The physiological roles of the vacuolar proton-pumping pyrophosphatase

Darley, Catherine P.

January 1997

No description available.

572

Single-channel recordings of potassium channels from guinea-pig inner hair cells

Appenrodt, Peter

January 1997

No description available.

571.4

Production and characterisation of conditionally immortal cystic fibrosis cell lines

Thomas, Emma J.

January 2000

No description available.

615.1

Alterations of the Monoaminergic Systems in the Rat Brain by Sustained Administration of Carisbamate and Lamotrigine

Shim, Stacey

01 November 2012

Carisbamate (CRS) and lamotrigine (LTG) are anticonvulsants which act mainly on neuronal voltage-gated sodium channels, that have been shown to have antidepressant-like effects in animal models of depression. In vivo electrophysiological recordings were carried out following 2 and 14 days of CRS or LTG administration. Overall firing activity in the dorsal raphe, locus coeruleus and ventral tegmental area were decreased with CRS. Similarly, a decrease in the dorsal raphe was also observed with LTG. Despite these presynaptic decreases in firing activity, both anticonvulsants exhibited significant enhancement of serotonergic transmission in the hippocampus as demonstrated by increased tonic activation of postsynaptic 5-HT1A receptors. This may be attributed to the observed desensitization of the terminal 5-HT1B autoreceptors. This study suggests that the enhanced serotonergic effect may be associated with an antiglutamatergic effect, and may contribute to the antidepressant-like effect of CRS in the forced swim test and the antidepressant properties of LTG.

anticonvulsants

in vivo electrophysiology

major depressive disorder

Patch-clamp studies of single type-1 Ins(1,4,5)P3 receptor channels

Dargan, Sheila Louise

January 2001

No description available.

572

Étude électrophysiologique de la mémoire visuelle à court terme

Perron, Rosalie

January 2008

Mémoire numérisé par la Division de la gestion de documents et des archives de l'Université de Montréal.

N2pc

Électrophysiologie

Electrophysiology

Attention

Mémoire

Memory

SPCN

Electrophysiological Analysis in an Animal Model of Dystonia

Chaniary, Kunal

23 April 2010

Dystonia is a movement disorder characterized by patterned, repetitive, and sustained muscle contractions that cause ineffective and often painful movements. The overall goal of this project was to understand the physiological mechanisms of dystonia in a rodent model as a basis for developing innovative treatments for secondary dystonias. The first half of the project was focused at developing essential techniques for systematically investigating the movement disorder in these animals. For achieving this, an innovative, multi-faceted approach was pursued starting with electromyographic (EMG) analysis for animal model validation, gait analysis for dystonia quantification, and development of a novel stereotaxic apparatus for recording brain activity during awake conditions. The later half of the project was focused on understanding how brain circuitry produces abnormal motor control in dystonia. Single and multi-unit neuronal activity was collected from individual basal ganglia nuclei along with EMG recordings to characterize the abnormal patterns of firing in dystonic animals and determine how neurons within individual nuclei communicate in dystonia, respectively. The findings of the current project have lead to new insights into the pathophysiology and treatment of secondary kernicteric dystonia and other secondary dystonia in humans.

dystonia

electrophysiology

Engineering

Neuroelectronic and Nanophotonic Devices Based on Nanocoaxial Arrays

Naughton, Jeffrey R.

January 2017

Thesis advisor: Michael J. Naughton / Thesis advisor: Michael J. Burns / Recent progress in the study of the brain has been greatly facilitated by the development of new measurement tools capable of minimally-invasive, robust coupling to neuronal assemblies. Two prominent examples are the microelectrode array, which enables electrical signals from large numbers of neurons to be detected and spatiotemporally correlated, and optogenetics, which enables the electrical activity of cells to be controlled with light. In the former case, high spatial density is desirable but, as electrode arrays evolve toward higher density and thus smaller pitch, electrical crosstalk increases. In the latter, finer control over light input is desirable, to enable improved studies of neuroelectronic pathways emanating from specific cell stimulation. Herein, we introduce a coaxial electrode architecture that is uniquely suited to address these issues, as it can simultaneously be utilized as an optical waveguide and a shielded electrode in dense arrays. / Thesis (PhD) — Boston College, 2017. / Submitted to: Boston College. Graduate School of Arts and Sciences. / Discipline: Physics.

electrophysiology

Microelectrode array

nanofabrication

nanotechnology

photonics

Palmitoylation of large conductance voltage- and calcium-dependent potassium (BK) channels

Bi, Danlei

January 2014

S-palmitoylation is a reversible post-translational lipid modification of proteins by adding a 16-carbon palmitate onto a cysteine residue. Palmitoylation has been shown to control the trafficking and function of many signalling proteins including ion channels. In this Thesis, palmitoylation is shown to control both the plasma membrane expression and gating properties of large conductance calcium- and voltage- dependent potassium (BK) channels. The BK channel is assembled from four pore-forming α-subunits. Each α-subunit contains seven transmembrane domains (S0-S6), with an extracellular N-terminus and a large intracellular C-terminus. BK channel α-subunit is encoded by a single gene Kcnma1 that undergoes extensive pre mRNA splicing at various splice sites, thus there are a number of alternatively spliced variants of α-subunits. Using quantitative imaging assays, palmitoylation of the intracellular S0-S1 loop controlled trafficking of full length ZERO variant BK channels to the plasma membrane in HEK293 cells as well as neuronal N2a cells. Importantly, all four α-subunits need to be palmitoylated for robust surface expression. Thus, palmitoylation of the S0-S1 loop of the α-subunit is important for surface expression of BK channels. The BK channel may also assemble with auxiliary β-subunits (β1-4) that regulate surface expression and gating properties of BK channels. The N-terminus of the β1- subunit and the C-terminus of the β4-subunit were shown to be palmitoylated using [3H]-palmitate incorporation, respectively. However, mutation of the palmitoylated cysteine (C18 in β1 and C193 in β4) to alanine to generate depalmitoylated β- subunits had no significant effects on the electrophysiological properties resulting from co-expression with the ZERO variant of the BK channel. However, although palmitoylation of the S0-S1 loop does not affect the electrophysiological properties of the ZERO channels alone, it is important for the shift in the V0.5max of ZERO channel when co-expressed with the β1-subunit, but not β4-subunit. These data suggest that palmitoylation of the S0-S1 loop controls the functional coupling between the ZERO α-subunit and β1-subunit. Although palmitoylation of C18 in the N-terminus of the β1-subunit was not required for functional coupling to α-subunits, we identified other critical residues within the short intracellular N-terminus of the β1-subunit that are essential. The functional coupling between BK α- and β1-subunit was predicted to be controlled by the interaction between a non-classic amphipathic α-helix in the β1 subunit N-terminus and the plasma membrane. Deletion, or mutations predicted to disrupt the interaction significantly decreased the β1-subunit induced left shift in the BK channel V0.5max. This suggests that the amphipathic in-plane anchor is critical for functional coupling of β1-subunits with BK channel α-subunits. In this Thesis, we demonstrated: i) palmitoylation of the α-subunit S0-S1 loop controls surface membrane expression of BK channels, and also controls functional regulation by β1, but not β4-subunits; and ii) a potential non-classical amphipathic in-plane anchor in the β1 N-terminus is essential for functional coupling with α- subunits. These studies help us further understand the regulation of BK channels and suggest potential therapeutic targets for various diseases related to dysfunctional BK channels, such as hypertension.

572

An invermectin sensitive ion channel from haemonchus contortus

McCavera, Samantha J. C.

January 2008

The avermectins (ivermectin, doramectin etc) and milbemycins are effective anthelmintics used widely in animal and human medicine for the past twenty years. The actual site of action of the avermectins on the GluCl is unclear, but binding studies have concluded that it does not share a binding site with glutamate. The GluCl channels have been well characterised in Caenorhabditis elegans and are beginning to be characterised in parasitic nematode species such as Haemonchus contortus, Dirofilaria immitis and Cooperia oncophora. The aim of this project was to characterise the H. contortus GluClα3B subunit and its interactions with agonists, glutamate and ivermectin using electrophysiology to study Xenopus oocytes expressing GluClα3B homomeric channels and ligand binding studies on COS-7 cells expressing the subunits. Site–directed mutagenesis was used to introduce resistance associated candidate polymorphisms into the H. contortus GluClα3B subunit. The effects of these changes on the response to glutamate and ivermectin were assessed. One mutation found in IVR C. oncophora, L256F, confers a 3-fold loss of sensitivity to glutamate and a 6.5 fold loss of sensitivity to IVM. This mutation is found in the C-terminal area of the extracellular region of the channel and, from homology modelling, we know it lies in close proximity and possibly interferes with another candidate mutation V235A, and the Cysteine residue at position 192 which forms one side of the structurally significant disulphide bridge. Further introduction of different mutations at this position showed the larger the substituted amino acid, the greater the effect on IVM sensitivity. Another amino acid substitution (T300S) results in the prohibition of a functional channel. The protein is produced and is able to bind IVM with high affinity but does not create a functional channel. These data show that polymorphisms found in field isolates of parasites can have a significant effect on GluCl channels and may contribute to drug resistance.

572