B-Ephrin Reverse Signaling Is Required for NMDA-Independent Long-Term Potentiation of Mossy Fibers in the Hippocampus

The application of tetraethylammonium (TEA), a blocker of voltage-dependent potassium channels, can induce long-term potentiation (LTP) in the synaptic systems CA3–CA1 and mossy fiber-CA3 pyramidal cells of the hippocampus. In the mossy fibers, the depolarization evoked by extracellular TEA induces a large amount of glutamate and also of zinc release. It is considered that zinc has a neuromodulatory role at the mossy fiber synapses, which can, at least in part, be due to the activation of presynaptic ATP-dependent potassium (KATP) channels. The aim of this work was to study properties of TEA-induced zinc signals, detected at the mossy fiber region, using the permeant form of the zinc indicator Newport Green. The application of TEA caused a depression of those signals that was partially blocked by the KATP channel inhibitor tolbutamide. After the removal of TEA, the signals usually increased to a level above baseline. These results are in agreement with the idea that intense zinc release during strong synaptic events triggers a negative feedback action. The zinc depression, caused by the LTP-evoking chemical stimulation, turns into potentiation after TEA washout, suggesting the existence of a correspondence between the observed zinc potentiation and TEA-evoked mossy fiber LTP.

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ADAPTIVE CEREBELLAR SPIKING MODEL EMBEDDED IN THE CONTROL LOOP: CONTEXT SWITCHING AND ROBUSTNESS AGAINST NOISE

International Journal of Neural Systems ◽

10.1142/s0129065711002900 ◽

2011 ◽

Vol 21 (05) ◽

pp. 385-401 ◽

Cited By ~ 54

Author(s):

N. R. LUQUE ◽

J. A. GARRIDO ◽

R. R. CARRILLO ◽

S. TOLU ◽

E. ROS

Keyword(s):

Degrees Of Freedom ◽

Mossy Fibers ◽

Long Term Potentiation ◽

Biologically Inspired ◽

Context Switching ◽

Term Potentiation ◽

Spiking Network ◽

Three Degrees Of Freedom ◽

Spiking Model

This work evaluates the capability of a spiking cerebellar model embedded in different loop architectures (recurrent, forward, and forward&recurrent) to control a robotic arm (three degrees of freedom) using a biologically-inspired approach. The implemented spiking network relies on synaptic plasticity (long-term potentiation and long-term depression) to adapt and cope with perturbations in the manipulation scenario: changes in dynamics and kinematics of the simulated robot. Furthermore, the effect of several degrees of noise in the cerebellar input pathway (mossy fibers) was assessed depending on the employed control architecture. The implemented cerebellar model managed to adapt in the three control architectures to different dynamics and kinematics providing corrective actions for more accurate movements. According to the obtained results, coupling both control architectures (forward&recurrent) provides benefits of the two of them and leads to a higher robustness against noise.

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Rapid Translocation of Zn2+ From Presynaptic Terminals Into Postsynaptic Hippocampal Neurons After Physiological Stimulation

Journal of Neurophysiology ◽

10.1152/jn.2001.86.5.2597 ◽

2001 ◽

Vol 86 (5) ◽

pp. 2597-2604 ◽

Cited By ~ 179

Author(s):

Yang Li ◽

Christopher J. Hough ◽

Sang Won Suh ◽

John M. Sarvey ◽

Christopher J. Frederickson

Keyword(s):

Hippocampal Neurons ◽

Hippocampal Slices ◽

Mossy Fibers ◽

Synaptic Cleft ◽

Immediate Release ◽

Long Term Potentiation ◽

Anatomical Location ◽

Term Potentiation ◽

Presynaptic Boutons

Zn2+ is found in glutamatergic nerve terminals throughout the mammalian forebrain and has diverse extracellular and intracellular actions. The anatomical location and possible synaptic signaling role for this cation have led to the hypothesis that Zn2+ is released from presynaptic boutons, traverses the synaptic cleft, and enters postsynaptic neurons. However, these events have not been directly observed or characterized. Here we show, using microfluorescence imaging in rat hippocampal slices, that brief trains of electrical stimulation of mossy fibers caused immediate release of Zn2+ from synaptic terminals into the extracellular microenvironment. Release was induced across a broad range of stimulus intensities and frequencies, including those likely to induce long-term potentiation. The amount of Zn2+ release was dependent on stimulation frequency (1–200 Hz) and intensity. Release of Zn2+ required sodium-dependent action potentials and was dependent on extracellular Ca2+. Once released, Zn2+ crosses the synaptic cleft and enters postsynaptic neurons, producing increases in intracellular Zn2+ concentration. These results indicate that, like a neurotransmitter, Zn2+ is stored in synaptic vesicles and is released into the synaptic cleft. However, unlike conventional transmitters, it also enters postsynaptic neurons, where it may have manifold physiological functions as an intracellular second messenger.

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