Global ETD Search

31	Analyzing and classifying bimolecular interactions:I. Effects of metal binding on an iron-sulfur cluster scaffold proteinII. Automatic annotation of RNA-protein interactions for NDB Roy, Poorna, Roy 02 August 2017 (has links) No description available. Bioinformatics Biochemistry Iron-sulfur proteins metalloprotein RNA, RNA-protein interactions
32	Mechanism of Fe-S cluster biosynthesis: the [2Fe-2S] IscU as a model scaffold Nuth, Manunya 29 September 2004 (has links) No description available. Chemistry, Biochemistry Fe-S iron-sulfur IscU IscS NifS
33	Characterization of human NFU and its interaction with the molecular chaperone system Liu, Yushi 27 March 2007 (has links) No description available. NFU NifS iron-sulfur cluster molten globule molecular chaperone
34	Structure-Function Study of Cellular Iron Chemistry Huang, Jia 10 September 2009 (has links) No description available. Chemistry Iron-Sulfur Cluster Frataxin Human ISU IRP1 HscB ITC
35	Characterization of AgaR and YihW, Members of the DeoR Family of Transcriptional Regulators, and GlpE, a Rhodanese Belonging to the GlpR Regulon, Also a Member of the DeoR Family Ray, William Keith 24 August 1999 (has links) AgaR, a protein in <i>Escherichia coli</i> thought to control the metabolism of N-acetylgalactosamine, is a member of the DeoR family of transcriptional regulators. Three transcriptional promoters within a cluster of genes containing the gene for AgaR were identified, specific for <i>agaR, agaZ</i> and <i>agaS</i>, and the transcription start sites mapped. Transcription from these promoters was specifically induced by N-acetylgalactosamine or galactosamine, though K-12 strains lacked the ability to utilize these as sole sources of carbon. The activity of these promoters was constitutively elevated in a strain in which <i>agaR</i> had been disrupted confirming that the promoters are subject to negative regulation by AgaR. AgaR-His6, purified using immobilized metal affinity chromatography, was used for DNase I footprint analysis of the promoter regions. Four operator sites bound by AgaR were identified. A putative consensus binding sequence for AgaR was proposed based on these four sites. <i>In vivo</i> and <i>in vitro</i> analysis of the <i>agaZ</i> promoter indicated that this promoter was activated by the cAMP-cAMP receptor protein (CRP). Expression from the <i>aga</i> promoters was less sensitive to catabolite repression in revertants capable of <i>N</i>-acetylgalactosamine utilization, suggesting that these revertants have mutation(s) that result in an elevated level of inducer for AgaR. A cluster of genes at minute 87.7 of the <i>E. coli</i> genome contains a gene that encodes another member of the DeoR family of transcriptional regulators. This protein, YihW, is more similar to GlpR, transcriptional regulator of <i>sn</i>-glycerol 3-phosphate metabolism in <i>E. coli</i>, than other members of the DeoR family. Despite the high degree of similarity, YihW lacked the ability to repress P<sub>glpK</sub>, a promoter known to be controlled by GlpR. A variant of YihW containing substitutions in the putative recognition helix to more closely match the recognition helix of GlpR was also unable to repress P<sub>glpK</sub>. Transcriptional promoters identified in this cluster of genes were negatively regulated by YihW. Regulation of genes involved in the metabolism of <i>sn</i>-glycerol 3-phosphate in <i>E. coli</i> by GlpR has been well characterized. However, the function of a protein (GlpE) encoded by a gene cotranscribed with that for GlpR was unknown prior to this work. GlpE was identified as a single-domain, 12-kDa rhodanese (thiosulfate:cyanide sulfurtransferase). The enzyme was purified to near homogeneity and characterized. As shown for other characterized rhodaneses, kinetic analysis revealed that catalysis occurs via an enzyme-sulfur intermediate utilizing a double-displacement mechanism requiring an active-site cysteine. K<sub>m</sub> (SSO₃²⁻) and K<sub>m</sub> (CN⁻) were determined to be 78 mM and 17 mM, respectively. The native molecular mass of GlpE was 22.5 kDa indicating that GlpE functions as a dimer. GlpE exhibited a kcat of 230 s-1. Thioredoxin, a small multifunctional dithiol protein, served as sulfur-acceptor substrate for GlpE with an apparent K<sub>m</sub> of 34 mM when thiosulfate was near its K<sub>m</sub>, suggesting thioredoxin may be a physiological substrate. / Ph. D. sulfurtransferase iron-sulfur cluster biosynthesis repressors carbon metabolism transcriptional control
36	Functional Characterization and Surface Mapping of Frataxin (FXN) Interactions with the Fe-S Cluster Assembly Complex Thorstad, Melissa 16 December 2013 (has links) In 1996, scientists discovered a connection between the gene for the human protein frataxin (FXN) and the neurodegenerative disease Friedreich’s ataxia (FRDA). Decreased FXN levels result in a variety of aberrant phenotypes including loss of activity for iron-sulfur containing enzymes, mitochondrial iron accumulation, and susceptibility to oxidative stress. These symptoms are the primary focus of current therapeutic efforts. In contrast our group is pursuing an alternate strategy of first defining FXN function at a molecular level then using this information to identify small molecule functional replacements. Recently, our group has discovered that FXN functions as an allosteric activator for the human Fe-S cluster assembly complex. The work presented here helps to further define molecular details of FXN activation and explain how FRDA missense mutants are functionally compromised. First, the FRDA missense mutants L182H and L182F were investigated. Unlike other characterized FRDA missense mutants, the L182F variant was not compromised in its ability to bind and activate the Fe-S assembly complex. The L182H variant exhibited an altered circular dichroism signature; suggesting a change in secondary structure relative to native FXN, and rapidly degraded. Together these studies suggest that L182 variants are less stable than native FXN and are likely prone to degradation in FRDA patients. Second, as a regulatory role of FXN suggests that its function is likely controlled by environmental stimuli, different maturation forms of FXN as well as post-translational modification mimics were tested as mechanisms to control FXN regulation. Here experiments were designed to test if a larger polypeptide form of FXN represents a functional form of the protein. Kinetic and analytical ultracentrifugation studies revealed a complex heterogeneous mixture of species some of which can activate the Fe-S assembly complex. A previously identified acetylation site was also tested using mutants that mimic acetylation. These mutants had little effect on the ability of FXN to bind and activate the assembly complex. Third, mutagenesis experiments were designed in which the FXN surface residues were replaced with alanine and the resulting variants were tested in binding and activity assays. These experiments revealed a localized “hot-spot” on the surface of FXN that suggests small cyclic peptide mimics might be able to replace FXN and function as FRDA therapeutics. Unexpectedly, one of the FXN variants exhibited significantly tighter binding and could have relevance for therapeutic development. Frataxin Friedreich's ataxia FRDA alanine scanning lysine acetylation allosteric regulation oligomerization
37	Maturation de sites métalliques de protéines par les protéines à radical S-Adénosyl-L-méthionine et la machinerie de fabrication des centres fer-soufre / Maturation of protein active sites containing metals by the radical S-Adenosyl-L-methionine proteins and the iron-sulfur cluster assembly machinery. Marinoni, Elodie 09 December 2011 (has links) Les centres FeS sont un des cofacteurs protéiques majeurs, ils se trouvent aussi bien chez les bactéries que chez les eucaryotes. Ils ont des rôles essentiels de transfert d'électron, liaison de substrat et son activation, régulation d'expression de gènes, donneur de soufre etc. Leur agencement est très varié, allant du centre [2Fe-2S] à l'agrégat plus complexe MoFe7S9X (X = C, N ou O) de la nitrogénase. L'assemblage de ces centres se fait par des machineries protéiques. Nous avons étudié le système ISC (Iron-Sulfur Cluster) chez les bactéries, qui fabrique des centres [2Fe-2S] et [4Fe-4S]. Il est composé des protéines IscS, IscU, IscA, HscA, HscB et d'une ferrédoxine. Deux de ces protéines, IscS, qui est une cystéine désulfurase et IscU, protéine dite échafaudage, sont le cœur de la machinerie puisque IscS apporte le soufre sur la protéine IscU, qui, avec le fer qu'elle aura obtenu d'une autre protéine (non clairement identifiée à ce jour), fabriquera le centre fer-soufre et le transfèrera à une apoprotéine. Nous avons isolé un complexe stable (IscS-D35A-IscU)2 contenant un centre [2Fe-2S] dans des conditions anaérobie. Différentes formes du complexe ont été obtenues et cristallisées afin d'obtenir leurs structures, résolues par remplacement moléculaire. Ces structures nous ont permis de proposer un mécanisme d'assemblage des centres [2Fe-2S] à l'échelle atomique et électronique. Nous avons d'autre part étudié la protéine HmdB probablement impliquée dans la maturation de l'hydrogénase à fer. HmdB fait partie de la superfamille des protéines à radical SAM. Des cristaux de l'apoprotéine ont été obtenus et sa structure a été résolue par remplacement moléculaire. Même si une partie de la structure n'est pas visible du fait de l'absence de centre [4Fe-4S], elle donne une première vue du site actif de la protéine. / FeS clusters are widely used protein cofactors, found both in bacteria and eukaryotes. They play key roles such as electron transfer, substrate binding and activation, regulation of gene expression, sulfur donor etc. They are really various, ranging from the [2Fe-2S] cluster to the more complex MoFe7S9X (X = C, N or O) agregate of nitrogenase. Clusters assembly is carried out by protein machineries. We studied the ISC (Iron-Sulfur Cluster) in bacteria, who assembles [2Fe-2S] and [4Fe-4S] clusters. It is composed of IscS, IscU, IscA, HscA, HscB proteins and a ferredoxin. Two of these proteins: the cysteine desulfurase IscS, and the scaffold protein IscU, represent the core of the machinery as IscS provides sulfur protein on IscU, which, with iron obtained from another protein (not clearly identified to date), assemble the iron-sulfur center. The latter transfers it to an apoprotein. We isolated under anaerobic conditions a stable (IscS-D35A-IscU)2 complex containing a [2Fe-2S] cluster. Different forms of the complex were obtained and their structures were solved by molecular replacement. These structures allowed us to propose a mechanism for the assembly of the [2Fe-2S] clusters at the atomic and electronic levels. We have also studied the HmdB protein, which is proposed to maturate the [Fe]-hydrogenase. HmdB is a member of the radical SAM proteins superfamily. Crystals of the apoprotein were obtained and its structure was solved by molecular replacement. Although part of the structure is not visible due to the absence of the [4Fe-4S] cluster, this structure gives a first view of the active site of the protein. Radical SAM Centres FeS Machinerie ISC Hydrogénase Radical SAM Iron-sulfur clusters ISC machinery Hydrogenase
38	I. Designing Brighter Fluorophores: A Computational And Spectroscopic Approach To Predicting Photophysical Properties Of Hydrazone-Based Dyes Ii. Developing Spectroscopic Methods To Better Understand The Cofactors Of Metalloproteins Cousins, Morgan 01 January 2017 (has links) Luminogens are molecules that emit light upon exposure to high-energy light, and fluorophores are one class of luminogens. Applications of fluorophores range from microviscosity sensors to light emitting diodes (LEDs), as well as biosensors, just to name a few. Many of these applications require the fluorophore to be in the aggregate or solid state. Some fluorophores become highly emissive in the aggregate state; these fluorophores are aggregation-induced emission (AIE) luminogens. Currently, very few quantum mechanical mechanisms have been proposed to describe the unique AIE behavior of luminogens. Boron difluorohydrazone (BODIHY) dyes are a new type of AIE fluorophore. The bright emission is from the S>1 excited state (“anomalous” emission) contrary to Kasha’s Rule. Thus, the mechanism Suppression of Kasha’s Rule (SOKR) was proposed to be responsible for the family of BODIHY dyes. We hypothesize that the SOKR mechanism can explain AIE as well as the anomalous emission of other fluorophores. New BODIHY derivatives (para-CO2H BODIHY, aluminum difluorohydrazone (ALDIHY), and paranitro ALDIHY) were predicted to be bright anomalous fluorophores through density functional theory (DFT) and time-dependent DFT (TDDFT) investigations. In addition, a series of anomalous fluorophores were investigated to determine if their photophysical properties could be explained by the SOKR mechanism (azulene, 1,6-diphenyl-1,3,5hexatriene, and zinc tetraphenylporphyrin). Finally, several triazolopyridinium and triazoloquinolinium dyes were computationally investigated by DFT and TDDFT calculations, and an accurate computational model for the large Stokes shifts of these dyes was developed. In conclusion, a better understanding of the photophysical properties through DFT and TDDFT modeling and spectroscopic investigation of hydrazone-based fluorophores has been achieved. In addition, the metal active sites and cofactors of metalloproteins were probed by optical spectroscopy, nuclear magnetic resonance (NMR) spectroscopy, and DFT modeling. In conjunction, these techniques can be used to elucidate the electronic structure responsible for the unique function of these metalloproteins. Specifically, a novel ironsulfur cluster of a metalloprotein that may be involved in endospore formation of Clostridium difficile, CotA, was characterized by magnetic circular dichroism (MCD) spectroscopy. We propose that CotA contains a high-spin [4Fe-4S] cluster and a Rieske [2Fe-2S] cluster. It appears that the multimerization of the protein is related to the cluster conversion at the interface of monomeric subunits where two [2Fe-2S] clusters combine to form the [4Fe-4S] cluster. In addition, a putative cobalamin acquisition protein from Phaeodactylum tricornutum, CBA1, was not expressed at sufficient concentrations in Escherichia coli for spectroscopic investigation. Finally, a new technique was developed using cobalt-59 NMR spectroscopy to better understand the nucleophilic character of cobalt tetrapyrroles, such as cobalamin (vitamin B12), as biological cofactors as well as synthetic catalysts. New insight into the electronic structure provides valuable information related to the mechanism of these metalloproteins. aggregation induced emission cobalamin DFT and TDDFT fluorescence hydrazone-based fluorophores iron-sulfur clusters Chemistry
39	Iron Requirement of Clostridiiyum Botulinum Type A and Characterization of Iron-Sulfur Proteins in Nitrite Treated and Untreated Botulinal Cells Reddy, Divya Shree A. 01 May 1985 (has links) The effect of added iron on the growth of Clostridium botulinum type A in a chemically defined medium was studied. Growth of C. botulinum was supported by an iron level of 0.05 ug/ml with maximum growth observed at a level of 3 ug iron/ml. Electron paramagnetic resonance (EPR) studies were conducted to detect the presence of iron-sulfur centers and iron-nitric oxide complexes in untreated and nitrite treated cell-free extracts of C. botulinum type A. Untreated extracts of C. botulinum exhibited EPR signals in the oxidized and reduced states characteristic of a "HiPiP-type" iron-sulfur center (g=2.02) in the oxidized state and a reduced signal at g=l.94, characteristic of a reduced iron-sulfur center. Extracts of C. botulinum treated with nitrite exhibited an EPR signal at g=2.035, characteristic of iron-nitrosyl complexes, with the simultaneous disappearance of the the signal at g=l.94. This indicates that nitrite reacts with the iron-sulfur centers in botulinal cells to form iron-nitrosyl complexes. Addition of ascorbate with nitrite intensified the EPR signal at g=2.035, probably by enhancing the reduction of nitrite to nitric oxide. A cytochrome c reduction method was used for the determination of ferredoxin activity in untreated and nitrite treated cells of C. botulinum type A from which ferredoxin had been partially purified. Untreated extracts of C. botulinum reduced cytochrome c which demonstrates ferredoxin activity within the cells. Treatment of the cells with nitrite at a level of 1000 ppm for 45 min was found to inhibit ferredoxin activity by 90%. Boiling the partially purified ferredoxin from the untreated cells for 5 min inactivated the protein. Pyruvate-ferredoxin oxidoreductase activity in partially purified extracts of nitrite treated and untreated cells of C. botulinum was determined by assaying for FAD reduction and acylhydroxamate formation. Nitrite treated cells exhibited an inhibition of 70% of FAD reducing activity and 80% inhibition of acylhydroxamate formation when compared to the untreated cells. Boiling inhibited the activity of partially purified oxidoreductase activity by more than 90% in both the assays. Iron Requirement Clostridium botulinum Characterization Iron-Sulfur Proteins Nitrite Treated Untreated Botulinal Cells Food Science Nutrition
40	Structural Driving Factors for the Coupled Electron and Proton Transfer Reactions in Mitochondrial Cytochrome BC1 Complex: Binding Geometries of Substrates and Protonation States of Ionizable Amino Acid Side Chains Near Qi and Qo Sites Nguyen, Bao Linh Tran 16 April 2014 (has links) Coupled electron and proton transfer (CEPT) events are fundamental for many bioenergetic conversions that involve redox reactions. Understanding the details underlying CEPT processes will advance our knowledge of (1) how nature regulates energy conversion; (2) our strategies for achieving renewable energy sources; (3) how to cope with CEPT dysfunction diseases. Studies of the detailed mechanism(s) of CEPT in biological systems is challenging due to their complex nature. Consequently, controversies between the concerted and sequential mechanism of CEPT for many systems remain. This dissertation focuses on the bovine mitochondrial cytochrome bc1 complex. CEPT in the bc1 complex operates by a modified "Q-cycle"(1) and catalyzes electron transfer from ubiquinol (QH2), to cyt c via an iron sulfur cluster (ISC) and to the low potential hemes of cyt b, where it reduces ubiquinone (UQ). The electron transfer is coupled to the translocation of protons across the mitochondrial inner membrane, generating a proton gradient that drives ATP synthesis. Although the Q-cycle is widely accepted as the model that best describes how electrons and protons flow in bc1, detailed binding geometries at the Qo site (QH2 oxidation site) and Qi site (UQ reduction site) remain controversial. The binding geometries play critical roles in the thermodynamic and/or kinetic control of the reaction and protonatable amino acid side chains can participate in the proton transfer. The central focuses of this dissertation are molecular dynamics simulations of cofactor binding geometries near the Qo and Qi sites, calculations of the pKa values of ionizable amino acid side chains implicated in cofactor binding, especially the ISC-coordinated histidines, and implications for the proposed mechanism(s) of CEPT. For the first time, pKa values of the ISC-coordinated histidines are differentiated. The computed pKa values of 7.8±0.5 for His141 and 9.1±0.6 for His161 agree well with experiment (7.63±0.15 and 9.16±0.28). Thus, His161 should be protonated at physiological pH and cannot be the first proton acceptor in the QH2 oxidation. Water mediated hydrogen bonds between substrate models and the protein and water accessibility to the Qo and Qi sites were maintained in simulations, implying that water molecules are likely the proton donors and acceptors. / Bayer School of Natural and Environmental Sciences; / Chemistry and Biochemistry / PhD; / Dissertation;

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