The effects of stress and corticosterone on synaptic plasticity and neuronal morphology in the rodent hippocampus

Alfarez, Deborah Natascha.

January 2006

Proefschrift Universiteit van Amsterdam. / Met bibliogr., lit.opg. - Met samenvatting in het Nederlands.

Mechanisms of Synaptic Homeostasis and their Influence on Hebbian Plasticity at CA1 Hippocampal Synapses

Soares, Cary

January 2016

Information is transferred between neurons in the brain via electrochemical transmission at specialized cell-cell junctions called synapses. These structures are far from being static, but rather are influenced by plasticity mechanisms that alter features of synaptic transmission as means to build routes of information flow in the brain. Hebbian forms of synaptic plasticity – long-term potentiation and long-term depression – have been well studied and are considered to be the cellular basis of learning and memory, although their positive feedback nature is prone to instability. Neurons are also endowed with homeostatic mechanisms of synaptic plasticity that act to stabilize neural network functions by globally tuning synaptic drive. Precisely how neurons orchestrate this adaptive homeostatic response and how it influences Hebbian forms of synaptic plasticity, however, remains only partially understood. Using a combination of whole-cell electrophysiology, two-photon imaging and glutamate uncaging in organotypic hippocampal slices, I have expanded upon the known repertoire of homeostatic mechanisms that increase excitatory synaptic drive when CA1 hippocampal neurons experience a prolonged period of diminished activity. I found that the subunit composition of AMPA and NMDA receptors, the two major glutamate receptor subtypes at excitatory synapses, are altered which, in addition to increasing synaptic strength, are predicted to change the signaling and integrative properties of synaptic transmission. Moreover, I found that the amount of glutamate released from presynaptic terminals during evoked-transmission is enhanced and that this mechanism might, in part, underlie the uniform cell-wide homeostatic increase in synaptic strengths. Lastly, I found that homeostatic strengthening of synaptic transmission reduced the potential for CA1 synapses to exhibit long-term potentiation, and that this was caused by altered presynaptic release dynamics that impeded plasticity induction. Together, this work highlights several mechanistic strategies employed by neurons to increase excitatory synaptic drive during periods of activity deprivation which, in addition to balancing cellular excitability, alters the metaplastic state of synapses.

Synapses

Plasticity

Homeostasis

Hippocampus

ALTERED HIPPOCAMPAL ASTROGLIAL METABOLISM ASSOCIATED WITH AGING AND COGNITIVE FUNCTION

Ebersole, Jeremy M.

01 May 2012

During aging, a decline in metabolism appears to be associated with altered hippocampal function. Thus, 1-13C-glucose and 2-13C-acetate were employed to assess neural metabolism in the dentate gyrus and CA1 of F344 rats with respect to aging and cognitive status. The results obtained when 1-13C-glucose was used as the metabolic substrate suggest that glucose metabolism may not be altered in neural tissue itself with respect to aging or a decline in hippocampal function. In contrast, the use of 2-13C-acetate, a substrate that is preferentially metabolized by astrocytes, revealed significantly increased astroglial metabolism associated with age and preserved hippocampal function. Specifically, greater 2-13C-acetate incorporation into glutamine and glutamate was observed in the dentate gyrus and CA1 of aged rats that performed similar to young rats in the Morris water maze task. Since glutamate is the primary excitatory neurotransmitter of the hippocampus and plays a central role in synaptic plasticity, the mechanism proposed to underlie learning and memory, these finding were taken to represent an adaptive metabolic response by astroglia in the aged hippocampus. Subsequently, astroglia metabolism could potentially be a future target of therapeutic strategies for age-related cognitive decline.

astrocytes

cognition

hippocampus

metabolism

An experimental study of the connexions of the hippocampus and related basal forebrain structures

Raisman, Geoffrey

January 1964

No description available.

Hippocampus (Brain) ; Rhinencephalon

The hippocampus in nociception

Khanna, Sanjay

January 1990

Limbic structures, including the hippocampus, are thought to be involved in pain though not much is known of their neuronal responses to noxious stimuli. Experiments were therefore performed in lightly anaesthetized rats to determine the effect of noxious heat stimuli on the excitability of dorsal hippocampal field CA1 pyramidal neurones. A prolonged and substantial depression of the CA1 population spike was produced by a brief but intense noxious stimulus applied to the tail. This depression was temperature-dependent and habituated to subsequent noxious stimuli applied more than 1 hr later. In other animals, a similar depression and habituation was also obtained with noxious heat stimuli applied to the left hind paw. However, following this habituation of the hind paw, a persistent depression of the CA1 population spike was seen if the tail was exposed to a noxious heat stimulus. The persistent depression was absent when noxious heat was applied in the presence of hippocampal theta rhythm. If, however, the hippocampal electroencephalographic ( EEG ) activity was in an irregular pattern at the time noxious heat was applied, a 4-6 Hz theta rhythm was produced along with the depression of the population spike. The latency and intensity of the reflex response was combined into a reflex-reaction score. There appeared to be a relationship between the reflex-reaction score and the duration of theta rhythm induced by different intensities of noxious heat stimuli but there was no habituation to these responses. The CA1 population spike evoked either by ipsilateral or contralateral CA3 stimulation was similarly depressed following a noxious stimulus. Concomitantly, the persistent depression and habituation of the commissural CA1 population spike was also accompanied by similar changes in the corresponding dendritic field excitatory postsynaptic potential ( EPSP ). However, the amplitude of the CA1 antidromic spike was increased in the majority of cases. These findings suggest that a presynaptically mediated decrease in synaptic transmission may account for the depression of the population spike and dendritic field EPSP. There is evidence to suggest that the noxious stimulus-induced persistent depression of CA1 pyramidal cell synaptic excitability is due to a cholinergic projection from the medial septal-vertical limb of the diagonal band of Broca complex ( MS-VLDBB ). Thus, atropine sulphate ( 40 mg/kg, i.p. ) prevented the persistent depression of the CA1 population spike to a noxious stimulus. It also antagonized the septal tetanus-evoked, cholinergic mediated facilitation of the CA1 commissural population spike but had no effect on the corresponding paired-pulse facilitation. Atropine, applied iontophoretically to the cell body region antagonized the iontophoretic acetylcholine-induced facilitation of the CA1 population spike but not its depression to a noxious stimulus. On the other hand, apical dendritic application of atropine antagonized iontophoretic acetylcholine and noxious stimulus-induced depression of the CA1 dendritic field EPSP. However, such iontophoretic application of atropine had no effect on dendritically applied gamma aminobutyric acid ( GABA )-induced depression of the CA1 dendritic field EPSP. These results support the notion that acetylcholine release in the dendritic region of CA1 neurones is involved in the depression of synaptic excitability of these neurones evoked by a noxious stimulus. / Pharmaceutical Sciences, Faculty of / Graduate

Hippocampus (Brain)

Nociceptors

The role of Ciliary Neurotrophic Factor in hippocampal synaptic plasticity and learning / Die Rolle von Ciliary Neurotrophic Factor bei hippocampaler synaptischer Plastizität und Lernen

Rüdt von Collenberg, Cora Freifrau

January 2021

Ciliary neurotrophic factor (Cntf) acts as a differentiation and survival factor for different types of neurons and glial cells. It is expressed by peripheral Schwann cells and astrocytes in the central nervous system and mediates its effects via a receptor complex involving CntfRα, LifRß and gp130, leading to downstream activation of Stat3. Recent studies by our group have shown that Cntf modulates neuronal microtubule dynamics via Stat3/stathmin interaction. In a mouse model for motor neuron disease, i.e. pmn, Cntf is able to rescue axonal degeneration through Stat3/stathmin signaling. While these findings suggest a role of Cntf in controlling axonal functions in the neuromuscular system, additional data indicate that Cntf might also play a role in synaptic plasticity in the hippocampus. Electrophysiological recordings in hippocampal organotypic cultures and acute slices revealed a deficit in long-term potentiation (LTP) in Cntf -/- mice. This deficit was rescued by 24 h stimulation with Cntf, combined with an acute application of Cntf during LTP-measurements indicating that Cntf is both necessary and sufficient for hippocampal LTP, and possibly synaptic plasticity. Therefore, Cntf knockout mice were investigated to elucidate this possible role of Cntf in hippocampal LTP and synaptic plasticity. First, we validated the presence of Cntf in the target tissue: in the hippocampus, Cntf was localized in Gfap-positive astrocytes surrounding small blood vessels in the fissure and in meningeal areas close to the dentate gyrus. Laser micro-dissection and qPCR analysis showed a similar distribution of Cntf-coding mRNA validating the obtained immunofluorescent results. Despite the strong LTP deficit in organotypic cultures, in vivo behavior of Cntf -/- mice regarding hippocampus-dependent learning and anxiety-related paradigms was largely inconspicuous. However, western blot analysis of hippocampal organotypic cultures revealed a significant reduction of pStat3 levels in Cntf -/- cultures under baseline conditions, which in turn were elevated upon Cntf stimulation. In order to resolve and examine synaptic structures we turned to in vitro analysis of cultured hippocampal neurons which indicated that pStat3 is predominantly located in the presynapse. In line with these findings, presynapses of Cntf -/- cultures were reduced in size and when in contact to astrocytes, contained less pStat3 immunoreactivity compared to presynapses in wildtype cultures. In conclusion, our findings hypothesize that despite of a largely inconspicuous behavioral phenotype of Cntf -/- mice, Cntf appears to have an influence on pStat3 levels at hippocampal synapses. In a next step these two key questions need to be addressed experimentally: 1) is there a compensatory mechanism by members of the Cntf family, possibly downstream of pStat3, which explains the in vivo behavioral results of Cntf -/- mice and can likewise account for the largely inconspicuous phenotype in CNTF-deficient humans? 2) How exactly does Cntf influence LTP through Stat3 signaling? To unravel the underlying mechanism further experiments should therefore investigate whether microtubule dynamics downstream of Stat3 and stathmin signaling are involved in the Cntf-induced modulation of hippocampal synaptic plasticity, similar to as it was shown in motoneurons. / Ciliary neurotrophic factor (Cntf) wirkt als Differenzierungs- und Überlebensfaktor für verschiedene Arten von Neuronen und Gliazellen. Es wird von peripheren Schwann´schen Zellen und Astrozyten des zentralen Nervensystems exprimiert und vermittelt seine Effekte über einen Rezeptorenkomplex, der aus CntfRα, LifRß und gp130 besteht, und zu einer nachfolgenden Aktivierung von Stat3 führt. Jüngste Studien unserer Arbeitsgruppe haben gezeigt, dass Cntf neuronale Mikrotubulidynamik über Stat3/stathmin Interaktion modulieren kann. In pmn Mäusen, einem Mausmodell für Motoneuronenerkrankungen, ist Cntf in der Lage, durch Stat3/Stathmin Signaltransduktion die zugrundeliegende axonale Degeneration wieder aufzuheben. Während diese Ergebnisse eine Rolle von Cntf bei der Kontrolle axonaler Funktionen im neuromuskulären System postulieren, deuten zusätzliche Daten darauf hin, dass Cntf ebenfalls eine Funktion bei synaptischer Plastizität im Hippocampus ausübt. Elektrophysiologische Messungen in hippocampalen organotypischen Kulturen und akuten Schnitten zeigen ein Defizit in der Langzeitpotenzierung (LTP) bei Cntf -/- Mäusen. Dieses Defizit konnte durch eine 24 stündige Stimulation mit Cntf, in Kombination mit akuter Zugabe von Cntf während der LTP Messungen, kompensiert werden. Dies weist darauf hin, dass Cntf sowohl notwendig als auch ausreichend für hippocampale LTP und möglicherweise synaptische Plasizität ist. Deshalb wurden Cntf knockout Mäuse untersucht, um diese putative Rolle von Cntf bei hippocampaler LTP und synaptischer Plastizität zu untersuchen. Zunächst haben wir die Lokalisation von Cntf in unserem Zielgewebe bestätigt: im Hippocampus war Cntf sowohl in Gfap-positiven Astrocyten lokalisiert, die kleine Blutgefäße in der Fissur umschließen, als auch in Gfap-positiven Astrocyten nahe des Gyrus dentatus. Lasermikrodissektion und qPCR-Analysen zeigten eine ähnliche Verteilung von Cntf kodierender mRNA, und bestätigten somit die durch Immunoflureszenz-Färbung erworbenen Ergebnisse. Trotz des starken LTP Defizits in organotypischen Kulturen zeigten jedoch Cntf -/- Mäuse in Hippocampus-abhängigen lern- und angstbedingten Verhaltensparadigmen keinen offensichtlichen Phänotyp. Allerdings zeigten Western Blot Analysen hippocampaler Kulturen eine signifikante Reduktion der pStat3 Level in Cntf -/- Kulturen unter Kontrollbedingungen, die nach Cntf Zugabe wieder erhöht werden konnten. Um synaptische Strukturen besser darstellen und evaluieren zu können, wurden hippocampale Neurone in vitro kultiviert, in denen Stat3 überwiegend in Präsynapsen lokalisiert war. In Übereinstimmung mit diesen Beobachtungen zeigten Cntf -/- Präsynapsen eine geringere Größe und enthielten, verglichen zu Präsynapsen in Wildtypkulturen, weniger pStat3 Immunreaktivität, gerade dann, wenn sie sich in Kontakt mit Astrozyten befanden. Zusammenfassend weisen unsere Befunde darauf hin, dass Cntf – trotz eines weitgehend unaufälligen Verhaltensphänotyps bei Cntf -/- Mäusen – einen Einfluss auf den Level von pStat3 an hippokampalen Synapsen zu haben scheint. In einem nächsten Schritt sollten die folgenden zwei Schlüsselfragen experimentell geklärt werden: 1) gibt es einen kompensierenden Mechanismus, über welchen Mitglieder der Cntf Familie wirken könnten – möglicherweise nachfolgend von pStat3 – und welcher das Verhalten der Cntf -/- Mäuse, sowie den größtenteils unauffälligen Phänotyp bei CNTF defizienten Menschen erklären könnte? 2) Wie genau wirkt sich Cntf induziertes pStat3 auf LTP aus? Um diesen zugrundeliegenden Mechanismus aufzuklären, sollten weitere Experimente untersuchen, ob pStat3 und Stathmin abhängige Mikrotubulidynamik in der durch Cntf induzierten Modulation hippocampaler Plastizität eine Rolle spielt – ähnlich, wie es in Motoneuronen bereits gezeigt wurde.

Hippocampus

ddc:610

Cardiorespiratory fitness and hippocampal subfield volume in healthy older adults

Mumtaz, Shiraz

13 June 2019

The increasing incidence of Alzheimer’s disease (AD) combined with recent evidence suggesting that its neuropathologies begin years prior to symptomatic onset has produced an immense focus on ways to attenuate the related structural and cognitive decline of certain brain regions. One low cost intervention is aerobic exercise. Rodent models have demonstrated aerobic exercise induces adult hippocampal neurogenesis, the birth of new neurons, in the dentate gyrus (DG) subregion of the hippocampus (HC) as well as increased performance on a spatial memory task. Further, human studies have demonstrated the association between increased cardiorespiratory fitness (CRF) and increased HC volume, and its translation to increased episodic memory performance. The goal of this study was to assess the relationship between CRF, as measured by VO2max, and brain region of interest (ROI) volumes notably including the left HC, left DG/Cornu Ammonis 3 (CA), and right entorhinal cortex (ErC). A secondary goal was to assess the relationship between CRF and cognitive performance on the Rey Auditory Verbal Learning Test. Baseline data was collected from 31 healthy older adults as a part of two larger clinical trials on aerobic exercise and HC function. Data included a CRF assessment as measured by VO2max, and structural MRI data including a high-resolution whole-brain T1-weighted image, and a T2-weighted image with higher-in-plane resolution. Automatic Segmentation of Hippocampal Subfields (ASHS) was the neuroimaging software utilized to segment the HC and medial temporal lobe cortices into its appropriate subfields. Multiple linear regressions ran in IBM SPSS 25 to determine if CRF predicted ROI volumes yielded no significant results when controlling for age, sex, intracranial volume, education, and scanner location. Multiple one-way between-subject ANOVAs conducted to compare ROI volumes in high-fit versus low-fit individuals revealed marginal significance for the left HC, but no other ROI. Multiple one-way between-subject ANOVAs conducted to compare cognitive performance in high-fit versus low-fit individuals also revealed no significant results. Considering the marginal significance achieved by the one-way between-subjects ANOVA for CRF and left HC, a larger sample size is needed to potentially achieve significant statistical significance. Given these remaining null results, further investigation is suggested using additional neuroimaging analyses that split the DG/CA3 into its anterior and posterior sections, as well as examining different aspects of the RAVLT or utilizing more sensitive episodic memory tests.

Neurosciences

Cardiorespiratory fitness

Hippocampus

Functional requirements determine relevant ingredients to model for on-line acquisition of context dependent memory

Koene, Randal A.

January 2005

No description available.

Memory.

Hippocampus (Brain)

Neurophysiology.

On the role of the hippocampus in episodic memory

Pisa, Michele A.

January 1978

Note:

Hippocampus (Brain)

Rats -- Behavior.

Voluntary Wheel Running Alters Brain-Derived Neurotrophic Factor Levels in the Hippocampus of Senescence Accelerated Mice

Janke, Kellie

05 April 2009

No description available.

Psychology

BDNF

Exercise

Hippocampus