1 |
Pyramidal cell diversity in the rat prefrontal cortex : electrophysiology, dopamine modulation and morphologyBartsch, Ullrich January 2011 (has links)
The prefrontal cortex (PFC) is critically involved in many higher cognitive functions such as goaldirected behaviour, affective behaviour and especially working memory. In vivo extracellular recordings of PFC neural activity during working memory tasks show high variety in observed spiking patterns. These complex dynamics are critically shaped by intrinsic, synaptic and structural parameters of respective prefrontal networks. Moreover, dopamine (DA) is crucial for correct functioning of the PFC during working memory tasks. DA modulates a number of synaptic and intrinsic biophysical properties of single neurons, in particular deep layer pyramidal cells, which represent the major output neurons of the PFC. Despite a high variability of cortical pyramidal cell firing patterns, and somatodendritic morphology, no study has yet systematically examined correlations between intrinsic properties, morphological features and dopaminergic modulation of intrinsic properties. This study investigated properties of deep layer pyramidal cells through whole cell patch clamp in acute brain slices of the adult rat PFC. Cells were characterised physiologically through a variety of stimulation protocols surveying different time scales and wide intensity ranges, while all fast synaptic transmission was blocked. Furthermore the same catalogue of stimuli was recorded whilst applying specific DA receptor agonists to elucidate effects of DA receptor activation on intrinsic properties. All recorded cells were injected with biocytin and dendritic morphology was reconstructed from confocal image stacks of fluorescently labelled neurons. From the resulting data a set of characteristic variables were defined and a combination of principal components analysis and hierarchical cluster analysis was used to identify similarity between recorded cells in different parameter spaces spanned by intrinsic properties, intrinsic properties under dopaminergic modulation and morphology, respectively. The analysis presents evidence for distinct subpopulations within prefrontal deep layer pyramidal cells, as seen by clustering of recorded cells in these high dimensional parameter spaces. These subpopulations also show distinct input-output relationships, bearing implications for computational functions of these subpopulations. Furthermore, this study presents for the first time evidence of subpopulation specific DA effects in deep layer pyramidal cells. The quantitative analysis of somatodendritic morphology confirms physiological subpopulations and identifies characteristic morphological features of deep layer pyramidal cells. Moreover, cluster observed in different parameter spaces overlap, leading to a definition of subpopulations that concurs with previously described prefrontal pyramidal cell types. In conclusion, the results presented provide some deeper insight into fundamental principles of information processing in prefrontal pyramidal cells under the influence of dopamine.
|
2 |
Chronic Effects of Antipsychotic Drugs on Pyramidal Cell Structure in Rat Anterior Cingulate Cortex: with relevance to schizophreniaDineshree Naiker Unknown Date (has links)
Antipsychotic drugs (typical and atypical) are used in the treatment of mental disorders such as schizophrenia. Typical antipsychotic drugs (such as haloperidol) specifically target dopamine D2 receptors and produce extrapyramidal side effects. Atypical antipsychotic drugs (such as risperidone and olanzapine) primarily target dopamine D2 and serotonin 5HT2A receptors and produce fewer extrapyramidal symptoms (EPS) than do the typical antipsychotic drugs at clinically effective doses (Meltzer and Nash, 1991). It has been proposed that the prefrontal cortex (a brain region implicated in the pathophysiology of schizophrenia) is the locus of antipsychotic drug action to improve cognitive dysfunction and negative symptoms of schizophrenia (Weinberger and Lipska, 1995; Jakab and Goldman-Rakic, 1998). Moreover, it is possible that the effects in the prefrontal cortex may contribute to the differences between typical and atypical antipsychotic drugs as well as differences among atypical antipsychotic drugs (Horacek et al., 2006). The core pathology associated with the dorsolateral prefrontal cortex includes reduced cerebral volume, increased ventricle size and deficits in neuronal morphology, including increased cell packing density, reduction in dendrites and its associated dendritic spines (Selemon and Goldman-Rakic, 1999). However, since most neuropathology data emerge from in vivo imaging and post-mortem studies of patients with schizophrenia, it is difficult to interpret and distinguish between findings that have an etiological or iatrogenic basis. Thus, the objective of the current study was to examine the effects of antipsychotic drugs, at therapeutically relevant concentrations, in a rat brain region that is homologous to that of the human dorsolateral prefrontal cortex. The hypothesis upon which this study was based is that haloperidol, risperidone and olanzapine (at 65 to 80% striatal dopamine D2 receptor occupancy) induce changes to pyramidal cell architecture in the rat anterior cingulate cortex (Vogt and Gabriel, 1993; Hoover and Vertes, 2007). This hypothesis was investigated by (a) determining doses that are within the therapeutic range (65 to 80% striatal dopamine D2 receptor occupancy) by measuring the occupancy of haloperidol, risperidone and olanzapine in the presence of 3H-raclopride ( a dopamine D2 receptor antagonist) at dopamine D2 receptors in the rat striatum; and (b) examining whether therapeutic doses of antipsychotic drugs in rats cause neuropathology comparable to that observed in human post-mortem brains of patients with schizophrenia. Antipsyhcotic drug doses were selected using an appropriate in vivo dopamine D2 receptor occupancy method. The findings from this study revealed that 0.25 mg/kg/day haloperidol, 5 mg/kg/day risperidone and 10 mg/kg/day olanzapine achieved therapeutically relevant rat striatal dopamine D2 receptor occupancy in the range of 65 to 80%. To determine whether antipsychotic drugs at therapeutic doses established above induce changes in neuronal cell density and morphology; immunohistochemistry, single cell injection of lucifer yellow dye and Golgi-Cox impregnation of layer II/III pyramidal cells was performed. The results from these experiments revealed that the density of cells expressing NeuN, parvalbumin, calretinin or calbindin is highly unlikely to be affected by chronic exposure to haloperidol, risperidone and olanzapine. The current study evaluated the effects of chronic antipsychotic drug exposure on spontaneous locomotor activity of a rat in a novel environment. The purpose of this study was to differentiate between a direct and an indirect drug effect. It was found that at the doses established above, risperidone and olanzapine did not overtly reduce spontaneous locomotor activity of a rat in a novel environment relative to controls. In contrast, haloperidol reduced spontaneous locomotor activity of rat in an open field, although this was not statistically significant. Nevertheless, the data reported here allowed us to conclude that the level of activity across groups is unlikely to affect the data obtained in subsequent studies investigating the effects of chronic antipsychotic drug treatment on pyramidal cell structure. Intracellular injection of lucifer yellow dye into pyramidal cells revealed that chronic haloperidol treatment (28 days) was associated with a relative increase in basal dendritic arborisation, but neither of these drug treatments induced changes in arborisation that were different from controls. No statistically significant change in the basal dendritic arbor was detected with animals treated with risperidone relative to controls. Similarly using the Golgi-impregnation method, changes in soma size, dendritic branching, total number of branches and the density of dendritic spines in antipsychotic drug treated groups were not significantly different to controls. Taken together, this finding indicates that only relatively subtle neuritic changes may be attributed to chronic treatment with typical or atypical antipsychotic drugs administered at doses that avhieved striatal dopamine D2 receptor occupancy in the range of 65 to 80%. In summary, this study confirms that antipsychotic drugs are unlikely to induce changes to neuronal cell density or morphology in the rat anterior cingulate cortex at therapeutically relevant doses. Hence, it can be concluded that the observed neuropathology, found in the brains of patients with schizophrenia that have undergone antipsychotic drug therapy, is more likely to be caused by the disease and not the effects of the concomitant drug therapy.
|
3 |
Rôle du VEGF dans la régulation de la synapse glutamatergique / VEGF modulates NMDAR synaptic function and localization in the hippocampusRossi, Pierre De 17 December 2013 (has links)
Le vascular endothelial growth factor (VEGF) un facteur de croissance essentiel du système vasculaire exerce des fonctions multiples sur les cellules nerveuses en favorisant la neurogenèse, la plasticité synaptique ou encore l'apprentissage et la mémoire. Cependant, les mécanismes impliqués dans son action régulatrice de la transmission et la plasticité synaptiques restent à élucider. Nous avons récemment mis en évidence une nouvelle interaction entre VEGFR2, le récepteur principal du VEGF, et les récepteurs NMDA (NMDAR) au cours de la migration des neurones pendant le développement du cervelet. Comme les NMDAR sont des acteurs clés de la transmission et de la plasticité synaptique, nous avons exploré le rôle du VEGF dans la régulation de l'expression et de la fonction des NMDAR synaptiques dans l'hippocampe. Nos résultats révèlent que le VEGF et son récepteur sont exprimés dans les régions CA1 et CA3 de l'hippocampe et le domaine extracellulaire de VEGFR2 peut se lier à la sous-unité GluN2B des NMDAR. Le VEGF est capable d'augmenter la transmission synaptique dépendant des NMDAR en régulant l'adressage synaptique des récepteurs exprimant la sous-unité GluN2B. Il se produit également une augmentation du nombre de synapses en présence du VEGF. Ces effets du VEGF requièrent la co-activation des récepteurs VEGFR2 et NMDAR et conduisent à un enrichissement synaptique en récepteurs glutamatergiques de type AMPA qui dépend de l'activation de la CaMKII. Nos travaux démontrent pour la première fois un rôle direct de la signalisation VEGF/VEGFR2 dans la fonction de la synapse excitatrice glutamatergique / The vascular endothelial growth factor (VEGF) plays a critical role during vascular development but recent evidence indicates that it also regulates various neuronal processes in the nervous system, such as neurogenesis, hippocampal synaptic plasticity, learning and memory. Recently, we showed a novel interaction between the glutamate receptor NMDA (NMDAR) and the VEGF receptor VEGFR2 during neuronal migration in the developing cerebellum. As NMDAR have been widely implicated in synaptic transmission and plasticity, we hypothesized that VEGF might regulate NMDAR function in hippocampal synaptic transmission and plasticity, as well as in learning and memory. Our results revealed that VEGF and its receptor VEGFR2 are expressed in the CA1 and CA3 regions of the hippocampus. Biochemical exploration highlighted an interaction between the extracellular domain of VEGFR2 and the GluN2B subunit of NMDAR. In addition, whole-cell patch clamp experiments in acute hippocampal slices showed that VEGF potentiates post-synaptic GluN2B-expressing NMDAR responses. Furthermore NMDAR and VEGFR2 co-activation in hippocampal neurons increased the pool of synaptic GluN2B-NMDAR and affects synapse number. These processes are associated with an increase in AMPAR synaptic expression and an involvment of CaMKII signaling pathway. Altogether, our results demonstrated for the first time a direct effect of VEGF on the function of excitatory glutamatergic synapses
|
4 |
The Role of the Neuronal gap Junction Protein Connexin36 in Kainic Acid Induced Hippocampal ExcitotoxicityAkins, Mark S. January 2014 (has links)
Kainic acid induced excitotoxicity causes pyramidal cell death in the CA3a/b region of the hippocampus. Electrical synapses, gap junctional communication, and single membrane channels in non-junctional membranes (hemichannels) composed of connexin36 (Cx36) have been implicated in both seizure propagation and the spread of excitotoxic cell death. In rats, Cx36 protein is expressed by pyramidal neurons. Localization of protein in mouse, however, is highly controversial. Expression is reported to be restricted to hippocampal interneurons yet the same excitotoxic mechanisms (electrical and metabolic coupling between pyramidal neurons) are invoked to explain the role of Cx36 in excitotoxic pyramidal loss in murine brain. To address this controversy, I show by confocal immunofluorescence and in situ hybridization that Cx36 protein expression is restricted to interneurons and microglia in murine hippocampus and is not expressed by, or is below level of detection in pyramidal neurons. Using behavioural and electrophysiological measures, seizure propagation was found to be moderately enhanced in the absence of Cx36 likely due to the loss of interneuron-mediated synchronous inhibition of the pyramidal cells. Further, CA3a/b neurons die post kainic acid injury in the presence of Cx36 but are protected in Cx36-/- mice. When delayed excitotoxic cell death is maximal, Cx36 is primarily expressed by activated microglia as demonstrated by confocal immunofluorescence, in situ hybridization, and Western blotting. These activated microglia are located in the direct vicinity of, and surrounding cells in the damaged Ca3a/b region. Finally, I show that loss of Cx36 from activated microglia in mice is sufficient to prevent excitotoxic cell death in the CA3a/b with surviving neurons functional as assessed by both electrophysiological and behavioural measures. Together, these data identify a new mechanism of excitotoxic injury, mediated by neuronal-glial interactions, and dependent on microglial Cx36 expression.
|
5 |
Analysis of hippocampal inhibitory and excitatory neurons during sharp wave-associated ripplePangalos, Maria 31 August 2016 (has links)
Im Hippokampus gibt es verschiedene Netzwerkoszillationen mit unterschiedlichen Frequenzen. Ein Typ dieser Oszillationen sind die ”Ripple” mit einer Frequenz von etwa 200 Hz, welche in Komplexen mit einer Aktivitätswelle, der ”Sharp wave” auftreten. Sharp wave-ripple Komplexe (SWR) werden mit der Konsolidierung von Gedächtnis in Zusammenhang gebracht. Das Netzwerk, das den SWR unterliegt, hat bestimmte Mechanismen, von denen einige in der vorliegenden Arbeit näher untersucht werden. Im ersten Teil wird untersucht, wie ein hemmendes Interneuron in der hippokampalen Region CA1, das ”oriens-lacunosum moleculare” (O-LM) Interneuron, während der SWR in das Netzwerk eingebunden ist. Wir konnten zeigen, dass O-LM Zellen während der SWR starke synaptische Exzitation erhalten. Die Exzitation tritt spät während des Ripples im lokalen Feldpotential (LFP) auf und zeigt eine Phasenankopplung an die Ripple. In etwa der Hälfte der O-LM Zellen konnten wir Aktionspotentiale während der SWR zeigen, die an die Ripple-Phase im LFP gebunden sind und nach dem Ripple-Maximum auftreten. Der zweite Teil der Arbeit bezieht sich auf die hippokampale Region CA1 und vergleicht während SWR den synaptischen Eingang in zwei Untertypen von Pyramidenzellen, die tiefen und die oberflächlichen Pyramidenzellen. Beide Untertypen bekommen synaptische Eingänge während der SWR. Diese Eingänge sind eine Mischung aus exzitatorischen und inhibitorischen Eingängen, die in den Untertypen in ihrer Stärke vergleichbar sind. Im dritten Teil untersuchen wir die SWR in der Region CA2 des Hippokampus und zeigen, dass Pyramidenzellen in CA2 in das Netzwerk während SWR eingebunden sind. Wir können sowohl exzitatorische als auch inhibitorische synaptische Eingänge in den Pyramidenzellen darstellen und konnten eine Phasenkopplung der synaptischen Eingänge an die SWR im LFP zeigen. Aufgrund der Phasenverschiebung bei verschiedenen Haltepotentialen vermuten wir einen Oszillator für die Exzitation und einen für die Hemmung. / In the hippocampus there are different patterns of activity also known as network oscillations. These oscillations express different frequencies, and one oscillation is the ripple oscillation at around 200 Hz. It is associated with an activity wave called sharp wave and form a so-called sharp wave-ripple complex (SWR). SWRs are implicated in memory consolidation. In this thesis we investigate mechanisms underlying sharp wave-ripple complexes. In the first part of this thesis I examine one type of inhibitory neurons in the region CA1 of the hippocampus during SWR. Oriens-lacunosum moleculare (O-LM) interneurons receive strong excitatory synaptic input during ripples. This input arrives after the ripple maximum and is phase locked with the ripple cycles. Around half of the probed O-LM cells fire during the SWR and thereby show an active participation during SWR. The magnitude of excitation in O-LM cells and the ratio between excitation and inhibition determine if an O-LM cell is active during the SWR. Action potentials in these cells occur late during the SWR and are phase locked. In the second part the synaptic input onto excitatory pyramidal cells were investigated during ripple oscillations. Previous work has identified two different types of pyramidal cells in area CA1. We recorded from deep and superficial pyramidal cells. For both types of pyramidal cells the inhibitory and excitatory synaptic inputs temporally associated with ripples express comparable strength. In the last and third part, I recorded SWR in the CA2 region of the hippocampus and showed incidence, frequency and amplitude of ripples and SWR. Pyramidal cells in the CA2 region are integrated into the network during SWR. They receive SWR associated synaptic input during SWR. The excitatory and inhibitory synaptic inputs in CA2 pyramidal cells were investigated in detail. Phase analysis show phase locking of local field potential ripples and synaptic inputs to the ascending phase of the ripple cycle.
|
6 |
The role of cell-type selective synaptic connections in rhythmic neuronal network activity in the hippocampusKatona, Linda January 2014 (has links)
No description available.
|
7 |
Hippocampal circuitsBöhm, Claudia 18 October 2016 (has links)
Der Hippokampus spielt eine wichtige Rolle bei der Erfassung, Festigung und dem Wiederabrufen von Gedächtnisinhalten. Diese Prozesse werden von Oszillationen begleitet, die synchronisierte neuronale Aktivität wiederspiegeln. Der erste Teil dieser Arbeit konzentriert sich auf ‘ripples’, eine schnell schwingende Netzwerkaktivität, die an der Festigung von Gedächtnisinhalten beteiligt ist. Das Subikulum ist eine der Hauptausgangsstationen des Hippokampus und überträgt Informationen zu Zielregionen außerhalb dieser Region. Um dies besser zu verstehen, habe ich hier die Eigenschaften von subikulären Pyramidenzellen und deren Regulierung während ripples untersucht. Es zeigte sich, dass eine Untergruppe von Zellen, burst (in Salven) feuernde Zellen, ihre Aktivität erhöht, während eine zweite Untergruppe, regulär feuerende Zellen, ihre Aktivitaet während ripples vermindert. Ferner ist bei regulär feuernden Zellen das Verhältnis zwischen Inhibition und Exzitation höher als bei burst feuernden Zellen. Zusammen mit Erkenntnissen aus früheren Studien lassen diese Ergebnisse vermuten, dass Information während ripples hauptsächlich zu Zielregionen der burst feuernden Zellen geleitet wird. Neben Pyramidenzellen beherbergt der Hippokampus auch eine Vielzahl verschiedener Interneurone. Im zweiten Teil dieser Arbeit habe ich O-LM Interneurone der hippokampalen Region CA1 untersucht. Diese spielen eine wichtige Rolle bei der Kontrolle von Eingängen aus dem entorhinalen Kortex. Wir konnten zeigen, dass die exzitatorische Übertragung auf O-LM Interneurone durch Serotonin, einem von den Raphe-Kernen ausgeschütteten Neuromodulator, vermindert wird. Dies geschieht durch einen präsynaptischen Mechanismus, der wahrscheinlich eine Verminderung des Kalziumeinstroms in präsynaptische Endigungen umfasst. Eine Verminderung der Aktivität von O-LM Interneuronen durch Serotonin könnte die synaptische Übertragung von Signalen aus dem entorhinalen Kortex auf CA1 Pyramidenzelldendriten erleichtern. / The hippocampus plays an important role in the acquisition, consolidation and retrieval of memory. These processes are accompanied by hippocampal oscillations, which reflect synchronized neuronal activity. The first part of this thesis focuses on ripples, a fast oscillatory activity which is involved in memory consolidation. The subiculum as one of the main output areas of the hippocampus is ideally suited to mediate information transfer to extrahippocampal targets. Here I investigated the properties of subicular pyramidal cells and their modulation during ripples. I found that a subset of subicular pyramidal cells increases its firing rate during ripples whereas another subset decreases its firing rate. Furthermore I was able to identify a correlate between modulation and cell subtype: burst firing cells increased their firing rate, and regular firing cells decreased their firing rate. We could further show that regular firing cells receive a higher ratio of inhibition to excitation as compared to burst firing cells. Together with earlier work, these results suggest that information transferred during ripples is likely to be routed preferentially to target regions of the burst firing subtype. Besides pyramidal cells, the hippocampus hosts a variety of interneuron types. The second part of this thesis focuses on GABAergic O-LM interneurons of hippocampal area CA1, which play an important role in controlling input from the entorhinal cortex. We could show that excitatory transmission from local pyramidal cells onto O-LM interneurons is decreased by serotonin, a neuromodulator released from the midbrain raphe nuclei. This modulation is mediated by a presynaptic mechanism and is likely to involve a decrease in calcium influx into presynaptic terminals. We conclude that serotonin, by decreasing O-LM output, might release fibers from entorhinal cortex impinging onto CA1 pyramidal cell dendrites from inhibition.
|
8 |
Single Cell Analysis of Hippocampal Neural Ensembles during Theta-Triggered Eyeblink Classical Conditioning in the RabbitDarling, Ryan Daniel 03 November 2008 (has links)
No description available.
|
Page generated in 0.0838 seconds