Voltage-Gated Potassium Channels

Remember that in Objective 1 we discussed the various types of ion channels found in neurons and other cells. In order to establish the basis for the resting potential, we examined leakage channels for potassium and leakage channels for sodium in Objective 3. Now we turn our attention from resting neurons to active neurons. Neurons become electrically active by opening or closing voltage-gated ion channels. In this Objective, we’ll consider voltage-gated potassium channels and voltage-gated sodium channels.

This diagram shows a voltage-gated potassium channel. The operation of these channels is relatively simple. When the voltage across the neuronal membrane changes, it causes the charges on amino acid –R groups to change; this, in turn, shifts the position of the amino acids and the protein changes shape. It can either be in an open configuration, as shown at left; or a closed configuration, as shown at right.

Voltage-Gated Sodium Channels

This diagram shows a simplified version of the three states of the sodium channel. Note that when the protein senses voltage, it operates one of two independent gates: the activation gate and the inactivation gate.

These two voltage-controlled gates operate on slightly different time scales, with activation gate being about 1 msec faster than the inactivation gate. Once it plugs the ion channel, the inactivation gate stays in place for about 2-3 msec on average. This means the voltage-gated sodium channel exists in one of three states, only one of which is open:

1. the closed (resting) state: activation gate closed, inactivation gate open (channel closed)
2. the open (activated) state: activation gate open, inactivation gate open (channel open)
3. the inactivated (refractory) state: activation gate closed, inactivation gate closed (channel closed)

Resting state closed

Activated state open

Inactivated state closed

The Refractory Period

When a furnace is lined with bricks that are not damaged by high heat, we say those bricks are refractory.

When a significant number of voltage-gated sodium channels are in the inactivated state shown at the bottom of this cycle, then we say the membrane is refractory. That is, it is extremely difficult to depolarize the membrane because it’s almost impossible for sodium to flow into the neuron and make it more positive.

About the author

name: Jim Hutchins, PhD

institution: Colorado School of Mines

website: https://jim.hutchins.name

Dr. Jim Hutchins is an adjunct instructor at Colorado School of Mines with 45 years of teaching experience spanning K-12 through medical school. He earned his PhD in Neuroscience from Baylor College of Medicine, where his dissertation focused on acetylcholine as a neurotransmitter in the human retina, followed by postdoctoral research at Vanderbilt University on visual system development. His research contributions include highly cited work on mitochondrial superoxide dismutase and synaptic pruning in the retinogeniculate system. Dr. Hutchins has authored multiple open-access textbooks in neuroscience, medical terminology, and anatomy & physiology, creating freely accessible educational resources that have saved students over $5 million in textbook costs. He is committed to open educational resources and Creative Commons licensing, believing that knowledge should be freely available to all learners.