Global ETD Search

261	Iodine Uptake in Larvae of the Purple Sea Urchin (Strogylocentrotus purpuratus Stimpson 1857): Evidence for Peroxide Dependent Diffusion of Iodine in an Animal Miller, Ashley E. M. 15 May 2013 (has links) Echinoids (sea urchins and sand dollars) undergo thyroid hormone (TH) regulated larval development and several species can endogenously synthesize these hormones. Although iodine is the essential component for TH synthesis, nothing is known about iodine uptake mechanisms in echinoids. This thesis primarily aimed to characterize integumental iodine uptake in larvae (echinoplutei) of the purple sea urchin Strongylocentrotus purpuratus. The two mechanisms considered were: iodine uptake via sodium dependent transport utilizing orthologs of vertebrate sodium iodide symporter (NIS) and apical iodide transporter (AIT) versus hydrogen peroxide dependent diffusion (PDD) of iodine. Pharmacology and radioiodine (125I) experiments characterized the effects of various compounds on echinoid iodine uptake. The results demonstrate that purple sea urchin echinoplutei acquire iodine from feeding on microalgae and through integumental transfer. Integumental transfer of iodine is inhibited by cyanide and is temperature dependent. Echinoplutei are not affected by perchlorate exposure demonstrating that NIS/AIT is not involved in S. purpuratus iodine uptake. NIS and AIT are both members of the Sodium Solute Carrier 5 (SSF5) transporter family and phylogenetic analysis of various vertebrate and invertebrate SLC5 members (obtained through BLAST searches) indicated that NIS-like transporters might be a vertebrate synapomorphy. Hydrogen peroxide exposure and oxidative stress induced an increase in iodine influx, whereas reducing agents and peroxidase inhibitors disrupted iodine uptake supporting a PDD-based iodine uptake model. In situ hybridization, immunohistochemistry and real time-PCR analysis demonstrate that the sea urchin dual oxidase 1 (Udx1) (an NADPH oxidase that produced hydrogen peroxide) is expressed throughout all stages of larval development in both S. purpuratus and Lytechinus variegatus specifically occurring in epithelial cells. These findings are the first data to demonstrate Udx1 presence and potential activity outside of fertilization and embryogenesis in echinoplutei. The expression patterns and pharmacological results make Udx1 an attractive candidate for involvement in integumental iodine transfer through PDD. These data provide the first evidence for PDD in an animal. The results also suggest that NIS/AIT may be a vertebrate synapomorphy and PDD of iodine across the integument may be widespread across organisms. Future characterization of iodine uptake mechanism in diverse taxa will address this issue. / Studies were funded by the Natural Sciences and Engineering REsearch Council (NSERC) to A.H. [grant number 400230], Equipment purchased with funding from the Caiadian Foundation for Innovation CFI and NSERC [grant number 400587] to A.H. iodine echinoids dual oxidase radio-iodine sea urchin integumental transfer
262	EVOLUTION OF OXIDATIVE METABOLISM IN FISHES Little, Alexander George 08 June 2010 (has links) My study investigated the evolution of oxidative metabolism in fishes. While intense selection for, or against, non-synonymous point mutations in coding sequence drives the evolution of mitochondrial OXPHOS genes, genome-specific mechanisms such as gene duplication events can play major roles in the evolution of nuclear OXPHOS genes. My thesis focused on the mitochondrial enzyme cytochrome c oxidase (COX), principally in fish because of their evolutionary origins and functional diversity in terms of energy metabolism. In the first part of my thesis, I examined a highly aerobic group of fishes (billfishes and tunas) to study the evolution of mitochondrial COX genes. Though the study began as a structure-function analysis of COX, my approach changed when my preliminary results called into question the accepted phylogenetic relationships of my species of interest. We generated a robust multigene phylogeny of this group to interpret data in a phylogenetically informative context. Phylogenetic analyses in this group provided us with a framework to study the evolution of mitochondrial OXPHOS genes, but unexpectedly revealed that: 1) billfishes are only distantly related to tunas, and share greater evolutionary affinities with flatfishes (Pleuronectiformes) and jacks (Carangidae), and 2) regional endothermy has evolved in a non-scombroid suborder in teleosts. These results collectively imply that regional endothermy has evolved independently at least twice within teleost fish. The second part of my thesis explored the evolution of the nuclear COX subunits, focusing on their origins in fish. Isoform transcription profiles coupled with phylogenetic analyses for each subunit show that vertebrate isoforms arose from a combination of early whole-genome duplications in basal vertebrates or specific lineages (e.g. teleosts), and more recent single gene duplication events. While there is evidence for retained function of some COX orthologues across fishes and mammals, others appear to have diverged in function since their earlier radiation, possibly contributing novel evolutionary functions. Together these two studies provide insight into the evolutionary forces facilitating adaptive change in mitochondrial and nuclear OXPHOS genes. / Thesis (Master, Biology) -- Queen's University, 2009-09-11 11:00:12.562 Oxidative Metabolism Billfish Flatfish Cytochrome Oxidase Isoforms Evolution
263	Biocatalysis of tyrosinase in chloroform medium using selected phenolic substrates Tse, Mara. January 1996 (has links) The biocatalytic activity of mushroom tyrosinase was optimized in chloroform medium, using five selected phenolic substrates, including catechin (CT), vanillin (VA), chlorogenic acid (CA), p-aminophenol (pAP) and hydroquinone (HQ). The specific activity (SA) of tyrosinase determined as the change in absorbance at the selected wavelength per $ mu$g protein per sec ($ delta$A/$ mu$g protein/sec) in chloroform was much higher than that obtained in aqueous media. The optimal amount of enzymatic protein for tyrosinase biocatalysis in chloroform was found to be 44.0 mg protein/L for CT and VA, 31.6, 180.5 and 90.3 mg protein/L, respectively, for CA, pAP and HQ. The optimal pH for the oxidative activity of tyrosinase in chloroform was 6.0 for all the substrates; however, the optimal temperature for enzymatic activity was 30$ sp circ$C for CT and 25$ sp circ$C for the other four substrates. The use of 1.25 and 6.65 mM catechol in chloroform medium activated the tyrosinase activity maximally by 56.2% and 267.2%, respectively for CT and CA as substrates; however, no effect from catechol (0 to 7 mM) was found with VA, pAP or HQ. In addition, the use of 4.25, 2.25 and 5.39 mM ethylenediamine tetraacetic acid (EDTA) in chloroform, with CT, VA and pAP as substrates, inhibited the tyrosinase activity maximally by 44.3, 84.7 and 67.0%, respectively; however, the use of 4.75 and 1.60 mM EDTA activated the enzyme by 101.9% and 115.9%, respectively, for CA and HQ. The use of high-performance liquid chromatography (HPLC) and capillary electrophoresis (CE) demonstrated the phenolic substrate bioconversion, whereas the spectrophotometric scanning showed the product formation during the enzymatic reaction. (Abstract shortened by UMI.) Plant enzymes. Phenol oxidase. Chlorophyll. Organic solvents. Mushrooms.
264	Characterization of a polyphenol esterase from Aspergillus niger and its role in the inhibition of tyrosinase Madani, Wigdan. January 2000 (has links) A crude enzyme extract (FI) of polyphenol esterase (PPE), obtained from the microbial culture of Aspergillus niger, was partially purified by ammonium sulfate precipitation. The partially purified fraction (FII) was subjected to further purification by ion-exchange chromatography, which resulted in five separated fractions, FIIIa, FIIIb, FIIIc, FIIId and FIIIe), where FIIIa showed the highest PPE activity towards chlorogenic acid, as substrate. The biocatalysis of the PPE with a wide range of mono- and diphenols, as substrates, was shown to inhibit mushroom tyrosinase (PPO) activity. Fraction FIIIa exhibited an inhibitory effect, measured spectrophotometrically, on PPO activity with the monophenols, including 4-hydroxyphenylpyruvic acid and m- and p-cresols and the diphenols, including chlorogenic acid, catechin, 3,4-dihydroxyphenylacetic acid (DHPAA), L-3,4-dihydroxyphenylalanine (L-DOPA), 4-methylcatechol, catechol and caffeic acid; however, using the polarographic method, the inhibition of PPO activity by PPE biocatalysis occurred with the diphenols but not with the monophenols. The selected enzymatic fraction FIIIa was further purified, using size-exclusion chromatography, which resulted in three fractions FIVa, FIVb and FIVc. Although fraction FIVc contained the highest PPE activity, it showed a lack of enzyme stability. Fraction FIIIa was therefore, subjected to further purification by hydrophobic interaction chromatography thereby yielding fractions FVa, FVb, FVc, FVd, FVe, FVf and FVg, where fraction FVc showed the highest PPE activity. The denatured electrophoretic analysis of fraction FVc showed the presence of one major band, with a molecular weight of 60 kDa. The successive purification of PPE resulted in a marked increase in the inactivation of PPO activity with diphenols, as demonstrated by both the lower I50 and inhibition dissociation constant (Ki) values. The purified fraction FVc was shown to exhibit, spectrophotometrically, a competitive and un Enzymatic browning. Polyphenol oxidase -- Inhibitors. Esterases. Aspergillus niger.
265	Cytochrome c oxidase subunit Vb interacts with human androgen receptor : a potential mechanism for neuronotoxicity in spinobulbar muscular atrophy Beauchemin, Annie. January 2000 (has links) Spinobulbar muscular atrophy (SBMA) is a neurodegenerative disease caused by the expansion of a polyglutamine (polyGln) tract in the human androgen receptor (hAR). One mechanism by which polyGln-expanded proteins are believed to cause neuronotoxicity is through aberrant interaction(s) with, and possible sequestration of, critical cellular protein(s). / Our goal was to confirm and further characterize the interaction between hAR and cytochrome c oxidase subunit Vb (COXVb), a nuclear-encoded mitochondrial protein. We had previously isolated COXVb as an AR-interacting protein in a yeast two-hybrid search to identify candidates that interact with normal and polyGln-expanded AR. Using the mammalian two-hybrid system, we confirm that COXVb interacts with normal and mutant AR and demonstrate that the COXVb-normal AR interaction is stimulated by heat shock protein 70 (Hsp70). Also, BFP-tagged AR specifically co-localizes with cytoplasmic aggregates formed by GFP-labelled polyGln-expanded AR in androgen-treated cells. / Mitochondrial dysfunction may precede neuropathological findings in polyGln-expanded disorders and may thus represent an early event in neuronotoxicity. Interaction of COXVb and hAR, with subsequent sequestration of COXVb, may provide a mechanism for putative mitochondrial dysfunction in SBMA. Cytochrome oxidase. Androgens -- Receptors. Spinal muscular atrophy -- Pathogenesis.
266	Role of Intracellular Oxidant Release in Oxidised Low Lipoprotein - Induced U937 Cell Death Chen, Alpha Yan January 2012 (has links) Atherosclerosis is a complex inflammation condition involving the accumulation of lipid-filled macrophages within the artery wall. Progression of the initial fatty streak to an advanced atherosclerotic plaque is characterized by the development of a necrotic core region containing cholesterol and dead cells. The oxidation of low-density lipoprotein (LDL) to oxidized LDL (oxLDL) and its subsequent uptake by macrophages to form foam cells are the key process in plaque formation. OxLDL is found within atherosclerotic plaque, and it is cytotoxic to a range of cells including macrophages through the generation of reactive oxygen species (ROS) and induction of oxidative stress. The aim of this study was to examine the cytotoxic effects of oxLDL to U937 human monocyte-like cells. OxLDL caused a rapid concentration-dependent cell viability loss in U937 cells within 6 hours. The progression of oxLDL-induced cell death was found to be strongly correlated with the intracellular ROS production and intracellular glutathione (GSH) loss. OxLDL also caused a rapid loss of intracellular aconitase activity, indicating the impairment of the cellular metabolic function. The cytosolic calcium ion (Ca²⁺) level was also elevated by oxLDL, which could be from both intra- and extra-cellular sources. OxLDL also activated plasma membrane superoxide generation complex NADPH oxidase (NOX), and the progression of oxLDL-induced NOX activation was correlated with oxLDL-mediated ROS production, suggesting NOX is the major source of ROS. Further investigations using NOX inhibitors apocynin or diphenyleneiodonium (DPI) found that inhibition of NOX prevented oxLDL-induced cell viability loss, ROS production, GSH loss and aconitase activity decrease. The cytosolic Ca²⁺ elevation caused by oxLDL was also suppressed slightly by inhibiting NOX activity. These results clearly show that NOX is the major site of oxidative stress upon oxLDL activation, contributing to the oxLDL-induced cell death. This study also examined the protective effect of 7,8-dihydroneopterin (7,8-NP) on oxLDL-induced oxidative stress. 7,8-NP dramatically protected cells from oxLDL-induced cell viability loss, ROS generation and aconitase activity loss. 7,8-NP also inhibited oxLDL-induced cytosolic Ca²⁺ influx particularly after 3 hours. 7,8-NP did not inhibited mitochondrial aconitase activity decrease caused by oxLDL, nor inhibited mitochondrial ROS production. This indicates the protective effect of 7,8-NP against oxLDL damage could primarily in cytoplasm. The failure of 7,8-NP protection from oxLDL activating NOX suggests that the protection of 7,8-NP against oxLDL-induced oxidative stress was not due to the inhibition of NOX activation, but by radical scavenging activity of the NOX products. OxLDL U937 cells cell death ROS NADPH oxidase (NOX)
267	CHARACTERIZATION OF POLYPHENOL OXIDASE AND ANTIOXIDANTS FROM PAWPAW (ASIMINA TRIBOLA) FRUIT Fang, Caodi 01 January 2007 (has links) The latest generation of fighter aircraft utilizes a 270Vdc power system [1]. Such high voltage DC power systems are difficult to protect with conventional circuit breakers because the current does not automatically go to zero twice per cycle during a fault like it does in an AC power system and thus arcing of the contacts is a problem. Solid state power controllers (SSPCs) are the solid state equivalent of a circuit breaker that do not arc and which can respond more rapidly to a fault than a mechanical breaker [2]. Present SSPCs are limited to lower voltages and currents by the available power semiconductors [8,9]. This dissertation presents design and experimental results for a SSPC that utilizes SiC power JFETs for the SSPC power switch to extend SSPC capability to higher voltages and currents in a space that is smaller than what is practically achievable with a Si power switch. The research started with the thermal analysis of the SSPCs power switch, which will guide the development of a SiC JFET multi-chip power module to be fabricated by Solid State Devices Inc. (SSDI) using JFETs from SiCED and/or Semisouth LLC. Multiple multi-chip power modules will be paralleled to make the SSPC switch. Fabricated devices were evaluated thermally both statically and dynamically and electrically both statically and dynamically. In addition to the SiC module research a detailed design of the high voltage SSPC control circuit capable of operating at 200andamp;ordm;C was completed including detailed analysis, modeling and simulations, detailed schematic diagrams and detailed drawings. Finally breadboards of selected control circuits were fabricated and tested to verify simulation results. Methods for testing SiC JFET devices under transient thermal conditions unique to the SSPC application was also developed.
268	Testing the utility of DNA barcoding for the rapid assessment of Formicidae biodiversity in the eThekwini region. Singh, Sohana. 30 October 2014 (has links) The biodiversity of Durban (eThekwini municipality) in KwaZulu Natal is primarily threatened by urbanization although other factors such as climate change and the spread of invasive species also pose a significant threat. Knowledge of what species exist within the city is important for biodiversity surveillance, detecting invasive taxa and uncovering cryptic species. Conducting a comprehensive biodiversity inventory is a daunting task, especially for hyperdiverse groups such as terrestrial arthropods, where closely related species can often only be separated by subtle morphological characters. This study investigated whether the barcoding marker, Cytochrome Oxidase C Subunit 1 (COI) can be used to efficiently and accurately delineate species of ants (family Formicidae) in comparison to traditional taxonomic approaches. The feasibility of DNA barcoding for assembling biodiversity inventories for urban areas which could be useful in conservation planning was also evaluated. A total of 619 individuals were sequenced from 23 geographic localities within the eThekwini region and surrounding regions. DNA barcoding revealed 80 provisional species/ “barcode clusters” or monophyletic lineages which could represent distinct species, while morphology revealed 51 different morphospecies. Extrapolation measures of species richness indicated that as many as 153 species of ants could occur in the city. Phylogenetic and phylogeographic analyses were performed on co-distributed species belonging to the genera Lepisiota, Camponotus, Pheidole and Pachycondyla to better understand the spatial distribution of genetic variability in the eThekwini region. Nuclear markers 18S rDNA and 28S rDNA were also sequenced and compared for a subsample of individuals from Camponotus and Pachycondyla. There was genetic variation at COI and the nuclear markers for each of the species examined. In order to fully elucidate the population genetic patterns which could be expected in eThekwini and surrounding regions, further sampling across more localities is essential. The use of more nuclear markers could also assist in uncovering these unique patterns of genetic variation in an urban setting. In this study, the utility of COI as a species diagnostic tool in ants was confirmed. The barcoding library constructed showed promise in highlighting reserves that should be preserved and possible cryptic speciation for further investigation. / M. Sc. University of KwaZulu-Natal, Durban 2014. Genetic markers. Cytochrome oxidase. Ants. Formica (Insects) Theses--Genetics.
269	Molecular machinery of a membrane-bound proton pump : Studies of charge transfer reactions in cytochrome c oxidase Svahn, Emelie January 2014 (has links) In cellular respiration, electron transfer from the breakdown of foodstuff is coupled to the formation of an electrochemical proton gradient. This is accomplished through proton translocation by respiratory complexes, and the proton gradient is subsequently used e.g. to drive ATP production. Consequently, proton- and electron-transfer reactions through the hydrophobic interior of membrane proteins are central to cellular respiration. In this thesis, proton- and electron transfer through an aa3-type terminal oxidase, cytochrome c oxidase (CytcO) from Rhodobacter sphaeroides, have been studied with the aim of understanding the molecular proton-transfer machinery of this proton pump. In the catalytic site of CytcO the electrons combine with protons and the terminal electron acceptor O2 to form water in an exergonic reaction that drives proton pumping. Therefore, CytcO must transfer both protons that are pumped and protons for the oxygen chemistry through its interior. This is done through its two proton-transfer pathways, termed the D pathway and the K pathway. Our studies have shown that the protons pumped during oxidation of CytcO are taken through the D pathway, and that this process does not require a functional K pathway. Furthermore, our data suggests that the K pathway is used for charge compensation of electron transfer to the catalytic site, but only in the A2 → P3 state transition. Our data also show that the water molecules identified in the crystal structures of CytcO play an important role in proton transfer through the D pathway. Finally, the effects of liposome reconstitution of CytcO on D-pathway proton transfer were investigated. The results suggest that the membrane modulates the rates of proton transfer through the D pathway, and also influences the extent of electron transfer between redox-active sites CuA and heme a. membrane protein respiration redox reaction cytochrome aa3 cytochrome c oxidase
270	Screening of virtual libraries for monoamine oxidase inhibitors / Melinda Barkhuizen Barkhuizen, Melinda January 2013 (has links) The traditional view of drug design is that a single drug should interact with a single molecular target. As science progressed, there was an understanding that most drugs interact with more than one target and that multiple targets may be responsible for either adverse effects or additional therapeutic effects. The idea of polypharmacology, which suggests that the focus of drug design should shift from a single drug that interacts with a single target to a single drug that can have interactions with multiple targets and multiple therapeutic effects, revolutionized the drug discovery process. Discovering new drugs is a long and costly process with years of research and development and clinical trials required before the drugs reach the market for much needed therapeutic applications. By repurposing drugs that are already on the market for a new therapeutic target, the discovery process is accelerated significantly. One such a target disease, for which there is a great need for new effective therapies, is Parkinson’s disease (PD). PD is a progressive neurodegenerative disease that is caused by the death of dopaminergic neurons in the substantia nigra with the resulting loss of dopamine from the striatum. Degeneration in PD leads to varying degrees of motor difficulty and disability, along with other symptoms. Current therapies are focussed on symptomatic management and an improvement of the quality of life of patients, rather than on a cure. There are several therapeutic targets that are currently used in the treatment of PD. One of those targets is the monoamine oxidase (MAO) enzymes, in particular the MAO-B isoform. The MAO enzymes are responsible for the metabolism of amine neurotransmitters, such as dopamine, and inhibition of MAO-B has proven to be an effective strategy to increase the dopamine levels in the brain. Clinically, selective MAO-B inhibitors are administered concurrently with levodopa (a precursor of dopamine) to increase the levels of dopamine derived from levodopa. This approach prolongs the beneficial effects of levodopa. Because MAO-A is responsible for the breakdown of noradrenalin, adrenalin, serotonin and tyramine, non-selective and selective MAO-A inhibitors have therapeutic applications in other neurological and psychiatric disorders such as depression. MAO-A inhibitors, particularly irreversible inhibitors, are also notable from a toxicological point of view. Irreversible MAO-A inhibitors may lead to potentially dangerous effects when combined with serotonergic drugs and certain foods containing tyramine, such as cheeses and processed meats. Selective MAO-B inhibitors and reversible MAO-A inhibitors appear to be free of these interactions. Based on the considerations above, this study aimed to identify clinically used drugs which also inhibit the MAO enzymes as a secondary pharmacological property. Such drugs may, in theory, be repurposed as MAO inhibitors for therapeutic use in the treatment of PD and depression. The identification of potential MAO-A inhibitory properties among clinically used drugs are of further importance since the irreversible inhibition of MAO-A may lead to dangerous effects when combined with certain drugs and foods. To screen clinically used drugs for potential MAO-A and MAO-B inhibitory activities, a pharmacophore approach was followed. A pharmacophore model is a virtual 3D representation of the common steric and electrostatic features of the interaction between an enzyme and a ligand. By identifying hydrogen bond acceptor, hydrogen bond donor and hydrophobic interactions between a reference ligand and an enzyme, a model is created that can search databases for other molecules that would have similar interactions with the enzyme and arguably also act as ligands. This enables the screening of a large amount of molecules in a short amount of time. To assist in the identification of MAO inhibitors, pharmacophore models of the MAO enzymes were constructed using the known crystallographic structures of MAO-A co-crystallized with harmine, and MAO-B cocrystallized with safinamide. The Discovery Studio® software package (Accelrys) was used for this purpose. In this study, virtual libraries of United States Food and Drug Administration (FDA) approved drugs and the United States Environmental Protection Agency (EPA) maximum daily dose databases were screened with pharmacophore models of MAO-A and MAO-B. Among the hits, 26 drugs were selected on the basis of availability and cost, and were subjected to in vitro bio-assays in order to determine their potencies (IC50 values) as inhibitors of recombinant human MAO-A and/or MAO-B. Among the drugs tested, 6 compounds exhibited inhibitory activity towards the MAO enzymes. Of the 6 compounds, pentamidine (IC50 = 0.61 μM for MAO-A and IC50 = 0.22 μM for MAO-B) and phenformin (IC50 = 41 μM for MAO-A) were selected for further analysis. An examination of the recoveries of the enzymatic activities after dilution and dialysis of the enzyme-inhibitor complexes showed that both pentamidine and phenformin interact reversibly with the MAO enzymes. A kinetic analysis suggests that pentamidine acts as a competitive inhibitor with estimated Ki values of 0.41 μM and 0.22 μM for the inhibition of MAO-A and MAO-B, respectively. An analysis of the available pharmacokinetic data and typical therapeutic doses of phenformin and pentamidine suggests that the MAO inhibitory potencies (and reversible mode of action) of phenformin are unlikely to be of pharmacological relevance in humans. Pentamidine, on the other hand, is expected to interact with both MAO-A and MAO-B at typical therapeutic doses. Because of its MAO-A inhibitory activity, pentamidine may thus, in theory, lead to a tyramine-associated hypertensive crisis when combined with tyramine-containing foods. However, pentamidine is unlikely to inhibit central MAO since it does not appear to penetrate the central nervous system to a large degree. In an attempt to gain further insight into the mode of binding to MAO, pentamidine and phenformin were docked into models of the active sites of MAO-A and/or MAO-B. An analysis of the interactions between the enzyme models and the ligands were carried out and the results are discussed in the dissertation. The results of this study show that the pharmacophore model approach may be useful in identifying existing drugs with potential MAO inhibitory effects. The search for new therapeutic MAO inhibitors, that can be used in the treatment of certain neurological disorders, including PD and depression, may be accelerated by employing a virtual screening approach. Such an approach may also be more cost effective than the de novo design of MAO inhibitors. / MSc (Pharmaceutical Chemistry), North-West University, Potchefstroom Campus, 2014 Monoamine oxidase Repurposing Parkinson’s disease Virtual screening Toxicology Enzyme inhibition

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