e. small RNA - messenger RNA regulation. This model provides a possible explanation for puzzling experimentally measured phenotypic responses. / Ph. D. post-translational modification small RNA quorum sensing Poisson-Boltzmann nucleosome
32	Structural Dynamics and Novel Biological Function of Topoisomerase 2 Chen, Yu-tsung Shane January 2015 (has links) <p>Eukaryotic Topoisomerase 2 is an essential enzyme that solves DNA topological problems such as DNA knotting, catenation, and supercoiling. It alters the DNA topology by introducing transient double strand break in one DNA duplex as a gate for the passage of another DNA duplex. Two different aspects of studies about eukaryotic Topoisomerase 2 will be covered in this thesis. In the first half of the thesis, we investigated conformational changes of human Topoisomerase 2 (hsTop2) in the presence of cofactors and inhibitors. In the second half, we focused on an unknown regulatory function in the C-terminal domain (CTD) of Drosophila Topoisomerase 2 (Top2).</p><p>In the project of studying enzyme conformational changes, we adapted a previously developed methodology, Pulse-Alkylation Mass Spectrometry, with monobromobimane to study the protein dynamics of hsTop2. Using this method, we captured the evidence of conformational changes in the presence of ATP and Mg2+ or the Top2 inhibitor, ICRF-193 which were not previously observed. Last, by using CTD truncated hsTop2, the increasing reactivity of Cys427 suggested the CTD domain might be tethered adjacent to the core enzyme.</p><p>Following the study of enzyme conformational changes, we switched gear to examine an interaction between Drosophila Top2 and Mus101, homolog of human TopBP1. We first found that Mus101 interacts with CTD of Top2 in a phosphorylation-dependent manner. Next, in the co-immunoprecipitation and pull-down experiments using truncated or mutant Top2 with various Ser to Ala substitutions, we mapped the binding motif to the last amino acids of Top2 and identified that phosphorylation of Ser1428 and Ser1443 is important for Top2 to interact with the N-terminus of Mus101, which contains BRCT1/2 domains (BRCT, BRCA1 C-terminus). The binding affinity of the N-terminal Mus101 with a synthetic phosphorylated peptide covering the last 25 amino acids of Top2 (with pS1428 and pS1443) was determined by surface plasmon resonance with a Kd of 0.57 μM. In an in vitro decatenation assay, Mus101 can specifically reduce the decatenation activity of Top2, and dephosphorylation of Top2 attenuates this response to Mus101. Next, we endeavored to establish a cellular system for testing the biological function of Top2-Mus101 interaction. Top2-silenced S2 cells rescued by Top220, truncation of 20 amino acids from the C-terminus of Top2, developed abnormally high chromosome numbers, which implies an infidelity in chromosome segregation during mitosis. Lastly, Top2-null flies rescued by Top2 with S1428A and S1443A were found to be viable but sterile. After investigating spermatogenesis, telophase of meiosis I was delayed, indicating Top2-Mus101 interaction is also important in segregating DNA in meiosis.</p> / Dissertation Biochemistry Cellular biology Genetics Fly Genetics Post-translational Modification Protein Dynamics Protein-protein Interaction shRNA Topoisomerase
33	Characterisation of 2-oxoglutarate- and fe(II)-dependent oxygenases targeting the protein synthesis apparatus Feng, Tianshu January 2014 (has links) Members of the 2-oxoglutarate (2OG)- and Fe(II)-dependent oxygenase (2OG oxygenase) superfamily catalyse a wide range of oxidative reactions in biology. 2OG oxygenases require Fe(II) and atmospheric oxygen for their activity, and couple substrate oxidation with the decarboxylation of 2OG into succinate and carbon dioxide. There are more than sixty known 2OG oxygenases in the human genome; they modify small molecules, nucleic acids and proteins implicated in diverse biological processes. Importantly, the seemingly disparate functions of 2OG oxygenases often converge to regulate gene expression. 2OG oxygenases have been shown to affect epigenetic reprogramming, chromatin remodelling, transcription factor activity and mRNA splicing. Emerging evidence indicates that 2OG oxygenases are also involved in the translational control of gene expression. Oxygenases TYW5, ALKBH8, ALKBH5 and FTO were found to catalyse modifications of tRNA and mRNA. The work in this thesis extends these observations by demonstrating that 2OG oxygenase-catalysed protein hydroxylations also play an important role in protein synthesis. The catalytic activities of two oxygenases belonging to the JmjC-only family, NO66 and JMJD4, are described. NO66 catalyses the histidinyl hydroxylation of 60S ribosomal subunit protein L8. NO66 is part of a conserved group of ribosomal protein hydroxylases that can be traced back to prokaryotes. JMJD4 is a lysyl hydroxylase of eRF1, the eukaryotic release factor responsible for translation termination. The hydroxylation of eRF1 takes place on a conserved NIKS motif important for release factor activity, and promotes effcient translational termination. JMJD4 is further implicated in cell growth and cancer, though the link between its activity and tumourigenesis remains to be determined. These results highlight the potential of 2OG oxygenases as regulators of protein synthesis, and further extend the scope of 2OG oxygenase function. The small molecule inhibition of 2OG oxygenases presents a novel therapeutic possibility targeting translational control in cancer and other diseases. 572
34	Optimization of disulfide mapping using mass spectrometry Matsumiya, Nozomi January 1900 (has links) Master of Science / Biochemistry / John Tomich / One of the important keys to characterize the biological function of a protein is the study of post-translational modification (PTM). Formation of disulfide bond linkages between cysteine residues within a protein is a common PTM which not only contributes to folding and stabilizing the protein structure, but also to accomplishing its native function. Therefore, the study and discovery of structural-functional relationships of expressed proteins using an isolated proteomics approach has been one of the biggest advances within the field of structural biology in recent years. In this study, rapid disulfide bond mapping of freshly obtained equine serum albumin (ESA) was performed using matrix assisted laser desorption/ionization time of flight mass spectrometry (MALDI-TOF MS). Highly sensitive MALDI-TOF MS is commonly used for the investigation of disulfide bond linkages in the proteomics field. However, it has also been known that the presence of disulfide bond linkages absorbs the energy which is created by the cysteine-cysteine kinetic vibration, resulting in a decrease of the instrumental sensitivity. To overcome this problem, the disulfide bond mapping method was optimized by applying a combination of chemical labeling, proteolytic enzymes, and matrices. With the optimized method, we were also able to achieve high protein sequence coverage. Obtaining higher sequence coverage of a protein provides more information about a protein which helps to identify the protein by peptide mass fingerprint (PMF) technique. These analyses eventually contribute to the estimation of the possible PTM sites. Disulfide bond mapping Mass spectrometry Post translational modification (PTM) Proteomics Chemistry, Biochemistry (0487)
35	Phosphoinositides et contrôle de la polarité cellulaire : régulations croisées entre la PIP5K Skittles et les protéines de polarité PAR1 et PAR3 / Phosphoinositides and cell polarity control : interplay between the PIP5K Skittles and the polarity proteins PAR1 and PAR3 Jouette, Julie 28 September 2017 (has links) La polarité cellulaire est un processus fondamental qui contrôle les spécificités fonctionnelle et physiologique de la plupart des cellules eucaryotes. Cette asymétrie intracellulaire repose sur l’existence de compartiments membranaires distincts, à la fois dans leur composition en protéines mais également en phosphatidyl-inositols (PIs). Ainsi, la mise en place et le maintien de la localisation asymétrique de modules multi-protéiques associés notamment aux protéines PAR sont essentiels pour l’élaboration des domaines de polarité cellulaire. Durant ma thèse, j’ai étudié les relations entre les protéines de polarité et les PIs dans le contrôle de la polarité cellulaire. Plus particulièrement, en utilisant la chambre ovarienne de Drosophile, j’ai cherché à caractériser la suite d’évènements qui en amont régule l’activité de la PIP5K, Skittles (SKTL), qui produit le PI(4,5)P2 et à caractériser les mécanismes moléculaires qui lient le PI(4,5)P2, SKTL et les protéines PAR dans le contrôle et le maintien de la polarité cellulaire. J’ai contribué à caractériser l’importance de PI(4,5)P2 majoritairement produit par SKTL, dans le maintien de la polarité apico-basale et lors de la morphogenèse des cellules folliculaires de la chambre ovarienne. Le PI(4,5)P2 assure la localisation apicale de PAR3 et le maintien des jonctions adhérentes, sans affecter la localisation de PAR1. Par une méthode de quantification précise, j’ai ensuite démontré dans l’ovocyte que SKTL et le PI(4,5)P2, probablement grâce au trafic vésiculaire, étaient requis pour à la fois l’accumulation à l’antérieur de PAR3 et son exclusion au postérieur qui se fait à partir du stade 9B. L’accumulation antérieure de PAR3 est également dépendante d’un transport Dynéine dépendant et de la kinase IKKε tandis que son exclusion postérieure dépendant des phosphorylations par PAR1. Enfin, j’ai également étudié les modifications post traductionnelles de SKTL et leur importance dans la polarité cellulaire. J’ai identifié la présence de palmitoylation et de phosphorylations dont certaines impliquent la kinase PAR1 et la phosphatase PP1. Ces phosphorylations pourraient avoir un lien avec le rôle de SKTL dans le trafic vésiculaire. Ces résultats permettent donc d’élucider certains mécanismes cellulaires qui contrôlent la mise en place et le maintien de la polarité des cellules en liant les PIs et les protéines PAR / Cell polarity is a fundamental process that controls cell’s functional and physiological specificities. This process relies on membranous compartments differently composed both on proteins and on phosphatidyl-inositols (PIs). Indeed, through their asymmetric localization, polarity proteins, such as the PAR proteins, are essentials to establish and maintain polarity of the cells. During my PhD, I studied the interplay between the polarity proteins and the PIs. Using the Drosophila egg chamber, as a model, I aimed to characterized the upstream events that regulate the PI(4,5)P2 producing kinase (PIP5K), Skittles (SKTL), activity and localization. I also studied the downstream molecular process that link the PI(4,5)P2, SKTL and the PAR proteins in cell polarity. I contributed to the characterization of the importance of PI(4,5)P2, mainly produced by SKTL in maintaining the apical-basal polarity and during the morphogenesis of the follicle cells. The PI(4,5)P2 is ensuring PAR3 and adherens junctions but not PAR1 proper localizations. Next, through a precise quantification method, I showed that SKTL and the PI(4,5)P2, probably via vesicular traffic, were also ensuring PAR3 proper localizations (anterior accumulation and stage 9B posterior exclusion) in the oocyte. PAR3 accumulation also relies on a Dynein mediated transport and the IKKε kinase while its posterior exclusion relies on PAR1 phosphorylation. Finally, I studied SKTL post translational modifications and their relevance on cell polarity. I identified palmitoylation and phosphorylations that are regulated by the kinase PAR1 and the phosphatase PP1. SKTL phosphorylations seem to be related to its role on the vesicular traffic. Altogether these results clarify some mechanisms involving both PIs and PAR proteins in cell polarity maintaining and establishment Protéines PAR Trafic vésiculaire PAR proteins Vésicular trafic Post-translational modification
36	Mass spectrometry analysis of protein/peptide S-palmitoylation Ji, Yuhuan 08 April 2016 (has links) The dynamic S-palmitoylation regulates many intracellular events, including protein trafficking, anchoring, targeting, and protein-protein interactions. Direct detection of S-palmitoylation by conventional liquid chromatography-mass spectrometry (LC-MS) methods is challenging because of the tendency of palmitoyl loss during sample preparation and gas phase fragmentation. Additionally, the high hydrophobicity of the palmitoyl group can prevent proper elution of palmitoyl peptides from the commonly used C18 column. Here, we developed a comprehensive strategy tailored for S-palmitoyl detection using three palmitoyl peptide standards. We found that S-palmitoylation was largely preserved in neutral Tris buffer with tris(2-carboxyethyl)phosphine as the reducing agent and that various fragmentation methods provided complementary information for palmitoyl localization. Moreover, S-palmitoyl peptides were efficiently analyzed using a C4 column and the derivatization of free cysteine with a hydrophobic tag allowed relative quantification of palmitoyl peptides and their unmodified counterparts. We further discovered potential complications to S-palmitoylation analysis caused by the use of ProteaseMAXTM, an MS-compatible detergent. The hydrophobic degradation products of ProteaseMAXTM reacted with the free cysteine thiols, generating artifacts that mimic S-acylation and hydroxyfarnesylation. Another MS-compatible detergent, RapiGestTM, did not produce such artifacts, and showed the ability to stabilize S-palmitoylation by preventing thioester hydrolysis and dithiothreitol-induced thioester cleavage. Moreover, we found that the palmitoyl peptide GCpalmLGNAK could undergo intermolecular palmitoyl migration from the cysteine to the peptide N-terminus or the lysine side chain during sample preparation, and this could lead to false discovery of N-palmitoylation. RapiGestTM inhibited such migration, and is thus recommended for S-palmitoyl sample preparation. We then applied the established method to analyze the regulator of G-protein signaling 4 (RGS4) which had been reported to undergo S-palmitoylation by radioactive labeling. It had also been reported that the S-palmitoylation state of RGS4 affects its GTPase activity. With LC-MS/MS analysis, we found that the addition of palmitate to the cell culture medium in metabolic labeling experiments could boost the level of S-palmitoylation, leading to false discovery of new S-palmitoylation site(s). We also noted discrepancies between the S-palmitoylation sites identified by radioactive labeling and by LC-MS/MS analysis. Further studies are needed to evaluate the reliability of S-palmitoyl detection by these two methods. Biochemistry High-performance liquid chromatography Mass spectrometry Palmitoylation Post-translational modification
37	Post-Translational Regulation of Superoxide Dismutase 1 (SOD1): The Effect of K122 Acylation on SOD1's Metabolic Activity Banks, Courtney Jean 01 August 2017 (has links) Many mutations in superoxide dismutase 1 (SOD1) cause destabilization and misfolding of the protein and are implicated in amyotrophic lateral sclerosis. Likewise, a few post-translational modifications (PTMs) on SOD1 have been shown to cause the same phenotype. However, relatively few PTMs on SOD1 have been studied in depth and, in particular, very few studies have demonstrated how these PTMs affect SOD1's various biological roles. SOD1 is traditionally known for its role in reactive oxygen species (ROS)-scavenging but has also been found to have a few other biological roles, including transcription factor activity to promote genomic stability, preservation of cytoskeletal activity, maintaining zinc and copper homeostasis, and suppressing respiration. We have used the computational analysis tool, SAPH-ire, to find PTM 'hotspots' on SOD1 that have a high likelihood of affecting its biological functions. Interestingly, the top seven ranked PTM 'hotspots' were found in a small region of SOD1, between S98-K128. We focused our studies on one of the PTM 'hotspots' found in this region, lysine-122 (K122). K122 is found in the electrostatic loop of SOD1, a loop that is important for shuttling in superoxide radicals to be neutralized. According to our data, and other studies, this lysine is both succinylated and acetylated. We found that acetyl and succinyl-mimetics (K122Q and K122E, respectively) of this site do not affect its ROS scavenging activity but do prevent SOD1 from suppressing respiration and decrease its localization to the mitochondria. Further, when cells are depleted of SIRT5 (the desuccinylase for K122), SOD1 can no longer suppress respiration. Additionally, we found that SOD1 appears to suppress respiration at complex I, whether directly or through an indirect pathway is unknown. When HCT116 colon cancer cells were depleted of endogenous SOD1, the overexpressed succinyl K122-mimetic (K122E) could not recover growth as well as overexpressed WT SOD1. The K122E SOD1 expressing cells also exhibited increased mitochondrial ROS and unhealthier mitochondria. We propose a mechanism whereby SOD1 suppression of respiration acts as an additional regulator of oxidative stress: SOD1 suppresses the electron transport chain to decrease reactive oxygen species leakage and to promote healthier mitochondria and growth. SOD1 post-translational modification acetylation succinylation acylation electron transport chain Chemistry
38	Modification of MDMX by Ubiquitination and Sumoylation Pan, Yu 23 March 2005 (has links) MDM2 and MDMX are two major negative regulators of tumor suppressor p53. Both MDM2 and MDMX can inactivate p53 and play important roles in mouse embryonic development in a p53 dependent manner. MDM2 possesses ubiquitin E3 ligase activity and mediates self-ubiquitination as well as ubiquitination and degradation of p53 by proteasome. We identify MDMX as another ubiquitin E3 ligase substrate of MDM2. MDM2 promotes the ubiquitination and degradation of MDMX through proteasome pathway. The RING domains of both MDMX and MDM2 are required and sufficient for MDM2-mediated MDMX ubiquitination. ARF overexpression, DNA damage or MDM2 overexpression can all stimulate MDMX ubiquitination and degradation. We present evidence that MDMX is also sumoylated. The sumoylation sites on MDMX are identified. ARF N-terminus is required for stimulating both MDMX ubiquitination and sumoylation. We also demonstrate that MDMX binds to ARF in an MDM2-dependent fashion. Post-translational modification Mdm2 Arf Ubiquitin Sumo American Studies Arts and Humanities
39	Eﬀective Strategies for Improving Peptide Identiﬁcation with Tandem Mass Spectrometry Han, Xi January 2011 (has links) Tandem mass spectrometry (MS/MS) has been routinely used to identify peptides from protein mixtures in the field of proteomics. However, only about 30% to 40% of current MS/MS spectra can be identified, while many of them remain unassigned, even though they are of reasonable quality. The ubiquitous presence of post-translational modifications (PTMs) is one of the reasons for current low spectral identification rate. In order to identify post-translationally modified peptides, most existing software requires the specification of a few possible modifications. However, such knowledge of possible modifications is not always available. In this thesis, we describe a new algorithm for identifying modified peptides without requiring users to specify the possible modifications before the search routine; instead, all modifications from the Unimod database are considered. Meanwhile, several new techniques are employed to avoid the exponential growth of the search space, as well as to control the false discoveries due to this unrestricted search approach. A software tool, PeaksPTM, has been developed and it has already achieved a stronger performance than competitive tools for unrestricted identification of post-translationally modified peptides. Another important reason for the failure of the search tools is the inaccurate mass or charge state measurement of the precursor peptide ion. In this thesis, we study the precursor mono-isotopic mass and charge determination problem, and propose an algorithm to correct precursor ion mass error by assessing the isotopic features in its parent MS spectrum. The algorithm has been tested on two annotated data sets and achieved almost 100 percent accuracy. Furthermore, we have studied a more complicated problem, the MS/MS preprocessing problem, and propose a spectrum deconvolution algorithm. Experiments were provided to compare its performance with other existing software. Bioinformatics Mass Spectrometry peptide identification post-translational modification data pre-processing Proteomics Computer Science
40	The role of the yeast COG3, VPS35, and YDR141C proteins in membrane trafficking / Bruinsma, Paul, January 2002 (has links) Thesis (Ph. D.)--University of Missouri-Columbia, 2002. / Typescript. Vita. Includes bibliographical references (leaves 177-189). Also available on the Internet.

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