Abstract

Membrane-integral inorganic pyrophosphatases (mPPases) couple pyrophosphate hydrolysis with H+ and Na+ pumping in plants and microbes. mPPases are homodimeric transporters with two catalytic sites facing the cytoplasm and demonstrating highly different substrate-binding affinities and activities. The structural aspects of the functional asymmetry are still poorly understood because the structure of the physiologically relevant dimer form with only one active site occupied by the substrate is unknown. We addressed this issue by molecular dynamics (MD) simulations of the H+-transporting mPPase of Vigna radiata, starting from its crystal structure containing a close substrate analog (imidodiphosphate, IDP) in both active sites. The MD simulations revealed pre-existing subunit asymmetry, which increased upon IDP binding to one subunit and persisted in the fully occupied dimer. The most significant asymmetrical change caused by IDP binding is a ‘rigid body’-like displacement of the lumenal loop connecting α-helices 2 and 3 in the partner subunit and opening its exit channel for water. This highly conserved 14–19-residue loop is found only in plant vacuolar mPPases and may have a regulatory function, such as pH sensing in the vacuole. Our data define the structural link between the loop and active sites and are consistent with the published structural and functional data.

Highlights

  • Membrane-bound inorganic pyrophosphatases, a relict transporter found in plants and microbes, uses pyrophosphate (PPi ) energy to translocate H+ and Na+ across membranes [1,2,3,4,5,6]

  • MPPase structure containing IDP in each subunit was simulated in a virtual membrane, mimicking plant vacuolar membrane, to relieve structural distortions of the crystalline state (Figure S1)

  • An essential advantage of the molecular dynamics (MD) approach is that it allows prediction of the dimer structure with only one active site occupied by substrate, not obtainable experimentally

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Summary

Introduction

Membrane-bound inorganic pyrophosphatases (mPPase; EC 7.1.3.1, formerly 3.6.1.1), a relict transporter found in plants and microbes, uses pyrophosphate (PPi ) energy to translocate H+ and Na+ across membranes [1,2,3,4,5,6]. The mPPase superfamily is divided into K+ -independent and K+ -dependent families [4]. H+ transporting mPPases, whereas the K+ -dependent family encompasses both H+ and. Plants posess only H+ -transporting mPPases of both families, and their overexpression is a well-documented approach to enhancing plant tolerance to abiotic stress [7].

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