The glutamate post-synaptic density in schizophrenia

Matas, Emmanuel

January 2012

Non-competitive antagonists of the glutamate N-methyl-D-aspartate receptor (NMDAR) induce a broad range of schizophrenia-like symptoms in humans. Consequently hypothesis has emerged suggesting that glutamate or NMDAR hypofunction may occur in schizophrenia. The NMDAR is localised at dendritic spines of neurons and is embedded in a multi-protein complex called the post-synaptic density (PSD). The biochemical composition of the postsynaptic membrane and the structure of dendritic spines are continuously modulated by glutamatergic synaptic activity. The activity-dependent interaction between glutamate receptors and proteins of the PSD stimulate intracellular signalling pathways underlying learning and memory processes. These may be disturbed in schizophrenia. In the present study we hypothesised that molecules of the PSD may be disturbed in expression in the premotor cortex of patients with schizophrenia. Postmortem premotor cortex from patients with schizophrenia, major depressive disorder, bipolar disorder and healthy controls were processed for PSD extraction and purification. Protein expression of the PSD fraction was assessed using co-immunoprecipitation (co-IP) and Western blotting (WB) methods. The expression of NMDAR subunit NR2A, PSD-95, Ca2+/calmodulin-dependent protein kinase II subunit β (CaMKIIβ) and truncated isoform of the tropomyosin receptor kinase type B (TrkB-T1) were significantly reduced in schizophrenia. A significant decrease in the expression of NR2A was also observed in patients with major depressive disorder relative to controls. A decrease in the abundance of key PSD proteins in schizophrenia provides strong evidence that PSD function and possibly synaptic plasticity may be disturbed in the premotor cortex in the disease. There may also be more subtle disturbances in PSD function in major depressive disorder.

616.89

A descending circuit derived from the superior colliculus modulates vibrissal movements / ラットのヒゲ運動における上丘からの下行性神経調節機構

Kaneshige, Miki

25 March 2019

京都大学 / 0048 / 新制・課程博士 / 博士(人間健康科学) / 甲第21706号 / 人健博第72号 / 新制||人健||5(附属図書館) / 京都大学大学院医学研究科人間健康科学系専攻 / (主査)教授 澤本 伸克, 教授 木下 彩栄, 教授 渡邉 大 / 学位規則第4条第1項該当 / Doctor of Human Health Sciences / Kyoto University / DFAM

whisker

premotor neurons

rat

anterograde tracing

kinematic analysis

498

Bases neurales de la respiration chez la souris : traçage monosynaptique et dissection génétique des neurones prémoteurs phréniques / Neural Bases of Breathing in the Mouse : Monosynaptic Tracing and Genetic Dissection of Phrenic Premotor Neurons

Wu, Jinjin

28 June 2016

Le comportement respiratoire est unique en ce qu’il requiert l’activation permanente de muscles squelettiques. Le contrôle exécutif de la respiration repose sur des groupes d’interneurones connectés par des synapses et formant un réseau ordonné : le générateur central respiratoire (CPG). Nous cherchons à comprendre l’implication de types neuronaux définis dans la logique de l’organisation du CPG respiratoire. Nous avons précédemment démontré que les neurones constitutifs du – complexe preBötzinger (preBötC) – le générateur du rythme inspiratoire, dérivaient de progéniteurs neuraux exprimant le gène à homéoboite Dbx1. J’étudie ici, par traçage viral monosynaptique chez des souriceaux, les neurones prémoteurs à l’interface entre le générateur de rythme et les motoneurones phréniques innervant le diaphragme. Je montre que les principaux neurones prémoteurs formant – le groupe respiratoire ventral rostral (rVRG) – sont aussi des neurones de type V0. Ce travail révèle une organisation des circuits inspiratoires dans laquelle les lignages cellulaires de types V0 sont cruciaux pour établir (i) le preBötC (générateur du rythme) et le rVRG (suiveur du rythme) et (ii) un dessin de connectivité assurant bilatéralement l’amplitude équilibrée et la synchronisation de la commande motrice des nerfs phréniques requise pour respirer efficacement. / Breathing uniquely engages permanent rhythmic contractions of skeletal muscles in a bilaterally synchronized manner. The executive control of respiration imparts on sets of brainstem interneurons synaptically assembled into an ordered network: the respiratory central pattern generator (CPG). We investigate the relationship of defined neuronal subtypes to the organizational logic of the respiratory CPG. We have previously demonstrated that neural progenitors expressing the homeobox gene Dbx1 give rise to V0 neurons that go on forming the – preBötzinger complex (preBötC) -- the inspiratory rhythm generator. I now study, via monosynaptic viral tracing in early postnatal mice, the premotor neurons that interface the rhythm generator to output phrenic motor neurons innervating the main inspiratory pump muscle, the diaphragm. I show that the principal premotor neurons in the – rostral ventral respiratory group (rVRG) – are also V0 interneurons. This work reveals an organization of inspiratory circuits in which V0 cell lineages are crucial for establishing (i) the preBötC (rhythm generator) and the rVRG (rhythm follower) and (ii) a connectivity design that secures the bilaterally balanced amplitude and temporal synchronicity of rhythmic phrenic motor drives necessary for efficient breathing.

Pré-Moteurs

Respiratoire

Tronc cérébral

Premotor neurons

Respiration

Brainstem

Neuronal basis of goal-directed reach planning under reversed vision in the parietal and premotor cortices

Kuang, Shenbing

19 February 2013

No description available.

570

reach planning

reversed vision

parietal reach region

dorsal premotor cortex

Biologie (PPN619462639)

Cell based therapy following cortical injury in Rhesus monkeys reduces secondary injury and enhances neurorestorative processes

Orczykowski, Mary Elizabeth

01 November 2017

While physical rehabilitation facilitates some recovery, it is uncommon for patients to recover completely from stroke. Cell based therapies derived from stem cells have produced promising results in enhancing recovery in pre-clinical studies, but the mechanism is not yet completely understood. We previously evaluated human umbilical tissue-derived cells (hUTC) in our non-human primate model of cortical injury, limited to the hand area of primary motor cortex. hUTC treatment, injected intravenously 24 hours after injury, resulted in significantly greater recovery of fine motor function compared to treatment with vehicle. Based on these striking findings, in the current study, we investigated the hypothesis that hUTC treatment leads to functional recovery through reducing cytotoxic responses and enhancing neurorestorative processes following cortical injury. Brain sections were assessed using histological techniques to quantify perilesional oxidative damage, hemosiderin accumulation, microglial activation, Betz cell number, synaptic density, and astrocytic complexity. Brain sections outside of the primary area of injury were also assessed for microglial activation in white matter pathways, cell activation through c-Fos in premotor cortices, and neurogenesis in neurogenic niches. Finally, blood samples from throughout the recovery period and CSF samples from 16 weeks after injury were analyzed for BDNF levels. In the perilesional area, hUTC treatment was associated with lower oxidative damage and hemosiderin accumulation, but not with a difference in microglial activation. hUTC also resulted in a trend toward higher astrocyte complexity and synaptic density in the lesion area, but no difference in ipsilesional Betz cell number. Further, hUTC treatment led to more microglia in white matter pathways, higher c-Fos activation in ventral premotor cortex, and a trend toward higher neurogenesis in the hippocampus. Finally, BDNF levels were higher in blood with hUTC treatment one week after injury, but there was no change beyond one week in blood serum or in CSF, when compared with vehicle. Taken together, these results suggest that hUTC treatment modulates immune responses, limits perilesional damage and cell death, enables neuroplasticity and reorganization, and enhances acute neurotrophic factor secretion. While many cell therapies are currently undergoing clinical trials, this study advances our understanding of the mechanism of cell based therapies.

Neurosciences

hUTC

Reorganization

Cell based therapy

Cortical injury

Secondary injury

Ventral premotor cortex

Organization of prefrontal and premotor layer-specific pathways in rhesus monkeys

Bhatt, Hrishti

16 February 2024

The Lateral Prefrontal Cortex (LPFC) and the Dorsal Premotor cortex (PMd) are two cortical structures that are involved in cognitive processes such as motor planning and decision-making. The LPFC is extensively connected to sensory, somatosensory, and motor cortices that help it control several cognitive functions [for review, see: (Tanji & Hoshi, 2008)]. Similarly, the PMd can integrate information from the prefrontal and motor cortex, acting as a link, in action planning and decision making [for review, see: (Hoshi & Tanji, 2007)]. Therefore, it is important to study the cortical pathways between these areas because of their common role in processing and selecting relevant information in tasks requiring decision-making. Using neural tract-tracing, immunolabeling and microscopy in rhesus monkeys (M. mulatta), we assessed the distribution and layer-specific organization of projection neurons from LPFC area 46 and PMd area 6 directed to the LPFC area 9. Our study revealed that projection neurons to area 9 were found originating from upper (L2-3) and deep (L5-6) layers of both areas, but with a slight upper layer bias. We found that the LPFC area 46 had a higher density of projection neurons directed to LPFC area 9 compared to the PMd area 6. Additionally, our data also revealed laminar differences in the perisomatic parvalbumin (PV) inhibitory inputs onto area 9 projection neurons, which were dependent on area of origin. Within ventral LPFC area 46, perisomatic PV+ inhibitory inputs onto upper layer projection neurons to area 9 was greater than those onto deep layer projection neurons. The opposite pattern was found for PMd area 6DR, where perisomatic PV+ inhibition onto deep layer projection neurons to area 9 was greater than those onto upper layer neurons. These findings provide additional insights into the layer-specific organization of prefrontal and premotor pathways that play an important role in action planning and decision-making.

Neurosciences

Cortical pathways

Inhibitory neurons

Lateral prefrontal cortex

Non-human primate

Premotor cortex

Tract-tracing

Continuous detection and prediction of grasp states and kinematics from primate motor, premotor, and parietal cortex

Menz, Veera Katharina

29 April 2015

No description available.

570

decoding

primate

motor cortex

premotor cortex

parietal cortex

neurprosthetics

spiking activity

microelectrodes

Kalman filter

Support Vector Machine

Biologie (PPN619462639)

Monkey see, monkey touch, monkey do: Influence of visual and tactile input on the fronto-parietal grasping network

Buchwald, Daniela

13 March 2020

No description available.

570

Grasping

Somatosensory cortex

Motor cortex

Parietal cortex

Premotor cortex

macaque monkey

multi-electrode recording

object recognition

Biologie (PPN619462639)

The Cortical Effects of Object Affordances on Motor Action Priming Used in Rapid Balance Recovery Actions

Foglia, Stevie

January 2019

There is considerable evidence to suggest that object affordances (see Gibson, 1966) can serve to moderate volitional responses by “priming” the visuomotor system toward certain actions (e.g., Tucker & Ellis, 1998). Typically, these studies assume that shorter voluntary reaction time latencies reflect more efficient movement planning. Questions remain however, as to whether object affordances offer the same motor priming benefits in situations where the temporal window to initiate motor action precludes volitional movements (e.g., during an unexpected balance perturbation). The efficiency of balance reactions to a perturbation is dependent upon the ability for the motor system to generate short latency actions at the onset of instability. Due to the rapid nature of these actions, they are suggested to be regulated by information received prior to the perturbation. In this study, participants sat in a custom-built chair that delivered posterior perturbations and, on each trial, were presented with two of three types of stimuli within their reach (two graspable poles that varied in orientation and a flat non-graspable control). They were instructed to reach and grasp one of the poles at the moment of perturbation so as to mitigate the tilt. To assess cortical activity that may be indicative of motor planning in response to the perception of object affordances, changes in oxyhemoglobin (oxy-Hb) in the right and left premotor cortices were measured using a continuous wave fNIRS system. Results revealed a significant increase (F= 4.62, p= .043) in oxy-Hb in the right and left hemisphere (M = .023 µM) in response to objects that afford an optimal form of grasping action (mitigating excessive supination or pronation of the hand), compared to when no grasping opportunity was present (M = -.051 µM). These results suggest that affordances may be used to prime the system in the event of a balance threat. / Thesis / Master of Science (MSc)

Neural correlates of affordance competition in dorsal premotor cortex

Pastor-Bernier, Alexandre

08 1900

Le travail présenté dans cette thèse porte sur le rôle du cortex prémoteur dorsal (PMd) au sujet de la prise de décision (sélection d’une action parmis nombreux choix) et l'orientation visuelle des mouvements du bras. L’ouvrage décrit des expériences électrophysiologiques chez le singe éveillé (Macaca mulatta) permettant d’adresser une fraction importante des prédictions proposées par l'hypothèse des affordances concurrentes (Cisek, 2006; Cisek, 2007a). Cette hypothèse suggère que le choix de toute action est l’issue d'une concurrence entre les représentations internes des exigences et des atouts de chacune des options présentées (affordances; Gibson, 1979). Un intérêt particulier est donné au traitement de l'information spatiale et la valeur des options (expected value, EV) dans la prise de décisions. La première étude (article 1) explore la façon dont PMd reflète ces deux paramètres dans la période délai ainsi que de leur intéraction. La deuxième étude (article 2) explore le mécanisme de décision de façon plus détaillée et étend les résultats au cortex prémoteur ventral (PMv). Cette étude porte également sur la représentation spatiale et l’EV dans une perspective d'apprentissage. Dans un environnement nouveau les paramètres spatiaux des actions semblent être présents en tout temps dans PMd, malgré que la représentation de l’EV apparaît uniquement lorsque les animaux commencent à prendre des décisions éclairées au sujet de la valeur des options disponibles. La troisième étude (article 3) explore la façon dont PMd est impliqué aux “changements d'esprit“ dans un procès de décision. Cette étude décrit comment la sélection d’une action est mise à jour à la suite d'une instruction de mouvement (GO signal). I II Les résultats principaux des études sont reproduits par un modèle computationnel (Cisek, 2006) suggérant que la prise de décision entre plusieurs actions alternatives peux se faire par voie d’un mécanisme de concurrence (biased competition) qui aurait lieu dans la même région qui spécifie les actions. / This thesis examines the role of the dorsal premotor cortex (PMd) in the process of decision making (action selection) and visual guidance of arm movements. The work describes electrophysiological experiments conducted in awake monkeys (Macaca mulatta) and tests a number of important predictions suggested by the affordance competition hypothesis (Cisek, 2006; Cisek, 2007a). This hypothesis suggests that decisions can be viewed as the result of a competition between internal representations of conflicting demands and opportunities for actions or affordances (Gibson, 1979). Specific interest is given to the interaction between spatial information and expected value (EV) in a proposed affordance competition mechanism for action selection. The first study presented (article 1) explores how EV is represented during the delay period in PMd. This study also describes how this area reflects the spatial metrics of the options and examines the interaction between value and spatial information. The second study (article 2) explores the mechanism of action selection in more detail and extends the results to ventral premotor cortex (PMv). This study also addresses the nature of value and spatial representations from a learning perspective. In a novel environment the spatial metrics of the actions seem to be invariably present in PMd, meanwhile EV representations appear only once the animals make behaviorally informed decisions about the value of the available options. The third study (article 3) explores how PMd is involved in “changes of mind” in which action selection is updated following a movement instruction (GO signal). III IV The major findings in all these studies are reproduced by a computational model (Cisek, 2006) suggesting that decisions between actions can be made through a biased competition process that takes place in the same region that specifies the actions.

decisions

decision

bias

competition

affordance

action selection

action specification

premotor cortex

PMd

PMv

relative value

absolute value

distance

spatial parameters

electrophysiology

electrophysiologie