Compensatory Cortical Sprouting Across the Lifespan of the Rat

Carnes, Benjamin J., Carnes

10 May 2016

No description available.

Biomedical Research

Biology

Neurobiology

Neurosciences

Sprouting

cholinergic

neurons

aging

AD

Entorhinal cortex

Effects of Acute Ethanol on Memory Encoding, Retrieval, and the Theta Rhythm

Edwards, Kristin S.

31 March 2011

No description available.

Neurobiology

Psychology

ethanol

encoding

retrieval

theta rhythm

anterior cingulate

dentate gyrus

entorhinal cortex

Time-Frequency Analysis of Electroencephalographic Activity in the Entorhinal cortex and hippocampus

Xu, Yan

10 1900

Oscillatory states in the Electroencephalogram (EEG) reflect the rhythmic synchronous activation in large networks of neurons. Time-frequency methods quantify the spectral content of the EEG as a function of time. As such, they are well suited as tools for the study of spontaneous and induced changes in oscillatory states. We have used time-frequency techniques to analyze the flow of activity patterns between two strongly connected brain structures: the entorhinal cortex and the hippocampus, which are believed to be involved in information storage. EEG was recorded simultaneously from the entorhinal cortex and the hippocampus of behaving rats. During the recording, low-intensity trains of electrical pulses at frequencies between 1 and 40 Hz were applied to the olfactory (piriform) cortex. The piriform cortex projects to the entorhinal cortex, which then passes the signal on to the hippocampus. Several time-frequency methods, including the short-time Fourier transform (STFT), Wigner-Ville distribution (WVD) and multiple window (MW) time-frequency analysis (TFA), were used to analyse EEG signals. To monitor the signal transmission between the entorhinal cortex and hippocampus, the time-frequency coherence functions were used. The analysed results showed that stimulation-related power in both sites peaked near 15 Hz, but the coherence between the EEG signals recorded from these two sites increased monotonically with stimulation frequency. Among the time-frequency methods used, the STFT provided time-frequency distributions not only without cross-terms which were present in the WVD, but also with higher resolutions in both time and frequency than the MW-TFA. The STFT seems to be the most suitable time-frequency method to study the stimulation-induced signals presented in this thesis. The MW-TFA, which gives low bias and low variance estimations of the time-frequency distribution when only one realization of data is given, is suitable for stochastic and nonstationary signals such as spontaneous EEG. We also compared the performance of the MW-TFA using two different window functions: Slepian sequences and Hermite functions. By carefully matching the two window functions, we found no noticeable difference in time-frequency plane between them. / Thesis / Master of Engineering (ME)

Mesure des changements de matière grise et de la connectivité cérébrale suite à un entrainement à des jeux vidéo

Diarra, Moussa

12 1900

No description available.

Jeu video

Hippocampe

Striatum

Amygdale

Noyau caudé

Stratégie de navigation

Vieillissement

Plasticité

Cortex entorhinal

Video game

Hippocampus

Striatum

Amygdala

Caudate nucleus

Navigation strategy

4/8

Entorhinal cortex

Aging

Plasticity

Bases neuronales de l’apprentissage associatif multisensoriel : implication différentielle du cortex entorhinal et de l’hippocampe chez le rat / Neuronal basis of multisensory associative learning : differential involvement of the entorhinal cortex and the hippocampus in the rat

Boisselier, Lise

02 December 2016

L'objectif de cette thèse est d'étudier l'implication de deux structures de la formation hippocampique, le cortex entorhinal latéral (CEL) et l'hippocampe dorsal (DH), dans les processus sous-tendant la formation et la flexibilité d'associations entre deux stimuli de modalités sensorielles différentes : l'olfaction et le toucher. Pour cela, une tâche bimodale olfacto-tactile (OT) est développée chez le rat. Dans celle-ci, l'animal doit apprendre à identifier une combinaison "odeur-texture" spécifique parmi les trois proposées afin d'obtenir un renforcement (ex: O1T1+ O2T1 O1T2, + désignant la combinaison renforcée). Aucun indice spatial ou contextuel n'est pertinent pour résoudre cette tâche. Suite à l'acquisition de deux tâches différentes, les stimuli sont réassociés sous forme de combinaisons inédites dans une troisième tâche appelée « recombinaison ». La manipulation pharmacologique de l'activité du CEL a mis en évidence l'implication des systèmes glutamatergique NMDA et cholinergique de cette structure dans les processus sous-tendant ces deux types de tâche. En revanche, si le DH n'est pas indispensable pour l'acquisition, son système cholinergique est critique pour la recombinaison. En comparaison avec l'acquisition, l'étude électrophysiologique a montré que la recombinaison repose sur un découplage de la synchronisation entre les activités oscillatoires du CEL et celles du DH dans la bande thêta (5-12 Hz). De plus, cet apprentissage est associé à une augmentation de l'amplitude des oscillations bêta (15-45 Hz) dans le CEL. Ces travaux montrent que le CEL et le DH interviennent dans les processus sous-tendant la flexibilité des représentations bimodales / The goal of this thesis is to study the involvement of two structures of the hippocampal formation, the lateral entorhinal cortex (LEC) and the dorsal hippocampus (DH), in the processes underlying the formation and the flexibility of associations of stimuli between two different sensory modalities. To this aim, a new olfactory-tactile (OT) bimodal task has been developed in the rat. To solve the task, animals have to identity one “odor-texture” combination between three in order to obtain a reinforcement (ex: O1T1+ O2T1 O1T2, + for the baited cup). This procedure excludes the use of any spatial or contextual cues for solving the task. After the acquisition of two different tasks, the familiar stimuli used in acquisition were recombined in a third task (called “recombination”). The pharmacological manipulation of the LEC showed that the NMDA glutamatergic and cholinergic system in this structure are involved in the processes underlying the acquisition and the recombination. In contrast, the cholinergic system in the DH is selectively and critically involved in the recombination processes. Compared to acquisition, our electrophysiological data showed that the recombination is based on a desynchronization between the oscillatory activities of the LEC and of the DH in the theta band (5-12 Hz). Moreover, this task is associated with increased amplitude of beta oscillations (15-45 Hz) in the LEC. These data demonstrated that the LEC and the DH are critically involved in the processes underlying the flexibility of bimodal representations

Mémoire cross-modale

Olfactif

Tactile

Cortex entorhinal latéral

Hippocampe dorsal

Neuropharmacologie

Dynamique neuronale

Rat

Cross-modal memory

Olfactory

Tactile

Lateral entorhinal cortex

Dorsal hippocampus

Neuropharmacology

Neuronal dynamic

Rat

612.8

Caractérisation de la substance grise cérébrale dans l’apnée obstructive du sommeil chez les personnes d’âge moyen et âgées

Martineau-Dussault, Marie-Ève

05 1900

L’apnée obstructive du sommeil (AOS) est l’un des troubles du sommeil les plus fréquents chez l’adulte et sa prévalence augmente avec l’âge. Elle se caractérise par des arrêts répétés de la respiration au cours du sommeil, menant à la présence de fragmentation du sommeil et à de l’hypoxémie intermittente. Lorsque non traité, ce trouble peut mener à diverses conséquences non négligeables sur la santé des individus qui en sont atteints, incluant sur la santé du cerveau. L’AOS est d’ailleurs de plus en plus reconnue comme étant un possible facteur de risque de déclin cognitif et de démence. Dans ce contexte, quelques études transversales ont caractérisé le volume de la substance grise cérébrale chez des adultes vieillissants atteints d’AOS, avec des résultats variables. En effet, certaines études ont noté de plus grands volumes de substance grise chez les personnes avec une AOS plus sévère, alors que d’autres ont retrouvé des plus petits volumes chez cette même population. Ce qui explique la variabilité entre les études demeure à ce jour mal compris, bien que certaines hypothèses aient émergé. Ainsi, cette thèse vise à évaluer l’association entre la sévérité de l’AOS et le volume de substance grise cérébrale chez des personnes d’âge moyen et âgées de manière transversale et longitudinale. La première étude de cette thèse se base sur des techniques de neuroimagerie afin d’évaluer les liens entre la sévérité de l’AOS et le volume de la substance grise cérébrale des sous-régions du lobe temporal médian, soit l’hippocampe, le cortex entorhinal et le cortex parahippocampique. Celles-ci ont été ciblées puisqu’elles peuvent être affectées tôt dans la progression de la pathologie de la maladie d’Alzheimer (MA). De plus, nous avons testé l’effet d’une correction de la portion d’eau libre sur les volumes cérébraux. Finalement, nous avions comme objectif de mieux comprendre si certaines caractéristiques démographiques ou cliniques de nos participants pouvaient avoir un impact sur les associations observées. Nous avons observé qu’une AOS plus sévère était associée à des volumes de substance grise plus grands de certaines sous-régions du lobe temporal médian (hippocampe et cortex entorhinal), mais seulement chez des groupes de participants spécifiques, soit les femmes, les participants plus âgés et ceux présentant un trouble cognitif léger de type amnésique. Le fait d’apporter une correction pour la portion d’eau libre aux volumes mesurés a rendu non significatives les associations observées. Il est donc possible que la présence accrue d’eau extracellulaire, suggérant de l’œdème cérébral, puisse expliquer la présence de plus grands volumes chez les participants présentant une AOS plus sévère. La deuxième étude visait quant à elle à évaluer les changements structurels des sous-régions du lobe temporal médian associés à la sévérité de l’AOS chez des personnes d’âge moyen et âgées sur une période d’environ 2 ans. Nous avons démontré que chez nos participants n’ayant pas utilisé un traitement pour l’AOS, la présence d’interaction entre la sévérité de l’AOS et l’âge permettait d’expliquer les changements annuels de volume de substance grise. De fait, les participants plus jeunes de notre échantillon (< 65 ans) avec une AOS plus sévère présentaient un plus grand taux de changement annuel de volume de substance grise, soulignant la présence d’hypertrophie dans ce sous-groupe. Ceci a été mis en lumière pour l’ensemble des sous-régions du lobe temporal médian. Chez les participants âgés entre 65 et 75 ans, aucune association entre la sévérité de l’AOS et les changements de volume au fil du temps n’a pu être soulignée. Les participants plus âgés (> 75 ans) avec une plus grande sévérité d’AOS présentaient quant à eux une plus grande atrophie au fil du temps dans certaines régions, soit l’hippocampe et le cortex entorhinal. Ces résultats supportent donc une hypothèse biphasique des changements au niveau de la substance grise cérébrale chez les gens présentant de l’AOS, avec une première phase caractérisée par des augmentations de volume chez les adultes plus jeunes, menant éventuellement à de l’atrophie chez les personnes plus âgées. Cette thèse permet d’avoir un portrait plus clair sur la nature des changements et des mécanismes impliqués dans l’association entre la sévérité de l’AOS et les volumes de substance grise. L’un des apports importants est l’utilisation d’une nouvelle méthodologie afin d’obtenir une portion d’eau libre, ce qui a permis de mieux comprendre l’apport potentiel de mécanismes pouvant sous-tendre les changements structuraux observés, notamment l’œdème cérébral. De plus, l’évaluation des caractéristiques individuelles des participants a permis d’expliquer partiellement les incongruences entre les études précédentes. Dans le cadre des études incluses dans cette thèse, nous avons observé des changements plus marqués chez les femmes. Nous avons également pu démontrer que l’âge des individus atteints d’AOS pouvait influencer significativement le patron de changements observés. Les résultats de cette thèse pourraient donc permettre de mieux cibler les personnes avec AOS qui pourraient le plus bénéficier d’un traitement pour maintenir leur santé cérébrale. / Obstructive sleep apnea (OSA) is one of the most common sleep disorders in adults, and its prevalence increases with age. It is characterized by repeated pauses in breathing during sleep, leading to sleep fragmentation and intermittent hypoxemia. If left untreated, this disorder can have numerous consequences, including on the brain’s health. OSA is increasingly recognized as a risk factor for cognitive decline and dementia. In this context, cross-sectional studies have characterized brain gray matter volume in aging adults with OSA, with variable results. Indeed, some studies have noted greater gray matter volumes in people with more severe OSA, while others have found smaller volumes in this same population. What explains the variability between studies remains poorly understood, although some hypotheses have emerged. Thus, this thesis aims to assess the association between OSA severity and cerebral gray matter volume in middle-aged and elderly individuals using cross-sectional and longitudinal designs. The first study in this thesis uses neuroimaging techniques to assess the links between OSA severity and cerebral gray matter volume of the medial temporal lobe subregions, i.e. the hippocampus, entorhinal cortex and parahippocampal cortex. These were chosen as they can be affected early in the progression of Alzheimer's disease (AD) pathology. We also corrected our brain volumes for free-water portion. Finally, we aimed to better understand whether certain demographic or clinical characteristics of our participants might have an impact on the associations observed. We noted that more severe OSA was associated with larger gray matter volumes in certain subregions of the medial temporal lobe (hippocampus and enthorinal cortex), but only in specific groups of participants: women, older participants and those with amnestic mild cognitive impairment. Correcting our volumes for free-water portion rendered the associations nonsignificant. It is therefore possible that the presence of extracellular water, suggestive of cerebral edema, could explain the presence of larger volumes in participants with more severe OSA. The second study aimed to assess longitudinal structural changes associated with OSA severity in middle-aged and elderly people over a period of around 2 years. We found that in participants who did not use treatment for OSA, the presence of interactions between OSA severity and age were associated with the annual changes in gray matter volume. Indeed, younger participants (< 65 years old) in our sample with more severe OSA showed a greater rate of annual change in gray matter volume, highlighting the presence of hypertrophy in this subgroup. This was underlined in all medial temporal lobe subregions. In participants aged between 65 and 75, no association between OSA severity and volume changes over time could be highlighted. Older participants (>75 years old) with greater OSA severity showed greater hippocampal and entorhinal cortex atrophy over time. These results therefore support a biphasic hypothesis of changes in cerebral gray matter in people with OSA, with an initial phase characterized by volume increases in younger adults, eventually leading to atrophy in older people. This thesis provides a clearer picture of the nature of the changes and mechanisms involved in the association between OSA severity and gray matter volumes. An important contribution is the use of a new methodology to obtain a free-water portion, which allows to better understand the potential contribution of mechanisms that may underlie the structural changes observed, notably cerebral edema. In addition, the assessment of participants' individual characteristics helped to partially explain incongruities between previous studies. Indeed, in the studies included in this thesis, we observed more marked changes in certain subgroups of participants, notably women. We were also able to demonstrate that the age of individuals with OSA could significantly influence the pattern of changes observed, either gray matter hypertrophy or atrophy. The results of this thesis could therefore make it possible to target specific subgroups of individuals suffering from OSA who may be at greater risk of displaying changes in gray matter structure, and thus promote screening and treatment when necessary.

Apnée obstructive du sommeil

Neuroimagerie

Trouble cognitif léger

Vieillissement

Hippocampe

Cortex entorhinal

Imagerie par résonance magnétique

Substance grise

Obstructive sleep apnea

Neuroimaging

Mild cognitive impairment

Grey matter

Magnetic resonance imaging.

Aging

Hippocampus

Entorhinal cortex

Psychology / Psychologie (UMI : 0621)

Interaktion zwischen entorhinalem Kortex und Hippokampus bei der Temporallappenepilepsie

Behr, Joachim

28 January 2003

1. Interaktion zwischen entorhinalem Kortex und Hippokampus Lernen und Gedächtnis sind auf das engste mit dem Hippokampus und dem entorhinalen Kortex (EC) verbunden. Allerdings sind diese Hirnstrukturen auch an einer der häufigsten und medikamentös oftmals nur schwer therapierbaren fokalen Epilepsien beteiligt: der mesialen Temporallappenepilepsie (TLE). Der EC scheint eine wesentliche Bedeutung in der Generierung extrahippokampaler Temporallappenanfälle zu besitzen. Unsere bisherigen Untersuchungen zur Interaktion zwischen dem EC und dem Hippokampus haben gezeigt, daß unter physiologischen Bedingungen die Area dentata eine Filterfunktion übernimmt und die Übertragung epileptiformer Aktivität vom EC zum Hippokampus unterbindet. Im chronisch epileptischen Tier (Kindling-Modell) kommt es allerdings zu einer Aufhebung dieser Filterfunktion und somit zu einer ungehinderten Ausbreitung epileptiformer Aktivität in den Hippokampus. Da der glutamaterge NMDA-Rezeptor eine zentrale Rolle in der Induktion nutzungsabhängiger Plastizität spielt, ist er von wesentlicher Bedeutung in der Epileptogenese. Untersuchungen an Körnerzellen der Area dentata zeigten wenige Stunden nach dem letzten epileptischen Anfall eine Zunahme der über NMDA-Rezeptoren vermittelten Ströme. Diese führte zu einer Faszilitierung hochfrequenter reizevozierter Potentiale. Dieser Befund zeigt, daß im epileptischen Gewebe hochfrequente Entladungen die Area dentata überwinden können und in den Hippokampus weitergeleitet werden. Vier Wochen nach dem letzten Anfallsereignis waren die beschriebenen Veränderungen allerdings nicht mehr nachweisbar. Diese kurzzeitig veränderte synaptische Transmission der NMDA-Rezeptorkanäle scheint demzufolge eher für die Epileptogenese als für die Ictogenese verantwortlich zu sein. Die Bedeutung der Kainat-Rezeptoren im chronisch epileptischen Gewebe ist aufgrund der bis vor wenigen Jahren fehlenden selektiven Agonisten und Antagonisten kaum untersucht worden. Wir haben gezeigt, daß in der Area dentata des chronisch epileptischen Tieres (Kindling-Modell) die Aktivierung von präsynaptischen Kainat-Rezeptoren inhibitorischer Interneurone sowohl die spontane als auch die reizevozierte GABA-Freisetzung reduziert. Über diesen Mechanismus scheint der während eines epileptischen Anfalls vermehrt freigesetzte exzitatorische Neurotransmitter Glutamat die GABAerge Inhibition zu vermindern und somit die Erregbarkeit der Area dentata zu steigern. 2. Die Rolle des Subikulums in der Temporallappenepilepsie Eine wesentliche Aufgabe des Subikulums ist es, hippokampale Informationen zu verarbeiten und in verschiedene kortikale und subkortikale Hirnregionen weiterzuleiten. Zudem scheint es von besonderer Bedeutung für die Generierung und Ausbreitung hippokampaler Anfälle zu sein. Gestützt wird diese Annahme durch folgende Befunde: Zunächst besitzt das Subikulum Netzwerkeigenschaften, die es ihm im in vitro Epilepsiemodell ermöglichen, spontane epileptiforme Aktivität zu generieren. Darüber hinaus verfügt es über einen hohen Anteil sogenannter burst-spiking Zellen. Deren intrinsische Eigenschaften tragen erheblich zu dem epileptogenen Verhalten des Subikulums bei. Weiterhin erhalten subikuläre Pyramidenzellen exzitatorische Eingänge sowohl aus der Area CA1 als auch aus dem EC, welche bereits bei Ruhemembranpotential aktivierbare NMDA-Rezeptorströme zeigen. Schließlich zeigen burst-spiking Zellen im Vergleich zu regular-spiking Zellen eine ausgeprägte über NMDA-Rezeptoren vermittelte synaptische Plastizität (Langzeit-Potenzierung; LTP). Untersuchungen am chronisch epileptischen Tier (Kindling-Modell) ergaben einen unverändert hohen Anteil an burst-spiking Zellen im Subikulum. Wenige Stunden nach dem letzten epileptischen Anfall fällt bei diesen Neuronen eine fehlende, durch Aktionspotentiale induzierte Nachhyperpolarisation auf. Diese supprimierte intrinsische Hemmung ist jedoch 28 Tage nach dem letzten epileptischen Anfall nicht mehr nachzuweisen und spielt demzufolge insbesondere in der Genese, weniger im chronischen Verlauf der Erkrankung eine Rolle. Neben den exzitatorischen und inhibitorischen Neurotransmittern Glutamat und GABA bestimmen auch körpereigene Amine wie Serotonin und Dopamin über subkortikale Afferenzen das funktionelle Gleichgewicht aus Erregung und Hemmung wesentlich mit. Da die TLE nicht selten mit neurologischen und psychiatrischen Erkrankungen einhergeht, die mit in das Dopamin- und Serotoninsystem eingreifenden Pharmaka therapiert werden, haben wir uns in einigen Arbeiten mit deren modulatorischen Wirkungen auf die Membraneigenschaften und die synaptische Transmission befaßt. Die Wirkungen von Dopamin auf die Neurotransmission sind vielfältig, abhängig von den beteiligten Rezeptoren in der entsprechenden Hirnregion. Das Subikulum, das eine ausgeprägte mesenzephale, dopaminerge Projektion vom ventralen Tegmentum erhält, expremiert sowohl D1- als auch D2-Rezeptoren. Wir konnten zeigen, daß Dopamin primär die glutamaterge synaptische Transmission über einen präsynaptisch lokalisierten D1-Dopaminrezeptor unterdrückt und sekundär über die verminderte Erregung inhibitorischer Interneurone die polysynaptische GABAerge Hemmung reduziert. / 1. Interaction between the entorhinal cortex and the hippocampus The hippocampus and the entorhinal cortex are crucially involved in the acquisition, consolidation and retrieval of long-term memory traces. However, both structures play a critical role in pharmacologically intractable temporal lobe epilepsy. The entorhinal cortex provides the main input to the hippocampus. We have shown that kindling facilitates the propagation of epileptiform activity through the dentate gyrus. Our data are consistent with the normal function of the dentate gyrus as a filter limiting the spread of epileptiform activity within the entorhinal-hippocampal complex. This gating mechanism breaks down after chronic epilepsy induced by kindling. In the mammalian brain, the NMDA subclass of glutamate receptors plays a central role in the induction of several forms of use-dependent plasticity. However, synaptic plasticity can potentially underlie pathological situations, notably in animal and human forms of epilepsy. The enhanced excitability of the kindled dentate gyrus several hours after the last seizure, as well as the breakdown of its gating function, appear to result from transiently enhanced NMDA receptor activation that provides significantly slower EPSC kinetics than those observed in control slices and in slices from kindled animals with a four weeks seizure-free interval. Therefore, NMDA receptors seem to play a critical role in the acute throughput of seizure activity and in the induction of the kindled state but not in the persistence of enhanced seizure susceptibility. The functional involvement of kainate receptors in epileptogenesis gets more and more elucidated. We found that in chronic epileptic rats (kindling-model), activation of presynaptic kainate receptors of inhibitory interneurons depresses spontaneous and stimulus-induced GABA release. The kindling-induced sensitivity of GABA release to kainate receptor activation may produce a use-dependent hyperexcitability in the epileptic dentate gyrus facilitating the spread of limbic seizures through the entorhinal-hippocampal complex in temporal lobe epilepsy. 2. The role of the subiculum in temporal lobe epilepsy The subiculum controls most of the entorhinal-hippocampal output. It receives strong excitatory input from area CA1 and the entorhinal cortex and relays information to a variety of distant cortical and subcortical structures. The subiculum seems to be crucially involved in the generation and propagation of hippocampal seizures. The seizure susceptibility of the subiculum relies (a) on a high fraction of burst-firing principle cells that a capable to undergo synaptic plasticity and (b) on an epilepsy-prone network to generate spontaneous seizures. In both, control and kindled preparations the subiculum contains an extensive sub-population of bursting cells expressing amplifying membrane characteristics. Subicular cells showed a transient depression of the fast and slow afterhyperpolarization in the course of kindling that may contribute to the induction but not permanence of the kindled state. Apart from the excitatory and inhibitory neurotransmission physiological amines like 5-HT and dopamine (DA) may offset the frail balance between excitation and inhibition in the hippocampus. As temporal lobe epilepsy is often associated with diseases that are treated with drugs affecting the 5-HT and DA system, we investigated the effect of these transmitters on intrinsic and synaptic properties of subicular principle cells. The subiculum receives a dense mesencepahalic dopaminergic projection from the ventral tegmental area and expresses high levels of D1- and D2-like DA receptors. Our results indicate that DA strongly suppresses glutamatergic hippocampal and entorhinal neurotransmission onto subicuar neurons by activation of presynaptic D1-like DA receptors. In addition, DA decreases polysynaptic inhibition by attenuating the glutamatergic drive onto subicular interneurons.

Hippokampus

entorhinaler Kortex

Temporallappenepilepsie

Subikulum

hippocampus

entorhinal cortex

temporal lobe epilepsy

subiculum

610 Medizin

33 Medizin

YH 6300

ddc:610

Functional architecture of the medial entorhinal cortex

Ray, Saikat

05 September 2016

Schicht 2 des mediale entorhinale Kortex (MEK) beinhaltet die größte Anzahl von Gitterzellen, welche durch ein hexagonales Aktivitätsmuster während räumlicher Exploration gekennzeichnet sind. In dieser Arbeit wurde gezeigt, dass spezielle Pyramidenzellen, die das Protein Calbindin exprimieren, in einem hexagonalen Gitter im Gehirn der Ratte angeordnet sind und cholinerg innerviert werden. Es ist bekannt, dass die cholinerge Innervation wichtig für die Aktivität von Gitterzellen ist. Weiterhin ergaben neuronale Ableitungen und Methoden zur Identifikaktion einzelner Neurone in frei verhaltenden Ratten, dass Calbindin-positive Pyramidenzellen (Calbindin+) eine große Anzahl von Gitterzellen beinhalten. Reelin-positive Sternzellen (Reelin+) im MEK, zeigten keine anatomische Periodizität und ihre Aktivität orientierte sich an den Begrenzungen der Umgebung. Eine weitere Studie untersucht die Architektur des MEK in verschiedenen Säugetieren, die von der Etrusker Spitzmaus, bis hin zum Menschen ~100 Millionen Jahre evolutionäre Vielfalt und ~20,000 fache Variation der Gehirngröße umfassen. Alle Arten zeigten jeweils eine periodische Anhäufung der Calbindin+ Zellen, was deren evolutive Bedeutung unterstreicht. Eine Studie zur Ontogenese der Calbindin Anhäufungen ergab, dass die periodische Struktur der Calbindin+ Zellen, sowie die verstreute Anordnung der Reelin+ Sternzellen schon zum Zeitpunkt der Geburt erkennbar war. Weitere Ergebnisse zeigen, dass Calbindin+ Zellen strukturell später ausreifen als Reelin+ Sternzellen - passend zu der Erkenntnis, dass Gitterzellen funktionell später reifen als Grenzzellen. Eine Untersuchung des Parasubiculums ergab, dass Verbindungen zum MEK präferiert in die Calbindin Anhäufungen in Schicht 2 projizieren. Zusammenfassend beschreibt diese Doktorarbeit eine Dichotomie von Struktur und Funktion in Schicht 2 des MEK, welche fundamental für das Verständnis von Gedächtnisbildung und deren zugrundeliegenden Mikroschaltkreisen ist. / The medial entorhinal cortex (MEC) is an important hub in the memory circuit in the brain. This thesis comprises of a group of studies which explores the architecture and microcircuits of the MEC. Layer 2 of MEC is home to grid cells, neurons which exhibit a hexagonal firing pattern during exploration of an open environment. The first study found that a group of pyramidal cells in layer 2 of the MEC, expressing the protein calbindin, were clustered in the rat brain. These patches were physically arranged in a hexagonal grid in the MEC and received preferential cholinergic-inputs which are known to be important for grid-cell activity. A combination of identified single-cell and extracellular recordings in freely behaving rats revealed that grid cells were mostly calbindin-positive pyramidal cells. Reelin-positive stellate cells in MEC were scattered throughout layer 2 and contributed mainly to the border cell population– neurons which fire at the borders of an environment. The next study explored the architecture of the MEC across evolution. Five mammalian species, spanning ~100 million years of evolutionary diversity and ~20,000 fold variation in brain size exhibited a conserved periodic layout of calbindin-patches in the MEC, underscoring their importance. An investigation of the ontogeny of the MEC in rats revealed that the periodic structure of the calbindin-patches and scattered layout of reelin-positive stellate cells was present around birth. Further, calbindin-positive pyramidal cells matured later in comparison to reelin-positive stellate cells mirroring the difference in functional maturation profiles of grid and border cells respectively. Inputs from the parasubiculum, selectively targeted calbindin-patches in the MEC indicating its role in shaping grid-cell function. In summary, the thesis uncovered a structure-function dichotomy of neurons in layer 2 of the MEC which is a fundamental aspect of understanding the microcircuits involved in memory formation.

Evolution

Mediale Entorhinale Kortex

Gitterzellen

Ontogenese

Medial Entorhinal Cortex

Grid cells

Evolution

Ontogeny

570 Biowissenschaften, Biologie

32 Biologie

ddc:570

Connecting the Dots: Investigating the Effects of Trans-Synaptic Tau Transmission in the Hippocampus

Bamisile, Michael

01 January 2019

Tauopathy, which results from the oligomerization of misfolded tau protein in neurons, is a feature present in a number of neurodegenerative diseases and a hallmark of Alzheimer’s Disease (AD). Tau is an important phosphoprotein that regulates the assembly of microtubules, but tauopathy can occur when tau becomes hyperphosphorylated. Phosphorylation prevents tau from binding to tubulin, which results in cytosolic accumulation of tau and eventual oligomerization. This abnormal accumulation of tau leads to the spreading of hyperphosphorylated tau to downstream synaptically connected neurons through an unknown mechanism. In AD, the hippocampus is one of the first brain structures to be affected by tauopathy in humans. According to previous research, tauopathy occurs primarily between principal cells in the hippocampus. The involvement of local inhibitory interneurons in tauopathy and their potential role in AD is more controversial. Previous research suggests that tau pathogenesis primarily affects principal cells; however, given the importance, diversity, and function of interneurons in the hippocampus, it is important to gain a better understanding of the interneuron subtypes that may be impacted by the spread of trans-synaptic tau into the hippocampus. Understanding the involvement of interneurons in trans-synaptic tau transmission is important to understanding neurodegeneration in AD and other neurodegenerative disorders. To investigate this, both male and female genetically-modified mice underwent surgery to examine the trans-synaptic spread of pathogenic tau (EGFP-Tau P301L) from the entorhinal cortex to hippocampal neurons. Histology and imaging analysis of brain sections were performed to examine the hippocampal cells impacted by trans-synaptic spread of tau. Results show that pathogenic tau can trans-synaptically spread from presynaptic neurons in the entorhinal cortex into downstream hippocampal interneurons and also that hippocampal interneurons are capable of trans-synaptically spreading tau. Future studies examining the specific subtypes of hippocampal interneurons vulnerable to trans-synaptic spread of tau will be important for a better understanding of disease progression, which could lead to uncovering new therapeutic targets for neurodegenerative diseases, like AD, which are associated with tauopathy.

Alzheimer's Disease

neurodegeneration

trans-synaptic tau transmission

tau

hippocampus

entorhinal cortex

inhibitory interneurons

principal cells

VGAT

calretinin

Medicine and Health Sciences

Early neurone loss in Alzheimer’s disease

Arendt, Thomas, Brückner, Martina K., Morawski, Markus, Jäger, Carsten, Gertz, Hermann-Josef

10 February 2015

Alzheimer’s disease (AD) is a degenerative disorder where the distribution of pathology throughout the brain is not random but follows a predictive pattern used for pathological staging. While the involvement of defined functional systems is fairly well established for more advanced stages, the initial sites of degeneration are still ill defined. The prevailing concept suggests an origin within the transentorhinal and entorhinal cortex (EC) from where pathology spreads to other areas. Still, this concept has been challenged recently suggesting a potential origin of degeneration in nonthalamic subcortical nuclei giving rise to cortical innervation such as locus coeruleus (LC) and nucleus basalis of Meynert (NbM). To contribute to the identification of the early site of degeneration, here, we address the question whether cortical or subcortical degeneration occurs more early and develops more quickly during progression of AD. To this end, we stereologically assesses neurone counts in the NbM, LC and EC layer-II in the same AD patients ranging from preclinical stages to severe dementia. In all three areas, neurone loss becomes detectable already at preclinical stages and is clearly manifest at prodromal AD/MCI. At more advanced AD, cell loss is most pronounced in the NbM > LC > layer-II EC. During early AD, however, the extent of cell loss is fairly balanced between all three areas without clear indications for a preference of one area. We can thus not rule out that there is more than one way of spreading from its site of origin or that degeneration even occurs independently at several sites in parallel.

Nucleus basalis

Locus caeruleus

Area entorhinalis

Neurodegenerative Erkrankung

Nucleus basalis of Meynert

Locus coeruleus

Entorhinal cortex

Neurodegeneration

ddc:610