Global ETD Search

131	Evaluation of isolated dorsal root ganglion cells as a model to study neural calcium overload / E.E. Jordaan Jordaan, Esaias Engelbertus January 2004 (has links) Background and motivation: The event of neural Ca2+ overload is known to have several deleterious effects resulting in cell death caused by ischaemia, hypoglycaemia, hypoxia and several neurodegenerative diseases such as Alzheimer's disease, Parkinson's disease and AIDS-related dementia. In vitro models for the investigation of the mechanisms involved in Ca2+ overload include brain slice preparations, neuronal cultures as well as acutely isolated neurons, mostly from the hippocampus and cortical brain areas. Additional models for investigating Ca2+ overload may bring about new knowledge to areas of the phenomenon that are still unresolved. Methodology: In this study, several theoretical Ca2+ overload-related interventions were combined aimed at inducing cell death in acutely isolated rat dorsal root ganglia. To elucidate the mechanism/s involved in the cell death observed following exposure to this intervention, the effects of several alterations to the intervention's composition were assessed. This examination was extended by the addition of several recognized and potential protective compounds to the intervention. Cell death was indicated by the trypan blue exclusion assay and recorded after 18 hours exposure to the interventions by counting live and dead neurons under a light microscope. Results and conclusions: The goal was to evaluate the possible application of dorsal root ganglia as a model for neural Ca2+ overload outside the brain. Since Ca2+w as required for cell death to be induced, it is concluded that the observed cell death was indeed primarily due to Ca2+ overload. Besides extracellular Ca2+, KC1-induced depolarization was also required for cell death to be induced, while the antagonists did not demonstrate significant protection against cell death. Based on the results, the mechanism of Ca2+ overload could not be defined beyond doubt, but the voltage activated Ca2+ channels are likely to be involved. / Thesis (M.Sc. (Physiology))--North-West University, Potchefstroom Campus, 2005. Glutamate excitotoxicity Model Dorsal root ganglia Viability Trypan blue NMDAR channels.
132	A Novel Role for Calpain 4 in Podosome Assembly Dowler, THOMAS 27 September 2008 (has links) Podosomes are adhesive and invasive structures which may play an important role in numerous physiological and pathological conditions including angiogenesis, atherosclerosis, and cancer metastasis. Recently, the cysteine protease m-calpain (m-Capn) has been shown to cleave cortactin, an integral component of the podosomal F-actin core, as well as various proteins found in the peripheral adhesive region leading to the disassembly of these dynamic structures. In this study, I investigated whether Capn plays a role in the formation of podosomes downstream of c-Src. I show that: 1) phorbol-12, 13-dibutyrate (PDBu) as well as c-Src-Y527F expression induces podosome formation in mouse embryonic fibroblasts; 2) PDBu- and constitutively active c-Src-induced podosome formation is inhibited by the knockout of the m- and µ-Capn small regulatory subunit Capn4 in mouse embryonic fibroblasts (Capn4-/-), but is partially restored by re-expression of Capn4; 3) Capn4 localizes to podosomes; and 4) Inhibition of m- and µ-Capn proteolytic activity by the cell permeable calpain inhibitors has little effect on the formation of podosomes downstream of active c-Src. I conclude that Capn4 may play a role in the assembly phase of podosomes independent of calpain proteolytic activity. Work done in collaboration to determine a possible mechanism of action for the role of Capn4 in podosome assembly indicates that a possible binding partner of Capn4, β-PIX, co-localizes with, and shows in vivo association with Capn4. Furthermore, β-PIX and Capn4 bind directly in vitro in the presence of Ca2+. We conclude that Capn4 plays a role in podosome assembly, and this role may be through direct interaction with β-PIX in a calcium-dependent manner. / Thesis (Master, Biochemistry) -- Queen's University, 2008-09-26 16:16:00.768 Calpain 4 Calpain Src Podosomes Podosome assembly Mouse embryonic fibroblast Dorsal ruffles PIX
133	p53 Regulates the Formation of Lamellipodia and Circular Dorsal Ruffles Through Caldesmon and PTEN VANDENBERG, Laura Joanna 14 June 2011 (has links) Vascular smooth muscle cell migration is a significant contributor to many aspects of heart disease, and specifically atherosclerosis. Tissue damage in the arteries can result in the formation of a fatty streak. Smooth muscle cells (SMC) can then migrate to this site to form a fibrous cap, stabilizing the fatty plaque. Since cardiovascular disease is the leading cause of death in developed countries, this function of SMC is an essential area of study. The formation of lamellipodia and circular dorsal ruffles were studied in this project as indicators that cell migration is occurring. The roles of the proteins p53, Rac, caldesmon and PTEN were investigated with regards to these actin-based structures. The tumour suppressor p53 is often reported to cause apoptosis, senescence or cell cycle arrest when stress is placed on a cell, but has recently been shown to regulate cell migration as well. It was determined in this project that p53 could inhibit the formation of both lamellipodia and circular dorsal ruffles. It was also shown that this could occur directly through an inhibition of the GTPase Rac. Previous studies have shown that p53 can upregulate caldesmon, a protein which is known to bind to and stabilize actin filaments while inhibiting Arp2/3-mediated branching. It was confirmed that p53 could upregulate caldesmon, and that caldesmon could inhibit the formation of lamellipodia and circular dorsal ruffles. The phosphorylation of caldesmon by p21-associated kinase (PAK) or extracellular signal-related kinase (Erk) was shown to effectively reverse the ability of caldesmon to inhibit these structures. The role of phosphatase and tensin homologue deleted on chromosome 10 (PTEN) was also studied with regards to this signalling pathway. PTEN was shown to inhibit lamellipodia and circular dorsal ruffles through its lipid phosphatase activity. It was concluded that p53 can inhibit the formation of lamellipodia and circular dorsal ruffles in vascular SMC, and that this occurs through Rac, caldesmon and PTEN. / Thesis (Master, Biochemistry) -- Queen's University, 2011-06-10 13:15:37.081 p53 caldesmon PTEN lamellipodia circular dorsal ruffles cell migration Rac Erk PAK
134	Rôle de l'habenula dans le circuit neuronal de l'autostimulation intracérébrale Morissette, Marie-Claude January 2007 (has links) Mémoire numérisé par la Division de la gestion de documents et des archives de l'Université de Montréal Autostimulation intracérébrale Habenula Aire tegmentaire ventrale Hypothalamus latéral Raphé médian Raphé dorsal
135	NMDA RECEPTORS IN THE DORSAL VAGAL COMPLEX OF NORMAL AND DIABETIC MICE Bach, Eva C 01 January 2013 (has links) The dorsal vagal complex (DVC), containing the nucleus of the solitary tract (NTS) and the dorsal motor nucleus of the vagus nerve (DMV), plays a pivotal role in autonomic regulation. Afferent fibers from peripheral organs and higher brain centers synapse in the NTS, which integrates these synaptic connections as well as information from systemically circulating hormones and metabolites. The integrated information is relayed to the dorsal motor nucleus of the vagus nerve (DMV), which in turn, projects motor fibers to elicit parasympathetic control of digestive and other viscera. Physiological functions mediated by the DVC are disrupted in diabetic patients and synaptic plasticity within the DVC has been linked to these complications. N-methyl-D-aspartic acid (NMDA) receptors have been extensively studied for their involvement in synaptic plasticity in a variety of central nervous system disorders; and their activation in the DVC modulates hepatic glucose production and feeding behavior. Although chronic disease can alter NMDA function, changes in DVC expression and/or sensitivity of NMDA receptors in diabetic states has not been addressed. Using whole cell electrophysiology, functional properties of the nuclei in the DVC were investigated in normoglycemic and type 1 diabetic mice. Preterminal NMDA (preNMDA) receptors were discovered to tonically modulate excitatory neurotransmission on terminals contacting DMV neurons. While these preNMDA receptors were not found to differentially modulate tonic excitatory neurotranmission, soma-dendritic NMDA receptor responses of NTS neurons were augmented in type 1 diabetic mice. Through the use single-cell PCR, increased NMDA receptor responses could be correlated to neurons that mediate excitatory neurotransmission and would argue that augmented NMDA receptor responses increase vagal output. In general, enhancing vagal output decreases activity of connected peripheral organs. Molecular approaches were employed to corroborate the observed functional NMDA receptors changes to their protein and mRNA expression levels. Overall, results argue that NMDA receptors are involved in synaptic plasticity in DVC of type 1 diabetic mice to enhance excitatory neurotransmission. This modulation may potentially serve as a physiological counter regulatory mechanism to control pathological disturbances of gastrointestinal homeostatic reflex responses. NMDA Dorsal Vagal Complex Electrophysiology Type 1 diabetes Synaptic Plasticity Medicine and Health Sciences Neuroscience and Neurobiology Physiology
136	The Role of Substrate Stiffness on the Dynamics of Actin Rich Structures and Cell Behavior Zeng, Yukai 01 November 2014 (has links) Cell-substrate interactions influence various cellular processes such as morphology, motility, proliferation and differentiation. Actin dynamics within cells have been shown to be influenced by substrate stiffness, as NIH 3T3 fibroblasts grown on stiffer substrates tend to exhibit more prominent actin stress fiber formation. Circular dorsal ruffles (CDRs) are transient actin-rich ring-like structures within cells, induced by various growth factors, such as the platelet-derived growth factor (PDGF). CDRs grow and shrink in size after cells are stimulated with PDGF, eventually disappearing ten of minutes after stimulation. As substrate stiffness affect actin structures and cell motility, and CDRs are actin structures which have been previously linked to cell motility and macropinocytosis, the role of substrate stiffness on the properties of CDRs in NIH 3T3 fibroblasts and how they proceed to affect cell behavior is investigated. Cells were seeded on Poly-dimethylsiloxane (PDMS) substrates of various stiffnesses and stimulated with PDGF to induce CDR formation. It was found that an increase in substrate stiffness increases the lifetime of CDRs, but did not affect their size. A mathematical model of the signaling pathways involved in CDR formation is developed to provide insight into this lifetime and size dependence, and is linked to substrate stiffness via Rac-Rho antagonism. CDR formation did not affect the motility of cells seeded on 10 kPa stiff substrates, but is shown to increase localized lamellipodia formation in the cell via the diffusion of actin from the CDRs to the lamellipodia. To further probe the influence of cell-substrate interactions on cell behavior and actin dynamics, a two dimensional system which introduces a dynamically changing, reversible and localized substrate stiffness environment is constructed. Cells are seeded on top of thin PDMS nano-membranes, and are capable of feeling through the thin layer, experiencing the stiffness of the polyacrylamide substrates below the nano-membrane. The membranes are carefully re-transplanted on top of other polyacrylamide substrates with differing stiffnesses. This reversible dynamic stiffness system is a novel approach which would help in the investigation of the influence of reversible dynamic stiffness environments on cell morphology, motility, proliferation and differentiation in various cells types.
137	Evaluation of isolated dorsal root ganglion cells as a model to study neural calcium overload / E.E. Jordaan Jordaan, Esaias Engelbertus January 2004 (has links) Background and motivation: The event of neural Ca2+ overload is known to have several deleterious effects resulting in cell death caused by ischaemia, hypoglycaemia, hypoxia and several neurodegenerative diseases such as Alzheimer's disease, Parkinson's disease and AIDS-related dementia. In vitro models for the investigation of the mechanisms involved in Ca2+ overload include brain slice preparations, neuronal cultures as well as acutely isolated neurons, mostly from the hippocampus and cortical brain areas. Additional models for investigating Ca2+ overload may bring about new knowledge to areas of the phenomenon that are still unresolved. Methodology: In this study, several theoretical Ca2+ overload-related interventions were combined aimed at inducing cell death in acutely isolated rat dorsal root ganglia. To elucidate the mechanism/s involved in the cell death observed following exposure to this intervention, the effects of several alterations to the intervention's composition were assessed. This examination was extended by the addition of several recognized and potential protective compounds to the intervention. Cell death was indicated by the trypan blue exclusion assay and recorded after 18 hours exposure to the interventions by counting live and dead neurons under a light microscope. Results and conclusions: The goal was to evaluate the possible application of dorsal root ganglia as a model for neural Ca2+ overload outside the brain. Since Ca2+w as required for cell death to be induced, it is concluded that the observed cell death was indeed primarily due to Ca2+ overload. Besides extracellular Ca2+, KC1-induced depolarization was also required for cell death to be induced, while the antagonists did not demonstrate significant protection against cell death. Based on the results, the mechanism of Ca2+ overload could not be defined beyond doubt, but the voltage activated Ca2+ channels are likely to be involved. / Thesis (M.Sc. (Physiology))--North-West University, Potchefstroom Campus, 2005. Glutamate excitotoxicity Model Dorsal root ganglia Viability Trypan blue NMDAR channels.
138	The Role of Mechanically Gated Ion Channels in Dorsal Closure During Drosophila Morphogenesis Hunter, Ginger January 2012 (has links) <p>Physical forces play a key role in the morphogenesis of embryos. As cells and tissues change shape, grow, and migrate, they exert and respond to forces via mechanosensitive proteins and protein complexes. How the response to force is regulated is not completely understood. </p><p>Dorsal closure in Drosophila is a model system for studying cell sheet forces during morphogenesis. We demonstrate a role for mechanically gated ion channels (MGCs) in dorsal closure. Microinjection of GsMTx4 or GdCl<sub>3</sub>, inhibitors of MGCs, blocks closure in a dose-dependent manner. UV-mediated uncaging of intracellular Ca<super>2+</super> causes cell contraction whereas the reduction of extra- and intracellular Ca<super>2+</super> slows closure. Pharmacologically blocking MGCs leads to defects in force generation via failure of actomyosin structures during closure, and impairs the ability of tissues to regulate forces in response to laser microsurgery.</p><p>We identify three genes which encode candidate MGC subunits that play a role in dorsal closure, <italic>ripped pocket</italic>, <italic>dtrpA1</italic>, and <italic>nompC</italic>. We find that knockdown of these channels either singly or in combination leads to defects in force generation and cell shapes during closure. </p><p>Our results reveal a key role for MGCs in closure, and suggest a mechanism for the coordination of force producing cell behaviors across the embryo.</p> / Dissertation Developmental biology Cellular biology actomyosin dorsal closure drosophila mechanically gated ion channels mechanotransduction
139	The Regulation of Neuronal Excitability and Nociception by Tonic GABAergic Inhibition Bonin, Robert 23 July 2013 (has links) The mammalian central nervous system maintains a delicate balance between neuronal excitation and inhibition. Conventional synaptic inhibition is mediated through the transient activity of postsynaptic γ-aminobutyric acid (GABA) at type A GABA (GABAA) receptors. A subset of GABAA receptors is also located outside of inhibitory synapses. These extrasynaptic receptors generate a tonic inhibitory conductance in response to low concentrations of extracellular GABA. Tonic inhibition broadly suppresses neuronal activity and regulates many vital processes such as sleep, consciousness and memory formation. This thesis examines the physiological effects of tonic inhibition at the cellular level and in the behaving animal. This thesis also explores whether gabapentin, a commonly used sedative, anxiolytic, and analgesic drug, enhances tonic GABAergic inhibition. I hypothesize that: (1) tonic GABAA receptor activity reduces the intrinsic excitability of neurons; (2) the activity of tonically active GABAA receptors in spinal pain pathways attenuates nociception; and (3) tonic inhibition can be upregulated by gabapentin. The results show that a tonic inhibitory current generated by α5 subunit-containing GABAA (α5GABAA) receptors reduces the excitability of hippocampal pyramidal neurons excitability by increasing the rheobase, but does not change the gain of action potential firing. A similar shunting inhibition is present in spinal cord lamina II neurons that is generated by δ subunit-containing GABAA receptors. The activity of these receptors in spinal nociceptive pathways reduces acute thermal nociception and may constrain central sensitization in a behavioural model of persistent pain. Finally, gabapentin increases a tonic inhibitory current in cultured hippocampal neurons independent from changes in the expression of α5GABAA receptors or in the concentration of GABAA receptor ligands. The results of this thesis demonstrate that tonically active GABAA receptors play an important role in the regulation of neuronal activity and nociception, and that tonic inhibition represents a novel target of therapeutic drugs. GABA neuronal excitability dorsal horn tonic inhibition nociception gabapentin 0317 0719
140	A Drosophila Winged-helix nude (Whn)-like transcription factor with essential functions throughout development Sugimura, Isamu, Adachi-Yamada, Takashi, Nishi, Yoshimi, Nishida, Yasuyoshi 06 1900 (has links) No description available. Forkhead HNF-3 development nude gene CNS PNS compound eye dorsal closure

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