K_v3.4 is a member of the voltage-gated K⁺ channel superfamily. Together with the related proteins K_v3.1, K_v3.2 and K_v3.3 they constitute the Shaw type subfamily family.¹

As with all K_v channels, K_v3.4 possesses the signature structure of the voltage-dependent K⁺ channels: six membrane-spanning domains with intracellular N and C termini. The functional K_v channel is a tetramer that can either be a homomer or a heteromer of K_v3 subunits.²

K_v3 subfamily members inactivate very rapidly and therefore are thought to play a role in the repolarization of action potentials and to facilitate repetitive high frequency firing.²

K_v3.4 expression is wide and the channel can be found in brain, skeletal muscle, prostate and pancreas among others.

K_v3.4 subunits have been implicated recently in the response mechanism to chronic hypoxia and the etiology of Alzheimer's and Parkinson's diseases. In addition, K_v3.4 was found to associate with the auxiliary subunit KCNE3 (MirP2) in skeletal muscle. A mutation in KCNE3 (R83H) has been associated with an inherited form of periodic paralysis (Thyrotoxic hypokalemic periodic paralysis) that is caused by the altered physiological function of the K_v3.4 channel.³

Toxins from sea anemone, BDS-I (#B-400), (47nM) and BDS-II (#B-450), (56nM), are potent blockers of K_V3.4 channels.⁴