Global ETD Search

71	Adult Hippocampal Neurogenesis and Memory Enhancement Stone, Scellig S. D. 31 August 2012 (has links) Hippocampal neurogenesis continues throughout life in mammals. These adult-generated dentate granule cells (DGCs) are generally believed to contribute to hippocampal memory processing and are generated at varying rates in response to neuronal network activity. Deep brain stimulation (DBS) allows clinicians to influence brain activity for therapeutic purposes and raises the possibility of targeted modulation of adult hippocampal neurogenesis. It has recently been shown that DBS may ameliorate cognitive decline associated with Alzheimer’s disease (AD), and while underlying mechanisms are unknown, one possibility is activity-dependent regulation of hippocampal neurogenesis. To this end, whether or not adult-generated DGCs can assume functional roles of developmentally-generated neurons, and stimulation-induced enhanced neurogenesis can benefit memory function in the normal and diseased brain, warrant study. First, we examined separate cohorts of developmentally- and adult-generated DGCs in intact mice and demonstrated similar rates of activation during hippocampus-dependent spatial memory processing, suggesting functional equivalence. Second, we examined the neurogenic and cognitive effects of targeted entorhinal cortex (EC) stimulation in mice using parameters analogous to clinical high frequency DBS. Stimulation increased the generation of DGCs. Moreover, stimulation-induced neurons were functionally recruited by hippocampal spatial memory processing in a cell age-dependent fashion that is consistent with DGC maturation. Importantly, stimulation facilitated spatial memory in the same maturation-dependent manner, and not when stimulation-induced promotion of adult neurogenesis was blocked, suggesting a causal relationship. Finally, we are in the process of testing whether similar stimulation facilitates spatial memory in a transgenic (Tg) disease model of AD that exhibits amyloid neuropathology and cognitive impairment. Preliminary results suggest stimulation promotes neurogenesis and rescues impaired spatial memory in Tg animals. When considered in the context of promising clinical results, this body of work suggests stimulation-induced neurogenesis could provide a novel therapeutic modality in settings where functional hippocampal regenerative therapy is desirable. neurogenesis memory hippocampus deep brain stimulation dentate gyrus adult hippocampal neurogenesis granule cell learning 0317
72	Erythropoietin as a driver of neurodifferentiation, neuroplasticity and cognition – A continuum view of the neuronal lineage Wakhloo, Debia Rajnath 19 November 2019 (has links) No description available. 570 Erythropoietin Neurogenesis Hippocampus Adult hippocampal neurogenesis cognition Hypoxia Biologie (PPN619462639)
73	LRP2 promotes adult neurogenesis through suppression of BMP signaling in the subventricular zone Gajera, Chandresh Ravjibhai 28 April 2010 (has links) LRP2/Megalin ist ein Rezeptor der LDL-Rezeptor Genfamilie mit essentieller Funktion in der Entwicklung des Zentralnervensystems. Der Rezeptor wird im Neuroepithel des Embryos exprimiert und steuert die Ausbildung der Vorderhirnstrukturen. In weiteren Untersuchungen an LRP2-defizienten Mäusen konnte ich zeigen, dass der Verlust der Expression des Rezeptors in adulten Tieren zu einer Beeinträchtigung der Proliferation neuronaler Vorläuferzellen in der subventrikulären Zone (SVZ) des lateralen Ventrikels führt. Infolgedessen war die Anzahl der Neuroblasten reduziert, die zum olfaktorischen Bulbus wandern und dort zu Interneuronen differenzieren. Anhand immunhistologischer Untersuchungen konnte ich nachweisen, dass der Verlust von LRP2 zu einer verminderten Anzahl GFAP-positiver Zellen, die auch die neuronalen Stammzellen (Typ B Zellen) umfassen, führt. Weiterhin wiesen LRP2 Mutanten eine Reduktion in den Signalen für Nestin, DLX2, PSA-NCAM und DCX. Meine derzeitige Hypothese besagt daher, dass LRP2 ebenso wie im embryonalen Neuroepithel auch in der adulten neuronalen Stammzellnische eine Rolle bei der Regulation der BMP4 Signalwege spielt. Dies wird möglicherweise durch Endozytose-vermittelte Aufnahme mit anschließendem Abbau des Morphogens durch LRP2 vermittelt, wie es bereits in vitro gezeigt werden konnte. BMP4 hat im Wesentlichen eine anti-proliferative Wirkung. Eine exakt gesteuerte Regulation der Konzentration dieses Morphogens ist daher eine Vorraussetzung für ein Neurogenese-permissives Milieu in der adulten neurogenen Stammzellnische. Die Ergebnisse meiner Arbeit entschlüsseln eine neue Rolle von LRP2 in der adulten Neurogenese. Die Expression des Rezeptors im Ependym des lateralen Ventrikels ist essentiell für die Regulation der BMP Signalwege in der neurogenen Stammzellnische. / LRP2 (also know as megalin) is a member of the low-density lipoprotein receptor gene family that plays an important role in regulation of neurogenesis in the embryonic neural tube. During early forebrain development, LRP2 deficiency leads to an increase in bone morphogenetic protein 4 (Bmp4) expression and signalling in the dorsal neuroepithelium, and a loss of sonic hedgehog (Shh) expression in the ventral forebrain. In this thesis I demonstrate that LRP2 is expressed in ependymal cells of the lateral ventricles in the adult brain. Intriguingly, expression is restricted to the ependyma that faces the stem cell niche. Expression is not seen in ependyma elsewhere in the lateral ventricles or in the dentate gyrus, the second neurogenic zone of the adult mouse brain. I further show that lack of LRP2 expression in adult mice results in impaired proliferation of neural precursor cells in the SVZ resulting in a decreased number of neuroblasts reaching the olfactory bulb. Using immunohistological detection of marker proteins, absence of LRP2 was shown mainly to affect the GFAP-positive neuronal precursor cell population in the SVZ (B cells). Furthermore, Lrp2 mutant mice also showed a decrease in the signals for nestin, DLX2, PSA-NCAM and DCX. Reduced neurogenesis in the SVZ in LRP2-deficient mice coincides with a significant increase in BMP2/4 expression and enhanced activation of downstream mediators Phospho-SMAD1/5/8 and ID3 in the stem cell niche. My findings revealed a novel regulatory pathway whereby LRP2 down-regulates BMP signaling to modulate the instructive microenvironment of the SVZ and to enable adult neurogenesis to proceed. Thus, LRP2 plays a crucial role in regulating BMP-signaling levels in the adult SVZ, highlighting the unique role of ependymal cells in this stem cell niche. The underlying mechanism of LRP2 action in control of neurogenesis may thus be conserved between the embryonic and adult brain. LRP2 neurogenesis BMP SVZ neurogenesis LRP2 BMP SVZ 570 Biologie 32 Biologie WW 2200 ddc:570
74	Neuronal Survival of the Fittest: The Importance of Aerobic Capacity in Exercise-Induced Neurogenesis and Cognition Tognoni, Christina Maria January 2014 (has links) <p>It is commonly accepted that aerobic exercise increases hippocampal neurogenesis, learning and memory, as well as stress resiliency. However, human populations are widely variable in their inherent aerobic fitness as well as their capacity to show increased aerobic fitness following a period of regimented exercise. It is unclear whether these inherent or acquired components of aerobic fitness play a role in neurocognition. To isolate the potential role of inherent aerobic fitness, we exploited a rat model of high (HCR) and low (LCR) inherent aerobic capacity for running. At a baseline, HCR rats have two- to three-fold higher aerobic capacity than LCR rats. We found that HCR rats also had two- to three- fold more young neurons in the hippocampus than LCR rats as well as rats from the heterogeneous founder population. We then asked whether this enhanced neurogenesis translates to enhanced hippocampal cognition, as is typically seen in exercise-trained animals. Compared to LCR rats, HCR rats performed with high accuracy on tasks designed to test neurogenesis-dependent pattern separation ability by examining investigatory behavior between very similar objects or locations. To investigate whether an aerobic response to exercise is required for exercise-induced changes in neurogenesis and cognition, we utilized a rat model of high (HRT) and low (LRT) aerobic response to treadmill training. At a baseline, HRT and LRT rats have comparable aerobic capacity as measured by a standard treadmill fit test, yet after a standardized training regimen, HRT but not LRT rats robustly increase their aerobic capacity for running. We found that sedentary LRT and HRT rats had equivalent levels of hippocampal neurogenesis, but only HRT rats had an elevation in the number of young neurons in the hippocampus following training, which was positively correlated with accuracy on pattern separation tasks. Taken together, these data suggest that a significant elevation in aerobic capacity is necessary for exercise-induced hippocampal neurogenesis and hippocampal neurogenesis-dependent learning and memory. To investigate the potential for high aerobic capacity to be neuroprotective, doxorubicin chemotherapy was administered to LCR and HCR rats. While doxorubicin induces a progressive decrease in aerobic capacity as well as neurogenesis, HCR rats remain at higher levels on those measures compared to even saline-treated LCR rats. HCR and LCR rats that received exercise training throughout doxorubicin treatment demonstrated positive effects of exercise on aerobic capacity and neurogenesis, regardless of inherent aerobic capacity. Overall, these findings demonstrate that inherent and acquired components of aerobic fitness play a crucial role not only in the cardiorespiratory system but also the fitness of the brain.</p> / Dissertation Neurosciences aerobic capacity exercise neurogenesis neuroprotection pattern separation
75	Novel Roles for Fragile X Protein in Neurogenesis Callan, Matthew Aron January 2011 (has links) Fragile X Syndrome (FXS) is the most common form of inherited mental retardation, affecting approximately 1/4000 males and 1/6000 females worldwide. FXS is caused by loss of FMR1 gene expression, resulting in the lack of the protein product, Fragile X protein (FMRP). FMRP is an RNA-binding protein thought to regulate synaptic plasticity by controlling the localization and translation of specific mRNAs in neurons. To determine whether FMRP is also required in early brain development we examined the distribution of cell cycle markers in Drosophila FMR1 (dFmr1) mutant brains compared to wild-type brains. Our results indicate that the loss of dFmr1 leads to a significant increase in the number of mitotic neuroblasts and BrdU incorporation in the brain, consistent with the notion that FMRP controls proliferation in neural stem cells. To determine the role of FMRP in neuroblast division and differentiation, we used Mosaic Analysis with a Repressible Marker (MARCM) approaches in the developing larval brain and found that single dFmr1 neuroblasts generate significantly more neurons than controls. Developmental studies suggest that FMRP also inhibits neuroblast exit from quiescence, or reactivation, in early larval brains, as indicated by misexpression of the G1 to S phase transition marker Cyclin E. We have also identified a novel role for FMRP in the glia surrounding the neuroblasts, indicating that FMRP in these cells contributes to the regulation of neuroblast reactivation via signaling from the supporting glial cells. Our results demonstrate that FMRP is required during brain development to control the exit from quiescence and proliferative capacity of neuroblasts as well as neuron production, which may provide insights into Fragile X Syndrome and other Autism-Spectrum disorders. Autism Spectrum Fragile X Glia Neural Stem Cell Neurogenesis
76	Social Regulation of Adult Neurogenesis in a Eusocial Mammal Peragine, Diana 09 December 2013 (has links) The present study examined social status and adult neurogenesis in the naked mole rat. These animals live in large colonies with a strict reproductive dominance hierarchy; one female and 1-3 males breed, while other members are subordinate and reproductively suppressed. We examined whether social status affects doublecortin (DCX; a marker for immature neurons) immunoreactivity in the dentate gyrus, piriform cortex (PCx), and basolateral amygdala (BLA) by comparing breeders to subordinates. We also examined subordinates removed from their colony and paired with opposite- or same-sex conspecifics for 6 months. Breeders had reduced DCX immunoreactivity in all areas, with BLA effects confined to females. Effects of housing condition were region-specific, with higher PCx DCX immunoreactivity observed in opposite- than same-sex paired subordinates regardless of gonadal status. The opposite pattern was observed in the BLA. Future work will clarify whether findings are attributable to status differences in stress, behavioural plasticity, or life stage. basolateral amygdala eusociality hippocampus neurogenesis social behaviour piriform cortex 0349
77	A comparative study of neocortical development between humans and great apes Badsha, Farhath 29 May 2017 (has links) (PDF) The neocortex is the most recently evolved part of the mammalian brain which is involved in a repertoire of higher order brain functions, including those that separate humans from other animals. Humans have evolved an expanded neocortex over the course of evolution through a massive increase in neuron number (compared to our close relatives-‐‑ the chimpanzees) in spite of sharing similar gestation time frames. So what do humans do differently compared to chimpanzees within the same time frame during their development? This dissertation addresses this question by comparing the developmental progression of neurogenesis between humans and chimpanzees using cerebral organoids as the model system. The usage of cerebral organoids, has enabled us to compare the development of both the human neocortex, and the chimpanzee neocortex from the very initiation of the neural phase of embryogenesis until very long periods of time. The results obtained so far suggest that the genetic programs underlying the development of the chimpanzee neocortex and the human neocortex are not very different, but rather the difference lies in the timing of the developmental progression. These results show that the chimpanzee neocortex spends lesser time in its proliferation phase, and allots lesser time to the generation of its neurons than the human neocortex. In more scientific terms, the neurogenic phase of the neocortex is shorter in chimpanzees than it is in humans. This conclusion is supported by (1) an earlier onset of gliogenesis in chimpanzees compared to humans which is indicative of a declining neurogenic phase, (2) an earlier increase in the chimpanzee neurogenic progenitors during development, compared to humans, (3) a higher number of stem cell– like progenitors in human cortices compared to chimpanzees, (4) a decline in neurogenic areas within the chimpanzee cerebral organoids over time compared to human cerebral organoids. humans apes glia progenitors Organoids neurogenesis ddc:570 rvk:WW 2400
78	Modulation de la neurogénèse par la glycine Côté, Sébastien 11 1900 (has links) Les vertébrés, du poisson à l'homme, possèdent un potentiel membranaire médié en partie par les ions chlorure (Cl-). L’une des premières formes d’activité neuronale lors du développement est la dépolarisation médiée par les ions chlorures extrudés par les canaux glycinergiques (GlyR) et GABAergiques. Cette dépolarisation est rendu possible grâce à l’expression retardée du co-transporteur d’ions chlorure et de potassium KCC2 lors du développement qui génère un gradient hyperpolarisant postnatalement chez les mammifères. Le rôle de cette dépolarisation précoce paradoxale durant le développement est inconnu. En injectant l’ARNm de KCC2 dans des embryons de poissons zébrés nouvellement fertilisé, nous avons devancé l’expression de ce co-transporteur rendant ainsi la glycine hyperpolarisante dans tous les neurones dès les premières phases du développement. Nous avons aussi ciblé le récepteur glycinergique directement en bloquant son activité et son expression à l’aide d’une drogue spécifique, la strychnine et d’un morpholino antisens (Knockdown). Dans les trois cas (KCC2, strychnine et GlyR KD), les perturbations de l’activité neuronale ont provoqués des erreurs dans la neurogenèse, en particulier une diminution du nombre d’interneurones sans avoir d’effets sur les motoneurones et les neurones sensoriels. De plus, en bloquant les canaux calciques activés à bas voltage dans le développement avec la drogue nifedipine, il y a des erreurs dans la neurogénèse semblables à celles remarquées dans les trois conditions précédentes. Nous concluons que la dépolarisation précoce par la glycine permet l’entrée du calcium et l’activation de la neurogénèse chez les interneurones. / Vertebrates, from fish to man, have a membrane potential mediated in part by chloride ions (Cl-). One of the first neuronal activity during development of the zebrafish spinal cord is cell depolarisation mediated by chloride extrusion via glycinergic receptors (GlyRs) and GABAergic receptors. This depolarisation is due to the absence of chloride-potassium cotransport channel KCC2, whose expression comes later in development, creating a hyperpolarising gradient. The role of this paradoxal depolarisation period during early stages of development is still unknown. By injecting KCC2 mRNA in newly fertilised zebrafish embryos, we expressed this co-transporter channel in neurons causing glycine to hyperpolarize in early phases of development. We also directly targeted the glycine receptor (GlyR) itself by blocking its activation with a chronic treatment of Strychnine, a specific drug, and by knocking down the expression of this receptor with an antisense morpholino injection. In those three conditions (KCC2, Strychnine and GlyR KD), perturbation of neuronal activity provoked major defects in neurogenesis, particulary in development of interneurons, without affecting other types of cells like motoneurons and sensory neurons. In addition, blocking low-voltage activated calcium channels with nifedipine provoked similar phenotypes. We conclude that the early glycine-mediated depolarisation allow calcium entry, thus activating certain aspects of interneurons neurogenesis. Neurogénèse Glycine Neurogenesis Glycine
79	FOOD FOR BURNOUT PATIENTS : A Systematic Review of the Efficacy of Dietary Polyphenols on Neurogenesis Redgård, Nicklas January 2019 (has links) Stress-related psychological ill health has increased dramatically in Europe. A diagnosis equivalent to occupational burnout can be found in the Swedish version of the tenth edition of the “International Statistical Classification of Diseases and Related Health Problems" by the World Health Organization. The Swedish National Board of Health and Welfare lists treatment suggestions including a section of self-care that recommended something that could be translated to “a sensible diet” (“vettig kost”) without providing evidence for what could constitute a sensible diet. By using the hypothesis of burnout being a stress-mediated decrease in neurogenesis which in turn decrease the ability to cope with stress, this article systematically reviews the efficacy of dietary polyphenols on neurogenesis in rodents to evaluate if dietary polyphenols could constitute a part of a sensible diet for burnout patients. Dietary polyphenols significantly increased various parts of neurogenesis, in rodents subjected to stressors, in some cases demonstrating effect sizes comparable to antidepressants. Adverse effects have been observed in extremely high doses and young rodents not exposed to induced stressors with a putative high level of neurogenesis. dietary polyphenols neurogenesis burnout curcumin EGCG resveratrol Neurosciences Neurovetenskaper
80	Avaliação da neuroplasticidade em modelos experimentais de epilepsia do lobo temporal / Evaluation of neuroplasticity in experimental models of temporal lobe epilepsy Santos, Victor Rodrigues 22 August 2011 (has links) As epilepsias acometem entre 1-2% da população mundial. De um modo geral, de todas as epilepsias quase um terço deste total de pacientes apresenta a síndrome epiléptica conhecida como Epilepsia de Lobo Temporal (ELT), a qual se instala geralmente após um insulto inicial ou em decorrência de outras patologias como, por exemplo, trauma ou tumor, e parece ser decorrente de anormalidades intrínsecas do lobo temporal tais como, amígdala, hipocampo e córtex piriforme. Depois de um período de latência variado, promove o surgimento de crises convulsivas. Dentre os pacientes que apresentam ELT, cerca de 20 a 30% deles apresentam resistência ao tratamento farmacológico. Para melhor estudar os processos plásticos envolvidos no processo de epileptogênese ocorridos após a instalação do insulto inicial que levam ao aparecimento de crises recorrentes espontâneas, ratos Wistar foram eletricamente estimulados na amígdala para indução de Status Epilepticus (SE). Foram feitas histoquímicas e immunohistoquímica para marcar neurônios ativados (c-Fos+), novos neurônios (Doublecortin DCX+) e em degeneração (FluoroJade C - FJC+) após as crises. Após a indução do SE observamos que quanto mais graves as crises, maior o número de áreas ativadas (c-Fos+) e maior número de neurônios em degeneração (FJC+). Além disso, não houve associação direta entre as áreas cerebrais ativadas e grau de neurodegeneração, nem associação entre gravidade do SE e intensidade de neurogênese (DCX). A segunda fase deste projeto, executada na University of Cincinnati, refere-se ao estudo do impacto do SE, induzido por pilocarpina (PILO) sistêmica, sobre a neurogênese hipocampal. Utilizando a injeção de BrdU, para marcar o dia do nascimento de novos neurônios granulares, em camundongos Thy1-GFP foram submetidos ao SE por PILO. Foram analisadas a plasticidade dendrítica de neurônios granulares em fase de maturação (imaturas, 1 semana) e maduras (8 semanas). As células imaturas sofreram drásticas modificações na sua morfologia e na densidade dendrítica. Por outro lado, as células maturas não sofreram alterações morfológicas na árvore dendrítica, mas apresentaram uma intensa redução na densidade dos espinhos dendríticos, mostrando assim que as células imaturas estão mais suceptíveis ao impacto das crises epilépticas. / The epilepsies affect between 1-2% of the world. In general, all epilepsies almost a third of total patients had an epilepsy syndrome known as temporal lobe epilepsy (TLE), which usually settles after the initial insult or due to other pathologies such as, for example, trauma or tumor, and seems to be due to intrinsic abnormalities such as temporal lobe, amygdala, hippocampus and piriform cortex. After latency period varied, promotes the emergence of seizures. Among the patients with TLE, about 20 to 30% of them are resistant to pharmacological treatment. To better study the processes involved in plastic epileptogenesis occurred after the installation of the initial insult leading to the appearance of spontaneous recurrent seizures, rats were electrically stimulated in the amygdala to induce status epilepticus (SE). Histochemical and immunohistochemistry were done to mark neurons activated (c-Fos +), newborn neurons (Doublecortin - DCX+) and degenerating (FluoroJade C - FJC+) after the crisis. After SE induction observed that the more serious crises, the greater the number of activated areas (c-Fos+) and greater number of degenerating neurons (FJC+). In addition, there was no direct association between the brain areas activated and the degree of neurodegeneration, or association between the severity and intensity of the SE of neurogenesis (DCX+). The second phase of this project, performed at the University of Cincinnati, refers to study the impact of SE induced by pilocarpine (Pilo) system on hippocampal neurogenesis. Using the injection of BrdU, to label the daybirth of new granule neurons in Thy1-GFP mice subjected to SE. We analyzed the dendritic plasticity of granule neurons undergoing maturation (immature, 1 week) and mature (8 weeks). The immature cells have undergone drastic changes in their dendritic morphology and density. On the other hand, the mature cells did not undergo morphological changes in dendritic tree but showed a marked decrease in the density of dendritic spines, thus showing that immature cells are more susceptible to the impact of epileptic seizures. ELT Neurodegeneração Neurodegeneration Neurogênese Neurogenesis Neuroplasticidade Neuroplasticity TLE

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