Arrangement of subunit IV in beef heart cytochrome c oxidase probed by chemical labeling and protease digestion experiments

The distribution of charged amino acids in mitochondrial inner-membrane proteins suggests different modes of membrane integration for nuclearly and mitochondrially encoded proteins

We have analyzed the amino acid distribution in seven nuclearly encoded and five mitochondrially encoded inner membrane proteins with experimentally well characterized topologies. The mitochondrially encoded proteins conform to the 'positive inside' rule, i.e. they have many more positively charged residues in their non-translocated as compared to translocated domains. However, most of the nuclearly encoded proteins do not show such a bias but instead have a surprisingly skewed distribution of Glu residues with an almost ten times higher frequency in the intermembrane space than in the matrix domains. These findings suggest that some, but possibly not all, nuclearly encoded inner membrane proteins may insert into the membrane by a mechanism that does not depend on the distribution of positively charged amino acids.

Subunit analysis of bovine cytochrome c oxidase by reverse phase high performance liquid chromatography

Bovine cytochrome c oxidase subunits were separated by reverse phase high performance liquid chromatography using a C4 column eluted with water and an acetonitrile gradient, both containing 0.1% trifluoroacetic acid. Subunits I and III precipitated in this solvent and could not be analyzed; the remaining eleven subunits were dissociated, denatured, soluble and could be resolved by elution from the column. The protein subunit eluting in each chromatographic peak was identified by a combination of polyacrylamide gel electrophoresis in sodium dodecyl sulfate, NH2-terminal amino acid sequencing, and amino acid analysis. Each subunit produced a single elution peak with the exception of subunit VIc (nomenclature of Kadenbach et al., 1983, Anal. Biochem. 129, 517-521), which eluted from the column as two well-resolved peaks. Sequence analysis showed that the two subunit VIc elution peaks resulted from partial chemical blockage of the alpha-amino serine residue of subunit VIc. The C4 reverse phase HPLC was used to document specific subunit removal from bovine cytochrome c oxidase either by tryptic digestion or by dodecyl maltoside extraction. The described HPLC method for separating cytochrome c oxidase subunits should be applicable for the analysis of other multisubunit proteins, especially other multisubunit membrane protein complexes.

Cytochrome oxidase subunit V gene of Neurospora crassa: DNA sequences, chromosomal mapping, and evidence that the cya-4 locus specifies the structural gene for subunit V

The sequences of cDNA and genomic DNA clones for Neurospora cytochrome oxidase subunit V show that the protein is synthesized as a 171-amino-acid precursor containing a 27-amino-acid N-terminal extension. The subunit V protein sequence is 34% identical to that of Saccharomyces cerevisiae subunit V; these proteins, as well as the corresponding bovine subunit, subunit IV, contain a single hydrophobic domain which most likely spans the inner mitochondrial membrane. The Neurospora crassa subunit V gene (cox5) contains two introns, 398 and 68 nucleotides long, which share the conserved intron boundaries 5'GTRNGT...CAG3' and the internal consensus sequence ACTRACA. Two short sequences, YGCCAG and YCCGTTY, are repeated four times each in the cox5 gene upstream of the mRNA 5' termini. The cox5 mRNA 5' ends are heterogeneous, with the major mRNA 5' end located 144 to 147 nucleotides upstream from the translational start site. The mRNA contains a 3'-untranslated region of 186 to 187 nucleotides. Using restriction-fragment-length polymorphism, we mapped the cox5 gene to linkage group IIR, close to the arg-5 locus. Since one of the mutations causing cytochrome oxidase deficiency in N. crassa, cya-4-23, also maps there, we transformed the cya-4-23 strain with the wild-type cox5 gene. In contrast to cya-4-23 cells, which grow slowly, cox5 transformants grew quickly, contained cytochrome oxidase, and had 8- to 11-fold-higher levels of subunit V in their mitochondria. These data suggest (i) that the cya-4 locus in N. crassa specifies structural information for cytochrome oxidase subunit V and (ii) that, in N. crassa, as in S. cerevisiae, deficiencies in the production of nuclearly encoded cytochrome oxidase subunits result in deficiency in cytochrome oxidase activity. Finally, we show that the lower levels of subunit V in cya-4-23 cells are most likely due to substantially reduced levels of translatable subunit V mRNA.

Cytochrome oxidase subunit V gene of Neurospora crassa: DNA sequences, chromosomal mapping, and evidence that the cya-4 locus specifies the structural gene for subunit V

The sequences of cDNA and genomic DNA clones for Neurospora cytochrome oxidase subunit V show that the protein is synthesized as a 171-amino-acid precursor containing a 27-amino-acid N-terminal extension. The subunit V protein sequence is 34% identical to that of Saccharomyces cerevisiae subunit V; these proteins, as well as the corresponding bovine subunit, subunit IV, contain a single hydrophobic domain which most likely spans the inner mitochondrial membrane. The Neurospora crassa subunit V gene (cox5) contains two introns, 398 and 68 nucleotides long, which share the conserved intron boundaries 5'GTRNGT...CAG3' and the internal consensus sequence ACTRACA. Two short sequences, YGCCAG and YCCGTTY, are repeated four times each in the cox5 gene upstream of the mRNA 5' termini. The cox5 mRNA 5' ends are heterogeneous, with the major mRNA 5' end located 144 to 147 nucleotides upstream from the translational start site. The mRNA contains a 3'-untranslated region of 186 to 187 nucleotides. Using restriction-fragment-length polymorphism, we mapped the cox5 gene to linkage group IIR, close to the arg-5 locus. Since one of the mutations causing cytochrome oxidase deficiency in N. crassa, cya-4-23, also maps there, we transformed the cya-4-23 strain with the wild-type cox5 gene. In contrast to cya-4-23 cells, which grow slowly, cox5 transformants grew quickly, contained cytochrome oxidase, and had 8- to 11-fold-higher levels of subunit V in their mitochondria. These data suggest (i) that the cya-4 locus in N. crassa specifies structural information for cytochrome oxidase subunit V and (ii) that, in N. crassa, as in S. cerevisiae, deficiencies in the production of nuclearly encoded cytochrome oxidase subunits result in deficiency in cytochrome oxidase activity. Finally, we show that the lower levels of subunit V in cya-4-23 cells are most likely due to substantially reduced levels of translatable subunit V mRNA.

Complexity and tissue specificity of the mitochondrial respiratory chain

There is a renewed interest in the structure and functioning of the mitochondrial respiratory chain with the realization that a number of genetic disorders result from defects in mitochondrial electron transfer. These socalled mitochondrial myopathies include diseases of muscle, heart, and brain. The respiratory chain can be fractionated into four large multipeptide complexes, an NADH ubiquinone reductase (complex I), succinate ubiquinone reductase (complex II), ubiquinol oxidoreductase (complex III), and cytochrome c oxidase (complex IV). Mitochondrial myopathies involving each of these complexes have been described. This review summarizes compositional and structural data on the respiratory chain proteins and describes the arrangement of these complexes in the mitochondrial inner membrane. This biochemical information is provided as a framework for the diagnosis and molecular characterization of mitochondrial diseases.

Demonstration that lysine-501 of the alpha polypeptide of native sodium and potassium ion activated adenosinetriphosphatase is located on its cytoplasmic surface

Evidence that the peptide HLLVMKGAPER, which can be released from intact sodium and potassium ion activated adenosinetriphosphatase by tryptic digestion, is located on the cytoplasmic surface of the native enzyme has been obtained. An immunoadsorbent directed against the carboxy-terminal sequence of this tryptic peptide has been constructed. The peptide KGAPER was synthesized by solid-phase techniques. Antibodies against the sequence -GAPER were purified by immunoadsorption, using the synthetic peptide attached to agarose beads. These antibodies, in turn, were coupled to agarose beads to produce an immunoadsorbent. Sealed, right-side-out vesicles, prepared from canine kidneys, were labeled with pyridoxal phosphate and sodium [3H]borohydride in the absence or presence of saponin, respectively. A tryptic digest of these labeled vesicles was passed over the immunoadsorbent. Large increases in the incorporation of radioactivity into the peptides bound by the immunoadsorbent were observed in the digests obtained from the vesicles exposed to saponin. From the results of several control experiments examining the labeling reaction as applied to these vesicles, it could be concluded that this increase in incorporation resulted only from the access that the reagents gained to the inside of the vesicles in the presence of saponin and that the increase in the extent of modification was due to the cytoplasmic disposition of this segment in the native enzyme.

Modulation of cytochrome oxidase activity by inorganic and organic phosphate

The activity of cytochrome oxidase reconstituted into phospholipid vesicles has been studied as a function of orthophosphate, ATP and inositol hexakisphosphate concentrations. The respiratory-control ratio was found to be quite sensitive to these compounds and was inversely related to the anion concentration. This effect is related to a phosphate-dependent decrease in the rate constant for ferrocytochrome c oxidation observed in the presence of ionophores. The data cannot be interpreted simply on the basis of ionic strength, which is known to limit cytochrome c binding to cytochrome oxidase, since cytochrome oxidase-containing vesicles responded differently to phosphate depending on the energization state of the phospholipid membrane.

The transmembrane helices of beef heart cytochrome oxidase

The locations of the transmembrane helices in the 12 subunits of beef heart cytochrome oxidase were predicted with a modified form of the von Heijne-Blomberg hydrophobicity scale. Based on ∼20 residues per transmembrane helix, about 480 of the estimated 660 helical residues (36.8% of 1,793 total residues) are expected to be in transmembrane helices that have their axes tilted by a small angle α from the normal to the plane of the membrane. This angle is calculated to be ∼30°, based on the observed overall tilt angle θ of 39° obtained from circular dichroism (CD) measurements on multilamellar films, or about 25°, based on the observed tilt angle θ of 36° obtained from the infrared linear dichroism of films. For 21 residues per transmembrane helix, the calculated values of α become 32° and 28°, respectively, depending upon the value of θ used. Thus, a transmembrane helical tilt angle of ∼30° accounts for the predicted transmembrane stretches in cytochrome oxidase if 20-21 residues are sufficient to span the membrane. Additional helical residues in the lipid head region may deviate by a larger angle from the normal to the plane of the membrane in cytochrome oxidase.

Sequence homologies and structural similarities between the polypeptides of yeast and beef heart cytochrome c oxidase

The homologous polypeptides in yeast and beef heart cytochrome c oxidase have been identified by sequence comparisons and structural similarities. The properties of individual polypeptides have been used to specify which components are extrinsic, and which intrinsic and bilayer spanning, in the cytochrome c oxidase complex.

Structure and function of cytochrome-c oxidase

Recent works on the structure and the function of cytochrome-c oxidase are reviewed. The subunit composition of the mitochondrial enzyme depends on the species and is comprised of between 5 and 13 subunits. It is reduced to 1 to 3 subunits in prokaryotes. The complete amino acid composition has been derived from protein sequencing. Gene sequences are partially known in several eukaryote species. Metal centers are only located in subunits I and II. The mitochondrial cytochrome-c oxidase is Y-shaped; the arms of the Y cross the inner membrane, the stalk protrudes into the intermembrane space. The bacterial enzyme has a simpler, elongated shape. A number of data have been accumulated on the subunit topology and on their location within the protein. All available spectrometric techniques have been used to investigate the environment of the metal centers as well as their interactions. From the literature, attention must be paid to what may be considered or not as an active form. The steady improvement of the instrumentation has yielded evidence for different kinds of heterogeneities which could reflect the in vivo situation. The 'pulsed' and 'resting' conformers have been well characterized. The 'oxygenated' form has been identified as a peroxide derivative of the fully oxidized cytochrome-c oxidase. The mammalian enzyme has been isolated in fully active monomeric form which does not preclude the initially suggested dimeric behavior in situ. The role of the lipids is still largely investigated, mainly through reconstitution experiments. Kinetic studies of electron transfer between cytochrome c and cytochrome-c oxidase lead to a single catalytic site model to account for the multiphasic kinetics. Results related to the low temperature investigation of the intermediate steps in the reaction between oxygen and cytochrome-c oxidase received a sound confirmation by the resolution of compound A at room temperature. It is also pointed out that the so-called mixed valence state might not be a transient state in the catalytic reduction of oxygen. The functioning of cytochrome-c oxidase as a proton pump has been supported by a number of experimental results. Subunit III would be involved in this process. The redox link to the proton pump has been suggested to be at the Fea-CuA site. The molecular mechanism responsible for the proton pumping is still unknown.

Effect of trypsin on the kinetic properties of reconstituted beef heart cytochrome c oxidase

Isolated beef heart cytochrome c oxidase was reconstituted in liposomes by the cholate dialysis method with 85% of the binding site for cytochrome c oriented to the outside. Trypsin cleaved specifically subunit VIa and half of subunit IV from the reconstituted enzyme. The kinetic properties of the reconstituted enzyme were changed by trypsin treatment if measured by the spectrophotometric assay but not by the polarographic assay. It is concluded that subunit VIa and/or subunit IV participate in the electron transport activity of cytochrome c oxidase.

Characterization of electron transfer and proton translocation activities in trypsin-treated bovine heart mitochondrial cytochrome c oxidase

Bovine heart mitochondrial cytochrome c oxidase has been treated with trypsin in order to investigate the role of components a, b, and c (nomenclature of Capaldi) in cytochrome c binding, electron transfer, and proton-pumping activities. Cytochrome c oxidase was dispersed in nondenaturing detergent solution (B. Ludwig, N. W. Downer, and R. A. Capaldi (1979) Biochemistry 18, 1401) and treated with trypsin. This treatment inhibited electron transfer activity by 9% when compared to a similarly treated control in a polarographic assay (493 s-1) and had no large effect on the high affinity (Km = 6.1 X 10(-8) M) or low affinity (Km = 2.2 X 10(-6) M) sites of cytochrome c interaction with cytochrome c oxidase. Direct thermodynamic binding experiments with cytochrome c showed that neither the high affinity (1.04 +/- 0.06 mol cytochrome c/mol cytochrome c oxidase) nor the high-plus-low affinity (2.21 +/- 0.15 mol cytochrome c/mol cytochrome c oxidase) binding sites of cytochrome c on the enzyme were perturbed by the trypsin treatment. Control and trypsin-treated enzyme incorporated into phospholipid vesicles (prepared by the cholate dialysis method) exhibited respiratory control ratios of 6.5 +/- 0.7 and 6.3 +/- 0.6, respectively. The vectorial proton translocation activity in the phospholipid vesicles was unaffected by trypsin treatment with proton translocated to electron transferred ratios being equivalent to the control. NaDodSO4-PAGE showed that components a, b, and c were completely removed by the trypsin treatment. [14C]Iodoacetamide labeling experiments showed that the content of component c in the enzyme was depleted by 85% and that greater than 50% of component a was cleaved upon the trypsin treatment. These results suggest that components a, b, and c are not required for maximum electron transfer and proton translocation activities in the isolated enzyme.

Orientation of rat liver cytochrome c oxidase subunits investigated with subunit-specific antisera

The orientation of rat liver cytochrome c oxidase subunits in the inner mitochondrial membrane was investigated with monospecific antisera against subunit II and nine nuclear-coded subunits. Mitoplasts were incubated with the antisera and the amount of bound antibodies was determined either directly with fluorescein-conjugated protein A or indirectly by back-titration of unbound antibodies with a nitrocellulose immunoassay. All subunits were found oriented to the cytosolic side, except subunits VIb and VIIc which did not react with their corresponding antisera. Antisera against subunits I, III and Vb were not available.

Orientation of cytochrome c oxidase molecules in the two populations of reconstituted vesicles resolved by column chromatography on DEAE-Sephacryl

Vesicles reconstituted with bovine heart cytochrome c oxidase and dioleoylphosphatidylcholine can be resolved into two populations by column chromatography in DEAE-Sephacryl (Madden, T.D. and Cullis, P.R. (1984) J. Biol. Chem. 259, 7655-7658). These two fractions (I and II) were treated with two proteases. These are trypsin, which has been found to cleave subunit IV in the M domain of the cytochrome c oxidase molecule, and chymotrypsin, which has been found to cleave subunit III in the C domain. These studies show that fraction I vesicles contain cytochrome c oxidase orientation with the M domain outside, i.e., in the same topology as in submitochondrial particles, while fraction II vesicles contain enzyme molecules with their C domain outside, and thus in the same orientation as in mitochondria.

Cytochrome oxidase: structural insights from electron microscopy and from secondary structure prediction

Electron microscopic images of selectively contrasted cytochrome oxidase dimer crystals are interpreted in a manner consistent with the structure of monomers determined by Fuller et al. (J. Molec. Biol. 134, 305-327). The arms of the y-shaped monomers lie within and perpendicular to the lipid bilayer protruding approximately 25 A on the matrix side of the membrane. The cytoplasmic-side tails of two monomers spread apart in a dimer forming a large cleft. Decoration of the exposed matrix side of vesicle crystals with antisubunit IV antibody fragments indicates that subunit IV lies along the a-crystal axis roughly 20 A from the center of the dimer. A membrane propensity algorithm applied to the sequences of cytochrome oxidase subunits predicts a total of 19 transmembrane alpha-helices per monomer.

Topology of beef heart cytochrome c oxidase from studies on reconstituted membranes

The orientation of purified beef heart cytochrome c oxidase, incorporated into vesicles by the cholate dialysis procedure [Carroll, R.C., & Racker, E. (1977) J. Biol. Chem. 252, 6981], has been investigated by functional and structural approaches. The level of heme reduction obtained by using cytochrome c along with the membrane-impermeant electron donor ascorbate was 78 +/- 2% of that obtained with cytochrome c and the membrane-permeant reagent N,N,N',N'-tetramethyl-p-phenylenediamine. Electron transfer from cytochrome c is known to occur exclusively from the outer surface of the mitochondrial inner membrane (C side), implying that at least 78% of the oxidase molecules are oriented in the same way in these vesicles as in the intact mitochondria. Trypsin, which cleaves subunit IV near its N terminus, modifies only 5-7% of this subunit in intact vesicles. This removal of the N-terminal residues has been shown to occur only in mitochondrial membranes with their inner side (M side) exposed. Diazobenzene [35S]sulfonate [( 35S]DABS) likewise modifies subunit IV only in submitochondrial particles. Labeling of intact membranes with [35S]DABS resulted in incorporation of only 4-8% of the total counts that could be incorporated into this subunit in membranes made leaky to the reagent by addition of 2% Triton X-100. Therefore, both the functional and structural data show that at least 80% and probably more of the cytochrome c oxidase molecules are oriented with their C domain outermost and M domains in the lumen of vesicles prepared by the cholate dialysis method.(ABSTRACT TRUNCATED AT 250 WORDS)