Evaluation of isolated dorsal root ganglion cells as a model to study neural calcium overload / E.E. Jordaan

Jordaan, Esaias Engelbertus

January 2004

Background and motivation: The event of neural Ca2+ overload is known to have several deleterious effects resulting in cell death caused by ischaemia, hypoglycaemia, hypoxia and several neurodegenerative diseases such as Alzheimer's disease, Parkinson's disease and AIDS-related dementia. In vitro models for the investigation of the mechanisms involved in Ca2+ overload include brain slice preparations, neuronal cultures as well as acutely isolated neurons, mostly from the hippocampus and cortical brain areas. Additional models for investigating Ca2+ overload may bring about new knowledge to areas of the phenomenon that are still unresolved. Methodology: In this study, several theoretical Ca2+ overload-related interventions were combined aimed at inducing cell death in acutely isolated rat dorsal root ganglia. To elucidate the mechanism/s involved in the cell death observed following exposure to this intervention, the effects of several alterations to the intervention's composition were assessed. This examination was extended by the addition of several recognized and potential protective compounds to the intervention. Cell death was indicated by the trypan blue exclusion assay and recorded after 18 hours exposure to the interventions by counting live and dead neurons under a light microscope. Results and conclusions: The goal was to evaluate the possible application of dorsal root ganglia as a model for neural Ca2+ overload outside the brain. Since Ca2+w as required for cell death to be induced, it is concluded that the observed cell death was indeed primarily due to Ca2+ overload. Besides extracellular Ca2+, KC1-induced depolarization was also required for cell death to be induced, while the antagonists did not demonstrate significant protection against cell death. Based on the results, the mechanism of Ca2+ overload could not be defined beyond doubt, but the voltage activated Ca2+ channels are likely to be involved. / Thesis (M.Sc. (Physiology))--North-West University, Potchefstroom Campus, 2005.

Glutamate excitotoxicity

Model

Dorsal root ganglia

Viability

Trypan blue

NMDAR channels.

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.

T-type modulation

Calcium channel receptor

Glutamate

Acetylcholine

Purkinje cell

Electrophysiology

Neural Mechanisms of Temporomandibular Joint and Masticatory Muscle Pain

Lam, David King

19 January 2009

The underlying nociceptive mechanisms in temporomandibular joint (TMJ) and masticatory muscles in many pain conditions are still unclear, largely due to the limited study of peripheral and central neural mechanisms affecting craniofacial musculoskeletal tissues. This study provided evidence in support of Hypothesis 1: Peripheral glutamatergic and capsaicin-sensitive mechanisms modulate the properties of primary afferents and brainstem neurons processing deep craniofacial nociceptive information. Effects of glutamate and capsaicin injected into the receptive field of deep craniofacial nociceptive afferents or TMJ of TMJ-responsive nociceptive neurons in trigeminal subnucleus caudalis/upper cervical cord (Vc/UCC) were studied in halothane-anesthetized rats. When injected alone, glutamate and capsaicin activated and induced peripheral sensitization in many afferents. Following glutamate injection, capsaicin-evoked activity was greater than that evoked by capsaicin alone, whereas following capsaicin injection, glutamate-evoked responses were similar to those of glutamate alone. When injected alone, glutamate and capsaicin also activated and induced central sensitization in most Vc/UCC neurons. Following glutamate injection, capsaicin evoked greater activity and less sensitization compared with capsaicin alone, whereas following capsaicin, glutamate was less effective in activating and sensitizing most Vc/UCC neurons. This apparent desensitizing effect of capsaicin on glutamate-evoked excitability of Vc/UCC neurons contrasts with the lack of capsaicin-induced modulation of glutamate-evoked afferent excitability, suggesting that peripheral and central sensitization may be differentially involved in the nociceptive effects of glutamate and capsaicin applied to deep craniofacial tissues. Further evidence of glutamate-capsaicin interactions was documented in the attenuation by TMJ pre-injection of glutamate receptor antagonists of jaw muscle activity reflexly evoked by TMJ injection of capsaicin. Moreover, additional findings support Hypothesis 2: Surgical cutaneous incision modulates the properties of brainstem neurons processing deep craniofacial nociceptive information. TMJ-responsive nociceptive Vc/UCC neurons could be activated by surgical incision of the skin overlying the TMJ and this incision-induced afferent barrage caused nociceptive neurons to be temporarily refractory to further capsaicin-induced central sensitization. These novel findings suggest that peripheral glutamate and capsaicin receptor mechanisms as well as surgical cutaneous incision may be involved in the nociceptive processing of deep craniofacial afferent inputs and may interact to modulate both activation as well as sensitization evoked from these tissues.

excitatory amino acid

TRPV1

glutamate

capsaicin

incision

trigeminal

pre-emptive analgesia

0317

Neural Mechanisms of Temporomandibular Joint and Masticatory Muscle Pain

Lam, David King

19 January 2009

The underlying nociceptive mechanisms in temporomandibular joint (TMJ) and masticatory muscles in many pain conditions are still unclear, largely due to the limited study of peripheral and central neural mechanisms affecting craniofacial musculoskeletal tissues. This study provided evidence in support of Hypothesis 1: Peripheral glutamatergic and capsaicin-sensitive mechanisms modulate the properties of primary afferents and brainstem neurons processing deep craniofacial nociceptive information. Effects of glutamate and capsaicin injected into the receptive field of deep craniofacial nociceptive afferents or TMJ of TMJ-responsive nociceptive neurons in trigeminal subnucleus caudalis/upper cervical cord (Vc/UCC) were studied in halothane-anesthetized rats. When injected alone, glutamate and capsaicin activated and induced peripheral sensitization in many afferents. Following glutamate injection, capsaicin-evoked activity was greater than that evoked by capsaicin alone, whereas following capsaicin injection, glutamate-evoked responses were similar to those of glutamate alone. When injected alone, glutamate and capsaicin also activated and induced central sensitization in most Vc/UCC neurons. Following glutamate injection, capsaicin evoked greater activity and less sensitization compared with capsaicin alone, whereas following capsaicin, glutamate was less effective in activating and sensitizing most Vc/UCC neurons. This apparent desensitizing effect of capsaicin on glutamate-evoked excitability of Vc/UCC neurons contrasts with the lack of capsaicin-induced modulation of glutamate-evoked afferent excitability, suggesting that peripheral and central sensitization may be differentially involved in the nociceptive effects of glutamate and capsaicin applied to deep craniofacial tissues. Further evidence of glutamate-capsaicin interactions was documented in the attenuation by TMJ pre-injection of glutamate receptor antagonists of jaw muscle activity reflexly evoked by TMJ injection of capsaicin. Moreover, additional findings support Hypothesis 2: Surgical cutaneous incision modulates the properties of brainstem neurons processing deep craniofacial nociceptive information. TMJ-responsive nociceptive Vc/UCC neurons could be activated by surgical incision of the skin overlying the TMJ and this incision-induced afferent barrage caused nociceptive neurons to be temporarily refractory to further capsaicin-induced central sensitization. These novel findings suggest that peripheral glutamate and capsaicin receptor mechanisms as well as surgical cutaneous incision may be involved in the nociceptive processing of deep craniofacial afferent inputs and may interact to modulate both activation as well as sensitization evoked from these tissues.

excitatory amino acid

TRPV1

glutamate

capsaicin

incision

trigeminal

pre-emptive analgesia

0317

Aspects of Nitrogen Metabolism in Symbiotic Cnidarians

Boutilier, Ryan Michael

24 August 2012

The pathway of seawater ammonium assimilation and influence of light on amino acid synthesis remain unresolved in cnidarian symbioses. Labeled ammonium (10 μM 15NH4Cl) in seawater was used to trace the pathway of the incorporation into amino acids in host tissue, Zoanthus sp., and zooxanthellae, Symbiodinium microadriaticum. Freshly isolated zooxanthellae were exposed to 20 μM 15NH4Cl with coral homogenate to evaluate the role of host factors on amino acid synthesis. High performance liquid chromatography and mass spectrometry was used to measure percent labeling and concentrations of amino acids. In zooxanthellae, ammonium was assimilated into glutamine likely via glutamine synthetase and into glutamate via glutamine 2-oxoglutarate amidotransferase. Interrupting photosynthesis with DCMU did not inhibit glutamine and tryptophan synthesis however reduced the 15N-enrichment of glutamate, aspartate, and ornithine in zooxanthellae, as well as arginine, ornithine, and lysine in host tissue. Coral homogenate had little effect on the 15N-enrichment of glutamine, aspartate, and alanine in freshly isolated zooxanthellae. Evidence is presented to support the uptake of ammonium ions and data shows that glutamine and not glutamate is translocated to the coral host.

Modulation de l’expression du transporteur vésiculaire du glutamate : implication dans la plasticité des neurones dopaminergiques

Dal Bo, Grégory

07 1900

De nombreuses études ont établi que la majorité des neurones libèrent plus qu’une substance chimique. Il est bien connu que les neurones peuvent co-exprimer et co-libérer des neuropeptides en plus de leur neurotransmetteur, mais des évidences de la co-libération de deux petits neurotransmetteurs à action rapide se sont accumulées récemment. Des enregistrements électrophysiologiques ont aussi montré que des neurones sérotoninergiques et dopaminergiques isolés peuvent libérer du glutamate quand ils sont placés en culture. De plus, la présence de glutamate et de glutaminase a été détectée dans des neurones sérotoninergiques, dopaminergiques et noradrénergiques par immunomarquage sur des tranches de cerveau. Malheureusement, en considérant le rôle métabolique du glutamate, sa détection immunologique n’est pas suffisante pour assurer le phénotype glutamatergique d’un neurone. Récemment, la découverte de trois transporteurs vésiculaires du glutamate (VGLUT1-3) a grandement facilité l’identification des neurones glutamatergiques. Ces transporteurs sont nécessaires pour la libération de glutamate et constituent les premiers marqueurs morphologiques du phénotype glutamatergique. Il a été démontré que des neurones noradrénergiques expriment VGLUT2 et que des neurones sérotoninergiques expriment VGLUT3. Mais aucune évidence d’expression d’un des sous-types de VGLUT n’a été reportée pour les neurones dopaminergiques. Le but de notre travail était d’identifier quel sous-type de VGLUT est exprimé par les neurones dopaminergiques mésencéphaliques, et de déterminer si le phénotype glutamatergique de ces neurones peut être modulé dans des conditions particulières. Premièrement, nous avons utilisé des microcultures pour isoler les neurones dopaminergiques et des doubles marquages immunocytochimiques pour observer l’expression de VGLUT dans les neurones positifs pour la tyrosine hydroxylase (TH). Nous avons montré que la majorité (80%) des neurones TH+ isolés exprime spécifiquement VGLUT2. Cette expression est précoce au cours du développement in vitro et limitée aux projections axonales des neurones dopaminergiques. Toutefois, cette forte expression in vitro contraste avec la non-détection de ce transporteur dans les rats adultes in vivo. Nous avons décidé ensuite de regarder si l’expression de VGLUT2 pouvait être régulée pendant le développement cérébral de jeunes rats et sous des conditions traumatiques, par double hybridation in situ. Entre 14 et 16 jours embryonnaires, les marquages de VGLUT2 et de TH montraient une superposition significative qui n’était pas retrouvée à des stades ultérieurs. Dans le mésencéphale de jeunes rats postnataux, nous avons détecté l’ARNm de VGLUT2 dans environs 1-2% des neurones exprimant l’ARNm de TH dans la substance noire et l’aire tegmentaire ventrale (ATV). Pour explorer la régulation de l’expression de VGLUT2 dans des conditions traumatiques, nous avons utilisé la 6-hydroxydopamine (6-OHDA) pour léser les neurones dopaminergiques dans les jeunes rats. Dix jours après la chirurgie, nous avons trouvé que 27% des neurones dopaminergiques survivants dans l’ATV exprimaient l’ARNm de VGLUT2 dans les rats 6-OHDA. Finalement, nous avons observé la colocalisation de la protéine VGLUT2 dans les terminaisons TH positives par microscopie électronique. Dans les rats normaux, la protéine VGLUT2 est retrouvée dans 28% des terminaisons axonales TH dans le noyau accumbens. Dans les rats lésés à la 6-OHDA, nous avons observé une diminution considérable des terminaisons TH positives, et une augmentation dans la proportion (37%) des terminaisons dopaminergiques présentant du VGLUT2. Nos résultats suggèrent que le phénotype glutamatergique des neurones dopaminergiques est régulé au cours du développement, peut être réactivé dans des états pathologiques, et que ces neurones peuvent libérer du glutamate dans conditions spécifiques. / Numerous studies have established that the majority of neurons release more than one chemical substance. It is well known that neurons can co-express and co-release neuropeptides in addition to their neurotransmitter, but evidence of co-release of two small and fast-acting neurotransmitters has been accumulated recently. Electrophysiological recordings have also shown that isolated serotonine and dopamine neurons can release glutamate as a co-transmitter when they are placed in culture. Furthermore, the presence of glutamate and glutaminase has been detected in serotonine, dopamine and noradrenaline neurons by immunolabelling in brain slices. Unfortunately, considering the metabolic role of glutamate, its immunodetection is not sufficient to assert the glutamatergic phenotype of a neuron. Recently, the discovery of three vesicular glutamate transporters (VGLUT1-3) has greatly facilitated the identification of glutamate neurons. These transporters are necessary for the glutamate release by neurons and constitute the first molecular markers of a glutamatergic phenotype. Interestingly, it was demonstrated that some noradrenaline neurons express VGLUT2 and that some serotonin neurons express VGLUT3. But no evidence for expression of any VGLUT subtypes was initially reported for dopamine neurons. The goal of our work was to identify which VGLUT subtype is expressed by mesencephalic dopamine neurons, and to determine if the glutamatergic phenotype of these neurons can be modulated under specific conditions. First, we used microcultures to isolate dopamine neurons and double immunocytochemistry to visualize VGLUT expression in tyrosine hydroxylase (TH) positive neurons. We showed that the majority (80%) of isolated TH+ neurons express specifically VGLUT2. This expression occurred early during in vitro development and was limited to axonal projections of dopamine neurons. However, this strong expression in vitro contrasted with the lack of detection of this transporter in adult rats in vivo. We next decided to investigate if VGLUT2 expression could be regulated during brain development of young rats and under traumatic conditions, using double in situ hybridization. At embryonic days 14 to 16, VGLUT2 and TH labelling displayed significant overlap which was no longer found at later stages. In postnatal mesencephalon of young rats, we detected VGLUT2 mRNA in approximately 1-2% of neurons expressing TH mRNA in the substantia nigra and in ventral tegmental area (VTA). To explore the regulation of VGLUT2 expression under traumatic condition, we used 6-hydroxydopamine (6-OHDA) to damage dopamine neurons in young rats. Ten days post-surgery, we found that 27% of surviving dopamine neurons in the VTA expressed VGLUT2 mRNA in 6-OHDA animals. Finally, we observed the colocalisation of VGLUT2 protein in TH positive terminals by electron microscopy. In normal rats, VGLUT2 protein was found in 28% of TH positive axon terminals in nucleus accumbens. In 6 OHDA-lesioned rats, we observed a considerable reduction of TH positive terminals, and an increase in the proportion (37%) of dopamine terminals displaying VGLUT2. Our results suggest that the glutamatergic phenotype of dopamine neurons is developmentally regulated, can be reactivated under pathological states, and that these neurons are able to release glutamate under specific conditions.

dopamine

mésencéphale

ATV

glutamate

VGLUT2

Parkinson

6-OHDA

mesencephalon

VTA

Glutamate in the medial prefrontal cortex in the early postpartum

Mitchell, Nicholas D

Unknown Date

No description available.

Glutamate

Neuroimaging

Postpartum Depression

Prefrontal Cortex

Magnetic Resonance Spectroscopy

Neuroactive Steroids

Données nouvelles sur l’innervation à dopamine du striatum et son co-phénotype glutamatergique

Bérubé-Carrière, Noémie

04 1900

Une sous-population des neurones à dopamine (DA) du mésencéphale ventral du rat et de la souris étant connue pour exprimer l'ARN messager du transporteur vésiculaire 2 du glutamate (VGLUT2), nous avons eu recours à l'immunocytochimie en microscopie électronique, après simple ou double marquage de l'enzyme de synthèse tyrosine hydroxylase (TH) et de VGLUT2, pour déterminer la présence de l'une et/ou l'autre protéine dans les terminaisons (varicosités) axonales de ces neurones et caractériser leur morphologie ultrastructurale dans diverses conditions expérimentales. Dans un premier temps, des rats jeunes (P15) ou adultes (P90), ainsi que des rats des deux âges soumis à l'administration intraventriculaire cérébrale de la cytotoxine 6-hydroxydopamine (6-OHDA) dans les jours suivant la naissance, ont été examinés, afin d'étayer l'hypothèse d'un rôle de VGLUT2 au sein des neurones DA, au cours du développement normal ou pathologique de ces neurones. Chez le jeune rat, ces études ont montré: i) la présence de VGLUT2 dans une fraction importante des varicosités axonales TH immunoréactives du coeur du noyau accumbens ainsi que du néostriatum; ii) une augmentation de la proportion de ces terminaisons doublement marquées dans le noyau accumbens par suite de la lésion 6-OHDA néonatale; iii) le double marquage fréquent des varicosités axonales appartenant à l'innervation DA aberrante (néoinnervation), qui se développe dans la substance noire, par suite de la lésion 6-OHDA néonatale. Des différences significatives ont aussi été notées quant à la dimension des terminaisons axonales marquées pour la TH seulement, VGLUT2 seulement ou TH et VGLUT2. Enfin, à cet âge (P15), toutes les terminaisons doublement marquées sont apparues dotées d'une spécialisation membranaire synaptique, contrairement aux terminaisons marquées pour la TH ou pour VGLUT2 seulement. Dans un deuxième temps, nous avons voulu déterminer le devenir du double phénotype chez le rat adulte (P90) soumis ou non à la lésion 6-OHDA néonatale. Contrairement aux observations recueillies chez le jeune rat, nous avons alors constaté: i) l'absence complète de terminaisons doublement marquées dans le coeur du noyau accumbens et le néostriatum d'animaux intacts, de même que dans les restes de la substance noire des animaux 6-OHDA lésés; ii) une très forte baisse de leurnombre dans le coeur du noyau accumbens des animaux 6-OHDA lésés. Ces observations, suggérant une régression du double phénotype TH/VGLUT2 avec l'âge, sont venues renforcer l'hypothèse d'un rôle particulier d'une co-libération de glutamate par les neurones mésencéphaliques DA au cours du développement. Dans ces conditions, il est apparu des plus intéressants d'examiner l'innervation DA méso-striatale chez deux lignées de souris dont le gène Vglut2 avait été sélectivement invalidé dans les neurones DA du cerveau, ainsi que leurs témoins et des souris sauvages. D'autant que malgré l'utilisation croissante de la souris en neurobiologie, cette innervation DA n'avait jamais fait l'objet d’une caractérisation systématique en microscopie électronique. En raison de possibles différences entre le coeur et la coque du noyau accumbens, l'étude a donc porté sur les deux parties de ce noyau ainsi que le néostriatum et des souris jeunes (P15) et adultes (P70-90) de chaque lignée, préparées pour l'immunocytochimie de la TH, mais aussi pour le double marquage TH et VGLUT2, selon le protocole précédemment utilisé chez le rat. Les résultats ont surpris. Aux deux âges et quel que soit le génotype, les terminaisons axonales TH immunoréactives des trois régions sont apparues comparables quant à leur taille, leur contenu vésiculaire, le pourcentage contenant une mitochondrie et une très faible incidence synaptique (5% des varicosités, en moyenne). Ainsi, chez la souris, la régression du double phénotype pourrait être encore plus précoce que chez le rat, à moins que les deux protéines ne soient très tôt ségréguées dans des varicosités axonales distinctes des mêmes neurones DA. Ces données renforcent aussi l’hypothèse d’une transmission diffuse (volumique) et d’un niveau ambiant de DA comme élément déterminant du fonctionnement du système mésostriatal DA chez la souris comme chez le rat. / Knowing that a subset of rat and mouse mesencephalic dopamine (DA) neurons expresses the mRNA of the vesicular glutamate transporter type 2 (VGLUT2), we used electron microscopic immunocytochemistry, after single or double labeling of the biosynthetic enzyme tyrosine hydroxylase (TH) and of VGLUT2, to determine the presence of one and/or both proteins in axon terminals (varicosities) of these neurons and characterize their ultrastructural morphology under various experimental conditions. At first, young (P15) or adult (P90) rats, subjected or not to cerebro-ventricular administration of the cytotoxin 6-hydroxydopamine (6-OHDA) a few days after birth, were examined in order to investigate the role of VGLUT2 in DA neurons during normal and pathological development of these neurons. In the young rats, these studies revealed: i) the presence of VGLUT2 in a significant fraction of TH immunoreactive varicosities in the core of the nucleus accumbens and the neostriatum; ii) an increase in the proportion of dually labeled terminals in the nucleus accumbens following neonatal 6-OHDA lesion; iii) frequent double labeling of TH varicosities belonging to the aberrant DA innervation (neoinnervation) which develops in the substantia nigra following neonatal 6-OHDA lesion. Significant differences were also noted in the size of the axon terminals labeled for TH only, VGLUT2 only, or TH and VGLUT2. Finally, at this age (P15), all the dually labeled terminals appeared equipped with a synaptic membrane specialization, unlike the terminals labeled for TH or for VGLUT2 only. In a second step, we sought to determine the fate of the dual phenotype in adult rats (P90) subjected or not to the neonatal 6-OHDA lesion. In contrast with the observations made in young rats, we found: i) a complete absence of dually labeled terminals in the core of the nucleus accumbens and striatum of intact animals, as well as in the remains of the substantia nigra after neonatal 6-OHDA lesion; ii) a sharp decline of their number in the core of the nucleus accumbens of 6-OHDA-lesioned animals. These findings, suggesting a regression of the dual TH/VGLUT2 phenotype with age, reinforced the hypothesis of a specific role of the co-release of glutamate from midbrain DA neurons during development. Under these conditions, it was of considerable interest to examine the DA meso-striatal innervation in two strains of mice whose Vglut2 gene has been selectively invalidated in DA neurons, as well as in their control littermates and wild-type mice. This issue was particularly relevant with the increasing use of genetically modified mice in neurobiology; indeed, this DA innervation had never been systematically characterized by electron microscopy. Because of possible differences between the core and shell of the nucleus accumbens, the study included both parts of this nucleux as well as the striatum of young (P15) and adult (P70-90) mice of each strain, prepared for TH immunocytochemistry, and also for double labeling of TH and VGLUT2, according to the protocol previously used in rats. The results were surprising. At both ages, regardless of the genotype, the TH immunoreactive axon terminals of the three regions appeared comparable in size, vesicle content, percent with mitochondria, and exceeding low frequency of synaptic membrane specialization (5% of varicosities, on average). Thus, in mice, the regression of the dual phenotype might be even more precocious than in rats, unless the two proteins are segregated very early in different axon terminals of the same DA neurons. These data also strenghten the hypothesis of a diffuse (volume) transmission and of an ambient level of DA as determinant elements in the functioning of the meso-striatal DA system in mice as well as rats.

Dopamine

Glutamate

Noyau accumbens

Néostriatum

Substance noire

Terminaisons axonales

Co-localisation

Transmission diffuse

Immunocytochimie

Dopamine

Glutamate

Vesicular glutamate transporter type 2

Nucleus accumbens

Neostriatum

Substantia nigra

Axon terminals

Co-localisation

Diffuse transmission

Immunocytochemistry

Évaluation de l'activité sérotoninergique du cortex préfrontal médian dans un modèle animal de psychose

Labonté, Benoit

January 2007

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

Dizocilpine (MK-801)

Cortex préfrontal médian (CPFm)

Sérotonine (5-HT)

Glutamate (GLU)

Schizoprhénie

Role of the NR2 subunit composition and intracellular C-terminal domain in N-methy-D-aspartate receptor signalling

Martel, Marc-Andre´

January 2009

N-methyl-D-aspartate receptors (NMDARs) are glutamate-gated ionotropic receptors. When activated, NMDARs let extracellular sodium and calcium ions enter neurons. This calcium influx, depending on its duration, intensity and the presence of nearby signalling proteins can signal to synaptic plasticity. Additionally, physiological NMDAR activity promotes pro-survival cascades and gene transcription, whereas both lack of activation and overactivation of these receptors trigger pro-death signals. Several neurodegenerative pathologies such as stroke/ischemia and Alzheimer’s disease are thought to involve NMDAR overactivation, so-called “excitotoxicity”, but since NMDARs are important for normal neuronal physiology, potential therapeutical approaches needs to go beyond simple antagonism. Here, we studied the receptor subunit composition and the molecular cascades downstream of the receptor activation to try and isolate the pro-death pathways in NMDAR-mediated excitotoxicity. We found that the NR2 subunit composition did not dictate the type of NMDAR-mediated signals, as receptors comprised of NR2B subunits were able to signal to death, survival and plasticity. However, we also found that the intracellular tail of the NR2B subunit was more efficient at triggering neuronal death compared to the NR2A C-terminus, which suggests that different pro-death signalling complexes are associated to each subunit. Two pro-death signals, the p38 and c-Jun N-terminal kinase (JNK) cascades, are key mediators of neuronal excitotoxicity. In a non-neuronal cell line, NMDAR-mediated cell death could be reconstituted but was found to rely solely on JNK and not p38. This was due to the lack of pro-death signals from the NR2B-PDZ domain, a cytoplasmic interacting domain which forms a signalling cassette with the neuronal proteins PSD-95 and neuronal nitric oxide synthase. This PDZ-ligand recruits the p38 cascade in neurons, but was absent in non-neuronal cells. The pro-death p38 pathway could be inhibited in neurons by disrupting the PDZ domain interactions, which protects against excitotoxicity. This disruption was not affecting normal synaptic transmission, potentiation or survival signalling, suggesting that this could be a therapeutically viable avenue. Thus, this work has expanded the understanding of how NMDAR subunits and their cytoplasmic domains mediate signalling leading to a variety of cellular outcomes; a crucial point for the development of a strategy specifically targeting NMDAR- mediated pro-death signalling.

612.8