Nobuyuki Nakanishi scite author profile

Cytochromes b(561) are a family of transmembrane proteins found in most eukaryotic cells and contain two haem b prosthetic groups per molecule being coordinated with four His residues from four different transmembrane alpha-helices. Although cytochromes b(561) residing in the chromaffin vesicles has long been known to have a role for a neuroendocrine-specific transmembrane electron transfer from extravesicular ascorbate to intravesicular monodehydroascorbate radical to regenerate ascorbate, newly found members were apparently lacking in the sequence for putative ascorbate-binding site but exhibiting a transmembrane ferrireductase activity. We propose that cytochrome b(561) has a specific mechanism to facilitate the concerted proton/electron transfer from ascorbate by exploiting a cycle of deprotonated and protonated states of the N(delta1) atom of the axial His residue at the extravesicular haem center, as an initial step of the transmembrane electron transfer. This mechanism utilizes the well-known electrochemistry of ascorbate for a biological transmembrane electron transfer and might be operative for other type of electron transfer reactions from organic reductants.

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Importance of the Conserved Lysine 83 Residue of Zea mays Cytochrome b₅₆₁ for Ascorbate-Specific Transmembrane Electron Transfer As Revealed by Site-Directed Mutagenesis Studies

Nakanishi¹,

Rahman²,

Sakamoto

et al. 2009

Biochemistry

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Cytochromes b(561), a novel class of transmembrane electron transport proteins residing in a large variety of eukaryotic cells, have a number of common structural features including six hydrophobic transmembrane alpha-helices and two heme ligation sites. We found that recombinant Zea mays cytochrome b(561) obtained by a heterologous expression system using yeast Pichia pastoris cells could utilize the ascorbate/mondehydroascorbate radical as a physiological electron donor/acceptor. We found further that a concerted proton/electron transfer mechanism might be operative in Z. mays cytochrome b(561) as well upon the electron acceptance from ascorbate to the cytosolic heme center. The well-conserved Lys(83) residue in a cytosolic loop was found to have a very important role(s) for the binding of ascorbate and the succeeding electron transfer via electrostatic interactions based on the analyses of three site-specific mutants, K83A, K83E, and K83D. Further, unusual behavior of the K83A mutant in pulse radiolysis experiments indicated that Lys(83) might also be responsible for the intramolecular electron transfer to the intravesicular heme. On the other hand, pulse radiolysis experiments on two site-specific mutants, S118A and W122A, for the well-conserved residues in the putative monodehydroascorbate radical binding site showed that their electron transfer activities to the monodehydroascorbate radical were very similar to those of the wild-type protein, indicating that Ser(118) and Trp(122) do not have major roles for the redox events on the intravesicular side.

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Inhibition of Electron Acceptance from Ascorbate by the Specific N-carbethoxylations of Maize Cytochrome b561: A Common Mechanism for the Transmembrane Electron Transfer in Cytochrome b561 Protein Family

Nakanishi

Rahman

Sakamoto

et al. 2009

Journal of Biochemistry

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Cytochromes b(561) constitute a novel class of proteins in eukaryotic cells with a number of highly relevant common features including six transmembrane alpha-helices and two haem groups. Of particular interest is the presence of a large number of plant homologues having putative ascorbate- and monodehydroascorbate radical-binding sites. We conducted a diethylpyrocarbonate-modification study employing Zea mays cytochrome b(561) heterologously expressed in Pichia pastoris cells. Pre-treatment of cytochrome b(561) with diethylpyrocarbonate in oxidized form caused N-carbethoxylation of His(86), His(159) and Lys(83), leading to a drastic inhibition of the electron transfer from ascorbate. The activity was protected by the inclusion of ascorbate during the treatment. However, midpoint potentials of two haem centres did show only slight decreases upon the treatment, suggesting that changes in the midpoint potentials were not the major cause of the inhibition. Present results indicated that Zea mays cytochrome b(561) conducted an ascorbate-specific transmembrane electron transfer by utilizing a concerted H(+)/e(-) transfer mechanism and that the specific N-carbethoxylation of haem axial His(86) that would inhibit the removal of a proton from the bound ascorbate was a major cause of the inhibition. On the other hand, Lys(83) might be important for an initial step(s) of the fast electron acceptance from ascorbate.

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