The role of cell-type selective synaptic connections in rhythmic neuronal network activity in the hippocampus

Katona, Linda

January 2014

No description available.

612.8

Impact du genre et du modèle sur les mécanismes d’épileptogénèse dans le cerveau immature

Foadjo Awoume, Berline

04 1900

Les modèles kainate et pentylènetétrazole représentent deux modèles d’épilepsie du lobe temporal dont les conséquences à long terme sont différentes. Le premier est un modèle classique d’épileptogénèse avec crises récurrentes spontanées tandis que le second se limite aux crises aigües. Nous avons d’abord caractérisé les différents changements survenant dans les circuits excitateurs et inhibiteurs de l’hippocampe adulte de rats ayant subi des crises à l’âge immature. Ensuite, ayant observé dans le modèle fébrile une différence du pronostic lié au genre, nous avons voulu savoir si cette différence était aussi présente dans des modèles utilisant des neurotoxines. L’étude électrophysiologique a démontré que les rats KA et PTZ, mâles comme femelles, présentaient une hyperactivité des récepteurs NMDA au niveau des cellules pyramidales du CA1, CA3 et DG. Les modifications anatomiques sous-tendant cette hyperexcitabilité ont été étudiées et les résultats ont montré une perte sélective des interneurones GABAergiques contenant la parvalbumine dans les couches O/A du CA1 des mâles KA et PTZ. Chez les femelles, seul le DG était légèrement affecté pour les PTZ tandis que les KA présentaient, en plus du DG, des pertes importantes au niveau de la couche O/A. Les évaluations cognitives ont démontré que seuls les rats PTZ accusaient un déficit spatial puisque les rats KA présentaient un apprentissage comparable aux rats normaux. Cependant, encore une fois, cette différence n’était présente que chez les mâles. Ainsi, nos résultats confirment qu’il y a des différences liées au genre dans les conséquences des convulsions lorsqu’elles surviennent chez l’animal immature. / Kainate and pentylenetetrazole models represent two animal models of temporal lobe epilepsy in which long-term consequences differ. The first model is a classical model of epileptogenesis with spontaneous recurrent seizures while the second one is limited to acute seizures. We wanted to characterize the difference in changes which occur in excitatory and inhibitory systems of the hippocampus of adult males and females having suffered an episode of status epilepticus during the immature stage of life. Besides having noticed a difference between genders in the febrile model, our second objective was to see if this difference was also present in models using neurotoxins. Electrophysiology recordings indicated that KA and PTZ rats (both male and female) showed a hyperactivity of NMDA receptors in CA1, CA3 and DG pyramidal cells. Anatomical modifications causing hyperactivity were studied and results show a selective loss of specific GABA interneurons PV in the O/A layer of CA1 region of the hippocampus in KA and PTZ male rats. However in female rats, only the DG layer was slightly affected in PTZ while female KA presented losses in both DG and O/A layers. Cognitive evaluation indicated that only PTZ rats showed a spatial impairment since KA rats had a similar learning pattern as controls. However, once again, that difference was observed only in males and not in females. In summary, our results confirmed that there is a difference between genders regarding brain damages after having suffered an episode of status epilepticus during the immature stage.

Kainate

Kainate

Pentylènetétrazole

Pentylenetetrazole

Epilepsie

Epilepsy

Hippocampe

Hippocampus

Système excitateur

Excitatory system

Système inhibiteur

Inhibitory system

Séquelles cognitives

Cognitive consequences

Hyperexcitabilité

Hyperexcitability ∙

Cellules pyramidales

Pyramidal cells

Interneurones GABAergiques

GABA interneuron

Neocortical Interneuron Subtypes Show an Altered Distribution in a Rat Model of Maldevelopment Associated With Epileptiform Activity

Hays, Kimberly Lynne

01 January 2007

Cortical malformations as a result of altered development are a common cause of human epilepsy. The cellular mechanisms that render neurons of malformed cortex epileptogenic remain unclear. Using a rat model of the malformation of microgyria, a previous study showed an alteration in the number of immunocytochemically-identified parvalbumin cells, a GABAergic inhibitory interneurons subtype (Rosen et al., 1998). A second study showed no change in the total number of GABAergic neurons (Schwarz et al., 2000). Consequently, we hypothesize that interneuron subtypes are differentially affected by maldevelopment. The present study investigated (1) whether interneuron subtype identity is retained in malformed cortex, based on chemical content, and (2) whether the proportion of three chemical subtypes is altered in malformed cortex. Here we demonstrate that three non-overlapping subtype markers remain non-overlapping in malformed cortex, but show altered distributions. These findings suggest that an increase in one subpopulation of interneurons may compensate for a corresponding decrease in a second subset.

interneuron development

epilepsy

polymicrogyria

cortical development

somatostatin

neonatal freeze-lesions

parvalbumin

vasoactive intestinal peptide

fast spiking cells

low-threshold spiking cells

metabotropic glutamate receptors

stereology

immunohistochemistry

Anatomy

Medicine and Health Sciences

Nervous System

Impact du genre et du modèle sur les mécanismes d’épileptogénèse dans le cerveau immature

Foadjo Awoume, Berline

04 1900

Les modèles kainate et pentylènetétrazole représentent deux modèles d’épilepsie du lobe temporal dont les conséquences à long terme sont différentes. Le premier est un modèle classique d’épileptogénèse avec crises récurrentes spontanées tandis que le second se limite aux crises aigües. Nous avons d’abord caractérisé les différents changements survenant dans les circuits excitateurs et inhibiteurs de l’hippocampe adulte de rats ayant subi des crises à l’âge immature. Ensuite, ayant observé dans le modèle fébrile une différence du pronostic lié au genre, nous avons voulu savoir si cette différence était aussi présente dans des modèles utilisant des neurotoxines. L’étude électrophysiologique a démontré que les rats KA et PTZ, mâles comme femelles, présentaient une hyperactivité des récepteurs NMDA au niveau des cellules pyramidales du CA1, CA3 et DG. Les modifications anatomiques sous-tendant cette hyperexcitabilité ont été étudiées et les résultats ont montré une perte sélective des interneurones GABAergiques contenant la parvalbumine dans les couches O/A du CA1 des mâles KA et PTZ. Chez les femelles, seul le DG était légèrement affecté pour les PTZ tandis que les KA présentaient, en plus du DG, des pertes importantes au niveau de la couche O/A. Les évaluations cognitives ont démontré que seuls les rats PTZ accusaient un déficit spatial puisque les rats KA présentaient un apprentissage comparable aux rats normaux. Cependant, encore une fois, cette différence n’était présente que chez les mâles. Ainsi, nos résultats confirment qu’il y a des différences liées au genre dans les conséquences des convulsions lorsqu’elles surviennent chez l’animal immature. / Kainate and pentylenetetrazole models represent two animal models of temporal lobe epilepsy in which long-term consequences differ. The first model is a classical model of epileptogenesis with spontaneous recurrent seizures while the second one is limited to acute seizures. We wanted to characterize the difference in changes which occur in excitatory and inhibitory systems of the hippocampus of adult males and females having suffered an episode of status epilepticus during the immature stage of life. Besides having noticed a difference between genders in the febrile model, our second objective was to see if this difference was also present in models using neurotoxins. Electrophysiology recordings indicated that KA and PTZ rats (both male and female) showed a hyperactivity of NMDA receptors in CA1, CA3 and DG pyramidal cells. Anatomical modifications causing hyperactivity were studied and results show a selective loss of specific GABA interneurons PV in the O/A layer of CA1 region of the hippocampus in KA and PTZ male rats. However in female rats, only the DG layer was slightly affected in PTZ while female KA presented losses in both DG and O/A layers. Cognitive evaluation indicated that only PTZ rats showed a spatial impairment since KA rats had a similar learning pattern as controls. However, once again, that difference was observed only in males and not in females. In summary, our results confirmed that there is a difference between genders regarding brain damages after having suffered an episode of status epilepticus during the immature stage.

Kainate

Kainate

Pentylènetétrazole

Pentylenetetrazole

Epilepsie

Epilepsy

Hippocampe

Hippocampus

Système excitateur

Excitatory system

Système inhibiteur

Inhibitory system

Séquelles cognitives

Cognitive consequences

Hyperexcitabilité

Hyperexcitability ∙

Cellules pyramidales

Pyramidal cells

Interneurones GABAergiques

GABA interneuron

Ultrastructural, molecular and functional heterogeneities of cerebellar granule cell presynaptic terminals / Hétérogénéités ultrastructurales, moléculaires et fonctionnelles aux terminaisons synaptiques des cellules en grain du cervelet

Dorgans, Kevin

03 October 2017

Le cervelet est une structure cérébrale impliquée dans la régulation motrice. Dans le cortex cerebelleux, les informations sensorimotrices sont transmises par les cellules en grain. Mon travail de thèse démontre que les connections synaptiques de ces neurones ont des propriétés hétérogènes. D’une synapse à l’autre, j’ai pu observer des variations d’ultrastructure, de composition moléculaire et de fonctionnement au cours de trains de potentiels d’action à haute fréquence. Plus particulièrement, j’ai caractérisé les propriétés de « plasticité à court terme » des synapses unitaires des cellules en grain : 1) Elles sont très différentes d’une synapse à l’autre et peuvent être classées en différentes sous-catégories. 2) Certaines catégories de fonctionnement synaptique reposent sur l’expression de molécules telles que la Synapsine2. 3) La réponse d’un neurone post-synaptique à de hautes fréquences de stimulation dépend de la nature de la synapse activée. / Cerebellum is a brain structure involved in motor regulation and motor learning. In the cerebellar cortex, sensorimotor information is transmitted by granule cells. During my PhD, I demonstrated that the properties of individual granule cell synaptic connections are highly heterogeneous. From one synapse to another, I observed ultrastructural, molecular and functional variability at unitary contacts. More precisely, I assessed the properties of short term plasticity at individual synapses during high frequency trains of stimulation :1) Short term plasticities are highly heterogeneous from one synapse to another and can be classified in sub-categories.2) Some categories of short-term plasticity profiles relie on the expression of molecules such as Synapsin2.3) The response of post-synaptic neuron to high-frequency inputs is dependent on the nature of the activated synaptic contact.

Neurone

Synapse

Cervelet

Cellule en grain

Interneurone de la couche moléculaire

Neurotransmission

Plasticité synaptique à court terme

Synapsine2

Patch-clamp

Microscopie électronique

Neurone

Synapse

Cerebellum

Granule cell

Molecular layer interneuron

Neurotransmission

Short-term synaptic plasticity

Synapsin2

Patch-clamp

Electron microscopy

572.4

573.8

Molecular Players in Preserving Excitatory-Inhibitory Balance in the Brain

Mao, Wenjie

07 December 2017

Information processing in the brain relies on a functional balance between excitation and inhibition, the disruption of which leads to network destabilization and many neurodevelopmental disorders, such as autism spectrum disorders. One of the homeostatic mechanisms that maintains the excitatory and inhibitory balance is called synaptic scaling: Neurons dynamically modulate postsynaptic receptor abundance through activity-dependent gene transcription and protein synthesis. In the first part of my thesis work, I discuss our findings that a chromatin reader protein L3mbtl1 is involved in synaptic scaling. We observed that knockout and knockdown of L3mbtl1 cause a lack of synaptic downscaling of glutamate receptors in hippocampal primary neurons and organotypic slice cultures. Genome-wide mapping of L3mbtl1 protein occupancies on chromatin identified Ctnnb1 and Gabra2 as downstream target genes of L3mbtl1-mediated transcriptional regulation. Importantly, partial knockdown of Ctnnb1 by itself prevents synaptic downscaling. Another aspect of maintaining E/I balance centers on GABAergic inhibitory neurons. In the next part of my thesis work, we address the role of the scaffold protein Shank1 in excitatory synapses onto inhibitory interneurons. We showed that parvalbumin-expressing interneurons lacking Shank1 display reduced excitatory synaptic inputs and decreased levels of inhibitory outputs to pyramidal neurons. As a consequence, pyramidal neurons in Shank1 mutant mice exhibit increased E/I ratio. This is accompanied by a reduced expression of an inhibitory synapse scaffolding protein gephyrin. These results provide novel insights into the roles of chromatin reader molecules and synaptic scaffold molecules in synaptic functions and neuronal homeostasis.

synaptic plasticity

homeostatic plasticity

homeostatic scaling

synaptic scaling

excitatory and inhibitory balance

hippocampus

epigenetics

chromatin reader

MBT

interneuron

parvalbumin

shank

synaptic scaffolding molecule

autism spectrum disorders

mouse model

Molecular and Cellular Neuroscience

Homeostatic and functional implications of interneuron plasticity

Mackwood, Owen John

14 March 2019

Die Erhaltung der Gehirnfunktion trotz Veränderungen im Organismus und dessen Umwelt erfordert homöostatische Mechanismen. Inhibitorische Interneurone spielen eine Schlüsselrolle bei Berechnungen und Homöostase im Gehirn. Es ist jedoch unklar, welcher Mechanismus diese Eigenschaften erzeugen kann. Diese Arbeit hat das Ziel, die homöostatischen Fähigkeiten solcher Interneurone zu bestimmen und die daraus resultierenden funktionellen Konsequenzen mit analytischen und numerischen Techniken zu ergründen. Die zentrale Hypothese dieser Arbeit ist, dass Interneurone ihre Feuerraten modulieren, um langfristig die Aktivität exzitatorischer Neurone bei einem homöostatischen Sollwert zu halten. Wir beginnen mit einem normativen Ansatz und leiten eine Plastizitätsregel her, welche die Aktivität von Interneuronen regelt, um netzwerkweite Abweichungen vom Sollwert zu minimieren. Um die biologische Plausibilität zu erhöhen, liefern wir zwei Approximationen, bei denen jede Interneurone auf die exzitatorische Population reagiert, die sie inhibiert und zeigen, dass alle drei Varianten vergleichbare aber unterschiedliche homöostatische Fähigkeiten haben. Wir kontrastieren den normativen Ansatz mit Regeln, welche die Aktivität einer Interneurone verändern, wenn die Neuronen, die sie treiben, vom Sollwert abweichen. Diese Regeln erzeugen Konkurrenz zwischen Neuronen und führen daher zu zerstreuter Netzwerkaktivität. Im zweiten Teil dieser Arbeit untersuchen wir, wie eine der approximierten Regeln die funktionellen Eigenschaften des sensorischen Kortex beeinflusst. Wir zeigen, dass sie mehrere experimentell Beobachtungen erklären kann, inklusive des Ko-Tunings von exzitatorischen und inhibitorischen Strömen und der Entwicklung von Zellverbänden. Zusammenfassend liefert diese Arbeit neue Erkenntnisse darüber, wie die Regulierung der Interneuron-Aktivität für neuronale Netzwerke homöostatisch sein kann, und zeigt mögliche Auswirkungen auf die Entwicklung und Erhaltung der Gehirnfunktion auf. / Preserving brain function despite ongoing changes inside the organism, and out in the world, necessitates homeostatic mechanisms. Inhibitory interneurons play a key role in both computation and homeostasis within the brain. However, it remains unclear if there is a mechanism that can account for both of these properties. This thesis therefore aims to determine the homeostatic capabilities of such interneurons and elucidate the resulting computational consequences, using analytical and numerical techniques. The central hypothesis of this thesis is that some interneurons slowly modulate their firing rates to maintain the long-term activity of excitatory neurons at a homeostatic set-point. Thus we begin with a normative approach, deriving a plasticity rule that regulates the activity of interneurons to minimise network-wide deviations from that set-point. In the interest of biological plausibility we also provide two approximations, both of which make each interneuron responsive to the excitatory population it inhibits, and show that all three variants exhibit comparable though distinct homeostatic capabilities. We contrast this normative approach by characterising the homeostatic properties of rules which instead alter the activity of an interneuron when the neurons that drive it deviate from the set-point. Those rules induce a competition between neurons, causing network activity to become sparse. In the second part of this thesis, we investigate how one of the approximate rules affects computational properties of sensory cortex. We show that it can account for several experimentally reported results, including co-tuning of excitatory and inhibitory currents, and the development of excitatory-inhibitory cell assemblies. In summation, this thesis provides new insight into how regulating interneuron activity can be homeostatic for neuronal networks, and reveals potential implications for development and preservation of brain function.

Inhibitorische Interneurone

Feuerraten-Homöostase

Plastizität von Interneuronen

synaptische Plastizität

inhibitory interneurons

firing rate homeostasis

interneuron plasticity

synaptic plasticity

570 Biowissenschaften; Biologie

500 Naturwissenschaften und Mathematik

WW 2201

ddc:570

ddc:500

Subthreshold Oscillations and Persistent Activity Modulate Spike Output in the Rodent Dentate Gyrus

Anderson, Ross William

09 February 2015

No description available.

Animals

Biology

Biophysics

Health Sciences

Neurobiology

Neurosciences

Physiology

In vivo recordings

whole cell patch clamp

hippocampus

mouse

dentate gyrus

granule cell

mossy cell

interneuron

acetylcholine

head-fixed awake recordings

persistent firing

plateau potential

current clamp

subthreshold oscillations

alpha

Steuerung der Beinmotorik von Grillen durch ein Paar gravizeptiver Interneurone / Control of leg motor activity via a pair of graviceptive interneurons in crickets

Funke, Frank

04 November 2004

No description available.

590 Tiere (Zoologie)

Mathematics and Computer Science

Gryllus bimaculatus

Grille

Cercales System

Cerci

Keulenhaare

Gleichgewichtsorgan

Gravizeption

PSI

positionssensitive Interneurone

Kippung

Rieseninterneurone

gravitationskompensatorische Motorik

mesothorakale Motorik

mesothorakaler Nerv 3D1

mesothorakaler Nerv 3D3

neurales Netzwerk

Gryllus bimaculatus

cricket

cercal system

cerci

club-shaped hairs

clavate hairs

equilibrium organ

graviception

PSI

position sensitive interneuron

tilting

giant interneuron

gravitation compensatory motor activity

mesothoracic motor activity

mesothoracic nerve 3D1

mesothoracic nerve 3D3

neural network

42.63

Studies of Spinal Motor Control Networks in Genetically Modified Mouse Models

Gezelius, Henrik

January 2009

Spinal neurons are important in several aspects motor control. For example, the neurons essential for locomotor movements reside in the ventral spinal cord. In this thesis, different motor control functions are being related to neuronal populations defined by their common expression of a gene. First, a targeted disruption of the gene for vesicular glutamate transporter 2 (Vglut2/ Slc17a6) is described. The mutant animals die at birth because of their inability to breathe. The neuronal network in the brainstem, responsible for inspiration, was shown to become non-functional by the targeted deletion of Vglut2. To our surprise, it was still possible to induce rhythmic activity with normal left/right alternation in spinal cords isolated from VGLUT2-null embryos. Inconsistent reports of Vglut1 expression in the spinal cord made us re-evaluate the Vglut1 and Vglut2 expressions. While Vglut2 expression was widespread in the spinal cord, Vglut1 expression was restricted to a few cells dorsal to the central canal.  Taken together, the data suggest that, glutamatergic signaling is mandatory to drive the bilateral breathing, but not needed for coordination of basal alternating spinal locomotor rhythm. Next, a screen for genes with restricted ventral expression was made. Some of the genes found could be connected to the characteristics of specific neuronal cell populations. For example, fast motor neurons were shown to express the genes Calca and Chodl. Further, we found the Chrna2 expression selectively in putative Renshaw cells. It seems likely that the gene product, the alpha2 subunit of the nicotinergic receptor, could be linked to the unique connection of motor neurons to Renshaw cells. We used the Chrna2 promoter to drive expression of Cre recombinase in a transgenic mouse. The Cre activity was present in most neurons labeled with Renshaw cell markers, which should make it a useful tool for functional studies of this population. The studies presented here show how the genes expressed in subsets of neurons can be used to target populations of neurons for functional studies of neuronal systems.

acetyl choline

central nervous system

central pattern generator

Cre recombinase

development

genetic screen

glutamate

interneuron

motor neuron

mouse

mouse genetics

movement

network

neuronal network

nicotinic receptors

physiology

Renshaw cell

rhythm

spinal cord

transmitter

Neuroscience

Neurovetenskap

Neurobiology

Neurobiologi

Molecular neurobiology

Molekylär neurobiologi

Neurophysiology

Neurofysiologi

Neurobiology

Neurobiologi