Global ETD Search

1	Chloride Channels and Brown Fat Cells Sabanov, Victor January 2005 (has links) <p>Chloride ion channels are macromolecular pores providing for passage of chloride ions (and certain other inorganic and organic anions) through the cell membrane, down their electrochemical gradients. Chloride channels are differentially expressed in various cells, to best suit specific cellular activities. They are present in practically all living cells, and regardless of cell specialization they play an important role in vital housekeeping functions of cell-volume and pH regulation and in membrane potential stabilization. Regulation of cell volume underlies the structural integrity and constancy of the intracellular milieu. A variety of metabolic pathways have been shown to be sensitive to cell volume, and alterations of cell volume and osmoregulation processes can influence various intracellular signaling and organizing factors.</p><p>Volume-regulated anion channels (VRACs) are believed to play a pivotal role in cell-volume regulating processes. In this report I present data from macroscopic patch-clamp studies of VRACs performed in a fibroblast cell line and from single channel studies of chloride channels (tentatively related to VRACs) in mouse brown adipocytes in primary culture.</p><p>One of the characteristic features of the VRACs is their dependence on the presence of cytoplasmic ATP. In whole-cell experiments, removal of ATP from the pipette solution almost completely prevented activation of VRACs, whereas substitution of ATP with the nonhydrolyzable analog ATPγS did not alter the activation of VRACs. The inhibitors of protein tyrosine kinases (PTK) tyrphostin A25 and B46 depressed VRAC currents in both cases (ATP and ATPγS), but a PTK ineffective analog (tyrphostin A1) did not affect VRAC currents. We infer that in the cell preparation we used, ATP has a dual role in VRAC regulation: it is required for channel-protein phosphorylation and it can influence channel activity through non-hydrolytic binding in a ligand-receptor manner. It can additionally be suggested that tyrosine-specific protein kinases can be involved in the regulation of VRACs, independently of the effects of ATP. We also studied cell cycle-related changes in activation of VRACs by osmotic swelling of cells chemically arrested at different phases of the cell cycle. We found no significant changes during most of the cell cycle, except short periods before and after mitosis and in the quiescent G0 state.</p><p>The single Cl<sup>- </sup>channels of brown adipocytes resemble in their electrophysiological phenotype outwardly rectifying Cl<sup>-</sup> channels (ORCCs). We investigated the sensitivity of these channels to intracellular Ca<sup>2+</sup>. It appeared that the commonly used Ca<sup>2+</sup>-chelators EGTA and BAPTA could influence the ORCCs currents by themselves, independently of their calcium chelating effects. In some channels, these chelators induced classical flickery-type block of activity, whereas in others there was quasi-blockage, i.e. a peculiar combination of flickery blockage and overall channel activation. The chloride channel blocking agents DIDS and SITS mimicked the true/quasi blockage of EGTA and BAPTA. These phenomena add to the structure-function characteristics of the ORCC molecule. Moderate inhibitory effect of Ca<sup>2+</sup> within a physiological range of intracellular concentrations (sub-µM) was also detected; however, the biological relevance of this observation, as well as of these Cl<sup>-</sup> channels in general, remains to be clarified.</p> Chloride channel BAPTA EGTA Ca Animal physiology Zoofysiologi
2	Chloride Channels and Brown Fat Cells Sabanov, Victor January 2005 (has links) Chloride ion channels are macromolecular pores providing for passage of chloride ions (and certain other inorganic and organic anions) through the cell membrane, down their electrochemical gradients. Chloride channels are differentially expressed in various cells, to best suit specific cellular activities. They are present in practically all living cells, and regardless of cell specialization they play an important role in vital housekeeping functions of cell-volume and pH regulation and in membrane potential stabilization. Regulation of cell volume underlies the structural integrity and constancy of the intracellular milieu. A variety of metabolic pathways have been shown to be sensitive to cell volume, and alterations of cell volume and osmoregulation processes can influence various intracellular signaling and organizing factors. Volume-regulated anion channels (VRACs) are believed to play a pivotal role in cell-volume regulating processes. In this report I present data from macroscopic patch-clamp studies of VRACs performed in a fibroblast cell line and from single channel studies of chloride channels (tentatively related to VRACs) in mouse brown adipocytes in primary culture. One of the characteristic features of the VRACs is their dependence on the presence of cytoplasmic ATP. In whole-cell experiments, removal of ATP from the pipette solution almost completely prevented activation of VRACs, whereas substitution of ATP with the nonhydrolyzable analog ATPγS did not alter the activation of VRACs. The inhibitors of protein tyrosine kinases (PTK) tyrphostin A25 and B46 depressed VRAC currents in both cases (ATP and ATPγS), but a PTK ineffective analog (tyrphostin A1) did not affect VRAC currents. We infer that in the cell preparation we used, ATP has a dual role in VRAC regulation: it is required for channel-protein phosphorylation and it can influence channel activity through non-hydrolytic binding in a ligand-receptor manner. It can additionally be suggested that tyrosine-specific protein kinases can be involved in the regulation of VRACs, independently of the effects of ATP. We also studied cell cycle-related changes in activation of VRACs by osmotic swelling of cells chemically arrested at different phases of the cell cycle. We found no significant changes during most of the cell cycle, except short periods before and after mitosis and in the quiescent G0 state. The single Cl- channels of brown adipocytes resemble in their electrophysiological phenotype outwardly rectifying Cl- channels (ORCCs). We investigated the sensitivity of these channels to intracellular Ca2+. It appeared that the commonly used Ca2+-chelators EGTA and BAPTA could influence the ORCCs currents by themselves, independently of their calcium chelating effects. In some channels, these chelators induced classical flickery-type block of activity, whereas in others there was quasi-blockage, i.e. a peculiar combination of flickery blockage and overall channel activation. The chloride channel blocking agents DIDS and SITS mimicked the true/quasi blockage of EGTA and BAPTA. These phenomena add to the structure-function characteristics of the ORCC molecule. Moderate inhibitory effect of Ca2+ within a physiological range of intracellular concentrations (sub-µM) was also detected; however, the biological relevance of this observation, as well as of these Cl- channels in general, remains to be clarified. Chloride channel BAPTA EGTA Ca Animal physiology Zoofysiologi
3	Physiological and molecular studies on silicon-induced cadmium tolerance in rice (Oryza sativa l.) Nwugo, Chika Charles. January 2008 (has links) Thesis (Ph. D.)--Miami University, Dept. of Botany, 2008. / Title from second page of PDF document. Includes bibliographical references (p. 115-131).
4	Physiological and Molecular Studies on Silicon-Induced Cadmium Tolerance in Rice (<i>Oryza sativa</i> L.) Nwugo, Chika Charles 05 August 2008 (has links) No description available. Botany cadmium-stress chlorophyll fluorescence EGTA photosynthesis proteins silicon stomatal conductance silicon
5	Testing and implementation of a titration technique for use in the determination of Ca<sup>2+</sup> binding constants Rotterman, Erik M. 04 May 2011 (has links) No description available. Biophysics Chemistry calcium binding EGTA calmodulin pressure dialysis titration indo-1
6	Membrane Properties Involved in Calcium-Stimulated Microparticle Release from the Plasma Membranes of S49 Lymphoma Cells Campbell, Lauryl Elizabeth 14 August 2012 (has links) (PDF) The mechanism of microparticle shedding from the plasma membrane of calcium-loaded cells has been investigated in erythrocytes and platelets. Recent studies have revealed the physiological and clinical importance of microparticle release from nucleated cells such as lymphocytes and endothelium. The experiments of this study were designed to address whether simple mechanisms discovered in platelets and erythrocytes also apply to the more complex nucleated cells. Four such mechanisms were addressed: potassium efflux, transbilayer phosphatidylserine migration, cytoskeleton degradation, and membrane lipid order. The rate and amount of microparticle release in the presence of a calcium ionophore, ionomycin, was assayed by light scatter at 500 nm. To inhibit the calcium-activated potassium current, cells were exposed to 1 mM quinine or a high-potassium buffer. Both interventions substantially attenuated microparticle shedding induced by ionomycin. Microparticle release was also greatly reduced in a lymphocyte cell line deficient in the expression of scramblase, the enzyme responsible for calcium-stimulated phosphatidylserine migration to the cell surface. This result indicated that such phosphatidylserine exposure is also required for microparticle shedding. The importance of cytoskeletal rearrangement was evaluated through the use of E64-d, a calpain inhibitor, which appeared to have no affect on release. Thus, if cytoskeleton degradation is important for microparticle release, a different enzyme or protein must be involved. Finally, the effect of membrane physical properties was addressed by varying the experimental temperature (32–42 °C). A significant positive trend in the rate of microparticle release as a function of temperature was observed. Fluorescence experiments with trimethylammoniumdiphenylhexatriene and patman revealed significant differences in the level of apparent membrane order along that temperature range. Ionomycin treatment appeared to cause further disordering of the membrane, although the magnitude of this change was minimally temperature-sensitive. Thus, it was concluded that microparticle release depends more on the initial level of membrane order than on the change imposed by calcium uptake. In general, mechanisms involved in particle release from platelets and erythrocytes appeared relevant tolymphocytes with the exception of the hydrolytic enzyme involved in cytoskeletal degradation. cytoskeleton phosphatidylserine TMA-DPH patman ionomycin Raji fluorescence potassium gradient membrane fluidity nucleated cells anisotropy EGTA calpain gelsolin Cell and Developmental Biology Physiology
7	Multidisciplinary study of the role of calcium in plant in vitro embryogenesis Calabuig Serna, Antonio 06 September 2023 (has links) [ES] El calcio (Ca2+) es un catión esencial que juega un papel fundamental en todos los organismos vivos. Desde el punto de vista funcional, el Ca2+ actúa como un segundo mensajero que regula distintos procesos celulares. Trabajos anteriores indican que la señalización mediante Ca2+ podría estar implicada en las primeras etapas de la inducción de la embriogénesis in vitro de las plantas, pero el verdadero papel del Ca2+ en este proceso es aún desconocido. Por eso, el principal objetivo de la presente Tesis es el estudio del papel del Ca2+ en la embriogénesis in vitro mediante dos sistemas in vitro: la embriogénesis somática y la embriogénesis de microsporas. Para determinar la importancia de la homeostasis del Ca2+ en la inducción de la embriogénesis y las dinámicas de los niveles de Ca2+ durante la inducción y el establecimiento de embriones somáticos y derivados de microsporas, se utilizaron tratamientos químicos y se detectaron los niveles de Ca2+ mediante sondas fluorescentes y sensores cameleon codificados genéticamente, visualizados con microscopía fluorescente y confocal. Observamos que el aumento de Ca2+ es un marcador temprano en la inducción de la embriogénesis in vitro y que los niveles de Ca2+ durante la embriogénesis in vitro son dinámicos en todos los sistemas estudiados. Además, las oscilaciones en los niveles de Ca2+ podrían estar relacionadas con los procesos de diferenciación que ocurren en las células inducidas una vez une el Ca2+ a la calmodulina. Mostramos que un aumento de Ca2+ dentro de un rango definido de concentración tiene un efecto positivo, dependiendo del sistema, en la producción de embriones, siendo más sensibles aquellos sistemas basados en suspensiones de células aisladas que aquellos que usan tejidos como explantes. Finalmente, estudiamos el papel de la calosa durante la embriogénesis somática, observando que la inhibición de la deposición de calosa impide el desarrollo embrionario, lo que sugiere una relación entre la formación de una barrera de calosa y el establecimiento de la identidad embrionaria en las células somáticas. / [CAT] El calci (Ca2+) és un catió essencial que juga un paper fonamental en tots els organismes vius. Des del punt de vista funcional, el Ca2+ actua com a un segon missatger que regula diferents processos cel·lulars. Treballs anteriors indiquen que la senyalització mitjançant el Ca2+ podria estar implicada en les primeres etapes de la inducció de l'embriogènesi in vitro de les plantes, però el paper real del Ca2+ en aquest procés encara és desconegut. Per això, el principal objectiu de la present Tesi és l'estudi del paper del Ca2+ en l'embriogènesi in vitro mitjançant dos sistemes in vitro: l'embriogènesi somàtica i l'embriogènesi de micròspores. Per tal de determinar la importància de l'homeòstasi del Ca2+ en la inducció de l'embriogènesi i les dinàmiques dels nivells de Ca2+ durant la inducció i l'establiment d'embrions somàtics i derivats de micròspores, es van utilitzar tractaments químics i es van detectar els nivells de Ca2+ mitjançant sondes fluorescents i sensors de cameleon codificats genèticament, visualitzats amb microscòpia fluorescent i confocal. Vam observar que l'augment de Ca2+ és un marcador primerenc en la inducció de l'embriogènesi in vitro i que els nivells de Ca2+ durant l'embriogènesi in vitro són dinàmics en tots els sistemes estudiats. A més, les oscil·lacions en els nivells de Ca2+ podrien estar relacionades amb els processos de diferenciació que tenen lloc en les cèl·lules induïdes una vegada uneix el Ca2+ a la calmodulina. Vam mostrar que un augment de Ca2+ dins d'un rang definit de concentració té un efecte positiu, depenent del sistema, en la producció d'embrions, essent més sensibles aquells sistemes basats en suspensions de cèl·lules aïllades que aquells que usen teixits com a explants. Finalment, vam estudiar el paper de la cal·losa durant l'embriogènesi somàtica, i vam observar que la inhibició de la deposició de cal·losa impedeix el desenvolupament embrionari, la qual cosa suggereix una relació entre la formació d'una barrera de cal·losa i l'establiment de la identitat embrionària en les cèl·lules somàtiques. / [EN] Calcium (Ca2+) is an essential cation that plays fundamental roles in all living organisms. From a functional point of view, Ca2+ acts as a second messenger that regulates different cellular processes. Previous works point to the fact that Ca2+ signaling may be involved in the early stages of induction of in vitro plant embryogenesis, but the actual role of Ca2+ in this process remained unveiled. Thus, the main goal of the present Thesis is to study the role of Ca2+ in in vitro embryogenesis using two in vitro systems: somatic embryogenesis and microspore embryogenesis. Chemical treatments and detection of Ca2+ with fluorescent probes and genetically-encoded cameleon sensors imaged by fluorescence and confocal microscopy were performed to determine the importance of Ca2+ homeostasis for induction of embryogenesis and the dynamics of Ca2+ levels during the induction and establishment of somatic and microspore-derived embryos. We observed that Ca2+ increase is an early marker of induction of in vitro embryogenesis and Ca2+ levels during in vitro embryogenesis are dynamic in all the systems we studied. Moreover, Ca2+ oscillations might be related to the differentiation processes that take place in the induced cells upon binding to calmodulin. We showed that Ca2+ increase within a defined range has system-specific positive effects in embryo yield, being more sensitive those systems using isolated cell suspensions rather than those using tissues as explants. Finally, we studied the role of callose during somatic embryogenesis, and we observed that inhibiting callose deposition prevents embryo development, which suggests a relationship between the formation of a callose barrier and the establishment of embryo identity in somatic cells. / Calabuig Serna, A. (2023). Multidisciplinary study of the role of calcium in plant in vitro embryogenesis [Tesis doctoral]. Universitat Politècnica de València. https://doi.org/10.4995/Thesis/10251/196022 Embriogènesi Embryogenesis Embriogénesis Embriogènesi vegetal Plant embryogenesis Embriogénesis vegetal Embriogènesi somàtica Somatic embryogenesis Embriogénesis somática Embriogènesi de micròspores Microspore embryogenesis Embriogénesis de microsporas Dobles haploides Doubled haploids Calcium Calcio Fluorescence resonance energy transfer Cal·losa Callose Calosa Wuschel Cultiu in vitro In vitro culture Cultivo in vitro In vitro embryogenesis Morphogenesis Transformació genètica Genetic transformation Transformación genética Agrobacterium Cameleon Arabidopsis Arabidopsis thaliana Daucus carota Carrot Brassica napus Rapeseed Colza Nicotiana tabacum Tobacco Calmodulin Calmodulina Calcium signaling Cultiu de micròspores Microspore culture Cultivo de microsporas Androgènesi Androgenesis Androgénesis Cell biology Cell culture Molecular biology 2-deoxy-D-glucose Chlorpromazine EGTA Inositol 1,4,5- trisphosphate Ionophore A23187 W-7 BIOQUIMICA Y BIOLOGIA MOLECULAR GENETICA

1

Page generated in 0.0243 seconds