Structure-guided simulations illuminate the mechanism of ATP transport through VDAC1

Om P. Choudhary; Aviv Paz; Joshua L. Adelman; Jacques Philippe Colletier; Jeff Abramson; Michael Grabe

doi:10.1038/nsmb.2841

Structure-guided simulations illuminate the mechanism of ATP transport through VDAC1

Om P. Choudhary
, Aviv Paz
, Joshua L. Adelman
, Jacques Philippe Colletier
, Jeff Abramson
, Michael Grabe

Department of Structural Biology

University at Buffalo

Research output: Contribution to journal › Article › peer-review

89 Scopus citations

Abstract

The voltage-dependent anion channel (VDAC) mediates the flow of metabolites and ions across the outer mitochondrial membrane of all eukaryotic cells. The open channel passes millions of ATP molecules per second, whereas the closed state exhibits no detectable ATP flux. High-resolution structures of VDAC1 revealed a 19-stranded β-barrel with an α -helix partially occupying the central pore. To understand ATP permeation through VDAC, we solved the crystal structure of mouse VDAC1 (mVDAC1) in the presence of ATP, revealing a low-affinity binding site. Guided by these coordinates, we initiated hundreds of molecular dynamics simulations to construct a Markov state model of ATP permeation. These simulations indicate that ATP flows through VDAC through multiple pathways, in agreement with our structural data and experimentally determined physiological rates.

Original language	English
Pages (from-to)	626-632
Number of pages	7
Journal	Nature Structural and Molecular Biology
Volume	21
Issue number	7
DOIs	https://doi.org/10.1038/nsmb.2841
State	Published - Jul 2014

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title = "Structure-guided simulations illuminate the mechanism of ATP transport through VDAC1",

abstract = "The voltage-dependent anion channel (VDAC) mediates the flow of metabolites and ions across the outer mitochondrial membrane of all eukaryotic cells. The open channel passes millions of ATP molecules per second, whereas the closed state exhibits no detectable ATP flux. High-resolution structures of VDAC1 revealed a 19-stranded β-barrel with an α -helix partially occupying the central pore. To understand ATP permeation through VDAC, we solved the crystal structure of mouse VDAC1 (mVDAC1) in the presence of ATP, revealing a low-affinity binding site. Guided by these coordinates, we initiated hundreds of molecular dynamics simulations to construct a Markov state model of ATP permeation. These simulations indicate that ATP flows through VDAC through multiple pathways, in agreement with our structural data and experimentally determined physiological rates.",

author = "Choudhary, \{Om P.\} and Aviv Paz and Adelman, \{Joshua L.\} and Colletier, \{Jacques Philippe\} and Jeff Abramson and Michael Grabe",

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T1 - Structure-guided simulations illuminate the mechanism of ATP transport through VDAC1

AU - Choudhary, Om P.

AU - Paz, Aviv

AU - Adelman, Joshua L.

AU - Colletier, Jacques Philippe

AU - Abramson, Jeff

AU - Grabe, Michael

PY - 2014/7

Y1 - 2014/7

N2 - The voltage-dependent anion channel (VDAC) mediates the flow of metabolites and ions across the outer mitochondrial membrane of all eukaryotic cells. The open channel passes millions of ATP molecules per second, whereas the closed state exhibits no detectable ATP flux. High-resolution structures of VDAC1 revealed a 19-stranded β-barrel with an α -helix partially occupying the central pore. To understand ATP permeation through VDAC, we solved the crystal structure of mouse VDAC1 (mVDAC1) in the presence of ATP, revealing a low-affinity binding site. Guided by these coordinates, we initiated hundreds of molecular dynamics simulations to construct a Markov state model of ATP permeation. These simulations indicate that ATP flows through VDAC through multiple pathways, in agreement with our structural data and experimentally determined physiological rates.

AB - The voltage-dependent anion channel (VDAC) mediates the flow of metabolites and ions across the outer mitochondrial membrane of all eukaryotic cells. The open channel passes millions of ATP molecules per second, whereas the closed state exhibits no detectable ATP flux. High-resolution structures of VDAC1 revealed a 19-stranded β-barrel with an α -helix partially occupying the central pore. To understand ATP permeation through VDAC, we solved the crystal structure of mouse VDAC1 (mVDAC1) in the presence of ATP, revealing a low-affinity binding site. Guided by these coordinates, we initiated hundreds of molecular dynamics simulations to construct a Markov state model of ATP permeation. These simulations indicate that ATP flows through VDAC through multiple pathways, in agreement with our structural data and experimentally determined physiological rates.

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DO - 10.1038/nsmb.2841

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SP - 626

EP - 632

JO - Nature Structural and Molecular Biology

JF - Nature Structural and Molecular Biology

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Structure-guided simulations illuminate the mechanism of ATP transport through VDAC1

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