Abstract
Evidence is presented that the transmembrane KdpA subunit of the high affinity K(+)-translocating P-type Kdp-ATPase is evolutionarily derived from the superfamily of 2TM-type K(+) channels in bacteria. This extends a previous study relating the K(+) channels to the KtrAB, Trk, Trk1,2, and HKT1 K(+) symporter superfamily of both prokaryotes and eukaryotes. Although the channels are formed by four single-MPM motif subunits, the transmembrane KdpA subunit and the transmembrane subunit of the symporter proteins are postulated to have four corresponding MPM motifs within a single sequence. Analysis of 17 KdpA sequences reveals a pattern of residue conservation similar to that of the symporters and channels, and consistent with the crystal structure of the KcsA K(+) channel. In addition, the most highly conserved residues between the families, specifically the central glycines of the P2 segments, are those previously identified as crucial for the property of K(+)-selectivity that is common to each protein. This hypothesis is consistent with an experimental study of mutations that alter K(+) binding affinity of the Kdp transporter. Although most of the results of a previous study of the transmembrane topology of KdpA are consistent with the 4-MPM model, the one deviation can be explained by a plausible change in the structure due to the experimental method.