Experience-dependent persistent expression of zif268 during rest is preserved in the aged dentate gyrus

Gheidi, Ali, Azzopardi, Erin, Adams, Allison, Marrone, Diano

January 2013

BACKGROUND:Aging is typically accompanied by memory decline and changes in hippocampal function. Among these changes is a decline in the activity of the dentate gyrus (DG) during behavior. Lasting memory, however, is thought to also require recapitulation of recent memory traces during subsequent rest - a phenomenon, termed memory trace reactivation, which is compromised in hippocampal CA1 with progressive age. This process has yet to be assessed in the aged DG, despite its prominent role in age-related memory impairment. Using zif268 transcription to measure granule cell recruitment, DG activity in adult and aged animals was assessed both during spatial exploration and as animals remained at rest in the home cage in order to detect potential memory-related replay.RESULTS:Consistent with the observation of memory trace reactivation in DG, the probability that an individual granule cell transcribes zif268 during rest in the animal's home cage is increased by recent experience in a novel environment. Surprisingly, a comparable increase was observed in the probability of granule cells in the aged DG expressing zif268 during rest. Moreover, no significant age-related difference was observed in the number of granule cells expressing zif268 during rest. Thus, the number and pattern of granule cell expression of zif268 during rest is preserved in aged animals, despite a significant decline in exploration-related zif268 expression.CONCLUSIONS:These data lead to the hypothesis that the input the aged DG receives from backprojections from CA3 (the region widely hypothesized to mediate reactivation) remains functionally intact despite loss of innervation from the perforant path.

Fascia dentata

egr1

ngfi-a

Reactivation

Replay

Granule cell

IEG

Hippocampus

Investigating the Fate of Pre-neoplastic Cells in a Mouse Model of Medulloblastoma

Kessler, Jessica Dawn

January 2009

<p>Studying the early stages of cancer can provide important insight into the molecular basis of the disease. In many human cancers, such as prostate, pancreatic, and colon cancer, a pre-neoplastic, or intermediate, stage of the disease has been identified. The pre-neoplastic stage is presumed to be a transition during which normal cells undergo malignant transformation. However, the link between the pre-neoplastic cells and end-stage disease has never been formally established. To investigate the fate of such cells, the patched (ptc) mutant mouse, a model for the brain tumor medulloblastoma was used. Pre-neoplastic cells (PNCs) are found in most ptc mutants during early adulthood, but only 15% of these animals develop tumors. Although PNCs are found in mice that develop tumors, the ability of PNCs to give rise to tumors has never been demonstrated directly, and the fate of cells that do not form tumors remains unknown. Genetic fate mapping and orthotopic transplantation provided definitive evidence that PNCs give rise to tumors and showed that the predominant fate of PNCs that do not form tumors is differentiation. Moreover, N-myc, a gene commonly amplified in medulloblastoma, can dramatically alter the fate of PNCs, preventing differentiation and driving progression to tumors. Importantly, N-myc allows PNCs to grow independently of hedgehog signaling, making the resulting tumors resistant to hedgehog antagonists. These studies provide the first direct evidence that PNCs can give rise to tumors, and demonstrate that identification of genetic changes that promote tumor progression is critical for designing effective therapies for cancer.</p> / Dissertation

Biology, Molecular

granule cell precursors

medulloblastoma

patched

pre

neoplastic lesions

Mechanisms of Synaptic Plasticity in the Rat Olfactory Bulb

Gao, Yuan

23 January 2010

No description available.

Biomedical Research

olfactory bulb

granule cell

mitral cell

inhibition

excitation

mTOR Regulation of Hippocampal Granule Cell Pathology in Temporal Lobe Epilepsy

Hester, Michael S.

January 2014

No description available.

Neurology

Epilepsy

Granule Cell

mTOR

Rapamycin

Seizure

Mossy Cell

DNA Binding Activities in Cerebellar Granule Cell Neurons Recognizing the Promoter for The GABA(A)-alpha6 Receptor Subunit

Stock, Rachel E.

22 August 2002

"The objective of this thesis project was to begin identifying which regulatory transcription factors are involved in the up-regulation of the gene promoter for the Ą6 subunit of the gamma-alpha-butyric acid (GABAA-Ą6) receptor in cerebellar granule cell neurons (GCNs). Although a 150 base pair sequence proximal to the GABAA-Ą6 gene promoter had been characterized previously using electrophoretic mobility shift assays (EMSAs), the specific transcription factor(s) needed to express the GABAA-Ą6 gene had not been examined. This project utilized EMSAs to investigate this 150 base pair sequence further. It was found that when this sequence proximal to the gene promoter was divided into two overlapping halves, both shortened sequences were able to compete for binding with nuclear extracts. The full-length sequence was further divided into six sub-regions, and double-stranded competitors were generated from synthetic oligonucleotides. The only oligonucleotide to compete was the one that corresponded to the region of overlap between the left and right halves. This overlap region contains consensus sites for OCT-1, STAT, and the regulatory transcription factor NF-1. An NF-1 consensus sequence was able to compete DNA-protein complexes. Supershift assays showed that a xenopus NF-1 antibody, previously shown to compete in gel shift assays, caused a mobility shift of the DNA-probe complex. Analysis of extracts from granule cell neurons, cultured from 0 to 6 days in vitro (DIV) indicated NF-1 to be present all time points. Northern analyses were performed using probes for NF-1A, NF-1B, NF-1C and NF-1X. NF-1A transcripts were observed from 0 to 6 DIV, while NF-1B and NF-1X transcripts were present at 2 and 4 DIV. NF-1C RNA was barely detectable at any time point."

NF-1

granule cell neuron

Genetic regulation

Transcription factors

Electrophoresis

Cerebellum

Adult Hippocampal Neurogenesis and Memory Enhancement

Stone, Scellig S. D.

31 August 2012

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

Adult Hippocampal Neurogenesis and Memory Enhancement

Stone, Scellig S. D.

31 August 2012

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

Activity-dependent bidirectional regulation of terminal neuronal maturation in the adult hippocampus / 神経活動依存的な海馬成熟状態の両方向制御

Imoto, Yuki

23 March 2015

京都大学 / 0048 / 新制・課程博士 / 博士(薬科学) / 甲第18919号 / 薬科博第33号 / 新制||薬||4(附属図書館) / 31870 / 京都大学大学院薬学研究科薬科学専攻 / (主査)教授 中山 和久, 教授 金子 周司, 教授 竹島 浩 / 学位規則第4条第1項該当 / Doctor of Pharmaceutical Sciences / Kyoto University / DFAM

Dentate gyrus

Granule cell

Maturation

Neural activity

Hippocampus

Antiepressant

Neurogenesis

499.3

Aberrant hippocampal granule cell neurogenesis and integration in epilepsy

Murphy, Brian L.

06 December 2010

No description available.

Neurology

plasticity

dentate granule cell

recurrent basal dendrite

epilepsy

neurogenesis

early-life seizure

Rôle du facteur de transcription Otx2 dans le développement normal et tumoral du cervelet / Role of transcription factor Otx2 in the normal and tumoral development of the cerebellum

El Nagar, Salsabiel

19 December 2017

Les médulloblastomes (MB) sont les tumeurs cérébrales les plus fréquentes en pédiatrie. Ils apparaissent le plus souvent au niveau du cervelet. Ils peuvent être stratifiés en quatre groupes : les groupes WNT et SHH, où ces voies de signalisation sont altérées, et les groupes 3 et 4, présentant des anomalies chromosomiques et amplifications multiples, dont c-Myc (groupe 3) et N-Myc (groupe 4). L’une des altérations génétiques les plus retrouvées dans les MB est la surexpression du facteur de transcription OTX2. Ce facteur est exprimé dans les précurseurs des cellules granulaires (GCP) du cervelet, cellules d’origine de la majorité des MB. Pendant la période périnatale, les GCP subissent une phase de prolifération très intense en réponse au mitogène Sonic Hedgehog (SHH), ce qui les rendrait particulièrement sensibles à la tumorigenèse. Au cours de cette thèse, nous nous sommes intéressé à la fonction d’Otx2 dans ces GCP. Nous avons montré que l’ablation conditionnelle d’Otx2 conduit à un défaut de prolifération des ces cellules. L’analyse approfondie de ce phénotype a permis de révéler qu’Otx2 stimule la prolifération des GCP parallèlement à la voie de signalisation Shh. Par ailleurs, l’ablation d’Otx2 dans un modèle murin mimant la formation de MB Shh-dépendants a montré qu’Otx2 s’avère indispensable pour leur maintien à long terme. En parallèle, nous avons tenté de créer un nouveau modèle murin mimant la formation de MB de groupe 3 en induisant l’expression, pendant la période postnatale, d’un dominant actif de c-Myc dans les cellules exprimant Otx2. Cette approche a donné des résultats inattendus : des carcinomes de plexus choroïdes, et non des MB, ont été obtenus. / Medulloblastomas (MB) are the most common brain tumors in paediatrics. They appear during development in the posterior part of the brain, mainly in cerebellum. MB can be stratified in four groups: the WNT and SHH groups, where these signalling pathways are aberrantly activated, and the groups 3 and 4, which display chromosomal abnormalities and multiple amplifications, including c-Myc (group 3) and N-Myc (group 4). One of the most frequent genetic alterations in MB is the overexpression of the Otx2 transcription factor (in 75% of cases). This factor, which is essential for central nervous system development, is expressed in granule cell precursors (GCP) of the cerebellum, which represent the cell of origin of the majority of MB. During the perinatal period, GCPs undergo intense proliferation in response to Sonic Hedgegog (SHH), making them particularly susceptible to tumorigenesis. During this thesis, we were interested in examining the function of Otx2 in GCPs. We have shown that conditional ablation of Otx2 leads to a GCP proliferation defect and that Otx2 stimulates the proliferation of these cells independently of the Shh signaling pathway. Moreover, ablation of Otx2 in a mice model of Shh-dependent medulloblastomas yielded very interesting results: while Otx2 does not seem to be required for the initiation of these tumors, it is essential for their long-term maintenance. In parallel, we tried to create a new murine model for the MB group 3 by inducing the expression, during the postnatal period, of an active dominant of c-Myc in cells expressing Otx2. This approach yielded unexpected results: choroid plexus carcinomas, instead of MB, were obtained.

Otx2

Cervelet

Prolifération

Médulloblastomes

Précurseurs des cellules granulaires

Modèle murin

Otx2

Cerebellum

Proliferation

Medulloblastoma

Granule cell precursors

Mouse model