Regulation Of Voltage-Gated Potassium Channels: X-ray Structures Of Cytosolic Components Of The BK Nd Kv Families
Funder
National Health and Medical Research Council
Funding Amount
$235,500.00
Summary
This research will investigate aspects of ion channel gating (opening). Ion channels are specialised pores perforating cell membranes that facilitate transport of ions, or charged atoms, across its breadth. The flow of ions from one side to another is measurable as an electrical current. The pore, or channel, through which ions pass narrows in regions, creating an impasse, or gate , prohibiting passage. The gate is controlled by external factors, such as the binding of certain molecules (ligands ....This research will investigate aspects of ion channel gating (opening). Ion channels are specialised pores perforating cell membranes that facilitate transport of ions, or charged atoms, across its breadth. The flow of ions from one side to another is measurable as an electrical current. The pore, or channel, through which ions pass narrows in regions, creating an impasse, or gate , prohibiting passage. The gate is controlled by external factors, such as the binding of certain molecules (ligands), or, in the case of voltage-dependent ion channels, the application of a voltage to the membrane. Such perturbations widen the pore sufficiently to permit conduction. Voltage-gated potassium channels specifically transport potassium ions. They fall into multiple categories, and generally form large complexes with intracellular, as well as membrane-bound, portions. For some types, cues from intracellular chemical processes are known to regulate electrical excitability, using the intracellular domains to transfer information to the membrane. In others it is not clear if and how this might happen. Our efforts will focus on exploring this theme in two contrasting systems, Kv and BK channels. Kv channels open in response to voltage, whereas activation of BK channels requires both voltage and moderate levels of intracellular calcium. X-ray crystallography will be used to generate accurate three-dimensional images of selected potassium channel components, allowing us to visualise discrete steps in the regulation processes. Potassium channels are essential for life. They effect transmission of our nerve impulses, and are thus fundamental to central nervous system activity. This research will help us to understand the factors that control them.Read moreRead less