Domain II (S5-P) region in Lymnaea T-type calcium channels and its role in determining biophysical properties, ion selectivity and drug sensitivity

Guan, Wendy

27 May 2015

Invertebrate T-type calcium channels cloned from the great pond snail, Lymnaea Stagnalis (LCav3) possess highly sodium permeant ion channel currents by means of alternative splicing of exon 12. Exon 12 is located on the extracellular turret and the descending helix between segments 5 and segments 6, upstream of the ion selectivity filter in Domain II. Highly-sodium permeant T-type channels are generated without altering the selectivity filter locus, the primary regulatory domain known to govern ion selectivity for calcium and sodium channels. Comparisons of exon 12 sequences between invertebrates and vertebrate T-type channels reveals a conserved pattern of cysteine residues. Calcium-selective mammalian T-type channels possess a single cysteine in exon 12 in comparison to invertebrate T-type channels with either a tri- or penta- cysteine framework. Cysteine residues in exon 12 were substituted with a neutral amino acid, alanine in LCav3 channels harbouring exon 12a and 12b to mimic the turret structure of vertebrate T-type channels. The results generated T-type channels that were even more sodium-permeable than the native T-type channels in snails. Furthermore, permeant divalent ions similar in structure to calcium (eg. barium) were unable to sufficiently block the monovalent ion current of channels lacking cysteines in Domain II, suggesting that the pore is highly sodium permeant, and has weak affinity and block by permeant divalent ions other than calcium. Besides ion selectivity, the cysteine mutated T-type channels were 10 to 100 fold more sensitive to inhibition by nickel and zinc, respectively. The cysteine mutation data highly suggests that the cysteines form an extracellular structure that regulates ion selectivity and shields T-type channels from block by nickel and zinc. In addition, we replaced exon 12 from the sodium permeant snail T-type channel with exon 12 from human Cav3.2 channels. The snail T-type channel with exon 12 from human T-type channels produced a T-type channel that was modestly sodium permeable, but did not confer the high calcium permeability of Cav3.2 channels. These findings suggest that the cysteine containing extracellular domains in exon 12 are not sufficient to generate calcium selective channels similar to human Cav3.2 and likely work in concert with other extracellular domains to regulate the calcium or sodium selectivity of T-type channels.

Analysis of Hippocampal Cell Proliferation, Survival, and Neuronal Morphology in P/Q-Type Voltage-Gated Calcium Channel Mutant Mice

Nigussie, Fikru

02 October 2013

Tottering and leaner mutant mice carry mutations in the pore-forming subunit (1A) of P/Q-type (CaV 2.1) voltage-gated calcium ion (Ca2+) channels that result in reduced Ca2+ current density. Since Ca2+ influx via voltage-dependent Ca2+ channels regulates important Ca2+-dependent neuronal processes including neurotransmitter release and synaptogenesis, we assessed effects of these mutations on hippocampus volume, neuronal density, neuronal morphology of hippocampal pyramidal cells in adult (six-month-old) mice, and adult neurogenesis in three-week-old and six-month-old mice. Hippocampal volume and neuronal density were assessed using hematoxylin and eosin stained serial sections. Neuronal morphology was assessed using Golgi-Cox staining as well as ultrastructural assessment using transmission electron microscopy. Adult hippocampal neurogenesis was assessed using standard 5-bromo-2’-deoxyuridine (BrdU) labeling with fluorescent immunohistochemistry (IHC) and proliferating cell nuclear antigen (PCNA) with diaminobenzidine IHC. To determine neuron and astrocyte survival, we used fluorescent double labeling for neurons with BrdU-neuronal nuclei IHC or astrocytes using BrdU-glial fibrillary acidic protein, respectively. Fluoro-Jade histochemistry was used to assess numbers of degenerating cells in the dentate gyrus subgranular zone. Decreased hippocampus volume was observed in tottering female mice and increased dentate hilar and CA1 cell density in mutant mice compared to wild type mice. Cell proliferation was increased in the hilus and combined CA3, CA2 and CA1 regions of mutant mice compared to wild type mice. Decreased total dendritic length and decreased number of dendritic intersections was observed in tottering mice compared to wild type mice. The decrease in dendritic arborization of tottering mice occurred at the concentric circles close to the neuronal cell body indicating that basal dendrites of CA1 pyramidal neurons are reduced. Taken together, P/Q-type voltage gated calcium channel mutation has age variable influence on adult hippocampal cell proliferation, and it altered neuronal morphology in terms of dendritic complexity in tottering mice, while the leaner mutation reduced mitochondrial density.

Tottering

Leaner

P/Q-type calcium channel

hippocampus,

Modulation of cardiac function by oxidized type I protein kinase A

Islam, M M Towhidul

15 December 2016

No description available.

610

PKA

Oxidation

L-type calcium channel

Heart failure

Arrhythmia

Calcium signaling

Medizin (PPN619874732)

Denitration in Colonic Smooth Muscle

Malick, Seemab

11 November 2009

Tyrosine nitration results in altered function of smooth muscle voltage-gated L-type calcium channel. We explored the possibility that smooth muscle contains denitrase activity to allow functional recovery of the calcium channel without requiring synthesis of new channel proteins. Following peroxynitrite treatment of mouse colonic smooth muscle strips, CaCl2 (1 mM)-induced smooth muscle contraction was significantly reduced by 67% (P ≤ 0.05), which reversed by approximately 86% upon periodic washing within 2 hr period (P ≤ 0.001). The effect of the c-Src kinase inhibitor, PP2, on muscle contraction was also restored after 2 hr post-peroxynitrite treatment consistent with the thesis that recovery from tyrosine nitration allows for tyrosine phosphorylation of the calcium channel. In addition, sodium orthovanadate prevented nitration-induced inhibition of muscle contraction by approximately 90%. Moreover, denitration of nitrated proteins was observed by western blots in smooth muscle cells over 2 hr. Since nitrotyrosine formation interferes with tyrosine kinase pathways involved in cell signaling, the presence of denitrase activity in smooth muscle cells may have profound and important effects in restoring the function of nitrated proteins involved in cell signaling processes.

L-type calcium channel

peroxynitrite

denitrase acitivity

Medical Pharmacology

Medical Sciences

Medicine and Health Sciences

The Role of Synaptically Evoked Plateau Potentials in Retinogeniculate Development

Dilger, Emily

01 January 2010

We study the activity-dependent refinement of sensory systems by using the mouse retinogeniculate system as a model. Spontaneous retinal waves lead to robust excitatory post-synaptic activity in developing relay cells in the dorsal lateral geniculate nucleus (dLGN) of the thalamus and are reportedly needed to help guide the segregation of retinal inputs into eye-specific domains as well as for the pruning of extraneous retinal inputs onto single dLGN relay cells. The composition of retinally evoked post-synaptic activity activated by these retinal waves in dLGN is largely unknown, but based on our in vitro recordings, such activity seems well suited to activate large, long-lasting, high-amplitude depolarizations mediated by L-type Ca2+ channel activation, plateau potentials. Plateau activity prevails early in life, at the peak of retinogeniculate refinement, however, little is known about the factors that contribute to the activation of these events, or the potential role of plateau potentials in mediating activity-dependent remodeling. In this thesis, we examined the factors and stimulus conditions that lead to the activation of plateau activity. We found that many aspects of developing retinogeniculatecircuitry (e.g., the high degree of retinal convergence, the temporal summation of excitatory post-synaptic potentials, and the lack of inhibitory connections) seem to favor their activation at early postnatal ages. We then tested whether such activity is necessary for the refinement of retinal projections, as well as their functional connections onto dLGN cells. To address this, we took a loss-of-function approach and made use of a transgenic mouse that lacks the β3 subunit of the L-type Ca2+ channel. These mutants have far fewer membrane-bound L-type Ca2+ channels and greatly attenuated L-type activity. In β3 nulls, L-type plateau potentials are rarely observed in the dLGN, even at young ages or when repetitive pulses of electrical stimulation are applied to the optic tract. Although these mice have normal stage II and III spontaneous retinal waves, the retinogeniculate projections of β3 null mice fail to segregate properly. In addition, the degree of retinal pruning is impaired. These results suggest that post-synaptic L-type Ca2+ channel activity is necessary to implement the activity-dependent refinement of the retinogeniculate pathway.

retinogeniculate development

L-type Ca channel

Medical Sciences

Medicine and Health Sciences

Neurosciences

Neurotransmission and functional synaptic plasticity in the rat medial preoptic nucleus

Malinina, Evgenya

January 2009

Brain function implies complex information processing in neuronal circuits, critically dependent on the molecular machinery that enables signal transmission across synaptic contacts between neurons. The types of ion channels and receptors in the neuronal membranes vary with neuron types and brain regions and determine whether neuronal responses will be excitatory or inhibitory and often allow for functional synaptic plasticity which is thought to be the basis for much of the adaptability of the nervous system and for our ability to learn and store memories. The present thesis is a study of synaptic transmission in the medial preoptic nucleus (MPN), a regulatory center for several homeostatic functions but with most clearly established roles in reproductive behaviour. The latter behaviour typically shows several distinct phases with dramatically varying neuronal impulse activity and is also subject to experience-dependent modifications. It seems likely that the synapses in the MPN contribute to the behaviour by means of activity-dependent functional plasticity. Synaptic transmission in the MPN, however, has not been extensively studied and is not well understood. The present work was initiated to clarify the synaptic properties in the MPN. The aim was to achieve a better understanding of the functional properties of the MPN, but also to obtain information on the functional roles of ion channel types for neurotransmission and its plastic properties in general. The studies were carried out using a brain slice preparation from rat as well as acutely isolated neurons with adhering nerve terminals. Presynaptic nerve fibres were stimulated electrically or, in a few cases, by raised external K+ concentration, and postsynaptic responses were recorded by tight-seal perforated-patch techniques, often combined with voltage-clamp control of the post-synaptic membrane potential. Glutamate receptors of α-amino-3-hydroxy-5-methyl-4-izoxazole propionic acid (AMPA) and N-methyl-D-aspartate (NMDA) types were identified as mediating the main excitatory synaptic signals and γ-aminobutyric acid (GABA)A receptors as mediating the main inhibitory signals. Both types of signals were suppressed by serotonin. The efficacy of AMPA-receptor-mediated transmission displayed several types of short-term plasticity, including paired-pulse potentiation and paired-pulse depression, depending on the stimulus rate and pattern. The observed plasticity was attributed to mainly presynaptic mechanisms. To clarify some of the presynaptic factors controlling synaptic efficacy, the role of presynaptic L-type Ca2+ channels, usually assumed not to directly control transmitter release, was investigated. The analysis showed that (i) L-type channels are present in GABA-containing presynaptic terminals on MPN neurons, (ii) that these channels provide a means for differential control of spontaneous and impulse-evoked GABA release and (iii) that this differential control is prominent during short-term synaptic plasticity. A model where Ca2+ influx through L-type channels may lead to reduced GABA release via effects on Ca2+-activated K+ channels, membrane potential and other Ca2+-channel types explains the observed findings. In addition, massive Ca2+ influx through L-type channels during high-frequency stimulation may contribute to increased GABA release during post-tetanic potentiation. In conclusion, the findings obtained in the present study indicate that complex neurotransmission mechanisms and different forms of synaptic plasticity contribute to the specific functional properties of the MPN.

medial preoptic nucleus

synaptic plasticity

GABA

glutamate

L-type Ca2+ channel

Physiology

Fysiologi

Ion currents regulated by acute and chronic osmotic stimuli in rat supraoptic nucleus neurons

Zhang, Wenbo

25 February 2009

The magnocellular neurosecretory cells (MNCs) of the hypothalamus are able to change their firing rate and pattern in response to small changes in external osmolality due to the involvement of osmosensitive ion channels. The firing rate and pattern determine the release of vasopressin (VP), a primary hormone regulating osmolality by controlling water excretion from the kidney. Both VP- and oxytocin (OT)-MNCs display irregular and infrequent fire when plasma osmolality is near normal, and they progressively increase the frequency of firing to fast continuous firing with increases in osmolality. VP-MNCs also respond to osmotic stimulation by adopting a phasic pattern of firing, which maximizes neuropeptide secretion. Sustained dehydration also causes structural and functional adaptations in MNCs.<p> Voltage-dependent Ca2+ channels play many important roles not only in the regulation of cell excitability but also in intracellular signal transduction, and L-type Ca2+ channel-mediated Ca2+ signals initiate intracellular signal transduction events that activate long-lasting changes in brain function and behavior. Our electrophysiological and immunocytochemical studies demonstrate that 16-24 h of water deprivation causes a significant increase in the amplitude of L-type Ca2+ current (from 55.5 ± 6.2 to 99.1 ± 10.0 pA) but not in other types of Ca2+ current. This increase occurred in both VP- and OT-MNCs. Such an increase in L-type Ca2+ current may contribute to modulation of firing rate and pattern, regulation of vasopressin release, structural adaptation in MNCs during sustained dehydration.<p> The mechanisms underlying the transition of the electrical behaviour are not completely understood. Ion channels, especially osmosensitive ion channels, play key roles in the modulation of MNC firing. A voltage-gated, 4-AP- and TEA-insensitive slowly activating outward current displayed a significant increase in about 66% of MNCs when the osmolality of the external solution was acutely increased from 295 to 325 mosmol kg-1. The responding cells showed an increase in net outward current from 12.3 ± 1.3 pA/pF to 21.4 ± 1.8 pA/pF. The reversal potential of this current was near the equilibrium for K+ and shifted with changes of K+ concentrations in external solution, suggesting that this current is a K+-selective current. The KCNQ/M current selective blockers linopirdine (150 µM) and XE991 (5 µM) suppressed this current. The IC50 of XE991 blockade was 3.9 ìM. The KCNQ/M channel openers retigabine (10 µM) and flupirtine (10 µM) significantly increased the current and shifted its activation curve toward more negative potentials. E4031, a specific blocker of ERG K+ channels, did not significantly block this current. The results from immunocytochemistry suggest that MNCs express KCNQ2, KCNQ3, KCNQ4, and KCNQ5, but not KCNQ1. These data suggest that this osmosensitive current could be a KCNQ/M current. Studies using single unit extracellular recording in hypothalamic explants showed that 10 µM XE991 increased MNC firing rate and that 20 µM retigabine decreased firing rate or caused a cessation of firing. These data suggest that a KCNQ/M current contributes to the regulation of MNC firing. KCNQ/M channels play key roles in regulating neuronal excitability in many types of central neurons. Slow activation of this current during firing might suppress activity by hyperpolarizing the cells and thus contribute to a transition between fast continuous and burst firing.<p> Our studies will be beneficial to understand the mechanisms that control VP and OT in response to acute changes in osmolality and also the mechanisms underlying MNC adaptation during sustained dehydration.

Osmosensitivity

Vasopressin

Supraoptic nucleus

L-type Ca2+ channel

KCNQ/M channel

Ion currents regulated by acute and chronic osmotic stimuli in rat supraoptic nucleus neurons

Zhang, Wenbo

25 February 2009

The magnocellular neurosecretory cells (MNCs) of the hypothalamus are able to change their firing rate and pattern in response to small changes in external osmolality due to the involvement of osmosensitive ion channels. The firing rate and pattern determine the release of vasopressin (VP), a primary hormone regulating osmolality by controlling water excretion from the kidney. Both VP- and oxytocin (OT)-MNCs display irregular and infrequent fire when plasma osmolality is near normal, and they progressively increase the frequency of firing to fast continuous firing with increases in osmolality. VP-MNCs also respond to osmotic stimulation by adopting a phasic pattern of firing, which maximizes neuropeptide secretion. Sustained dehydration also causes structural and functional adaptations in MNCs.<p> Voltage-dependent Ca2+ channels play many important roles not only in the regulation of cell excitability but also in intracellular signal transduction, and L-type Ca2+ channel-mediated Ca2+ signals initiate intracellular signal transduction events that activate long-lasting changes in brain function and behavior. Our electrophysiological and immunocytochemical studies demonstrate that 16-24 h of water deprivation causes a significant increase in the amplitude of L-type Ca2+ current (from 55.5 ± 6.2 to 99.1 ± 10.0 pA) but not in other types of Ca2+ current. This increase occurred in both VP- and OT-MNCs. Such an increase in L-type Ca2+ current may contribute to modulation of firing rate and pattern, regulation of vasopressin release, structural adaptation in MNCs during sustained dehydration.<p> The mechanisms underlying the transition of the electrical behaviour are not completely understood. Ion channels, especially osmosensitive ion channels, play key roles in the modulation of MNC firing. A voltage-gated, 4-AP- and TEA-insensitive slowly activating outward current displayed a significant increase in about 66% of MNCs when the osmolality of the external solution was acutely increased from 295 to 325 mosmol kg-1. The responding cells showed an increase in net outward current from 12.3 ± 1.3 pA/pF to 21.4 ± 1.8 pA/pF. The reversal potential of this current was near the equilibrium for K+ and shifted with changes of K+ concentrations in external solution, suggesting that this current is a K+-selective current. The KCNQ/M current selective blockers linopirdine (150 µM) and XE991 (5 µM) suppressed this current. The IC50 of XE991 blockade was 3.9 ìM. The KCNQ/M channel openers retigabine (10 µM) and flupirtine (10 µM) significantly increased the current and shifted its activation curve toward more negative potentials. E4031, a specific blocker of ERG K+ channels, did not significantly block this current. The results from immunocytochemistry suggest that MNCs express KCNQ2, KCNQ3, KCNQ4, and KCNQ5, but not KCNQ1. These data suggest that this osmosensitive current could be a KCNQ/M current. Studies using single unit extracellular recording in hypothalamic explants showed that 10 µM XE991 increased MNC firing rate and that 20 µM retigabine decreased firing rate or caused a cessation of firing. These data suggest that a KCNQ/M current contributes to the regulation of MNC firing. KCNQ/M channels play key roles in regulating neuronal excitability in many types of central neurons. Slow activation of this current during firing might suppress activity by hyperpolarizing the cells and thus contribute to a transition between fast continuous and burst firing.<p> Our studies will be beneficial to understand the mechanisms that control VP and OT in response to acute changes in osmolality and also the mechanisms underlying MNC adaptation during sustained dehydration.

Osmosensitivity

Vasopressin

Supraoptic nucleus

L-type Ca2+ channel

KCNQ/M channel

THE ROLE OF THE L-TYPE CALCIUM CHANNEL AND ITS CARBOXYL-TERMINUS

Byse, Miranda Jean

01 January 2010

In the heart, the primary role of the L-type calcium channel (LTCC) CaV1.2 is to conduct calcium into cardiomyocytes and initiate contraction. However, part of the CaV1.2 channel itself, the cleaved carboxyl-terminus (CCt) can also localize to the nucleus and regulate gene transcription. Therefore, the goal of this dissertation project was to determine the role and regulation of CCt in the embryonic and adult heart. The global hypothesis of my dissertation project is that CCt localizes to the nucleus in embryonic and adult cardiomyocytes via a calcium-mediated mechanism and regulates transcription. A model of pharmacological LTCC block-induced perturbation of murine embryonic heart development was first utilized to study the role of CCt. Pharmacological block at embryonic day 10 perturbed cardiogenesis and increased CaV1.2 expression. This result was not mimicked by removal of extracellular calcium or inhibition of calcium release from the sarcoplasmic reticulum. Co-currently, pharmacological block decreased CCt nuclear localization in embryonic cardiomyocytes. At the transcriptional level, CCt suppressed the CaV1.2 promoter. This indicated that the observed upregulation of CaV1.2 induced by pharmacological block may be caused by nuclear localization of the transcriptional repressor, CCt. Therefore, the conclusion was made that pharmacological LTCC block perturbed embryonic cardiogenesis by decreasing nuclear localization of the transcription factor CCt; implying a role for CCt in embryonic heart development. Next, CCt regulation was studied in the adult heart. Similar to the embryonic heart, pharmacological LTCC block decreased nuclear localization of CCt. Inhibition of the calcium activated phosphatase calcineurin also decreased CCt nuclear localization. To determine a role for CCt in the adult heart, CCt nuclear localization was measured in response to hypertrophic stimuli. Serum-induced cardiomyocyte hypertrophy significantly increased nuclear localization of CCt. In conclusion, this dissertation supports the hypothesis that CCt localizes to the nucleus in embryonic and adult cardiomyocytes, and that this regulation is mediated by calcium entry into the cardiomyocyte. Furthermore, data from this dissertation suggests that CCt nuclear localization may play an important role in embryonic heart development and adult cardiac hypertrophy.

L-type Calcium Channel

Calcium Channel Block

Transcription

Cardiac Development

Cardiac Hypertrophy

Medical Physiology

EFFECTS OF CALCIUM CHANGES ON HYSTERESIS IN RESTITUTION OF ACTION POTENTIAL DURATION

Guzman, Kathleen Marie

01 January 2009

Sudden cardiac death (SCD) is a leading cause of fatalities. Several methods have been developed to predict instability in myocytes which could lead to SCD. The focus of this study was on altering memory in myocytes, i.e. hysteresis in restitution of action potential duration (APD), by differing levels of calcium. Determination of alteration was implemented by using a diastolic interval (DI) control program that implements a sinusoidal change in DI. Plotting APD versus previous DI, i.e. restitution, produces a hysteresis loop. From these hysteresis loops, five parameters were used to determine measures of memory: area, thickness, overall tilt, max delay and min delay. Calcium levels were then altered with either verapamil or BAPTA-AM. Statistically significant effects were found for the verapamil study, but not for the BAPTA-AM study. Simulations were used to explain significant results. The verapamil findings support clinical studies that have shown verapamil to not have anti-arrhythmic effects. Theory predicts that a decrease in memory would decrease the stability of a system, and perhaps verapamil may not increase stability as hypothesized previously. The results of the BAPTA-AM study were inconclusive, and further investigation is needed before it can be determined that BAPTA-AM has no significant effect on memory.

Hysteresis in restitution

L-type calcium channel

free intracellular calcium

memory

stability