The Dentate Gyrus of the Hippocampus: Roles of Transforming Growth Factor beta1 (TGFbeta1) and Adult Neurogenesis in the Expression of Spatial Memory

Martinez-Canabal, Alonso

08 August 2013

The dentate gyrus is a region that hosts most of the hippocampal cells in mammals. Nevertheless, its role in spatial memory remains poorly understood, especially in light of the recently-studied phenomenon of adult hippocampal neurogenesis and its possible role in aging and chronic brain disease. We found that chronic over-expression of transforming growth factor beta1 (TGFbeta1), a cytokine involved in neurodegenerative disease, results in several modifications of brain structure, including volumetric changes and persistent astrogliosis. Furthermore, TGFbeta1 over-expression affects the generation of new neurons, leading to an increased number of neurons in the dentate gyrus and deficits in spatial memory acquisition and storage in aged mice. Nonetheless, reducing neurogenesis via pharmacological treatment impairs spatial memory in juvenile mice but not in adult or aged mice. This suggests that the addition of new cells to hippocampal circuitry, and not the increased plasticity of these cells, is the most relevant role of neurogenesis in spatial memory. We tested this idea by modifying proliferation in the dentate gyrus at several ages using multiple techniques and evaluating the incorporation of newborn neurons into hippocampal circuitry. We found that all granule neurons, recently generated or not, have the same probability of being incorporated. Therefore, the number of new neurons participating in memory circuits is proportional to their availability. Our conclusion is that adult-generated cells have the same functional relevance as those generated during development. Together, our data show that the dentate gyrus is important for memory processing and that adult neurogenesis may be relevant to its functionality by optimizing the number of neurons for memory processing. The equilibrium between neurogenesis and optimal dentate gyrus size is disrupted when TGFbeta1 is chronically increased, which occurs in neurodegenerative pathologies, leading to cognitive impairment in aged animals.

adult neurogenesis

transforming growth factor-beta

hippocampus

Dentate gyrus

cognition

0317

0633

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

Sex differences for object location memory in rats : the contribution of the dentate gyrus

Ehresman, Crystal, University of Lethbridge. Faculty of Arts and Science

January 2010

Females exhibit superior object location memory (OLM) compared to males, but the reasons for this sex difference remains unknown. This thesis investigates the role of the dentate gyrus (DG) in an OLM task in normal rats (Experiment 1) and after bilateral adrenalectomy (ADX; Experiment 2). ADX is known to reduce volume of the DG and impair spatial learning. There was no sex difference for OLM in Experiment 1 but females exhibited superior OLM in Experiment 2. Experiment 2 found a significantly smaller DG due to ADX but this had no effect on behaviour. The male DG was significantly larger than the female DG in both experiments. Behaviour during the OLM task was not a predictor of DG volume, although a larger than average DG was related to poor OLM memory in females Thus, the DG involvement for OLM appears to differ between the sexes. / ix, 72 leaves : ill. ; 29 cm

Memory

Dentate Gyrus -- Sex differences

Memory -- Testing

Rats as laboratory animals

Dissertations, Academic

Differential neurogenesis in the adult rat dentate gyrus

Melvin, Neal, University of Lethbridge. Faculty of Arts and Science

January 2008

Adult neurogenesis is a fundamental feature of mammalian nervous systems. Curiously, neurogenesis in the dentate gyrus is typically regarded as homogenous. This thesis challenges that view, and reports the discovery and characterization of a novel region of the dentate gyrus that consistently lacks basal neurogenesis. We demonstrate that this area, referred to as the neurogenically quiescent zone, represents approximately 1.5% of the total volume of the dentate gyrus, and that its location is invariant among animals. This region contains several critical cell types and molecular factors that are known to be critical to the neurogenic niche, including stem cells. We also present data that attempt to conceptualize the existence of this region in the context of early agerelated declines in neurogenesis. Finally, we demonstrate that, under some behavioural conditions, neurogenesis can be induced in this region, suggesting that, under basal conditions, it may simply lack the presence of pro-neurogenic factors. / xvi, 125 leaves : ill. ; 29 cm. --

Dissertations, Academic

Electronic dissertations

Developmental neurobiology

Dentate gyrus

Brain -- Research

Rats as laboratory animals

Hippocampus (Brain)

A Role for the NMDA receptor in synaptic plasticity in the hippocampus of the Fmr1 transgenic mouse model of Fragile X Syndrome

Bostrom, Crystal A.

23 July 2012

Fragile-X syndrome (FXS) is the most common form of inherited intellectual impairment. Caused by the transcriptional repression of the Fmr1 gene on the X chromosome, FXS results in the loss of the Fragile-X Mental Retardation Protein (FMRP). Human female patients with FXS are heterozygous for the Fmr1 mutation whereas males are hemizygous. FXS has been studied far less in females than in males due to a generally less severe clinical phenotype. Previous research has implicated the metabotropic glutamate receptor (mGluR) in synaptic plasticity alterations in the cornu ammonis area 1 (CA1) region of the juvenile male Fmr1 knock-out (KO) hippocampus. In contrast, our investigations into the young adult dentate gyrus (DG) subfield of the hippocampus have revealed N-methyl-D-aspartate receptor (NMDAR)-associated impairments in synaptic plasticity. The current study sought to extend these investigations to the young adult female Fmr1 heterozygous (Het) and Fmr1 KO mouse as well as investigate NMDAR- and mGluR-mediated long-term depression (LTD) in the DG and CA1 of the young adult male Fmr1 KO mouse. Input-output curves and paired pulse measures of short-term plasticity were also evaluated in all genotypes. Field electrophysiology revealed a significant impairment in long-term potentiation (LTP) and LTD in male Fmr1 KO and female Fmr1 Het mice that was associated with NMDAR alteration. A more robust synaptic protocol was not able to rescue LTP in the male Fmr1 KO DG. Paired-pulse low-frequency stimulation and (RS)-3,5-dihydroxyphenylglycine (DHPG)-induced mGluR-LTD was intact in all genotypes and brain regions examined. Although further investigation will be required to expand our understanding of FXS and to fully elucidate the mechanisms behind intact synaptic plasticity in the female Fmr1 KO mouse, our results suggest that NMDARs may be poised as important contributors to hippocampal pathophysiology in FXS. / Graduate

electrophysiology

Fmr1

Fragile X Syndrome

mGluR

murine

hippocampus

dentate gyrus

CA1

NMDAR

The Dentate Gyrus of the Hippocampus: Roles of Transforming Growth Factor beta1 (TGFbeta1) and Adult Neurogenesis in the Expression of Spatial Memory

Martinez-Canabal, Alonso

08 August 2013

The dentate gyrus is a region that hosts most of the hippocampal cells in mammals. Nevertheless, its role in spatial memory remains poorly understood, especially in light of the recently-studied phenomenon of adult hippocampal neurogenesis and its possible role in aging and chronic brain disease. We found that chronic over-expression of transforming growth factor beta1 (TGFbeta1), a cytokine involved in neurodegenerative disease, results in several modifications of brain structure, including volumetric changes and persistent astrogliosis. Furthermore, TGFbeta1 over-expression affects the generation of new neurons, leading to an increased number of neurons in the dentate gyrus and deficits in spatial memory acquisition and storage in aged mice. Nonetheless, reducing neurogenesis via pharmacological treatment impairs spatial memory in juvenile mice but not in adult or aged mice. This suggests that the addition of new cells to hippocampal circuitry, and not the increased plasticity of these cells, is the most relevant role of neurogenesis in spatial memory. We tested this idea by modifying proliferation in the dentate gyrus at several ages using multiple techniques and evaluating the incorporation of newborn neurons into hippocampal circuitry. We found that all granule neurons, recently generated or not, have the same probability of being incorporated. Therefore, the number of new neurons participating in memory circuits is proportional to their availability. Our conclusion is that adult-generated cells have the same functional relevance as those generated during development. Together, our data show that the dentate gyrus is important for memory processing and that adult neurogenesis may be relevant to its functionality by optimizing the number of neurons for memory processing. The equilibrium between neurogenesis and optimal dentate gyrus size is disrupted when TGFbeta1 is chronically increased, which occurs in neurodegenerative pathologies, leading to cognitive impairment in aged animals.

adult neurogenesis

transforming growth factor-beta

hippocampus

Dentate gyrus

cognition

0317

0633

BK離子通道與海馬迴粒細胞死亡的相關性 / The relationship between BK channel alternative splicing and granule cell death in the hippocampus

吳君逸, Wu, Jun Yi

Unknown Date

海馬迴不僅在學習與記憶中扮演重要的角色，在許多神經退化性疾病中亦佔有重要的地位。海馬迴的齒迴內側區是哺乳動物大腦中成體幹細胞主要來源區域之一，其所新生的海馬迴粒細胞會往上遷移至海馬迴粒細胞層並與固有神經細胞形成功能性連結。 過去的研究發現太少或過量的壓力荷爾蒙均會造成海馬迴粒細胞的死亡，而一定量濃度的皮質固醇對於維持海馬迴粒細胞的生存亦扮演非常重要的角色。在摘除兩側的腎上腺後，海馬迴粒細胞在幾週後會逐漸死亡且造成認知功能的缺損。本實驗即利用雙側腎上腺摘除術建立動物模式，企圖了解海馬迴粒細胞在凋亡的過程中所產生的生理層面的改變。 壓力荷爾蒙（包含皮質固醇，在老鼠稱為corticosterone，在人類稱為cortisol）為腎上腺皮質分泌激素，已知會參與並調控BK 離子通道的選擇性剪接。BK離子通道的孔道形成α次單元由單一基因 (Slo) 負責轉錄，含有STREX外顯子的剪接變異體之α次單元藉由加速神經細胞的再極化，增強過極化電位以及促進鈉離子通道自去活化狀態中回復可造成神經細胞重複激發，而先前的研究已發現過度的激發會對神經細胞產生興奮性毒殺作用。本實驗即探討BK 鉀離子通道選擇性剪接在海馬迴粒細胞凋亡的過程中所扮演的角色。 實驗結果發現，與對照組相比，雙側腎上腺摘除的老鼠海馬迴細胞中含有STREX外顯子的剪接變異體在mRNA含量上確實有改變，而BK 鉀離子通道蛋白質含量亦有所變化。由上述結果推測，含有STREX外顯子的剪接變異體含量可能與海馬迴粒細胞的凋亡機制有關。 / The hippocampus is a brain region central to learning and memory and is a key target of many neurological diseases that have dramatic cognitive consequences, including Alzheimer’s and other forms of dementia, stroke, epilepsy, and chronic stress. Hippocampal granule cells are one of the two cell pools that contain newborn neurons continuously generated from the subgranular zone in adult mammalian brains. The newborn neurons will migrate to the granule cell layer and integrate into preexisting neuron network. Previous studies have indicated that both an excessive and insufficient levels of stress hormones can lead to neuron death. Corticosterone, an adrenal stress hormone, is essential for the survival of granule cells. Bilateral removal of adrenal glands leads to extensive granule cell death over a period of several weeks and gradually causes cognitive deficits. To understand the mechanisms underlying the granule cell death in the hippocampal formation, adrenalectomy (ADX, removal of adrenal glands) was used to specifically eliminate granule cells in the hippocampus, and the subsequent physiological changes in the hippocampal neurons including dentate granule cells are investigated. Stress hormones (corticosterone in rats and cortisol in human) , secreted from the adrenal cortex regulate the alternative splicing of BK channels (big potassium, calcium-voltage activated potassium channels) in adrenal medulla. An inclusion of STREX (stress axis-regulated exon) exon in pore-forming α subunit encoded by Slo gene promotes repetitive firing by speeding action potential repolarization and augmenting the afterhyperpolarization, as well as facilitating sodium channels de-inactivation. In the present study, the role of BK channel alternative splicing in the ADX-induced granule cell death in the hippocampus was explored. The results indicate that BK channel alternative splicing was regulated by stress hormones in the hippocampus including dentate gyrus. The expression patterns of STREX variant in hippocampus were altered after granule cells death induced by ADX, whilst the expression of total slo gene was changes only in translational level. These observations suggest that the alternation in STREX abundance might be involved in the induction of dentate granule cell death.

BK離子通道

海馬迴

齒狀回

BK

Hippocampus

Dentate gyrus

COUP-TFI est nécessaire dans la différentiation et la migration des granules du gyrus denté / COUP-TFI is required in the differentiation and migration of granule cells in the developing dentate gyrus

Parisot, Joséphine

23 November 2015

L’hippocampe est un composant majeur du cerveau des mammifères et joue d'importants rôles dans la mémoire, l’apprentissage et la navigation spatiale. Il comprend deux régions distinctes: les champs ammoniens et le gyrus denté (DG). Pendant ma thèse, je me suis intéressée au facteur de transcription COUP- TFI, jouant des rôles clefs dans la spécification et migration neocorticale. Peu de choses sont connues sur son rôle dans l’hippocampe. COUP-TFI y est exprimé en gradient dans les progéniteurs et dans les neurones différentiés, et est fortement localisé dans le neuroépithelium du DG. Le but de ma thèse était de déchiffrer le rôle de COUP-TFI dans le développement de l’hippocampe, au cours de la différentiation et migration des granules, population principale du DG. À l’aide de lignées de souris dans lesquelles COUP-TFI est soit inactivé dans les progéniteurs soit seulement dans les cellules différentiées, j’ai montré que l’absence de COUP-TFI induit différents degrés d’altérations. En l’absence de COUPTFI dans les progéniteurs, les précurseurs du DG se différentient précocement, ont une prolifération réduite et leur migration est altérée. De plus, les afférences du cortex n’innervent pas le DG septal et l’apoptose y est accrue. Le DG en résulte fortement réduit chez adulte, particulièrement dans la région septal. La perte de COUP-TFI dans les cellules différentiées n’entraine que des anomalies mineures et transitoires. Ainsi, mes résultats indiquent que COUP-TFI régule la différentiation et migration des granules, particulièrement au niveau des progéniteurs, et propose COUP-TFI comme un nouveau facteur requis dans le développement et le fonctionnement de l’hippocampe. / The hippocampus is a major component of the mammalian brain and plays important roles in memory, learning, and spatial navigation. It comprises two distinct regions: the hippocampus proper and the dentate gyrus (DG). During my thesis, I have challenged the role of the strong transcriptional regulator COUP-TFI, playing key roles during neocortical specification and migration. Yet, little is known about its involvement in the hippocampus. COUP-TFI is expressed in a gradient fashion in both proliferating progenitors and differentiated neurons in the hippocampus, and is highly localized in the DG neuroepithelium. The aim of my thesis was thus to decipher the role of COUP-TFI in the developing hippocampus, and specifically in cell differentiation and migration of granule cells, the major DG cell population. Using two mutant mouse lines, in which COUP-TFI is either ablated in progenitors, or solely in post-mitotic cells, I have shown that absence of COUP-TFI induces different degrees of growth impairments. In the absence of COUP-TFI in progenitors, DG precursors tend to differentiate precociously, exhibit reduced proliferation and granule cells migration is impaired. Postnatally, inputs from the cortex fail to innervate the septal DG and apoptosis is abnormally increased. The DG results strongly reduced in adult, particularly in the septal region. Loss of COUP-TFI in differentiated cells leads only to minor and transient defects. Together, my results indicate that COUP-TFI is involved in regulating granule cell differentiation and migration predominantly in progenitors, and propose COUPTFI as a novel transcriptional regulator required in hippocampal development and functions.

Hippocampe

Gyrus denté

Développement

COUP-TFI

Hippocampus

Dentate gyrus

Development

COUP-TFI

Performance on pattern recogniton declins with age while performance on pattern separation does not

Schnell, Felizia

January 2015

This report aims to explore if pattern recognition and pattern separation tasks performance degenerate with age. This as there are studies by Brickman et al. (2014) that suggest that these tasks are being performed by the hippocampus in particular, the dentate gyrus part. The tasks used in this report were replicated from a study in which it was assumed that they tested this parts. As both the hippocampus and the dentate gyrus supposedly degenerate with age, the tasks tested this degeneration by looking if the participant’s performance on the tasks changed with age. The performance on the pattern separation task did not change with age while the pattern recognition task did. This preservation of pattern separation might mean that the pattern separation tasks does not measure the dentate gyrus. It might also mean that the hippocampus might not degenerate as previously assumed or that the pattern separation task really test the hippocampus.

Pattern separation

Pattern recognition

Hippocampus

Episodic memory

Dentate gyrus

Human Computer Interaction