Your search keyword '"Metz AE"' showing total 3 results

1. Dendritic D-type potassium currents inhibit the spike afterdepolarization in rat hippocampal CA1 pyramidal neurons.

Author

Metz AE, Spruston N, and Martina M

Subjects

Animals, Dendritic Cells cytology, Elapid Venoms pharmacology, Evoked Potentials physiology, Hippocampus cytology, Male, Patch-Clamp Techniques, Pyramidal Cells cytology, Rats, Rats, Wistar, Shaker Superfamily of Potassium Channels drug effects, Action Potentials physiology, Dendritic Cells physiology, Hippocampus physiology, Pyramidal Cells physiology, Shaker Superfamily of Potassium Channels physiology

Abstract

In CA1 pyramidal neurons, burst firing is correlated with hippocampally dependent behaviours and modulation of synaptic strength. One of the mechanisms underlying burst firing in these cells is the afterdepolarization (ADP) that follows each action potential. Previous work has shown that the ADP results from the interaction of several depolarizing and hyperpolarizing conductances located in the soma and the dendrites. By using patch-clamp recordings from acute rat hippocampal slices we show that D-type potassium current modulates the size of the ADP and the bursting of CA1 pyramidal neurons. Sensitivity to alpha-dendrotoxin suggests that Kv1-containing potassium channels mediate this current. Dual somato-dendritic recording, outside-out dendritic recordings, and focal application of dendrotoxin together indicate that the channels mediating this current are located in the apical dendrites. Thus, our data present evidence for a dendritic segregation of Kv1-like channels in CA1 pyramidal neurons and identify a novel action for these channels, showing that they inhibit action potential bursting by restricting the size of the ADP.

Published

2007

2. Voltage-dependent potassium currents during fast spikes of rat cerebellar Purkinje neurons: inhibition by BDS-I toxin.

Author

Martina M, Metz AE, and Bean BP

Subjects

Action Potentials drug effects, Animals, Cerebellar Cortex cytology, Cerebellar Cortex drug effects, Neural Inhibition drug effects, Neural Inhibition physiology, Organ Culture Techniques, Potassium Channels, Voltage-Gated drug effects, Purkinje Cells drug effects, Rats, Rats, Long-Evans, Reaction Time drug effects, Reaction Time physiology, Shaw Potassium Channels antagonists & inhibitors, Synaptic Transmission drug effects, Synaptic Transmission physiology, Time Factors, Action Potentials physiology, Cerebellar Cortex physiology, Cnidarian Venoms pharmacology, Potassium Channels, Voltage-Gated metabolism, Purkinje Cells physiology, Shaw Potassium Channels metabolism

Abstract

We characterized the kinetics and pharmacological properties of voltage-activated potassium currents in rat cerebellar Purkinje neurons using recordings from nucleated patches, which allowed high resolution of activation and deactivation kinetics. Activation was exceptionally rapid, with 10-90% activation in about 400 mus at +30 mV, near the peak of the spike. Deactivation was also extremely rapid, with a decay time constant of about 300 mus near -80 mV. These rapid activation and deactivation kinetics are consistent with mediation by Kv3-family channels but are even faster than reported for Kv3-family channels in other neurons. The peptide toxin BDS-I had very little blocking effect on potassium currents elicited by 100-ms depolarizing steps, but the potassium current evoked by action potential waveforms was inhibited nearly completely. The mechanism of inhibition by BDS-I involves slowing of activation rather than total channel block, consistent with the effects described in cloned Kv3-family channels and this explains the dramatically different effects on currents evoked by short spikes versus voltage steps. As predicted from this mechanism, the effects of toxin on spike width were relatively modest (broadening by roughly 25%). These results show that BDS-I-sensitive channels with ultrafast activation and deactivation kinetics carry virtually all of the voltage-dependent potassium current underlying repolarization during normal Purkinje cell spikes.

Published

2007

3. R-type calcium channels contribute to afterdepolarization and bursting in hippocampal CA1 pyramidal neurons.

Author

Metz AE, Jarsky T, Martina M, and Spruston N

Subjects

Adenosine Diphosphate physiology, Animals, In Vitro Techniques, Male, Membrane Potentials, Neuronal Plasticity physiology, Patch-Clamp Techniques, Rats, Rats, Wistar, Synapses physiology, Action Potentials physiology, Calcium Channels, R-Type physiology, Hippocampus physiology, Pyramidal Cells physiology

Abstract

Action potentials in pyramidal neurons are typically followed by an afterdepolarization (ADP), which in many cells contributes to intrinsic burst firing. Despite the ubiquity of this common excitable property, the responsible ion channels have not been identified. Using current-clamp recordings in hippocampal slices, we find that the ADP in CA1 pyramidal neurons is mediated by an Ni2+-sensitive calcium tail current. Voltage-clamp experiments indicate that the Ni2+-sensitive current has a pharmacological and biophysical profile consistent with R-type calcium channels. These channels are available at the resting potential, are activated by the action potential, and remain open long enough to drive the ADP. Because the ADP correlates directly with burst firing in CA1 neurons, R-type calcium channels are crucial to this important cellular behavior, which is known to encode hippocampal place fields and enhance synaptic plasticity.

Published

2005