Transition metal transporting P-type ATPases: terminal metal-binding domains serve as sensors for autoinhibitory tails

Qiaoxia Hu, Oleg Sitsel, Viktoria Bågenholm, Christina Grønberg, Pin Lyu, Anna Sigrid Pii Svane, Kasper Røjkjær Andersen, Nick Stub Laursen, Gabriele Meloni, Poul Nissen, Dennis W. Juhl, Jakob Toudahl Nielsen, Niels Chr Nielsen, Pontus Gourdon*

*Corresponding author for this work

Research output: Contribution to journalJournal articleResearchpeer-review

Abstract

Copper is an essential micronutrient and yet is highly toxic to cells at elevated concentrations. P1B-ATPase proteins are critical for this regulation, providing active extrusion across cellular membranes. One unique molecular adaptation of P1B-ATPases compared to other P-type ATPases is the presence of metal-binding domains (MBDs) at the cytosolic termini, which however are poorly characterized with an elusive mechanistic role. Here we present the MBD architecture in metal-free and metal-bound forms of the archetype Cu+-specific P1B-ATPase LpCopA, determined using NMR. The MBD is composed of a flexible tail and a structured core with a metal ion binding site defined by three sulfur atoms, one of which is pertinent to the so-called CXXC motif. Furthermore, we demonstrate that the MBD rather than being involved in ion delivery likely serves a regulatory role, which is dependent on the classical P-type ATPase E1-E2 transport mechanism. Specifically, the flexible tail appears responsible for autoinhibition while the metal-binding core is used for copper sensing. This model is validated by a conformation-sensitive and MBD-targeting nanobody that can structurally and functionally replace the flexible tail. We propose that autoinhibition of Cu+-ATPases occurs at low copper conditions via MBD-mediated interference with the soluble domains of the ATPase core and that metal transport is enabled when copper levels rise, through metal-induced dissociation of the MBD. This allows P1B-ATPase ‘vacuum cleaners’ to tune their own activity, balancing the levels of critical micronutrients in the cells.

Original languageEnglish
JournalFEBS Journal
ISSN1742-464X
DOIs
Publication statusE-pub ahead of print - 2024

Bibliographical note

Publisher Copyright:
© 2024 The Author(s). The FEBS Journal published by John Wiley & Sons Ltd on behalf of Federation of European Biochemical Societies.

Keywords

  • autoinhibition
  • copper transport
  • metal-binding domains
  • P-type ATPases
  • regulation

Cite this