Estudo morfológico do hipocampo de uma espécie de primata da Amazônia: Cebus apella, (Linnaeus, 1758) / Anatomic study of the hippocampus in a primate species of the Amazon Cebus apella (Linnaeus, 1812)

Torres, Laila Brito [UNIFESP]

24 November 2010

Made available in DSpace on 2015-07-22T20:50:10Z (GMT). No. of bitstreams: 0 Previous issue date: 2010-11-24 / Os primatas constituem modelos animais insubstituíveis para áreas de investigação científica devido a sua estreita relação evolutiva com os seres humanos o que assegura modelos de alta fidelidade com capacidade preditiva e discriminativa que podem não estar disponíveis em outras espécies. O Cebus apella, uma espécie de primata do novo mundo que pertence à família Cebidae, subordem Cebinae (Linnaeus, 1758), são comumente usados em pesquisas biomédicas e comportamental sendo uma espécie eleita para muitos modelos experimentais com enfoque cognitivo. O hipocampo, estrutura límbica altamente plástica situado no lóbulo temporal é importante para a aprendizagem e consolidação da memória. Desta forma, o objetivo deste estudo foi caracterizar quantitativamente e qualitativamente as células parvalbumina-positivas no hipocampo de Cebus apella, bem como estimar o volume e o número de neurônios em seus diferentes subcampos, utilizando o método do fracionador óptico. Os resultados obtidos em nosso estudo podem ser úteis para diversos projetos experimentais que tenham como foco a medicina translacional. / The nonhuman primates constitute irreplaceable animal models for research areas in which their close evolutionary relationship to humans ensures high fidelity models with predictive and discriminative abilities that may not be available in other species. The Cebus apella, a New World primate specie belonging to the Cebidae family, Cebinae suborder (Linnaeus, 1758) are commonly used in biomedical and behavior research being the specie of choice for many cognitive experimental tasks. The hippocampus, a highly plastic limbic structure situated in the temporal lobe is important for learning and memory consolidation. In this way, the aim of this study was to characterize quantitatively and qualitatively the Parvalbumin positive cells in the hippocampal formation of the Cebus monkey and also estimate the volume and neuronal number in their different subfields using an optical fractionator design method. The results obtained in our study will be useful for many experimental designs in translational medicine. / TEDE / BV UNIFESP: Teses e dissertações

Cebus apella

Estereologia

Formação hippocampal

Parvalbuminas

Primatas não humanos

Primatas

Cebus

Hipocampo

Cebus apella

Hippocampus

Parvalbumins

Stereology

Non-human primates

Cebus

Primates

The identification of compounds from apples that regulate adult hippocampal neurogenesis

Ichwan, Muhammad

09 May 2016

The high composition of fruits and vegetables in the daily diet is associated with cognitive well-being, especially in the elderly population. The phytonutrients are shown to have effects as antioxidants that neutralize oxidative stressors and can interact with molecular pathways to signal neuron survival. Adult hippocampal neurogenesis is a dynamic lifelong process of generating functional newborn neurons in the granular layer of the dentate gyrus from adult precursor cells. This process contributes to brain plasticity and plays a role in learning and memory. External stimuli such as environmental enrichment and physical activity are known to positively regulate this process. However, the role of nutrition and whether nutritional compounds have pro-neurogenic effects on adult hippocampal precursor cells are still elusive. In this study, I investigated the impact of dietary compounds in apples, a significant source of phytonutrients in our food, on adult hippocampal neurogenesis. I demonstrated that quercetin, the most abundant polyphenol in apple, induces cell cycle exit and differentiation of adult hippocampal precursor cells in monolayer culture. Furthermore, this compound also increases the number of surviving cells upon differentiation in vitro, through the activation of endogenous antioxidants in the Nrf2-Keap1 pathway and the prosurvival Akt pathway. Quercetin supplementation in vivo is also shown to significantly increase the number of surviving cells and new neurons in the dentate gyrus. To search for other potential active compounds in apple, I performed bioassay-guided fractionation whereby the flesh extract from apples of the Pinova cultivar was subjected to liquid- and solid phase separation and the active fraction was determined using primary neurosphere assays using cells derived from adult mouse dentate gyrus. Using mass spectometry, we revealed that the active compounds in the apple flesh extract are dihydroxybenzoate glycosides, which are non-flavonoid benzoic acid derivatives. I also confirmed that the isomers of these compounds; 2,3- and 3,5 dihydroxybenzoic acids significantly increase the number of neurospheres. Interestingly, 3,5 dihdroxybenzoic acid is an agonist of lactate receptor hydroxycarboxylic acid receptor 1 (HCAR1), with an even higher affinity than lactate. This receptor is suggested to mediate neurotrophic actions such as increasing production and release of BDNF. I also demonstrated for the first time that this receptor is presence in adult hippocampal precursor cells. To observe whether customary fruits or fruit-related products consumption affects adult hippocampal neurogenesis, I performed an experiment giving apple juice supplementation ad libitum to mice. I did not find a significant increase in net neurogenesis or the performance in the Morris water maze after apple juice supplementation. This is likely due to the low concentration of active compounds in apple juice failing to reach an effective concentration in the body. I conclude that apples provide potential proneurogenic compounds that can influence adult hippocampal neurogenesis through the activation of endogenous antioxidant mechanisms and molecular pathways for cell survival. Further studies are necessary to investigate the role of HCAR1 activation on adult hippocampal neurogenesis, which is a potential new mechanism to explain the health benefits of fruit and vegetable consumption. / Eine Ernährung die täglich reich an Obst und Gemüse ist, hat insbesondere bei älteren Menschen einen positiven Einfluss auf kognitive Fähigkeiten. Pflanzeninhaltsstoffe wirken als natürliche Antioxidantien, indem sie oxidative Stressoren neutralisieren. Weiterhin beeinflussen pflanzliche Nährstoffe molekulare Signalwege welche beim Überleben von Neuronen eine Rolle spielen. Die adulte hippocampale Neurogenese ist ein dynamischer, lebenslanger Prozess, bei dem aus Vorläuferzellen funktionelle neue Neuronen in der Körnerzellschicht des Gyrus dentatus gebildet werden. Dieser Prozess trägt zur Plastizität des Gehirns bei und spielt eine bedeutende Rolle beim Lernen und für das Gedächtnis. Externe Stimuli wie zum Beispiel eine reizreiche Umgebung und körperliche Aktivität wirken als positive Regulatoren und begünstigen die adulte hippocampale Neurogenese. Welche Rolle die Ernährung dabei spielt und ob Nahrungsbestandteile einen proneurogenen Effekt auf adulte hippocampale Vorläuferzellen haben ist kaum bekannt. In diesem Projekt habe ich den Effekt von Nahrungsbestandteilen aus Äpfeln, welche eine bedeutende Quelle von pflanzlichen Nährstoffen in unserer Ernährung darstellen, auf die adulte hippocampale Neurogenese untersucht. Ich habe gezeigt, dass Querzetin, das am reichlichsten in Äpfeln enthaltende Polyphenol, in der Monolayer-Zellkultur den Austritt aus dem Zellzyklus induziert und die Differenzierung von adulten hippocampalen Vorläuferzellen fördert. Des Weiteren steigert Querzetin nach der Differenzierung in vitro die Anzahl an überlebenden Zellen. Dies geschieht durch die Aktivierung von endogenen Antioxidantien des Nrf2-Keap1-Signalweges und des für das Überleben von Zellen förderlichen Akt-Signalweges. Die Verabreichung von Querzetin in vivo als Nahrungsergänzungsmittel führte ebenfalls zu einem signifikanten Anstieg der Anzahl an überlebenden Zellen und neu gebildeten Nervenzellen im Gyrus dentatus. Um weitere potentiell aktive Wirkstoffe von Äpfeln zu bestimmen, habe ich eine Bioassay-ausgerichtete Fraktionierung durchgeführt, wobei der Fruchtfleischextrakt von Äpfeln der Sorte Pinova einer Fest-/ Flüssig-Separation unterzogen wurde. Die aktive Fraktion wurde anhand der primären Neurosphäre-Assay-Methode mit Zellen aus dem Gyrus dentatus adulter Mäuse ermittelt. Mittels spektrometrischer Analyse habe ich gezeigt, dass die aktiven Wirkstoffe im Fruchtfleischextrakt von Äpfeln zur Gruppe der Dihydroxybenzol-Glykosiden gehören, welche den nicht-flavonoiden Benzoesäure-Derivaten zuzuordnen sind. Im in vitro Neurosphäre-Assay habe ich zudem gezeigt, dass die Isomere dieser Wirkstoffe, die 2,3- und die 3,5-Dihydroxybenzoesäuren, die Anzahl der Neurosphären signifikant erhöhen. Interessanterweise ist die 3,5-Dihydroxybenzoesäure ein Agonist des Laktatrezeptors Hydroxycarboxylic acid receptor 1 (HCAR1) und weist sogar eine noch höhere Affinität als Laktat auf. Es wird suggeriert, dass dieser Rezeptor neurotrophische Wirkungen vermittelt, wie zum Beispiel eine erhöhte Produktion von BDNF und dessen Ausschüttung. Zudem habe ich das Vorkommen dieses Reporters erstmalig bei adulten hippocampalen Vorläuferzellen nachgewiesen. Um zu untersuchen, ob der Konsum handelsüblicher Obstprodukte die adulte hippocampale Neurogenese beeinflusst, habe ich Mäusen Apfelsaft ad libitum verabreicht. Nach der Gabe von Apfelsaft sah ich keinen signifikanten Anstieg der Gesamtneurogenese und keine Verbesserung der Leistungsfähigkeit im Morris-Wasserlabyrinth-Test. Dies ist bedingt durch eine zu geringe Konzentration der aktiven Wirkstoffe im Apfelsaft wodurch die wirksame Konzentration im Körper nicht erreicht wird. Ich schlussfolgere, dass in Äpfeln potentielle pro-neurogene Inhaltsstoffe enthalten sind, welche die adulte hippocampale Neurogenese beeinflussen. Dies wird insbesondere durch die Aktivierung endogener antioxidativer Mechanismen und molekularer Signalwege vermittelt, die für das Überleben von Zellen von Bedeutung sind. Weitere Studien sind nötig, um zu bestimmen wie sich die Aktivierung von HCAR1 auf die adulte hippocampale Neurogenese auswirkt. Dies stellt einen potentiellen neuen Wirkmechanismus dar, welcher die gesundheitlichen Vorteile von Obst- und Gemüsekonsum belegt.

Äpfel

Querzetin

Dihydroxybenzoesäuren

HCAR1

Neurosphäre Assay

adulte hippocampale Neurogenese

apples

quercetin

dihyroxybenzoic acids

HCAR1

neurosphere assay

adult hippocampal neurogenesis

ddc:610

rvk:WE 2400

Contribution of hippocampal diaschisis to the memory deficits associated with focal cerebral ischemia in the rat : converging behavioral, electrophysiological and functional evidence / Contribution du phénomène de diaschisis hippocampique aux déficits mnésiques associés à l’ischémie cérébrale focale chez le rat : convergences comportementale, électrophysiologique et fonctionnelle

Rabiller, Gratianne

21 December 2015

Les mécanismes impliqués dans les troubles cognitifs induits à la suite d’une ischémie cérébrale (IC) demeurent mal compris. En plus du cœur ischémique nécrosé et de la zone de pénombre entourant cette lésion, certaines régions éloignées de la zone ischémique peuvent être fonctionnellement affectées, un phénomène connu sous le nom de «diaschisis». Sachant qu’il existe de fortes interactions fonctionnelles entre l’hippocampe (HPC) et le cortex lors des processus mnésiques, nous avons émis la possibilité que les troubles mnésiques survenant après une IC focale qui préserve l’intégrité de l’HPC, auraient pour origine une perturbation de la connectivité cortico-hippocampique conduisant à un hypofonctionnement hippocampique induit par le phénomène de diaschisis. Afin d’éprouver cette hypothèse, nous avons utilisé le modèle d’occlusion permanente de l'artère cérébrale moyenne chez le rat (OPACM) qui reproduit l’ischémie cérébrale focale humaine. Dans ce modèle, le cortex somato-sensoriel (SS) est endommagé unilatéralement alors que l’intégrité de l’HPC est préservé. Les rats OPACM ont montré une diminution de l’expression du gène c-fos dans l’HPC lors de l'exploration d'un nouvel environnement, indiquant une hypoactivation neuronale. Les rats OPACM ont également présenté une perturbation des mémoires olfactive associative et spatiale lors des tests de transmission sociale de préférence alimentaire (TSPA) et du Barnes maze, respectivement. Afin de confirmer que l’hypofonctionnement hippocampique induit par l’IC résultait d’une réduction des afférences corticales («déactivation») provenant du cortex endommagé, nous avons réalisé des inactivations pharmacologiques spécifiques du cortex SS et ou de l’HPC par injection de lidocaïne ou de CNQX. Ces injections ont induit une hypoactivation hippocampique (réduction du nombre de noyaux Fos-positifs) associée à une perturbation mnésique dans le test de TSPA. L'activité hippocampique chez des rats anesthésiés pendant l’IC ou deux semaines après, ainsi que lors de l’inactivation pharmacologique du cortex SS, a également été examinée par une approche électrophysiologique. Les résultats ont montré une altération de la fréquence d’apparition des «sharp-wave ripples» hippocampiques et révélé une instabilité de la fréquence thêta hippocampique lors de la reperfusion ou deux semaines après IC, ainsi que lors de l’inactivation corticale, suggérant une altération de la dynamique d’interaction entre l’HPC et le cortex. Pris dans leur ensemble, ces résultats identifient le phénomène de diaschisis hippocampique comme un mécanisme crucial impliqué dans l’hypofonctionnement hippocampique et les déficits mnésiques observés après une IC. / The cognitive consequences and the underlying mechanisms leading to cognitive impairments after cerebrovascular occlusive diseases are still unclear. In addition to the infarct zone that suffer the deadly consequence of ischemic stroke, the penumbra surrounding the lesion site and some brain regions more remote to the ischemic areas can be functionally affected by the insult. This phenomenon is referred to as diaschisis. In light of the importance of interactions between hippocampus and cortex during memory processing, we hypothesized that the cognitive impairments observed following focal ischemia could occur in the absence of direct hippocampal insult, possibly via impaired connectivity within cortico-hippocampal networks leading to diaschisis-induced hypofunctioning in specific hippocampal subregions. To examine this possibility, we used the distal middle cerebral artery occlusion (dMCAO) ischemic model in rats which induces restricted cortical infarct in the somatosensory (SS) cortex in the absence of direct hippocampal injury. dMCAO rats exhibited reduced expression of the activity-dependent gene c-fos in the hippocampus when exploring a novel environment, indicating neuronal hypoactivation. Ischemic rats also showed impaired associative olfactory and spatial memory when tested in the social transmission of food preference (STFP) task and the Barnes maze test, respectively. To confirm that the ischemic-induced hippocampal hypofunctioning resulted from reduced afferent inputs (i.e. deactivation) originating in the damaged cortex, we performed region-specific pharmacological inactivation of SS and/or HPC using lidocaine or CNQX. Fos imaging revealed that these treatments induced hippocampal hypoactivation and impaired memory performance as measured in the STFP task. We additionally performed electrophysiological recordings of hippocampal activity in anesthetized rats during acute stroke and two weeks later or after SS cortex inactivation. We found an alteration in the occurrence of sharp-wave ripples associated with instability of theta frequency during reperfusion after stroke and SS cortex inactivation, suggesting an alteration in the dynamics of hippocampal-cortical interactions. Taken collectively, these findings identify hippocampal diaschisis as a crucial mechanism for mediating stroke-induced hippocampal hypofunction and associated memory deficits.

Mémoire spatiale

Mémoire associative

Ischémie cérébrale focale

Oscillations hippocampiques

C-fos

Rat

Spatial memory

Associative memory

Ischemic stroke

Hippocampal oscillations

C-fos

Rat

Lithium Exposure Induced Changes At Glutamatergic Synapses In Hippocampal Neurons- Insights From In Vitro Electrophysiology And Imaging Studies

Ankolekar, Shreya Maruti

05 1900

Lithium is a drug used to treat mood disorders and also has many side effects, including central nervous system (CNS) complications (such as cognitive dulling), associated with its use. The mechanism of its action still remains unknown. Over the years, many leads have started emerging. It has been shown to inhibit several enzymes in the cell and has been implicated in altering many neurotransmitter systems and signal transduction pathways (serotonin, dopamine and norepinephrine neurotransmissions). Effect of exposure to therapeutic levels of lithium on mature glutamatergic synapses is being studied and several changes in glutamate receptor subtypes have already been reported. Effects of lithium on developing glutamatergic synapses have not been studied. The thesis tries to document and understand the changes brought about by long term lithium treatment on developing glutamatergic synapses in vitro in hippocampal neuronal cultures. In the present work, patch clamp technique was used to monitor the changes in the postsynapse and fluorescence imaging to study the presynaptic changes. The hippocampal neuronal cultures were treated with 1 mM lithium for 6 days during the synaptogenesis stage (DIV 4-10) and termed as chronic Li treatment (CLi). Following CLi treatment the changes occurring in amplitude and rectification property of the AMPA receptor (AMPAR), a subtype of glutamate ionotropic receptor, mediated miniature excitatory postsynaptic currents (mEPSCs) have been reported (Chapter III). Lithium inhibits protein kinase A (PKA), glycogen synthase kinase–3β (GSK-3β) and glutamate reuptake. Effect of inhibiting PKA, GSK-3β and glutamate reuptake was also studied with a view to understand the molecular basis of lithium action on AMPAR mEPSCs (Chapter IV). It was found that chronic lithium treatment (CLi) caused a reduction in the mean amplitude of mEPSCs mediated by AMPARs and also changed the rectification property of these receptors from being more outwardly rectifying to being more inwardly rectifying, an indication probably of increase in contribution of Ca2+-permeable AMPARs to the synaptic events. AMPAR events in chronic lithium treated cultures were more sensitive to both N-acetyl spermine (NASPM) application and di-fluoro-methyl-ornithine (DFMO) treatment, both specific to Ca2+-permeable AMPARs, indicating that there was an increase in the contribution from Ca2+-permeable AMPARs to the synaptic events. PKA inhibition with H-89 treatment (starting from DIV 4 (for 6 days)) reduced the mean amplitude of AMPAR mEPSCs and increased the mean rectification index (RI). GSK-3β inhibition with SB415286 (starting from DIV 4 (for 6 days)) did not alter the mean mEPSC amplitude but reduced the mean RI. Transient (24 hrs) glutamate reuptake inhibition with threo-β-Hydroxy-Aspartic-Acid (THA) at DIV 4 followed by a period of recovery led to smaller amplitudes but no change in RI. The 24 hr glutamate reuptake block on DIV 4 had long term effects. It led to an increase in AMPAR mEPSC frequency while AMPAR mEPSC amplitudes were reduced. The mean RI decrease seen when glutamate reuptake was blocked for 24 hrs on DIV 10, was absent in DIV 4 THA treated neurons. However, when the neuronal cultures were maintained in the presence of PKA and GSK-3β inhibitors, the DIV 4 THA treated neurons showed AMPAR mEPSC characteristics similar to CLi neurons. Thus, it was seen that individual inhibition of PKA, GSK-3β and glutamate reuptake did not lead to changes in AMPAR mEPSCs similar to that seen in lithium treated neurons. The effect of lithium exposure during synapse development on AMPARs could be reproduced closely by co-inhibiting PKA, GSK-3β and glutamate reuptake. Using the styryl dye FM1-43, the changes induced in presynaptic release by a similar chronic lithium treatment was studied (Chapter V). It was found that lithium exposure (1 mM, DIV 4-10) brought down the extent of dye loading, destaining and also slowed down the rate of dye loss in response to high KCl stimulation (the τfast component of destaining was significantly slower). Minimum loading experiments did not reveal any difference in mode of exocytosis (kiss and run/full-collapse) in control and lithium treated cultures. Chlorpromazine treatment (that inhibits clathrin-mediated endocytosis) affected dye loading to a lesser extent in lithium treated cultures as compared to control. Surprisingly, exposure to hyperosmotic solution 10 minutes after dye wash out boosted the extent of dye loading and destaining in lithium treated cultures (a phenomenon not seen in control). This could happen if the FM1-43 is trapped away from the wash solution during the wash period. This would be possible if endocytosis in CLi takes place, differently from control, through a process involving membrane infoldings similar to bulk endocytosis albeit a slower/compromised one. Taken together, the data presented here indicates that lithium treatment during synaptogenesis affects vesicular recycling mostly at the endocytosis and docking/priming steps (mobilization of vesicles for release). Lithium treated cultures also did not show the high KCl associated presynaptic potentiation observed in control which is a significant finding. In conclusion, chronic lithium treatment affected both the presynaptic and postsynaptic compartments of the glutamatergic synapse. The effect of lithium on AMPAR mEPSC could not be reproduced by individual inhibitions of biochemical effectors but by multiple inhibitions. Thus, the study done here underscores the need to look at the manifold effect of lithium in an integrated way. The study also might have implications in understanding the CNS complications seen in patients taking lithium treatment and in babies perinatally exposed to lithium.

Hippocampal Neurons

Mood Disorders - Neurobiology

Image Processing

Electrophysiology

Glutamatergic Synapses

Mood Disorder Treatment

AMPA Receptors - Lithium Exposure

Chronic Lithium Treatment

Pharmacology and Therapeutics

Dérivés puriques et physiopathologie de la maladie d’Alzheimer / Purine derivatives and pathophysiology of Alzheimer’s disease

Leuxe, Charlotte

28 April 2017

La maladie d’Alzheimer (AD), pathologie neurodégénérative progressive, est caractérisée par des dépôts β-amyloïdes extracellulaires, des enchevêtrements neurofibrillaires intracellulaires de Tau et une dégénérescence neuronale. A travers les nombreux modèles transgéniques AD disponibles, les connaissances sur les peptides amyloïdes et la protéine Tau ne cessent de progresser. Mais contrairement aux cas génétiques, l’étiologie des cas sporadiques d’AD reste à ce jour idiopathique, rendant difficile d’établir une stratégie thérapeutique efficace. Au cours d’une étude sur l’implication des protéines kinases dans la pathogénèse d’AD, des collaborateurs ont fait une observation totalement inattendue, mais très intéressante: une molécule de faible poids moléculaire, serait capable d’induire une production spécifique d’Aβ1-42 sans altérer les niveaux d’Aβ1-40 dans un modèle de lignée cellulaire. Dans ce contexte, le projet de thèse portait sur l’utilisation de dérivé purique (PD1) pour développer des modèles AD induits chimiquement sur différents supports (culture primaire de neurones, culture organotypique d’hippocampe et souris) et en investiguer les mécanismes sous-jacents à l’augmentation des peptides A1-42 (issus du métabolisme de l’APP (Amyloid precursor protein)).La première partie du projet de thèse a permis de mettre en évidence dans un contexte in vitro (culture primaire de neurones et culture organotypique d’hippocampe) que PD1 à forte dose induisait une augmentation du ratio Aβ42/40 et de manière répétable. Fort de ces résultats, nous avons voulu étudier les mécanismes d’action de PD1 autour de deux hypothèses : interaction dans le métabolisme de l’APP et implication des cellules gliales. Contrairement à nos premières hypothèses, nous avons montré que PD1 aurait de potentiels effets anti-inflammatoires (i.e. IL-1β) in vitro et in vivo. La voie de signalisation de l’IL-1β étant de plus en plus incriminée dans la pathogenèse d’Alzheimer; nous nous sommes interrogés sur l’effet dual de PD1 : outil pharmacologique alzheimerigène ou candidat médicament pour le traitement d’AD? / Alzheimer’s disease (AD), a progressive neurodegenerative disorder, appears to be associated with an increase in a particular form of β-amyloid deposits, intracellular Tau tangles and neuronal degeneration. Through many available transgenic AD models, knowledge about amyloid peptides and Tau protein continues to increase. However, in contrast to the genetic cases of AD, the etiology of sporadic AD cases remains unknown, making the establishment of an effective therapeutic strategy difficult.During the course of a study on the role of protein kinase involved in AD, our collaborators made an unexpected but very interesting observation. They identified a low molecular weight compound able to induce production of Aβ1-42 while the level of the much less toxic form Aβ1-40 remained constant. This selective induction of Aβ1-42 versus Aβ1-40 was observed in a cell line model. Therefore, the overall goal of the project thesis was based on the use of purine derivative (PD1) to understand the molecular mechanisms underlying the selective production of Aβ1-42. This would allow us to establish cellular assays and a chemically-induced animal AD model relevant to studies on the treatment and prevention of AD.The first part of this project allowed us to demonstrate in vitro that PD1, at high dose, repeatedly induced an increase in Aβ42/40 ratio in primary neurons and in neuronal hippocampal slice culture (OHSCs). Based on these facts, we analyzed the amyloid profile by focusing on APP metabolism and on glial cell activity. In contrary to our hypothesis, we highlighted whether PD1 exhibits potential anti-inflammatory properties (i.e. IL-1β) both in vitro and in vivo. The IL-1β pathway is more and more linked in the AD pathogen which leads us to consider that PD1 could have a dual effect : alzheimerogenic pharmacological tool or potential drug candidate for the treatment of AD ?

Maladie d’Alzheimer

Modèles

Dérivés puriques

Signalisation de l’IL-1β

Alzheimer's disease

Models

Purine derivatives

IL-1β pathway

Role ventrálního hipokampu a mediální prefrontální kůry v behaviorální flexibilitě u hlodavců / Role of ventral hippocampus and medial prefrontal cortex in behavioral flexibility in rodents

Černotová, Daniela

January 2020

Behavioral adaptation to a continuously changing environment is critical for the survival of the animals, but also day-to-day interactions in the human world. The main components maintaining flexibility in cognition and behavior are well-established and depend mostly on proper intercommunication within the prefrontal cortex (PFC) and striatum. Some parts of the PFC are densely innervated by the ventral hippocampus (vHPC), which has a great impact on its functioning. Also, hippocampal-prefrontal circuit dysfunction has been shown to disrupt the integrity of flexible cognition in some neuropsychiatric diseases. Therefore, the exact functional role of this pathway is an indispensable part of the research. The aim of this study was to test the role of the vHPC and the medial PFC (mPFC) in an active place avoidance task on a rotating arena in 1) two flexibility task variants - reversal learning and set- shifting - and 2) the spatial memory retrieval. We inactivated these structures by muscimol (GABAA receptor agonist) in a variety of unilateral, bilateral, and combined local injections. Disrupted performance was apparent in reversal learning in vHPC-inactivated rats. No effect was seen in mPFC-inactivated rats. Impairments after the task acquisition were observed in bilateral vHPC and mPFC inactivations...

The identification of compounds from apples that regulate adult hippocampal neurogenesis

Ichwan, Muhammad

23 March 2016

The high composition of fruits and vegetables in the daily diet is associated with cognitive well-being, especially in the elderly population. The phytonutrients are shown to have effects as antioxidants that neutralize oxidative stressors and can interact with molecular pathways to signal neuron survival. Adult hippocampal neurogenesis is a dynamic lifelong process of generating functional newborn neurons in the granular layer of the dentate gyrus from adult precursor cells. This process contributes to brain plasticity and plays a role in learning and memory. External stimuli such as environmental enrichment and physical activity are known to positively regulate this process. However, the role of nutrition and whether nutritional compounds have pro-neurogenic effects on adult hippocampal precursor cells are still elusive. In this study, I investigated the impact of dietary compounds in apples, a significant source of phytonutrients in our food, on adult hippocampal neurogenesis. I demonstrated that quercetin, the most abundant polyphenol in apple, induces cell cycle exit and differentiation of adult hippocampal precursor cells in monolayer culture. Furthermore, this compound also increases the number of surviving cells upon differentiation in vitro, through the activation of endogenous antioxidants in the Nrf2-Keap1 pathway and the prosurvival Akt pathway. Quercetin supplementation in vivo is also shown to significantly increase the number of surviving cells and new neurons in the dentate gyrus. To search for other potential active compounds in apple, I performed bioassay-guided fractionation whereby the flesh extract from apples of the Pinova cultivar was subjected to liquid- and solid phase separation and the active fraction was determined using primary neurosphere assays using cells derived from adult mouse dentate gyrus. Using mass spectometry, we revealed that the active compounds in the apple flesh extract are dihydroxybenzoate glycosides, which are non-flavonoid benzoic acid derivatives. I also confirmed that the isomers of these compounds; 2,3- and 3,5 dihydroxybenzoic acids significantly increase the number of neurospheres. Interestingly, 3,5 dihdroxybenzoic acid is an agonist of lactate receptor hydroxycarboxylic acid receptor 1 (HCAR1), with an even higher affinity than lactate. This receptor is suggested to mediate neurotrophic actions such as increasing production and release of BDNF. I also demonstrated for the first time that this receptor is presence in adult hippocampal precursor cells. To observe whether customary fruits or fruit-related products consumption affects adult hippocampal neurogenesis, I performed an experiment giving apple juice supplementation ad libitum to mice. I did not find a significant increase in net neurogenesis or the performance in the Morris water maze after apple juice supplementation. This is likely due to the low concentration of active compounds in apple juice failing to reach an effective concentration in the body. I conclude that apples provide potential proneurogenic compounds that can influence adult hippocampal neurogenesis through the activation of endogenous antioxidant mechanisms and molecular pathways for cell survival. Further studies are necessary to investigate the role of HCAR1 activation on adult hippocampal neurogenesis, which is a potential new mechanism to explain the health benefits of fruit and vegetable consumption. / Eine Ernährung die täglich reich an Obst und Gemüse ist, hat insbesondere bei älteren Menschen einen positiven Einfluss auf kognitive Fähigkeiten. Pflanzeninhaltsstoffe wirken als natürliche Antioxidantien, indem sie oxidative Stressoren neutralisieren. Weiterhin beeinflussen pflanzliche Nährstoffe molekulare Signalwege welche beim Überleben von Neuronen eine Rolle spielen. Die adulte hippocampale Neurogenese ist ein dynamischer, lebenslanger Prozess, bei dem aus Vorläuferzellen funktionelle neue Neuronen in der Körnerzellschicht des Gyrus dentatus gebildet werden. Dieser Prozess trägt zur Plastizität des Gehirns bei und spielt eine bedeutende Rolle beim Lernen und für das Gedächtnis. Externe Stimuli wie zum Beispiel eine reizreiche Umgebung und körperliche Aktivität wirken als positive Regulatoren und begünstigen die adulte hippocampale Neurogenese. Welche Rolle die Ernährung dabei spielt und ob Nahrungsbestandteile einen proneurogenen Effekt auf adulte hippocampale Vorläuferzellen haben ist kaum bekannt. In diesem Projekt habe ich den Effekt von Nahrungsbestandteilen aus Äpfeln, welche eine bedeutende Quelle von pflanzlichen Nährstoffen in unserer Ernährung darstellen, auf die adulte hippocampale Neurogenese untersucht. Ich habe gezeigt, dass Querzetin, das am reichlichsten in Äpfeln enthaltende Polyphenol, in der Monolayer-Zellkultur den Austritt aus dem Zellzyklus induziert und die Differenzierung von adulten hippocampalen Vorläuferzellen fördert. Des Weiteren steigert Querzetin nach der Differenzierung in vitro die Anzahl an überlebenden Zellen. Dies geschieht durch die Aktivierung von endogenen Antioxidantien des Nrf2-Keap1-Signalweges und des für das Überleben von Zellen förderlichen Akt-Signalweges. Die Verabreichung von Querzetin in vivo als Nahrungsergänzungsmittel führte ebenfalls zu einem signifikanten Anstieg der Anzahl an überlebenden Zellen und neu gebildeten Nervenzellen im Gyrus dentatus. Um weitere potentiell aktive Wirkstoffe von Äpfeln zu bestimmen, habe ich eine Bioassay-ausgerichtete Fraktionierung durchgeführt, wobei der Fruchtfleischextrakt von Äpfeln der Sorte Pinova einer Fest-/ Flüssig-Separation unterzogen wurde. Die aktive Fraktion wurde anhand der primären Neurosphäre-Assay-Methode mit Zellen aus dem Gyrus dentatus adulter Mäuse ermittelt. Mittels spektrometrischer Analyse habe ich gezeigt, dass die aktiven Wirkstoffe im Fruchtfleischextrakt von Äpfeln zur Gruppe der Dihydroxybenzol-Glykosiden gehören, welche den nicht-flavonoiden Benzoesäure-Derivaten zuzuordnen sind. Im in vitro Neurosphäre-Assay habe ich zudem gezeigt, dass die Isomere dieser Wirkstoffe, die 2,3- und die 3,5-Dihydroxybenzoesäuren, die Anzahl der Neurosphären signifikant erhöhen. Interessanterweise ist die 3,5-Dihydroxybenzoesäure ein Agonist des Laktatrezeptors Hydroxycarboxylic acid receptor 1 (HCAR1) und weist sogar eine noch höhere Affinität als Laktat auf. Es wird suggeriert, dass dieser Rezeptor neurotrophische Wirkungen vermittelt, wie zum Beispiel eine erhöhte Produktion von BDNF und dessen Ausschüttung. Zudem habe ich das Vorkommen dieses Reporters erstmalig bei adulten hippocampalen Vorläuferzellen nachgewiesen. Um zu untersuchen, ob der Konsum handelsüblicher Obstprodukte die adulte hippocampale Neurogenese beeinflusst, habe ich Mäusen Apfelsaft ad libitum verabreicht. Nach der Gabe von Apfelsaft sah ich keinen signifikanten Anstieg der Gesamtneurogenese und keine Verbesserung der Leistungsfähigkeit im Morris-Wasserlabyrinth-Test. Dies ist bedingt durch eine zu geringe Konzentration der aktiven Wirkstoffe im Apfelsaft wodurch die wirksame Konzentration im Körper nicht erreicht wird. Ich schlussfolgere, dass in Äpfeln potentielle pro-neurogene Inhaltsstoffe enthalten sind, welche die adulte hippocampale Neurogenese beeinflussen. Dies wird insbesondere durch die Aktivierung endogener antioxidativer Mechanismen und molekularer Signalwege vermittelt, die für das Überleben von Zellen von Bedeutung sind. Weitere Studien sind nötig, um zu bestimmen wie sich die Aktivierung von HCAR1 auf die adulte hippocampale Neurogenese auswirkt. Dies stellt einen potentiellen neuen Wirkmechanismus dar, welcher die gesundheitlichen Vorteile von Obst- und Gemüsekonsum belegt.

info:eu-repo/classification/ddc/610

ddc:610

Quantitative analysis of neuropathological alterations in two transgenic mouse models of Alzheimer's disease

Kurdakova, Anastasiia

23 November 2016

No description available.

610

Alzheimer's disease

transgenic mouse model

Tg4-42

5XFAD

Hippocampal neuron loss

Neurodegeneration

Amyloid

Axonal degeneration

Physical and cognitive activity

Environmental enrichment

Stereology

Gene dosage

Medizin (PPN619874732)

Neuroprotective Effect Of Thyrotropin-Releasing Hormone (TRH) Against Glutamate Toxicity In Vitro

Yard, Michael

13 November 2009

Indiana University-Purdue University Indianapolis (IUPUI) / Acute and chronic activation of both ionotropic and metabotropic glutamate (glut) receptors is implicated in many neurodegenerative disorders including AD, dementia, epilepsy, stroke and neurotrauma. TRH and glut receptors (ionotropic & metabotropic) receptors are differentially coexpressed in granule and pyramidal neurons of the hippocampus. The author shows TRH to be protective when added to cultured pituitary adenoma (GH-3) cells and neuron-like pheochromocytoma (PC12) cells either prior to, during, or after glut-induced toxicity (Endo. Soc. Abs. 01), and also shows that the possible neuroprotective mechanism may involve heterologous downregulation of the metabotropic glut receptors, using superfused hippocampal slices and noting a reduction of Gαq/11 (SFN Abs. 02). He has also demonstrated that TRH protected against glut toxicity in fetal cortical cultures (Endo. Soc. Abs. 04). To extend these studies he used 14-day cultured rat fetal hippocampal neurons (Day E17) to determine if TRH is protective against toxicity induced by specific ionotropic and metabotropic glut agonists. Neuronal viability and integrity were assessed by trypan blue exclusion and LDH release after 18 hrs following 30 min exposure to glut agonists. Ten µM dihydroxyphenylglycine (DHPG, a Group 1 receptor agonist) + 30 µM N-methyl-D-aspartate (NMDA)-induced toxicity (42% vs contr. P<0.05); whereas, concurrent and continued treatment with 10 uM but not 1uM 3Me-HTRH resulted in less neuronal death and damage (86% vs contr P<0.05; 53% vs contr. P>0.05) respectively. DHPG treatment alone (10 µM) for 30 min. was non-toxic by both criteria (90% vs contr. P<0.05). The data suggest that TRH may be a selective modulator of glut-induced toxicity.

Heterologous Receptor Downregulation

PC12 Cell Culture

GH-3 Cell Culture

G alpha q/11

Hippocampal Slice Superfusion

TRH

Neuroprotection

Cell culture

Thyrotropin releasing factor

Glutamic acid

Nicotine Use in Schizophrenia: a part of the cure or the disease?

Berg, Sarah A.

16 March 2012

Indiana University-Purdue University Indianapolis (IUPUI) / Nicotine use among individuals with schizophrenia occurs at extremely high rates. The prevailing theory is that individuals with schizophrenia smoke as a form of self-medication to ameliorate sensory and cognitive deficits. However, these individuals also have enhanced rates of addiction to several drugs of abuse and may therefore smoke as a result of enhanced addiction liability. The experiments described herein explored these two hypotheses by assessing the effect that nicotine has on working memory, addiction vulnerability (locomotor sensitization and self-administration), and nicotinic acetylcholine receptor (nAChR) expression as well as the developmental expression of these characteristics in the neonatal ventral hippocampal (NVHL) neurodevelopmental animal model of schizophrenia. The results from these studies indicate that NVHLs had working memory impairments in both adolescence and adulthood, with nicotine having a negligible effect. Additionally, NVHLs displayed enhanced locomotor sensitization to nicotine which emerged in adulthood as well as an enhanced acquisition of nicotine self-administration, administering more nicotine overall. These behavioral differences cannot be attributed to nAChR expression as nicotine upregulated nAChR to a similar extent between NVHL and SHAM control animals. These data indicate that the enhanced rates of nicotine use among individuals with schizophrenia may occur as a result of an enhanced vulnerability to nicotine addiction.

dual diagnosis

nicotine self-administration

radial arm maze

locomotor sensitization

schizophrenia

neonatal ventral hippocampal lesion

addiction

nicotinic acetylcholine receptor

Schizophrenics

Nicotine addiction

Nicotinic receptors