Your search keyword '"Pérez-Mejías, Gonzalo"' showing total 8 results

1. Electric field-induced functional changes in electrode-immobilized mutant species of human cytochrome c.

Author

Olloqui-Sariego, José Luis, Pérez-Mejías, Gonzalo, Márquez, Inmaculada, Guerra-Castellano, Alejandra, Calvente, Juan José, De la Rosa, Miguel A., Andreu, Rafael, and Díaz-Moreno, Irene

Subjects

*CYTOCHROME c, *CHARGE exchange, *POST-translational modification, *ELECTRIC fields, *THERMODYNAMICS, *MITOCHONDRIAL membranes

Abstract

Post-translational modifications and naturally occurring mutations of cytochrome c have been recognized as a regulatory mechanism to control its biology. In this work, we investigate the effect of such in vivo chemical modifications of human cytochrome c on its redox properties in the adsorbed state onto an electrode. In particular, tyrosines 48 and 97 have been replaced by the non-canonical amino acid p -carboxymethyl- L -phenylalanine (p CMF), thus mimicking tyrosine phosphorylation. Additionally, tyrosine 48 has been replaced by a histidine producing the natural Y48H pathogenic mutant. Thermodynamics and kinetics of the interfacial electron transfer of wild-type cytochrome c and herein produced variants, adsorbed electrostatically under different local interfacial electric fields, were determined by means of variable temperature cyclic film voltammetry. It is shown that non-native cytochrome c variants immobilized under a low interfacial electric field display redox thermodynamics and kinetics similar to those of wild-type cytochrome c. However, upon increasing the strength of the electric field, the redox thermodynamics and kinetics of the modified proteins markedly differ from those of the wild-type species. The mutations promote stabilization of the oxidized form and a significant increase in the activation enthalpy values that can be ascribed to a subtle distortion of the heme cofactor and/or difference of the amino acid rearrangements rather than to a coarse protein structural change. Overall, these results point to a combined effect of the single point mutations at positions 48 and 97 and the strength of electrostatic binding on the regulatory mechanism of mitochondrial membrane activity, when acting as a redox shuttle protein. • Electron transfer is explored in immobilized mutant species of cytochrome c. • The interfacial electric field strength modulates the electron transfer in cytochrome c variants. • Electron transfer thermodynamic parameters depend on the dynamics of heme-surrounding residues. [ABSTRACT FROM AUTHOR]

Published

2022

2. Novel insights into the mechanism of electron transfer in mitochondrial cytochrome c.

Author

Pérez-Mejías, Gonzalo, Díaz-Quintana, Antonio, Guerra-Castellano, Alejandra, Díaz-Moreno, Irene, and De la Rosa, Miguel A.

Subjects

*CHARGE exchange, *CYTOCHROME c, *CYTOCHROME oxidase, *BINDING sites, *REDUCTION potential, *MITOCHONDRIA

Abstract

• Respiratory chain organization is highly dynamic and adapts to cellular needs. • Supercomplex formation facilitates cytochrome c 2D sliding from complex III to IV. • Physical contact contributes to redox potential gap and electron transfer. • Long-distance electron transfer allows a faster turnover of cytochrome c. The supramolecular arrangement of respiratory complexes into supercomplexes is widely accepted. The common feature observed in the supercomplex architecture from organisms of diverse phylogenetic origin is the reduction of the distance between cytochrome bc 1 (complex III) and cytochrome c oxidase (complex IV). Such an arrangement reduces the dimensionality (from 3D to 2D) of the diffusional search of cytochrome c as the electron carrier that connects both complexes. In this scenario, our recent finding of additional binding sites for cytochrome c reinforces the concept of a "restrained 2D sliding pathway" onto the supercomplex surface. Herein, we analyze novel mechanistic insights into electron transfer towards cytochrome c , including modulation of the redox potential by physical contact as well as gated, long-range electron transfer through an aqueous solution. These data establish a new horizon for the understanding of electron transfer mechanisms beyond unique and well-orientated protein complexes. Multiple and dynamic long-distance conformational ensembles compatible with electron transfer could indeed contribute to the rapid adjustment of electron flow in response to changing cellular conditions. [ABSTRACT FROM AUTHOR]

Published

2022

3. Physical contact between cytochrome c1 and cytochrome c increases the driving force for electron transfer.

Author

Pérez-Mejías, Gonzalo, Olloqui-Sariego, José Luis, Guerra-Castellano, Alejandra, Díaz-Quintana, Antonio, Calvente, Juan José, Andreu, Rafael, De la Rosa, Miguel A., and Díaz-Moreno, Irene

Subjects

*CYTOCHROME c, *PHYSICAL contact, *ELECTRON transport, *SURFACE plasmon resonance, *CHARGE exchange, *NUCLEAR magnetic resonance, *MEMBRANE potential, *UBIQUINONES

Abstract

In oxidative phosphorylation, the transfer of electrons from reduced cofactors to molecular oxygen via the electron transport chain (ETC) sustains the electrochemical transmembrane potential needed for ATP synthesis. A key component of the ETC is complex III (CIII, cytochrome bc 1), which transfers electrons from reduced ubiquinone to soluble cytochrome c (C c) coupled to proton translocation into the mitochondrial intermembrane space. One electron from every two donated by hydroquinone at site P is transferred to C c via the Rieske-cytochrome c 1 (C c 1) pathway. According to recent structural analyses of CIII and its transitory complex with C c, the interaction between the Rieske subunit and C c 1 switches intermittently during CIII activity. However, the electrochemical properties of C c 1 and their function as a wire between Rieske and C c are rather unexplored. Here, temperature variable cyclic voltammetry provides novel data on the thermodynamics and kinetics of interfacial electron transfer of immobilized C c 1. Findings reveal that C c 1 displays two channels for electron exchange, with a remarkably fast heterogeneous electron transfer rate. Furthermore, the electrochemical properties are strongly modulated by the binding mode of the protein. Additionally, we show that electron transfer from C c 1 to C c is thermodynamically favored in the immobilized C c 1 -C c complex. Nuclear Magnetic Resonance, HADDOCK, and Surface Plasmon Resonance experiments provide further structural and functional data of the C c 1 -C c complex. Our data supports the Rieske-C c 1 -C c pathway acting as a unilateral switch thyristor in which redox potential modulation through protein-protein contacts are complemented with the relay-like Rieske behavior. • C c 1 redox potential is modulated by binding to its physiological protein partners. • Directional electron transfer from C c 1 to C c is thermodynamically favored within the C c 1 -C c complex. • The Rieske-C c 1 -C c electron transfer pathway functions as a unilateral switch thyristor. [ABSTRACT FROM AUTHOR]

Published

2020

4. Proposed mechanism for regulation of H2O2‐induced programmed cell death in plants by binding of cytochrome c to 14‐3‐3 proteins.

Author

Elena‐Real, Carlos A., González‐Arzola, Katiuska, Pérez‐Mejías, Gonzalo, Díaz‐Quintana, Antonio, Velázquez‐Campoy, Adrián, Desvoyes, Bénédicte, Gutiérrez, Crisanto, De la Rosa, Miguel A., and Díaz‐Moreno, Irene

Subjects

*PLANT mitochondria, *CELL death, *APOPTOSIS, *CYTOCHROME c, *PROTEINS, *ARABIDOPSIS thaliana, *MULTICELLULAR organisms

Abstract

SUMMARY: Programmed cell death (PCD) is crucial for development and homeostasis of all multicellular organisms. In human cells, the double role of extra‐mitochondrial cytochrome c in triggering apoptosis and inhibiting survival pathways is well reported. In plants, however, the specific role of cytochrome c upon release from the mitochondria remains in part veiled yet death stimuli do trigger cytochrome c translocation as well. Here, we identify an Arabidopsis thaliana 14‐3‐3ι isoform as a cytosolic cytochrome c target and inhibitor of caspase‐like activity. This finding establishes the 14‐3‐3ι protein as a relevant factor at the onset of plant H2O2‐induced PCD. The in vivo and in vitro studies herein reported reveal that the interaction between cytochrome c and 14‐3‐3ι exhibits noticeable similarities with the complex formed by their human orthologues. Further analysis of the heterologous complexes between human and plant cytochrome c with plant 14‐3‐3ι and human 14‐3‐3ε isoforms corroborated common features. These results suggest that cytochrome c blocks p14‐3‐3ι so as to inhibit caspase‐like proteases, which in turn promote cell death upon H2O2 treatment. Besides establishing common biochemical features between human and plant PCD, this work sheds light onto the signaling networks of plant cell death. Significance Statement: Common features of the cytochrome c‐dependent pathways leading to programmed cell death in plants and humans are herein revealed. In response to oxidative stress, cytochrome c is released from mitochondria to the cytoplasm to hamper the iota isoform of the 14‐3‐3 protein family, thereby decreasing the inhibition of caspase‐like activity and likely contributing to promote cell death in plants. [ABSTRACT FROM AUTHOR]

Published

2021

5. Oxidative stress is tightly regulated by cytochrome c phosphorylation and respirasome factors in mitochondria.

Author

Guerra-Castellano, Alejandra, Díaz-Quintana, Antonio, Pérez-Mejías, Gonzalo, Elena-Real, Carlos A., González-Arzola, Katiuska, García-Mauriño, Sofía M., De la Rosa, Miguel A., and Díaz-Moreno, Irene

Subjects

*OXIDATIVE stress, *CYTOCHROME c, *PHOSPHORYLATION, *POST-translational modification, *MITOCHONDRIA

Abstract

Respiratory cytochrome c has been found to be phosphorylated at tyrosine 97 in the postischemic brain upon neuroprotective insulin treatment, but how such posttranslational modification affects mitochondrial metabolism is unclear. Here, we report the structural features and functional behavior of a phosphomimetic cytochrome c mutant, which was generated by site-specific incorporation at position 97 of p-carboxymethyl-L-phenylalanine using the evolved tRNA synthetase method. We found that the point mutation does not alter the overall folding and heme environment of cytochrome c, but significantly affects the entire oxidative phosphorylation process. In fact, the electron donation rate of the mutant heme protein to cytochrome c oxidase, or complex IV, within respiratory supercomplexes was higher than that of the wild-type species, in agreement with the observed decrease in reactive oxygen species production. Direct contact of cytochrome c with the respiratory supercomplex factor HIGD1A (hypoxia-inducible domain family member 1A) is reported here, with the mutant heme protein exhibiting a lower affinity than the wild-type species. Interestingly, phosphomimetic cytochrome c also exhibited a lower caspase-3 activation activity. Altogether, these findings yield a better understanding of the molecular basis for mitochondrial metabolism in acute diseases, such as brain ischemia, and thus could allow the use of phosphomimetic cytochrome c as a neuroprotector with therapeutic applications. [ABSTRACT FROM AUTHOR]

Published

2018

6. Respiratory Cytochrome c: a Master Pleiotropic Cell Regulator.

Author

Díaz-Moreno, Irene, Giner-Arroyo, Rafael, Pérez-Mejías, Gonzalo, Velázquez-Cruz, Alejandro, Baños-Jaime, Blanca, Casado-Combreras, Miguel A., Rivero-Rodríguez, Francisco, Guerra-Castellano, Alejandra, Corrales-Guerrero, Laura, Martínez-Fábregas, Jonathan, and De la Rosa, Miguel A.

Subjects

*CYTOCHROME c

Published

2022

7. Post-Translational Modifications of Cytochrome c in Cell Life and Disease.

Author

Guerra-Castellano, Alejandra, Márquez, Inmaculada, Pérez-Mejías, Gonzalo, Díaz-Quintana, Antonio, De la Rosa, Miguel A., and Díaz-Moreno, Irene

Subjects

*POST-translational modification, *CYTOCHROME c, *HEMOPROTEINS, *APOPTOSIS, *CELL metabolism, *ELECTRON transport, *CELL death

Abstract

Mitochondria are the powerhouses of the cell, whilst their malfunction is related to several human pathologies, including neurodegenerative diseases, cardiovascular diseases, and various types of cancer. In mitochondrial metabolism, cytochrome c is a small soluble heme protein that acts as an essential redox carrier in the respiratory electron transport chain. However, cytochrome c is likewise an essential protein in the cytoplasm acting as an activator of programmed cell death. Such a dual role of cytochrome c in cell life and death is indeed fine-regulated by a wide variety of protein post-translational modifications. In this work, we show how these modifications can alter cytochrome c structure and functionality, thus emerging as a control mechanism of cell metabolism but also as a key element in development and prevention of pathologies. [ABSTRACT FROM AUTHOR]

Published

2020

8. New moonlighting functions of mitochondrial cytochrome c in the cytoplasm and nucleus.

Author

González‐Arzola, Katiuska, Velázquez‐Cruz, Alejandro, Guerra‐Castellano, Alejandra, Casado‐Combreras, Miguel Á., Pérez‐Mejías, Gonzalo, Díaz‐Quintana, Antonio, Díaz‐Moreno, Irene, and De la Rosa, Miguel Á.

Subjects

*CYTOCHROME c, *HISTONES, *CARRIER proteins, *CYTOPLASM, *DNA damage, *CYTOSOL

Abstract

Cytochrome c (Cc) is a protein that functions as an electron carrier in the mitochondrial respiratory chain. However, Cc has moonlighting roles outside mitochondria driving the transition of apoptotic cells from life to death. When living cells are damaged, Cc escapes its natural mitochondrial environment and, once in the cytosol, it binds other proteins to form a complex named the apoptosome—a platform that triggers caspase activation and further leads to controlled cell dismantlement. Early released Cc also binds to inositol 1,4,5‐triphosphate receptors on the ER membrane, which stimulates further massive Cc release from mitochondria. Besides the well‐characterized binding proteins contributing to the proapoptotic functions of Cc, many novel protein targets have been recently described. Among them, histone chaperones were identified as key partners of Cc following DNA breaks, indicating that Cc might modulate chromatin dynamics through competitive binding to histone chaperones. In this article, we review the ample set of recently discovered antiapoptotic proteins—involved in DNA damage, transcription, and energetic metabolism—reported to interact with Cc in the cytoplasm and even the nucleus upon DNA breaks. [ABSTRACT FROM AUTHOR]

Published

2019