Estudos estruturais de agonistas de acetilcolina pela espectroscopia de RMN e calculos teoricos / Structural studies of acetylcholine agonists by NMR spectroscopy and theoretical calculations

da Silva, Julio Cesar Araujo, 1974-

13 February 2008

Orientador: Roberto Rittner / Dissertação (mestrado) - Universidade Estadual de Campinas, Instituto de Quimica / Made available in DSpace on 2018-08-11T06:54:29Z (GMT). No. of bitstreams: 1 daSilva_JulioCesarAraujo_M.pdf: 2287772 bytes, checksum: ee8613d61a9f9feb9fa6894b5197e36f (MD5) Previous issue date: 2008 / Resumo: Neste trabalho é apresentado o estudo conformacional dos agonistas muscarinicos da acetilcolina (ACh+): carbacol, metacolina e pilocarpina. O estudo baseou-se na análise das constantes de acoplamento 3JHH e nos dados obtidos pelos cálculos teóricos ab initio. O comportamento conformacional destes compostos é descrito principalmente por apenas dois dos seus ângulos diedros. Os resultados dos cálculos teóricos realizados com o nível teórico B3LYP/6- 311+G(d,p), bem como os dados experimentais, apontaram a conformação gauche como a predominante para todos os compostos estudados para o diedro responsável pela atividade farmacológica dos agonistas independente do solvente utilizado. Atribui-se a estabilização da forma gauche a interação eletrostática entre o atomo de nitrogênio positivamente carregado e o átomo de oxigênio da porção éster (OCH2). Os cálculos teóricos mostraram que os conformeros mais estáveis possuem uma distância N+/O menor. Em adição, estudos de NBO mostraram a importância das interações hiperconjugativas sC5H5 s* C6N7 e sC5H5s* O4C5 na maior estabilização dos conformeros gauche. Os conformeros mais estáveis para cada composto sao: aceticolina, TG-; carbacol, AG+; metacolina, TG+; pilocarpina, TG+C / Abstract: This work describes the conformational analysis of muscarine agonists of acetylcholine (ACh+): carbachol, metacholine and pilocarpine. It was performed from the analysis of 3JHH coupling constants and from ab initio theoretical calculations. Their conformational behavior is discussed taking into account the most important dihedral angles. Both the results from theoretical calculations at B3LYP/6-311+G(d,p) as the experimental data indicated that the gauche conformer is predominant, considering the dihedral angle wich is responsible by their pharmacological activity regardless the solvente employed. The stabilization of the gauche conformer was ascribed to the eletrostatic interaction between the positively charged nitrogen atom and the (OCH2) oxygen atom of the ester fragment. This was confirmed by the N+/O smaller distance for the most stable conformers. In addition, NBO data showed the relevant role of sC5H5 s* C6N7 e sC5H5s* O4C5 hyperconjugative interactions of the gauche conformers. The most stable conformers for the above compounds are: : acetycholine, TG-; carbachol, AG+; methacholine, TG+; pilocarpine, TG+C / Mestrado / Quimica Organica / Mestre em Química

Análise conformacional

Ressonância magnética nuclear

Cálculos teóricos

Agonistas de acetilcolina

Conformational analysis

RNM

Theoretical calculations

Acetylcholine agonists

Efeito da inibição aguda da acetilcolinesterase com piridostigmina na hemodinâmica e eletrocardiograma de ratos infartados / Effects of acute inhibition of acetylcholinesterase with pyridostigmine on hemodynamics and electrocardiogram of infarcted rats

Fernanda Machado dos Santos

14 February 2014

O infarto do miocárdio (IM), uma das principais causas de morte nas sociedades industrializadas, é sempre acompanhado por uma notável alteração da modulação autonômica, caracterizada por hiperatividade simpática e diminuição do tono parassimpático ao coração. O bloqueio da atuação do simpático cardíaco tem sido amplamente utilizado como estratégia terapêutica eficaz para redução da morbi-mortalidade em pacientes com IM. Entretanto, há evidências de que o restabelecimento da função parassimpática ao coração pode ser igualmente benéfica, uma vez que a diminuição do parassimpático cardíaco é um fator de risco independente de morte súbita. Assim, o objetivo do presente estudo foi avaliar a influência da inibição da acetilconinesterase plasmática (AChE), por meio da administração endovenosa do brometo de piridostigmina (PIR), sobre o eletrocardiograma (ECG), hemodinâmica e modulação autonômica apos o IM agudo em ratos. Ratos foram anestesiados com uretana e mantidos a uma temperatura de 36-37 ºC. Tiveram eletrodos subcutâneos para registro do ECG implantados, e a artéria e veia femoral cateterizadas para medida direta de PA e administração de drogas, respectivamente. Experimentos preliminares foram realizados para determinação de uma dose de PIR que não causasse grande repercussão hemodinâmica. A atividade da acetilcolinesterase plasmática, bem como o tono autonômico cardíaco também foram avaliados em ratos normais. Em outro protocolo, ratos anestesiados, sob registro contínuo do ECG e PA, tiveram o ramo descendente anterior da artéria coronária esquerda ligado para provocar um extenso IM e, após 10 min, foram tratados com PIR (0,25 mg/kg, i.v) ou salina (solução fisiológica 0,9%), e os registros foram acompanhados por 4 h. Ratos controles tiveram o tórax aberto, mas a artéria coronária foi mantida intacta. Ao final, os ratos tiveram o coração retirado para avaliação da extensão da isquemia miocárdica e para o estudo da conexina 43. A administração endovenosa de PIR foi efetiva em reduzir a atividade da AChE e provocou uma discreta redução da FC (438±8 para 387±10 bpm), sem alteração da PA. Ratos tratados com PIR tiveram menor tono simpático e maior tono vagal cardíaco que os ratos que receberam salina. O tratamento com PIR diminuiu a incidência de arritmias nos animais com IM e aumentou a porcentagem de ratos que sobreviveram até a 4ª hora após o infarto (72 vs 58% nos não tratados). A PIR também preveniu o aumento do intervalo QTc, observado após o IM em ratos não tratados (=-2±4, vs 33±13 ms). A quantidade de conexina 43 foi marcadamente reduzida pelo IM em ratos não tratados (0,7±0,1 vs 2,2±0,4 ua), redução esta que não ocorreu nos ratos com IM tratados com PIR (1,3±0,3 ua). Por fim, foi realizado um ensaio, in vitro, em cardiomiócitos da linhagem H9c2 em cultura, e foi observado que a PIR preveniu a degradação da Cx43 induzida por meio isquêmico durante 4 horas. Portanto, a administração aguda de PIR provocou uma bradicardia pouco intensa, sem repercussões hemodinâmicas importantes, aumentou o tono vagal cardíaco, preveniu o prolongamento do intervalo QTc, diminuiu a incidência de arritmias, e preveniu a degradação da Cx43 nos corações dos ratos infartados. / Myocardial infarction (MI), a leading cause of death in industrialized societies, is always accompanied by a remarkable change in cardiovascular autonomic modulation, characterized by sympathetic overactivity and decreased vagal tone to the heart. The blockade of the cardiac sympathetic activity has been widely used as an effective therapeutic strategy to reduce morbidity and mortality in patients with MI. However, there is evidence that improvement of parasympathetic function can also be beneficial since reduction of cardiac vagal function is an independent risk factor for sudden death. The aim of this study was to evaluate the influence of inhibition of plasma acetilconinesterase (AChE), by intravenous administration of pyridostigmine bromide (PYR) on the electrocardiogram (ECG), hemodynamics and cardiovascular autonomic modulation shortly after MI in rats. Rats were anesthetized with urethane and maintained on a heating pad. Subcutaneous electrodes to record the ECG were installed and catheters were inserted into femoral artery and vein for measurement of blood pressure and drug administration, respectively. Preliminary experiments were performed to determine a dose of PYR that would not cause major hemodynamic consequences. Plasma AChE activity, and cardiac autonomic tone were also evaluated in normal rats. Then, anesthetized rats under continuous recording of ECG and BP, had the anterior descending branch of the left coronary artery ligated to elicit extensive MI and, after 10 min, were treated with PYR (0.25 mg/kg, iv) or saline (0.9% NaCl) and monitored for the next 4 h. Control rats had the chest open, but coronary artery was kept intact. At the end, the rats had the heart removed to determine the size of myocardial isquemia and to study connexin 43. Intravenous administration of PYR was effective in reducing AChE activity of and caused a mild reduction in HR (438±8 to 387±10 bpm) with no change in BP. Also, rats treated with PYR had lower sympathetic and higher cardiac vagal tone as compared to untreated rats. The treatment with PYR decreased the incidence of arrhythmias after MI and increased the percentage of rats that survived until the 4th hour after infarction (72 vs 58 % in untreated). PYR also prevented the increase in QTc interval observed after MI in untreated rats (=-2±4 vs 33±13 ms). The amount of connexin 43 was markedly reduced by MI in untreated rats (2.24±0.46 vs 0.72±0.14 au), nevertheless, this reduction was not observed in infarcted rats that received PYR (1.31±0.29 au). Finally, an in vitro assay was performed on the line H9c2 cardiomyocytes in culture, and it was observed that PYR prevented the degradation of Cx43 induced by ischemic medium for 4 hours. Therefore, the acute administration of PYR caused mild bradycardia without hemodynamic repercussions, increased vagal tone, prevented the prolongation of the QTc interval and decreased the incidence of arrhythmias and prevented the degradation of Cx43 in infarcted rat hearts.

Acetilcolina

Arritmias

Conexina 43

Infarto do miocárdio

Vago

Acetylcholine

Arrhythmias

Connexin 43

Myocardial infarction

Vagus

Ações da metilecgonidina sobre a síntese de melatonina na glândula pineal de ratos. / Actions of the metilecgonidine on the syntesis of melatonin in the pineal gland of rats.

Livia Silva Medeiros de Mesquita

19 April 2012

A glândula pineal sintetiza o hormônio melatonina no período escuro. No rato, a ativação dos receptores a e b-adrenérgicos aumenta os níveis de AMPc, levando à síntese e ativação da enzima arilalquilamina-N-acetiltransferase (AANAT). A glândula recebe também inervação parassimpática, sendo inibitório o efeito da acetilcolina. A metilecgonidina (AEME) é o produto da pirólise da cocaína, quando esta é usada sob a forma de \"crack\". Neste trabalho estudamos os efeitos e os mecanismos de ação da AEME sobre a síntese da melatonina. Foram investigados a atividade da AANAT, o Ca2+, o AMPc e a viabilidade celular e a fragmentação do DNA. A AEME reduziu a síntese da melatonina in vivo e in vitro, sendo este efeito revertido pela atropina. A AEME induziu um aumento do Ca2+, não alterando o AMPc e a atividade da AANAT. A viabilidade celular e fragmentação do DNA não foram modificadas pela AEME. Em conclusão, a AEME reduz a síntese da melatonina, in vitro e in vivo, e a sua ação se dá por interferir com o sistema colinérgico muscarínico. / The pineal gland synthesizes the hormone melatonin in the dark. In rats, the activation of a and b-adrenergic receptors increases cAMP levels and the synthesis and activity of arylalkylamine-N-acetyltransferase enzyme (AANAT). The pineal gland is also innervated by parasympathetic fibers, being inhibitory the effect of acetylcholine. Methylecgonidine (AEME) is the pyrolysis product of cocaine when it is used as \"crack.\" In this work we studied the effects of AEME on the melatonin synthesis, in vitro and in vivo. We investigated AANAT activity, iCa2+, cAMP, cell viability and DNA fragmentation. AEME reduced melatonin synthesis in vivo and in vitro, and this effect was reversed by atropine. There was an increase in Ca2+, but not in cAMP or AANAT activity induced by AEME. Cell viability and DNA fragmentation were not affected by AEME. In conclusion, AEME reduced melatonin synthesis in vitro and in vivo, being this effect mediated by the muscarinic cholinergic system.

Acetilcolina

Glândula pineal

Melatonina

Ratos

Receptores adrenérgicos

Acetylcholine

Adrenergic receptors

Melatonin

Pineal gland

Rats

Cholinergic neurotransmission in different subregions of the substantia nigra differentially controls dopaminergic neuronal excitability and locomotion

Estakhr, Jasem

05 May 2017

Midbrain dopamine (DA) neurons play a key role in a wide range of behaviours, from motor control, motivation, reward and reinforcement learning. Disorders of midbrain dopaminergic signaling is involved in a variety of nervous system disorders including Parkinson’s disease, schizophrenia and drug addiction. Understanding the basis of how dopaminergic neuronal activity in the substantia nigra pars compacta (SNc) governs movements, requires a deep appreciation of how afferent inputs of various neurotransmitter systems create a neuronal circuit that precisely modulates DA neuronal excitability. Two brainstem cholinergic neuclei, the laterodorsal tegmental nucleus (LDT) and the pedunculopontine tegmental nucleus (PPT), have major cholinergic projections to the SNc, despite the fact that the precise mechanisms of cholinergic modulation of DA neuronal activity mediated by nAChRs remain unclear. To dissect out the modulatory roles of the cholinergic system in regulating DAergic neuronal activity in the SNc and locomotion, we employed optogenetics along with electrophysiological and behavioural approaches. My results from whole-cell recordings from lateral and medial SNc DA neurons revealed that lateral DA neurons received predominantly excitatory nAChR mediated cholinergic neurotransmission (monosynaptic nicotinic or disynaptic glutamatergic responses) resulting in greater excitability of DA neurons both at 5 and 15 Hz blue LED light stimulation of cholinergic terminals. However, medial SNc DA neurons received predominantly biphasic current responses that were both inhibitory GABAergic and excitatory nAChR mediated cholinergic neurotransmission. This led to a net inhibition of action potential firing of DA neurons at 5 Hz blue LED light stimulation of cholinergic terminals, while at 15 Hz stimulation there was an initial inhibition followed by a significant increase of the baseline action potential firing frequency. Furthermore, in vivo optogenetic experiments showed that activation of the cholinergic system in the medial SNc resulted in decreased locomotion, while for the lateral SNc led to increased locomotion. Together our findings provide new insights into the role of the cholinergic system in modulating DA neurons in the SNc. The cholinergic inputs to different subregions of the SNc may regulate the excitability of the DA neurons differentially within a tight range from excitation to inhibition which may translate into different kinds of locomotor behaviour. / Graduate

Effects of beta-2 adrenergic receptor agonists in DOK7 congenital myasthenic syndrome

Clausen, Lisa

January 2015

Congenital myasthenic syndromes (CMS) are a rare group of heterogeneous disorders, characterised by compromised neuromuscular transmission and symptoms of fatiguable muscle weakness. CMS is caused by mutations in genes that affect the structure and function of the neuromuscular junction (NMJ). In about 20% of CMS cases, patients have mutations in the gene DOK7; the protein product, DOK7, is crucial for maintaining the dense aggregation of acetylcholine receptor (AChR) clusters at the NMJ. DOK7-CMS patients do not respond to treatment with acetylcholinesterase inhibitors which are the first line treatment for most forms of CMS. Instead, a dramatic response to beta-2 adrenergic receptor (ADRB2) agonists, such as salbutamol, is observed. The aim of this project was to investigate the molecular mechanisms that underlie the beneficial effects of ADRB2 agonists. Firstly, NMJ functioning was modelled in vitro by studying AChR clusters formed on cultured C2C12 mouse myotubes in the presence of WT DOK7. Overexpression of mutant DOK7 led to a significant reduction in the number of AChR clusters, explaining the pathogenic effect of the mutation. Importantly, incubation of myotubes with salbutamol increased the number of AChR clusters and their stability. The results provide the first evidence that ADRB2 agonists directly affect proteins located at the NMJ. However, this disease model suffers from limitations. The rest of the thesis focussed on developing alternative cell culture models to explore the AChR clustering pathway. The first model combined optogenetics and fluorescence lifetime microscopy to study the effects of ADRB2 activation on AChR cluster stability in single live cells. The second used CRISPR/Cas9 genome editing tools to directly introduce Dok7 mutations to the genome of C2C12 cells, thereby overcoming some of the drawbacks associated with DOK7 overexpression. Further manipulations of these novel model systems will be used in the future to examine in more detail the molecular events underlying the pathogenic effects of DOK7 mutations and the mechanisms of ADRB2 agonists.

Investigation into the effects of specific muscarinic acetylcholine receptor antagonists on the myocardium in pre-clinical conditions of ischaemia reperfusion injury and oxidative stress model

Khan, J.

January 2015

Muscarinic acetylcholine receptors (mAChRs) are G-protein coupled receptors that mediate various actions of Acetylcholine (ACh) in the central nervous system and peripheral nervous system. In mammals, five distinct mAChR subtypes (M1-M5) have been recognised with the M2 subtype being predominantly present in the heart. The mAChR antagonists are routinely used for the treatment of various pathophysiological conditions including respiratory conditions. However, it has been postulated that mAChR antagonists may increase morbidity and mortality in chronic obstructive pulmonary disorder (COPD) and asthma patients with underlying cardiovascular disease, raising concerns regarding the cardiovascular safety of these agents. The current study was therefore undertaken to investigate the effects of individual mAChR antagonists in the setting of myocardial ischaemia reperfusion injury and oxidative stress models. We also investigated whether the inhibition of the mitochondrial permeability transition pore (MPTP) with cyclosporine-A (CsA) in the presence and absence of individual mAChR antagonists provided protection against ischaemia reperfusion injury. Furthermore, we also aimed to investigate the intracellular signalling pathway associated with mAChRs antagonists mediated myocardial injury under the stress conditions. Langendorff results showed that the non-selective M1-M3 mAChR antagonist, ipratropium bromide, the M2 mAChR antagonist, AF-DX 116 and the M3 mAChR antagonist, DAU 5884 significantly increased the infarct size to risk ratio of the heart in conditions of ischaemia and reperfusion. Detrimental effects of AF-DX 116 and DAU 5884 were abrogated by co-treatment of these drugs with mAChR agonist, acetylcholine (ACh) and/or CsA. Cell viability data of isolated cardiac myocytes revealed that AF-DX 116 and DAU 5884 caused a concentration dependent decrease in the viability of cardiac myocytes as well as causing a reduction in the time taken to depolarisation and hypercontracture under oxidative stress. AF-DX 116 and DAU 5884 significantly increased the levels of p-SAPK/JNK and decreased the levels of p-Akt and p-ERK. In addition, ACh and CsA showed to activate p-Akt and p-ERK. To conclude, the data suggest that AF-DX 116 and DAU 5884 caused cardiotoxicity at cellular, tissue and protein level in conditions of ischaemia reperfusion injury and oxidative stress. Furthermore, inhibition of the mitochondrial transition pore with CsA protected against the AF-DX 116 and DAU 5884 induced injury via activation of the pro-survival proteins, p-Akt and p-ERK.

612.8

Differential modulation of T-type voltage gated calcium channels by G-protein coupled receptors.

Hildebrand, Michael Earl

11 1900

T-type voltage-gated calcium (Ca2+) channels play critical roles in controlling neuronal excitability, firing patterns, and synaptic plasticity, although the mechanisms and extent to which T-type Ca2+ channels are modulated by G-protein coupled receptors (GPCRs) remains largely unexplored. Investigations into T-type modulation within native neuronal systems have been complicated by the presence of multiple GPCR subtypes and a lack of pharmacological tools to separate currents generated by the three T-type isoforms; Cav3.1, Cav3.2, and Cav3.3. We hypothesize that specific Cav3 subtypes play unique roles in neuronal physiology due to their differential functional coupling to specific GPCRs. Co-expression of T-type channel subtypes and GPCRs in a heterologous system allowed us to identify the specific interactions between muscarinic acetylcholine (mAChR) or metabotropic glutamate (mGluR) GPCRs and individual Cav3 isoforms. Perforated patch recordings demonstrated that activation of Galpha<q/11>-coupled GPCRs had a strong inhibitory effect on Cav3.3 T-type Ca2+ currents but either no effect or a stimulating effect on Cav3.1 and Cav3.2 peak current amplitudes. Further study of the inhibition of Cav3.3 channels by a specific Galpha<q/11>-coupled mAChR (M1) revealed that this reversible inhibition was associated with a concomitant increase in inactivation kinetics. Pharmacological and genetic experiments indicated that the M1 receptor-mediated inhibition of Cav3.3 occurs specifically through a Galpha<q/11> signaling pathway that interacts with two distinct regions of the Cav3.3 channel. As hypothesized, the potentiation of Cav3.1 channels by a Galpha<q/11>-coupled mGluR (mGluR1) initially characterized in the heterologous system was also observed in a native neuronal system: the cerebellar Purkinje cell (PC). In recordings on PCs within acute cerebellar slices, we demonstrated that the potentiation of Cav3.1 currents by mGluR1 activation is strongest near the threshold of T-type currents, enhancing the excitability of PCs. Ultrafast two-photon Ca2+ imaging demonstrated that the functional coupling between mGluR1 and T-type transients occurs within dendritic spines, where synaptic integration and plasticity occurs. A subset of these experiments utilized physiological synaptic activation and specific mGluR1 antagonists in wild-type and Cav3.1 knock-out mice to show that the mGluR1-mediated potentiation of Cav3.1 T-type currents may promote synapse-specific Ca2+ signaling in response to bursts of excitatory inputs. / Medicine, Faculty of / Graduate

T-type modulation

Calcium channel receptor

Glutamate

Acetylcholine

Purkinje cell

Electrophysiology

Effects of Pharmacological Manipulation of the Serotonergic/Cholinergic Systems on Sleep Structure in Two 5-HT1A Genotypes: Implications for a Model of Depression

Biard, Kathleen

January 2015

The serotonergic and cholinergic systems are jointly involved in regulating sleep but this balance is theorized to be disturbed in depressed individuals (Janowsky 1972, Jouvet 1972). One potential cause of disturbed neurotransmission is genetic predisposition. The G(-1019) allele of the 5-HT1A receptor predicts an increased risk for depression compared to the wild-type C(-1019) allele. The goal of this study was to use pharmacological probes in normal controls to model the serotonergic/cholinergic imbalance of depression and its associated abnormalities in sleep structure while controlling for 5-HT1A receptor genotype. Seventeen healthy female participants homozygous for either C (n=11) or G (n=6) alleles, age 18-27 years were tested on four non-consecutive nights. Participants were given galantamine (an anti-acetylcholinesterase), buspirone (a serotonergic agonist), both drugs together, or placebos before sleeping. Buspirone suppressed tonic REM: there was a significant increase in REM latency (p<0.001). Galantamine increased tonic REM sleep, leading to more time spent in stage REM (p<0.001) and shorter REM latency (p<0.01). Galantamine and buspirone given together tended to negate the effects of each other on REM sleep measures but disrupted sleep more than either drug alone, showing lower SE and N3% and increased awakenings, Wake% and N1% (p<0.019). There was no main effect of genotype nor was there a significant multivariate interaction between genotype and drug condition. These findings are partially consistent with the literature about sleep in depression, notably short REM latency, higher percentage of total sleep time spent in REM, and increased sleep fragmentation. The C/G mutation in the 5-HT1A receptor does not appear to cause noticeable differences in the sleep patterns of healthy young females.

Sleep

Depression

Sleep structure

REM

serotonin

acetylcholine

buspirone

galantamine

neurotransmission

5-HT1A receptor

genetic risk factors

The Structural Basis for Lipid-Dependent Uncoupling of the Nicotinic Acetylcholine Receptor

Sun, Jiayin

January 2017

In lipid membranes lacking activating lipids, the nicotinic acetylcholine receptor adopts an uncoupled conformation that binds ligand, but does not transition into an open conformation. Understanding the mechanisms of lipid-dependent uncoupling is essential to understanding lipid-nAChR interactions, which may be implicated in pathological conditions such as nicotine addition. Here, I tested two structural features of a proposed uncoupling method to elucidate the mechanism of lipid-dependent uncoupling. First, infrared measurements and electrophysiological characterization performed in prokaryotic homologues indicate that lipid sensitivity is largely controlled by the most peripheral α-helix in the transmembrane domain, M4. My data show that tighter association of M4 with the adjacent M1 and M3 transmembrane α-helices decreases a receptor’s propensity to adopt a lipid-dependent uncoupled conformation. Second, I indirectly tested the hypothesis that uncoupling results from a conformational change at the extracellular/transmembrane domain interface that leads to an increased separation between the two domains and ultimately to a constriction of the channel pore. Finally, biophysical studies presented in this dissertation shed light on the complex binding of a number of non-competitive channel blockers to the nicotinic acetylcholine receptor channel pore in both the resting and desensitized states. The data provide further insight into the structural rearrangements that occur upon uncoupling of ligand binding and gating in the nicotinic acetylcholine receptor.

Structure

Lipid-protein interactions

Mechanism

Nicotinic acetylcholine receptor

Uncoupling

ELIC

Pentameric ligand-gated ion channels

Réponses des circuits corticaux aux afférences sous-corticales impliquées dans les états de vigilance / Responses of cortical circuits to subcortical inputs involved in the modulation of vigilance states

Hay, Audrey

05 September 2014

Au cours de cette thèse, j’ai cherché à comprendre comment trois structures impliquées dans la modulation des états vigilance agissaient sur la dynamique du réseau cortical. Les noyaux du thalamus non-spécifique sont impliqués dans le transfert d’informations contextuelles. À l’inverse, les noyaux spécifiques convoient des informations sensorielles vers le néocortex. Ces entrées sensorielles activent fortement les interneurones fast-spiking du cortex qui limite la durée de l’activation du réseau. À l’inverse, mes travaux montrent que les entrées contextuelles entraînent l’activation des interneurones lents, générant une activation prolongée du réseau cortical. D’autre part, je me suis intéressée à la couche VIb du néocortex dont les neurons sont sensibles à deux modulateurs des états de vigilance : l’orexine et à l’acétylcholine. J’ai pu montrer que la couche VIb projette principalement dans les couches corticales infragranulaires où elle pourrait être servir d’amplificateur dépendant de l’orexine des entrées du thalamus non-spécifique. Finalement, j’ai cherché à comprendre si la transmission nicotinique endogène était médiée par une synapse ou par transmission volumique. Pour cela, j’ai comparé les courants nicotinques reçus par les neurones des couches I et VI. Mes travaux mettent en évidence l’existence d’une synapse mixte comprenant des récepteurs α4β2 et α7 dans la couche I et d’une synapse simple comprenant uniquement α4β2 en couche VI. Ces synapses sont activées par la stimulation phasique des neurones cholinergiques. Néanmoins mes résultats suggèrent aussi l’existence de récepteurs α4β2 extra-synaptiques activés par la libération tonique des fibres cholinergiques. / During my PhD, I investigated how three structures involved in the modulation of arousal states act on the dynamic of the cortical network. Nuclei of the non-specific thalamus convey information on environmental and behavioral context, whereas specific nuclei relay sensory information to the neocortex. These sensory inputs activate strongly the fast-spiking interneurons of the neocortex that limits response duration of the network. Conversely, I showed that contextual inputs target mainly the slow adapting interneurons allowing a long-lasting activation of the cortical network. I have also been interesting in the layer VIb of the neocortex whose neurons are sensitive to orexin and acetylcholine, two main modulators of the arousal states. I showed that layer VIb projects mainly onto infragranular cortical layers where its activation should act as an orexin-dependent amplifier of the non-specific thalamic inputs. Finally, I tried to decipher whether the endogenous nicotinic transmission is mediated by a synapse or by volume transmission. To do that, I compared nicotinic currents received by layer I interneurons and layer VI pyramidal cells. I showed that nicotinic transmission is likely to be mediated by a mixed synapse comprising α4β2 and α7 receptors in layer I and a simple α4β2 containing synapse in layer VI. These synapses are activated by a phasic stimulation of the cholinergic fibers. However, my results also suggest that a tonic activation of these fibers recruits extra-synaptic α4β2 receptors in both layer I and VI neurons.

Réseau cortical

Acétylcholine

Orexine

Couche VIb

Thalamus non-Spécifique

Optogénétique

Cortical network

Acetylcholine

616.8