Evaluation of the Role of Astrocyte Glutamate Transport and of Synaptic NMDA Receptor Subtype Representation in the Pathogenesis of PTSD

Cotrone, Thomas Steven

22 June 2017

Post-traumatic stress disorder (PTSD) is a psychological disorder that can cause great social/economic hardship. Progress towards treating PTSD has been slow due to a lack of understanding of its pathogenesis. This dissertation aimed to address this issue by investigating the involvement of the astrocytic glutamate reuptake transporter, GLT-1, and regional differences in expression of NMDA receptor subtypes in the development of a rat model of PTSD. We hypothesized that impaired astrocytic glutamate reuptake inhibits long-term memory processes, and that concurrent presence of glucocorticoids (GCs) during situational trauma selectively inhibits fear extinction memory processes in the prefrontal cortex, but not of conditioned fear memory processes in the amygdala, due to differences between these brain regions in expression of NMDA receptor subtypes. The effect of GLT-1 manipulation was studied in vivo. Utilizing the Single Prolonged Stress (SPS) model of PTSD, rats were either exposed to SPS or not. Within these groups, rats were administered a saline sham, a GLT-1 facilitator (ceftriaxone (CEF)), or a GLT-1 inhibitor (dihydrokainic acid (DHK)). Using Classical Fear Conditioning (CFC) and Fear Extinction (EXT) paradigms, retention of fear extinction memories was measured to determine the effect of GLT-1 manipulation on SPS-induced behavior (i.e., impaired fear extinction retention). From the brain of each rat, the amygdala, hippocampus, and prefrontal cortex (PFC) were collected and expression of GLT-1, p-CREB (a molecular indicator of long-term memory), and glucocorticoid receptor (GR, a molecular indicator of a PTSD-like state) were quantified. Analysis of the behavioral data showed that SPS exposure alone reduced the retention of extinction memories, but CEF and DHK both eliminated this effect. Analysis of the brain tissues revealed that SPS induced an increase in GR expression in the hippocampus. SPS also increased GLT-1 expression, but not p-CREB, in the PFC and amygdala. To evaluate the involvement of regional differences in NMDA receptor subtype expression ex vivo, tissue sections of amygdala, hippocampus, and PFC were taken from SPS and non-SPS exposed rats. Synaptic transmission was stimulated in these tissues using bicuculline in the presence of glucocorticoids, NVP-AA077 (a NR2A NMDA receptor subtype inhibitor), or Ro-25 (a NR2B NMDA receptor subtype inhibitor). P-CREB was measured in the tissues treated with GCs to determine if GCs exert greater inhibition of long-term memory in the PFC (a region reported to express high NR2A) than in the amygdala (a region reported to express high NR2B). P-CREB was also measured in the tissues treated with NVP or Ro-25 to determine if these reported receptor profile differences could be demonstrated, and if they changed following SPS exposure. Contrary to the stated hypothesis, analysis of non-SPS exposed rats revealed that GCs, NVP, and Ro-25 decreased p-CREB in all three regions with no differences between regions. However, in the SPS exposed group, p-CREB was not decreased in PFC and hippocampal tissues treated with GCs, amygdalar and PFC tissues treated with NVP, and PFC tissue treated with Ro-25. Overall, the results of the in vivo experiment did not convincingly demonstrate a role of glutamate spill-over in the pathogenesis of PTSD, but did show that modulation of glutamate reuptake can mitigate some of the behavioral consequences of exposure to situational trauma. The results of the ex vivo experiment did not reveal evidence that regional differences in NMDA receptor profiles exist across the three regions analyzed, nor did they show that GCs exert a region specific inhibition of long-term memory formation. However, it was demonstrated that SPS may affect long-term memory by altering expression of synaptic NMDA receptors. This study provides evidence that glial cells may play a role in the pathogenesis of PTSD, and thus may serve as targets for future therapy. / Ph. D.

PTSD

astrocyte

GLT-1

NR2A

NR2B

glutamate reuptake

Contrôle des récepteurs du glutamate de type NMDA par leur site co-agoniste / Control or NMDA receptors through their co-agonist binding-site

Papouin, Thomas

06 October 2011

Le récepteur du glutamate de type N-méthyl-D-aspartate (NMDAR) est un transducteur clef dans la physiologie du système nerveux et dans nombre de ses pathologies, selon qu’il est localisé à la synapse ou en position extra-synaptique respectivement. Son activité est sous le contrôle étroit du ‘site-glycine’, dont l’activation est gouvernée par la disponibilité en coagoniste. Pourtant, on ignore encore largement les règles qui régissent cette étape limitante de l’activation des NMDARs in situ. Par ailleurs, l’ensemble des onnaissances actuelles suggère que les astrocytes pourraient contrôler les NMDARs dans le contexte des interactions entre cellules gliales et neurones, en particulier via la libération du gliotransmetteur D-sérine. Le principal objectif de ce travail de thèse a été de comprendre les modalités du contrôle endogène des NMDARs par leur site co-agoniste, dans la région CA1 de l’hippocampe. Nous avons porté notre attention, avant tout, sur les acteurs de ce contrôle : la glycine et la D-sérine, qui sont les ligands endogènes du site-co-agoniste. Nous nous sommes intéressés à leur contribution respective dans le contrôle des NMDARs, aux dynamiques de ce contrôle en fonction de l’activité neuronale, à ses variations en fonction de la localisation des NMDARs, ainsi qu’à ses modifications développementales. Nous montrons par des approches d’électrophysiologie que la D-sérine, et non la glycine, est le co-agoniste endogène des NMDARs à la synapse CA3-CA1 chez l’adulte. Elle est délivrée par les prolongements astrocytaires environnants, d’une manière qui est influencée par l’activité synaptique. Sa libération répond à un mécanisme vésiculaire et est dépendante de la signalisation calcique intra-astrocytaire. De cette manière, les astrocytes exercent un contrôle étroit et dynamique des NMDARs à l’état basal et au cours de phénomènes de plasticité synaptique. En contre partie, à l’inverse de leurs homologues localisés à la synapse, les NMDARs extrasynaptiques sont contrôlés par la glycine à l’âge adulte. Cette compartimentation spatiale est dictée par une disponibilité différentielle des deux co-agonistes aux différents sites. Elle est également favorisée par une composition en sous-unités des NMDARs synaptiques et extra-synaptiques différente qui leur confère une affinité distincte pour la glycine et la D-sérine. Enfin, le contrôle des NMDARs par la D-sérine astrocytaire observé à l’âge adulte n’est pas opérationnel à la naissance. En effet, il ne se met en place qu’au cours du premier mois post-natal, de façon concomitante au changement de composition en sous-unités des NMDARs. / N-methyl D-aspartate receptors (NMDARs) are central to many aspects of brain physiology and pathology, which they impact differently depending on their synaptic or extrasynaptic location, respectively. In addition to glutamate, they are gated by the necessary binding of a co-agonist on the so-called ‘glycine-binding site’. However, very little is known about the rules that govern the control of NMDARs through this site, in situ. Evidence now suggests that astrocytes could play a critical role in controlling NMDARs activity, in particular through the release of the gliotransmitter D-serine. In the present work, we aimed at understanding how NMDARs are endogenously controlled through their co-agonist binding site, in the CA1 region of rat hippocampus. We primarily focused on the role of two endogenous ligands of this site: glycine and D-serine. We investigated their relative contribution in the control of NMDARs at the different subcellular locations, the dynamics of such control according to synaptic activity, as well as possible changes during post-natal development. Using elecrophysiological approaches, we demonstrate that NMDARs are gated by Dserine, but not glycine, at CA3-CA1 synapses in adults. D-serine is supplied at least in part by surrounding astrocytes in an activity-dependant manner. Its release occurs in response to calcium signalling within the astrocyte and in a vesicular way. Correspondingly, we found astrocytic supply of D-serine to be essential for NMDARs-dependant functions such as synaptic plasticity. In contrast with their synaptic counterparts, extrasynaptic NMDARs are gated by endogenous glycine and not by D-serine. We provide evidence that this compartmentation relies on the differential availability of the two co-agonists at synaptic and extrasynaptic sites. Besides, due to differences in their subunit composition, synaptic and extrasynaptic NMDARs may have preferential affinity for D-serine and glycine respectively. Finally, we show that the control of the NMDAR co-agonist site is developmentally regulated. Early after birth, glycine is the endogenous co-agonist of synaptic NMDARs. The control exerted by D-serine only progressively appears during the first post-natal month, as the switch in NMDARs subunit composition occurs, suggesting a maturation of cellular interactions at the tripartite synapse.

Récepteur NMDA

D-serine

Glycine

Co-agoniste

Synapse tripartite

Astrocyte

Plasticité synaptique

Développement

Sous-unités NR2A & NR2B

Hippocampe

Extra-synaptique

NMDA receptor

D-serine

Glycine

Co-agonist

Tripartite synapse

Astrocyte

LTP

Development

NR2A- NR2B-subunits

Hippocampus

Extrasynaptic

Examination of NMDA receptor subunit prevalence and distribution in crude synaptic membranes purified from a mouse model of Rett syndrome.

Maliszewska-Cyna, Ewelina

17 February 2010

In this study we tested whether the prevalence or synaptic distribution of NMDA receptor subunits would be altered in the brain of the MeCP2-null mouse model of Rett syndrome. Detergent resistant membranes (DRMs) and post-synaptic densities (PSDs) were isolated from the synaptic membranes treated with TritonX-100, and resolved by sucrose density gradient centrifugation. Immunoblot analysis of the resulting density gradient fractions revealed that the relative distribution of the different NMDA receptor subunits between the DRM fractions, soluble fractions, and insoluble postsynaptic density fractions was preserved in the MeCP2-null brain. However, analysis of the overall NMDA receptor subunit prevalence within these fractions revealed a significant decrease in the expression of the NR1 and NR2A subunits, but not the NR2B subunit, in the MeCP2-null brain. The preservation of distribution of NMDAR subunits to the synaptic membranes, together with the decrease in NR1 and NR2A prevalence, suggest an imbalance in equilibrium between the mature and the immature synapses in a mouse model of Rett syndrome.

Rett syndrome

MeCP2

epigenetics

neurodevelopment

synaptic maturation

glutamate

NMDA receptor complex

NR2A

lipid rafts

postsynaptic density

discontinuous sucrose gradient

0719

0317

Examination of NMDA receptor subunit prevalence and distribution in crude synaptic membranes purified from a mouse model of Rett syndrome.

Maliszewska-Cyna, Ewelina

17 February 2010

In this study we tested whether the prevalence or synaptic distribution of NMDA receptor subunits would be altered in the brain of the MeCP2-null mouse model of Rett syndrome. Detergent resistant membranes (DRMs) and post-synaptic densities (PSDs) were isolated from the synaptic membranes treated with TritonX-100, and resolved by sucrose density gradient centrifugation. Immunoblot analysis of the resulting density gradient fractions revealed that the relative distribution of the different NMDA receptor subunits between the DRM fractions, soluble fractions, and insoluble postsynaptic density fractions was preserved in the MeCP2-null brain. However, analysis of the overall NMDA receptor subunit prevalence within these fractions revealed a significant decrease in the expression of the NR1 and NR2A subunits, but not the NR2B subunit, in the MeCP2-null brain. The preservation of distribution of NMDAR subunits to the synaptic membranes, together with the decrease in NR1 and NR2A prevalence, suggest an imbalance in equilibrium between the mature and the immature synapses in a mouse model of Rett syndrome.

Rett syndrome

MeCP2

epigenetics

neurodevelopment

synaptic maturation

glutamate

NMDA receptor complex

NR2A

lipid rafts

postsynaptic density

discontinuous sucrose gradient

0719

0317