Molecular Dynamics Studies of Ion Permeation in VDAC

Rui, Huan; Lee, Kyu Il; Pastor, Richard W.; Im, Wonpil

doi:10.1016/j.bpj.2010.12.3711

Cited by 81 publications

(105 citation statements)

References 46 publications

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“…The second (Fe B-2 ) is near the cytosolic surface, where it is coordinated by D34 and E66. These observations, which provide the first experimental evidence of Fe ions in B-pores, strongly support the idea derived from our MD simulations (51) that iron traffics across the Bfr shell using B-pores as conduits.…”

Section: Resultssupporting

confidence: 89%

Concerted Motions Networking Pores and Distant Ferroxidase Centers Enable Bacterioferritin Function and Iron Traffic

Yao¹,

Rui²,

Kumar³

et al. 2015

Biochemistry

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X-ray crystallography, molecular dynamics (MD) simulations and biochemistry were utilized to investigate the effect of introducing hydrophobic interactions in the 4-fold (N148L and Q151L) and B-pores (D34F) of Pseudomonas aeruginosa bacterioferritin B (BfrB) on BfrB function. The structures show only local structural perturbations and confirm the anticipated hydrophobic interactions. Surprisingly, structures obtained after soaking crystals in Fe2+-containing crystallization solution revealed that although iron loads into the ferroxidase centers of the mutants, the side chains of ferroxidase ligands E51 and H130 do not reorganize to bind the iron ions, as is seen in the wt BfrB structures. Similar experiments with a double mutant (C89S/K96C) prepared to introduce changes outside the pores show competent ferroxidase centers that function akin to those in wt BfrB. MD simulations comparing wt BfrB with the D34F and N148L mutants show that the mutants exhibit significantly reduced flexibility, and reveal a network of concerted motions linking ferroxidase centers and 4-fold and B-pores, which are important for imparting ferroxidase centers in BfrB with the required flexibility to function efficiently. In agreement, the efficiency of Fe2+ oxidation and uptake of the 4-fold and B-pore mutants in solution is significantly compromised relative to wt or C89S/K96C BfrB. Finally, our structures show a large number of previously unknown iron binding sites in the interior cavity and B-pores of BfrB, which reveal in unprecedented detail conduits followed by iron and phosphate ions across the BfrB shell, as well as paths in the interior cavity that may facilitate nucleation of the iron phosphate mineral.

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Section: Resultssupporting

confidence: 89%

Concerted Motions Networking Pores and Distant Ferroxidase Centers Enable Bacterioferritin Function and Iron Traffic

Yao¹,

Rui²,

Kumar³

et al. 2015

Biochemistry

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“…Our findings corroborate recent MD simulations showing that E73 causes bending and water penetration into the membrane when charged (Villinger et al, 2010). However, simulations have not reported deprotonation of K110 (Choudhary et al, 2014; Noskov et al, 2013; Rui et al, 2011; Villinger et al, 2010) potentially due to electrostatic compensation due to snorkeling into the headgroups.…”

Section: Resultsmentioning

confidence: 99%

Membrane Protein Properties Revealed through Data-Rich Electrostatics Calculations

et al. 2015

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SUMMARY The electrostatic properties of membrane proteins often reveal many of their key biophysical characteristics, such as ion channel selectivity and the stability of charged membrane-spanning segments. The Poisson-Boltzmann (PB) equation is the gold standard for calculating protein electrostatics, and the software APBSmem enables the solution of the PB equation in the presence of a membrane. Here, we describe significant advances to APBSmem including: full automation of system setup, per-residue energy decomposition, incorporation of PDB2PQR, calculation of membrane induced pKa shifts, calculation of non-polar energies, and command-line scripting for large scale calculations. We highlight these new features with calculations carried out on a number of membrane proteins, including the recently solved structure of the ion channel TRPV1 and a large survey of 1,614 membrane proteins of known structure. This survey provides a comprehensive list of residues with large electrostatic penalties for being embedded in the membrane potentially revealing interesting functional information.

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“…The physiological purpose of the ion dependence of the VDAC conductivity was theoretically addressed by Brownian and molecular dynamics simulations and essentially confirmed the experimental results on mammalian VDAC1 . For example, these studies showed that the free energy barrier prevents K + from entering or leaving the pore, whereas passage of Cl -is unhindered, when the pore is in the open state Rui et al, 2011). The hampered K + flux apparently depends on repulsive interactions between K + and a number of amino acid residues (D15, K19, D30, K61 and K95) within the barrel pore .…”

Section: Ion Conductance By Vdacsmentioning

confidence: 98%

Voltage-dependent anion channels: the wizard of the mitochondrial outer membrane

Mertins

Psakis

Essen

2014

Biological Chemistry

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Voltage dependent anion channels (VDACs) are the most abundant proteins in the outer mitochondrial membrane. Although they are essential in metabolite exchange, cell defense and apoptosis, the molecular mechanism of these VDAC-mediated processes remains elusive. Here we review recent progress in terms of VDACs' structure and regulation, with a special focus on the molecular aspects of gating and the interaction with effector proteins.

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Molecular Dynamics Studies of Ion Permeation in VDAC

Cited by 81 publications

References 46 publications

Concerted Motions Networking Pores and Distant Ferroxidase Centers Enable Bacterioferritin Function and Iron Traffic

Concerted Motions Networking Pores and Distant Ferroxidase Centers Enable Bacterioferritin Function and Iron Traffic

Membrane Protein Properties Revealed through Data-Rich Electrostatics Calculations

Voltage-dependent anion channels: the wizard of the mitochondrial outer membrane

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