Marcos N. Morgada scite author profile

Maturation of cytochrome oxidases is a complex process requiring assembly of several subunits and adequate uptake of the metal cofactors. Two orthologous Sco proteins (Sco1 and Sco2) are essential for the correct assembly of the dicopper Cu A site in the human oxidase, but their function is not fully understood. Here, we report an in vitro biochemical study that shows that Sco1 is a metallochaperone that selectively transfers Cu(I) ions based on loop recognition, whereas Sco2 is a copper-dependent thiol reductase of the cysteine ligands in the oxidase. Copper binding to Sco2 is essential to elicit its redox function and as a guardian of the reduced state of its own cysteine residues in the oxidizing environment of the mitochondrial intermembrane space (IMS). These results provide a detailed molecular mechanism for Cu A assembly, suggesting that copper and redox homeostasis are intimately linked in the mitochondrion.

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COA6 Is Structurally Tuned to Function as a Thiol-Disulfide Oxidoreductase in Copper Delivery to Mitochondrial Cytochrome c Oxidase

Soma

Morgada

Naik

et al. 2019

Cell Reports

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The role of molecular crowding in long-range metalloprotein electron transfer: Dissection into site- and scaffold-specific contributions

Zitare

Szuster

Scocozza

et al. 2019

Electrochimica Acta

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Reversible Switching of Redox‐Active Molecular Orbitals and Electron Transfer Pathways in Cu_A Sites of Cytochrome c Oxidase

et al. 2015

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The Cu(A) site of cytochrome c oxidase is a redox hub that participates in rapid electron transfer at low driving forces with two redox cofactors in nearly perpendicular orientations. Spectroscopic and electrochemical characterizations performed on first and second-sphere mutants have allowed us to experimentally detect the reversible switching between two alternative electronic states that confer different directionalities to the redox reaction. Specifically, the M160H variant of a native Cu(A) shows a reversible pH transition that allows to functionally probe both states in the same protein species. Alternation between states exerts a dramatic impact on the kinetic redox parameters, thereby suggesting this effect as the mechanism underlying the efficiency and directionality of Cu(A) electron transfer in vivo. These findings may also prove useful for the development of molecular electronics.

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Dynamical effects in metalloprotein heterogeneous electron transfer

Zitare

Szuster

Santalla

et al. 2020

Electrochimica Acta

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Control of the Electronic Ground State on an Electron‐Transfer Copper Site by Second‐Sphere Perturbations

et al. 2014

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The Cu(A) center is a dinuclear copper site that serves as an optimized hub for long-range electron transfer in heme-copper terminal oxidases. Its electronic structure can be described in terms of a σ(u)* ground-state wavefunction with an alternative, less populated ground state of π(u) symmetry, which is thermally accessible. It is now shown that second-sphere mutations in the Cu(A) containing subunit of Thermus thermophilus ba3 oxidase perturb the electronic structure, which leads to a substantial increase in the population of the π(u) state, as shown by different spectroscopic methods. This perturbation does not affect the redox potential of the metal site, and despite an increase in the reorganization energy, it is not detrimental to the electron-transfer kinetics. The mutations were achieved by replacing the loops that are involved in protein-protein interactions with cytochrome c, suggesting that transient protein binding could also elicit ground-state switching in the oxidase, which enables alternative electron-transfer pathways.

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Control of the Electronic Ground State on an Electron‐Transfer Copper Site by Second‐Sphere Perturbations

et al. 2014

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The Cu A center is a dinuclear copper site that serves as an optimized hub for long-range electron transfer in hemecopper terminal oxidases. Its electronic structure can be described in terms of a s u * ground-state wavefunction with an alternative, less populated ground state of p u symmetry, which is thermally accessible. It is now shown that secondsphere mutations in the Cu A containing subunit of Thermus thermophilus ba 3 oxidase perturb the electronic structure, which leads to a substantial increase in the population of the p u state, as shown by different spectroscopic methods. This perturbation does not affect the redox potential of the metal site, and despite an increase in the reorganization energy, it is not detrimental to the electron-transfer kinetics. The mutations were achieved by replacing the loops that are involved in protein-protein interactions with cytochrome c, suggesting that transient protein binding could also elicit ground-state switching in the oxidase, which enables alternative electron-transfer pathways.

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Dramatic Electronic Perturbations of Cu_A Centers via Subtle Geometric Changes

et al. 2018

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CuA is a binuclear copper site acting as electron entry port in terminal heme-copper oxidases. In the oxidized form, CuA is a mixed valence pair whose electronic structure can be described using a potential energy surface with two minima: σu* and πu, that are variably populated at room temperature. We report that mutations in the first and second coordination spheres of the binuclear metallocofactor can be combined in an additive manner to tune the energy gap and, thus, the relative populations of the two lowest-lying states. A series of designed mutants span σu*/πu energy gaps ranging from 900 to 13 cm−1. The smallest gap corresponds to a variant with an effectively degenerate ground state. All engineered sites preserve the mixed-valence character of this metal center and the electron transfer functionality. An increase of the Cu-Cu distance less than 0.06 Å modifies the σu*/πu energy gap by almost two orders of magnitude, with longer distances eliciting a larger population of the πu state. This scenario offers a stark contrast to synthetic systems, as model compounds require a lengthening of 0.5 Å in the Cu-Cu distance to stabilize the πu state. These findings show that the tight control of the protein environment allows drastic perturbations in the electronic structure of CuA sites with minor geometric changes.

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Marcos N. Morgada

Loop recognition and copper-mediated disulfide reduction underpin metal site assembly of Cu _A in human cytochrome oxidase

COA6 Is Structurally Tuned to Function as a Thiol-Disulfide Oxidoreductase in Copper Delivery to Mitochondrial Cytochrome c Oxidase

The role of molecular crowding in long-range metalloprotein electron transfer: Dissection into site- and scaffold-specific contributions

Reversible Switching of Redox‐Active Molecular Orbitals and Electron Transfer Pathways in Cu_A Sites of Cytochrome c Oxidase

Dynamical effects in metalloprotein heterogeneous electron transfer

Control of the Electronic Ground State on an Electron‐Transfer Copper Site by Second‐Sphere Perturbations

Control of the Electronic Ground State on an Electron‐Transfer Copper Site by Second‐Sphere Perturbations

Dramatic Electronic Perturbations of Cu_A Centers via Subtle Geometric Changes

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Marcos N. Morgada

Loop recognition and copper-mediated disulfide reduction underpin metal site assembly of Cu A in human cytochrome oxidase

COA6 Is Structurally Tuned to Function as a Thiol-Disulfide Oxidoreductase in Copper Delivery to Mitochondrial Cytochrome c Oxidase

The role of molecular crowding in long-range metalloprotein electron transfer: Dissection into site- and scaffold-specific contributions

Reversible Switching of Redox‐Active Molecular Orbitals and Electron Transfer Pathways in CuA Sites of Cytochrome c Oxidase

Dynamical effects in metalloprotein heterogeneous electron transfer

Control of the Electronic Ground State on an Electron‐Transfer Copper Site by Second‐Sphere Perturbations

Control of the Electronic Ground State on an Electron‐Transfer Copper Site by Second‐Sphere Perturbations

Dramatic Electronic Perturbations of CuA Centers via Subtle Geometric Changes

Contact Info

Product

Resources

About

Loop recognition and copper-mediated disulfide reduction underpin metal site assembly of Cu _A in human cytochrome oxidase

Reversible Switching of Redox‐Active Molecular Orbitals and Electron Transfer Pathways in Cu_A Sites of Cytochrome c Oxidase

Dramatic Electronic Perturbations of Cu_A Centers via Subtle Geometric Changes