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Xylan Biosynthesis in Grasses: Uncovering Specific Protein-Protein Interactions (PPIs) between Rice Members of the GT43 and GT47 Families and their Implication in Plant DevelopmentJavaid, Tasleem January 2022 (has links)
No description available.
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Application de la complémentation de fluorescence bi-moléculaire à l'étude du mode d'action des protéines Hox in vivoHudry, Bruno 24 October 2011 (has links)
Comment le plan d’organisation d’un organisme est-il mis en place est une question centrale de la biologie du développement. Les séquençages complets de plusieurs génomes de métazoaires ont montré qu’un nombre restreint de molécules régulatrices soutiennent la diversité des plans d’organisation des animaux, suggérant que ces molécules sont utilisées de manière répétée dans des contextes différents. Cela soulève la question de la diversité d’action : comment ces molécules acquièrent-elle une diversité fonctionnelle ? De plus, la plupart des molécules régulatrices partagent des motifs (fonctionnels/structuraux) communs, soulevant la question de la spécificité : comment des molécules partageant des propriétés biochimiques similaires contrôlent-elles des programmes développementaux spécifiques ?Mon équipe d’accueil s’intéresse à ces questions en utilisant les facteurs de transcription Hox de la Drosophile comme paradigme d’étude.Durant ma thèse, j’ai développé trois lignes de recherches : (1) J’ai adapté la technique de complémentation bi-moléculaire de fluorescence (BiFC) de visualisation des interactions protéines-protéines à l’embryon de drosophile en développement.(2) J’ai employé la BiFC pour disséquer la formation des complexes Hox-protéines PBC. Mes résultats remettent en question le paradigme établit : (a) en soulignant la multiplicité des modes d’interaction Hox-PBC existants, (b) en démontrant que cette diversité peut être source de spécificité d’action.(3) La BiFC a ensuite été exploitée dans un crible par approche gènes candidats pour identifier de nouveaux partenaires des protéines Hox. / My current laboratory aims to tackle the issue of specificity and diversity of regulatory molecules, taking the Drosophila Hox transcription factors as a paradigm for the analysis. During my PhD, I developed three connected research lines.Project 1: Visualization of protein interactions in living Drosophila embryos by the BiFC assayOur results establish the general suitability of BiFC for revealing and studying protein interactions in their physiological context during the rapid course of Drosophila embryonic development.Project 2: Investigation of Hox/PBC complex formation in vivo using BiFC Our findings challenge the current paradigm of Hox/Pbx complex assembly: (a) highlighting the existence of alternative modes of Pbx recruitment, (b) demonstrating that unique Hox-PBC interaction modes can provide specific regulatory function in absence of DNA-binding selectivity.To achieve this project BiFC was also performed with vertebrate Hox proteins in chicken embryos.Project 3: Realization of a candidate interaction screen based on BiFC to identify novel Hox protein partners in vivo(a) We have revealed that Hox proteins establish specific interactions with different subunits of the general mediator complex. These results constituted one of the rare studies making a direct link between the Hox regulators and components of the basal transcriptional machinery, in a physiological context.(b) We have discovered that Hox proteins can interact with importin proteins. This result allows us to assess the importance of controlling the nuclear localization of Hox proteins for controlling their regulatory activities during embryogenesis.
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Fast Methods for Bimolecular Charge OptimizationBardhan, Jaydeep P., Lee, J.H., Kuo, Shihhsien, Altman, Michael D., Tidor, Bruce, White, Jacob K. 01 1900 (has links)
We report a Hessian-implicit optimization method to quickly solve the charge optimization problem over protein molecules: given a ligand and its complex with a receptor, determine the ligand charge distribution that minimizes the electrostatic free energy of binding. The new optimization couples boundary element method (BEM) and primal-dual interior point method (PDIPM); initial results suggest that the method scales much better than the previous methods. The quadratic objective function is the electrostatic free energy of binding where the Hessian matrix serves as an operator that maps the charge to the potential. The unknowns are the charge values at the charge points, and they are limited by equality and inequality constraints that model physical considerations, i.e. conservation of charge. In the previous approaches, finite-difference method is used to model the Hessian matrix, which requires significant computational effort to remove grid-based inaccuracies. In the novel approach, BEM is used instead, with precorrected FFT (pFFT) acceleration to compute the potential induced by the charges. This part will be explained in detail by Shihhsien Kuo in another talk. Even though the Hessian matrix can be calculated an order faster than the previous approaches, still it is quite expensive to find it explicitly. Instead, the KKT condition is solved by a PDIPM, and a Krylov based iterative solver is used to find the Newton direction at each step. Hence, only Hessian times a vector is necessary, which can be evaluated quickly using pFFT. The new method with proper preconditioning solves a 500 variable problem nearly 10 times faster than the techniques that must find a Hessian matrix explicitly. Furthermore, the algorithm scales nicely due to the robustness in number of IPM iterations to the size of the problem. The significant reduction in cost allows the analysis of much larger molecular system than those could be solved in a reasonable time using the previous methods. / Singapore-MIT Alliance (SMA)
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Liquid crystalline polyesters prepared by flexible spacers with rigid spiral moieties: synthesis and characterization.Zheng, Weideng 10 July 2001 (has links)
Different monomeric diols, with a central rigid FD unit connected with two aliphatic chains of
various length, were prepared to react with aromatic mesogenic triad, TOBC. In this manner,
thermotropic polyesters with possible low thermal transition temperatures (including Tmand Ti) and high solubility in organic solvent can be
generated in view of the non-linear polymeric chain imposed by the rigid, bent FD moieties.
In addition to the effect of the aliphatic chain length, polyesters of different molecular weight
will be obtained by different synthesis approach (or fractionation of the resulting polyester
product) and therefore, the influence of molecular weight on liquid crystalline properties
can be evaluated.
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CHARACTERIZATION OF THE ANGIOTENSIN TYPE 1 RECEPTOR AND THE BETA2 ADRENERGIC RECEPTOR PROPERTIES: THE INVOLVEMENT OF ARRESTIN2, RAB1 AND SOME MOLECULAR CHAPERONES IN THE ASSEMBLY AND TRAFFICKING OF GPCRSHammad, Maha 21 July 2010 (has links)
Current drugs used to treat Congestive Heart Failure target the renin-angiotensin and adrenergic systems. Studies showed increased mortality rates in patients treated with a combination of these medications. Angiotensin-AT1 and ?2-Adrenergic receptors were shown to form receptor heteromers. Blockade of one receptor in the complex can affect the signal transmitted by the other; suggesting that ligand-based therapy is not as selective as we might think. Modulating receptor trafficking after synthesis might prove to be a valid therapeutic strategy. Unfortunately, little is known about receptor assembly and transport from Endoplasmic Reticulum to Plasma Membrane. The objectives of this study are to identify the proteins that participate in the assembly of AT1R-?2AR heteromer and the regulators of the anterograde trafficking of G-Protein Coupled Receptors. This thesis introduces the role of important targets in those poorly understood processes. The identification of such targets could lead to developing better drugs with fewer adverse effects.
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In Vivo Characterization of Interactions Among Dynein Complex Components at Microtubule Plus EndsPlevock, Karen M 01 January 2010 (has links) (PDF)
Dynein is a minus end directed molecular motor required for numerous cellular processes during intracellular transport and mitosis. Pac1/LIS1 and Bik1/CLIP-170 are two proteins required for targeting dynein to cytoplasmic microtubule plus ends in budding yeast. The lab previously proposed a model whereby Pac1/LIS1 binds to the motor domain of dynein heavy chain, Dyn1/HC, forming a complex that interacts with the +TIP protein Bik1/CLIP170 at plus ends. This project focused on using Bimolecular Fluorescence Complementation (BiFC) to visualize protein-protein interactions among dynein pathway components in vivo. Budding yeast, Saccharomyces cerevisiae is an ideal system to manipulate dynein as it is a non-essential protein in this system.
The BiFC assay fuses two non-fluorescent halves of Venus, a YFP-derivative, to proteins of interest. If an interaction between the proteins occur, the two halves are brought to close proximity and the fluorophore is reconstituted.
Cells co-expressing Dyn1-VN with Pac1-VC or Bik1-VC exhibited fluorescent foci associated with microtubule plus ends, the cell cortex and spindle pole bodies (SPBs). Additionally, cells co-expressing Pac1-VC with Bik1-VN exhibited fluorescent foci associated with microtubule plus ends.
Cells coexpressing Tub1-VC and Bik1-VN or Dyn1-VN have BiFC signal indicating that both interact with the microtubule directly. Pac-1 coexpressed with Tub1 had no signal above background. These data support that these three components associate at microtubule plus ends. Dyn1 and Pac1 interact with Bik1 at microtubule plus ends. Bik1 serves as a docking platform for the two, but dynein is still able to interact with microtubules, while Pac1 is not.
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Characterization of the cellular network of ubiquitin conjugating and ligating enzymes / Caractérisation du réseau cellulaire d'enzymes de conjugaison et de ligation de l'ubiquitineBlaszczak, Ewa Katarzyna 26 June 2015 (has links)
L'ubiquitylation des protéines est une modification post-traductionnelle qui joue un rôle capital dans la régulation des nombreuses fonctions cellulaires, y compris la croissance cellulaire et la prolifération. Les dysfonctionnements de ce mécanisme sont à l'origine de diverses maladies telles que le cancer par exemple. Le processus d'ubiquitylation implique une série des réactions enzymatiques en cascade, catalysées par une famille des enzymes, structuralement très proches. Cette famille est composée des enzymes activateurs d'ubiquitine (E1s), des enzymes de conjugaison d'ubiquitine (E2s) et des ligases d'ubiquitine (E3s). Les interactions entre E2s et E3s sont dans le centre de la cascade d'ubiquitylation. Une combinaison particulière des pairs E2/E3 va déterminer le type de chaînes d'ubiquitine qui seront attachées à la protéine d'intérêt pour ensuite déterminer la fonction régulatrice de la voie d'ubiquitylation. A ce jour, seulement une petite fraction de paires possibles entre E2 et E3 a été investiguée par des approches biochimiques et in vitro. Cependant ces approches ne reflètent pas forcément des conditions qu'on trouve dans une cellule vivante. Prenant ceci en considération, les principales objectives de ma thèse seront comme suit : identifier et optimiser une méthode de détection et de quantification des interactions E2/E3 dans une cellule vivante de la levure de boulanger (Saccharomyces cerevisiae) ; construire une bibliothèque de souches de la levure qui permettrait d'établir des interactions entre E2 et E3 ; chercher de nouvelles potentielles paires E2/E3 ; caractériser fonctionnellement une potentielle paire E2/E2. Il est difficile de trouver une méthodologie appropriée afin d'étudier les interactions entre E2 et E3 parce qu'ils sont relativement faibles et transitoires. Leurs études nécessitent donc des techniques de détection avec une grande sensibilité. Parmi différentes techniques nous avons testé et choisi la complémentation bimoléculaire de la fluorescence, BiFC. Kurtosis, une mesure permettant localiser et quantifier la fluorescence BiFC-spécifique. Nos résultats nous nous avons permis à identifier 117 putatives paires E2/E3 parmi quels, 23 paires ont été déjà décrit dans la littérature. Parmi 94 nouvelles paires, certains E3s interagissent avec seulement une seule E2 ou d'autres donnent un signal BiFC avec plusieurs E2s. Ubc13, Ubc1 et Ubc4 sont les E2s qui interagissent le plus souvent. Nous avons identifié aussi une interaction entre les protéines Asi1 et Asi3 et les enzymes de conjugaison d'ubiquitine Ubc6 et Ubc7. Asi1 et 3 sont connus de former un complexe Asi1/3 sur la membrane intérieure du noyau impliqué dans la réponse de la cellule aux acides aminés extracellulaires. Ces protéines contiennent un domaine RING caractéristique pour les ligases d'ubiquitine mais cette activité n'était pas démontrée auparavant. / Protein ubiquitylation is a post-translational modification that plays a crucial role in regulating many cellular functions, including cell growth and proliferation. Defects in this control mechanism cause cancer and other diseases. The ubiquitylation process involves a cascade of enzymatic reactions catalyzed by a family of structurally-related enzymes, namely ubiquitin activating enzymes (E1s), ubiquitin conjugating enzymes (E2s) and ubiquitin ligases (E3s). Interactions between E2s and E3s are in the centre of ubiquitylation cascade and it is a combination of particular E2/E3 pairs that determine what types of ubiquitin chains are made, thus determining the regulatory functions of the ubiquitin pathway. To date, only a small fraction of all possible E2/E3 pairs have been investigated, mainly using biochemical and in vitro approaches that may not accurately reflect the conditions that occur in living cells. We aimed to develop a method capable of detecting specific E2-E3 interactions under physiological conditions. Using budding yeast as a model organism, we found that the Bimolecular Fluorescence Complementation (BiFC) enables sensitive detection of the well described Ubc4-Ufd4 pair under endogenous conditions. The assay is specific since the interaction signal is lost in yeasts expressing Ubc4 mutants truncated in its E3 interaction domain. We then used this system to further analyze the physiological network of E2 and E3 enzymes in living yeast. We performed a microscopy screen to assay all interactions between eleven E2s and 56 E3s. Our results show that approximately 20% of all E2/E3 combinations give a detectable BiFC signal. Few E3s interacted only with a single E2, whereas most E3s produced a BiFC signal with multiple E2s. Ubc13, Ubc1 and Ubc4 were found to be the most frequently interacting E2s. Our results match many examples from current literature but we also detected 94 new E2/E3 interactions, in particular we identified an interaction between the proteins Asi1 and Asi3 and E2s Ubc6 and Ubc7. Asi1 and Asi3 are known to form a complex (the Asi1/3 complex) at the inner nuclear membrane and are involved in the regulation of the response to extracellular amino acids. The Asi1/3 complex was suspected to function as a ubiquitin ligases because they contain a RING domain, but this has previously not been demonstrated. We therefore further characterized them functionally.
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Progress of Work towards Cloning Gravity Persistence Signal (gps) Mutants by PCR-Based Methods and Positional MappingBriju, Betsy J. January 2011 (has links)
No description available.
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Isotopes as Mechanism Spies : Nucleophilic Bimolecular Substitution and Monoamine Oxidase B Catalysed Amine Oxidation Probed with Heavy Atom Kinetic Isotope EffectsMacMillar, Susanna January 2006 (has links)
<p>This thesis concerns the study of reaction mechanisms by means of kinetic isotope effects (KIEs). Studies of the nucleophilic bimolecular substitution (S<sub>N</sub>2) reaction had the dual purpose of improving our fundamental understanding of molecular reactivity and assessing the ability of kinetic isotope effects to serve as mechanistic tools. The transition state of the S<sub>N</sub>2 reaction between a cyanide ion and ethyl chloride in tetrahydrofuran was found to be reactant like and only slightly tighter than has been found previously for the same reaction in dimethyl sulphoxide. One conclusion was that the transition-state structure in this reaction was predicted fairly well by the theoretical calculations, even without solvent modelling. The S<sub>N</sub>2 reactions between cyanide ions and <i>para</i>-substituted benzyl chlorides were found to have reactant-like transition states, of which the C<sub>α</sub>-Cl bond was most influenced by the <i>para</i>-substitution. Theoretical calculations indicated that the chlorine KIEs could be used as probes of the substituent effect on the C<sub>α</sub>-Cl bond if bond fission was not too advanced in the transition state. Furthermore, the nucleophile carbon <sup>11</sup>C/<sup>14</sup>C KIEs were determined for the reactions between cyanide ions and various ethyl substrates in dimethyl sulphoxide.</p><p>Precision conductometry was employed to estimate the aggregation status of tetrabutylammonium cyanide in tetrahydrofuran and in dimethyl sulphoxide, which is of interest as tetrabutylammonium cyanide is frequently used as the nucleophilic reagent in mechanistic investigations and synthetic reactions. The tendency for ion-pair formation was found to be very slight, significant, and very strong in dimethyl sulphoxide, water, and tetrahydrofuran, respectively. </p><p>The nitrogen kinetic isotope effect on monoamine oxidase B catalysed deamination of benzylamine was determined in an attempt to obtain conclusive evidence regarding the mechanism of the oxidation. Monoamine oxidase is an important drug target in connection with the treatment of, for example, depression and Parkinson’s disease, and knowledge on how the enzyme effects catalysis would facilitate the design of highly selective and efficient inhibitors.</p>
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Isotopes as Mechanism Spies : Nucleophilic Bimolecular Substitution and Monoamine Oxidase B Catalysed Amine Oxidation Probed with Heavy Atom Kinetic Isotope EffectsMacMillar, Susanna January 2006 (has links)
This thesis concerns the study of reaction mechanisms by means of kinetic isotope effects (KIEs). Studies of the nucleophilic bimolecular substitution (SN2) reaction had the dual purpose of improving our fundamental understanding of molecular reactivity and assessing the ability of kinetic isotope effects to serve as mechanistic tools. The transition state of the SN2 reaction between a cyanide ion and ethyl chloride in tetrahydrofuran was found to be reactant like and only slightly tighter than has been found previously for the same reaction in dimethyl sulphoxide. One conclusion was that the transition-state structure in this reaction was predicted fairly well by the theoretical calculations, even without solvent modelling. The SN2 reactions between cyanide ions and para-substituted benzyl chlorides were found to have reactant-like transition states, of which the Cα-Cl bond was most influenced by the para-substitution. Theoretical calculations indicated that the chlorine KIEs could be used as probes of the substituent effect on the Cα-Cl bond if bond fission was not too advanced in the transition state. Furthermore, the nucleophile carbon 11C/14C KIEs were determined for the reactions between cyanide ions and various ethyl substrates in dimethyl sulphoxide. Precision conductometry was employed to estimate the aggregation status of tetrabutylammonium cyanide in tetrahydrofuran and in dimethyl sulphoxide, which is of interest as tetrabutylammonium cyanide is frequently used as the nucleophilic reagent in mechanistic investigations and synthetic reactions. The tendency for ion-pair formation was found to be very slight, significant, and very strong in dimethyl sulphoxide, water, and tetrahydrofuran, respectively. The nitrogen kinetic isotope effect on monoamine oxidase B catalysed deamination of benzylamine was determined in an attempt to obtain conclusive evidence regarding the mechanism of the oxidation. Monoamine oxidase is an important drug target in connection with the treatment of, for example, depression and Parkinson’s disease, and knowledge on how the enzyme effects catalysis would facilitate the design of highly selective and efficient inhibitors.
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