Clonagem, expressão e caracterização de proteinas recombinantes de Xylella fastidiosa / Cloning, expression and characterization of Xylella fastidiosa proteins

Celia Sulzbacher Caruso

23 March 2007

A bactéria Xylella fastidiosa (X. fastidiosa) é um patógeno de planta que causa a clorose variegada dos citros, também conhecida como amarelinho. Xylella fastidiosa é uma bactéria limitada ao xilema, sendo transmitida de planta a planta através de insetos vetores. Através da determinação experimental da seqüência primária de algumas proteínas marcadamente expressas pela X. fastidiosa e a comparação destas com seqüências de ácidos nucléicos do genoma identificou entre elas três ORFs codificadoras de proteínas que podem estar relacionadas à patogenicidade desta bactéria no seu hospedeiro. No entanto, a função biológica destas proteínas ainda não foi funcionalmente caracterizada. Para investigar o papel biológico e realizar estudos de estrutura e função, as ORFs correspondentes as proteínas hidroxinitrila liase, corismato sintase e proteína D do sistema de transporte e secreção Tat foram clonadas, seqüenciadas e expressas em Escherichia coli. As proteínas recombinantes expressas foram purificadas por cromatografia de afinidade e suas identidades verificadas por seqüenciamento. As proteínas purificadas foram encontradas como uma única banda em SDS-PAGE. As proteínas recombinantes, pela primeira vez isoladas, foram caracterizadas em termos de estabilidade conformacional e comportamento estrutural frente a mudanças de pH e temperatura utilizando-se as espectroscopias de dicroísmo circular e fluorescência. O sucesso na construção do gene sintético e na clonagem em vetores de expressão de E. coli resultou em quantidade satisfatória de expressão das proteínas recombinantes. Duas delas apresentaram-se na formas solúveis, facilmente purificadas e ativas e permitindo suas caracterizações. / Xylella fastidiosa is the causal agent of citrus variegated chlorosis, also known as \"amarelinho\". Xylella fastidiosa inhabits exclusively the xylem vessels, and is transmitted by sharpshooter vectors. The experimental determination of the primary sequence of some markedly expressed proteins for X. fastidiosa and the comparison with the nucleic acids sequence of its genome aided the identification of three of them as being proteins involved in host pathogenicity. However, the biological role of these proteins should be assigned experimentally. In order to investigate the biological role, function and structure, ORFs corresponding to hydroxynitrile liase, chorismate synthase and type V secretory pathway proteins were cloned, sequenced and expressed in Escherichia coli. The expressed recombinant proteins were purified by immobilized metal affinity chromatography (Ni-NTA resin) and their identities were verified by protein sequencing. The purified proteins were found as a single band on SDS-PAGE. The successful cloning and heterologous expression of recombinant HNL in E. coli resulted in a satisfactory amount of expressed protein. Two of the expressed recombinant proteins were soluble, easily purified, and isolated in an active form. X. fastidiosa recombinant proteins, for the first time isolated, were characterized according to enzyme conformational stability and structural behavior as a function of pH and temperature using circular dichroism and fluorescence spectroscopy.

caracterização

clonagem

dicroismo circular

expressão

fluorescência"

pET28a

Xylella fastidiosa

characterization

circular dichroism

cloning

expression

fluorescence spectroscopy

pET28a

Xylella fastidiosa

Carbon K-Shell X-Ray and Auger-Electron Cross Sections and Fluorescence Yields for Selected Molecular Gases by 0.6 To 2 .0 MeV Proton Impact

Bhalla, Raj P. (Raj Pal), 1948

08 1900

Absolute K-shell x-ray cross sections and Auger-electron cross sections are measured for carbon for 0.6 to 2.0 MeV proton incident on CH₄, n-C₄H₁₀ (n-Butane), i-C₄H₁₀ (isobutane), C₆H₆ (Benzene), C₂H₂ (Acetylene), CO and CO₂. Carbon K-shell fluorescence yields are calculated from the measurements of x-ray and Auger-electron cross sections. X-ray cross sections are measured using a variable geometry end window proportional counter. An alternate method is described for the measurement of the transmission of the proportional counter window. Auger electrons are detected by using a constant transmission energy Π/4 parallel pi ate electrostatic analyzer. Absolute carbon K-shell x-ray cross sections for CH₄ are compared to the known results of Khan et al. (1965). Auger-electron cross sections for proton impact on CH₄ are compared to the known experimental values of RΦdbro et al. (1979), and to the theoretical predictions of the first Born and ECPSSR. The data is in good agreement with both the first Born and ECPSSR, and within our experimental uncertainties with the measurements of RΦdbro et al. The x-ray cross sections, Auger-electron cross sections and fluorescence yields are plotted as a function of the Pauling charge, and show significant variations. These changes in the x-ray cross sections are compared to a model based on the number of electrons present in the 2s and 2p sub shells of these carbon based molecules. The changes in the Auger-electron cross sections are compared to the calculations of Matthews and Hopkins. The variation in the fluorescence yield is explained on the basis of the multiconfiguration Dirac-Fock model.

Auger-electron cross sections

fluorescence yields

Dirac-Flock model

Mattews and Hopkins model

Gases -- Spectra.

Auger effect.

Fluorescence spectroscopy.

Investigation of Amyloid β Oligomer Dissociation Mechanisms by Single Molecule Fluorescence Techniques

Abdalla, Hope Cook

01 January 2019

Alzheimer’s disease (AD) is currently considered the most prevalent neurodegenerative disease and places a large financial burden on society as healthcare resources are limited and the disease does not have a cure. Alzheimer’s disease is characterized by the presence of amyloid beta (Aβ) plaques and neurofibrillary tangles; however current literature suggests Aβ oligomers are the main aggregating species leading to AD symptoms. Therefore, the underlying cause of Alzheimer’s, accumulation of amyloid beta, is currently being studied in hopes of developing treatment options. Our research aims at determining the mechanism and kinetics of Aβ oligomer dissociation into non-toxic monomers in the presence of denaturants or small molecule dissociators. These highly active small molecule dissociators, selected from the Apex Screen 5040 library, were previously identified by ELISA studies by the laboratory of Dr. Harry LeVine. We have used fluorescence correlation spectroscopy (FCS) to characterize the size distribution and mole fraction of synthetically prepared fluorescein labeled Aβ (1-42) oligomers. Our FCS results show that in the presence of denaturants or small molecule dissociators, oligomer dissociation may proceed by at least two different mechanisms; high order cooperative dissociation and linear dissociation. A cooperative mechanism is more desirable for therapeutics as oligomer directly dissociates into monomer rather than through various oligomer intermediates. Our FCS studies show the most efficient dissociators proceed through the cooperative dissociation mechanism. We also observed a large retardation of the oligomer dissociation in the presence of gallic acid. We also started preliminary work to develop a total internal reflection fluorescence (TIRF) spectroscopy method to image Aβ (1-42) oligomers. This technique if successful will help to verify the two distinct mechanisms seen by FCS or determine if there is one mechanism that occurs at different rates as TIRF allows for faster analysis.

Alzheimer’s disease

Amyloid β

oligomer dissociators

fluorescence correlation spectroscopy

dissociation mechanisms

Biochemistry

Chemistry

Optical characterization of potential drugs and drug delivery systems

Rosenbaum, Erik

January 2011

This Thesis is a characterization study on substances having potency as drugs as well as on a lipid based drug-delivery matrix. The optical properties of newly synthesized molecules with proven pilicide properties have been characterized with several spectroscopic methods. These methods include optical absorption and fluorescence as well as time-resolved fluorescence. Upon covalently linking compounds with high quantum yields of fluorescence to specific parts of the pilicide, the biological impact was found to increase for some of the derivatives. Furthermore, by expanding the aromatic part of the pilicide molecule, a significant increase in the inherent fluorescence was obtained. The S0-S1 absorption band for these molecules was found to originate from an impure electronic transition, vibronically promoted by intensity borrowing from higher electronic states. Included in this Thesis is the measurement of how deeply some in this class of newly synthesized molecules become situated when placed inside ganglioside GM1 micelles, and how the molecules’ reorientation is affected. By means of radiation-less energy transfer, it was shown that the molecules place themselves close to the hydrophobic-hydrophilic interface inside the GM1 micelles. As a consequence they are exposed to a densely packed environment, which inhibits the free tumbling of the molecule. This restricted tumbling could be measured by means of time-resolved depolarization experiments. The release of drug-like fluorescent molecules is investigated from a lipid mixture, which upon equilibrium with water forms a mixture of inverted hexagonal and cubic phases. The lipid matrix displayed an extended release over the course of weeks, in vitro, for molecules having a large variation in hydrophobicity.

Pilicide

Ganglioside GM1 micelles

Drug Delivery

Elecronic Energy Transfer

UV-Vis Absorption

Fluorescence Spectroscopy

Biophysical chemistry

Biofysikalisk kemi

Modeling of transient protein-protein interactions: a structural study of the thioredoxin system

Obiero, Josiah Maina

25 February 2011

ABSTRACT Protein-protein interactions play a central role in most biological processes. One such biological process is the maintenance of a reducing environment inside the cell. To maintain an internal reducing environment, living cells have evolved two enzymatic systems (glutathione and thioredoxin (Trx) systems). The Trx system is composed of the enzyme TrxR and its substrate Trx. The two proteins constitute an important thiol-dependent redox system that catalyzes the reduction of many proteins that are responsible for a variety of cellular functions. The system relies on transient protein-protein interactions between Trx and TrxR for its function. Cross-reactivity of components of the Trx system between species has been shown to be medically relevant. For example, Helicobacter pylori Trx (HP Trx) is thought to mediate catalytic reduction of human immunoglobulins and thus facilitate immune evasion. It has also been proposed that Helicobacter pylori gains access to the impenetrable gastric mucous layer by using secreted HP Trx to reduce the disulfide bonds present in the cysteine-rich mucin regions that are responsible for cross-linking mucin monomers. Therefore, disruption of secreted HP Trx-host protein interaction may result in restoration of the viscoelastic and hydrophobic protective properties of mucus. Previous studies aimed at understanding the nature of cross-reactivity of Trx system components among various species have shown that Trxs have higher affinity for cognate TrxRs (same species), than for TrxRs from different species. However, the basis for this specificity is not known. A growing body of evidence suggests that most protein-protein interactions are mediated by a small number of protein-protein interface residues, referred to as hot spot residues or binding epitopes. Therefore, understanding the biochemical basis of the affinity of proteins for their partners usually begins by identifying the hot spot residues responsible for the protein complex interactions. In this study, the crystal structures of Deinococcus radiodurans thioredoxin reductase (DR TrxR) and Helicobacter pylori TrxR (HP TrxR) were determined at 1.9 Å and 2.4 Å respectively. Analysis of the Trx-binding sites of both structures suggests that the basis of affinity and specificity of Trx for TrxR is primarily due to the shape rather than the charge of the surface. In addition, the complex between Escherichia coli thioredoxin reductase (EC TrxR) and its substrate thioredoxin (EC Trx) was used to identify residues that are responsible for TrxR-Trx interface stability. Using computational alanine scanning mutagenesis and visual inspection of the EC TrxR-Trx interface, 22 EC TrxR side chains were shown to make contact across the TrxR-Trx interface. Although more than 20 EC TrxR side chains make contact across the TrxR-Trx interface, our results suggest that only 4 residues (F81, R130, F141, and F142) account for the majority of the EC TrxR-Trx interface stability. Individual replacement of equivalent DR TrxR residues (M84, K137, F148, F149) with alanine resulted in drastic changes in binding affinity, confirming that the four residues account for most of TrxR-Trx interface stability. These hot spot residues are surrounded by less important residues (hydrophobic and hydrophilic) that are also predicted to contribute to interface stability. F148 and F149 are invariant across bacterial TrxRs, however other residues that contact Trx are less conserved including M84 and K137. When M84 and K137 were changed to match equivalent E. coli TrxR residues (K137R, M84F); D. radiodurans TrxR substrate specificity was altered from its own Trx to that of E. coli Trx. The results suggest that a small subset of the TrxR-Trx interface residues are responsible for the majority of Trx binding affinity and specificity, a property that has been shown to general to protein-protein interfaces.

fluorescence spectroscopy

Deinococcus radiodurans

Helicobacter pylori

enzyme kinetics

site-directed mutagenesis

thioredoxin system

x-ray crystallography

Protein-protein interactions

Production and Characterization of Wheat Gluten Films

Cousineau, Jamie

January 2012

Biodegradable, edible wheat gluten films offer a renewable alternative to plastic food packaging or can be incorporated directly in the food product. Wheat gluten is a good option because it forms a fibrous network, lending strength and elasticity to films. The goal of this research project was to produce, with a water-based film formulation and methodology, smooth, homogeneous wheat gluten films with low water vapour permeability (WVP). The water-based film formulation also served to compare the FT Wonder wheat cultivar, grown in Ontario, to commercially produced wheat gluten and determine the effect of wheat source on the film properties, surface morphology, surface hydrophobicity, WVP, and film swelling in water for different pH, temperature and casting surface conditions. Fluorescence, SPR, and casting formulation viscosity provided preliminary information on the mechanism of film formation and on gluten protein structure induced by modifying the film formulation. This research provides an alternate use for some Ontario wheat cultivars based on their properties in films compared to commercial sources of gluten. As a result, using Ontario cultivars to prepare gluten film packaging material has potential as an alternate source of income for Ontario farmers. This research also defines the film properties for gluten films produced from aqueous solutions, helping to identify processing parameters that could bring gluten films on par with plastic packaging and make gluten films a viable alternative food packaging material. Finally, it was determined that the water vapour permeability of wheat gluten films was not correlated to film surface contact angle.

wheat gluten

film

hydophobicity

water vapour permeability

fluorescence spectroscopy

surface plasmon resonance

thermogravimetric analysis

viscosity

kjeldahl

swelling

biomaterial

Chemical Engineering

Modeling of transient protein-protein interactions: a structural study of the thioredoxin system

Obiero, Josiah Maina

25 February 2011

ABSTRACT Protein-protein interactions play a central role in most biological processes. One such biological process is the maintenance of a reducing environment inside the cell. To maintain an internal reducing environment, living cells have evolved two enzymatic systems (glutathione and thioredoxin (Trx) systems). The Trx system is composed of the enzyme TrxR and its substrate Trx. The two proteins constitute an important thiol-dependent redox system that catalyzes the reduction of many proteins that are responsible for a variety of cellular functions. The system relies on transient protein-protein interactions between Trx and TrxR for its function. Cross-reactivity of components of the Trx system between species has been shown to be medically relevant. For example, Helicobacter pylori Trx (HP Trx) is thought to mediate catalytic reduction of human immunoglobulins and thus facilitate immune evasion. It has also been proposed that Helicobacter pylori gains access to the impenetrable gastric mucous layer by using secreted HP Trx to reduce the disulfide bonds present in the cysteine-rich mucin regions that are responsible for cross-linking mucin monomers. Therefore, disruption of secreted HP Trx-host protein interaction may result in restoration of the viscoelastic and hydrophobic protective properties of mucus. Previous studies aimed at understanding the nature of cross-reactivity of Trx system components among various species have shown that Trxs have higher affinity for cognate TrxRs (same species), than for TrxRs from different species. However, the basis for this specificity is not known. A growing body of evidence suggests that most protein-protein interactions are mediated by a small number of protein-protein interface residues, referred to as hot spot residues or binding epitopes. Therefore, understanding the biochemical basis of the affinity of proteins for their partners usually begins by identifying the hot spot residues responsible for the protein complex interactions. In this study, the crystal structures of Deinococcus radiodurans thioredoxin reductase (DR TrxR) and Helicobacter pylori TrxR (HP TrxR) were determined at 1.9 Å and 2.4 Å respectively. Analysis of the Trx-binding sites of both structures suggests that the basis of affinity and specificity of Trx for TrxR is primarily due to the shape rather than the charge of the surface. In addition, the complex between Escherichia coli thioredoxin reductase (EC TrxR) and its substrate thioredoxin (EC Trx) was used to identify residues that are responsible for TrxR-Trx interface stability. Using computational alanine scanning mutagenesis and visual inspection of the EC TrxR-Trx interface, 22 EC TrxR side chains were shown to make contact across the TrxR-Trx interface. Although more than 20 EC TrxR side chains make contact across the TrxR-Trx interface, our results suggest that only 4 residues (F81, R130, F141, and F142) account for the majority of the EC TrxR-Trx interface stability. Individual replacement of equivalent DR TrxR residues (M84, K137, F148, F149) with alanine resulted in drastic changes in binding affinity, confirming that the four residues account for most of TrxR-Trx interface stability. These hot spot residues are surrounded by less important residues (hydrophobic and hydrophilic) that are also predicted to contribute to interface stability. F148 and F149 are invariant across bacterial TrxRs, however other residues that contact Trx are less conserved including M84 and K137. When M84 and K137 were changed to match equivalent E. coli TrxR residues (K137R, M84F); D. radiodurans TrxR substrate specificity was altered from its own Trx to that of E. coli Trx. The results suggest that a small subset of the TrxR-Trx interface residues are responsible for the majority of Trx binding affinity and specificity, a property that has been shown to general to protein-protein interfaces.

fluorescence spectroscopy

Deinococcus radiodurans

Helicobacter pylori

enzyme kinetics

site-directed mutagenesis

thioredoxin system

x-ray crystallography

Protein-protein interactions

Widefield fluorescence correlation spectroscopy

Nicovich, Philip R.

26 March 2010

Fluorescence correlation spectroscopy has become a standard technique for modern biophysics and single molecule spectroscopy research. Here is presented a novel widefield extension of the established single-point technique. Flow in microfluidic devices was used as a model system for microscopic motion and through widefield fluorescence correlation spectroscopy flow profiles were mapped in three dimensions. The technique presented is shown to be more tolerant to low signal strength, allowing image data with signal-to-noise values as low as 1.4 to produce accurate flow maps as well as utilizing dye-labeled single antibodies as flow tracers. With proper instrumentation flows along the axial direction can also be measured. Widefield fluorescence correlation spectroscopy has also been utilized to produce super-resolution confocal microscopic images relying on the single-molecule microsecond blinking dynamics of fluorescent silver clusters. A method for fluorescence modulation signal extraction as well as synthesis of several novel noble metal fluorophores is also presented.

Correlation spectroscopy

Super resolution microscopy

Single molecule spectroscopy

Velocimetry

Microfluidics

Fluorescence spectroscopy

Spectrum analysis

Flow visualization

Axial flow

Image analysis

Zur Wechselwirkung von Uran mit den Bioliganden Citronensäure und Glucose

Steudtner, Robin

25 March 2011

Um das Verhalten von Actiniden im Menschen (Stoffwechsel), in geologischen und in biologischen Systemen vorherzusagen, ist es erforderlich deren Speziation genau zu kennen. Zur Bestimmung dieser wird das chemische Verhalten des Urans hinsichtlich Komplexbildungsreaktionen und Redoxreaktionen in Modellsystemen untersucht. Anhand der gewonnenen thermodynamischen Konstanten und dem Redoxverhalten können Risikoabschätzungen für das jeweilige untersuchte System getroffen werden. Das umweltrelevante Uran(IV)-Uran(VI)-Redoxsystem besitzt mit der metastabilen fünfwertigen Oxidationsstufe einen zumeist kurzlebigen Zwischenzustand. Innerhalb dieser Arbeit gelang es erstmalig die Uran(V)-Fluoreszenz mittels laserspektroskopischer Methoden nach zu weisen. Beispielsweise konnte das Bandenmaximum von aquatischem Uranyl(V) im perchlorhaltigem Medium (λex = 255 nm) mit 440 nm, bei einer Fluoreszenzlebensdauer von 1,10 ± 0,02 µs bestimmt werden. Die fluoreszenzspektroskopische Untersuchung eines aquatischen [U(V)O2(CO3)3]5--Komplexes (λex= 255 nm und 408 nm) zeigte bei Raumtemperatur keine Fluoreszenz. Durch Anwendung der Tieftemperaturtechnik wurden bekannte Quencheffekte des Carbonats unterdrückt, so dass bei beiden Anregungswellenlängen ein für Uran(V) typisches Fluoreszenzspektrum im Bereich von 375 nm bis 450 nm, mit Bandenmaxima bei 401,5 nm (λex = 255 nm) und 413,0 nm (λex = 408 nm) detektiert werden konnte. Darüber hinaus konnte bei 153 K (λex = 255 nm) eine Fluoreszenzlebensdauer von 120 ± 0,1 µs bestimmt werden. Untersetzt wurden diese fluoreszenzspektroskopischen Nachweise durch mikroskopische Studien verschiedener Uran(IV)-Festphasen (Uraninit…UO2, Uran(IV) Tetrachlorid…UCl4) und einer sulfathaltigen Uran(IV)-Lösung (UIVSO4). Diese wurden durch kontinuierliche Sauerstoffzufuhr zu Uran(VI) oxidiert. Die ablaufende Oxidation wurde mit dem konfokalen Laser Scanning Mikroskop (CLSM) verfolgt, wobei die Proben mit einer Wellenlänge von 408 nm zur Fluoreszenz angeregt wurden. Die auftretenden Bandenmaxima bei 445,5 nm (UO2), bei 445,5 nm (UCl4) und bei 440,0 nm (UIVSO4) konnten eindeutig der Uran(V)-Fluoreszenz zugeordnet werden. Zur Bestimmung thermodynamischer Konstanten mit Hilfe der Tieftemperaturfluoreszenz wurde zunächst der Einfluss der Temperatur auf das Fluoreszenzverhalten des freien Uranyl(VI)-Ions näher betrachtet. Es zeigte sich, dass mit Erwärmung der Probe (T>298 K) die Fluoreszenzlebensdauer von 1,88 µs (298 K) deutlich absinkt. Die Fluoreszenzintensität verringerte sich dabei um 2,3 % pro 1 K zwischen 273 K und 313 K. Im Gegensatz dazu, steigt die Fluoreszenzlebensdauer um das 150-fache auf 257,9 µs bei einer Verminderung der Temperatur (T <298 K) auf 153 K. Das weitere Absenken der Temperatur (T <153 K) zeigte keinen Einfluss auf die Fluoreszenzlebensdauer. Die Lage der Hauptemissionsbanden des freien Uranyl(VI)-Ions (488,0 nm, 509,4 nm, 532,4 nm, 558,0 nm, 586,0 nm) zeigte bei diesen Untersuchungen keine temperaturabhängige Verschiebung. Die Validierung der Tieftemperaturtechnik zur Bestimmung thermodynamischer Konstanten mittels zeitaufgelöster laserinduzierten Fluoreszenzspektroskopie erfolgte anhand des Uran(VI)-Citrat-Systems. Im Gegensatz zu bisherigen fluoreszenzspektroskopischen Betrachtungen bei Raumtemperatur wurde das Fluoreszenzsignal bei tiefen Temperaturen mit einsetzender Komplexierung nicht gequencht, woraus die Ausprägung einer gut interpretierbaren Fluoreszenz resultierte. Die Analyse der spektralen Daten mit SPECFIT ergaben mit log β101 = 7,24 ± 0,16 für den [UO2(Cit)]--Komplex und log β202 = 18,90 ± 0,26 für den [(UO2)2(Cit)2]2 -Komplex exakt die in der Literatur angegebenen Stabilitätskonstanten. Zudem konnten Einzelkomponentenspektren mit Bandenmaxima bei 475,3 nm, 591,8 nm, 513,5 nm, 537,0 nm und 561,9 nm für den 1:0:1-Komplex und 483,6 nm, 502,7 nm, 524,5 nm, 548,1 nm und 574,0 nm für den 2:0:2-Komplex und Fluoreszenzlebensdauern von 79 ± 15 µs (1:0:1) und 10 ± 3 µs (2:0:2) bestimmt werden. Zur Modellkomplexierung des Uran-Citrat-Systems wurde in dieser Arbeit auch das Komplexbildungsverhalten von U(IV) in Gegenwart von Citronensäure untersucht. Hierbei wurden über den gesamten pH-Wertbereich gelöste Uran-Citrat-Spezies spektroskopisch nachgewiesen und die Stabilitätskonstanten sowie die Einzelkomponentenspektren für die neu gebildeten Uran(IV) und (VI)-Spezies bestimmt. Für die neu gebildeten Citrat-Komplexe des sechswertigen Urans wurden Komplexbildungskonstanten von log β203 = 22,67 ± 0,34 ([(UO2)2(Cit)3]5-) und log β103 = 12,35 ± 0,22 ([UO2(Cit)3]7-) und für die Komplexe des vierwertigen Urans von log β1-21 = -9,74 ± 0,23 ([U(OH)2Cit]-) und log β1 31 = -20,36 ± 0,22 ([U(OH)3Cit]2-) bestimmt. Untersuchungen zum Redoxverhalten von Uran in Gegenwart von Citronensäure zeigten unter aeroben und anaeroben Versuchsbedingungen eine photochemische Reduktion vom U(VI) zu U(IV), welche spektroskopisch nachgewiesen werden konnte. Dabei zeigt speziell die Reaktion unter oxidierenden Bedingungen, welchen großen Einfluss vor allem organischen Liganden auf das chemische Verhalten des Urans haben können. Sowohl die Reduktion unter O2- als auch die unter N2-Atmosphäre, weisen ein Maximum bei einem pH Wert von 3,5 bis 4 auf. Unter anaeroben Bedingungen reduziert die Citronensäure mit ca. 66 %, 14 % mehr Uran(VI) zu Uran(IV) als unter anaeroben Bedingungen mit ca. 52 %. Ab einem pH-Wert von 7 konnte eine Reduktion nur unter sauerstofffreien Bedingungen festgestellt werden. Die Wechselwirkung von U(VI) in Gegenwart von Glucose wurde hinsichtlich Reduktion und Komplexierung des Uran(VI) betrachtet. Mit Hilfe der zeitaufgelösten laserinduzierten Fluoreszenzspektroskopie bei tiefen Temperaturen wurde dabei ein Uranyl(VI)-Glucose-Komplex nachgewiesen. Die Komplexierung wurde lediglich bei pH 5 beobachtet und weist eine Komplexbildungskonstante von log βI=0,1 M = 15,25 ± 0,96 für den [UO2(C6H12O6)]2+-Komplex auf. Mit einer Fluoreszenzlebensdauer von 20,9 ± 2,9 µs und den Hauptemissionsbanden bei 499,0nm, 512,1 nm, 525,2 nm, 541,7 nm und 559,3 nm konnte der Uranyl(VI)-Glucose-Komplex fluoreszenzspektroskopisch charakterisiert werden. Unter reduzierenden Bedingungen wurde, ab pH-Wert 4 eine auftretende Umwandlung vom sechswertigen zum vierwertigen Uran durch Glucose in Gegenwart von Licht beobachtet. Der Anteil an gebildetem Uran(IV) steigt asymptotischen bis zu einem pH-Wert von 9, wo das Maximum mit 16 % bestimmt wurde. Als Reaktionsprodukt der Redoxreaktion wurde eine Uran(VI)-Uran(IV)-Mischphase mit der Summenformel [UIV(UVIO2)5(OH)2]12+ identifiziert. Mit Hilfe der cryo-TRLFS wurde, durch Verminderung von Quencheffekten die Uranspeziation in natürlichen Medien (Urin, Mineralwasser) direkt bestimmt. Proben mit Uran Konzentrationen von < 0,1 µg/L konnten dadurch analysiert werden. In handelsüblichen Mineralwässern wurde die zu erwartende Komplexierung durch Carbonat nachgewiesen. Im Urin zeigte sich in Abhängigkeit vom pH-Wert eine unterschiedliche Uranspeziation. Die fluoreszenzspektroskopische Untersuchung wies bei niedrigerem pH Wert (pH<6) eine Mischung aus Citrat- und Phosphat-Komplexierung des U(VI) und bei höheren pH-Wert (pH>6) eine deutliche Beteilung von Carbonat an der Komplexierung auf. Diese Ergebnisse stehen in sehr guter Übereinstimmung mit theoretischen Modellrechnungen zur Uranspeziation im Urin. Die in dieser Arbeit gewonnenen Ergebnisse zeigen, dass für eine zuverlässigere Prognose des Urantransportes in Geo- und Biosphäre in Zukunft nicht nur Betrachtungen zur Komplexchemie, sondern auch zum Redoxverhalten des Urans nötig sind, um die Mobilität in der Natur richtig abschätzen zu können.

Fluoreszenzspektroskopie

cryo-TRLFS

UV/VIS

Komplexierung

Reduktion

fluorescence spectroscopy

cryo-TRLFS

UV/VIS

complexation

reduction

ddc:546

rvk:VH 8078

Étude du couplage entre les sous-unités du canal potassique KcsA par des mesures de spectroscopie de fluorescence en canal unitaire

McGuire, Hugo

January 2009

Mémoire numérisé par la Division de la gestion de documents et des archives de l'Université de Montréal

Biophysique

"Gating"

Canal ionique

Molécule unitaire

Spectroscopie de fluorescence

KcsA

Biophysics

Gating

Ion channel

Single-molecule

Fluorescence spectroscopy

KcsA