Abstract
In this study, we probe the folding of K(v)AP, a voltage-gated K(+) (K(v)) channel. The K(v)AP channel, though of archaebacterial origin, is structurally and functionally similar to eukaryotic K(v) channels. An advantage of the K(v)AP channel is that it can be folded in vitro from an extensively unfolded state and the folding can be controlled by temperature. We utilize these properties of the K(v)AP channel to separately study the membrane insertion and the tetramerization stages during folding. We use two quantitative assays: a Cys PEGylation assay to monitor membrane insertion and a cross-linking assay to monitor tetramerization. We show that during folding the K(v)AP polypeptide is rapidly inserted into the lipid bilayer with a "native-like" topology. We identify a segment at the C-terminus that is important for multimerization of the K(v)AP channel. We show that this C-terminal domain forms a dimer, which raises the possibility that the tetramerization of the K(v)AP channel proceeds through a dimer of dimers pathway. Our studies show that the in vitro folding of the K(v)AP channel mirrors aspects of the cellular assembly pathway for voltage-gated K(+) channels and therefore suggest that evolutionarily distinct K(v) channels share a common folding pathway. The pathway for the folding and assembly of a K(v) channel is of central importance as defects in this pathway have been implicated in the etiology of several disease states. Our studies indicate that the K(v)AP channel provides an experimentally tractable system for elucidating the folding mechanism of K(v) channels.