308 research outputs found

    Advances in modeling and characterization of human neuromagnetic oscillations

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    Intracranial electrophysiological measurements as well as electromagnetic recordings from the scalp have shown that oscillatory activity in the human brain plays an important role in sensory and cognitive processing. Communication between distant brain regions seems to be mediated by oscillatory coherence and synchrony. Our brain is both reactive and reflexive: it reacts to changes in the external environment, but it is also influenced by its past and present internal state. On the one hand, task-related or induced modulations of oscillatory activity provide an important marker for cortical excitability and information processing of the reactive brain. On the other hand, spontaneous oscillatory dynamics subserves information processing of the reflexive brain. In this thesis, methods were developed to model and characterize task-related oscillatory changes, as well as spontaneous oscillatory activity measured using magnetoencephalography (MEG). In Publication I, we developed a predictive model to capture the suppression-rebound reactivity of the ~20 Hz mu rhythm originating in the sensorimotor cortex and applied this model to locate the cortical generators of the rhythm from independent measurements. In Publications II and III, we developed temporal and spatial variants of a data-driven method to characterize spatial, temporal, and spectral aspects of spontaneous MEG oscillations. Analysis of complex-valued Fourier coefficients identified well-known rhythms, such as the parieto-occipital ~10-Hz and the rolandic ~20-Hz rhythms consistently across subjects. In Publication IV, we applied independent component analysis to time-frequency representations of cortical current estimates computed from simulated as well as resting-state and naturalistic stimulation data. Group-level analysis of Fourier envelopes also identified the ~20-Hz bilateral sensorimotor network, a subset of the default-mode network at ~8 and ~15 Hz, and lateralized temporal-lobe sources at ~8 Hz. The methods developed here represent important advances in the modeling and characterization of the brain's oscillatory activity measured using non-invasive electrophysiological methods in healthy humans

    Error Signals from the Brain: 7th Mismatch Negativity Conference

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    The 7th Mismatch Negativity Conference presents the state of the art in methods, theory, and application (basic and clinical research) of the MMN (and related error signals of the brain). Moreover, there will be two pre-conference workshops: one on the design of MMN studies and the analysis and interpretation of MMN data, and one on the visual MMN (with 20 presentations). There will be more than 40 presentations on hot topics of MMN grouped into thirteen symposia, and about 130 poster presentations. Keynote lectures by Kimmo Alho, Angela D. Friederici, and Israel Nelken will round off the program by covering topics related to and beyond MMN

    Functional and structural substrates of increased dosage of Grik4 gene elucidated using multi-modal MRI

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    Grik4 is the gene responsible for encoding the high-affinity GluK4 subunit of the kainate receptors. Increased dosage of this subunit in the forebrain was linked to an increased level of anxiety, lack of social communication, and depression. On the synaptic level, abnormal synaptic transmission was also reported. The manifestations of this abnormal expression have not been investigated at the circuit level, nor the correlations between those circuits and the abnormal patterns of the behavior previously reported. In this line of work, we aspired to use different non-invasive magnetic resonance imaging (MRI) modalities to elucidate any disturbance that might stem from the increased dosage of Grik4 and how those changes might explain the abnormal behaviors. MRI offers a noninvasive way to look into the intact brain in vivo. Resting-state functional MRI casts light on how the brain function at rest on the network level and has the capability to detect any anomalies that might occur within or between those networks. On the microstructural level, the diffusion MRI is concerned with the underlying features of the tissues, using the diffusion of water molecules as a proxy for that end. Moving more macroscopically, using structural scans, voxel-based morphometry can detect subtle differences in the morphology of the different brain structures. We recorded videos of our animals performing two tasks that have long been linked to anxiety, the open field and the plus-maze tests before acquiring structural and functional scans. Lastly, we recorded blood-oxygenationlevel dependent (BOLD) signals in a different set of animals during electrical stimulation of specific white matter tracts in order to investigate how neuronal activity propagates. Our analysis showed a vast spectrum of changes in the transgenic group relative to the animals in the control group. On the resting-state networks level, we observed an increase in the within-network strength spanning different structures such as the hippocampus, some regions of the cortex, and the hypothalamus. The increased internal coherence or strength in the networks contrasted with a significant reduction in between-networks connectivity for some regions such as parts of the cortex and the hypothalamus, suggesting long-range network decorrelation. Supporting this idea, major white matter (WM) tracts, such as the corpus callosum and the hippocampal commissure, suffered from substantial changes compatible with an important reduction in myelination and/or a decrease in the mean axonal diameter. Macrostructurally speaking, the overexpression of GluK4 subunit had a bimodal effect, with expansion in some cortical areas in the transgenic animals accompanied by a shrinkage in the subcortical regions. Upon stimulating the brain with an electrical current, we noticed a difference in activity propagation between the two hemispheres. In transgenic animals, the evoked activity remained more confined to the stimulated hemisphere, again consistent with an impaired long-range connectivity. The structural changes both, at the micro and macro level, were in tight correlation with different aspects of the behavior including markers of anxiety such as the time spent in the open arms vs the closed arms in the plus-maze test and the time spent in the center vs the corners in the open field test. Our findings reveal how the disruption of kainate receptors, or more globally the glutamate receptors, and the abnormal synaptic transmission can translate into brain-wide changes in connectivity and alter the functional equilibrium between macro-and mesoscopic networks. The postsynaptic enhancement previously reported in the transgenic animals was here reflected in the BOLD signal and measured as an increase in the within-network strength. Importantly, the correlations between the structural changes and the behavior help to put the developmental changes and their behavioral ramifications into context. RESUMEN Grik4 es el gen responsable de codificar la subunidad GluK4 de alta afinidad de los receptores de kainato. El aumento de la dosis de esta subunidad en el prosencéfalo se relacionó con un mayor nivel de ansiedad, falta de comunicación social y depresión. A nivel sináptico, también se informó una transmisión sináptica anormal. Las manifestaciones de esta expresión anormal no se han investigado a nivel de circuito, ni las correlaciones entre esos circuitos y los patrones anormales de la conducta previamente informada. En esta línea de trabajo, aspiramos a utilizar diferentes modalidades de imágenes por resonancia magnética (MRI) no invasivas para dilucidar cualquier alteración que pudiera derivarse del aumento de la dosis de Grik4 y cómo esos cambios podrían explicar los comportamientos anormales. La resonancia magnética ofrece una forma no invasiva de observar el cerebro intacto in vivo. La resonancia magnética funcional en estado de reposo arroja luz sobre cómo funciona el cerebro en reposo en el nivel de la red y tiene la capacidad de detectar cualquier anomalía que pueda ocurrir dentro o entre esas redes. En el nivel microestructural, la resonancia magnética de difusión se ocupa de las características subyacentes de los tejidos utilizando la difusión de moléculas de agua como un proxy para ese fin. Moviéndose más macroscópicamente, utilizando escaneos estructurales, la morfometría basada en vóxeles puede detectar diferencias sutiles en la morfología de las diferentes estructuras cerebrales. Grabamos videos de nuestros animales realizando dos tareas que durante mucho tiempo se han relacionado con la ansiedad, el campo abierto y las pruebas de laberinto positivo antes de adquirir escaneos estructurales y funcionales. Por último, registramos señales dependientes del nivel de oxigenación de la sangre (BOLD) en un grupo diferente de animales durante la estimulación eléctrica de tractos específicos de materia blanca para investigar cómo se propaga la actividad neuronal. Nuestro análisis mostró un amplio espectro de cambios en el grupo transgénico en relación con los animales en el grupo de control. En el nivel de las redes de estado de reposo, observamos un aumento en la fuerza dentro de la red que abarca diferentes estructuras como el hipocampo, algunas regiones de la corteza y el hipotálamo. La mayor coherencia interna o fuerza en las redes contrastó con una reducción significativa en la conectividad entre redes para algunas regiones como partes de la corteza y el hipotálamo, lo que sugiere una descorrelación de redes de largo alcance. Apoyando esta idea, los grandes tractos de materia blanca (WM), como el cuerpo calloso y la comisura del hipocampo, sufrieron cambios sustanciales compatibles con una importante reducción de la mielinización y / o una disminución del diámetro axonal medio. Macroestructuralmente hablando, la sobreexpresión de la subunidad GluK4 tuvo un efecto bimodal, con expansión en algunas áreas corticales en los animales transgénicos acompañada de una contracción en las regiones subcorticales. Al estimular el cerebro con una corriente eléctrica, notamos una diferencia en la propagación de la actividad entre las dos hemiesferas. En los animales transgénicos, la actividad evocada permaneció más confinada al hemisferio estimulado, de nuevo consistente con una conectividad de largo alcance deteriorada. Los cambios estructurales, tanto a nivel micro como macro, estaban en estrecha correlación con diferentes aspectos de la conducta, incluidos marcadores de ansiedad como el tiempo pasado con los brazos abiertos frente a los brazos cerrados en la prueba del laberinto positivo y el tiempo pasado en el centro vs las esquinas en la prueba de campo abierto. Nuestros hallazgos revelan cómo la interrupción de los receptores de kainato, o más globalmente los receptores de glutamato, y la transmisión sináptica anormal pueden traducirse en cambios de conectividad en todo el cerebro y alterar el equilibrio funcional entre las redes macro y mesoscópicas. La mejora postsináptica informada anteriormente en los animales transgénicos se reflejó aquí en la señal BOLD y se midió como un aumento en la fuerza dentro de la red. Es importante destacar que las correlaciones entre los cambios estructurales y elcomportamiento ayudan a contextualizar los cambios en el desarrollo y sus ramificaciones conductuales

    Early postnatal development of neocortex-wide activity patterns in GABAergic and pyramidal neurons

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    Before the onset of sensory experience, developing circuits generate synchronised activity that will not only influence its wiring, but ultimately contribute to behaviour. These complex functions rely on widely distributed cortical that simultaneously operate at multiple spatiotemporal scales. The timing of GABAergic maturation appears to align with the developmental trajectories of cortical regions, playing a crucial role in the functional development of individual brain areas. While local connectivity in cortical microcircuits has been extensively studied, the dynamics of brain-wide functional maturation, especially for GABAergic populations, remain underexplored. In this project, a dual-colour widefield calcium imaging approach was developed to examine the neocortex-wide dynamics of cortical GABAergic and excitatory neurons simultaneously across early postnatal development. This study provides the first broad description of neocortex-wide GABAergic developmental trajectories and their cross-talk with excitatory dynamics during the second and third postnatal weeks. The observed spontaneous activity revealed discrete activity domains, reflecting the modular organisation of the cortex. Both excitatory and GABAergic population exhibited an increase in the size and frequency of activity motifs, as well as changes in motif variability. However, as they matured, the distribution of these spatiotemporal properties displayed divergent trajectories across populations and regions. These findings suggest fundamental differences in the spatial organisation of both populations, indicating potential distinct roles in cortical network function development. Moreover, while excitatory and GABAergic dynamics exhibited high correlations, brief deviations from perfect timing were observed. This correlation patterns changed significantly during development and across regions, with the two populations gradually becoming more correlated as they matured. Manipulating inhibition in vivo disrupted these fluctuations, impacting both local activity and the wider functional network.These findings provide valuable insights into the developmental trajectories of spontaneous activity patterns in excitatory and GABAergic cell populations during early postnatal development. The interplay between both neuronal populations plays a critical role in shaping activity patterns, and understanding the underlying mechanisms of their development can provide valuable insights into neurodevelopmental disorders

    Micro-, Meso- and Macro-Dynamics of the Brain

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    Neurosciences, Neurology, Psychiatr

    Spatiotemporal development of the forebrain in the Dp(16)1Yey/+ mouse model of Down syndrome

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    Down syndrome (DS), or trisomy 21 (Ts21), is the most common genetic developmental disorder with a prevalence of about one in 700 live births. The triplication of human chromosome 21 (Hsa21) that characterizes this disorder results in a constellation of cognitive and physical alterations. The cognitive deficits range from mild to severe, and persist throughout life. Post-mortem studies of individuals with DS have revealed various neuropathologic abnormalities that are thought to underlie cognitive dysfunction, including: disruption of neurogenesis, corticogenesis, synapse formation, and myelination. However, the etiology of these alterations remains largely unknown. In order to elucidate the genetic basis of DS-phenotypes, several mouse models have been developed. The Ts65Dn, Ts1Cje, and Ts16 models, recapitulate DS-related phenotypes and have extended our knowledge of the associated pathological changes. Despite this progress, genetic dissimilarities in mouse models may confound phenotypic comparisons between mouse models and human DS. Specifically, the aforementioned models have a limited subset of triplicated Hsa-21 homologs or contain non-syntenic genes. Recently, a novel mouse model, the Dp(16)1Yey/+ (or Dp16), that has the entire Hsa-21 syntenic region of Mmu16 triplicated and no non-syntenic genes has been developed, suggesting that Dp16 may present phenotypes more closely matching the human disorder. In this study, we present the first comprehensive analysis of Dp16 embryonic, young and adult brains that includes a focus on the proliferative, inhibitory/excitatory neuronal and oligodendrocyte-lineage phenotypes using histological, immunohistochemical, and behavioral assessments. We hypothesize that due to the larger triplicated segment, the Dp16 mouse model better recapitulates DS-related neuropathologies relative to other mouse models. Despite the extended triplication, Dp16 animals lack DS-related embryonic phenotypes, however, behavioral and cellular phenotypes arise during the 2nd week following birth. The Dp16 is the first model of DS to develop postnatal phenotypes in the absence of changes to embryonic brain development, as such, Dp16 may not be a reliable model to further understand brain development in the DS fetus. However, when used in conjuncture with other models, the Dp16 will be a useful tool in understanding the contribution of aneuploidy and gene dosage to DS-phenotypes in mouse models of DS

    The role of mechanistic target of rapamycin (mTOR) pathway and synaptic protein GABAA-R in cortical GABAergic cell connectivity

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    Quelque 30 % de la population neuronale du cortex mammalien est composée d’une population très hétérogène d’interneurones GABAergiques. Ces interneurones diffèrent quant à leur morphologie, leur expression génique, leurs propriétés électrophysiologiques et leurs cibles subcellulaires, formant une riche diversité. Après leur naissance dans les éminences ganglioniques, ces cellules migrent vers les différentes couches corticales. Les interneurones GABAergiques corticaux exprimant la parvalbumin (PV), lesquels constituent le sous-type majeur des interneurones GABAergiques, ciblent spécifiquement le soma et les dendrites proximales des neurones principaux et des neurones PV+. Ces interneurones sont nommés cellules à panier (Basket Cells –BCs) en raison de la complexité morphologique de leur axone. La maturation de la connectivité distincte des BCs PV+, caractérisée par une augmentation de la complexité de l’axone et de la densité synaptique, se déroule graduellement chez la souris juvénile. Des travaux précédents ont commencé à élucider les mécanismes contrôlant ce processus de maturation, identifiant des facteurs génétiques, l’activité neuronale ainsi que l’expérience sensorielle. Cette augmentation marquante de la complexité axonale et de la synaptogénèse durant cette phase de maturation suggère la nécessité d’une synthèse de protéines élevée. La voie de signalisation de la cible mécanistique de la rapamycine (Mechanistic Target Of Rapamycin -mTOR) a été impliquée dans le contrôle de plusieurs aspects neurodéveloppementaux en régulant la synthèse de protéines. Des mutations des régulateurs Tsc1 et Tsc2 du complexe mTOR1 causent la sclérose tubéreuse (TSC) chez l’humain. La majorité des patients TSC développent des problèmes neurologiques incluant des crises épileptiques, des retards mentaux et l’autisme. D’études récentes ont investigué le rôle de la dérégulation de la voie de signalisation de mTOR dans les neurones corticaux excitateurs. Toutefois, son rôle dans le développement des interneurones GABAergiques corticaux et la contribution spécifique de ces interneurones GABAergiques altérés dans les manifestations de la maladie demeurent largement inconnus. Ici, nous avons investigué si et comment l’ablation du gène Tsc1 perturbe le développement de la connectivité GABAergique, autant in vitro que in vivo. Pour investiguer le rôle de l’activation de mTORC1 dans le développement d’une BC unique, nous avons délété le gène Tsc1 en transfectant CRE-GFP dirigé par un promoteur spécifique aux BCs dans des cultures organotypiques provenant de souris Tsc1lox. Le knockdown in vitro de Tsc1 a causé une augmentation précoce de la densité des boutons et des embranchements terminaux formés par les BCs mutantes, augmentation renversée par le traitement à la rapamycine. Ces données suggèrent que l’hyperactivation de la voie de signalisation de mTOR affecte le rythme de la maturation des synapses des BCs. Pour investiguer le rôle de mTORC1 dans les interneurones GABAergiques in vivo, nous avons croisé les souris Tsc1lox avec les souris Nkx2.1-Cre et PV-Cre. À P18, les souris Tg(Nkx2.1-Cre);Tsc1flox/flox ont montré une hyperactivation de mTORC1 et une hypertrophie somatique des BCs de même qu’une augmentation de l’expression de PV dans la région périsomatique des neurones pyramidaux. Au contraire, à P45 nous avons découvert une réduction de la densité des punctas périsomatiques PV-gephyrin (un marqueur post-synaptique GABAergique). L’étude de la morphologie des BCs en cultures organotypiques provenant du knock-out conditionnel Nkx2.1-Cre a confirmé l’augmentation initiale du rythme de maturation, lequel s’effondre ensuite aux étapes développementales tardives. De plus, les souris Tg(Nkx2.1Cre);Tsc1flox/flox montrent des déficits dans la mémoire de travail et le comportement social et ce d’une façon dose-dépendante. En somme, ces résultats suggèrent que l’activation contrôlée de mTOR régule le déroulement de la maturation et la maintenance des synapses des BCs. Des dysfonctions de la neurotransmission GABAergique ont été impliquées dans des maladies telles que l’épilepsie et chez certains patients, elles sont associées avec des mutations du récepteur GABAA. De quelle façon ces mutations affectent le processus de maturation des BCs demeuret toutefois inconnu. Pour adresser cette question, nous avons utilisé la stratégie Cre-lox pour déléter le gène GABRA1, codant pour la sous-unité alpha-1 du récepteur GABAA dans une unique BC en culture organotypique. La perte de GABRA1 réduit l’étendue du champ d’innervation des BCs, suggérant que des variations dans les entrées inhibitrices en raison de l’absence de la sous-unité GABAAR α1 peuvent affecter le développement des BCs. La surexpression des sous-unités GABAAR α1 contenant des mutations identifiées chez des patients épileptiques ont montré des effets similaires en termes d’étendue du champ d’innervation des BCs. Pour approfondir, nous avons investigué les effets de ces mutations identifiées chez l’humain dans le développement des épines des neurones pyramidaux, lesquelles sont l’endroit privilégié pour la formation des synapses excitatrices. Somme toute, ces données montrent pour la première fois que différentes mutations de GABRA1 associées à des syndromes épileptiques peuvent affecter les épines dendritiques et la formation des boutons GABAergiques d’une façon mutation-spécifique.About 30% of the total neuronal population in the mammalian cortex is composed by a very heterogeneous population of GABAergic interneurons. These interneurons differ in their morphology, gene expression, electrophysiological properties and subcellular targets, thus establishing a rich diversity. After birth in the ganglionic eminences these cells migrate to distinct cortical layers. Parvalbumin (PV) expressing cortical GABAergic cells which constitute the major GABAergic subtype specifically targets the soma and proximal dendrites of principal neurons and PV+ cells. These cells are often referred as Basket cells (BCs) because of the intricate morphological complexity of their axons. The maturation of the distinct connectivity of PV+ BCs, characterized by an increase of axon complexity and synapse density, occurs gradually in juvenile mice. Previous studies started to elucidate the mechanisms controlling this maturation process, including genetic factors, neuronal activity and sensory experiences. The striking increase in axonal complexity and synaptogenesis occurring during the maturation phase suggests the requirement for elevated proteins synthesis in order to sustain the developmental process. The Mechanistic Target Of Rapamycin (mTOR) pathway has been implicated in controlling several aspects of neurodevelopment by regulating protein synthesis. Mutations in the regulatory components Tsc1 and Tsc2 of mTOR-Complex1 (mTORC1) cause the disease Tuberous Sclerosis (TSC) in humans. The majority of TSC patients develop neurological problems including seizures, mental retardation and autism. Recent studies investigated the role of mTOR pathway dys-regulation in excitatory cortical cells, however its role in the development of cortical GABAergic interneurons and the specific contribution of altered GABAergic cells in disease manifestation remain largely unknown. Here, we investigated whether and how Tsc1 knockout perturbs GABAergic circuit development, both in vitro and in vivo. To investigate the role of mTORC1 activation in BC development, we knocked out Tsc1 expression, by transfecting Cre-GFP driven by a promoter specific for BCs in cortical organotypic cultures prepared from Tsc1lox mice. Tsc1 knockdown in vitro caused a precocious increase in bouton density and terminal branching formed by mutant BCs, which was reversed by Rapamycin treatment. These data suggest that mTOR pathway hyperactivation affects the timing of BC synapse maturation. To investigate the role of mTORC1 in GABAergic cells in vivo, we bred Tsc1lox mice with Nkx2.1-Cre and PV-Cre mice. At P18, Tg(Nkx2.1Cre),Tsc1flox/flox mice showed both mTORC1 hyperactivation and somatic hypertrophy in BCs along with increased expression of PV in the perisomatic region of pyramidal neurons. In contrast, by P45 we found a reduction of PV-gephyrin (post-synaptic GABAergic marker) perisomatic puncta density. Study of BC morphology in organotypic cultures from the Nkx2.1-Cre conditional knockout confirmed the occurrence of a faster maturation rate initially which however collapsed at later stages. Additionally Tg(Nkx2.1Cre),Tsc1flox/flox mice exhibit Tsc1 dose-dependent deficits in working memory and social behaviour. All together, these results suggest that controlled mTOR activation regulates both the time course and the maintenance of BC synapses. Dysfunction of GABAergic neurotransmission has been implicated in several disease states like epilepsy and in some patients it is associated with mutations in the GABAA receptor. How these mutations affect the BC cell maturation process remains largely unknown. To address this question, we used the Cre-lox strategy to knockout the endogenous GABRA1 gene coding for the GABAA-receptor alpha-1 subunit in single PV-expressing basket cells (BCs) in organotypic cultures. Cell-autonomous loss of GABRA1 reduced the extent of BC innervation field suggesting changes in inhibitory inputs caused by the absence of GABAAR α1 subunit may alter BC development. Over-expression of mutant GABAAR α1 subunits (found in patients diagnosed with epilepsy) show similar effects in terms of BC target coverage. Further studies involved the effect of these human mutations in the development of Pyramidal cell dendritic spines, which are the preferential site for excitatory synapse formation. Altogether, this data show for the first time that different GABRA1 mutations associated with genetic epilepsy syndromes can affect dendritic spine and GABAergic bouton formation in a mutation-specific manner
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