Molecular basis of proton uptake in single and double mutants of cytochrome c oxidase
Molecular basis of proton uptake in single and double mutants of cytochrome c oxidase
Cytochrome c oxidase, the terminal enzyme of the respiratory chain, utilizes the reduction of dioxygen into water to pump protons across the mitochondrial inner membrane. The principal pathway of proton uptake into the enzyme, the D channel, is a 2.5nm long channel-like cavity named after a conserved, negatively charged aspartic acid (D) residue thought to help recruiting protons to its entrance (D132 in the first subunit of the S. sphaeroides enzyme). The single-point mutation of D132 to asparagine (N), a neutral residue, abolishes enzyme activity. Conversely, replacing conserved N139, one-third into the D channel, by D, induces a decoupled phenotype, whereby oxygen reduction proceeds but not proton pumping. Intriguingly, the double mutant D132N/N139D, which conserves the charge of the D channel, restores the wild-type phenotype. We use molecular dynamics simulations and electrostatic calculations to examine the structural and physical basis for the coupling of proton pumping and oxygen chemistry in single and double N139D mutants. The potential of mean force for the conformational isomerization of N139 and N139D side chains reveals the presence of three rotamers, one of which faces the channel entrance. This out-facing conformer is metastable in the wild-type and in the N139D single mutant, but predominant in the double mutant thanks to the loss of electrostatic repulsion with the carboxylate group of D132. The effects of mutations and conformational isomerization on the pKa of E286, an essential proton-shuttling residue located at the top of the D channel, are shown to be consistent with the electrostatic control of proton pumping proposed recently (Fadda et al 2008 Biochim. Biophys. Acta 1777 277-84). Taken together, these results suggest that preserving the spatial distribution of charges at the entrance of the D channel is necessary to guarantee both the uptake and the relay of protons to the active site of the enzyme. These findings highlight the interplay of long-range electrostatic forces and local structural fluctuations in the control of proton movement and provide a physical explanation for the restoration of proton pumping activity in the double mutant. © 2011 IOP Publishing Ltd.
Henry, Rowan M.
45869a7d-544c-43c3-a5f2-48f15a4b684a
Caplan, David
862e7f30-3802-4532-85bf-4f3004eac0ee
Fadda, Elisa
11ba1755-9585-44aa-a38e-a8bcfd766abb
Pomès, Régis
a4036858-eadc-4588-a08f-506419e99731
6 June 2011
Henry, Rowan M.
45869a7d-544c-43c3-a5f2-48f15a4b684a
Caplan, David
862e7f30-3802-4532-85bf-4f3004eac0ee
Fadda, Elisa
11ba1755-9585-44aa-a38e-a8bcfd766abb
Pomès, Régis
a4036858-eadc-4588-a08f-506419e99731
Henry, Rowan M., Caplan, David, Fadda, Elisa and Pomès, Régis
(2011)
Molecular basis of proton uptake in single and double mutants of cytochrome c oxidase.
Journal of Physics Condensed Matter, 23 (23).
(doi:10.1088/0953-8984/23/23/234102).
Abstract
Cytochrome c oxidase, the terminal enzyme of the respiratory chain, utilizes the reduction of dioxygen into water to pump protons across the mitochondrial inner membrane. The principal pathway of proton uptake into the enzyme, the D channel, is a 2.5nm long channel-like cavity named after a conserved, negatively charged aspartic acid (D) residue thought to help recruiting protons to its entrance (D132 in the first subunit of the S. sphaeroides enzyme). The single-point mutation of D132 to asparagine (N), a neutral residue, abolishes enzyme activity. Conversely, replacing conserved N139, one-third into the D channel, by D, induces a decoupled phenotype, whereby oxygen reduction proceeds but not proton pumping. Intriguingly, the double mutant D132N/N139D, which conserves the charge of the D channel, restores the wild-type phenotype. We use molecular dynamics simulations and electrostatic calculations to examine the structural and physical basis for the coupling of proton pumping and oxygen chemistry in single and double N139D mutants. The potential of mean force for the conformational isomerization of N139 and N139D side chains reveals the presence of three rotamers, one of which faces the channel entrance. This out-facing conformer is metastable in the wild-type and in the N139D single mutant, but predominant in the double mutant thanks to the loss of electrostatic repulsion with the carboxylate group of D132. The effects of mutations and conformational isomerization on the pKa of E286, an essential proton-shuttling residue located at the top of the D channel, are shown to be consistent with the electrostatic control of proton pumping proposed recently (Fadda et al 2008 Biochim. Biophys. Acta 1777 277-84). Taken together, these results suggest that preserving the spatial distribution of charges at the entrance of the D channel is necessary to guarantee both the uptake and the relay of protons to the active site of the enzyme. These findings highlight the interplay of long-range electrostatic forces and local structural fluctuations in the control of proton movement and provide a physical explanation for the restoration of proton pumping activity in the double mutant. © 2011 IOP Publishing Ltd.
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Published date: 6 June 2011
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Local EPrints ID: 499617
URI: http://eprints.soton.ac.uk/id/eprint/499617
ISSN: 0953-8984
PURE UUID: cf61e0cf-121a-4c87-a713-cf80a92a74f6
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Date deposited: 27 Mar 2025 18:14
Last modified: 28 Mar 2025 03:14
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Author:
Rowan M. Henry
Author:
David Caplan
Author:
Elisa Fadda
Author:
Régis Pomès
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