Cav1.2 pore structure using the substituted-cysteine accessibility method /

Breeze, Liam J.

January 2006

Thesis (Ph.D. in Neuroscience) -- University of Colorado at Denver and Health Sciences Center, 2006. / Typescript. Includes bibliographical references (leaves 108-118). Free to UCD Anschutz Medical Campus. Online version available via ProQuest Digital Dissertations;

Electrophysiological and behavioral mechanisms of Caenorhabditis elegans feeding

Shtonda, Boris Borisovich.

January 2004

Thesis (Ph. D.) -- University of Texas Southwestern Medical Center at Dallas, 2004. / Vita. Bibliography: 148-158.

Diferenciação neuronal in vitro de células-tronco mesenquimais humanas para uso em transplante neural / Neuronal differentiation of human mesenchymal stem cells in vitro for neural transplantation

Lepski, Guilherme Alves

07 August 2007

Introdução. O transplante de células é possibilidade terapêutica promissora para muitas doenças neurológicas. Nos últimos anos, a possibilidade do isolamento de células-tronco dos tecidos adultos, por exemplo da medula-óssea, atrai a atenção da comunidade científica, estratégia que minimiza os problemas éticos relativos ao uso de tecido fetal para implantes visando ao tratamento de doenças neurológicas. Entretanto, a eficiência da transdiferenciação de células-tronco mesenquimais em neurônios, bem como os mecanismos envolvidos nesse processo, permanecem desconhecidos. A obtenção de neurônios maduros ocorreu somente em sistemas de co-cultura, o que induz a questão se a diferenciação representa um potencial das células per si, ou se é possível somente devido à fusão com neurônios maduros. Objetivos. No presente trabalho, pretendeu-se verificar o potencial de as células-tronco mesenquimais tornarem-se neurônios e esclarecer os possíveis mecanismos envolvidos nesse processo. Material e métodos. Células-tronco mesenquimais foram isoladas de 20 doadores voluntários normais e caracterizadas por análise de separação celular ativada por fluorescência. A multipotencialidade foi investigada ao se diferenciar as células em condrócitos e osteócitos. A capacidade de auto-renovação foi confirmada pelo ensaio de incorporação de BrdU. Ulteriormente, as células foram diferenciadas por uma semana em meio contendo AMPc, IBMX, ou combinação de ambos, e os resultados foram comparados com o cultivo em meio básico. Diferentes bloqueadores de Ca2+ ou inibidores de PKA foram usados como tentativa de se impedir a diferenciação, ocorrência que foi mensurada com imunocitoquímica para NF-200 (marcador de neurônios maduros). O registro eletrofisiológico por meio de patch clamp foi usado para se confirmar o fenótipo neuronal. As figuras foram configuradas em microscopia confocal. Para análise estatística foi utilizada ANOVA com teste post-hoc. Resultados. As células isoladas expressaram CD90, 105, 44 e 13 mas foram negativas para CD34 e 45. Isto significa que não são de origem hematopoiética; 98,74 ± 0,43% das células incorporaram BrdU em 24 horas. Após o isolamento, foi possível diferenciá-las em condrócitos ou osteócitos. Em situação controle, não foram evidenciadas células positivas para NF200. Por outro lado, ocorreu positividade em 10,75% ± 1,35 (p<0,0001) das células sob IBMX e, em 15,18% ± 1,12, sob a combinação cAMP e IBMX (p<0,0001). Foram registradas correntes de Na+ e K+ dependentes de voltagem, mas não potenciais de ação. A diferenciação foi inibida com PKAi (5,73% ± 0,42, p<0,0001), nifedipina (5,79% ± 0,98, p<0,0001), Ni2+ (7,06% ± 1,68, p<0,0001) e Cd2+ (0 ± 0, p<0,0001). Discussão. Isolou-se uma população de células-tronco estromais da medula-óssea de seres humanos que se mostrou multipotencial e auto-renovável. O aumento da concentração de AMPc no meio elevou a concentração de neurônios para 15%. A diferenciação parece depender da via PKA mas também envolve a concentração intracelular de Ca2+. Conclusão. O correto entendimento de como as células-tronco mesenquimais diferenciam-se pode contribuir para aumentar a eficácia do método e, talvez um dia, tornar possível o uso dessa ferramenta no campo clínico. / Introduction. Cell transplantation has been considered a promising therapeutic approach for many neurological diseases. The possibility of isolation of stem cells from adult tissues, i.e. bone marrow, has attracted the attention of the scientific community in the recent years. This strategy is interesting on avoiding the ethical issues regarding the use of fetal tissue for neural implants. Moreover, the efficiency of the transdifferentiation of mesenchymal stem cells (MSCs) into neurons, and the mechanisms involved in this process remain largely unknown. The obtention of mature neurons was described only in coculture systems, what raised the question if the differentiation is a potential of the cells itself, or if it is possible only due to fusion with mature neurons. Objectives. In the present investigation, we aimed to verify the potential of MSCs to differentiate into neurons, and also to clarify the possible mechanisms involved on it. Material and methods. MSCs were isolated from 20 healthy human subjects and characterized by FACS-analysis. Multipotentiality was addressed by differentiating them into chondrocytes and osteocytes. The self-renewal capacity was confirmed with BrdU-incorporation assay. Afterwards, cells were differentiated for 1 week in a medium containing cAMP, IBMX, or a combination of both, and the results were compared with cells treated in basal-medium condition. Different Ca2+-blockers and PKA-inhibitor peptide were used on an attempt to impair differentiation, which was quantified with NF-200 immunostaining (a marker of mature neurons). Patch-clamp recording was used to confirm neuronal phenotype. Pictures were taken in confocal microscope. For statistical analysis ANOVA with a post-hoc test was used. Results. The isolated cells expressed CD90, 105, 44, and 13, but were negative for CD34 and 45, meaning that they were non-hematopoiethic; 98.74 ± 0.43 % of them incorporated BrdU in 6hs. After isolation, they differentiated into chondrocytes and osteocytes. In a control situation, no NF200 positive cell was seen. On the other hand, 10.75% ± 1.35 (p<.0001) of positivity was seen under IBMX and 15.18% ± 1.12 in the combination of cAMP with IBMX (p<.0001). Na+ and K+-voltage gated currents were recorded. Differentiation was impaired with PKAi (5.73% ± 0.42, p<.0001), nifedipin (5.79% ± 0.98, p<.0001), Ni2+ (7.06% ± 1.68, p<.0001), and Cd2+ (0 ± 0, p<.0001). Discussion. We were able to isolate a population of stromal stem cells from the bone marrow of human subjects, since they were multipotential and self-renewable. Increasing the concentration of cAMP raised the percentage of neurons up to 15%. The differentiation seems to be dependent on the PKA pathway, but also involved the intracellular concentration of Ca2+. Conclusions. The complete understanding of how MSC differentiate can contribute to increase the efficiency of the method and thus make possible to use this powerful tool in the clinical practice.

Adult stem cells

Células-tronco adultas

Doenças neurodegenerativas

Mesenchymal stem cell transplantation

Microscopia de fluorescência

Neurodegenerative diseases

Técnicas de Patch Clamp.

Role of potassium channels in regulating neuronal activity /

Klement, Göran,

January 2007

Diss. (sammanfattning) Stockholm : Karolinska institutet, 2007. / Härtill 5 uppsatser.

K⁺ channels in the inner ear : electrophysiological and molecular studies /

Liang, Guihua,

January 2005

Diss. (sammanfattning) Stockholm : Karol. inst., 2005. / Härtill 5 uppsatser.

Diferenciação neuronal in vitro de células-tronco mesenquimais humanas para uso em transplante neural / Neuronal differentiation of human mesenchymal stem cells in vitro for neural transplantation

Guilherme Alves Lepski

07 August 2007

Introdução. O transplante de células é possibilidade terapêutica promissora para muitas doenças neurológicas. Nos últimos anos, a possibilidade do isolamento de células-tronco dos tecidos adultos, por exemplo da medula-óssea, atrai a atenção da comunidade científica, estratégia que minimiza os problemas éticos relativos ao uso de tecido fetal para implantes visando ao tratamento de doenças neurológicas. Entretanto, a eficiência da transdiferenciação de células-tronco mesenquimais em neurônios, bem como os mecanismos envolvidos nesse processo, permanecem desconhecidos. A obtenção de neurônios maduros ocorreu somente em sistemas de co-cultura, o que induz a questão se a diferenciação representa um potencial das células per si, ou se é possível somente devido à fusão com neurônios maduros. Objetivos. No presente trabalho, pretendeu-se verificar o potencial de as células-tronco mesenquimais tornarem-se neurônios e esclarecer os possíveis mecanismos envolvidos nesse processo. Material e métodos. Células-tronco mesenquimais foram isoladas de 20 doadores voluntários normais e caracterizadas por análise de separação celular ativada por fluorescência. A multipotencialidade foi investigada ao se diferenciar as células em condrócitos e osteócitos. A capacidade de auto-renovação foi confirmada pelo ensaio de incorporação de BrdU. Ulteriormente, as células foram diferenciadas por uma semana em meio contendo AMPc, IBMX, ou combinação de ambos, e os resultados foram comparados com o cultivo em meio básico. Diferentes bloqueadores de Ca2+ ou inibidores de PKA foram usados como tentativa de se impedir a diferenciação, ocorrência que foi mensurada com imunocitoquímica para NF-200 (marcador de neurônios maduros). O registro eletrofisiológico por meio de patch clamp foi usado para se confirmar o fenótipo neuronal. As figuras foram configuradas em microscopia confocal. Para análise estatística foi utilizada ANOVA com teste post-hoc. Resultados. As células isoladas expressaram CD90, 105, 44 e 13 mas foram negativas para CD34 e 45. Isto significa que não são de origem hematopoiética; 98,74 ± 0,43% das células incorporaram BrdU em 24 horas. Após o isolamento, foi possível diferenciá-las em condrócitos ou osteócitos. Em situação controle, não foram evidenciadas células positivas para NF200. Por outro lado, ocorreu positividade em 10,75% ± 1,35 (p<0,0001) das células sob IBMX e, em 15,18% ± 1,12, sob a combinação cAMP e IBMX (p<0,0001). Foram registradas correntes de Na+ e K+ dependentes de voltagem, mas não potenciais de ação. A diferenciação foi inibida com PKAi (5,73% ± 0,42, p<0,0001), nifedipina (5,79% ± 0,98, p<0,0001), Ni2+ (7,06% ± 1,68, p<0,0001) e Cd2+ (0 ± 0, p<0,0001). Discussão. Isolou-se uma população de células-tronco estromais da medula-óssea de seres humanos que se mostrou multipotencial e auto-renovável. O aumento da concentração de AMPc no meio elevou a concentração de neurônios para 15%. A diferenciação parece depender da via PKA mas também envolve a concentração intracelular de Ca2+. Conclusão. O correto entendimento de como as células-tronco mesenquimais diferenciam-se pode contribuir para aumentar a eficácia do método e, talvez um dia, tornar possível o uso dessa ferramenta no campo clínico. / Introduction. Cell transplantation has been considered a promising therapeutic approach for many neurological diseases. The possibility of isolation of stem cells from adult tissues, i.e. bone marrow, has attracted the attention of the scientific community in the recent years. This strategy is interesting on avoiding the ethical issues regarding the use of fetal tissue for neural implants. Moreover, the efficiency of the transdifferentiation of mesenchymal stem cells (MSCs) into neurons, and the mechanisms involved in this process remain largely unknown. The obtention of mature neurons was described only in coculture systems, what raised the question if the differentiation is a potential of the cells itself, or if it is possible only due to fusion with mature neurons. Objectives. In the present investigation, we aimed to verify the potential of MSCs to differentiate into neurons, and also to clarify the possible mechanisms involved on it. Material and methods. MSCs were isolated from 20 healthy human subjects and characterized by FACS-analysis. Multipotentiality was addressed by differentiating them into chondrocytes and osteocytes. The self-renewal capacity was confirmed with BrdU-incorporation assay. Afterwards, cells were differentiated for 1 week in a medium containing cAMP, IBMX, or a combination of both, and the results were compared with cells treated in basal-medium condition. Different Ca2+-blockers and PKA-inhibitor peptide were used on an attempt to impair differentiation, which was quantified with NF-200 immunostaining (a marker of mature neurons). Patch-clamp recording was used to confirm neuronal phenotype. Pictures were taken in confocal microscope. For statistical analysis ANOVA with a post-hoc test was used. Results. The isolated cells expressed CD90, 105, 44, and 13, but were negative for CD34 and 45, meaning that they were non-hematopoiethic; 98.74 ± 0.43 % of them incorporated BrdU in 6hs. After isolation, they differentiated into chondrocytes and osteocytes. In a control situation, no NF200 positive cell was seen. On the other hand, 10.75% ± 1.35 (p<.0001) of positivity was seen under IBMX and 15.18% ± 1.12 in the combination of cAMP with IBMX (p<.0001). Na+ and K+-voltage gated currents were recorded. Differentiation was impaired with PKAi (5.73% ± 0.42, p<.0001), nifedipin (5.79% ± 0.98, p<.0001), Ni2+ (7.06% ± 1.68, p<.0001), and Cd2+ (0 ± 0, p<.0001). Discussion. We were able to isolate a population of stromal stem cells from the bone marrow of human subjects, since they were multipotential and self-renewable. Increasing the concentration of cAMP raised the percentage of neurons up to 15%. The differentiation seems to be dependent on the PKA pathway, but also involved the intracellular concentration of Ca2+. Conclusions. The complete understanding of how MSC differentiate can contribute to increase the efficiency of the method and thus make possible to use this powerful tool in the clinical practice.

Células-tronco adultas

Doenças neurodegenerativas

Microscopia de fluorescência

Técnicas de Patch Clamp.

Adult stem cells

Mesenchymal stem cell transplantation

Neurodegenerative diseases

Mathematical modeling of the regulation, development and genetically engineered experimental models of cardiac excitation-contraction coupling

Korhonen, T. (Topi)

24 March 2009

Abstract Excitation-contraction coupling (ECC) is a process linking the electrical excitation of the muscle cell (myocyte) membrane to the contraction of the cell. In this study the possibilities of mathematical modeling were studied in current ECC research. Mathematical modeling was employed in two distinct ECC research areas, the enzymatic regulation of ECC and ECC during cardiac myocyte development. Despite the distinction, both of these are extremely complex biological systems characterized by diverse and partly contradictory reported experimental results, with a large part based on genetically engineered animal models. Novel mathematical models were developed for both of these research areas. The model of ventricular myocyte ECC with calmodulin-dependent protein kinase II (CaMKII)-mediated regulation faithfully reproduced the heart-rate dependent regulation of ECC. This regulation is thought to be the major effect of CaMKII-mediated regulation. The model of the embryonic ventricular myocyte provided the first comprehensive system analysis of how the embryonic heartbeat is generated at the cellular level. A similar type of model was also developed to show the notable differences between neonatal and adult ventricular myocyte ECC. The mathematical models of ECC presented in this study were further used to simulate ECC in genetically engineered myocytes. The cellular mechanisms of genetically engineered animal models could be better understood by employing mathematical modeling in parallel to experimental characterization of the animal model. It was found in simulations that the indirect consequences and the compensatory mechanisms induced by genetic modification may have a more significant effect on ECC than the direct consequences of the modification. To understand the overwhelming complexity of biological systems including ECC, competent system analysis tools, such as mathematical modeling, are required. The purpose of mathematical modeling is not to replace the experimental studies, but to provide a more comprehensive system analysis based on the experimental data. This system analysis will help in planning subsequent experiments needed to gain the most relevant information about the studied biological system.

action potentials

calcium

cardiac myocytes

computer simulation

confocal microscopy

embryonic development

genetic engineering

ion channels

patch-clamp techniques

signal transduction

systems biology

Mechanisms of O2-Chemosensitivity in Adrenal Medullary Chromaffin Cells from the Developing Rat and Mouse / Mechanisms of O2-Chemosensitivity in Developing Chromaffin Cells

Thompson, Roger J.

06 1900

The mammalian adrenal gland (or suprarenal gland) is a small organ located on the superior aspect of the kidney. The central region of the gland, the medulla, consists of chromaffin cells, which release catecholamines into the blood during periods of stress. This is best known as the 'fight or flight' response and is regulated, in the adult animal, by neuronal signals from the cholinergic sympathetic fibres of the splanchnic nerve. Interestingly, in some mammals, such as rat and human, sympathetic innervation is immature at birth, yet the chromaffin cells can still secrete catecholamines in response to physiological stessors, e.g. hypoxia. Increased plasma catecholamines is thought to provide a vital protective role for the neonatal animal during, and following birth. This is mediated in part by promoting lung fluid absorption, surfactant secretion, heart rate stabilization, and brown fat mobilization. The observation that, in the neonate, catecholamines are secreted in the absence of functional sympathetic innervation suggests that the chromaffin cells possess other mechanisms for directly 'sensing' a fall in blood O2 tension (hypoxia). The primary goal of this thesis was to uncover the mechanisms of oxygen-sensing in developing chromaffin cells from the rat and mouse, using primary short-term cell cultures of chromaffin cells. The experimental approaches relied on patch clamp techniques to record ionic currents and membrane potential, carbon fibre electrochemistry to record catecholamine secretion from cell clusters, and fluorescent indicators to measure reactive oxygen species generation. Hypoxic chemosensitivity was found in embryonic and neonatal, but not juvenile chromaffin cells from both the rat and mouse. Exposure to hypoxia or anoxia caused a reversible suppression of whole-cell current, which was comprised of the differential modulation of three K+ currents: (1) suppression of a large-conductance Ca2+-dependent K+ current; (2) suppression of a delayed rectifier K+ current; and (3) activation of an ATP-sensitive K+ current. Hypoxia also induced membrane depolarization that was not initiated by any of these three voltage-dependent K+ currents. Additionally, hypoxia broadened action potentials in chromaffin cells that showed spontaneous activity, and this was mediated by a prolongation of the time course of membrane repolarization. All of these factors likely contribute to catecholamine secretion by enhancing the influx of Ca2+ through depolarization-activated L-type Ca2+ channels. Two sets of experiments were designed to identify the oxygen sensor in neonatal chromaffin cells. First, cells from transgenic mice, deficient in the gp91^phox component of the putative O2-sensor protein, NADPH oxidase, responded to hypoxia in the same way as wild type cell, indicating that NADPH oxidase is not primarily responsible for oxygen sensitivity in these cells. Second, inhibitors of the proximal electron transport chain (e.g. rotenone and antimycin A) mimicked and attenuated the hypoxic response, while inhibitors of the distal electron transport chain (cyanide) and uncouplers of oxidative phosphorylation (2,4-dinitrophenol) had no effect. Furthermore, reactive oxygen species production, primarily H2O2, decreased during exposure to hypoxia or inhibitors of the proximal electron transport chain, revealing a potential mitochondrial mechanism for 'sensing' of the hypoxic stimulus. Reduced oxygen availability to the electron transport chain is proposed to cause a fall in cellular reactive oxygen species (ROS), principally H2O2. This fall in ROS signals closure of Ca2+-dependent and Ca2+-independent K+ channels, which causes broadening action potentials and increases Ca2+ influx. The latter is further enhanced by the hypoxia-induced membrane depolarization, which in turn increases the probability of cell firing. The rise in intracellular Ca2+ then acts as the signal for catecholamine release from the chromaffin cells. / Thesis / Doctor of Philosophy (PhD)

suprarenal gland

adrenal gland

mammal

chromaffin cells

catecholamines

hypoxia

patch clamp techniques

carbon fibre electrochemistry

hypoxic chemosensitivity

rat

mouse

embryo

neonatal

anoxia

SUMOylation and phosphorylation of GluK2 regulate kainate receptor trafficking and synaptic plasticity

Chamberlain, S.E., Gonzàlez-Gonzàlez, I.M., Wilkinson, K.A., Konopacki, F.A., Kantamneni, Sriharsha, Henley, J.M., Mellor, J.R.

January 2012

No / Phosphorylation or SUMOylation of the kainate receptor (KAR) subunit GluK2 have both individually been shown to regulate KAR surface expression. However, it is unknown whether phosphorylation and SUMOylation of GluK2 are important for activity-dependent KAR synaptic plasticity. We found that protein kinase C-mediated phosphorylation of GluK2 at serine 868 promotes GluK2 SUMOylation at lysine 886 and that both of these events are necessary for the internalization of GluK2-containing KARs that occurs during long-term depression of KAR-mediated synaptic transmission at rat hippocampal mossy fiber synapses. Conversely, phosphorylation of GluK2 at serine 868 in the absence of SUMOylation led to an increase in KAR surface expression by facilitating receptor recycling between endosomal compartments and the plasma membrane. Our results suggest a role for the dynamic control of synaptic SUMOylation in the regulation of KAR synaptic transmission and plasticity.

Animals

Excitatory postsynaptic potentials

HEK293 cells

Humans

Mossy fibers

Neuronal plasticity

Organ culture techniques

Patch-clamp techniques

Phosphorylation

Protein transport

Rats

Wistar

Receptors

Kainic acid

Sumoylation

Synaptic transmission

Transfection

REF 2014

Functional properties and Ca2+-dependent feedback modulation of voltage-gated Ca2+ channels in glutamatergic nerve terminals of the mammalian auditory brainstem / Funktionelle Eigenschaften und Ca2+-abhängige 'feedback'-Regulation spannungsaktivierter Ca2+-Kanäle in glutamatergen Nervterminalien des auditorischen Stammhirns der Säugetiere

Lin, Kun-Han

08 April 2011

No description available.

570 Biowissenschaften, Biologie

Biology (incl. Psychology)

Elektrophysiologie

Patch-Clamp Techniken

Heldschen Calyces

Heldschen Endbulbs

Electrophysiology

Patch-Clamp Techniques

voltage-gated Ca2+-Channels

Calyx of Held

Endbulb of Held

42.12

42.17