Presentation is loading. Please wait.

Presentation is loading. Please wait.

Quickening the Pace Neuron

Published byEmmanuelle Blanchard Modified over 5 years ago

Similar presentations

Presentation on theme: "Quickening the Pace Neuron"— Presentation transcript:

1 Quickening the Pace Neuron
Tamara Rosenbaum, Sharona E Gordon  Neuron  Volume 42, Issue 2, Pages (April 2004) DOI: /S (04)

2 Figure 1 Movement of S4 Is Coupled to Gating of HCN Channels
The green cylinders represent the S4 transmembrane segment. Plus signs represent positively charged residues, and circles represent uncharged sites. Black represents residues exposed to either the extracellular or intracellular solutions. Red depicts residues not accessible from either side. Upon depolarization, the S4 segment moves upward to produce closure of the intracellular gate in HCN channels (top right) and opening of the intracellular gate in Kv channels (bottom left). Hyperpolarization causes inward movement of S4 in both channels, resulting in opening of the gate in HCN channels (top left) and closing of the gate in Kv channels (bottom right). The drawing shown here depicts a scenario in which the S4 helix is buried within the channel protein, and depolarization causes it to move up toward the extracellular side. Recently, MacKinnon and collaborators proposed a model in which S4 is in fact a paddle that lies parallel to the membrane in the resting state and moves outward upon depolarization (Jiang et al., 2003). Neuron  , DOI: ( /S (04) )

3 Figure 2 Coupling of the Voltage Sensor to the Intracellular Gate in HCN Channels The green symbols represent the S4 domain. Red cylinders represent the S6 domain which is thought to line the ion-conducting pathway and form the “intracellular gate.” In the closed state, S4 and S6 remain uncoupled. Relatively mild hyperpolarizations allow the channels to enter a preactivated state in which S4 and S6 interact (denoted by the holding hands), but ions cannot permeate through the pore. Further hyperpolarization promotes an opening conformational change. Upon sustained hyperpolarization, the coupling of S4 and S6 can “slip,” leading to an inactivated state. In channels such as HCN2, in which the opening conformation change is relatively favorable, the equilibrium favors opening. In contrast, in channels such as spHCN, in which the opening conformational change is less favorable, the equilibrium favors the inactivated state. Neuron  , DOI: ( /S (04) )

4 Figure 3 Structure of the C Linker and CNBD of HCN2
Four color-coded subunits are shown relative to the S1-S6 core of the channel. Views from the top (180° rotation) reveal that the primary intersubunit interactions occur between C linker regions (left). Removal of the C linkers demonstrates that the CNBD regions have few intersubunit interactions (right). Neuron  , DOI: ( /S (04) )

Download ppt "Quickening the Pace Neuron"

Similar presentations

1 Voltage-Gated Ion Channel: Activation States Li + Ca 2+,Cl -,K +, Na + -Channels In the closed resting state, the cell membrane is polarized, the extracellular.

1 Voltage-Gated Ion Channel: Activation States Li + Ca 2+,Cl -,K +, Na + -Channels In the closed resting state, the cell membrane is polarized, the extracellular.
Chapter 10 Membrane Transport Chapter 10 Membrane Transport Biochemistry I Dr. Loren Williams Biochemistry I Dr. Loren Williams Revised 03/11/2013.

Chapter 10 Membrane Transport Chapter 10 Membrane Transport Biochemistry I Dr. Loren Williams Biochemistry I Dr. Loren Williams Revised 03/11/2013.
Structure and function of voltage-gated Na+ channels. A

Structure and function of voltage-gated Na+ channels. A
Copyright © 2017 McGraw-Hill Education. All rights reserved

Copyright © 2017 McGraw-Hill Education. All rights reserved
Electrical Activity in Axons

Electrical Activity in Axons
Sudden cardiac death: A matter of faulty ion channels?

Sudden cardiac death: A matter of faulty ion channels?
Interaction between Extracellular Hanatoxin and the Resting Conformation of the Voltage-Sensor Paddle in Kv Channels  Hwa C Lee, Julia M Wang, Kenton.

Interaction between Extracellular Hanatoxin and the Resting Conformation of the Voltage-Sensor Paddle in Kv Channels  Hwa C Lee, Julia M Wang, Kenton.
Neurotransmitter Transporters: Structure Meets Function

Neurotransmitter Transporters: Structure Meets Function
A Gate in the Selectivity Filter of Potassium Channels

A Gate in the Selectivity Filter of Potassium Channels
Transmembrane Movement of the Shaker K+ Channel S4

Transmembrane Movement of the Shaker K+ Channel S4
Functional Interactions at the Interface between Voltage-Sensing and Pore Domains in the Shaker Kv Channel  Gilberto J. Soler-Llavina, Tsg-Hui Chang,

Functional Interactions at the Interface between Voltage-Sensing and Pore Domains in the Shaker Kv Channel  Gilberto J. Soler-Llavina, Tsg-Hui Chang,
Vishwanath Jogini, Benoît Roux  Biophysical Journal 

Vishwanath Jogini, Benoît Roux  Biophysical Journal 
Gennady V. Miloshevsky, Peter C. Jordan  Structure 

Gennady V. Miloshevsky, Peter C. Jordan  Structure 
Closing In on the Resting State of the Shaker K+ Channel

Closing In on the Resting State of the Shaker K+ Channel
B.Alexander Yi, Yu-Fung Lin, Yuh Nung Jan, Lily Yeh Jan  Neuron 

B.Alexander Yi, Yu-Fung Lin, Yuh Nung Jan, Lily Yeh Jan  Neuron 
Sebastian Meyer, Raimund Dutzler  Structure 

Sebastian Meyer, Raimund Dutzler  Structure 
Volume 102, Issue 8, Pages (April 2012)

Volume 102, Issue 8, Pages (April 2012)
Common Principles of Voltage-Dependent Gating for Hv and Kv Channels

Common Principles of Voltage-Dependent Gating for Hv and Kv Channels
Volume 20, Issue 8, Pages (August 2012)

Volume 20, Issue 8, Pages (August 2012)
Neurobiology: The acid test for resting potassium channels

Neurobiology: The acid test for resting potassium channels

Similar presentations

Ads by Google