Animal Models of Prophylaxis and Prevention of Schizophrenia: Prenatal Seasonal Influenza Vaccine and Postnatal Valproate

Doucet, Jean-Sebastien

21 November 2012

Schizophrenia is a mental illness with early adult onset. Prophylactic treatments would be clinically important and therefore we investigated the effect of two interventions: influenza vaccination of pregnant mothers and valproate treatment during late adolescence. Maternal immune response during pregnancy is thought to adversely affect brain development. We sought to assess whether immune activation by influenza vaccine could itself cause behavioural abnormalities in a mouse model. Our data suggest that further work is needed to make firm conclusions about the behavioural effects of the influenza vaccine. The second part of this thesis describes an analysis of valproate treatment on cortical neuron morphology in Disc1 L100P mice, a model for schizophrenia. Valproate was previously shown to prevent the onset of abnormal behaviours in Disc1 L100P mice. Contrary to expectations, valproate decreased apical spine density and the number of dendritic processes rather than reversing the dendritic deficits seen in Disc1 L100P mice.

Valproate

Disc1

MIA

influenza

Disc1 L100P

Valproic Acid

VPA

Schizophrenia

maternal immune activation

neurodevelopment

prenatal

mouse

pregnancy

vaccine

behaviour

IL-6

postnatal

pyramidal neuron

cortex

morphology

0419

0317

Animal Models of Prophylaxis and Prevention of Schizophrenia: Prenatal Seasonal Influenza Vaccine and Postnatal Valproate

Doucet, Jean-Sebastien

21 November 2012

Schizophrenia is a mental illness with early adult onset. Prophylactic treatments would be clinically important and therefore we investigated the effect of two interventions: influenza vaccination of pregnant mothers and valproate treatment during late adolescence. Maternal immune response during pregnancy is thought to adversely affect brain development. We sought to assess whether immune activation by influenza vaccine could itself cause behavioural abnormalities in a mouse model. Our data suggest that further work is needed to make firm conclusions about the behavioural effects of the influenza vaccine. The second part of this thesis describes an analysis of valproate treatment on cortical neuron morphology in Disc1 L100P mice, a model for schizophrenia. Valproate was previously shown to prevent the onset of abnormal behaviours in Disc1 L100P mice. Contrary to expectations, valproate decreased apical spine density and the number of dendritic processes rather than reversing the dendritic deficits seen in Disc1 L100P mice.

Valproate

Disc1

MIA

influenza

Disc1 L100P

Valproic Acid

VPA

Schizophrenia

maternal immune activation

neurodevelopment

prenatal

mouse

pregnancy

vaccine

behaviour

IL-6

postnatal

pyramidal neuron

cortex

morphology

0419

0317

Serotonin 5-HT Receptor Currents in the Healthy Rodent Prefrontal Cortex and in a Model of Affective Disorders

Goodfellow, Nathalie M.

07 August 2013

Affective disorders represent one of the greatest global burdens of disease. Work in patients with affective disorders demonstrates that serotonin (5-HT) signaling within the prefrontal cortex, particularly at the level of the 5-HT receptors, plays an integral role in both the pathology and treatment of these diseases. Surprisingly, the characterization of the prefrontal 5-HT receptors under both healthy and pathological conditions remains incomplete. The technique of whole cell electrophysiological recording provides an unparalleled tool for investigating the functional effects of these 5-HT receptors on neurons in acute prefrontal cortical slices. The objectives of my thesis were to delve deeper into the 5-HT receptor subtypes that modulate the prefrontal cortex in the healthy control rodents and to examine how this modulation was disrupted in a rodent model of affective disorders. In work from healthy control rodents, I examined two prefrontal 5-HT receptor-mediated currents. I show for the first time the presence of the 5-HT1A receptor during the early postnatal period, a critical developmental window during which this receptor programs adult anxiety behaviors. In adulthood, I characterized an inhibitory current mediated by the 5-ht5A receptor; findings that will permit the classification of this receptor within the 5-HT receptor family. Collectively, this investigation of functional early 5-HT1A receptors and adult 5-ht5A receptors offers a novel conceptual framework for understanding 5-HT receptor modulation of the healthy prefrontal cortex. To model vulnerability to affective disorder in the rodent, I used the early stress of maternal separation. In early stress rodents, I observed a marked increase in 5-HT1A receptor currents during the early postnatal period, the critical time window for the programming of anxiety. By comparison, in adulthood I found that rodents exposed to early stress displayed increased 5-HT2A receptor currents. These findings provide novel insight into the developmental and long-lasting pathology underlying early stress, indicating that the early prefrontal 5-HT1A receptor and adult prefrontal 5-HT2A receptors as a potential therapeutic target in treatment of affective disorders At a fundamental level, the findings provided herein offer critical insight into the cellular mechanisms underlying affective disorders, one of the most debilitating and costly diseases worldwide.

Serotonin

Electrophysiology

Prefrontal cortex

5-HT

Anxiety

Depression

Maternal Separation

Stress

pyramidal neuron

acute slice

psychiatric disorders

development

early life stress

whole-cell

0433

0317

0719

0349

0419

Mechanisms of spikelet generation in cortical pyramidal neurons

Michalikova, Martina

05 April 2017

Unter Spikelets versteht man kleine Depolarisationen mit einer Spike-ähnlichen Wellenform, die man in intrazellulären Ableitungen von verschiedenen Neuronentypen messen kann. In kortikalen Pyramidenzellen wurde ausgeprägte Spikelet-Aktivität nachgewiesen, die erheblich das Membranpotential beeinflussen kann (Crochet et al., 2004; Epsztein et al., 2010; Chorev and Brecht, 2012). Nichtsdestotrotz bleibt der Ursprung von Spikelets in diesen Neuronen unbekannt. In der vorgelegten Arbeit nutzte ich theoretische Modellierung um die Mechanismen von Spikelet-Erzeugung in Pyramidenzellen zu untersuchen. Zuerst sah ich die verschiedenen Hypothesen über den Ursprung von Spikelets durch. In der Literatur entdeckte ich zwei verschiedene Typen von Spikelets. Diese Arbeit konzentriert sich auf den häufiger vorkommenden Typ von Spikelets, welcher durch relativ große Amplituden gekennzeichnet ist. Die Eigenschaften dieser Spikelets passen am besten zu einem axonal Erzeugungsmechanismus. Im zweiten Kapitel widmete ich mich der Hypothese, dass somatische Spikelets axonalen Ursprungs mit somato-dendritischen Inputs hervorgerufen werden können. Ich identifizierte Bedingungen, die es erlauben ein Aktionspotential (AP) am Initialsegment vom Axon (AIS) zu initiieren, welches sich entlang des Axons ausbreitet, aber kein AP im Soma auslöst. Schließlich simulierte ich extrazelluläre Wellenformen von APs und Spikelets und verglich sie mit experimentellen Daten (Chorev and Brecht, 2012). Dieser Vergleich zeigte auf, dass die extrazellulären Wellenformen von Spikelets, die innerhalb einer Zellen am AIS erzeugt werden, gut zu den Daten passen. Zusammenfassend unterstützen meine Ergebnisse die Hypothese, dass Spikelets in Pyramidenzellen am AIS entstehen. Dieser Mechanismus könnte ein Mittel zum Energiesparen bei der Erzeugung von Output-APs sein. Außerdem könnte dadurch die dendritische Plastizität, die auf der Rückwärtspropagierung von APs beruht, reguliert werden. / Spikelets are transient spike-like depolarizations of small amplitudes that can be measured in somatic intracellular recordings of many neuron types. Pronounced spikelet activity has been demonstrated in cortical pyramidal neurons in vivo (Crochet et al., 2004; Epsztein et al., 2010; Chorev and Brecht, 2012), influencing membrane voltage dynamics including action potential initiation. Nevertheless, the origin of spikelets in these neurons remains elusive. In thi thesis, I used computational modeling to examine the mechanisms of spikelet generation in pyramidal neurons. First, I reviewed the hypotheses previously suggested to explain spikelet origin. I discovered two qualitatively different spikelet types described in the experimental literature. This thesis focuses on the more commonly reported spikelet type, characterized by relatively large amplitudes of up to 20 mV. I found that the properties of these spikelets fit best to an axonal generation mechanism. Second, I explored the hypothesis that somatic spikelets of axonal origin can be evoked with somato-dendritic inputs. I identified the conditions allowing these orthodromic inputs to trigger an action potential at the axon initial segment, which propagates along the axon to the postsynaptic targets, but fails to elicit an action potential in the soma and the dendrites. Third, I simulated extracellular waveforms of action potentials and spikelets and compared them to experimental data (Chorev and Brecht, 2012). This comparison demonstrated that the extracellular waveforms of single-cell spikelets of axonal origin are consistent with the data. Together, my results suggest that spikelets in pyramidal neurons might originate at the axon initial segment within a single cell. Such a mechanism might be a way of reducing the energetic costs associated with the generation of output action potentials. Moreover, it might allow to control the dendritic plasticity by backpropagating action potentials.

Aktionspotential-Initiierung

Pyramidenneuron

theoretisches Modell

Initialsegment des Axons

action potential initiation

pyramidal neuron

computational model

axon initial segment

570 Biologie

32 Biologie

WW 2400

ddc:570

Perirhinal feedback input controls neocortical memory formation via layer 1

Shin, Jiyun

29 January 2021

Das deklarative Gedächtnis beruht auf Wechselwirkungen zwischen dem medialen Temporallappens (MTL) und Neokortex. Aufgrund der verteilten Natur neokortikaler Netzwerke bleiben zelluläre Ziele und Mechanismen der Gedächtnisbildung im Neokortex jedoch schwer fassbar. Im sechsschichtigen Säugetier-Neokortex konvergieren die Top-Down-Inputs auf Schicht 1 (L1). Wir untersuchten, wie Top-Down-Inputs von MTL die neokortikale Aktivität während der Gedächtnisbildung modulieren. Wir haben zunächst ein Kortex- und Hippocampus-abhängiges Lernparadigma angepasst, in dem Tiere gelernt haben, direkte kortikale Mikrostimulation und Belohnung zu assoziieren. Neuronen in den tiefen Schichten des perirhinalen Kortex lieferten monosynaptische Eingaben in L1 des primären somatosensorischen Kortex (S1), wo die Mikrostimulation vorgestellt wurde. Die chemogenetische Unterdrückung der perirhinalen Inputs in L1 von S1 störte die Gedächtnisbildung, hatte jedoch keinen Einfluss auf die Leistung der Tiere nach abgeschlossenem Lernen. Dem Lernen folgte das Auftreten einer klaren Subpopulation von Pyramidenneuronen der Schicht 5 (L5), die durch hochfrequentes Burst-Feuern gekennzeichnet war und durch Blockieren der perirhinalen Inputs zu L1 reduziert werden konnte. Interessanterweise zeigte ein ähnlicher Anteil an apikalen Dendriten von L5-Pyramidenneuronen ebenfalls eine signifikant erhöhte Ca2+-Aktivität während des Gedächtnisabrufs bei Expertentieren. Wichtig ist, dass die Störung der dendritischen Ca2+-Aktivität das Lernen beeinträchtigte, was darauf hindeutet, dass apikale Dendriten von L5-Pyramidenneuronen eine entscheidende Rolle bei der Bildung des neokortikalen Gedächtnisses spielen. Wir schließen daraus, dass MTL-Eingaben das Lernen über einen perirhinalen vermittelten Gating-Prozess in L1 steuern, der sich in einer erhöhten dendritischen Ca2+-Aktivität und einem Burst-Firing in pyramidalen L5-Neuronen manifestiert. / Declarative memory relies on interactions between the medial temporal lobe (MTL) and neocortex. However, due the distributed nature of neocortical networks, cellular targets and mechanisms of memory formation in the neocortex remain elusive. In the six-layered mammalian neocortex, top-down inputs converge on its outermost layer, layer 1 (L1). We examined how layer-specific top-down inputs from MTL modulate neocortical activity during memory formation. We first adapted a cortical- and hippocampal-dependent learning paradigm, in which animals learned to associate direct cortical microstimulation and reward, and characterized the learning behavior of rats and mice. We next showed that neurons in the deep layers of the perirhinal cortex not only provide monosynaptic inputs to L1 of the primary somatosensory cortex (S1), where microstimulation was presented, but also actively reflect the behavioral outcome. Chemogenetic suppression of perirhinal inputs to L1 of S1 disrupted early memory formation but did not affect animals’ performance after learning. The learning was followed by an emergence of a distinct subpopulation of layer 5 (L5) pyramidal neurons characterized by high-frequency burst firing, which could be reduced by blocking perirhinal inputs to L1. Interestingly, a similar proportion of apical dendrites (~10%) of L5 pyramidal neurons also displayed significantly enhanced calcium (Ca2+) activity during memory retrieval in expert animals. Importantly, disrupting dendritic Ca2+ activity impaired learning, suggesting that apical dendrites of L5 pyramidal neurons have a critical role in neocortical memory formation. Taken together, these results suggest that MTL inputs control learning via a perirhinal-mediated gating process in L1, manifested by elevated dendritic Ca2+ activity and burst firing in L5 pyramidal neurons. The present study provides insights into cellular mechanisms of learning and memory representations in the neocortex.

Lernen und Gedächtnis

Neokortex

perirhinaler Kortex

Hippocampus

Chemogenetik

Pyramidenneuron

aktive Dendriten

learning and memory

neocortex

perirhinal cortex

hippocampus

chemogenetics

Layer 1

Layer 5 pyramidal neuron

active dendrites

570 Biologie

571 Physiologie und verwandte Themen

WW 4200

ddc:570

ddc:571

Nanoscopy inside living brain slices

Urban, Nicolai Thomas

01 November 2012

No description available.

571.4

STED

RESOLFT

nanoscopy

super-resolution

microscopy

aberration correction

spherical aberrations

deep tissue imaging

penetration depth

RSFP

time-lapse

dendritic spines

dendrites

actin

cytoskeleton

LTP

long-term potentiation

synaptic plasticity

morphological changes

postsynaptic activity

motility

hippocampus

CA1

pyramidal neuron

living brain

organotypic brain slice

Biologie (PPN619462639)