EXCEED THE SPACE PROVIDED. Voltage-gated ion channels are involved in nerve impulse propagation, synaptic transmission, muscle action potentials, and excitation/contraction coupling. Abnormal function of voltage-gated channels has been implicated in many neurological diseases, for example, epilepsy, episodic ataxia, and periodic paralyses. An understanding of the normal and pathological function of these channels could lead to the development of treatments for a number of neurological diseases. Voltage-activated ion channels are activated by changes in the voltage across the cell membrane. The classic voltage-activated potassium channels open when the membrane is depolarized. This has been shown to be due to the outward movement of an intrinsic voltage sensor, $4, which triggers the conformational changes that open the channel. However, how the movement of $4 is coupled to the opening of the channel is not understood. Recently, a new class of voltage-activated ion channels were cloned: hyperpolarization-activated cyclic nucleotide-gated ion channels (HCN channels). These channels also contain a putative voltage sensor, $4. Surprisingly, the HCN channels open with the opposite polarity from the voltage-activated potassium channels; that is, the HCN channels open when the membrane is hyperpolarized. We hypothesize that $4 is also the voltage sensor in the HCN channels, but that the coupling between $4 movement and the opening of the channel involves a different mechanism than in voltage-activated potassium channels.
The aim of the proposed project is to determine whether $4 is the voltage sensor in the HCN channels and to compare and contrast the $4 movement in these channels with the $4 movement in voltage-activated potassium channels. The movement of $4 will be measured in cysteine-substituted channels using cysteine-specific fluorescent probes or membrane-impermeable cysteine reagents. These measurements will be used to determine how $4 moves in the different channels and will further our understanding of the different mechanisms of opening of these two classes of channels. PERFORMANCE SITE ========================================Section End===========================================
Lassuthova, Petra; Rebelo, Adriana P; Ravenscroft, Gianina et al. (2018) Mutations in ATP1A1 Cause Dominant Charcot-Marie-Tooth Type 2. Am J Hum Genet 102:505-514 |
Gonzalez, Carlos; Larsson, H Peter (2010) Permeation mechanism in voltage-activated proton channels: a new glimpse. Proc Natl Acad Sci U S A 107:1817-8 |
Vemana, Sriharsha; Pandey, Shilpi; Larsson, H Peter (2008) Intracellular Mg2+ is a voltage-dependent pore blocker of HCN channels. Am J Physiol Cell Physiol 295:C557-65 |
Bruening-Wright, Andrew; Larsson, H Peter (2007) Slow conformational changes of the voltage sensor during the mode shift in hyperpolarization-activated cyclic-nucleotide-gated channels. J Neurosci 27:270-8 |
Bruening-Wright, Andrew; Elinder, Fredrik; Larsson, H Peter (2007) Kinetic relationship between the voltage sensor and the activation gate in spHCN channels. J Gen Physiol 130:71-81 |
Elinder, Fredrik; Mannikko, Roope; Pandey, Shilpi et al. (2006) Mode shifts in the voltage gating of the mouse and human HCN2 and HCN4 channels. J Physiol 575:417-31 |
Mannikko, Roope; Pandey, Shilpi; Larsson, H Peter et al. (2005) Hysteresis in the voltage dependence of HCN channels: conversion between two modes affects pacemaker properties. J Gen Physiol 125:305-26 |
Koch, Hans P; Larsson, H Peter (2005) Small-scale molecular motions accomplish glutamate uptake in human glutamate transporters. J Neurosci 25:1730-6 |
Vemana, Sriharsha; Pandey, Shilpi; Larsson, H Peter (2004) S4 movement in a mammalian HCN channel. J Gen Physiol 123:21-32 |
Broomand, Amir; Mannikko, Roope; Larsson, H Peter et al. (2003) Molecular movement of the voltage sensor in a K channel. J Gen Physiol 122:741-8 |
Showing the most recent 10 out of 11 publications