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

Specific activation of the alternative cardiac promoter of Cacna1c by the mineralocorticoid receptor / Activation spécifique du promoteur cardiaque alternatif du Cacna1c par le récepteur aux minéralocorticoïdes

Ribeiro mesquita, Thássio Ricardo

13 December 2017

Les antagonistes des récepteurs aux minéralocorticoïdes (MR) appartiennent à l'arsenal thérapeutique pour le traitement de diverses maladies cardiovasculaires, mais les mécanismes conférant leurs effets bénéfiques sont encore mal compris. Une partie de ces effets peuvent être liée à la régulation de l'expression du canal Ca2+ de type L Cav1.2, largement impliqué dans l'insuffisance cardiaque et l'hypertension. Nous montrons que MR fonctionne comme un facteur de transcription transformant le signal de l'aldostérone dans l'utilisation du 'cardiaque' promoteur alternatif P1, dirigeant l'expression du long N-terminal transcrit (Cav1.2-LNT. L'aldostérone augmente de façon concentration- et de temps dépendente l'expression de Cav1.2-LNT dans les cardiomyocytes en raison de l'activation du promoteur P1, par interactions des MR avec des séquences spécifiques de l'ADN sur le promoter P1. Ce mécanisme de cis-régulation induit l'activation de promoteur P1 dans les cellules vasculaires conduisant à une nouvelle signature moléculaire de Cav1.2-LNT associé à une sensibilité réduite aux bloqueurs des canaux Ca2+. Ces résultats révèlent Cav1.2-LNT comme une cible minéralocorticoïde spécifique qui pourrait influencer sur l'éfficacité thérapeutique dans les maladies cardiovasculaires. / The mineralocorticoid receptor (MR) antagonists belong to the current therapeutic armamentarium for the management of cardiovascular diseases, but the mechanisms conferring their beneficial effects are still poorly understood. Part of these MR effects might be related to the L-type Cav1.2 Ca2+ channel expression regulation, critically involved in heart failure and hypertension. Here, we show that MR acts as a transcription factor triggering aldosterone signal into specific alternative 'cardiac' P1-promoter usage, given rise to long (Cav1.2-LNT) N-terminal transcripts. Aldosterone increases Cav1.2-LNT expression in cardiomyocytes in a time- and dose-dependent manner due to MR-dependent P1-promoter activity, through specific DNA sequence-MR interactions. This cis-regulatory mechanism induced a MR-dependent P1-promoter switch in vascular cells leading to a new Cav1.2-LNT molecular signature with reduced Ca2+ channel blocker sensitivity. These findings uncover Cav1.2-LNT as a specific mineralocorticoid target that might influence the therapeutic outcome of cardiovascular diseases.

Canaux Ca2+ de type L

Aldostérone

Récepteur aux minéralocorticoïde

Cœur

Muscle lisse vasculaire

L-Type Ca2+ channel

Aldosterone

Mineralocorticoid receptor

Heart

Vascular smooth muscle cells

Disrupted Cav1.2 Selectivity Causes Overlapping Long QT and Brugada Syndrome Phenotypes in CACNA1C-E1115K iPS Cell Model / CACNA1C-E1115K変異ヒトiPS細胞モデルにおけるCav 1.2イオン選択性障害がQT延長症候群・ブルガダ症候群のオーバーラップを引き起こすメカニズムの検討

Kashiwa, Asami

23 March 2023

京都大学 / 新制・課程博士 / 博士(医学) / 甲第24485号 / 医博第4927号 / 新制||医||1063(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 江藤 浩之, 教授 湊谷 謙司, 教授 大鶴 繁 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DGAM

L-type Ca2+ channel

Induced pluripotent stem cell

Late Na+ channel current

Long QT syndrome

Brugada syndrome

Gene editing

Arrhythmia

490