A Neuroimaging Investigation of the Effects of Age and Sleep on Pattern Separation

Doxey, Christopher Robert

01 March 2016

Effective memory representations must be specific to prevent interference between episodes that may overlap in terms of place, time, or items present. Pattern separation, a computational process performed by the hippocampus overcomes this interference by establishing non-overlapping memory representations. This project explores pattern separation and how it is impacted by age and sleep. Experiment 1. Structures of the medial temporal lobe (MTL) are known to be involved in declarative memory processes. However, little is known about how age-related changes in MTL structures, white matter integrity, and functional connectivity affect pattern separation processes in the MTL. In the present study, we used magnetic resonance imaging (MRI) to measure the volumes of MTL regions of interest, including hippocampal subfields (dentate gyrus, CA3, CA1, and subiculum) in healthy older and younger adults. Additionally, we used diffusion tensor imaging to measure white matter integrity for both groups. Finally, we used functional MRI to acquire resting functional connectivity measures for both groups. We show that, along with age, the volume of left CA3/dentate gyrus predicts memory performance. Differences in fractional anisotropy and the strength of resting functional connections between the hippocampus and other cortical structures implicated in memory processing were not significant predictors of performance. As previous studies have only hinted, it seems that the size of left CA3/dentate gyrus contributes more to successful discrimination between similar mnemonic representations than other hippocampal sub-fields, MTL structures, and other neuroimaging correlates. Accordingly, the implications of aging and atrophy on lure discrimination capacities are discussed. Experiment 2. Although it is widely accepted that declarative memories are consolidated during sleep, the effects of sleep on pattern separation have yet to be elucidated. We used whole-brain, high-resolution functional neuroimaging to investigate the effects of sleep on a task that places high demands on pattern separation. Sleep had a selective effect on memory specificity and not general recognition memory. Activity in brain regions related to attention, visual acuity, and visual recall demonstrated an interaction between sleep and delay. Surprisingly, there was no effect of sleep on hippocampal activity using a group-level analysis. To further understand the role of the hippocampus on our task, we performed a representational similarity analysis. We investigated whether hippocampal activity associated with looking at novel stimuli correlated more with similar-looking (lure) stimuli or repeated stimuli. Results indicate that while a single night's sleep does not significantly impact hippocampal responses, the hippocampus does treat lure stimuli similarly as it does novel stimuli.

pattern separation

sleep

hippocampus

fMRI

DTI

Physiology

Beneficial contribution of health behaviors to learning and related brain mechanisms in older adults

Cole, Rachel Amelia Clark

01 May 2018

Aging is associated with adverse structural and functional changes in the brain. These changes have been directly linked to declines in certain types of learning and memory, likely due to the negative impact of aging on the hippocampus, a region necessary for cognitive functions such as relational learning, memory, and spatial navigation. Health behaviors and characteristics, like exercise and cardiorespiratory fitness (CRF), are related to better brain and cognitive aging, though more research is needed to better understand which age-sensitive aspects of cognitive function are most benefited by these health characteristics. The purpose of this collection of studies was to examine how exercise and fitness affect older adults’ learning and memory abilities, specifically using tasks that are designed to tax hippocampal binding processes. Further, I aimed to determine whether the volume of the hippocampus plays a key mediating role in this relationship. I answer these questions with three specific aims, each testing part of a model that represents complex interactions between physical activity, fitness, learning, and the potential mediator of hippocampal volume. The first aim examines these relationships using a cross-sectional design of 45 cognitively healthy older adults. The second aim evaluates the effects of a 12-week moderate intensity exercise program on 37 previously low-active older adults’ fitness, hippocampal volume, and relational learning rate. In this aim I first examine the amount of change in multiple variables following the intervention in order to infer causal relations, and then I examine the relationships of change across the different outcome measures. Finally, the third aim evaluates in 40 healthy older adults the role of hippocampal structure in the relationships between fitness and both spatial learning and memory in a virtual navigation task that has been found to be sensitive to age and disease-related changes in the hippocampus. In the first aim I found that higher cardiorespiratory fitness (CRF) was associated with larger hippocampal volume and faster relational learning rate. Larger hippocampal volume was also associated with faster learning rate. This pattern of results supports my hypotheses and provides a novel finding about how CRF relates specifically to older adults’ relational learning, which is thought to place demands on hippocampal binding. In the second aim I found that 12-weeks of regular light and moderate exercise increased CRF and early learning of relational associations. These changes were not larger for moderate intensity stationary cycling compared to light intensity stationary cycling. I also unexpectedly found that hippocampal volume decreased for both exercise groups, which suggests that this exercise intervention did not mitigate potential age-related decline in hippocampal volume. Finally, in the third aim I found that CRF was not related to learning object locations on spatial navigation, but higher CRF was related to fewer memory errors on the delayed recall of object locations in the virtual environment. Additionally, hippocampal volume was positively associated with the number of object locations learned after the first five minutes of free exploration in the virtual environment. Overall I found that higher CRF is related to faster relational learning and better memory of spatial object locations, both of which are expected to tax hippocampal binding processes. As even healthy older adults tend to experience structural and functional decline in the brain, CRF may be an effective health characteristic to target to increase the active life expectancy of our aging population.

Aging

Cardiorespiratory Fitness

Exercise

Hippocampus

Learning

Memory

Mechanisms through which nuclear estrogen receptors remain transcriptionally active in the mouse hippocampus in absence of ovarian estrogens.

January 2017

acase@tulane.edu / The goal of the following experiments was to determine the cellular mechanisms through which estrogen receptor activity is maintained in hippocampal cells following termination of ovarian function. Aim 1 determined that kinase signaling contributes to the maintenance of estrogen receptor activity in the hippocampus of ovariectomized mice in addition to local synthesis of brain derived “neuroestrogens”. Inhibition of both the mitogen activated protein kinase (MAPK) and phosphoinositide-3 kinase (PI3K) cascades with intracerebroventricular infusion of specific kinase inhibitors reduced estrogen response element (ERE)-dependent gene expression in the hippocampus of ovariectomized mice. Aim 2 determined that neuroestrogen synthesis, MAPK signaling, and PI3K signaling interact to regulate the transcriptional output of estrogen receptors in response to insulin like growth factor-1 receptor (IGF-1R) activation in the Neuro-2A cell culture model. Rapid IGF-1R-dependent MAPK signaling promotes, while PI3K signaling inhibits, IGF-1R-dependent activation of endogenous estrogen receptors in Neuro-2A cells. Long-term IGF-1R stimulation reduces ERE-dependent gene expression in part through phosphorylation of estrogen receptor alpha (ERα). Rapid IGF-1R-dependent activation but not long-term repression of estrogen receptor activity in Neuro-2A cells requires neuroestrogen synthesis. Aim 3 determined that exposure to 40 days of continuous unopposed estradiol at the time of ovariectomy results in lasting enhancement of estrogen receptor activity in the hippocampus and lasting enhancement of hippocampus dependent memory in female mice beyond the period of short-term estradiol exposure. Together these three aims determine that neuroestrogen synthesis and kinase signaling interact to actively maintain estrogen receptor signaling in neuronal cells and these autonomous neuronal mechanisms of estrogen receptor activation have functional consequences on cognition long after cessation of ovarian function. / 1 / Kevin J Pollard

estrogen

hippocampus

insulin-like growth factor-1

Establishment and validation of hippocampal LTP for characterization of memory enhancing drugs as potential treatment of Alzheimer’s disease / Etablierung und Validierung hippocampalen LTPs zur Charakterisierung gedächtnissteigernde Substanzen zur potentiellen Behandlung der Alzheimer’schen Erkrankung

Kroker, Katja

January 2011

Die Alzheimer’sche Erkrankung ist eine neurodegenerative Erkrankung des Gehirns. Um geeignete Medikamente für die Behandlung der Alzheimer’schen Erkrankung zu finden, werden experimentelle Modellsysteme zur Erforschung von Substanzkandidaten verwendet. Ein solches experimentelles System ist die hippocampale Langzeitpotenzierung (LTP), welche ein anerkanntes in vitro Modell für die Erforschung der zugrundeliegenden zellulären Prozesse der Gedächtnisbildung ist. Die vorliegende Arbeit beschäftigt sich mit der Etablierung und Validierung von LTP in hippocampalen Hirnschnitten der Ratte um gedächtnissteigernde Substanzen zur potentiellen Behandlung der Alzheimer’schen Erkrankung zu charakterisieren. Dazu wurde zunächst ein Messsystem zur parallelen Charakterisierung mehrerer Schnitte aufgebaut, das Messungen bis zu sieben Stunden erlaubt (Kapitel 2). Dann wurden unterschiedliche Protokolle etabliert um Früh- und Spätphasen-LTP zu generieren. Dabei würde Frühphasen-LTP konzeptionell eher mit dem Kurzzeitgedächtnis einhergehen, während Spätphasen-LTP dem Langzeitgedächtnis gleichkommen würde (Kapitel 3). Da in Alzheimer-Patienten hauptsächlich ein Defizit cholinerger und glutamaterger Neurone vorliegt, wurden die validierten LTP Formen benutzt, um solche Substanzen zu analysieren, die potentiell cholinerge und/oder glutamaterge neuronale Funktion erhöhen. Die Effekte zweier ausschließlich cholinerge Funktion erhöhender Substanzen wurden analysiert: Der α4β2 nicotinische Acetylcholin-Rezeptor Agonist TC-1827 (Kapitel 4) und der Acetylcholinesterase-Inhibitor Donepezil (Kapitel 5). Beide Substanzen erhöhten Frühphasen-LTP, aber hatten keinen Effekt auf Spätphasen-LTP. Desweiteren wurden zwei Substanzen getestet, die ausschließlich mit glutamaterger Funktion interferieren: Der metabotrope Glutamatrezeptor 5 positiv allosterische Modulator ADX-47273 (Kapitel 3) und der Phosphodiesterase (PDE) 9A-Inhibitor BAY 73-6691 (Kapitel 5). ADX-47273 erhöhte Spätphasen-LTP, aber hatte keinen Effekt auf Frühphasen-LTP, wohingegen BAY 73-6691 eine erhöhende Wirkung auf beide LTP Formen aufwies und sogar Früh- in Spätphasen-LTP umwandelte. Die gleichen Effekte, wie bei dem PDE9A-Inhibitor, konnten auch mit dem partiellen α7 nicotinische Acetylcholin-Rezeptor Agonisten SSR180711 (Kapitel 4) demonstriert werden. SSR180711 wirkt sowohl auf cholinerge, als auch auf glutamaterge neuronale Funktion. Dann wurde die Fähigkeit der Substanzen überprüft, durch lösliche Aβ Oligomere verschlechtertes LTP zu verbessern (Kapitel 6). Lösliche Aβ Oligomere, auch als amyloid-β derived diffusible ligands (ADDLs) bezeichnet, werden zurzeit als eine mutmaßliche Ursache der Alzheimer’schen Erkrankung angesehen. In der vorliegenden Arbeit wurde gezeigt, dass ADDLs Früh- und Spätphasen-LTP in verschiedenem Ausmaß vermindern. Donepezil und TC-1827 konnten die durch ADDLs induzierten Defizite bei Frühphasen-LTP geringfügig wiederherstellen, aber sie hatten keinen Einfluss auf das durch ADDLs verschlechterte Spätphasen-LTP. Im Gegensatz dazu, konnten sowohl SSR180711 als auch BAY 73-6691 ein durch ADDLs verschlechtertes Früh- und Spätphasen-LTP komplett wiederherstellen. ADX-47273 hatte keinen positiven Effekt auf Frühphasen-LTP, welches durch ADDLs verschlechtert worden war, konnte aber ein durch ADDLs verschlechtertes Spätphasen-LTP teilweise wiederherstellen. Somit wurde der vorherige Befund der Arbeit bestätigt: Substanzen, welche die glutamaterge Funktion verbessern, scheinen nicht nur wirksamer im Bezug auf LTP-Erhöhung zu sein als Substanzen die ausschließlich cholinerge Funktion erhöhen, sondern sie sind auch in der Lage, durch lösliche Aβ Oligomere verursachte Defizite bei LTP zu verbessern. Aus einem präklinischen Blickwinkel und basierend auf den Ergebnissen der vorliegenden Arbeit weisen demnach Substanzen, die glutamaterge Funktionen verbessern, ein hohes therapeutisches Potential als alternative Ansätze bezüglich kognitiver Defizite auf. Möglicherweise könnten sie sogar wirksamere Ansätze für die symptomatische Behandlung der Alzheimer’schen Erkrankung darstellen, als derzeitige Behandlungen, die ausschließlich cholinerge Funktion verbessern. / Alzheimer’s disease (AD) is a progressive neurodegenerative disease of the brain. Today AD is the most common form of dementia in elderly people. It is clinically characterized by a progressive loss of memory and later on a decline in higher cognitive functions. The pathological hallmarks of AD, consistently demonstrated in brain tissue of patients, are extracellular amyloid-β (Aβ plaques, intracellular neurofibrillary tangles of tau protein and a profound loss of mainly cholinergic and glutamatergic synapses and ultimatively neurons. Estimates foresee that more than 80 million individuals will be affected by the disease by 2040 due to population aging worldwide underlining the high medical need for this disease. In order to find suitable drugs for the treatment of AD, experimental model systems are utilized to explore potential drug candidates. Such an experimental system is hippocampal long-term potentiation (LTP), which is widely accepted as an in vitro model of cellular processes fundamentally involved in memory formation. The present thesis focuses on the establishment and validation of LTP in rat hippocampal slices to characterize memory enhancing drugs as a potential treatment of AD. First, a multi-slice recording system was set up enabling stable measurements of LTP for up to seven hours from several slices simultaneously (chapter 2). Then, distinct protocols to induce early and late CA1 LTP, resembling short-term and long-term memory, were established. They were validated by addressing the hallmarks accepted for these forms of LTP: protein-synthesis independence and NMDA receptor dependence without contribution of L-VDCCs for early LTP, as opposed to protein-synthesis and NMDA / L-VDCCs dependence for late LTP (chapter 3). As in AD patients a loss of mainly cholinergic and glutamatergic synapses is obvious, these validated forms of LTP were used to study drugs potentially being able to enhance cholinergic and/or glutamatergic neuronal functions. The effects of two drugs exclusively interfering with cholinergic function on LTP were tested: the α4β2 nicotinic acetylcholinergic receptor agonist TC-1827 (chapter 4) and the acetylcholine esterase inhibitor donepezil (chapter 5). Both drugs were found to increase early LTP, but to not affect late LTP. Furthermore, two drugs exclusively interfering with glutamatergic function were analyzed: the metabotropic glutamate 5 receptor postive allosteric modulator ADX-47273 (chapter 3) and the phosphodiesterase (PDE) 9A inhibitor BAY 73-6691 (chapter 5). ADX-47273 increased late LTP, but had no effect on early LTP, whereas BAY 73-6691 showed enhancing effects on both early and late LTP and even transformed early into late LTP. The same effects like for the PDE9A inhibitor were observed for the α7 nicotinic acetylcholinergic receptor partial agonist SSR180711 (chapter 4), which interferes with both, cholinergic and glutamatergic function. Thus, drugs facilitating glutamatergic function or both glutamatergic and cholinergic function seem to be more efficacious in enhancing LTP than drugs facilitating solely cholinergic function. To evaluate whether this finding also proves true for experimental circumstances mimicking decreased cognitive function together with pathophysiology in AD patients, the ability of the drugs to ameliorate LTP impaired by soluble Aβ oligomer was analyzed (chapter 6). Soluble Aβ oligomers, also referred to as amyloid-β derived diffusible ligands (ADDLs), are thought to a putative cause of AD. Here, they were demonstrated to impair early and late LTP to different extents by exclusively targeting NMDA receptors and/or their signaling. These results further contribute to the hypothesis that soluble Aβ oligomers cause synaptic dysfunction which might lead to cognitive decline seen in AD patients. Regarding drug effects, donepezil and TC-1827 slightly restored ADDLs induced impairment of early LTP, but had no effect on late LTP impaired by ADDLs. In contrast, both, SSR180711 and BAY 73-6691 completely rescued early as well as late LTP impaired by ADDLs. ADX-47273 had no restoring effect on ADDLs induced early LTP impairment, but partially restored late LTP impaired by ADDLs. Thus, the earlier finding of the present thesis was confirmed: drugs facilitating glutamatergic function not only seem to be more efficacious in enhancing LTP than drugs facilitating solely cholinergic function, but are also superior in ameliorating soluble Aβ oligomer induced LTP deficits. Therefore, from a preclinical perspective and based on the results of the present thesis, drugs interfering with glutamatergic function seem to have a high therapeutic potential as alternative treatment concerning cognitive deficits. Probably, they represent more efficacious approaches for the symptomatic treatment of AD than current treatments solely facilitating cholinergic function.

Alzheimerkrankheit

Langzeitpotenzierung

Hippocampus

Ratte

Wirkstoff

ddc:570

Die Rolle von CRAF bei der adulten hippocampalen Neurogenese / The role of CRAF in adult hippocampal neurogenesis

Pfeiffer, Marion Verena

January 2018

Der gyrus dentatus im Hippocampus ist die primäre Zielregion kortikaler Afferenzen des Enthorinalen Cortex. Im Laufe seiner Entwicklung erlangt der gyrus dentatus durch die Etablierung einer neurogenen Nische (tertiäre Matrix) die Fähigkeit fortwährender postnataler Neurogenese. Diese wird durch eine Vielzahl von Mediatoren wie Transkriptionsfaktoren gesteuert, die die Proliferation und Zelldifferenzierung, aber auch das Überleben der hippocampalen neuralen Vorläuferzellen (NPCs, neural progenitor cells) kontrollieren. In Säugetieren steuern die homologen RAF Kinasen ARAF, BRAF und CRAF die mitogene Kaskade, die bei der adulten Neurogenese von elementarer Bedeutung ist. In dieser Studie wurde untersucht ob die Nullmutation von CRAF eine Auswirkung auf die postnatale und adulte hippocampale Neurogenese hat. Unsere Analysen von BRAF- und CRAF-defizienten Mäusen zeigen in der frühen Embryonalentwicklung gemeinsame Funktionen beider Kinasen, weshalb das Fehlen einer Kinase bis zu bestimmten embryonalen Entwicklungszeitpunkten durch die jeweils andere Kinase kompensiert werden kann. Letalitätsstudien zeigen jedoch, dass BRAF und CRAF bei späteren Entwicklungsstadien jeweils unabhängig für das Überleben von Tieren relevant sind. CRAF Nullmutanten werden nicht nach der erwarteten Mendelschen Frequenz geboren und nahezu 70% der Tiere sterben bereits kurz nach der Geburt. Die maximale beobachtete Lebenserwartung adulter CRAFko Tiere lag bei postnatal Tag 55. CRAFko Mäuse haben eine reduzierte Körpergröße, veränderte Hautfarbe und einen eye-open-at-birth-Phänotyp. Verhaltensexperimente in unserer Arbeitsgruppe zeigten an heterozygoten CRAF Mäusen einen Einfluss von CRAF auf das Angst - und Lernverhalten, was einen Einfluss von CRAF auf die Neurogenese-vermittelte hippocampale Funktion andeutete. Tatsächlich konnte hier die Expression von CRAF im postnatalen Gehirn von Mäusen immunhistologisch wie auch proteinbiochemisch nachgewiesen werden. Im Hippocampus zeigte sich, dass ein Funktionsverlust von CRAF zu einer erhöhten Anzahl mitotisch aktiver NPCs führt, die massive Zellzyklusveränderungen aufweisen. Zudem wurde eine fehlerhafte Reorganisation der tertiären Matrix beobachtet. NPCs CRAF-defizienter Tiere befinden sich vermehrt im Hilus und bleiben in der Entwicklung zu reifen Körnerzellen im D Zell-Vorläuferstadium stecken. Weitere Analysen zeigen, dass diese fehlplatzierten NPCs teilweise über apoptotische Signalwege eliminiert werden. Als Resultat dieser Entwicklungsstörung ist der gyrus dentatus CRAF-defizienter Tiere verkleinert und es kann eine verlangsamte neuronale Differenzierung NPC-abgeleiteter Neurone beobachtet werden. Diese Befunde zeigen erstmals einen CRAF-spezifischen Einfluss auf die Regulation elementarer, zellulärer Eigenschaften neuronaler Vorläuferzellen des Hippocampus. / The hippocampal dentate gyrus is the primary target region of cortical afferents originating in the entorhinal cortex. During its evolutionary development, the dentate gyrus has achieved the ability of continuous postnatal neurogenesis by establishing a neurogenic niche (tertiary matrix). This process is regulated by multiple mediators such as transcription factors that control proliferation, cell differentiation and survival of hippocampal neural precursor cells (NPCs). Mammals express three homologous RAF kinases ARAF, BRAF and CRAF which regulate the mitogenic cascade, an essential element of adult neurogenesis. In this study we analysed if the nullmutation of CRAF interferes with postnatal and adult hippocampal neurogenesis. Our analysis of BRAF and CRAF-deficient mice reveals common functions of both kinases during early embryogenesis. In this developmental phase, lack of one kinase may be compensated by the other kinase. This phenomenon ends at later embryonic developmental stages. Lethality studies show independent roles of BRAF and CRAF in survival during later developmental stages. CRAF null-mutants are not born in mendelian frequency and almost 70% of all CRAF mutants die within a short time window after birth. The oldest analysed CRAFko mice survived until postnatal day P55. CRAFko mice show a decreased body size, altered skin colour and possess an eye-open-at-birth-phenotype. Previous behavioural experiments by our group revealed the influence of CRAF in anxiety-like behaviour and specific learning paradigms, indicating an effect of CRAF on neurogenesis-dependent hippocampal functions. Indeed, this study confirmed the expression of CRAF with immunohistological and biochemical methods in postnatal mouse brain tissue. In the hippocampus, the loss-of-function mutation of CRAF leads to increased numbers of mitotically activated NPCs which exhibit drastic cell-cycle abnormalities. In addition, CRAF-deficient mice carry malformations in the organisation of their tertiary matrix. NPCs of CRAF-deficient mice are mainly located in the hilus where their maturation towards the neuronal lineage persists in the D-cell stage. A detailed analysis shows that these misplaced NPCs are - at least partially - eliminated by apoptosis. Due to this developmental defect the dentate gyrus of CRAF-deficient mice is smaller and the neuronal differentiation of NPC-derived neurons is delayed. These results show for the first time a CRAF-specific effect on the regulation of basic cellular functions of neuronal precursors in the hippocampus.

Hippocampus

adulte Neurogenese

RAF Kinasen

ddc:570

Effect of Cadherin-13 inactivation on different GABAergic interneuron populations of the mouse hippocampus / Effekt der Cadherin-13 Inaktivierung auf verschiedene GABAerge Interneuronenpopulationen im Hippocampus der Maus

Bacmeister, Lucas

January 2018

Cadherin-13 (CDH13) is an atypical member of the cadherin superfamily, a group of membrane proteins mediating calcium-dependent cellular adhesion. Although CDH13 shows the classical extracellular cadherin structure, the typical transmembrane and cytoplasmic domains are absent. Instead, CDH13 is attached to the cell membrane via a glycosylphosphatidylinositol (GPI) anchor. These findings and many studies from different fields suggest that CDH13 also plays a role as a cellular receptor. Interestingly, many genome-wide association studies (GWAS) have found CDH13 as a risk gene for attention-deficit/hyperactivity disorder (ADHD) and other neurodevelopmental disorders. In previous work from our research group, strong expression of Cdh13 mRNA in interneurons of the hippocampal stratum oriens (SO) was detected. Therefore, double-immunofluorescence studies were used to evaluate the degree of co-expression of CDH13 with seven markers of GABAergic interneuron subtypes. For this purpose, murine brains were double stained against CDH13 and the respective marker and the degree of colocalization in the SO of the hippocampus was assessed. Based on the result of this immunofluorescence study, quantitative differences in interneuron subtypes of the SO between Cdh13 knockout (ko), heterozygote (het) and wildtype (wt) mice were investigated in this dissertation using stereological methods. In addition, genotype- dependent differences in the expression of genes involved in GABAergic and glutamatergic neurotransmission were analyzed by quantitative real-time PCR (qRT-PCR). Primers targeting different GABA receptor subunits, vesicular GABA and glutamate transporter, GABA synthesizing enzymes and their interaction partners were used for this purpose. The results of the stereological quantification of the interneuron subtypes show no significant differences in cell number, cell density or volume of the SO between Cdh13 ko, het and wt mice. On the other hand, qRT-PCR results indicate significant differences in the expression of tropomyosin-related kinase B gene (TrkB), which encodes the receptor of brain-derived neurotrophic factor (BDNF), a regulator of GABAergic neurons. This finding supports a role for CDH13 in the regulation of BDNF signaling in the hippocampus. / Cadherine sind eine große Gruppe von calciumabhängigen Typ-1 Transmembranproteinen, die an der Ausbildung von Zell-Zell-Kontakten beteiligt sind. Cadherin-13 (CDH13) ist ein atypisches Mitglied dieser Proteinfamilie. Obwohl es die gleiche extrazelluläre Struktur wie klassische Cadherine besitzt, fehlen sowohl die cytoplasmatische als auch die Transmembrandomäne. Stattdessen ist CDH13 über einen GPI-Anker an der zellulären Plasmamembran befestigt. Diese Ergebnisse und viele andere Studien aus unterschiedlichen Bereichen lassen vermuten, dass CDH13 auch als zellulärer Rezeptor wirkt. Interessanterweise ergaben verschiedene genomweite Assoziationsstudien, dass CDH13 ein vielversprechendes Kandidatengen für das Auftreten von Aufmerksamkeitsdefizit-/Hyperaktivitätsstörung (ADHS) und anderen Störungen der neuronalen Entwicklung ist. In früheren Studien unserer Arbeitsgruppe wurde eine starke Expression von Cd13 mRNA in Interneuronen des stratum oriens (SO) des Hippocampus festgestellt. Daher wurde mit Hilfe von Immunfluoreszenz der Grad der Koexpression von CDH13 mit 7 verschiedenen Markern von Subtypen GABAerger Interneuronen ermittelt. Zu diesem Zweck wurden Doppelfärbungen gegen CDH13 und den jeweiligen Marker durchgeführt und anschließend der Grad der Kolokalisation im SO des Hippocampus berechnet. Ausgehend von diesen Ergebnissen wurden in dieser Dissertation quantitative Unterschiede zwischen verschiedenen Subtypen von Interneuronen in Cdh13 knockout (ko), heterozygoten (het) und Wildtyp (wt)-Mäusen mit Hilfe von stereologischen Methoden ermittelt. Darüber hinaus wurden genotypabhängige Unterschiede in der GABAergen und glutamatergen Neurotransmission mit quantitativer Echtzeit-PCR (qRT-PCR) evaluiert. Hierzu wurden Primer eingesetzt, die sowohl auf Untereinheiten des GABA Rezeptors, GABA-synthetisierende Enzyme als auch auf GABA- und Glutamat-Transporter innerhalb synaptischer Vesikel abzielen. In der stereologischen Quantifizierung der Interneuron-Subtypen wurden keine signifikanten Unterschiede bezüglich der Zellzahl, der Zelldichte oder des Volumens des SO zwischen den verschieden Genotypen gefunden. Im Gegensatz dazu zeigten sich in der qRT-PCR signifikante Unterschiede in der Expression von tropomyosin-related kinase B (TrkB), einem Gen, das für den Rezeptor des brain-derived neurotrophic factor (BDNF) kodiert. Bei diesem handelt es sich um einen Regulator von GABAergen Neuronen. Diese Ergebnisse bekräftigen, dass CDH13 an der Regulation des BDNF-Signalwegs im Hippocampus teilnimmt.

Cadherine

GABAerge Nervenzelle

Hippocampus

Maus

ddc:610

Brain region gene expression responds discretely to chronic alcohol withdrawal with specific disruption of the hippocampus during intoxication

Berman, Ari Ethan,

January 1900

Thesis (Ph. D.)--University of Texas at Austin, 2005. / Vita. Includes bibliographical references.

The effects of neurosteroids and neuropeptides on anxiety-related behavior

Engin, Elif

11 1900

Anxiety disorders are the most prevalent of all psychiatric conditions. However, current pharmacological treatments for anxiety disorders are characterized by one or more of the following deficiencies: 1) unwanted side effects, 2) partial efficacy, 3) addictive potential, and 4) delayed onset of therapeutic effects. These therapeutic liabilities motivate the search for better pharmacological treatments. This research effort has been concentrated in three broad, neuropharmacological domains: 1) Sub-unit specific GABAA receptor agonists, 2) Neurosteroids, and 3) Neuropeptides. The general purpose of this thesis was to advance our understanding of the putative anxiolytic potential of neurosteroids and neuropeptides, and their neural mechanisms of action, as revealed by intracerebral infusion studies in animal models of anxiety. Chapter 1 of this thesis will provide a systematic review of what is now known about the behavioral effects of intra-cerebrally infused agonists and antagonists of anxiolytic compounds in animal models of anxiety. A theoretical context in which to view the empirical work is also outlined. Chapter 2 will provide a brief introduction to neurosteroids and neuropeptides, and their potential as anxiolytic drugs as suggested by the current literature. In Chapter 3, the anxiolytic-like effects of the neurosteroid allopregnanolone were examined in the amygdala, the hippocampus or the medial prefrontal cortex. Allopregnanolone had site- and test-specific anxiolytic effects, causing anxiolysis following infusion into the amygdala and the medial prefrontal cortex. In Chapter 4, the anxiety-related effects of two receptor antagonists of the neuropeptide arginine vasopressin were investigated in the hippocampus. Anxiolytic effects were specific to both receptor sub-type and by infusion site. In chapter 5, the putative anxiolytic and antidepressant effects of the neuropeptide somatostatin were investigated. Intracerebroventricular microinfusion of somatostatin produced anxiolytic-like and antidepressant-like signatures in distinct domains. In chapter 6, selective agonists for each of the 5 G-protein coupled somatostatin receptors were administered to rats. Intracerebroventricular administration of an sst2 agonist produced anxiolytic-like effects, whereas an antidepressant-like effect was observed following the administration of both sst2 and sst3 agonists. In summary, the present thesis provides important clues to the neurochemical correlates of anxiety, and its potential treatment with alternative compounds such as neuropeptides.

anxiety

vasopressin

somatostatin

allopregnanolone

neuroscience

hippocampus

Radiological Studies on Hippocampal Development : Morphological Variants and their Relationship to Epilepsy

Bajic, Dragan

January 2010

During fetal development, the hippocampal structures are folded forming the hippocampal sulcus which penetrates into the temporal lobe and then the entity rotates.  During this process, the hippocampal sulcus will be closed and the inverted hippocampus takes a rounded form. After complete inversion, the hippocampus has an oval form in a plane perpendicular to its long axis. If this process has not been completed the hippocampus remains the rounded form. That condition is called incomplete hippocampal inversion (IHI). The aims of this study was to evaluate the frequency of IHI in non-epileptic and epileptic children and adults and to explore the development of the hippocampal region by studying premature neonates and fetuses. Magnetic resonance (MR) images of 201 epilepsy patients and 150 non-epileptic subjects were evaluated without knowing clinical data. IHI was found in 19 % in seizure free controls (20 left-sided and 8 bilateral). 30% of the 201 epilepsy patients had IHI (40 left-sided, 4 right-sided, 16 bilateral). The difference was statistically significant (p<0.02). 25% of the temporal lobe epilepsy patients had IHI. The frequency was not significantly higher than in controls. There is no causality between temporal lobe epilepsy and IHI. 44% of the Rolandic epilepsy patients and 57% of the cryptogenic generalized epilepsy patients had IHI. IHI can be a sign of possible disturbed cerebral development in other parts of the brain. Cranial ultrasound examinations of 160 premature children were analyzed. The age at examination was 23-24 GW in 24 children, 25-28 GW in 72 children, and 29-36 GW in 64 children. IHI was found in 50%, 25% and 14%, respectively. The frequency difference between the children < 25 GW and > 25 GW was statistically significant (p< 0.001). From 25 GW onwards, the frequency and laterality of IHI is similar to that in the adult population. MRIs of 63 fetuses without intracranial pathology were reviewed independently by two radiologists. Three MRIs were performed post mortem at gestation week (GW) 17-18 and 60 in utero at GW 19-35. The hippocampal sulcus was open, bi- or unilaterally, in 35 fetuses at GW 17-32. The oldest of them was at GW 32.  The sulcus was closed at GW 21 at the earliest, unilaterally, and always from GW 33 onwards bilaterally. In 26/63 fetuses (41%), the hippocampal development was asymmetric and in 23 fetuses, the right side had developed faster.

MRI

Brain development

Hippocampus

Epilepsy

Radiology

Radiologi

Hippocampal Functioning in Adolescents with Congenital Hypothyroidism

Wheeler, Sarah

12 January 2012

Congenital hypothyroidism (CH) is a pediatric endocrine disorder caused by an insufficiency of thyroid hormone. Despite treatment following newborn screening, CH is associated with persisting memory weaknesses. Given animal research has shown thyroid hormone plays a crucial role in the development of the hippocampus, a brain structure required for normal declarative memory, it is possible that altered hippocampally-dependent processes underlie the memory weakness associated with CH. Previous studies of individuals with CH have found reduced memory abilities and left hippocampal volumes but no study has thoroughly assessed memory abilities or how the hippocampus functions to support memory. Thus, the present study compared individuals with CH and typically developing adolescents using clinical memory tests and two associative memory tasks shown in adults to activate the hippocampus during functional magnetic resonance imaging (fMRI). Results indicated groups did not differ in memory accuracy on clinical measures or either fMRI task. However, fMRI revealed hippocampal activation differed between the groups when performing the associative memory tasks. The first task utilized a visuospatial paired associates novelty detection paradigm to show the CH group increased activation relative to controls in left hippocampus and recruited right hippocampus when controls did not. Since previous research suggested the left hippocampus and verbal memory were more vulnerable to the effects of CH, the second task utilized a verbal paired associates paradigm to demonstrate that when making old and new judgments about associations versus items, the CH group increased activation relative to controls in left hippocampus. Further investigation revealed that when recognizing old associations versus items, the CH group had increased bilateral posterior hippocampal activation whereas controls showed increased activation in right anterior hippocampus, a distinction noted in previous research with this paradigm which suggests individuals with CH may retrieve associations in a less flexible manner than controls. In addition, worse memory performance and increased hippocampal activation, particularly on the left, was predicted by severity of hypothyroidism experienced early in life. In conclusion, these studies demonstrate that early thyroid hormone insufficiency associated with CH alters the functioning of the hippocampus and engenders use of compensatory mechanisms to support associative memory functions.

memory

congenital hypothyroidism

functional imaging

hippocampus

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