Quantitative analysis of the spontaneous activity and response profiles of odorant receptor neurons in larval Xenopus laevis using the cell-attached patch-clamp technique

Topci, Rodi

24 June 2020

No description available.

610

Xenopus laevis

patch-clamp

sensitivity of odorant receptor neurons

GOK-MEDIZIN

Einflüsse der Serum- und Glukokortikoidkinasen 1 und 3 auf den humanen Na⁺- Dikarboxylat- Transporter NaDC3 / Differential effect of the serum and glucocorticoid kinases 1 and 3 on the sodium-dependent dicarboxylate cotransporter NaDC3

Dzidowski, Andrea

22 August 2017

No description available.

610

Organischer Anionentransporter 1 (OAT1)

Organischer Anionentransporter 3 (OAT3)

SLC13-Transporterfamilie

α-Ketoglutarat

Zwei-Elektroden-Spannungsklemmtechnik

Voltage-Clamp-Technik

proximale Tubuluszelle

Xenopus laevis Oozyten

organic anion transporter 1 (OAT1)

organic anion transporter 3 (OAT3)

solute carrier 13 (SLC13)

solute carrier 22 (SLC22)

α-ketoglutarate (αKG)

two-electrode voltage clamp

tracer uptake experiments

renal proximal tubule cells

Xenopus laevis oocytes

Spindle-Localized CPE-Mediated Translation Controls Mediotic Chromosome Segregation

Eliscovich, Carolina

11 June 2008

La progresión meiótica y el desarrollo embrionario temprano están programados, en parte, por la activación tradcuccional de mRNAs maternos como lo son los que codifican para las proteinas de ciclina B1 o mos. Estos mRNAs no son traducidos al mismo tiempo ni en el mismo lugar. Por lo contrario, su traducción está especificamente regulada por elementos de poliadenilación citoplasmática (CPEs) presentes en sus 3'UTRs. Los elementos CPEs reclutan a la proteina de unión a CPE (CPE-binding protein CPEB (Colegrove-Otero et al., 2005; de Moor et al., 2005; Mendez and Richter, 2001; Richter, 2007)). Esta proteina de unión al RNA no sólo determina cuándo y en qué medida un mRNA será activado traduccionalmente por poliadenilación citoplasmática (Mendez et al., 2000a; Mendez et al., 2000b; Mendez et al., 2002) sino que también participa, junto con el represor de la traducción Maskin, en el transporte y la localización de sus mRNAs diana hacia los sitios de localización subcelular donde su traducción ocurrirá (Huang et al., 2003; Huang and Richter, 2004). Durante el desarrollo embrionario de Xenopus, CPEB se encuentra localizada en el polo animal de los oocitos y más tarde, sobre el huso mitótico y centrosomas en el embrión (Groisman et al., 2000). Se ha demostrado que embriones de Xenopus inyectados con agentes que interrumpen la traducción dependiente de poliadenilación citoplasmática, detienen la división celular y presentan estructuras mitóticas anormales (Groisman et al., 2000). En este trabajo que derivó en mi tesis doctoral, hemos demostrado que la activación traduccional localizada en el huso mitótico de mRNAs regulados por CPEB que codifican para proteinas con una conocida función en aspectos estructurales del ciclo celular como la formación del huso mitótico y la segregación cromosómica, es esencial para completar la primera división meiótica y para la correcta segregación cromosómica en oocitos de Xenopus.

interkinesis

microtubule organizing center

microtubule-cytoskeleton

chromosome segregation

centrosomes

spindle assembly

germinal vesicle breakdown

prophase-I arrest

meiotic cell cycle progression

Poly(A) tail lengthening

animal and vegetal hemispheres

xenopus oocytes and development

RNA-binding proteins

translational activation

untranslated regions (UTRs)

translational repression

mRNA Localization

Cytoplasmic polyadenylation

translation

CPEB

vesícula Germinal

profase-I

formación del huso mitótico

progresión del ciclo meiótico

elongamiento de la cola de poli(A)

polo animal y vegetal

oocitos de Xenopus

al RNA

proteínas de unión

regiones no traducidas (UTRs)

activación traduccional

citoesqueleto de microtúbulos

localización de mRNAs

represión traduccional

poliadenilación citoplasmática

traducción

centro organizador de microtúbulos

centrosomas segregación cromosómica

Xkid

TPX2

interquinesis

CPEB

Xkid

TPX2

57

Étude structure/fonction des cotransporteurs Na+/glucose

Sasseville, Louis

06 1900

Cette thèse porte sur l’étude de la relation entre la structure et la fonction chez les cotransporteurs Na+/glucose (SGLTs). Les SGLTs sont des protéines membranaires qui se servent du gradient électrochimique transmembranaire du Na+ afin d’accumuler leurs substrats dans la cellule. Une mise en contexte présentera d’abord un bref résumé des connaissances actuelles dans le domaine, suivi par un survol des différentes techniques expérimentales utilisées dans le cadre de mes travaux. Ces travaux peuvent être divisés en trois projets. Un premier projet a porté sur les bases structurelles de la perméation de l’eau au travers des SGLTs. En utilisant à la fois des techniques de modélisation moléculaire, mais aussi la volumétrie en voltage imposé, nous avons identifié les bases structurelles de cette perméation. Ainsi, nous avons pu identifier in silico la présence d’une voie de perméation passive à l’eau traversant le cotransporteur, pour ensuite corroborer ces résultats à l’aide de mesures faites sur le cotransporteur Na/glucose humain (hSGLT1) exprimé dans les ovocytes. Un second projet a permis d’élucider certaines caractéristiques structurelles de hSGLT1 de par l’utilisation de la dipicrylamine (DPA), un accepteur de fluorescence dont la répartition dans la membrane lipidique dépend du potentiel membranaire. L’utilisation de la DPA, conjuguée aux techniques de fluorescence en voltage imposé et de FRET (fluorescence resonance energy transfer), a permis de démontrer la position extracellulaire d’une partie de la boucle 12-13 et le fait que hSGLT1 forme des dimères dont les sous-unités sont unies par un pont disulfure. Un dernier projet a eu pour but de caractériser les courants stationnaires et pré-stationaires d’un membre de la famille des SGLTs, soit le cotransporteur Na+/myo-inositol humain hSMIT2 afin de proposer un modèle cinétique qui décrit son fonctionnement. Nous avons démontré que la phlorizine inhibe mal les courants préstationnaires suite à une dépolarisation, et la présence de courants de fuite qui varient en fonction du temps, du potentiel membranaire et des substrats. Un algorithme de recuit simulé a été mis au point afin de permettre la détermination objective de la connectivité et des différents paramètres associés à la modélisation cinétique. / This thesis is about the structure/function relationship in Na+/glucose cotransporters (SGLTs). SGLTs are membrane proteins which use the Na+ transmembrane electrochemical gradient to accumulate their substrates within the cell. As an introduction, a short review of the current state of the field will be followed by a presentation of the different technics used in this work. This work can be divided in three main projects. In the first project, we investigated the structural basis of water permeation through SGLTs. By using molecular modeling technics, we have identified, in silico, a passive permeation pathway used by water to go through the cotransporter across the membrane. Using voltage-clamp volumetric measurement, we were able to corroborate these findings for hSGLT1 expressed in oocytes. A second project allowed elucidation of some of hSGLT1 structural characteristics through the use of dipicrylamine (DPA), a fluorescence acceptor whose repartition in the lipid membrane is voltage-dependant. Use of DPA concomitantly with voltage-clamp fluorescence and FRET (fluorescence resonance energy transfer) has clearly demonstrated the extracellular localisation of part of the 12-13 loop which was previously assumed to be intracellular. In addition, we have shown that hSGLT1 forms a dimeric structure where the subunits are linked by a disulfide bridge. A last project aimed at characterizing the steady-state and pre-steadystate currents of a member of the SGLT family named hSMIT2 (human Na/myo-inositol transporter 2). We showed that phlorizin is a poor inhibitor of pre-steady state currents following depolarisation, and the presence of a time, membrane potential and substrate dependent leak current. A simulated annealing algorithm was developed in order to allow objective determination of both the connectivity and the parameters associated with the optimal kinetic model.

Biophysique

Protéines membranaires

Cotransporteurs Na+/glucose (SGLTs)

Famille structurelle de LeuT

Électrophysiologie

Spectroscopie de fluorescence

Modélisation moléculaire

Modélisation cinétique

Ovocytes de xénopes

Biophysics

Membrane proteins

Na+/glucose transporters (SGLTs)

LeuT structural family

Electrophysiology

Fluorescence spectroscopy

Molecular modeling

Kinetic modeling

Xenopus laevis oocytes

Homology-Based Functional Proteomics By Mass Spectrometry and Advanced Informatic Methods

Liska, Adam J.

16 November 2003

Functional characterization of biochemically-isolated proteins is a central task in the biochemical and genetic description of the biology of cells and tissues. Protein identification by mass spectrometry consists of associating an isolated protein with a specific gene or protein sequence in silico, thus inferring its specific biochemical function based upon previous characterizations of that protein or a similar protein having that sequence identity. By performing this analysis on a large scale in conjunction with biochemical experiments, novel biological knowledge can be developed. The study presented here focuses on mass spectrometry-based proteomics of organisms with unsequenced genomes and corresponding developments in biological sequence database searching with mass spectrometry data. Conventional methods to identify proteins by mass spectrometry analysis have employed proteolytic digestion, fragmentation of resultant peptides, and the correlation of acquired tandem mass spectra with database sequences, relying upon exact matching algorithms; i.e. the analyzed peptide had to previously exist in a database in silico to be identified. One existing sequence-similarity protein identification method was applied (MS BLAST, Shevchenko 2001) and one alternative novel method was developed (MultiTag), for searching protein and EST databases, to enable the recognition of proteins that are generally unrecognizable by conventional softwares but share significant sequence similarity with database entries (~60-90%). These techniques and available database sequences enabled the characterization of the Xenopus laevis microtubule-associated proteome and the Dunaliella salina soluble salt-induced proteome, both organisms with unsequenced genomes and minimal database sequence resources. These sequence-similarity methods extended protein identification capabilities by more than two-fold compared to conventional methods, making existing methods virtually superfluous. The proteomics of Dunaliella salina demonstrated the utility of MS BLAST as an indispensable method for characterization of proteins in organisms with unsequenced genomes, and produced insight into Dunaliella?s inherent resilience to high salinity. The Xenopus study was the first proteomics project to simultaneously use all three central methods of representation for peptide tandem mass spectra for protein identification: sequence tags, amino acids sequences, and mass lists; and it is the largest proteomics study in Xenopus laevis yet completed, which indicated a potential relationship between the mitotic spindle of dividing cells and the protein synthesis machinery. At the beginning of these experiments, the identification of proteins was conceptualized as using ?conventional? versus ?sequence-similarity? techniques, but through the course of experiments, a conceptual shift in understanding occurred along with the techniques developed and employed to encompass variations in mass spectrometry instrumentation, alternative mass spectrum representation forms, and the complexities of database resources, producing a more systematic description and utilization of available resources for the characterization of proteomes by mass spectrometry and advanced informatic approaches. The experiments demonstrated that proteomics technologies are only as powerful in the field of biology as the biochemical experiments are precise and meaningful.

Biochemie

Massenspektrometrie

Proteomik

BLAST

Database Searching

Dunaliella salina

EST

Mass Spectrometry

Microtubule-Associated Proteins

Peptides

Protein Sequence Database

Proteins

Proteomics

Salt Stress Induced Proteins

Sequence-Similarity

Xenopus laevis

ddc:570

rvk:WC 4460

rvk:WD 5085

Biochemie

Datenbank

MAPs

Massenspektrometrie

Peptide

Proteine / s.Aminosäurensequenz

Proteomanalyse

Étude structure/fonction des cotransporteurs Na+/glucose

Sasseville, Louis

06 1900

Cette thèse porte sur l’étude de la relation entre la structure et la fonction chez les cotransporteurs Na+/glucose (SGLTs). Les SGLTs sont des protéines membranaires qui se servent du gradient électrochimique transmembranaire du Na+ afin d’accumuler leurs substrats dans la cellule. Une mise en contexte présentera d’abord un bref résumé des connaissances actuelles dans le domaine, suivi par un survol des différentes techniques expérimentales utilisées dans le cadre de mes travaux. Ces travaux peuvent être divisés en trois projets. Un premier projet a porté sur les bases structurelles de la perméation de l’eau au travers des SGLTs. En utilisant à la fois des techniques de modélisation moléculaire, mais aussi la volumétrie en voltage imposé, nous avons identifié les bases structurelles de cette perméation. Ainsi, nous avons pu identifier in silico la présence d’une voie de perméation passive à l’eau traversant le cotransporteur, pour ensuite corroborer ces résultats à l’aide de mesures faites sur le cotransporteur Na/glucose humain (hSGLT1) exprimé dans les ovocytes. Un second projet a permis d’élucider certaines caractéristiques structurelles de hSGLT1 de par l’utilisation de la dipicrylamine (DPA), un accepteur de fluorescence dont la répartition dans la membrane lipidique dépend du potentiel membranaire. L’utilisation de la DPA, conjuguée aux techniques de fluorescence en voltage imposé et de FRET (fluorescence resonance energy transfer), a permis de démontrer la position extracellulaire d’une partie de la boucle 12-13 et le fait que hSGLT1 forme des dimères dont les sous-unités sont unies par un pont disulfure. Un dernier projet a eu pour but de caractériser les courants stationnaires et pré-stationaires d’un membre de la famille des SGLTs, soit le cotransporteur Na+/myo-inositol humain hSMIT2 afin de proposer un modèle cinétique qui décrit son fonctionnement. Nous avons démontré que la phlorizine inhibe mal les courants préstationnaires suite à une dépolarisation, et la présence de courants de fuite qui varient en fonction du temps, du potentiel membranaire et des substrats. Un algorithme de recuit simulé a été mis au point afin de permettre la détermination objective de la connectivité et des différents paramètres associés à la modélisation cinétique. / This thesis is about the structure/function relationship in Na+/glucose cotransporters (SGLTs). SGLTs are membrane proteins which use the Na+ transmembrane electrochemical gradient to accumulate their substrates within the cell. As an introduction, a short review of the current state of the field will be followed by a presentation of the different technics used in this work. This work can be divided in three main projects. In the first project, we investigated the structural basis of water permeation through SGLTs. By using molecular modeling technics, we have identified, in silico, a passive permeation pathway used by water to go through the cotransporter across the membrane. Using voltage-clamp volumetric measurement, we were able to corroborate these findings for hSGLT1 expressed in oocytes. A second project allowed elucidation of some of hSGLT1 structural characteristics through the use of dipicrylamine (DPA), a fluorescence acceptor whose repartition in the lipid membrane is voltage-dependant. Use of DPA concomitantly with voltage-clamp fluorescence and FRET (fluorescence resonance energy transfer) has clearly demonstrated the extracellular localisation of part of the 12-13 loop which was previously assumed to be intracellular. In addition, we have shown that hSGLT1 forms a dimeric structure where the subunits are linked by a disulfide bridge. A last project aimed at characterizing the steady-state and pre-steadystate currents of a member of the SGLT family named hSMIT2 (human Na/myo-inositol transporter 2). We showed that phlorizin is a poor inhibitor of pre-steady state currents following depolarisation, and the presence of a time, membrane potential and substrate dependent leak current. A simulated annealing algorithm was developed in order to allow objective determination of both the connectivity and the parameters associated with the optimal kinetic model.

Biophysique

Protéines membranaires

Cotransporteurs Na+/glucose (SGLTs)

Famille structurelle de LeuT

Électrophysiologie

Spectroscopie de fluorescence

Modélisation moléculaire

Modélisation cinétique

Ovocytes de xénopes

Biophysics

Membrane proteins

Na+/glucose transporters (SGLTs)

LeuT structural family

Electrophysiology

Fluorescence spectroscopy

Molecular modeling

Kinetic modeling

Xenopus laevis oocytes

Homology-Based Functional Proteomics By Mass Spectrometry and Advanced Informatic Methods

Liska, Adam J.

16 December 2003

Functional characterization of biochemically-isolated proteins is a central task in the biochemical and genetic description of the biology of cells and tissues. Protein identification by mass spectrometry consists of associating an isolated protein with a specific gene or protein sequence in silico, thus inferring its specific biochemical function based upon previous characterizations of that protein or a similar protein having that sequence identity. By performing this analysis on a large scale in conjunction with biochemical experiments, novel biological knowledge can be developed. The study presented here focuses on mass spectrometry-based proteomics of organisms with unsequenced genomes and corresponding developments in biological sequence database searching with mass spectrometry data. Conventional methods to identify proteins by mass spectrometry analysis have employed proteolytic digestion, fragmentation of resultant peptides, and the correlation of acquired tandem mass spectra with database sequences, relying upon exact matching algorithms; i.e. the analyzed peptide had to previously exist in a database in silico to be identified. One existing sequence-similarity protein identification method was applied (MS BLAST, Shevchenko 2001) and one alternative novel method was developed (MultiTag), for searching protein and EST databases, to enable the recognition of proteins that are generally unrecognizable by conventional softwares but share significant sequence similarity with database entries (~60-90%). These techniques and available database sequences enabled the characterization of the Xenopus laevis microtubule-associated proteome and the Dunaliella salina soluble salt-induced proteome, both organisms with unsequenced genomes and minimal database sequence resources. These sequence-similarity methods extended protein identification capabilities by more than two-fold compared to conventional methods, making existing methods virtually superfluous. The proteomics of Dunaliella salina demonstrated the utility of MS BLAST as an indispensable method for characterization of proteins in organisms with unsequenced genomes, and produced insight into Dunaliella?s inherent resilience to high salinity. The Xenopus study was the first proteomics project to simultaneously use all three central methods of representation for peptide tandem mass spectra for protein identification: sequence tags, amino acids sequences, and mass lists; and it is the largest proteomics study in Xenopus laevis yet completed, which indicated a potential relationship between the mitotic spindle of dividing cells and the protein synthesis machinery. At the beginning of these experiments, the identification of proteins was conceptualized as using ?conventional? versus ?sequence-similarity? techniques, but through the course of experiments, a conceptual shift in understanding occurred along with the techniques developed and employed to encompass variations in mass spectrometry instrumentation, alternative mass spectrum representation forms, and the complexities of database resources, producing a more systematic description and utilization of available resources for the characterization of proteomes by mass spectrometry and advanced informatic approaches. The experiments demonstrated that proteomics technologies are only as powerful in the field of biology as the biochemical experiments are precise and meaningful.

info:eu-repo/classification/ddc/570

ddc:570