Plasticité synaptique dans l’aire tegmentaire ventrale : implication des endocannabinoïdes

Kortleven, Christian

12 1900

Le système dopaminergique (DA) méso-corticolimbique du cerveau, qui prend son origine dans l'aire tegmentaire ventrale (ATV), est fortement impliqué dans les comportements motivés et la toxicomanie. Les drogues d'abus activent ce système et y induisent une plasticité synaptique de longue durée. Les neurones DA de l'ATV reçoivent sur leur arborisation dendritique une grande densité de terminaisons glutamatergiques. Les drogues d'abus induisent une potentialisation à long terme (PLT) de ces contacts glutamatergiques. La PLT est une augmentation prolongée de la transmission synaptique, qui semble sous-tendre la mémoire et l'apprentissage. Les endocannabinoïdes (ECs) sont des neurotransmetteurs qui agissent de façon rétrograde sur des récepteurs présynaptiques (CB1) pour diminuer la libération des neurotransmetteurs comme le glutamate. Les neurones libèrent les ECs à partir de leur compartiment somatodendritique suite à une stimulation des afférences et la dépolarisation membranaire qui s’ensuit. La neurotensine (NT) est un neuropeptide retrouvé de façon abondante dans le système DA du cerveau. Il a été découvert que la NT peut induire la libération des ECs dans le striatum. En faisant appel à une combinaison d’approches immunohistochimique, électrophysiologique et pharmacologique chez la souris, nous avons confirmé dans la première étude de cette thèse la présence des récepteurs CB1 sur les terminaisons glutamatergiques des neurones DA de l'ATV, et avons montré que leur activation induit une diminution de la libération de glutamate. Par ailleurs, nous avons montré que des trains de stimulation peuvent induire la libération des ECs. Nous avons découvert qu'en présence d'un antagoniste des récepteurs CB1, il y a facilitation de l’induction de la PLT. Cette observation suggère que les ECs ont un effet inhibiteur sur l’induction de la PLT, plutôt que sur son expression. Nous avons déterminé que le 2-arachidonoylglycerol (2-AG) est l’EC qui est principalement responsable de cette action inhibitrice. Finalement, la PLT induite en présence d’un antagoniste CB1 est aussi dépendante d'une activation des récepteurs NMDA du glutamate. Les travaux réalisés dans la deuxième étude de cette thèse ont montré que la NT est présente dans une sous-population de terminaisons axonales glutamatergiques dans l’ATV. Une application exogène de NT induit une diminution prolongée de l'amplitude des courants postsynaptiques excitateurs (CPSEs). Cette diminution est bloquée en présence d'un antagoniste non-sélectif des récepteurs à la NT, ainsi qu'en présence d'un antagoniste sélectif pour le récepteur de NT de type 1 (NTS1). Confirmant l’implication d’une production d’ECs, la baisse des CPSEs par la NT a été bloquée en présence d’un antagoniste des récepteurs CB1 ou d’un bloqueur de la synthèse de 2-AG. La chélation du calcium intracellulaire n'empêchait pas l’effet inhibiteur de la NT sur les CPSEs, cependant, l'inhibition des protéines G ou de la phospholipase C a complètement bloqué la dépression synaptique induite par la NT. Par ailleurs, nos travaux ont montré que la nature prolongée de la dépression synaptique induite par la NT exogène s’explique par une libération soutenue des ECs, et non pas à une activation prolongée des NTR. Finalement, notre observation qu’un antagoniste des récepteurs de la NT ne facilite pas l’induction de la PLT, comme le fait un antagoniste du récepteur CB1, suggère que la stimulation répétitive des afférences glutamatergiques nécessaire à l’induction de la PLT n’induit pas de libération des ECs via la libération de NT, nous permettant ainsi de conclure que la sécrétion de NT n'agit pas dans ces conditions comme un facteur de régulation négative de la PLT. / The meso-corticolimbic dopamine (DA) system of the brain, originating in the ventral tegmental area (VTA), is strongly implicated in reward, motivation and drug addiction. Drugs of abuse activate this system and cause significant long term plasticity. DA neurons in the VTA receive are densely innervated by glutamatergic inputs. All major classes of drugs of abuse have been found to cause a long term potentiation (LTP) of glutamate transmission onto DA neurons of the VTA. LTP is an enduring increase of synaptic transmission, hypothesized to underlie memory and learning. Endocannabinoids (ECs) are transmitters that act in a retrograde fashion on pre-synaptic receptors leading to a decrease in neurotransmitter release. DA neurons can release ECs from their somatodendritic compartment in response to afferent stimulation or depolarization. Neurotensin (NT) is a neuropeptide that presents an extensive interaction with the DA system. It was discovered that NT can induce production of ECs in the striatum. In the first study of this thesis, we used a combination of immunohistochemical, pharmacological and electrophysiological techniques in mouse brain slices to demonstrate that CB1 EC receptors are present on glutamatergic afferents to DA neurons. Their activation induces a depression of glutamate release. We further showed that trains of afferent stimulation induce EC release from DA neurons and that in the presence of the CB1 antagonist AM251, there is a marked facilitation of the induction of LTP, suggesting that ECs produced in response to activation of glutamate synapses normally negatively regulate the induction, but not the expression of LTP. Finally, we found that 2-arachidonoylglycerol (2-AG) is the main EC implicated in this negative regulation of LTP and that LTP induced in the presence of a CB1 receptor antagonist is otherwise also dependent on NMDA glutamate receptors. In the second study, we report that NT is present in a subset of glutamatergic axon terminals in the VTA and that activation of NT receptors by exogenous NT induces a long-lasting decrease of the amplitude of excitatory postsynaptic currents (EPSCs) in VTA DA neurons. This decrease was blocked by a broad-spectrum NTR antagonist, as well as by a specific antagonist of the type 1 NT receptor NTS1. The decrease was also blocked when CB1 receptors or 2-AG synthesis were blocked. Chelating intracellular calcium had no effect, but inhibiting G-proteins or phospholipase C blocked NT-mediated synaptic depression. The long-lasting nature of the synaptic depression induced by NT was due to protracted EC release and not to prolonged NT receptor activation. Finally, our observation that a NT receptor antagonist did not facilitate LTP induction, as did a CB1 receptor antagonist, suggests that repetitive stimulation of glutamatergic afferents required to induce LTP does not cause EC production through the release of NT, thus allowing us to conclude that secretion of NT does not act under such conditions as a negative regulator of LTP.

Dopamine

ATV

Plasticité

Glutamate

endocannabinoïde

neurotensine

2-arachidonoylglycerol

patch-clamp

PLT

CB1

VTA

plasticity

endocannabinoid

neurotensin

LTP

Développement de la technologie des récepteurs couplés à un canal ionique pour des études structure-fonction des récepteurs couplés aux protéines G et du canal Kir6.2

Niescierowicz, Katarzyna

21 October 2013

Les Récepteurs Couplés à un Canal Ionique (ICCRs) sont des canaux ioniques artificielscréés par fusion d'un Récepteur Couplé aux Protéines G (RCPG) au canal ionique Kir6.2. Dansce concept, le canal agit comme un rapporteur direct des changements conformationnels desRCPGs permettant de détecter par simple mesure de courant, la fixation d'agonistes etd'antagonistes proportionnellement à leur concentration.Le signal induit étant directement corrélé à l'activité du récepteur, indépendamment desvoies de signalisation des protéines G, nous avons exploité cet avantage pour étendre le champd'applications des ICCRs au cours de cette thèse. Nous avons développé quatre applications quisont: 1) la caractérisation fonctionnelle des RCPG optimisés pour la cristallisation par insertionde domaine du lysozyme du phage T4 dans la boucle ICL3; 2) la détection de la dépendance desRCPGs au cholestérol; 3) la détection de ligands dits "biaisés" pour faciliter leur criblage; et 4) lacartographie fonctionnelle des portes du canal Kir6.2 régulées par des protéines membranairesinteragissant par le domaine N-terminal.

GPCR

Canal KATP

Biocapteur

Électrophysiologie (patch-clamp)

Double micro-électrodes)

Ingénierie moléculaire

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.

Role of the ventromedial hypothalamus in control of innate defensive behaviours

Wroblewska, Natalia

January 2018

Our senses are constantly bombarded with information. How does the brain integrate such a variety of inputs to generate appropriate behaviours? Innate defensive behaviours are a good model to address this question. They are essential for animal survival and the brain circuits that control them are highly conserved across species. Moreover, the sensory inputs and behavioural outputs can be well defined and reliably reproduced in the lab. This allows us to study function of the individual components of the circuit controlling these behaviours. Ventromedial hypothalamus (VMH) is a key brain region for controlling responses to predators; it has been shown that inactivating the VMH can reduce defensive behaviours. Interestingly, activating the VMH output neurons (SF1+ cells) can produce a variety of different behaviours, from immobility to escape, depending on the intensity of activation. During my PhD I used a variety of approaches to address the question of the function of the VMH in control of defensive behaviours. At first I hypothesised that the VMH might act as a centre responsible for choosing an appropriate behavioural response according to the stimulus. I set to investigate how different activation levels of SF1+ neurons can produce such different behavioural outputs, and how this activity is modulated in vivo in response to predator stimuli. I began the project by quantifying mouse defensive behaviours in response to olfactory and auditory predator cues, as well as to the optogenetic activation of SF1+ neurons. I then questioned whether there was heterogeneity within the population of SF1+ neurons, which could explain their ability to trigger different behaviours. I performed patch clamp recordings from acute brain slices and conducted a study of the electrophysiological properties of SF1+ neurons. I next investigated how SF1+ neurons integrate excitatory inputs from the medial amygdala, a region which receives olfactory inputs from the accessory olfactory bulb. By combining optogenetics with slice electrophysiology and behavioural assessment, I described the physiology and relevance of this connection. Finally, I investigated in vivo activity in the VMH in response to predator cues by performing calcium imaging of the VMH neurons in freely moving mice. By presenting different sensory stimuli, I addressed the question of heterogeneity of the input pattern to the VMH neurons and the relationship between the VMH activity and the behavioural output. Taken all together, the results of this project have led to a hypothesis whereby the function of the VMH is to facilitate rather than directly control the choice of an appropriate behavioural response.

Investigação do efeito vasorelaxante e caracterização eletrofisiológica dos alcalóides curina e reticulina

Medeiros, Marcos Antônio Alves de

24 September 2009

Made available in DSpace on 2015-05-14T13:00:06Z (GMT). No. of bitstreams: 1 parte1.pdf: 1450137 bytes, checksum: 1838bf2efddf0ca147f276df88417bb6 (MD5) Previous issue date: 2009-09-24 / Coordenação de Aperfeiçoamento de Pessoal de Nível Superior - CAPES / It was been demonstrated that curine and reticuline, induced a vasodilator effect in the rat small mesenteric arteries through inhibition of voltage-gated Ca2+ channels (VGCC). These compounds, curine and reticuline were isolated from the root barks of Chondrondendron platyphyllum and Ocotea duckei Vattimo, respectively, therefore the aim of this work was to evaluate the vasodilator mechanism of curine and reticuline, bisbenzylisoquinoline alkaloids (BBA), isolated from the root barks of Chondrondendron platyphyllum and Ocotea duckei Vattimo, respectively, using functional and molecular approaches. Tension measurements in aorta rings, whole-cell patch-clamp and confocal techniques were employed to study the action of these alkaloids. The A7r5 smooth muscle derived cell line was used for Ca2+ currents measuring and the intracellular calcium concentration ([Ca2+]i) were evaluated using confocal microscopy. The main results are as follows: in aortic rings, curine (3 - 300 μM) antagonized KCl (60 mM) and Bay K8644 (3 x 10-7 M) induced contractions. In whole-cell configuration, curine reduced the voltage-activated peak amplitude of ICa,L in a concentration-dependent manner. However, the Ca+2 current density versus voltage relationship and maximal activation voltage of ICa,L were not changed. Moreover curine did not also affect the steady-state activation of ICa,L, but shifted the steady-state inactivation curve of ICa,L for more negative potentials, however this effect was not changed in the presence of IBMX, dbcAMP and 8-brcGMP, suggesting that cyclic mononucleotides, such as cAMP and cGMP, are not involved in curine effect. In confocal experiments, curine inhibited the rise on the [Ca2+]i induced by KCl (60 mM) in dispersed vascular smooth muscle cells. In reference to reticuline (3 300 μM) was verified that alkaloid agonized CaCl2 and KCl-induced contractions and elicited vasorelaxation in aortic rings. In whole-cell configuration, reticuline reduced the voltage-activated peak amplitude of ICa,L in a concentration-dependent manner, but did not change the characteristics of current density versus. voltage relationship. Reticuline shifted leftwards the steady-state inactivation curve of ICa,L, however this effect was not changed after application of dibutyryl cyclic adenosine monophosphate to the cell. In cells pretreated with forskolin, an adenylate cyclase activator, the addition of reticuline caused further inhibition of the Ca2+ currents suggesting an additive effect, indicating that cyclic mononucleotides were not involved. Taken together the results have shown that curine and reticuline elicits vasorelaxation due to the blockade of the L-type voltage-dependent Ca2+ current in rat aorta smooth muscle cells. The reported effect may contribute to the potential cardioprotective efficacy of curine and reticuline. / Curina e reticulina são alcalóides isolados das cascas do caule e raízes de Chondrondendron platyphyllum e de Ocotea duckei Vattimo, respectivamente. Estudos anteriores demonstraram que esses alcalóides são capazes de induzir efeito vasodilatador em artéria mesentérica e aorta de rato, respectivamente, devido possível inibição dos canais para Ca2+ dependentes de voltagem (VGCC). O objetivo deste trabalho foi investigar o mecanismo vasodilatador de curina e reticulina realizando experimentações funcionais e moleculares. Foram utilizadas medidas de tensão em anéis de aorta de rato, e empregadas técnicas de patch-clamp e de microscopia confocal para estudos da ação desses alcalóides. Também foram utilizadas células A7r5, uma linhagem de células musculares lisas embrionária derivada de aorta torácica de rato, que foram usadas para medir as correntes de Ca2+ macroscópicas e a concentração de cálcio intracelular ([Ca2+]i), que foram avaliadas usando a técnicas de patch-clamp e microscopia confocal, respectivamente. Os principais resultados são: em anéis de aorta, curina (3 - 300 μM) antagonizou as contrações induzidas por KCl (60 mM) e Bay K8644 (3 x 10-7 M). Na configuração whole-cell patch clamp , curina reduziu a amplitude da corrente de cálcio do tipo L (ICa,L) de maneira dependente de concentração. Porém, curina não alterou as características das correntes na relação corrente-voltagem. A voltagem de ativação máxima para ICa,L não foi diferente em relação ao controle. Além disso, curina também não afetou a ativação no estado estacionário das ICa,L, mas deslocou a curva da inativação estacionária para potenciais mais negativos. No entanto, esse efeito promovido por curina não foi alterado na presença de IBMX, dbcAMP e 8- brcGMP, sugerindo que os mononucleotídeos cíclicos, como APMc e GMPc, não estão envolvidos no efeito da curina. Em experimentos com microscopia confocal curina inibiu os transientes de cálcio intracelulares, e reduziu o aumento de [Ca2+]i induzidos por KCl (60 mM) em células de músculo liso vascular. Em relação à reticulina (3 300 μM), foi verificado que esse alcalóide antagonizou as contrações induzidas por CaCl2 e KCl, provocando vasorelaxamento em anéis de aorta. Na configuração whole-cell patch clamp , reticulina também reduziu a amplitude das ICa,L de maneira dependente de concentração, mas não mudou as características da corrente na relação corrente-voltagem. A reticulina deslocou para potenciais mais negativos a curva de inativação estacionária para as ICa,L. Porém, esse efeito não foi alterado após a aplicação de dbcAMP e 8-brcGMP. Em células pré-tradadas com forskolina, um ativador da adenilil ciclase, a adição da reticulina causou uma inibição adicional das correntes de Ca2+ que sugere um efeito aditivo da reticulina, indicando que os mononucleotídeos cíclicos não estão envolvidos. Dessa forma, curina e reticulina provocaram vasorelaxamento, devido ao bloqueio das correntes de Ca2+ dependentes de voltagem do tipo-L em células de músculo liso, em cultura e recémdispersas, de aorta de rato, revelando que esses alcalóides têm um importante potencial como modelo químico para a concepção e posterior desenvolvimento de novos fármacos com propriedade protetora cardiovascular.

Curina

Reticulina

Células A7r5

Aorta de rato

Whole cell patchclamp

Correntes de cálcio

Cálcio intracelular

Curine

Reticuline

A7r5 cells

Rat aorta

Patch-clamp

Calcium currents

Intracellular calcium

CIENCIAS BIOLOGICAS::FARMACOLOGIA

Estudo eletrofisiológico dos canais iônicos das células-tronco mesenquimais da geléia de wharton do cordão umbilical humano

do Nascimento, Williamis

31 January 2011

Made available in DSpace on 2014-06-12T15:54:28Z (GMT). No. of bitstreams: 2 arquivo6489_1.pdf: 1208262 bytes, checksum: c1b40f981f11c014c773e3922d544d81 (MD5) license.txt: 1748 bytes, checksum: 8a4605be74aa9ea9d79846c1fba20a33 (MD5) Previous issue date: 2011 / Conselho Nacional de Desenvolvimento Científico e Tecnológico / A caracterização de canais iônicos em células tronco é importante pelo fato destas estruturas atuarem no controle da proliferação e diferenciação destas células. Há poucos trabalhos focados nos canais iônicos presentes nas membranas plasmáticas das células tronco e nenhum deles trata das células tronco mesenquimais da geléia de Wharton do cordão umbilical humano (whMSC). O cordão umbilical é uma fonte importante de células tronco para tão esperada terapia celular. Estes fatos motivaram o estudo dos canais iônicos das whMSC como objetivo maior do presente trabalho. Foi utilizada a técnica de patch-clamp na configuração whole-cell e a atuação de inibidores específicos para identificar os canais iônicos presentes nas whMSC. Os inibidores escolhidos foram: tetraetilamonio (TEA) e 4-aminopiridina (4-AP) como inibidores de canais de potássio dependentes de voltagem e de Ca2+, Glibenclamida (GB) um inibidor de canais de potássio dependentes de ATP, canais aniônicos dependentes de volume celular e CFTR e 5-nitro-2-(3-phenylpropylamino) ácido benzóico (NPPB) um potente bloqueador dos canais de cloreto, mas que também é capaz de bloquear os canais de potássio dependentes de Ca2+ de condutância intermediária. Os resultados mostraram que as correntes iônicas ativadas por voltagem das whMSC podem ser bloqueadas consideravelmente por TEA (10 mM), 4-AP (5 mM) e NPPB (100 μM) indicando a presença dos canais de K+ dependentes de voltagem e de Ca2+ e de canais de Cl- dependentes de voltagem conforme descrito para células tronco de outras origens. Utilizando GB (100 μM) observamos um aumento (estimulação) significativo da corrente. Este é um resultado inédito, pois estudos anteriores demonstram que o GB atua inibindo a corrente iônica transmembrana. Em todos os casos, com todos os inibidores testados, os efeitos foram reversíveis. Estes resultados demonstram que as membranas citoplasmáticas das whMSC possuem canais de K+ dependentes de voltagem e de Ca2+ e canais de Cl- dependentes de voltagem. O surpreendente efeito da glibenclamida indica a presença de canais iônicos desconhecidos nas membranas das whMSC

Geléia de Wharton

Células tronco mesenquimais

Canais iônicos

Patch-clamp

Tetraetilamônio (TEA)

4-Amonopiridina (4-AP)

Glibenclamida (GB)

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

De la diffusion latérale des récepteurs AMPA à la perception des whiskers : un nouveau modèle de cartographie corticale / From AMPAR lateral diffusion to whisker perception : a new model for cortical remapping

Campelo, Tiago

07 October 2019

Les champs récepteurs corticaux se réorganisent en réponse aux changements de l'environnement. Par exemple, suite à une lésion périphérique, les modalités sensorielles préservées gagnent de l'espace cortical au détriment de celles lésées. L'étude du cortex somatosensoriel en tonneau des rongeurs a fourni des données importantes pour la compréhension des mécanismes synaptiques à l'origine de cette réorganisation corticale. En condition normale, les neurones de chaque colonne corticale répondent préférentiellement à la stimulation d'une seule vibrisse principale ("Principal Whisker, PW"). Au contraire, suite à l'amputation de l'ensemble des vibrisses sauf une ("Single Whisker Experience, SWE"), les neurones des colonnes associées aux vibrisses amputées répondent à la stimulation de la vibrisse conservée, à l'origine du renforcement et de l'expansion des représentations corticales des vibrisses conservées. Bien que des preuves indirectes aient révélées un rôle de la potentialisation à long terme ("Long-Term Potentiation, LTP") de synapses préexistantes dans la modification des cartes corticales, probablement via une augmentation du nombre des récepteurs AMPA (AMPARs) aux synapses, un lien direct entre la LTP, la réorganisation des cartes corticales, et l'adaptation des comportements sensori-moteurs suite à une altération des entrées sensorielles n'a pas encore été démontré. L'objectif de cette thèse a donc été de mettre en évidence cette relation de façon expérimentale et en condition physiologique. Pour cela, nous avons mis au point une stratégie in vivo combinant des enregistrements électrophysiologiques, de l'imagerie biphotonique et l'analyse du comportement d'exploration chez la souris contrôle ("Full Whisker Experience, FWE) et amputée de certaines vibrisses (SWE). Nous avons d'abord confirmé que la stimulation rythmique de la PW ("Rhytmic Whisker Swtimulation, RWS") renforce les synapses excitatrices (RWS-LTP) in vivo des souris anesthésiées FWE. Au contraire des souris FWE, les neurones pyramidaux des souris SWE présentent une augmentation de l'excitabilité neuronale et une absence de RWS-LTP, indiquant ainsi que les synapses corticales associées à la vibrisse intacte ont été potentialisées en réponse au protocole SWE. Pour mieux comprendre l'implication de la RWS-LTP dans la réorganisation des cartes corticales et l'adaptation des comportements sensori-moteurs, nous avons développé une nouvelle approche pour manipuler la LTP in vivo grâce à l'immobilisation des AMPARs par des anticorps extracellulaires ("cross-linking"). En effet, notre équipe a montré précédemment que le cross-linking des AMPARs empêche la LTP in vitro. Par ailleurs, une accumulation des AMPARs au niveau post-synaptique a été démontrée in vivo par imagerie biphotonique au cours d'une stimulation RWS, suggérant un rôle de la mobilité de ces récepteurs dans cette RWS-LTP. Au cours de cette thèse, nous avons démontré que le cross-linking des AMPARs in vivo bloque également l'expression de la RWS-LTP, mais sans affecter la transmission synaptique basale, ni l'induction de la RWS-LTP, indiquant ainsi que la mobilité des AMPARs est également fondamental pour l'expression de la LTP in vivo. De façon importante, le cross-linking des AMPARs de façon chronique, au cours du SWE, permet non seulement de rétablir la RWS-LTP et l'excitabilité neuronale, et donc de bloquer la réorganisation corticale, mais aussi de modifier les capacités de récupération sensori-motrices des souris amputées. Dans l'ensemble, nos données démontrent pour la première fois un rôle critique et direct de la RWS-LTP dans le réarrangement des circuits en réponse à l'amputation de certaines vibrisses. La réorganisation des cartes corticales serait ainsi assurée par le renforcement de la transmission synaptique, et constituerait alors un mécanisme compensatoire pour optimiser le comportement sensorimoteur de l'animal lors de l'altération des entrées sensorielles. / Neuronal receptive fields in the cerebral cortex change in response to peripheral injury, with active modalities gaining cortical space at the expense of less active ones. Experiments on the mouse whisker-to-barrel cortex system provided important evidences about the synaptic mechanisms driving this cortical remapping. Under normal conditions, neurons in each barrel-column have receptive fields that are strongly tuned towards one principal whisker (PW). However, trimming all the whiskers except one (single-whisker experience, SWE) causes layer (L) 2/3 pyramidal neurons located in the deprived and spared-related columns to increase their response towards the spared input. This results in a strengthening and expansion of the spared whisker representation within the barrel sensory map. Indirect evidences suggest that these cortical alterations might depend on the activity-dependent potentiation of pre-existing excitatory synapses (LTP), likely through increased levels of postsynaptic AMPA receptors (AMPARs). However, a clear link between LTP, cortical remapping, and the adaptation of sensorimotor skills following altered sensory experience has not yet convincingly been demonstrated. Here, we combined in vivo whole-cell recordings, 2-Photon calcium imaging and a whisker-dependent behavior protocol to directly demonstrate this relationship. It has been described that rhythmic whisker stimulation potentiates cortical synapses (RWS-LTP) in vivo. An accumulation of postsynaptic AMPARs during similar sensory stimulation was also reported by imaging evidences. Our data demonstrates that this potentiation is occluded by SWE, suggesting that cortical synapses are already potentiated by this trimming protocol. This is translated into an increased neuronal excitability in the spared column and sensorimotor recovery by the spared whisker. To better understand the implication of LTP in cortical remapping, we developed a novel approach to manipulate LTP in vivo without affecting overall circuit properties. Our team showed previously that the blockage of AMPARs synaptic recruitment by extracellular antibody cross-linking prevents LTP in vitro. Here, we report that in vivo cross-linking of AMPARs blocks the expression but not the induction of RWS-LTP, suggesting that the synaptic recruitment of AMPARs is fundamental for in vivo LTP as well. Moreover, chronic AMPAR cross-linking during SWE reverts RWS-LTP occlusion and the increased neuronal excitability caused by whisker trimming. As consequence, the sensorimotor performance by the spared whisker is permanently impaired by the blockage of cortical remapping. Altogether, these evidences led us to define a critical role for synaptic LTP on circuit re-arrangement after whisker trimming. Our data shows that LTP-driven cortical remapping is a compensatory mechanism to optimize animal’s sensorimotor behavior upon altered sensory experience.

Récepteurs AMPA

Plasticité synaptique

Ltp

Réorganisation des cartes corticales

Imagerie et Electrophysiologie In vivo

Ampar

Synaptic Plasticity

Ltp

Cortical Remapping

In vivo Patch Clamp

In vivo 2-Photon Imaging

Závislost velikosti proudu IKs kanálu srdce na stimulaci / Cardiac IKs channel: rate-dependence of the current magnitude

Kachan, Ksenia

January 2019

This diploma thesis deals with study of the rate-dependence of the magnitude of a current through the heart channel that conducts slowly activating component of delayed rectifier outward current (IKs). This property is very important for the IKs channel function. When other repolarizing currents are insufficient, but also when the heart rate accelerates, especially during elevated sympathetic tone, IKs provides so-called repolarization reserve, which prevents excessive lengthening of cardiac action potential repolarization. The IKs channel structure is encoded by the KCNQ1 (pore-forming -subunit) and KCNE1 (modulatory -subunit) genes. Mutations in these genes disrupt the physiological function of the IKs channel and cause inherited arrhythmogenic syndromes, especially long QT syndrome (LQTS). Such mutations include the c.926C>T (p.T309I) mutation in the KCNQ1 gene, which results in LQTS type 1 in heterozygous carriers. The theoretical part of the thesis provides basic information about the IKs channel and the patch clamp technique, this knowledge is necessary for the practical part. The experimental part is focused on cultivation of the CHO cell line and its transient transfection for subsequent electrophysiological measurements by whole-cell patch clamp technique to study the dependence of the IKs magnitude on stimulation frequency, both in the wild type channels (i.e. without mutation) and in those with cotransfected wild type and T309I subunits.