Abstract
KdpFABC is a high-affinity prokaryotic K<sup>+</sup> uptake system that forms a functional chimera between a channel-like subunit (KdpA) and a P-type ATPase (KdpB). At high K<sup>+</sup> levels, KdpFABC needs to be inhibited to prevent excessive K<sup>+</sup> accumulation to the point of toxicity. This is achieved by a phosphorylation of the serine residue in the TGES<sub>162</sub> motif in the A domain of the pump subunit KdpB (KdpB<sub>S162-P</sub>). Here, we explore the structural basis of inhibition by KdpB<sub>S162</sub> phosphorylation by determining the conformational landscape of KdpFABC under inhibiting and non-inhibiting conditions. Under turnover conditions, we identified a new inhibited KdpFABC state that we termed E1P tight, which is not part of the canonical Post-Albers transport cycle of P-type ATPases. It likely represents the biochemically described stalled E1P state adopted by KdpFABC upon KdpB<sub>S162</sub> phosphorylation. The E1P tight state exhibits a compact fold of the three cytoplasmic domains and is likely adopted when the transition from high-energy E1P states to E2P states is unsuccessful. This study represents a structural characterization of a biologically relevant off-cycle state in the P-type ATPase family and supports the emerging discussion of P-type ATPase regulation by such states.
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