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Diverse Mechanisms Impair Thalamic Circuit Function in a Dravet Syndrome Mouse ModelStudtmann, Carleigh 06 April 2022 (has links)
Dravet syndrome (DS) is an infantile epileptic encephalopathy that is caused by loss-of-function mutations in the SCN1A gene, which encodes the voltage-gated sodium channel, NaV1.1. Haploinsufficiency of NaV1.1 in DS patients leads to imbalanced excitability across brain circuits, resulting in a broad phenotypic profile including drug-resistant convulsive and non-convulsive (absence) seizures, cognitive impairment, ataxia, and sleep disruption. Dysfunction in the somatosensory corticothalamic (CT) circuit underlies several DS phenotypes including absence seizures and sleep disturbances. Yet, the precise mechanisms underlying somatosensory CT circuit dysfunction in DS remain unclear. Here, we sought to identify the cellular and synaptic mechanisms underlying somatosensory CT circuit dysfunction in a haploinsufficiency DS mouse model. This work reveals that NaV1.1 haploinsufficiency leads to cell-type-specific changes in the excitability of reticular thalamic (nRT), ventral posterolateral (VPL), and ventral posteromedial (VPM) neurons. Further, we identified alterations in both glutamatergic and GABAergic synaptic connectivity within the somatosensory CT circuit in DS mice. These findings introduce glutamatergic neuron dysfunction and synaptic alterations as novel disease mechanisms underlying thalamic circuit dysfunction in DS, providing new targets for therapeutic intervention. In addition, we reveal that VPL and VPM neurons exhibit distinct firing properties in a healthy CT circuit, suggesting they differentially contribute to circuit-wide function in health and dysfunction in disease. / Doctor of Philosophy / The brain is composed of biological circuits made up of excitatory and inhibitory neurons, which are connected through synapses. Proper balance between excitatory and inhibitory activity in these circuits is essential for maintaining healthy brain function. Dravet syndrome (DS) is an infantile-onset epilepsy caused by mutations in the SCN1A gene, which encodes the voltage-gated sodium channel, Nav1.1. Loss of this protein in the brain leads to an imbalance of excitation and inhibition across a variety of brain circuits, resulting in drug-resistant seizures and cognitive, motor, and learning deficits. Disrupted excitability in the somatosensory corticothalamic (CT) circuit specifically leads to non-convulsive seizures and sleep disruption in DS. However, the mechanisms underlying this circuit's dysfunction remain unclear. Revealing these mechanisms is critical for identifying therapeutic targets by which we can correct circuit function. In this work, we used a mouse model of DS to reveal changes in the excitability of three distinct cell populations of the somatosensory CT circuit. Importantly, changes were exhibited in both excitatory and inhibitory thalamic neuron populations. We further identified impairments in the synapses, both excitatory and inhibitory, connecting the somatosensory CT circuit. These cell-type-specific changes in excitability and synaptic connectivity provide novel targets for therapeutic intervention in DS.
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Analysis of axon tract formation in Gli3 conditional mutant miceAmaniti, Eleni Maria January 2014 (has links)
The cerebral cortex is the largest subdivision of the human brain and is associated with higher cognitive functions. These functions are based on the interconnections between the neurons that form pre- and postnatally in the different telencephalic regions. The processes of neurons with similar functions and connectivity follow the same course and form axon tracts. There are three main axons tracts analysed in this thesis the corpus callosum, the corticothalamic/thalamocortical tracts and the lateral olfactory tract that transfers olfactory information to the telencephalon. In the mouse, these tracts are generated during embryogenesis as axons project to their target area. The mechanisms by which axons navigate still need to be elucidated. Studies of a number of mutant mice have shown that axon pathfinding is under the control of genes. Gli3 is a zinc finger transcription factor with known roles in axon pathfinding. Gli3 is widely expressed in progenitor cells of the dorsal and ventral telencephalon complicating the elucidation of the molecular mechanisms by which Gli3 controls axon tract formation. My aim here is to investigate the spatial and temporal requirements for Gli3 in axon pathfinding in the forebrain using Gli3 conditional mutants as a tool. Regarding the corpus callosum, my findings demonstrated a crucial role for Gli3 in the dorsal telencephalon, but not in the septum or medial ganglionic eminence, to control corpus callosum formation and indicated that defects in the formation of the corticoseptal boundary affect the positioning of callosal guidepost cells. Moreover, conditional inactivation of Gli3 in dorsal telencephalic progenitors led to few corticothalamic axons leaving the cortex in a restricted lateral neocortical domain. This restricted entry is at least partially caused by an expansion of the piriform cortex, which forms from an enlarged progenitor domain of the ventral pallium. Transplantation experiments showed that the expanded piriform cortex repels corticofugal axons. Moreover, expression of Sema5B, a chemorepellent for corticofugal axons produced by the piriform cortex, is similarly expanded. Hence, control of lateral cortical development by Gli3 at the progenitor level is crucial for corticothalamic pathfinding. Finally, by using Emx1Cre;Gli3fl/fl mutants I analysed the consequences of the expansion of the piriform cortex on the formation of the lateral olfactory tract (LOT). This analysis showed that LOT axons also appear to be medially shifted with LOT collaterals aberrantly colonising the expanded piriform cortex. Time course analysis confirmed an expansion of the paleocortical primordium from E13.5 onwards, coinciding with the arrival of the LOT axons. Hence, it is possible that the expanded piriform cortex contributed to the medial shift of the LOT. In conclusion, these findings support a strong link between Gli3 controlled early patterning defects and axon pathfinding defects and form the basis for future analysis of the molecular mechanisms by which Gli3 controls axon pathfinding in the forebrain. My findings also reveal how alterations in GLI3 function may contribute to connectivity defects in human patients with mutations in GLI3.
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Neuronal Correlates of Reward Contingency in the Rat Thalamocortical SystemPantoja, Janaina Hernandez January 2009 (has links)
<p>Perception arises from sensory inputs detected by peripheral organs and processed in the brain by complex neuronal circuits required for the integration of external information with internal states such as expectation and attention. Stimulus discrimination requires activation of primary sensory areas in the brain, but expectation is traditionally associated with the activation of higher-order brain areas. Sensory information obtained by tactile organs is represented along the primary areas that comprise the trigeminal thalamocortical pathway. In anesthetized animals, neuronal activity in the somatosensory system has been extensively described over the past century. However, it is still unclear how the different thalamocortical structures contribute to active tactile discrimination and represent relevant features of the stimulus. It is also unknown whether expectation modulates tactile representations in these regions. In this dissertation, I investigated neuronal ensemble activity recorded from freely behaving rats performing a whisker-based tactile discrimination t-+ask. Multielectrode arrays were chronically implanted to record simultaneously from the main stages of the trigeminal thalamocortical pathways involved in whisking: the primary somatosensory cortex (S1), the ventral posterior medial nucleus of the thalamus (VPM), the posterior medial complex (POm) and the zona incerta (ZI). In Chapter 1 I describe the behavior of rats performing the tactile discrimination task, which requires animals to associate two different tactile stimuli with two corresponding choices of spatial trajectory in order for reward to be delivered. I found that both cortical and thalamic neurons are dynamically engaged during execution of the task. The data reveal a very complex mosaic of responses comprising single or multiple periods of inhibition and excitation. Thalamocortical activity was modulated during whisker stimulation as well as after stimulus removal, up until reward delivery. To investigate whether reward expectation plays a role in tactile processing at early processing stages, I also recorded neuronal activity from rats performing a freely-rewarded version of the tactile discrimination task. Comparing data from regularly-rewarded and freely-rewarded sessions, I show in chapter 2 that the activity of single neurons in the primary somatosensory thalamocortical loop is strongly modulated by reward expectation. Stimulus-related information coded by primary thalamocortical neurons is high when a correct association between stimulus and response is crucial for reward, but decreases significantly when the association is irrelevant. These results indicate that tactile processing in primary somatosensory areas of the thalamus and cerebral cortex is directly affected by reward expectation.</p> / Dissertation
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Shaping somatosensory responses in awake rats: cortical modulation of thalamic neurons / 触覚システムにおける皮質視床投射ニューロンによる視床ニューロンの感覚応答調節Hirai, Daichi 26 March 2018 (has links)
京都大学 / 0048 / 新制・論文博士 / 博士(医学) / 乙第13156号 / 論医博第2143号 / 新制||医||1028(附属図書館) / 京都大学大学院医学研究科医学専攻 / (主査)教授 林 康紀, 教授 渡邉 大, 教授 影山 龍一郎 / 学位規則第4条第2項該当 / Doctor of Medical Science / Kyoto University / DFAM
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Targeting NMDA Receptors to Tune Corticothalamic Circuit FunctionChen, Yang 09 February 2023 (has links)
The somatosensory corticothalamic (CT) circuit processes ascending sensory signals, and disruption to the balance of excitation and inhibition (E/I) within CT circuitry leads to absence seizures, sleep disorders, and attention deficits. E/I balance may be restored by independently modulating excitatory CT input to the ventral posteromedial (VPM) thalamus and inhibitory input to the VPM through the CT-thalamic reticular nucleus (nRT)-VPM pathway. This work revealed novel N-methyl-D-aspartate receptor (NMDAR) nucleus-specific and frequency-dependent functional diversity in the somatosensory CT circuit. Specifically, these findings illustrate the different effects of NMDAR negative modulation in the nRT and the VPM, which offers a method to preferentially decrease high frequency excitatory CT input to the VPM while having no significant effect on nRT activity. These results demonstrate the potential of utilizing NMDAR selective modulators to decrease overall excitation within the somatosensory CT circuit. Further investigation is required to elucidate the precise mechanisms underlying this phenomenon, including where NMDARs are localized at CT synapses and the effect of positive NMDAR modulators on nRT and VPM activity. / Master of Science / The sensory gating mechanism helps our brain to select essential sensory information to process. Impairment of this sensory gating has been reported in epilepsy, schizophrenia, and autism. The somatosensory corticothalamic (CT) circuit oversea the sensory gating process by adjusting how much excitation and inhibition signals are integrated into the thalamus. Disruption of the balance of excitation and inhibition (E/I) within CT circuitry leads to the absence seizures, sleep disorders, and attention deficits. Our work revealed one of the glutamate receptors N-methyl-D-aspartate receptor (NMDAR), has nucleus-specific and frequency-dependent functional diversity in the somatosensory CT circuit. By targeting the different NMDAR subunits in the circuit, we were able to preferentially decrease high-frequency excitatory input to the thalamus while having no significant effect on inhibitory input. These results offer the potential to utilize NMDAR selective modulators to decrease overall excitation within the somatosensory CT circuit, which is useful to restore the disrupted E/I balance in the thalamus from a variety of neurological diseases. Further investigation is required to elucidate the precise mechanisms underlying this phenomenon.
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Role for Gli3 in the formation of the major axonal tracts in the telencephalonMagnani, Dario January 2011 (has links)
In the adult brain, the thalamocortical tract conveys sensory information from the external environment to the cortex. The cortex analyzes and integrates this information and sends neural responses back to the thalamus through the corticothalamic tract. To reach their final target both thalamocortical and corticothalamic axons have to cover long distances during embryogenesis, changing direction several times and passing through different brain territories. The ventral telencephalon plays a major role in the early development of these tracts. At least three main axon guidance mechanisms act in the ventral telencephalon. First, two different populations of pioneer neurons in the lateral ganglionic eminence (LGE) (LGE pioneer neurons) and medial ganglionic eminence (MGE) (MGE pioneer neurons) provide scaffolds which allow growing corticothalamic and thalamocortical axons to cross the pallium sub pallium boundary (PSPB) and the diencephalic telencephalic boundary (DTB), respectively. Second, the ventral telencephalon forms a permissive corridor for thalamic axons by tangential migration of Isl1 and Ebf1 expressing cells from the LGE into the MGE. Finally, thalamortical and corticothalamic axons guide each other once they have met in the ventral telencephalon (“handshake hypothesis”). The Gli3 transcription factor has been shown to be essential for normal early embryonic regionalization of the mammalian forebrain, although roles of Gli3 in later aspects of forebrain development, like the formation of axonal connections, have not been investigated previously. Here, I present the analysis of axonal tract development in the forebrain of the Gli3 hypomorphic mutant mouse Polydactyly Nagoja (Pdn). These animals lack the major axonal commissures of the forebrain: the corpus callosum, the hippocampal commissure, the anterior commissure and the fimbria. In addition, DiI injections and neurofilament (NF) staining showed defects in the formation of the corticothalamic and thalamocortical tracts. Although the Pdn/Pdn cortex forms early coticofugal neurons and their axons, these axons do not penetrate the LGE and instead run along the PSPB. Later in development, although a thick bundle of Pdn/Pdn cortical axons is still observed to project along the PSPB, some Pdn/Pdn cortical axons eventually enter the ventral telencephalon navigating along several abnormal routes until they reach thalamic regions. In contrast, Pdn/Pdn thalamic axons penetrate into the ventral telencephalon at early stages of thalamic tract development. However, rostrally they deviate from their normal trajectory, leaving the internal capsule prematurely and only few of them reach the developing cortex. Caudally, an ectopic Pdn/Pdn dorsal thalamic axon tract projects ventrally in the ventral telencephalon not entering the internal capsule at all. These defects are still observed in newborn Pdn/Pdn mutant mice. Next, I investigated the developmental mechanisms causing these pathfindings defects. No obvious defects are present in Pdn/Pdn cortical laminae formation and in the patterning of the Pdn/Pdn dorsal thalamus. In addition, Pdn/Pdn thalamocortical axons are able to respond to ventral telencephalic guidance cues when transplanted into wild type brain sections. However, these axonal pathfinding defects correlate with patterning defects of the Pdn/Pdn LGE. This region is partially ventralized and displays a reduction in the number of postmitotic neurons in the mantle zone due to an elongated cell cycle length of LGE progenitor cells. Finally, Pdn/Pdn mutant display an upregulation of Shh expression and Shh signalling in the ventral telencephalon. Interestingly, these patterning defects lead to the absence of DiI back-labelled LGE pioneer neurons, which correlates with the failure of corticothalamic axons to penetrate the ventral telencephalon. In addition, ventral telencephalic thalamocortical guidance mistakes happen at the same time of abnormal formation of the corridor cells. Taken together these data reveal a novel role for Gli3 in the formation of ventral telencephalic intermediate cues important for the development of the thalamocortical and corticothalamic connections. Indeed, Pdn animals are the first known mutants with defective development of the LGE pioneer neurons, and their study provides a link between early patterning defects and axon pathfinding in the developing telencephalon.
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The development of corticothalamic and corticotectal connections in the murine visual systemGrant, Eleanor January 2014 (has links)
All peripheral sensory information is represented in the thalamus before being transmitted to the cortex, with the exception of olfaction. The thalamus projects to all areas of the neocortex and all neocortical areas project to the thalamus. I am interested in the development of three corticothalamic populations which are anatomically and functionally distinct; they project to different thalamic nuclei and generate different post-synaptic responses. Layer V fibres project exclusively to higher order thalamic nuclei. These projections drive thalamic neuron activity and mediate a trans-thalamic cortico-cortical relay. Layer VI and VIb fibres project to both first order and higher order thalamic nuclei. These projections modulate thalamic neuron activity and mediate feedback to the thalamus. Using three transgenic mouse lines I demonstrate that developing corticothalamic fibres target the specific groups of thalamic nuclei to which they project in adulthood. Rbp4-Cre::tdTomato labels layer V; Ntsr1-Cre::tdTomato labels layer VI; Golli-τ-eGFP labels layer VI and VIb. By P4 layer V fibres arborise densely in higher order nuclei but do not innervate the first order nuclei at any age. In contrast, at this age VI and VIb fibres densely innervate the first order ventral posterior-medial nucleus (VPM), as well as higher order nuclei. Layer VI and VIb fibres accumulate outside the dorsal Lateral Geniculate Nucleus (dLGN) from P2 before entering at P6. During this waiting period, retinal fibres transmit spontaneous waves of activity to the dLGN. To assess whether retinal input regulates corticothalamic circuit development I performed monocular enucleation. I demonstrate that after loss of retinal input, layer VI and VIb fibres enter the dLGN prematurely, by P2. Furthermore layer V fibres which target the retino-recipient superior colliculus also enter prematurely following enucleation. These results suggest there may be a retinal mechanism which regulates the timing of corticofugal ingrowth to joint retinal/cortical targets. The loss of retinal driver input to the dLGN also induces layer V driver fibres to aberrantly enter the first order dLGN. These results are the first to show cross-hierarchical rewiring after losing peripheral sensory input. The role of peripheral activity in the developing nervous system is underscored by activity dependent molecular mechanisms. I therefore performed a microarray gene expression experiment to systematically analyse molecular changes in the dLGN following enucleation. The expression of numerous genes is altered following enucleation including potassium channels Kcnk9 and Kcnn3, kinase pathway mediators, Shc3 and Dgkk, and immediate early genes BDNF, Egr1 and Egr2. The majority of genes regulated by enucleation are regulated in the opposite direction over development indicating that the loss of the retinal input delays maturation of the dLGN transcriptome. In this thesis I demonstrate that early corticothalamic development targets specific thalamic nuclei. Using the visual system as a model I demonstrate that retinal input regulates corticothalamic development and contributes to the transcriptome of thalamic nuclei.
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Functional neuroanatomy of visual pathways involving the pulvinarAbbas Farishta, Reza 04 1900 (has links)
Les neurones du cortex visuel primaire (V1) peuvent emprunter deux voies de communications afin d’atteindre les aires extrastriées : une voie cortico-corticale, et une voie cortico-thalamo-corticale à travers des noyaux thalamiques de haut niveau (HO) comme le pulvinar. Les fonctions respectives de ces deux voies restent toujours méconnues. Un pas vers une meilleure compréhension de celles-ci seraient d’investiguer la nature des signaux qu’elles transmettent. Dans ce contexte, deux grands types de projections cortico-thalamiques (CT) ont été identifiés dans le système visuel : les neurones de type I (modulator) et type II (driver) caractérisés respectivement par des axones minces dotés de petits boutons terminaux et par des axones plus épais et de plus grands boutons respectivement. Une proposition récente a aussi émis l'hypothèse que ces deux types pourraient également être distingués par leur expression de transporteur de glutamate vésiculaire. Cette hypothèse suggère que les projections de type II et de type I peuvent exprimer sélectivement VGLUT2 et VGLUT1, respectivement (Balaram, 2013; Rovo et al, 2012).
Chez le chat, les projections de V1 vers le pulvinar se composent principalement de terminaux de type II, tandis que celles de l’aire PMLS présentent une combinaison de terminaux de type I et II suggérant ainsi que, la proportion de terminaux de type I augmente avec le niveau hiérarchique cortical des zones visuelles. Afin de tester cette hypothèse, nous avons cartographié la distribution des terminaux CT du cortex AEV (article 1) ainsi que de l’aire 21a (article 2). Nous avons aussi étudié l’expression de VGLUT 1 et 2 dans le système visuel du chat afin de tester si leurs expressions corrèlent avec les sites de projections de neurones de type I et II (article 3).
Nos résultats indiquent que la grande majorité des terminaux marqués dans le pulvinar provenant de l’AEV et de l’aire 21a sont de type I (Article 1 et 2) alors que ceux de V1 sont majoritairement de type II. Une comparaison de la proportion des projections de type I à travers les aires V1, PMLS, 21a et AEV révèlent une corrélation positive de sorte que celle-ci augmente avec le degré hiérarchique des aires visuelles.
Nos résultats indiquent que VGLUT 1 et 2 présentent une distribution complémentaire et que leur localisation dans des sites connus pour recevoir une projection de type ‘modulateur’ et ‘déclencheur’ proéminente suggère que leurs expressions peuvent montrer un biais pour celles-ci dans la voie géniculo-strié.
Les résultats de cette thèse ont permis de mieux connaitre la nature des projections CT des aires visuelles extrastriées. Ces résultats sont d’autant plus importants qu’ils établissent un lien entre la nature de ces projections et le degré hiérarchique des aires visuelles, suggérant ainsi l’existence une organisation anatomofonctionnelle des voies CT passant par le pulvinar. Enfin, les résultats de cette thèse ont aussi permis une meilleure compréhension des vésicules VGLUT 1 et 2 dans le système visuel du chat et leurs affinités respectives pour les sites de projections de neurones de type I et II. / Visual signals from the primary visual cortex (V1), can take two main communication routes in order to reach higher visual areas: a corticocortical pathway and a cortico-thalamo-cortical (or transthalamic) pathway through high-order thalamic nuclei such as the pulvinar. While these pathways are receiving an increasing interest from the scientific community, their respective functions still remain largely unknown. An important step towards a better understanding of these pathways would be to investigate the nature of the signals they transmit. In this context, two main types of corticothalamic (CT) projections have been identified in the visual system: type I projections (modulators) and type II (drivers) characterized respectively by thin axons with small terminal and by thicker axons and larger terminals. A recent proposal has also hypothesized that these two types can also be distinguished by their expression of vesicular glutamate transporter (VGLUT) in their respective synaptic terminals such that type II (driver) and type I (modulator) projections can selectively express VGLUT 2 and VGLUT 1, respectively (Balaram, 2013; Rovo et al, 2012).
In cats, projections from V1 to the LP-pulvinar are mainly composed of type II terminals, while those from the Posteromedial lateral suprasylvian (PMLS) cortex present a combination of type I and II terminals. This observation suggests that, in higher-order (HO) thalamic nuclei, the proportion of type I terminals increases with the hierarchical level of the visual areas. To test this hypothesis, we charted the distribution of CT terminals originating from the Anterior EctoSylvian visual cortex (AEV) (article 1) and from area 21a (article 2). We also studied the expression of VGLUT 1 and 2 in the cat's visual system in order to test whether their expressions correlate with the projection sites of type I and II axon terminals (article 3). Our results from article 1 and 2 indicate that the vast majority of terminals sampled in the pulvinar from the AEV and area 21a are of type I while projections from V1 projections to the pulvinar were mostly composed of type II terminals. A comparison of the proportion of type I projections across areas V1, PMLS, 21a and the AEV revealed a positive correlation such that its proportion increased with the hierarchical rank of visual areas.
Our results also indicate that VGLUT 1 and 2 have a complementary distribution pattern which matches prominent projection of type I and II respectively in ascending visual projections but does not in extra-geniculate pathways involving the pulvinar (Article 3).
Taken together, results from this thesis have allowed a better understanding of the nature of cortico-thalamic projections originating from extra-striate visual areas (21a and AEV). These results are all the more important in that they establish a link between the nature of these projections and the hierarchical degree of their cortical area of origin, thus suggesting that there is a functional organization of CT pathways passing through the pulvinar. Finally, results of this thesis also enabled a better understanding of the expression of VGLUT 1 and 2 in the visual system and their possible respective biases for type I and type II projections.
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