Modeling and treatment of rat cervical spinal cord injury

Gensel, John Carib

05 January 2007

No description available.

Biology, Neuroscience

spinal cord injury

cervical

contusion

model

gray matter

neuroprotective

grooming

topiramate

minocycline

methylprednisolone

unilateral

hemicontusion

neuroprotection

translational research

excitotoxicity

glutamate

AMPA

excitotoxic

rat

Differential regulation of GABAB receptor trafficking by different modes of N-methyl-D-aspartate (NMDA) receptor signaling

Kantamneni, Sriharsha, Gonzàlez-Gonzàlez, I.M., Luo, J., Cimarosti, H., Jacobs, S.C., Jaafari, N., Henley, J.M.

2013 December 1924

Yes / Inhibitory GABAB receptors (GABABRs) can down-regulate most excitatory synapses in the CNS by reducing postsynaptic excitability. Functional GABABRs are heterodimers of GABAB1 and GABAB2 subunits and here we show that the trafficking and surface expression of GABABRs is differentially regulated by synaptic or pathophysiological activation of NMDA receptors (NMDARs). Activation of synaptic NMDARs using a chemLTP protocol increases GABABR recycling and surface expression. In contrast, excitotoxic global activation of synaptic and extrasynaptic NMDARs by bath application of NMDA causes the loss of surface GABABRs. Intriguingly, exposing neurons to extreme metabolic stress using oxygen/glucose deprivation (OGD) increases GABAB1 but decreases GABAB2 surface expression. The increase in surface GABAB1 involves enhanced recycling and is blocked by the NMDAR antagonist AP5. The decrease in surface GABAB2 is also blocked by AP5 and by inhibiting degradation pathways. These results indicate that NMDAR activity is critical in GABABR trafficking and function and that the individual subunits can be separately controlled to regulate neuronal responsiveness and survival. / BBSRC, MRC and the European Research Council

Chem-LTP

G Protein-coupled Receptors (GPCR)

GABA Receptors

GABAB Receptor

Glutamate Receptor Ionotropic (AMPA

NMDA)

Neurodegeneration

Neurotransmitter Receptors

Oxygen-glucose Deprivation (OGD)

Receptor Endocytosis

Receptor Recycling

Die Bedeutung der Proteine 4.1G und 4.1N für den Aufbau und die Funktion glutamaterger Synapsen / The role of proteins 4.1G and 4.1N for the composition and function of glutamatergic synapses

Wolk, Friederike

09 July 2009

No description available.

570 Biowissenschaften, Biologie

Mathematics and Computer Science

synaptische Transmission

AMPA-Rezeptor

4.1 Proteine

PSD

Hippocampus

Cerebellum

synaptic transmission

AMPA receptor

4.1 proteins

PSD

hippocampus

cerebellum

42.13

42.15

42.17

WF 200: Molekularbiologie

Neuroligin-4: Einfluss auf die synaptische Übertragung exzitatorischer Neurone der Schicht IV des Barrel-Kortex / Neuroligin-4: Effect on synaptic transmission of excitatory neurons in layer IV of barrel-cortex

Olt, Stephen

20 November 2013

Neuroligine (NL) sind vorwiegend postsynaptisch lokalisierte transmembrane Adhäsionsmoleküle, die in Wechselwirkung mit dem präsynaptisch lokalisierten Protein Neurexin eine wichtige Rolle in der Reifung und Funktion von Synapsen spielen. Es existieren verschiedene NL-Isoproteine (NL-1 – NL-4), die sich in ihrer Assoziation zu exzitatorischen und inhibitorischen Synapsen unterscheiden. Die funktionelle und klinische Relevanz der Neuroligine belegen beispielhaft Mutationen des Isotyps NL 4, welche mit neuropsychiatrischen Erkrankungen wie Autismus-Spektrum-Störungen assoziiert vorkommen. Anhand eines durch Ausschalten des human-orthologen NL-4-Gens generierten Mausmodells (NL 4 Knockout, NL 4 KO) konnte in vorhergehenden Studien die Bedeutung einer immunhistochemisch beobachteten Lokalisation von NL 4 an glycinergen Synapsen der Retina für die inhibitorische synaptische Übertragung nachgewiesen werden. Im Unterschied dazu konnte kein Zusammenhang zwischen einer in Schicht IV des Barrel-Kortex nachweisbaren Lokalisation von NL-4 mit inhibitorischen Synapsen hergestellt werden. Deshalb, und aufgrund der in Schicht IV dominierenden exzitatorischen Verschaltung von thalamischen Projektionen und den kolumnenassoziierten Rückverschaltungen aus dem Neokortex, lässt sich eine Interaktion von NL-4 mit exzitatorischen Synapsen in diesem Areal vermuten. Im Rahmen der vorliegenden Arbeit wurde anhand der NL-4-KO-Modellmaus der Frage nachgegangen, inwiefern NL-4 die exzitatorische synaptische Übertragung im Barrel-Kortex beeinflusst. Dafür wurden mit Hilfe der Patch-Clamp-Technik abgeleitete AMPA-Rezeptor-vermittelte exzitatorische postsynaptische Ströme (EPSC) von bedornten Sternzellen, Sternpyramiden- und Pyramidenzellen der Schicht IV ausgewertet und zwischen NL-4-Wildtyp- (NL 4-WT) und NL 4 KO-Neuronen verglichen. Dabei zeigten NL 4-KO-Neurone signifikant veränderte Parameter der EPSC-Kinetik. Die Abfallszeit war in NL 4 KO-Neuronen signifikant länger, das maximale Gefälle und die maximale Steigung signifikant flacher gegenüber NL-4-WT-Kontrollen. Diese Veränderungen sprechen für eine funktionelle Relevanz von NL-4 für die AMPA-Rezeptor-vermittelte synaptische Übertragung auf exzitatorische Neurone in Schicht IV des Barrel-Kortex. Das Muster der in NL-4-KO-Neuronen veränderten EPSC-Kinetik weist dabei auf eine Modulation der biophysikalischen AMPA-Rezeptoreigenschaften hin und könnte mit Veränderungen der synaptisch exprimierten AMPA-Rezeptor-TARP-Subtypen in Zusammenhang stehen, die über Proteine der postsynaptischen Dichte (wie PSD-95 und S SCAM) mit Neuroliginen interagieren.

610

Neuroligin-4

Neurexin

AMPA-Rezeptor

Patch-Clamp-Technik

Exzitatorische Neurone

Barrel-Kortex

Schicht 4

Synaptische Übertragung

Exzitatorische postsynaptische Ströme

EPSC

neuroligin-4

neurexin

ampa-receptor

patch-clamp

excitatory neurons

barrel-cortex

synaptic transmission

excitatory postsynaptic currents

epsc

layer 4

Estrogens Rapidly Enhance Neural Plasticity and Learning

Phan, Anna

24 July 2013

This thesis examines the rapid, non-genomic effects of estrogens on neural plasticity and learning. Estrogens are classically known to affect gene transcription events, however they have more recently been found to also rapidly activate second messenger systems within 1hr of administration. Therefore, we first examined the rapid effects of 17β-estradiol, and an estrogen receptor (ER) α and ERβ agonist on three different learning paradigms: object placement, object recognition, and social recognition. We found that both systemic injections and intrahippocampal delivery of 17β-estradiol and the ERα agonist improved performance on all 3 learning paradigms within 40min of hormone administration. However, the ERβ agonist administered systemically or intrahippocampally, improved performance only on the object placement learning paradigm, while having no effect on object recognition, and impairing social recognition at high doses. To elucidate how estrogens might rapidly affect learning, we examined how estrogens rapidly affect the neural plasticity of CA1 hippocampal neurons. We found that 17β-estradiol and the ERα agonist increased dendritic spine density in CA1 hippocampal neurons within 40min of administration, suggesting that estrogens rapidly increase the density of synapses within this brain region. Conversely, the ERβ agonist did not affect spine density, or decreased spine density. In addition, by using whole-cell patch clamp recordings of CA1 pyramidal neurons, we were able to determine that 17β-estradiol and the ERα agonist rapidly reduced AMPA receptor (but not NMDA receptor) mediated membrane depolarizations after 15min of hormone application. Similar to above, the ERβ agonist had no effect on AMPA or NMDA receptor mediated membrane depolarizations. These data suggest that estrogens rapidly promote the development of immature synapses (which contain low levels of synaptic AMPA receptors) within the CA1 hippocampus. Immature spines provide synaptic sites at which new memories can be stored and are thought of as “learning spines” (Kasai et al, 2003). Therefore, estrogens (through ERα) may rapidly induce the formation of hippocampal immature spines to promote learning. / Funded by NSERC

Estrogen

Estradiol

Learning

Memory

Object Placement

Object Recognition

Social Recognition

Non-genomic

AMPA

NMDA

Dendritic Spines

Electrophysiology

LTP

LTD

Hippocampus

CA1

GPER

ERα

ERβ

Mice

Immature synapse

Synaptic plasticity

Structural plasticity

Glutamate

Learning spine

Memory spine

Sound encoding in mutant mice with disrupted action potential generation

Yamanbaeva, Gulnara

21 August 2017

No description available.

570

WRB

PSD-95

AMPA receptors recycling

ßIV-spectrin

single unit in vivo recording

spiral ganglion neuron

in vivo electrophysiology

STED microscopy

inner hair cell ribbon synapse

otoferlin

cochlear nucleus neuron

action potential generation

sound encoding

Biologie (PPN619462639)

Evaluating a Novel Photochemical Tool for Labeling and Tracking Live, Endogenous Calcium-Permeable AMPARs

Combs-Bachmann, Rosamund Elizabeth

13 July 2016

The purpose of this research is to advance development of a photochemical tool designed to probe the role of ionotropic glutamate receptor signaling in neurodegenerative processes, and to delve more deeply into the biological processes underlying the role of these receptors in signaling and memory formation. This ligand-targeted nanoprobe was designed and developed in our lab to label endogenous calcium-permeable AMPARs (CP-AMPARs) in live cells with minimal disruption to native receptor activity. Nanoprobe is designed to use naphthyl acetyl spermine (NASPM) as a photocleavable ligand to target and covalently label native CP-AMPARs with a non-perturbing, fluorescent marker that then allows observation of these receptors using standard epifluorescence microscopy. My contribution to this work, outlined in the aims below, is the characterization of nanoprobe using electrophysiology and fluorescent imaging to evaluate its effectiveness as an endogenous CP-AMPAR label on live neurons. Aim 1: To use whole cell patch clamp electrophysiology to test the labeling of CP-AMPARs with nanoprobe by recording changes in glutamate-evoked current through heterologously expressed GluA1-L497Y homomultimers during, pre- and post- nanoprobe labeling. Aim 2: To use fluorescent imaging to evaluate nanoprobe labeling of glutamate receptors endogenously expressed in hippocampal neurons by co-labeling nanoprobe-treated neurons with traditional antibodies to AMPAR and synaptic targets. Aim 3: To use nanoprobe to detect endogenously expressed CP-AMPARs on live neurons during the course of neuron development. Live neuronal cultures will be imaged before and after labeling with nanoprobe in young dissociated cultures (DIV 1-2) and in maturing cultures (DIV 14-17). Conclusions: Whole cell patch clamp electrophysiology results provide evidence that nanoprobe will label CP-AMPARs in a minimally-perturbing fashion that allows the receptors to resume normal activity after photolytic-release of ligand as designed. Fixed cell imaging of CP-AMPAR nanoprobe labeling was largely ineffective, and live cell imaging was not conclusive, but provided supporting evidence that nanoprobe targets and labels NASPM-sensitive endogenous glutamate receptors on live dissociated hippocampal neurons

calcium-permeable AMPA receptors

receptor trafficking

fluorescent labeling

ligand-directed labeling

endogenous receptors

labeling live receptors

Biology

Cell and Developmental Biology

Molecular and Cellular Neuroscience

Neuroscience and Neurobiology

Neurosciences

Analysis of CPEB Family Protein Member CPEB4 Function in Mammalian Neurons: A Dissertation

Kan, Ming-Chung

01 June 2008

Local protein synthesis is required for long-term memory formation in the brain. One protein family, Cytoplasmic Polyadenylation Element binding Protein (CPEB) that regulates protein synthesis is found to be important for long-term memory formation possibly through regulating local protein synthesis in neurons. The well-studied member of this family, CPEB1, mediates both translational repression and activation of its target mRNAs by regulating mRNA polyadenylation. Mouse with CPEB1 KO shows defect in memory extinction but not long-term memory formation. Three more CPEB1 homologs (CPEB2-4) are identified in mammalian system. To test if CPEB2-4 may have redundant role in replacing CPEB1 in mediating local protein synthesis, the RNA binding specificity of these homologs are studied by SELEX. The result shows CPEB2-4 bind to RNAs with consensus sequence that is distinct from CPE, the binding site of CPEB1. This distinction RNA binding specificity between CPEB1 and CPEB2-4 suggests CPEB2-4 cannot replace CPEB1 in mediating local protein synthesis. For CPEB2-4 have distinct RNA binding specificity compared to CPEB1, they are referred as CPEB-like proteins. One of CPEB-like protein, CPEB3, binds GluR2 mRNA and represses its translation. The subcellular localization of CPEB family proteins during glutamate over stimulation is also studied. The CPEB family proteins are identified as nucleus/cytoplasm shuttling proteins that depend on CRM1 for nuclear export. CPEB-like proteins share similar nuclear export ciselement that is not present in CPEB1. Over-stimulation of neuron by glutamate induces the nuclear accumulation of CPEB family proteins possibly through disrupted nuclear export. This nuclear accumulation of CPEB family protein is induced by imbalance of calcium metabolism in the neurons. Biochemical and cytological results suggest CPEB4 protein is associated with ER membrane peripherally in RNA independent manner. This research provides general description of biochemical, cytological properties of CPEB family proteins.

Neurons

Protein Biosynthesis

RNA

Messenger

RNA-Binding Proteins

Receptors

AMPA

Memory

Transcription Factors

Gene Expression Regulation

Amino Acids, Peptides, and Proteins

Cells

Genetic Phenomena

Nervous System

Exploring the effects of 5-HT2A and AMPA receptors on brain 5-HT via a mechanism-based pharmacodynamic model

Zhou, Zhu

01 January 2014

Depression is a common mood disorder. Although major ethical challenges make it nearly impossible to invasively and directly measure serotonin (5-hydroxytryptamine, 5-HT) levels in human brains, neuroimaging technologies have shown macroscopic structural and functional abnormalities in the prefrontal cortex (PFC) of depressed patients. The monoamine hypothesis of depression is based on the neurotransmitter imbalance, such as deceased serotonin brain levels are implicated in the cause of depression. Research has focused on the control mechanisms involved in the dorsal raphé nucleus (DRN) which is the serotonergic control center located in the midbrain. We hypothesized that activation 5-HT 2A receptor in PFC would increase serotonin levels by an AMPA-dependent mechanism in both DRN and PFC. Enhancement of the 5-HT in DRN may inhibit 5-HT level in PFC by 5-HT 1A receptor. This becomes the full feedback loop system. While 5-HT levels in the PFC have been well studied, pathway that modulate this DRN pool through upstream cascade interactions leading to a downstream feedback loop have been difficult to elucidate. Developing a mechanism-based pharmacokinetics (PK) and pharmacodynamics (PD) model to quantitatively describe the effect of 5-HT 2A receptors regulation to serotonin in the DRN and PFC would help us to better understand the complex brain. 5-HT 2A receptor agonist and AMPA receptor agonist and antagonist were used to activate or block the related receptor. Male Wistar rats underwent neurosurgery for implantation of microdialysis (MD) probes. Three to five rats were randomly assigned to experimental arms. Using the MD method, the drug combination was examined to explore the drug effect on time course of 5-HT release in DRN and PFC. Based on the experiment results, a mechanism-based PD model was developed. Phoenix WinNonlin ® and Berkeley Madonna™ were used for model estimation, external validation with secondary data set, and simulation. The result supports the possibility of a 5-HT 2A /AMPA feedback control circuit that originates in the PFC and modulates DRN and PFC 5-HT levels through feedback coupling of 5-HT. The time-course profiles of 5-HT in both DRN and PFC was well modeled and model parameters were estimated with good precision (CV% ranged from 1.37% to 35.03%). The mechanism model was developed to characterize and better understand the neurotransmitter mechanisms, providing estimations of various parameters of the disease related receptor system.

Pharmacy sciences

Health and environmental sciences

AMPA receptors

Depression

Mood disorder

Serotonin

Chemicals and Drugs

Chemistry

Medical Pharmacology

Medicinal-Pharmaceutical Chemistry

Medicine and Health Sciences

Pharmaceutical Preparations

Pharmacy and Pharmaceutical Sciences

Physical Sciences and Mathematics

Estrogenic Modulation of Fear Generalization

Lynch, Joseph Francis, III

06 July 2016

No description available.

Animals

Behavioral Psychology

Biology

Endocrinology

Experimental Psychology

Neurobiology

Pharmacology

estrogens

fear generalization, rats

passive avoidance

context fear generalization

testosterone

gonadal hormones

hippocampus

Posttraumatic stress disorder

anterior cingulate cortex

NMDA

AMPA

glutamatergic signaling