The Phenotypic Landscape of a Tbc1d24 Mutant Mouse Includes Convulsive Seizures Resembling Human Early Infantile Epileptic Encephalopathy / けいれん発作を伴う早期乳児てんかん性脳症のモデルとしてのTbc1d24変異マウスの表現型の展望

Tona, Risa

25 March 2019

京都大学 / 0048 / 新制・課程博士 / 博士(医学) / 甲第21664号 / 医博第4470号 / 新制||医||1035(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 髙橋 良輔, 教授 浅野 雅秀, 教授 影山 龍一郎 / 学位規則第4条第1項該当 / Doctor of Medical Science / Kyoto University / DFAM

Tbc1d24 mutant mouse

Micro-exon

Seizures

SRRM3

Hippocampus

490

Synaptic Transmission in the Leaner Mutant Mouse Calyx of Held/MNTB Synapse

Epps, Tina

20 January 2009

The effects of alpha1A subunit mutations on presynaptic Ca2+ channel activity and functional development of synaptic properties remain elusive. The calyx of Held/medial nucleus of the trapezoid body synapse is an ideal model for studying the developmental effects of presynaptic voltage-gated Ca2+ channel (VGCC) impairment on synaptic function since simultaneous voltage-clamp recordings can be made directly from the pre- and postsynapse. The alpha1A subunit leaner (tgla/la) mutation induced a profound reduction in synaptic transmission after hearing onset (> postnatal day 12; P12), with relatively preserved relationship between presynaptic Ca2+ current (Pre-ICa) and release and G-protein-mediated inhibition. Some synaptic properties were more reflective of an immature state, while other properties displayed a delay in maturation after P12. Direct presynaptic recordings from P15/16 tgla/la nerve terminals revealed a decrease in the density of Pre-ICa, elevated activation threshold and slowing in the kinetics of VGCCs, all of which contribute to the deficit in transmitter release. Fractional contribution of P/Q-type channels to total Pre-ICa and their role in vesicle release was markedly reduced. N-type Ca2+ channels and close association of VGCCs to release sites was not sufficient to fully compensate for impaired P/Q-type channel function. The extent to which compensatory mechanisms preserve synaptic transmission at tgla/la synapses was further constrained by the developmental narrowing of the action potential waveform. Activation of the cAMP pathway by forskolin or direct modulation of VGCCs by cdk inhibitors rescued deficits in transmitter release at P15/16 tgla/la synapses. The major effect of roscovitine was a slowing of presynaptic VGCC deactivation kinetics accompanied by a leftward shift in the activation curve. Activation of the cAMP pathway or direct modulation of presynaptic VGCCs may serve as two potential pathways to facilitate release and improve neuronal communication at synapses normally compromised by impaired P/Q-type channel function. While significant for the tgla/la mutant, these studies provide an important advancement in our understanding of the crucial developmental and functional roles of P/Q-type Ca2+ channels in driving the maturation of synaptic properties at central synapses. These findings may improve our understanding of the pathophysiology of presynaptic VGCCs and elucidate essential mechanisms underlying the tgla/la phenotype.

Calcium Channels

Leaner Mutant Mouse

Calyx of Held

Synaptic Transmission

Development

Presynaptic

Roscovitine

0317

Synaptic Transmission in the Leaner Mutant Mouse Calyx of Held/MNTB Synapse

Epps, Tina

20 January 2009

The effects of alpha1A subunit mutations on presynaptic Ca2+ channel activity and functional development of synaptic properties remain elusive. The calyx of Held/medial nucleus of the trapezoid body synapse is an ideal model for studying the developmental effects of presynaptic voltage-gated Ca2+ channel (VGCC) impairment on synaptic function since simultaneous voltage-clamp recordings can be made directly from the pre- and postsynapse. The alpha1A subunit leaner (tgla/la) mutation induced a profound reduction in synaptic transmission after hearing onset (> postnatal day 12; P12), with relatively preserved relationship between presynaptic Ca2+ current (Pre-ICa) and release and G-protein-mediated inhibition. Some synaptic properties were more reflective of an immature state, while other properties displayed a delay in maturation after P12. Direct presynaptic recordings from P15/16 tgla/la nerve terminals revealed a decrease in the density of Pre-ICa, elevated activation threshold and slowing in the kinetics of VGCCs, all of which contribute to the deficit in transmitter release. Fractional contribution of P/Q-type channels to total Pre-ICa and their role in vesicle release was markedly reduced. N-type Ca2+ channels and close association of VGCCs to release sites was not sufficient to fully compensate for impaired P/Q-type channel function. The extent to which compensatory mechanisms preserve synaptic transmission at tgla/la synapses was further constrained by the developmental narrowing of the action potential waveform. Activation of the cAMP pathway by forskolin or direct modulation of VGCCs by cdk inhibitors rescued deficits in transmitter release at P15/16 tgla/la synapses. The major effect of roscovitine was a slowing of presynaptic VGCC deactivation kinetics accompanied by a leftward shift in the activation curve. Activation of the cAMP pathway or direct modulation of presynaptic VGCCs may serve as two potential pathways to facilitate release and improve neuronal communication at synapses normally compromised by impaired P/Q-type channel function. While significant for the tgla/la mutant, these studies provide an important advancement in our understanding of the crucial developmental and functional roles of P/Q-type Ca2+ channels in driving the maturation of synaptic properties at central synapses. These findings may improve our understanding of the pathophysiology of presynaptic VGCCs and elucidate essential mechanisms underlying the tgla/la phenotype.

Calcium Channels

Leaner Mutant Mouse

Calyx of Held

Synaptic Transmission

Development

Presynaptic

Roscovitine

0317

Diminished climing fiber innervation of Purkinje cells in the cerebellum of myosin Va mutant mice and rats

Takagishi, Yoshiko, Hashimoto, Kouichi, Kayahara, Tetsuro, Watanabe, Masahiko, Otsuka, Hiroyuki, Mizoguchi, Akira, Kano, Masanobu, Murata, Yoshiharu

06 1900

Running title: Climbing fibers in myosin Va mutants

myosin Va

cerebellum

climbing fiber

development

Purkinje cell

axonal transport

Ca^2＋ signaling

mutant mouse

Cellular Mechanism of Obsessive-Compulsive Disorder

Tee, Louis Yunshou

January 2015

<p>Obsessive-compulsive disorder (OCD) is a devastating illness that afflicts around 2% of the world's population with recurrent distressing thoughts (obsessions) and repetitive ritualistic behaviors (compulsions). While dysfunction at excitatory glutaminergic excitatory synapses leading to hyperactivity of the orbitofrontal cortex and head of the caudate - brain regions involved in reinforcement learning - are implicated in the pathology of OCD, clinical studies involving patients are unable to dissect the molecular mechanisms underlying this cortico-striatal circuitry defect. Since OCD is highly heritable, recent studies using mutant mouse models have shed light on the cellular pathology mediating OCD symptoms. These studies point toward a crucial role for deltaFosB, a persistent transcription factor that accumulates with chronic neuronal activity and is involved in various diseases of the striatum. Furthermore, elevated deltaFosB levels results in the transcriptional upregulation of Grin2b, which codes GluN2B, an N-methyl-D-aspartate glutamate receptor (NMDAR) subunit required for the formation and maintenance of silent synapses. Taken together, the current evidence indicates that deltaFosB-mediated expression of aberrant silent synapses in caudate medium spiny neurons (MSNs), in particular D1 dopamine-receptor expressing MSNs (D1 MSNs), mediates the defective cortico-striatal synaptic transmission that underlies compulsive behavior in OCD.</p> / Dissertation

Neurosciences

Psychobiology

Cellular biology

cellular mechanism

deltaFosB

NMDA receptor

obsessive-compulsive disorder

Sapap3 mutant mouse

silent synapse

Altered distribution of inhibitory synaptic terminals in reeler cerebellum with　special reference to malposition of GABAergic neurons / リーラーマウス小脳における抑制性神経回路の改変とGABA作動性ニューロンの位置異常との関係

高山, 千利

30 September 1994

Hokkaido University (北海道大学) / 博士 / 医学

reeler mutant mouse

cerebellum

γ-aminobutyric acid

glycine

glutamic acid decarboxylase

inhibitory interneuron

cellular migration

local neural circuirty

490

Étude du rôle de Pax6 dans la gliogenèse

Cannizzaro, Enrica

08 1900

Les astrocytes sont des cellules gliales présentes dans le système nerveux central, qui exercent de nombreuses fonctions physiologiques essentielles et sont impliquées dans la réponse aux lésions et dans plusieurs pathologies du cerveau. Les astrocytes sont générés par les cellules de la glie radiale, les précurseurs communs de la plupart des cellules neuronales et gliales du cerveau, après le début de la production des neurones. Le passage de la neurogenèse à la gliogenèse est le résultat de mécanismes moléculaires complexes induits par des signaux intrinsèques et extrinsèques responsables du changement de propriété des précurseurs et de leur spécification. Le gène Pax6 code pour un facteur de transcription hautement conservé, impliqué dans plusieurs aspects du développement du système nerveux central, tels que la régionalisation et la neurogenèse. Il est exprimé à partir des stades les plus précoces dans les cellules neuroépithéliales (les cellules souches neurales) et dans la glie radiale, dérivant de la différenciation de ces cellules. L’objectif de cette étude est d’analyser le rôle de Pax6 dans la différenciation et dans le développement des astrocytes. À travers l’utilisation d’un modèle murin mutant nul pour Pax6, nous avons obtenu des résultats suggérant que la suppression de ce gène cause l'augmentation de la prolifération et de la capacité d'auto-renouvellement des cellules souches neurales embryonnaires. In vitro, les cellules mutantes prolifèrent de façon aberrante et sous-expriment les gènes p57Kip2, p16Ink4a, p19Arf et p21Cip1, qui inhibent la progression du le cycle cellulaire. De plus, Pax6 promeut la différenciation astrocytaire des cellules souches neurales embryonnaires et est requis pour la différenciation des astrocytes dans la moëlle épinière. Les mutants nuls pour Pax6 meurent après la naissance à cause de graves défauts développementaux dus aux fonctions essentielles de ce gène dans le développement embryonnaire de plusieurs organes. En utilisant un modèle murin conditionnel basé sur le système CRE/ loxP (hGFAP-CRE/ Pax6flox/flox) qui présente l’inactivation de Pax6 dans les cellules de la glie radiale, viable après la naissance, nous avons montré que Pax6 est impliqué dans la maturation et dans le développement post-natal des astrocytes. Le cortex cérébral des souris mutantes conditionnelles ne présente pas d’astrocytes matures à l’âge de 16 jours et une très faible quantité d’astrocytes immatures à l’âge de trois mois, suggérant que Pax6 promeut la différenciation et la maturation des astrocytes. De plus, Pax6 semble jouer un rôle même dans le processus de différenciation et de maturation de cellules gliales rétiniennes. L’étude des gènes et des mécanismes moléculaires impliqués dans la génération des astrocytes est crucial pour mieux comprendre le rôle physiologique et les altérations pathologiques des ces cellules. / Astrocytes, a subtype of glial cells present in the central nervous system, have multiple physiological functions and are involved in the response to lesions and in several brain pathologies. Astrocytes are generated by radial glia cells, the common precursors of most neural and glial cells of the brain, after the beginning of neurons production. The transition from neurogenesis to gliogenesis is the result of complex molecular mechanisms induced by both intrinsic and extrinsic signals responsible for the change of precursors properties and commitment. The Pax6 gene encodes a highly conserved transcription factor, involved in several aspects of central nervous system development, such as regionalization and neurogenesis. It is expressed from the earliest stages in the neuroepithelial cells (neural stem cells) and in their more differentiated radial glia progeny. The aim of this study was to analyze the role of Pax6 in the differentiation and development of astrocytes. By using a Pax6 null mutant mouse, we obtained results suggesting that the suppression of this gene increases the proliferation and the self-renewal ability of embryonic neural stem cells. In vitro mutant cells overproliferate and overexpress p57Kip2, p16Ink4a, p19Arf et p21Cip1 genes, which inhibit the cell cycle progression. Moreover Pax6 promotes astrocytic differentiation of embryonic neural stem cells and is required for astrocyte differentiation in spinal cord. Pax6 null mutants die after birth because of severe developmental defects, due to the essential functions of this gene in embryonic development of several organs. Using a conditional mutant mouse of Pax6 in radial glia (hGFAP-CRE/ Pax6flox/flox, based on site-specific Cre/loxP-mediated gene excision), which is viable after birth, we obtained evidences showing that Pax6 is involved in astrocyte maturation and postnatal development. The cerebral cortex of sixteen-day-old conditional mutant mice doesn’t present mature astrocytes, and the three-month-old mice cortex presents only few immature astrocytes, suggesting that Pax6 promotes astrocyte differentiation and maturation. Moreover Pax6 seems to play a role also in the maturation and differentiation of retinal glial cells. The identification of genes and molecular pathways involved in the generation of astrocytes is crucial to better understand the physiological function and pathological alterations of these cells.

Astrocytes

Astrocytes

Gliogènese

Gliogenesis

Développement

Development

Système nerveux central

Central nervous system

Cellules souches neurales

Neural stem cells

Pax6

Pax6

Facteur de transcription

Transcription factor

Souris mutante nulle

Nul mutant mouse

Souris mutante conditionnelle

Conditional mutant mouse

Système CRE/ loxP

CRE/ loxP system

Étude du rôle de Pax6 dans la gliogenèse

Cannizzaro, Enrica

08 1900

Les astrocytes sont des cellules gliales présentes dans le système nerveux central, qui exercent de nombreuses fonctions physiologiques essentielles et sont impliquées dans la réponse aux lésions et dans plusieurs pathologies du cerveau. Les astrocytes sont générés par les cellules de la glie radiale, les précurseurs communs de la plupart des cellules neuronales et gliales du cerveau, après le début de la production des neurones. Le passage de la neurogenèse à la gliogenèse est le résultat de mécanismes moléculaires complexes induits par des signaux intrinsèques et extrinsèques responsables du changement de propriété des précurseurs et de leur spécification. Le gène Pax6 code pour un facteur de transcription hautement conservé, impliqué dans plusieurs aspects du développement du système nerveux central, tels que la régionalisation et la neurogenèse. Il est exprimé à partir des stades les plus précoces dans les cellules neuroépithéliales (les cellules souches neurales) et dans la glie radiale, dérivant de la différenciation de ces cellules. L’objectif de cette étude est d’analyser le rôle de Pax6 dans la différenciation et dans le développement des astrocytes. À travers l’utilisation d’un modèle murin mutant nul pour Pax6, nous avons obtenu des résultats suggérant que la suppression de ce gène cause l'augmentation de la prolifération et de la capacité d'auto-renouvellement des cellules souches neurales embryonnaires. In vitro, les cellules mutantes prolifèrent de façon aberrante et sous-expriment les gènes p57Kip2, p16Ink4a, p19Arf et p21Cip1, qui inhibent la progression du le cycle cellulaire. De plus, Pax6 promeut la différenciation astrocytaire des cellules souches neurales embryonnaires et est requis pour la différenciation des astrocytes dans la moëlle épinière. Les mutants nuls pour Pax6 meurent après la naissance à cause de graves défauts développementaux dus aux fonctions essentielles de ce gène dans le développement embryonnaire de plusieurs organes. En utilisant un modèle murin conditionnel basé sur le système CRE/ loxP (hGFAP-CRE/ Pax6flox/flox) qui présente l’inactivation de Pax6 dans les cellules de la glie radiale, viable après la naissance, nous avons montré que Pax6 est impliqué dans la maturation et dans le développement post-natal des astrocytes. Le cortex cérébral des souris mutantes conditionnelles ne présente pas d’astrocytes matures à l’âge de 16 jours et une très faible quantité d’astrocytes immatures à l’âge de trois mois, suggérant que Pax6 promeut la différenciation et la maturation des astrocytes. De plus, Pax6 semble jouer un rôle même dans le processus de différenciation et de maturation de cellules gliales rétiniennes. L’étude des gènes et des mécanismes moléculaires impliqués dans la génération des astrocytes est crucial pour mieux comprendre le rôle physiologique et les altérations pathologiques des ces cellules. / Astrocytes, a subtype of glial cells present in the central nervous system, have multiple physiological functions and are involved in the response to lesions and in several brain pathologies. Astrocytes are generated by radial glia cells, the common precursors of most neural and glial cells of the brain, after the beginning of neurons production. The transition from neurogenesis to gliogenesis is the result of complex molecular mechanisms induced by both intrinsic and extrinsic signals responsible for the change of precursors properties and commitment. The Pax6 gene encodes a highly conserved transcription factor, involved in several aspects of central nervous system development, such as regionalization and neurogenesis. It is expressed from the earliest stages in the neuroepithelial cells (neural stem cells) and in their more differentiated radial glia progeny. The aim of this study was to analyze the role of Pax6 in the differentiation and development of astrocytes. By using a Pax6 null mutant mouse, we obtained results suggesting that the suppression of this gene increases the proliferation and the self-renewal ability of embryonic neural stem cells. In vitro mutant cells overproliferate and overexpress p57Kip2, p16Ink4a, p19Arf et p21Cip1 genes, which inhibit the cell cycle progression. Moreover Pax6 promotes astrocytic differentiation of embryonic neural stem cells and is required for astrocyte differentiation in spinal cord. Pax6 null mutants die after birth because of severe developmental defects, due to the essential functions of this gene in embryonic development of several organs. Using a conditional mutant mouse of Pax6 in radial glia (hGFAP-CRE/ Pax6flox/flox, based on site-specific Cre/loxP-mediated gene excision), which is viable after birth, we obtained evidences showing that Pax6 is involved in astrocyte maturation and postnatal development. The cerebral cortex of sixteen-day-old conditional mutant mice doesn’t present mature astrocytes, and the three-month-old mice cortex presents only few immature astrocytes, suggesting that Pax6 promotes astrocyte differentiation and maturation. Moreover Pax6 seems to play a role also in the maturation and differentiation of retinal glial cells. The identification of genes and molecular pathways involved in the generation of astrocytes is crucial to better understand the physiological function and pathological alterations of these cells.

Astrocytes

Astrocytes

Gliogènese

Gliogenesis

Développement

Development

Système nerveux central

Central nervous system

Cellules souches neurales

Neural stem cells

Pax6

Pax6

Facteur de transcription

Transcription factor

Souris mutante nulle

Nul mutant mouse

Souris mutante conditionnelle

Conditional mutant mouse

Système CRE/ loxP

CRE/ loxP system

Modelování Huntingtonovy choroby a bněčná terapie při poškození míchy. / Huntington's disease modeling and stem cell therapy in spinal cord disorders and injury

Hruška-Plocháň, Marián

January 2013

Neurological disorders affect more than 14% of the population worldwide and together with traumatic brain and spinal cord injuries represent major health, public and economic burden of the society. Incidence of inherited and idiopathic neurodegenerative disorders and acute CNS injuries is growing globally while neuroscience society is being challenged by numerous unanswered questions. Therefore, research of the CNS disorders is essential. Since animal models of the CNS diseases and injuries represent the key step in the conversion of the basic research to the clinics, we focused our work on generation of new animal models and on their use in pre-clinical research. We generated and characterized transgenic minipig model of Huntington's disease (HD) which represents the only successful establishment of a transgenic model of HD in minipig which should be valuable for testing of long term safety of HD therapeutics. Next, we crossed the well characterized R6/2 mouse HD model with the gad mouse model which lacks the expression of UCHL1 which led to results that support the theory of "protective" role of mutant huntingtin aggregates and suggest that UCHL1 function(s) may be affected in HD disturbing certain branches of Ubiquitin Proteasome System. Traumatic spinal cord injury and Amyotrophic Lateral...