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Fast Synaptic Transmission (fast + synaptic_transmission)

Distribution by Scientific Domains
Life Sciences50%

Selected Abstracts

Elements of a neurobiological theory of hippocampal function: the role of synaptic plasticity, synaptic tagging and schemas

EUROPEAN JOURNAL OF NEUROSCIENCE, Issue 11 2006
R. G. M. MorrisArticle first published online: 8 JUN 200
Abstract The 2004 EJN Lecture was an attempt to lay out further aspects of a developing neurobiological theory of hippocampal function [Morris, R.G.M., Moser, E.I., Riedel, G., Martin, S.J., Sandin, J., Day, M. & O'Carroll, C. (2003) Phil. Trans. R. Soc. Lond. B Biol. Sci., 358, 773,786.] These are that (i) activity-dependent synaptic plasticity plays a key role in the automatic encoding and initial storage of attended experience; (ii) the persistence of hippocampal synaptic potentiation over time can be influenced by other independent neural events happening closely in time, an idea with behavioural implications for memory; and (iii) that systems-level consolidation of memory traces within neocortex is guided both by hippocampal traces that have been subject to cellular consolidation and by the presence of organized schema in neocortex into which relevant newly encoded information might be stored. Hippocampal memory is associative and, to study it more effectively than with previous paradigms, a new learning task is described which is unusual in requiring the incidental encoding of flavour,place paired associates, with the readout of successful storage being successful recall of a place given the flavour with which it was paired. NMDA receptor-dependent synaptic plasticity is shown to be critical for the encoding and intermediate storage of memory traces in this task, while AMPA receptor-mediated fast synaptic transmission is necessary for memory retrieval. Typically, these rapidly encoded traces decay quite rapidly over time. Synaptic potentiation also decays rapidly, but can be rendered more persistent by a process of cellular consolidation in which synaptic tagging and capture play a key part in determining whether or not it will be persistent. Synaptic tags set at the time of an event, even many trivial events, can capture the products of the synthesis of plasticity proteins set in train by events before, during or even after an event to be remembered. Tag,protein interactions stabilize synaptic potentiation and, by implication, memory. The behavioural implications of tagging are explored. Finally, using a different protocol for flavour,place paired associate learning, it is shown that rats can develop a spatial schema which represents the relative locations of several different flavours of food hidden at places within a familiar space. This schema is learned gradually but, once acquired, enables new paired associates to be encoded and stored in one trial. Their incorporation into the schema prevents rapid forgetting and suggests that schema play a key and hitherto unappreciated role in systems-level memory consolidation. The elements of what may eventually mature into a more formal neurobiological theory of hippocampal memory are laid out as specific propositions with detailed conceptual discussion and reference to recent data. [source]

Expression of Nav1.6 sodium channels by Schwann cells at neuromuscular junctions: Role in the motor endplate disease phenotype

GLIA, Issue 1 2006
Magali Musarella
Abstract In addition to their role in action potential generation and fast synaptic transmission in neurons, voltage-dependent sodium channels can also be active in glia. Terminal Schwann cells (TSCs) wrap around the nerve terminal arborization at the neuromuscular junction, which they contribute to shape during development and in the postdenervation processes. Using fluorescent in situ hybridization (FISH), immunofluorescence, and confocal microscopy, we detected the neuronal Nav1.6 sodium channel transcripts and proteins in TSCs in normal adult rats and mice. Nav1.6 protein co-localized with the Schwann cell marker S-100 but was not detected in the SV2-positive nerve terminals. The med phenotype in mice is due to a mutation in the SCN8A gene resulting in loss of Nav1.6 expression. It leads to early onset in postnatal life of defects in neuromuscular transmission with minimal alteration of axonal conduction. Strikingly, in mutant mice, the nonmyelinated pre-terminal region of axons showed abundant sprouting at neuromuscular junctions, and most of the ,-bungarotoxin-labeled endplates were devoid of S-100- or GFAP-positive TSCs. Using specific antibodies against the Nav1.2 and Nav1.6 sodium channels, ankyrin G and Caspr 1, and a pan sodium channel antibody, we found that a similar proportion of ankyrin G-positive nodes of Ranvier express sodium channels in mutant and wild-type animals and that nodal expression of Nav1.2 persists in med mice. Our data supports the hypothesis that the lack of expression of Nav1.6 in Schwann cells at neuromuscular junctions might play a role in the med phenotype. © 2005 Wiley-Liss, Inc. © 2005 Wiley-Liss, Inc. [source]

A new role for P2 receptors: talking with calcium-activated potassium channels

NEUROGASTROENTEROLOGY & MOTILITY, Issue 11 2007
P. P. Bertrand
Abstract Purinergic fast synaptic transmission may play a very subtle role in regulating the excitability of enteric circuits. That is one of the important findings in a new paper by Ren and Galligan in the current issue of this Journal. They first provide compelling evidence that P2X3 receptors (ionotropic purine receptors) are expressed by guinea-pig motor and interneurons and that these subtypes mediate the purinergic fast excitatory postsynaptic potential (EPSP). They also found that the P2X3 -mediated depolarization was often followed by a hyperpolarization. This is an intriguing finding because if the purinergic fast EPSPs are also followed by a hyperpolarization, then it could play a role in truncating bursts of synaptic potentials or in shaping periodic synaptic input. The hyperpolarization is caused by calcium entry through the P2X3 receptor which then activates a calcium-activated potassium (KCa) channel. Surprisingly, the hyperpolarization was not affected by any of the standard blockers of calcium- or voltage-activated K+ channels suggesting that a novel KCa channel is present in the enteric neurons. Such a wide-spread channel could well have an important physiological role and could be an important new drug target for regulating reflex activity in the enteric nervous system. [source]

Presynaptic modulation of cholinergic and non-cholinergic fast synaptic transmission in the myenteric plexus of guinea pig ileum

NEUROGASTROENTEROLOGY & MOTILITY, Issue 3 2004
K. J. LePard
Abstract, These studies investigated receptors modulating release of mediators of fast excitatory postsynaptic potentials (fEPSPs) in guinea pig ileum myenteric plexus using electrophysiological methods. Fast EPSPs inhibited by >95% by hexamethonium (100 ,mol L,1) were cholinergic; mixed fEPSPs were inhibited <95% by hexamethonium. Non-cholinergic fEPSPs were studied in the presence of hexamethonium. The ,2-adrenergic receptor agonist UK 14304 inhibited cholinergic (maximum inhibition = 76%, EC50 = 18 nmol L,1), mixed (81%, 21 nmol L,1) and non-cholinergic (76%, 44 nmol L,1) fEPSPs equally. The 5-HT1 receptor agonist 5-carboxamidotryptamine inhibited cholinergic, mixed and non-cholinergic fEPSPs equally. Renzapride, increased non-cholinergic (33%) less than mixed (97%, 13 ,mol L,1) fEPSPs. Renzapride inhibited the purely cholinergic fEPSPs (,29%) but potentiated the cholinergic component of mixed fEPSPs (39%). Prucalopride potentiated all fEPSPs equally (30,33%). 5-HT (0.1 ,mol L,1) induced potentiation of cholinergic (75%), mixed (97%) and non-cholinergic (84%) fEPSPs was not statistically different. The potentiating effects of renzapride and 5-HT on fEPSPs were inhibited by the 5-HT4 receptor antagonist, SB 204070 (10 nmol L,1). Renzapride (0.3 ,mol L,1) blocked 5-HT-induced increases in cholinergic fEPSPs. ,2-Adrenergic and 5-HT1 receptors mediate inhibition of transmitter release from cholinergic and mixed terminals. 5-HT and prucalopride, acting at 5-HT4 receptors, facilitate all fEPSPs; renzapride facilitates the cholinergic and non-cholinergic components of mixed fEPSPs but not purely cholinergic fEPSPs. Cholinergic synapses may express few 5-HT4 receptors or a renzapride-insensitive 5-HT4 receptor isoform. [source]