Cytochrome oxidase rotates in the inner membrane of intact mitochondria and submitochondrial particles

A transient dichroism is detected after photolysis by a linearly polarized laser flash of the cytochrome oxidaseCO complex in bovine heart mitochondria, rat heart mitochondria, and bovine heart submitochondrial particles. A decay in the absorption anisotropy is characterized by a time constant of about 300 to 400 mus in both mitochondria and submitochondrial particles. Since vesicle tumbling in the time range less than 5 ms can be excluded in these experiments, we conclude that cytochrome oxidase rotates in the mitochondrial membrane with a relaxation time of several hundred microseconds. However, it is likely that only about one-half of cytochrome oxidase contributes to the observed decay, the remainder being relatively immobile.     

Cytochrome oxidase subunit III gene in Neurospora crassa mitochondria. Location and sequence

We have located and sequenced the gene for cytochrome oxidase subunit III (CoIII) in Neurospora crassa mitochondria. The CoIII gene is located downstream from the small rRNA gene within a cluster of tRNA genes and is coded by the same strand as the tRNA and the rRNA genes. Like the tRNA and the rRNA genes, the CoIII gene is also flanked by the GC-rich palindromic DNA sequences which are highly conserved in N. crassa mitochondria. The CoIII coding sequence predicts a protein 269 amino acids long including 8 tryptophan residues. All 8 tryptophan residues are coded for by UGA. This supports our previous conclusion based on the anticodon sequence of N. crassa mitochondrial tryptophan tRNA and provides evidence for the notion that use of UGA as a codon for tryptophan rather than chain termination may be a feature common to most mitochondrial protein synthesis systems. The close correspondence between the amino acid composition of N. crassa CoIII and that of the protein predicted by the CoIII gene sequence suggests that unlike in mammalian mitochondria, AUA is a codon for isoleucine and not for methionine in N. crassa mitochondria. The N. crassa CoIII sequence shows strong homologies to the corresponding yeast and human proteins (53 and 47%, respectively). The overall hydrophobic character of the protein is consistent with suggestions that most of CoIII is embedded in the mitochondrial inner membrane.     

Cytochrome oxidase subunit II gene in mitochondria of Oenothera has no intron

The cytochrome oxidase subunit II gene has been localized in the mitochondrial genome of Oenothera berteriana and the nucleotide sequence has been determined. The coding sequence contains 777 bp and, unlike the corresponding gene in Zea mays, is not interrupted by an intron. No TGA codon is found within the open reading frame. The codon CGG, as in the maize gene, is used in place of tryptophan codons of corresponding genes in other organisms. At position 742 in the Oenothera sequence the TGG of maize is changed into a CGG codon, where Trp is conserved as the amino acid in other organisms. Homologous sequences occur more than once in the mitochondrial genome as several mitochondrial DNA species hybridize with DNA probes of the cytochrome oxidase subunit II gene.     

Cytochrome oxidase as a proton pump

The general structure of cytochrome oxidase is reviewed and evidence that the enzyme acts as a redox-linked proton pump outlined. The overall H⁺/e ^– stoichiometry of the pump is discussed and results [Wikström (1989),Nature 338, 293] which suggest that only the final two electrons which reduce the peroxide adduct to water are coupled to protein translocated are considered in terms of the restrictions they place on pump mechanisms. Direct and indirect mechanisms for proton translocation are discussed in the context of evidence for redox-linked conformational changes in the enzyme, the role of subunit III, and the nature of the Cu_A site.     

The distance between cytochromes a and a3 in the azide compound of bovine-heart cytochrome oxidase

The electron-spin relaxation rates of the two species of cytochrome a3(3+)-azide found in the azide compound of bovine-heart cytochrome oxidase were measured by progressive microwave saturation at T = 10 K. It has been shown previously that Cyt a3(3+)-azide gives rise to two distinct EPR resonances, depending upon the oxidation state of Cyt a. When Cyt a is ferrous, Cyt a3(3+)-azide has g = 2.88, 2.19 and 1.64; upon oxidation of Cyt a, the a3(3+)-azide g-values become g = 2.77, 2.18, and 1.74 (Goodman, G. (1984) J Biol. Chem. 259, 15094-15099). The relaxation effect of Cyt a on Cyt a3 could be measured as the difference in microwave field saturation parameter H1/2 between the g = 2.77 and g = 2.88 species. For each signal the spin-lattice relaxation time T1 was determined from H1/2 using the transverse relaxation time T2. The value of T2 at 10 K was extrapolated from a plot of line-width vs. temperature at higher temperature. The dipolar contribution to T1 was related to the Cyt a-Cyt a3 spin-spin distance utilizing available information on the relative orientation of Cyt a3-azide and Cyt a (Erecińska, M., Wilson, D.F. and Blasie, J.K. (1979) Biochim. Biophys. Acta 545, 352-364). By taking into account the relaxation parameters for both gx and gz components of the Cyt a3-azide g-tensor, the angle between the gz components of the Cyt a and Cyt a3 g-tensors was determined to be between 0 and 18 degrees, and the Cyt a-Cyt a3 spin-spin distance was found to be 19 +/- 8 A.     

Cytochrome oxidase in health and disease

Yeast and bovine cytochrome c oxidases (COX) are composed of 12 and 13 different polypeptides, respectively. In both cases, the three subunits constituting the catalytic core are encoded by mitochondrial DNA. The other subunits are all products of nuclear genes that are translated on cytoplasmic ribosomes and imported through different transport routes into mitochondria. Biogenesis of the functional complex depends on the expression of all the structural and more than two dozen COX-specific genes. The latter impinge on all aspects of the biogenesis process. Here we review the current state of information about the functions of the COX-specific gene products and of their relationship to human COX deficiencies.     

Cytochrome c biogenesis in mitochondria

As part of the respiratory chain, c-type cytochromes are essential electron transporters. They are characterized by the covalent attachment of a heme prosthetic group. The biogenesis of these proteins includes all the processes leading to this fixation. Yeast and animals have evolved a comparatively simple mechanism relying on cytochrome c heme lyases. In contrast, plant mitochondria have kept a maturation pathway inherited from their prokaryote ancestor. It involves Ccm proteins encoded in both the nuclear and the mitochondrial genomes of plants. These proteins compose a heme delivery pathway, include an ABC transporter, a redox protein and a putative heme lyase.     

Cytochrome cbb(3) oxidase and bacterial microaerobic metabolism

Cytochrome cbb(3) oxidase is a member of the haem-copper oxidase superfamily. It is characterized by its high oxygen affinity, while retaining the ability to pump protons. These attributes are central to its proposed role in bacterial microaerobic metabolism. Recent spectroscopic characterization of both the cytochrome cbb(3) oxidase complex from Pseudomonas stutzeri and the dihaem ccoP subunit expressed separately in Escherichia coli has revealed the presence of a low-spin His/His co-ordinated c-type cytochrome. The low midpoint reduction potential of this haem (E(m)<+100 mV), together with its unexpected ability to bind CO in the reduced state at the expense of the distal histidine ligand, raises questions about the role of the ccoP subunit in the delivery of electrons to the active site.