Structural Basis for the Function of the C-Terminal Proton Release Pathway in the Calcium Pump.

L Michel Espinoza-Fonseca

doi:10.3390/ijms22073507

Abstract

The calcium pump (sarco/endoplasmic reticulum Ca2+-ATPase, SERCA) plays a major role in calcium homeostasis in muscle cells by clearing cytosolic Ca2+ during muscle relaxation. Active Ca2+ transport by SERCA involves the structural transition from a low-Ca2+ affinity E2 state toward a high-Ca2+ affinity E1 state of the pump. This structural transition is accompanied by the countertransport of protons to stabilize the negative charge and maintain the structural integrity of the transport sites and partially compensate for the positive charges of the two Ca2+ ions passing through the membrane. X-ray crystallography studies have suggested that a hydrated pore located at the C-terminal domain of SERCA serves as a conduit for proton countertransport, but the existence and function of this pathway have not yet been fully characterized. We used atomistic simulations to demonstrate that in the protonated E2 state and the absence of initially bound water molecules, the C-terminal pore becomes hydrated in the nanosecond timescale. Hydration of the C-terminal pore is accompanied by the formation of water wires that connect the transport sites with the cytosol. Water wires are known as ubiquitous proton-transport devices in biological systems, thus supporting the notion that the C-terminal domain serves as a conduit for proton release. Additional simulations showed that the release of a single proton from the transport sites induces bending of transmembrane helix M5 and the interaction between residues Arg762 and Ser915. These structural changes create a physical barrier against full hydration of the pore and prevent the formation of hydrogen-bonded water wires once proton transport has occurred through this pore. Together, these findings support the notion that the C-terminal proton release pathway is a functional element of SERCA and also provide a mechanistic model for its operation in the catalytic cycle of the pump.

Highlights

Published: 29 March 2021The calcium pump (sarco/endoplasmic reticulum (SR) Ca2+ -ATPase, SERCA) is an intensely studied ATP-dependent transmembrane ion pump, truly the biophysical model for active transport and energy transduction [1] in more than 600 homologous P-type ion pumps [2]
We used molecular dynamics simulations starting from a crystal structure of the pump in the absence of non-cognate ligands
These simulations conclusively showed that the C-terminal is intrinsically hydrated in the protonated E2 state of SERCA and that this

Summary

Introduction

Published: 29 March 2021The calcium pump (sarco/endoplasmic reticulum (SR) Ca2+ -ATPase, SERCA) is an intensely studied ATP-dependent transmembrane ion pump, truly the biophysical model for active transport and energy transduction [1] in more than 600 homologous P-type ion pumps [2]. SERCA actively transports Ca2+ from the cytosol back into the SR lumen of cells at the expense of ATP hydrolysis, playing vital roles in Ca2+ homeostasis and signaling [3]. Proton currents through SERCA play an essential role in balancing the charge deficit that occurs during active ion transport across the SR membrane. SERCA populates a high-Ca2+ affinity state (E1), that binds two Ca2+ ions from the cytosol to the transmembrane transport sites and one molecule of ATP in the nucleotide-binding domain. This nucleotide-bound E12Ca2+ -ATP complex facilitates ATP utilization and the formation of the phosphorylated

Methods

Discussion

Conclusion