Characterization of the Molecular Mechanisms Regulating the Agrin Signaling Pathway: a Dissertation

Megeath, Laura Jalso

04 October 1999

The nervous system requires rapid, efficient, and accurate transmission between cells for proper functioning. Synapses are the predominant structures through which such vital communication occurs. How synapses are formed, maintained, and eliminated are questions of fundamental importance. At the nerve-muscle synapse, formation of the postsynaptic apparatus is directed by agrin. The hallmark activity of agrin is the aggregation of acetylcholine receptors (AChRs) into dense clusters opposite the presynaptic nerve terminal. Early events in the agrin signal transduction cascade include activation of the receptor tyrosine kinase MuSK and tyrosine phosphorylation of AChRs, but how these events lead to AChR cluster formation is unknown. Using the calcium buffer BAPTA, we demonstrate that intracellular calcium fluxes are necessary for agrin-induced formation of AChR clusters. However, clamping calcium fluxes before agrin stimulation does not alter agrin-induced phosphorylation of either MuSK or AChRs, indicating that this calcium-dependent step occurs downstream of both MuSK and AChR phosphorylation. These results identify a new step in the agrin signaling pathway required for the formation of AChR clusters. We show that intracellular calcium fluxes also play an important role in stabilizing AChR clusters. Clamping intracellular calcium fluxes results in rapid dispersal of AChR clusters and dephosphorylation of both MuSK and AChRs, even if agrin is continually present. Furthermore, the protein tyrosine phosphatase inhibitor pervanadate inhibits both the dispersal and dephosphorylation, indicating a role for a tyrosine phosphatase in AChR cluster dispersal. Our data indicate that AChR clusters are maintained by agrin/MuSK-induced intracellular calcium fluxes that tonically inhibit a tyrosine phosphatase localized to AChR clusters. Our findings also show that distinct molecular mechanisms mediate the formation and the dispersal of agrin-induced AChR clusters. The work presented here expands our understanding of synaptic differentiation in several ways. First, I characterized a new, calcium-dependent step required for the formation of agrin-induced AChR clusters. Next, I showed that postsynaptic specializations must be actively maintained, and describe a molecular mechanism that stabilizes AChR clusters. Finally, dispersal and formation of AChR clusters occurs by distinct pathways. Our understanding of the mechanisms regulating the formation and modulation of synapses will help us to better understand how the nervous system develops and responds to the world around us.

Neuromuscular Junction

Agrin

Synaptic Transmission

Amino Acids, Peptides, and Proteins

Nervous System

Molecular Mechanisms of Neuropeptide Secretion from Neurohypophysial Terminals: a Dissertation

McNally, James M.

19 May 2008

A clear definition of the mechanisms involved in synaptic transmission is of paramount importance for the understanding of the processes governing synaptic efficacy. Despite decades of intense study, these mechanisms remain poorly understood. The work contained in this thesis examines several such mechanisms using the hypothalamic-neurohypophysial system (HNS), a classical preparation for the study of Ca2+-dependent neuropeptide release. The first portion of this thesis is comprised of my efforts to define the cellular machinery essential for the exocytosis of secretory granules isolated from peptidergic neurohypophysial terminals of the HNS. Here, using the planar lipid bilayer model system, I have been able to show that syntaxin alone in the target membrane is sufficient to elicit fusion of modified neurohypophysial secretory granules. Surprisingly, SNAP-25 does not appear to be necessary for this process. This suggests that syntaxin may be able to substitute for SNAP-25 to form functional non-cognate fusion complexes. Additionally, the coupling of amperometric detection with the planar lipid bilayer system has allowed me to confirm these results using native, unmodified secretory granules, and also provides some insight into the kinetics of release in this reconstituted system. This model system should provide a convenient means for the study of additional regulatory factors believed to be involved in secretory vesicle exocytosis. The second and third sections of this thesis involve my examination of the role of presynaptic Ca2+ stores in neuropeptide secretion from isolated peptidergic neurohypophysial terminals (NHT). I initially examined the source of recently discovered ryanodine-sensitive Ca2+ stores in this system. Using Immuno-electron microscopy I have found that ryanodine receptor (RyR) labeling appears to co-localize with large dense core granules. Additionally, I have shown that a large conductance cation channel, with similarities to the RyR, found in the membrane of these granules has the same characteristic response to pharmacological agents specific for the RyR. Further, application of RyR agonists modulates basal neuropeptide release from NHT. These results suggest that the large dense core granules of NHT serve as the source of a functional ryanodine-sensitive Ca2+store. Recent work has revealed that spark-like Ca2+ transients, termed syntillas, can be observed in NHT. These syntillas arise from ryanodine-sensitive intracellular stores. In other neuronal preparations, similar Ca2+ transients have been suggested to affect spontaneous transmitter release. However, such a role for syntillas had yet to be examined. To assess if syntillas could directly trigger spontaneous release from NHT, I used simultaneous Ca2+imaging along with amperometric detection of release. Amperometry was adapted to this system via a novel method of false-transmitter loading. Using this approach I have found no apparent correlation between these two events, indicating that syntillas are unable to directly elicit spontaneous transmitter release. As this finding did not rule out an indirect modulatory role of syntillas on release, I additionally present some preliminary studies examining the ability of ryanodine-sensitive Ca2+ release to modulate vesicular priming. Using immunocytochemistry, I have shown that RyR agonist treatment shifts the distribution of neuropeptides toward the plasma membrane in oxytocinergic NHT, but not in vasopressinergic NHT. RyR antagonists have the opposite affect, again only in oxytocinergic NHT. Further, I have found that application of RyR agonists result in a facilitation of elicited release in NHT using membrane capacitance recording. This facilitation appears to be due primarily to an increase in recruitment of vesicles to the readily-releasable pool. These findings suggest that ryanodine-sensitive Ca2+stores may be involved in vesicular priming in NHTs. Taken together, the work presented in this thesis provides some new and interesting insights into the underlying mechanisms and modulation of transmitter release in both the HNS and other CNS terminals.

Synaptic Transmission

Presynaptic Terminals

Neurosecretory Systems

Neuropeptides

Calcium Channels

Amino Acids, Peptides, and Proteins

Nervous System

Molecular physiology of signal transmission along the auditory pathway

Butola, Tanvi

16 May 2017

No description available.

570

Piccolo

Bassoon

RIM-BP

LRBA

Cochlea

endbulb of Held

Synaptic transmission

Short-term plasticity

Biologie (PPN619462639)

Characterization of neuropharmacological systems in the mammalian central nervous system

Hicks, T. Philip

January 1979

The effects of a range of neuronal excitants were examined on the firing of central neurones of the cerebral cortex, ventrobasal thalamus, dentate gyrus and dorsal and ventral horns of the spinal cords of urethane anaesthetized rats. These responses were pharmacologically characterized on the basis of their susceptibilities to a number of antagonists and from these results, inferences were made concerning probable receptor mechanisms employed by the agonists. Throughout these experiments the technique of iontophoresis was found to be an ideal one for evaluating the effects of agonists and antagonists on single neurones. Neurones in the cortex, thalamus and Renshaw cells of the spinal cord were readily excited by acetylcholine. These responses were elicited also by both nicotinic and muscarinic cholinomimetics. Excitations produced by acetylcholine and acetyl-β-methylcholine were antagonized by atropine and those of acetylcholine and nicotinic agonists were blocked by nicotinic antagonists. The results may be interpreted as revealing a difference between excitatory cholinergic receptors in the rat and in the cat; the nature of these receptors is discussed. to The excitatory responses of ventrobasal thalamic neurones iontophoretically applied amino acids related to glutamate and aspartate could be blocked both by glutamate diethylester and α-aminoadipate. These two antagonists were found to possess different mechanisms of action however, as the ranking orders of susceptibility of the agonists differed for each antagonist. An analysis of these orders led to the proposal that more than one and possibly as many as three different receptors for the excitatory amino acids exist on central neurones. A number of additional compounds were tested for an evaluation of their antagonistic properties against the amino acid induced responses, and these results are discussed in light of possible steric requirements of the receptors. Granule cells of the dentate gyrus were excited by the amino acids and by their synaptic responses to stimulation of perforant path and commissural inputs. A differential effectiveness of glutamate diethylester and α-aminoadipate was suggestive that two distinct excitatory amino acid receptors, both of which appear to be of synaptic significance, coexist on the same neurones. The effects of octopamine were compared with those of catecholamines on neurones of the cortex and dorsal horn of the spinal cord. Both excitation and depression of neuronal firing was observed with octopamine and these responses appeared not to be correlated with those effected by the catecholamines. A further separation of the actions of octopamine and the catecholamines was evident when the amine induced responses were compared in the presence of the antagonists, propranolol and α-flupenthixol. These blocking compounds were effective in attenuating the effects of the catecholamines, but had no effect upon the octopamine induced changes in firing rate. The results suggest that receptors sensitive to octopamine and which appear to be pharmacologically distinct from those previously categorized as catecholamine receptors, may exist on central neurones of the rat. On the basis of the present findings, it was evident that when the technique of iontophoresis is combined with standard neurophysiological methods of identifying central neurones by their responses to synaptic stimulation, valuable information can be obtained concerning the nature of the synaptic transmitters employed by these cells. / Medicine, Faculty of / Cellular and Physiological Sciences, Department of / Graduate

Neuropharmacology

Neural transmission

Central nervous system

Central Nervous System -- drug effects

Synaptic Transmission

Mechanismen der synaptischen Übertragung an der zerebellären Moosfaser-Körnerzell-Synapse

Delvendahl, Igor

24 January 2017

Die Funktion unseres Zentralnervensystems beruht auf der zeitlich präzisen Übertragung elektrischer Signale zwischen Neuronen. Diese synaptische Übertragung findet in weniger als einer tausendstel Sekunde statt. Eine schnelle und hochfrequente Signalübertragung erweitert die Kodierungskapazität und beschleunigt die Verarbeitung von Informationen. Obwohl viele der an synaptischer Übertragung beteiligten Prozesse und Proteine bekannt sind, ist das Verständnis der Mechanismen, die für eine schnelle und hochfrequente Signalübertragung verantwortlich sind, bisher unvollständig. Um die Mechanismen hochfrequenter synaptischer Übertragung zu untersuchen, wurden in dieser Arbeit prä- und postsynaptische Patch-Clamp Ableitungen an der zerebellären Moosfaser-Körnerzell-Synapse in akuten Hirnschnitten der Maus eingesetzt. Es zeigte sich, dass diese Synapse präsynaptische Aktionspotenziale mit einer Frequenz über einem Kilohertz feuern kann und dass Informationen in diesem Frequenzbereich an die postsynaptische Zelle übertragen werden können. Hierbei vermitteln besonders schnelle Natrium- und Kalium-Kanäle eine extrem kurze Dauer der Aktionspotenziale, die dennoch metabolisch relativ effizient sind. Schnelle Kalzium-Kanäle und eine schwache präsynaptische Kalzium-Pufferung ermöglichen eine synchrone Vesikelfreisetzung mit hohen Frequenzen. Zusätzlich greift die Präsynapse auf einen großen Vorrat an freisetzbaren Vesikeln zurück, dessen Auffüllung besonders schnell stattfindet. Aufgrund der hochfrequenten synaptischen Übertragung ist die Moosfaser- Körnerzell-Synapse ideal, um zu untersuchen, wie schnell die auf eine Vesikelfreisetzung folgende Endozytose vonstatten geht. Mit optimierten, hochauflösenden Kapazitätsmessungen konnte an der Moosfaser-Körnerzell- Synapse eine sehr schnelle Endozytose nach einzelnen Aktionspotenzialen gezeigt werden. Die hohe Geschwindigkeit der Endozytose unterstützt somit eine hochfrequente synaptische Übertragung. Diese schnelle Endozytose wird durch die Moleküle Dynamin und Actin vermittelt und ist unabhängig von einer Wirkung von Clathrin. Stärkere Stimuli wie längere Depolarisationen evozieren eine langsamere Form der Endozytose, die zusätzlich Clathrin-abhängig ist. Durch die mechanistische Beschreibung hochfrequenter Signalübertragung an einer zentralen Synapse erweitern die Ergebnisse der vorliegenden Arbeit unser Verständnis von synaptischer Übertragung und Informationsverarbeitung im Zentralnervensystem.

info:eu-repo/classification/ddc/610

ddc:610

Vlivy neurosteroidů na intracelulární vápník a excitotoxicitu / Neurosteroid effects on intracellular calcium and excitotoxicity

Naimová, Žaneta

January 2019

NMDA receptors belong to the family of ionotropic glutamate receptors, and are involved in synaptic plasticity, learning and memory. However, overactivation by the agonist glutamate can lead to neuronal death - excitotoxicity. Exitotoxicity is a result of excessive calcium influx into the cell through NMDA receptors, and is associated with many cental nervous system (CNS) diseases. Neurosteroids are endogenous compounds capable of NMDA receptor modulation, thus they may have pharmacological potential in the treatment of CNS disorders. The aim of this work was to investigate how pregnanolone sulfate (PA-S) and pregnanolone hemipimelate (PA-hPim) influence somatic calcium and excitotoxicity. We used fluorescence microscopy for recording changes in somatic calcium concentration. We observed that PA-S had no influence on relative somatic calcium concentration. Synthetic analog PA-hPim increased somatic calcium levels slightly. Next, we used oxygen-glucose deprivation (OGD) in vitro to study the influence of neurosteroids on excitotoxicity. Both PA-S and PA-hPim were neuroprotective in the model of acute OGD in vitro. Moreover, PA-S or PA-hPim pretreatment induced ischemic tolerance to a subsequent OGD episode. Our results suggest that neurosteroids PA-S and PA-hPim are potential candidates for the development...

Astrocyte-Neuron Interactions Regulate Nervous System Assembly and Function: A Dissertation

Muthukumar, Allie

08 January 2015

Astrocytes densely infiltrate the brain and intimately associate with synaptic structures. In the past 20 years, they have emerged as critical regulators of both synapse assembly and synapse function. During development, astrocytes modulate the formation of new synapses, and later, control refinement of synaptic connections in response to activity dependent cues. In a mature nervous system, astrocytes modulate synapse function through a variety of mechanisms. These include ion buffering, neurotransmitter uptake and the release of molecules that activate synaptic receptors. Through such roles, astrocytes shape the structure and function of neuronal circuits. However, how astrocytes and synapses reciprocally communicate during circuit assembly remains an unanswered question in the field. The vast majority of our understanding of astrocyte biology has come from studies conducted in mammals, where it is challenging to dissect molecular mechanisms with cell type specificity. Drosophila melanogaster is a less established model system for studying astrocyteneuron interactions, but its vast array of genetic tools and rapid life cycle promises great potential for precisely targeted manipulations. My thesis work has utilized Drosophila melanogaster to investigate the reciprocal nature of astrocyte-synapse communication. First, I characterized Drosophila late metamorphosis as a developmental stage in which astrocyte-synapse associations can be studied. My work demonstrates that during this time, when the adult Drosophila nervous system is being assembled, synapse formation relies on the coordinated infiltration of astrocyte membranes into the neuropil. Next, I show that in a reciprocal manner, neural activity can shape astrocyte biology during this time as well and impart long lasting effects on neuronal circuit function. In particular expression of the astrocyte GABA transporter (GAT) is modulated in an activity-dependent manner via astrocytic GABABR1/2 receptor signaling. Inhibiting astrocytic GABABR1/2 signaling strongly suppresses hyperexcitability in a Drosophila seizure model, vii arguing this pathway is important for modulating excitatory/inhibitory balance in vivo. Finally, utilizing the ease of the Drosophila system, I performed a reverse genetic screen to identify additional astrocyte factors involved in modulating excitatory-inhibitory neuronal balance.

Astrocytes

Synapses

Synaptic Transmission

Drosophila melanogaster

Neurons

Dissertations, UMMS

Developmental Neuroscience

Molecular and Cellular Neuroscience

Neuroscience and Neurobiology

A Novel Communication Mechanism Between the Presynapse and Postsynapse Through Exosomes: A Dissertation

Korkut, Ceren

10 August 2012

The minimal element of the nervous system, the synapse, is a plastic structure that has the ability to change in response to various internal and external factors. This property of the synapse underlies complex behaviors such as learning and memory. However, the exact molecular and cellular mechanisms involved in this process are not fully understood. To understand the mechanisms that regulate synapse development and plasticity I took advantage of a powerful model system, the Drosophila larval neuromuscular junction (NMJ). In this system, both anterograde and retrograde signaling pathways critical for coordinated synapse development and plasticity have been documented. An anterograde WNT/Wingless (Wg) signaling pathway plays a crucial role in both developmental and activity-dependent synaptic plasticity at the NMJ. Presynaptic motor neuron terminals secrete highly hydrophobic Wg, which travels to relatively distant postsynaptic sites where it activates a signal transduction pathway required for postsynaptic development. In the first half of my thesis I unraveled a previously unrecognized cellular mechanism by which Wg is shuttled to postsynaptic sites. In this mechanism Wg rides on secreted microvesicles or exosomes that contain a dedicated WNT secretion factor, the WNT-binding transmembrane protein, Evenness Interrupted/Wntless/Sprinter (Evi/Wls/Srt). To our knowledge, this was the first in vivo study demonstrating that neurons release exosomes, which are involved in trans-synaptic communication. Moreover, this was the first study showing that hydrophobic WNT signals are transported to the extracellular space on exosomes to reach WNT-receptor containing target cells. Retrograde signals are also critical during development and plasticity of synaptic connections. These signals function to adjust the activity of presynaptic cells according to postsynaptic cell outputs, to maintain synaptic function within a dynamic range. However, the mechanisms that trigger the release of retrograde signals and the role of presynaptic cells in this signaling event are not clear. In the second half of my thesis, I provided evidence that a crucial component of retrograde signaling at the fly NMJ, Synaptotagmin-4 (Syt4), is transmitted to the postsynaptic cell through anterograde delivery of Syt4 via exosomes. Drosophila Syt4 is known to reside on postsynaptic vesicles at the NMJ and function as a calcium sensor to release a retrograde signal upon synaptic activity. This event is required for coordinated maturation of the presynaptic terminal. We demonstrated that retrograde Syt4 function in postsynaptic muscle is required for activity-dependent presynaptic growth. However, surprisingly, Syt4 protein was not synthesized in postsynaptic muscles. Instead, Syt4 was produced in motorneurons and transferred to postsynaptic muscle cells via exosome secretion by presynaptic cells. The above study provided evidence for a presynaptic control of postsynaptic retrograde signaling through exosomal transfer of an essential retrograde signaling component. In summary, this body of work reveals a novel mechanism of trans-synaptic communication through exosomes. While intercellular communication through exosomes had been demonstrated during antigen presentation in the immune system, our studies were the first to substantiate this mode of communication in the nervous system. Thus, these studies provide a significantly deeper and novel understanding of the mechanisms underlying synapse development and plasticity.

Synapses

Synaptic Transmission

Exosomes

Amino Acids, Peptides, and Proteins

Animal Experimentation and Research

Cells

Nervous System

Neuroscience and Neurobiology

An improved method for the estimation of firing rate dynamics using a Kaiser window /

Cherif, Sofiane.

January 2007

No description available.

Computer Simulation.

Action Potentials -- physiology.

Synaptic Transmission -- physiology.

Vestibule, Labyrinth -- physiology

Models, Neurological.

Inhibitory synpatic transmission in striatal neurons after transient cerebral ischemia

Li, Yan

08 December 2009

Large aspiny neurons are the only non-GABAergic neurons in the striatum. After transient cerebral ischemia, large aspiny neurons survive while medium spiny neurons die. Previous studies have shown that differential changes in the intrinsic membrane properties and excitatory synaptic transmission play a role in this selective vulnerability. However, the role of inhibitory synaptic transmission in this selective vulnerability is still unknown. Since inhibitory tone is very important in the control of neuronal excitability, the present study is aimed at examining if there are any changes in inhibitory synaptic transmission in striatal neurons after ischemia and the possible mechanisms. We also examined if facilitation of inhibitory synaptic transmission by muscimol could attenuate ischemic neuronal injury in the striatum after ischemia. Results from this study will improve the understanding of the mechanisms underlying selective neuronal injury after transient cerebral ischemia. We hope this study could contribute to the translational studies for the stroke patients after cardiac arrest. / Indiana University-Purdue University Indianapolis (IUPUI) / In the striatum, large aspiny (LA) interneurons survive transient cerebral ischemia while medium spiny (MS) neurons die. Excitotoxicity is believed to be the major cause for neuronal death after ischemia. Since inhibitory tone plays an important role in the control of neuronal excitability, the present study is aimed at examining if there are any changes in inhibitory synaptic transmission in striatal neurons after ischemia and the possible mechanisms. Transient forebrain ischemia was induced in male Wistar rats using the four-vessel occlusion method. Inhibitory postsynaptic currents (IPSCs) were evoked intrastriatally and whole-cell voltage-clamp recording was performed on striatal slices. The expression of glutamate decarboxylase65 (GAD65) was analyzed using immunohistochemical studies and Western blotting. Muscimol (a specific GABAA receptor agonist) was injected intraperitoneally to the rats (1 mg/kg) to observe ischemic damage, evaluated by counting the survived cells in the striatum after hematoxylin & eosin (HE) staining. The amplitudes of evoked IPSCs were significantly increased in LA neurons while depressed in MS neurons after ischemia. This enhancement was due to the increase of presynaptic release. Muscimol (1 μM) presynaptically facilitated inhibitory synaptic transmission in LA neurons at 24 h after ischemia. The optical density of GAD65-positive terminals and the number of GAD65-positive puncta was significantly increased in the striatum at both 1 day and 3 days after ischemia. Consistently, data from western blotting suggested an increased expression of GAD65 in the striatum after ischemia. For the rats treated with muscimol, the number of survived cells in the striatum was greatly increased compared to the non-treatment group. The present study demonstrates an enhancement of inhibitory synaptic transmission in LA neurons after ischemia, which is contributed by two mechanisms. One is the increased presynaptic release of GABA mediated by presynaptic GABAA receptors. The other is the increased expression of GAD. Facilitation of inhibitory synaptic transmission by muscimol protects striatal neurons against ischemia. Therefore, the enhancement of inhibitory synaptic transmission might reduce excitotoxicity and contribute to the selective survival of LA neurons after ischemia.

inhibitory synaptic transmission

large aspiny neurons

transient cerebral ischemia

striatum

Transient ischemic attack

Cerebral ischemia