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Main Authors: Vinayagam, Deivanayagabarathy, Sitsel, Oleg, Schulte, Uwe, Constantin, Cristina E, Oosterheert, Wout, Prumbaum, Daniel, Zolles, Gerd, Fakler, Bernd, Raunser, Stefan
Format: Artículo científico
Language:en
Published: Nature 2025
Subjects:
Online Access:https://pubmed.ncbi.nlm.nih.gov/40836084/
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author Vinayagam, Deivanayagabarathy
Sitsel, Oleg
Schulte, Uwe
Constantin, Cristina E
Oosterheert, Wout
Prumbaum, Daniel
Zolles, Gerd
Fakler, Bernd
Raunser, Stefan
author_facet Vinayagam, Deivanayagabarathy
Sitsel, Oleg
Schulte, Uwe
Constantin, Cristina E
Oosterheert, Wout
Prumbaum, Daniel
Zolles, Gerd
Fakler, Bernd
Raunser, Stefan
Vinayagam, Deivanayagabarathy
Sitsel, Oleg
Schulte, Uwe
Constantin, Cristina E
Oosterheert, Wout
Prumbaum, Daniel
Zolles, Gerd
Fakler, Bernd
Raunser, Stefan
collection PubMed - marine biology
contents Molecular mechanism of ultrafast transport by plasma membrane Ca-ATPases. Vinayagam, Deivanayagabarathy Sitsel, Oleg Schulte, Uwe Constantin, Cristina E Oosterheert, Wout Prumbaum, Daniel Zolles, Gerd Fakler, Bernd Raunser, Stefan Animals Mice Phosphatidylinositol 4,5-Diphosphate Calcium Plasma Membrane Calcium-Transporting ATPases Cell Membrane Models, Molecular Biological Transport Humans Mutation Kinetics Tight control of intracellular Ca levels is fundamental as they are used to control numerous signal transduction pathways. Plasma membrane Ca-ATPases (PMCAs) have a crucial role in this process by extruding Ca against a steep concentration gradient from the cytosol to the extracellular space. Although new details of PMCA biology are constantly being uncovered, the structural basis of the most distinguishing features of these pumps, namely, transport rates in the kilohertz range and regulation of activity by the plasma membrane phospholipid PtdIns(4,5)P, has so far remained elusive. Here we present the structures of mouse PMCA2 in the presence and absence of its accessory subunit neuroplastin in eight different stages of its transport cycle. Combined with whole-cell recordings that accurately track PMCA-mediated Ca extrusion in intact cells, these structures enable us to establish the first comprehensive transport model for a PMCA, reveal the role of disease-causing mutations and uncover the structural underpinnings of regulatory PMCA-phospholipid interaction. The transport cycle-dependent dynamics of PtdIns(4,5)P are fundamental for its role as a 'latch' promoting the fast release of Ca and opening a passageway for counter-ions. These actions are required for maintaining the ultra-fast transport cycle. Moreover, we identify the PtdIns(4,5)P-binding site as an unanticipated target for drug-mediated manipulation of intracellular Ca levels. Our work provides detailed structural insights into the uniquely fast operation of native PMCA-type Ca pumps and its control by membrane lipids and drugs.
format Artículo científico
id pubmed_40836084
institution PubMed
language en
publishDate 2025
publisher Nature
record_format pubmed
spellingShingle Molecular mechanism of ultrafast transport by plasma membrane Ca-ATPases.
Vinayagam, Deivanayagabarathy
Sitsel, Oleg
Schulte, Uwe
Constantin, Cristina E
Oosterheert, Wout
Prumbaum, Daniel
Zolles, Gerd
Fakler, Bernd
Raunser, Stefan
Animals
Mice
Phosphatidylinositol 4,5-Diphosphate
Calcium
Plasma Membrane Calcium-Transporting ATPases
Cell Membrane
Models, Molecular
Biological Transport
Humans
Mutation
Kinetics
Molecular mechanism of ultrafast transport by plasma membrane Ca-ATPases. Vinayagam, Deivanayagabarathy Sitsel, Oleg Schulte, Uwe Constantin, Cristina E Oosterheert, Wout Prumbaum, Daniel Zolles, Gerd Fakler, Bernd Raunser, Stefan Animals Mice Phosphatidylinositol 4,5-Diphosphate Calcium Plasma Membrane Calcium-Transporting ATPases Cell Membrane Models, Molecular Biological Transport Humans Mutation Kinetics Tight control of intracellular Ca levels is fundamental as they are used to control numerous signal transduction pathways. Plasma membrane Ca-ATPases (PMCAs) have a crucial role in this process by extruding Ca against a steep concentration gradient from the cytosol to the extracellular space. Although new details of PMCA biology are constantly being uncovered, the structural basis of the most distinguishing features of these pumps, namely, transport rates in the kilohertz range and regulation of activity by the plasma membrane phospholipid PtdIns(4,5)P, has so far remained elusive. Here we present the structures of mouse PMCA2 in the presence and absence of its accessory subunit neuroplastin in eight different stages of its transport cycle. Combined with whole-cell recordings that accurately track PMCA-mediated Ca extrusion in intact cells, these structures enable us to establish the first comprehensive transport model for a PMCA, reveal the role of disease-causing mutations and uncover the structural underpinnings of regulatory PMCA-phospholipid interaction. The transport cycle-dependent dynamics of PtdIns(4,5)P are fundamental for its role as a 'latch' promoting the fast release of Ca and opening a passageway for counter-ions. These actions are required for maintaining the ultra-fast transport cycle. Moreover, we identify the PtdIns(4,5)P-binding site as an unanticipated target for drug-mediated manipulation of intracellular Ca levels. Our work provides detailed structural insights into the uniquely fast operation of native PMCA-type Ca pumps and its control by membrane lipids and drugs.
title Molecular mechanism of ultrafast transport by plasma membrane Ca-ATPases.
topic Animals
Mice
Phosphatidylinositol 4,5-Diphosphate
Calcium
Plasma Membrane Calcium-Transporting ATPases
Cell Membrane
Models, Molecular
Biological Transport
Humans
Mutation
Kinetics
url https://pubmed.ncbi.nlm.nih.gov/40836084/