Global ETD Search

11	Ablation of Progenitor Cells Does Not Impede Motor Recovery or Diminish Cognitive Function Following a Focal Cortical Stroke Lee, Karah S.H. January 2016 (has links) Following a stroke there is a significant increase in the number and migration of progenitor cells (PCs) to the infarct, and positive correlations between neurogenesis and recovery. Loss-of-function studies have conflicting findings on whether the ablation of PCs impedes motor or cognitive function post-stroke. This thesis examines if neurogenesis per se is required for motor recovery and spatial learning and memory. PCs were ablated in an adult GFAP-TK rat model that allows for the inducible deletion of GFAP-expressing PCs in the brain. An endothelin-1 (ET-1) stroke was produced and assessment of motor function and spatial learning and memory revealed no differences between control and GFAP-TK rats in which PCs were ablated. This study is the first to use a focal cortical stroke model in a rat to study PCs and stroke recovery, and suggest that PCs and their progeny are dispensable for motor recovery and spatial learning and memory post-stroke. Adult neurogenesis Stroke Transgenic Rat
12	Regulation of Adult Hippocampal Neurogenesis: Insights from Mouse Models of Dementia and Depression Donovan, Michael H. January 2008 (has links) Dissertation (Ph.D.) -- University of Texas Southwestern Medical Center at Dallas, 2008. / Vita. Bibliography: p.149-164
13	The role of adult neurogenesis and oligodendrogenesis in age-related cognitive decline in the non-human primate Heyworth, Nadine 15 June 2016 (has links) Cognitive aging is a biological process characterized by physical changes in the brain and subsequent alterations in cognitive function. While neurodegenerative diseases result in extensive neuronal death and anatomical abnormalities, normal aging has subtle changes resulting in a range of cognitive abilities. Early studies of cognitive aging focused on changes in the neuronal population, but evidence has demonstrated that forebrain neurons are largely preserved with age. Furthermore, the proliferation of new neurons in the adult brain has generated great speculation regarding the role and contribution of new neurons to cognitive function. Conversely, both imaging and ultrastructural analyses have shown that age-related alterations in white matter and myelin are good predictors of cognitive impairment, suggesting that alterations in connectivity between brain regions may result in cognitive decline. In this dissertation, a rhesus monkey model of normal aging was used to assess the contribution of adult-neurogenesis and oligodendrogenesis to cognitive function. First, cell proliferation and adult neurogenesis were assessed in the subgranular zone of the hippocampal dentate gyrus. Aged animals demonstrated a decline in proliferating cells and neurogenesis but only limited correlations with behavioral impairment. Immature neurons were also identified in temporal lobe cortices, but results indicate these immature cortical neurons are most likely not adult-generated. Moreover, despite an age-related decline in numbers, they persist throughout the lifespan and many differentiate into Calretinin neurons. Further investigation of white matter alterations used immunohistochemistry and diffusion spectrum imaging to correlate oligodendrocyte numbers with white matter connectivity. In the corpus callosum and cingulum bundle, there were no correlations with age, but cognitive impairment was associated with increased oligodendrocyte number and decreased white matter connectivity. These correlations were only present in the anterior aspect of the cingulum bundle, not the posterior cingulum suggesting differential oligodendrocyte responses along the anterior-posterior axis of the brain. Together, these data demonstrate an age-related decline in adult neurogenesis may be only a small contributor to cognitive impairment. Additionally, a reserve pool of immature neurons continues to differentiate in the temporal cortex potentially contributing to local plasticity. Furthermore, cognitive impairment rather than aging has a stronger correlation with oligodendrocytes alterations and connectivity. Neurosciences Aging Cognition Doublecortin Oligodendrogenesis Adult neurogenesis Dentate gyrus
14	Identification of Functional Roles for Pofut1 in Skeletal Muscle and Brain Kim, Mi-Lyang 16 September 2009 (has links) No description available. Molecular Biology Protein O-fucosyltransferase1 agrin adult neurogenesis adult myogenesis
15	THE EFFECT OF NICOTINE CO-ADMINISTRATION ON ALCOHOL-INDUCED REACTIVE HIPPOCAMPAL CELL PROLIFERATION DURING ABSTINENCE IN AN ADOLESCENT MODEL OF AN ALCOHOL USE DISORDER Heath, Megan 01 January 2016 (has links) A significant consequence of alcohol use disorders (AUDs) is hippocampal neurodegeneration. The hippocampus is responsible for learning and memory, and neurodegeneration in this brain region has been shown to result in cognitive deficits. Interestingly, some alcoholics demonstrate improvements in hippocampus-dependent functions, potentially due the phenomenon termed adult neurogenesis. Adult neurogenesis, the process by which neural stem cells (NSCs) proliferate, differentiate into neurons, migrate into the granule cell layer, and survive, occurs in two brain regions; however, this study examines only neurogenesis occurring in the subgranular zone of the hippocampal dentate gyrus. Four-day binge ethanol exposure in an animal model causes a decrease in neurogenesis during intoxication; however, there is a reactive increase in cell proliferation on day seven of abstinence. The purpose of this study was to determine the timing of increased cell proliferation. Furthermore, most alcoholics also smoke tobacco, and nicotine, the addictive component of tobacco, has also been shown to affect hippocampal neurogenesis. As many people initiate alcohol and tobacco use during adolescence, the second experiment herein examined the effect of nicotine coadministration on alcohol-induced reactive hippocampal cell proliferation. alcohol use disorder nicotine adult neurogenesis adolescent alcohol use hippocampal cell proliferation
16	B-cell Lymphoma-2 (Bcl-2) Is an Essential Regulator of Adult Hippocampal Neurogenesis Ceizar, Maheen 19 September 2012 (has links) Of the thousands of dividing progenitor cells (PCs) generated daily in the adult brain only a very small proportion survive to become mature neurons through the process of neurogenesis. Identification of the mechanisms that regulate cell death associated with neurogenesis would aid in harnessing the potential therapeutic value of PCs. Apoptosis, or programmed cell death, is suggested to regulate death of PCs in the adult brain as overexpression of B-cell lymphoma 2 (Bcl-2), an anti-apoptotic protein, enhances the survival of new neurons. To directly assess if Bcl-2 is a regulator of apoptosis in PCs, this study examined the outcome of removal of Bcl-2 from the developing PCs in the adult mouse brain. Retroviral mediated gene transfer of Cre into adult floxed Bcl-2 mice eliminated Bcl-2 from developing PCs and resulted in the complete absence of new neurons at 30 days post viral injection. Similarly, Bcl-2 removal through the use of nestin-induced conditional knockout mice resulted in reduced number of mature neurons. The function of Bcl-2 in the PCs was also dependent on Bcl-2-associated X (BAX) protein, as demonstrated by an increase in new neurons formed following viral-mediated removal of Bcl-2 in BAX knockout mice. Together these findings demonstrate that Bcl-2 is an essential regulator of neurogenesis in the adult hippocampus. Adult Neurogenesis Apoptosis Bcl-2 Hippocampus Transgenic Mouse Model BAX Progenitor Cells Retrovirus Inducible Knock out
17	Neurogenèse adulte hippocampique : Rôle fonctionnel dans la mémoire épisodique et recrutement des nouveaux neurones lors de la mémorisation / Adult hippocampal neurogenesis : Functional role in episodic memory and recruitment of newborn neurons during memory Gros, Alexandra 28 September 2015 (has links) La neurogenèse adulte du gyrus denté de l’hippocampe joue un rôle essentiel dans les processus mnésiques dépendants de l’hippocampe, mais son rôle dans des formes complexes de mémoire comme la mémoire épisodique n’a jamais été exploré. Le travail de cette thèse porte sur l’étude de l’implication des nouveaux neurones de l’hippocampe dans la mise en mémoire d’un souvenir épisodique à long terme. Nous avons développé une nouvelle tâche de mémoire épisodique reposant sur la présentation occasionnelle d’épisodes permettant d’encoder des informations de type « Quoi – Où – Dans quel contexte ». Nous montrons pour la première fois que les rats sont capables de se souvenir à très long terme de brefs épisodes de vie et d’utiliser cette mémoire d’une manière flexible. La caractérisation des profils de rétention permet d’accéder aux capacités individuelles de recollection des différents éléments du souvenir et montre que le rappel fiable de la mémoire épisodique nécessite l’intégrité de l’hippocampe et met en jeu un vaste réseau hippocampo-cortical dont l’activation est corrélée au rappel. Les performances de rats soumis à une irradiation focale de l’hippocampe montrent que la neurogenèse adulte hippocampique contribue de façon significative à la consolidation et au rappel fiable du souvenir épisodique. Ces résultats sont discutés dans le cadre d’une implication de la neurogenèse adulte dans la résolution de la mise en mémoire d’événements occasionnels dans le but de discriminer deux épisodes de vie proches, en lien avec les fonctions de séparation et de complétion de patterns de l’hippocampe. Par ailleurs, les mécanismes moléculaires qui sous-tendent le recrutement des nouveaux neurones lors d’un apprentissage restent inconnus. Nous avons analysé le rôle du gène immédiat précoce Zif268, acteur moléculaire essentiel dans les processus mnésiques, et montrons que ce gène joue un rôle crucial dans la sélection et le recrutement des nouveaux neurones lors de la mémorisation au cours de leur période critique d’intégration dans les réseaux neuronaux de l’hippocampe. Ce travail apporte des éléments nouveaux sur la participation des nouveaux neurones hippocampiques dans les processus mnésiques dans une situation à forte demande cognitive basée sur l’encodage d’une représentation intégrée et résolue d’événements occasionnels complexes, ainsi que sur les mécanismes qui sous-tendent leur recrutement. / Adult hippocampal neurogenesis plays a critical role in hippocampal-dependent memory, however its role in complex forms of memory such as episodic memory has not as yet been explored. The work presented in this thesis focuses on the issue of the involvement of newborn hippocampal neurons in long term episodic memory. We developed a new episodic memory task based on the presentation of occasional episodes allowing rats to encode “What – Where – In which context” information. We show for the first time that rats are able to remember on the long term brief past episodes of life and to use their episodic memory in a flexible manner. The characterization of retention profiles allows us to identify individual abilities in the recollection of the various elements of the memory and shows that episodic memory recall requires the integrity of the hippocampus and involves a hippocampo-cortical network, the activation of which correlates with recall performance. Performance of rats subjected to focal irradiation of the hippocampus shows that adult hippocampal neurogenesis contributes significantly to the consolidation and faithful recall of episodic memory. These results are discussed in the context of the implication of hippocampal newborn neurons in the resolution of memories of occasional events in order to discriminate different, but closely related episodes of life in relation to pattern separation and pattern completion functions of the hippocampus. Furthermore, the molecular mechanisms underlying the recruitment of newborn hippocampal neurons by learning remain to date unknown. We investigated the role of Zif268, an immediate early gene known to play an essential role in memory processes, and show that this gene plays a crucial role in the selection and recruitment of newborn hippocampal neurons by learning during their critical period of integration in hippocampal neural networks. Overall, this work brings new knowledge on the contribution of newborn hippocampal neurons to memory processes in a highly demanding cognitive situation based on the encoding of an integrated and high-resolution representation of complex occasional events, and on the mechanisms underlying their recruitment. Neurogenèse adulte Hippocampe Mémoire épisodique Résolution mnésique Zif268 Adult neurogenesis Hippocampus Episodic memory Memory resolution Zif268
18	The Impact of Parkinson’s Disease on Mammalian Adult Neurogenesis Bastasic, Joseph 12 September 2019 (has links) Parkinson’s disease (PD) has been reported to negatively affect adult neurogenesis. Mitochondrial dysfunction associated with PD may be involved, given that recent studies have identified mitochondria to be central regulators of neural stem cell (NSC) fate decisions. For this thesis, we sought to characterize adult neurogenesis in PINK1 and parkin knockout (KO) mouse models of PD. Immunohistochemical staining of subventricular zone (SVZ) and subgranular zone (SGZ) tissue sections from 6 month old mice was performed in order to identify and quantify changes in specific cell populations involved with adult neurogenesis. The loss of PINK1 or parkin was found to cause aberrant changes in adult neurogenesis, particularly in the SGZ. Going forward, it would be interesting to determine if the observed changes in adult neurogenesis were the result of mitochondrial dysfunction. Parkinson’s Disease Adult Neurogenesis Subventricular Zone Subgranular Zone PINK1 Parkin Mitochondria
19	B-cell Lymphoma-2 (Bcl-2) Is an Essential Regulator of Adult Hippocampal Neurogenesis Ceizar, Maheen 19 September 2012 (has links) Of the thousands of dividing progenitor cells (PCs) generated daily in the adult brain only a very small proportion survive to become mature neurons through the process of neurogenesis. Identification of the mechanisms that regulate cell death associated with neurogenesis would aid in harnessing the potential therapeutic value of PCs. Apoptosis, or programmed cell death, is suggested to regulate death of PCs in the adult brain as overexpression of B-cell lymphoma 2 (Bcl-2), an anti-apoptotic protein, enhances the survival of new neurons. To directly assess if Bcl-2 is a regulator of apoptosis in PCs, this study examined the outcome of removal of Bcl-2 from the developing PCs in the adult mouse brain. Retroviral mediated gene transfer of Cre into adult floxed Bcl-2 mice eliminated Bcl-2 from developing PCs and resulted in the complete absence of new neurons at 30 days post viral injection. Similarly, Bcl-2 removal through the use of nestin-induced conditional knockout mice resulted in reduced number of mature neurons. The function of Bcl-2 in the PCs was also dependent on Bcl-2-associated X (BAX) protein, as demonstrated by an increase in new neurons formed following viral-mediated removal of Bcl-2 in BAX knockout mice. Together these findings demonstrate that Bcl-2 is an essential regulator of neurogenesis in the adult hippocampus. Adult Neurogenesis Apoptosis Bcl-2 Hippocampus Transgenic Mouse Model BAX Progenitor Cells Retrovirus Inducible Knock out
20	Mechanisms by Which Early Nutrition Influences Spatial Memory, Adult Neurogenesis, and Response to Hippocampal Injury Wong-Goodrich, Sarah Jeanne Evens January 2010 (has links) <p>Altered dietary availability of the vital nutrient choline during early development leads to persistent changes in brain and behavior throughout adulthood. Prenatal choline supplementation during embryonic days (ED) 12-17 of the rodent gestation period enhances memory capacity and precision and hippocampal plasticity in adulthood, and protects against spatial learning and memory deficits shortly after excitotoxic seizures, whereas prenatal choline deficiency can compromise hippocampal memory and plasticity in adulthood. Recent evidence from our laboratory has determined that lifelong proliferation of newborn neurons in the adult hippocampus, a feature of adult hippocampal plasticity that has been implicated in some aspects of learning and memory, is modulated by early choline availability. Prenatal choline's effects on adult neurogenesis may be one mechanism for diet-induced cognitive changes throughout life and in response to injury, although little is known about the mechanisms underlying how prenatal choline alters adult neurogenesis or the neural mechanisms underlying prenatal choline supplementation's protection against cognitive deficits after seizures. To address these issues, the present set of experiments investigated how prenatal choline availability modulates specific properties of neurogenesis in the adult brain (in the intact brain and in response to injury), as well as hippocampal markers known to change in response to excitotoxin-induced seizures, and sought to relate changes in neurogenesis and in neuropathological markers following injury to changes in performance on spatial learning and memory tasks. Subjects in each experiment were adult offspring from rat dams that received either a control diet or diet supplemented with choline chloride or deficient of choline on ED 12-17. To measure neurogenesis, rats were given injections of the mitotic marker bromodeoxyurdine to label dividing cells in the hippocampus. Prenatal choline supplementation enhanced several properties of basal adult hippocampal neurogenesis (cell division and survival, neural stem/progenitor cell phenotype and proliferative capacity, trophic support), and this increase was associated with improvements in spatial working memory retention in a delayed-matching-to-place water maze task. In contrast, prenatal choline deficiency had little effect on basal adult hippocampal neurogenesis, and no effect on spatial memory performance. Prenatal choline supplementation also enhanced olfactory bulb neurogenesis without altering cell proliferation in the subventricular zone, while prenatal choline deficiency had no effect on either measure, showing for the first time that prenatal choline's effects on adult neurogenesis is similarly expressed in another distinct neurogenic region of the adult brain. Altered prenatal choline availability also modulated the hippocampal response to kainic acid-induced seizures where supplementation attenuated while deficiency had no effect on the injury-induced proliferative response of the dentate gyrus shortly after injury. Prenatal choline supplementation also attenuated other markers of hippocampal neuropathology shortly after seizures and promoted the long-term hippocampal recovery from seizures months after injury, including rescuing declines in adult hippocampal neurogenesis and in spatial memory performance in a standard water maze task. Taken together, these findings demonstrate a robust neuroprotective effect of prenatal choline supplementation that may be driven by enhanced adult hippocampal plasticity and trophic support prior to injury, and shed light on the mechanisms underlying how prenatal choline availability alters adult hippocampal neurogenesis, which may contribute to changes in memory capacity and precision both throughout life and following neural assault.</p> / Dissertation Psychology, Experimental Biology, Neuroscience Psychology, Behavioral adult neurogenesis growth factor hippocampus memory olfactory bulb seizure

Search results