Differential regulation of the two genes encoding Saccharomyces cerevisiae cytochrome c oxidase subunit V by heme and the HAP2 and REO1 genes.

In Saccharomyces cerevisiae, the COX5a and COX5b genes encode two forms of cytochrome c oxidase subunit V, Va and Vb. We report here that heme increases COX5a expression and decreases COX5b expression and that the HAP2 and REO1 genes are involved in positive regulation of COX5a and negative regulation of COX5b, respectively. Heme regulation of COX5a and COX5b may dictate which subunit V isoform is available for assembly into cytochrome c oxidase under conditions of high- and low-oxygen tension.     

Identification of Reo1, a Gene Involved in Negative Regulation of Cox5b and Anb1 in Aerobically Grown Saccharomyces Cerevisiae

In Saccharomyces cerevisiae, the COX5a and COX5b genes constitute a small gene family that encodes two forms of cytochrome c oxidase subunit V, Va and Vb, either of which can provide a function essential for cytochrome c oxidase activity and respiration. In aerobically grown wild-type yeast cells, Va is the predominant form of subunit V. The COX5b gene alone does not produce enough Vb to support a respiration rate sufficient to allow growth on nonfermentable carbon sources. By selecting for mutations that increase the respiratory capacity of a strain deleted for COX5a, we have identified a gene that is involved in negative regulation of COX5b expression under aerobic growth conditions. Each of four independently isolated reo1 mutations are shown to be recessive, unlinked to COX5b, but dependent on COX5b for phenotypic expression. The mutations define a single complementation and linkage group: designated as REO1 for regulator of expression of oxidase. reo1 mutations increase expression of COX5b in aerobically grown cells, but not in anaerobically grown cells, where expression is already elevated. These mutations have no effect on COX5a, the other member of this small gene family which is positively regulated by heme and oxygen. The REO1 gene does play a role in repression of ANB1, a gene that is normally repressed under aerobic but not anaerobic conditions. Neither rox1 or rox3 mutations, which have previously been shown to increase ANB1 expression, are in the same complementation group as reo1 mutations.     

The isoforms of yeast cytochrome c oxidase subunit V alter the in vivo kinetic properties of the holoenzyme.

One of the nuclear-coded subunits of yeast cytochrome c oxidase is specified by a gene family composed of two genes, COX5a and COX5b. These genes are regulated differentially by oxygen and encode isoforms of subunit V, designated Va and Vb, which have only 66% primary sequence identity. Yeast cells require one or the other isoform for a functional cytochrome c oxidase (Trueblood, C. E., and Poyton, R. O. (1987) Mol. Cell Biol. 7, 3520-3526). To determine if these isoforms of subunit V alter the catalytic properties of holocytochrome c oxidase, we have analyzed various aspects of cytochrome c oxidase function in intact yeast cells that produce only one type of isoform. From measurements of room temperature turnover numbers and low temperature rates of ligand binding, single turnover cytochrome c oxidation, and internal electron transfer (heme a oxidation), we have found that isozymes which incorporate the Vb isoform have both higher turnover rates and higher rates of heme a oxidation than isozymes which incorporate Va. These findings support the conclusion that the isoforms of subunit V modulate cytochrome c oxidase activity in vivo and suggest that they do so by altering the rates of one or more intramolecular electron transfer reactions.     

Isolation and characterization of COX12, the nuclear gene for a previously unrecognized subunit of Saccharomyces cerevisiae cytochrome c oxidase.

We have cloned and sequenced COX12, the nuclear gene for subunit VIb of Saccharomyces cerevisiae cytochrome c oxidase. This subunit, which was previously not found in cytochrome c oxidase purified from S. cerevisiae, has a deduced amino acid sequence which is 41% identical to the sequences of subunits VIb of bovine and human cytochrome c oxidases. The chromosomal copy of COX12 was replaced with a plasmid-derived copy of COX12, in which the coding region for the suspected cytochrome oxidase subunit was replaced with the yeast URA3 gene. The resulting Ura+ deletion strain grew poorly at room temperature and was unable to grow at 37 degrees C on ethanol/glycerol medium, whereas growth was normal at both temperatures on dextrose. This temperature-dependent, petite phenotype of the deletion strain was complemented to wild-type growth with a single copy plasmid carrying COX12. Cytochrome c oxidase activity in mitochondrial membranes from the cox12 deletion strain is decreased to 5-15% of that in membranes from the wild-type parent, and this activity is restored to normal when the cox12 deletion strain is complemented by the plasmid-borne COX12. Optical spectra of mitochondrial membranes from the cox12 deletion strain revealed that optically detectable cytochrome c oxidase is assembled at room temperature and at 37 degrees C, although the heme a + a3 absorption is diminished approximately 50%. The N-terminal amino acid sequence of the protein encoded by COX12 is identical to the N-terminal sequence of a subunit found in yeast cytochrome c oxidase purified by a new procedure (Taanman, J.-W., and Capaldi, R. A. (1992) J. Biol. Chem. 267, 22481-22485). We conclude that COX12 encodes a subunit of yeast cytochrome c oxidase which is essential during assembly for full cytochrome c oxidase activity but apparently can be removed after the oxidase is assembled, with retention of oxidase activity. This is the first instance in which deletion of a subunit of cytochrome c oxidase results in assembly of optically detectable cytochrome c oxidase but having markedly diminished activity.     

Identification of regulatory elements involved in expression and induction by sucrose and UV-B light of the Arabidopsis thaliana COX5b-2 gene, encoding an isoform of cytochrome c oxidase subunit 5b

The promoter sequences required for expression of the Arabidopsis thaliana COX5b-2 gene, encoding an isoform of cytochrome c oxidase subunit 5b, were analyzed using plants transformed with deleted and mutagenized forms of the promoter fused to gus . A 1000-bp promoter fragment produces expression in root and shoot meristems, leaf and cotyledon tips, and anthers. Deletion analysis indicated the presence of positive and negative regulatory elements. A regulatory element located between −660 and −620 from the translation start site was identified as a G-box by mutagenic analysis. Mutation of the G-box, that is present within the coding region of the preceding gene in the genome, increases expression of COX5b-2 in cotyledon and leaf lamina and abolishes induction by ultraviolet-B (UV-B) light, which presumably acts through the removal of an inhibitory factor. Identified positive regulatory elements include a site II element (TGGGCC), a related element with the sequence TGGGTC and four initiator elements (YTCANTYY) that completely abolish expression when mutated in combination. Site II elements are also involved in the response to sucrose. The results imply that the COX5b-2 gene has retained expression characteristics presented by most respiratory chain component genes, but its expression mechanisms have diverged from those employed by COX5b-1 , the other gene encoding cytochrome c oxidase subunit 5b in Arabidopsis.     

COX8, the structural gene for yeast cytochrome c oxidase subunit VIII. DNA sequence and gene disruption indicate that subunit VIII is required for maximal levels of cellular respiration and is derived from a precursor which is extended at both its NH2 and COOH termini

From the amino acid sequence of yeast cytochrome c oxidase subunit VIII published previously (Power, S. D., Lochrie, M.A., Patterson, T.E., and Poyton, R.C. (1984) J. Biol. Chem. 259, 6571-6574), we have synthesized a pair of oligonucleotide probes and used them to identify COX8, its structural gene. By genomic Southern blot analysis and disruption of the COX8 chromosomal locus, we have shown that this gene is present in one copy per haploid genome and that its product, subunit VIII, is essential for maximal levels of cellular respiration and cytochrome c oxidase activity. Alignment of the amino acid sequence predicted from the DNA sequence of COX8 with the determined amino acid sequence of subunit VIII indicates that mature subunit VIII is derived from a larger precursor that extends from both the NH2 and COOH termini of the mature polypeptide. Thus, like many other nuclear coded mitochondrial proteins, subunit VIII is derived from a precursor which carries a leader peptide. In addition, this precursor, like that for yeast cytochrome c oxidase subunit VIIa, appears to carry a four-amino acid "trailer peptide" at its COOH terminus.     

Nuclear genes for mitochondrial proteins. Identification and isolation of a structural gene for subunit V of yeast cytochrome c oxidase

The gene for yeast cytochrome c oxidase subunit V, COX5, has been isolated from a Saccharomyces cerevisiae DNA library by complementation of a cytochrome c oxidase subunit V mutant, JM28. One complementing plasmid, YEp13-511, with a DNA insert of 4.8 kilobase pairs, has been characterized in detail. This plasmid restores respiratory competency in JM28, results in increased cytochrome c oxidase activity and a new form of subunit V in JM28 mitochondria, and is capable of selecting mRNA for subunit V. These results indicate that YEp13-511 carries the COX5 gene and that the subunit V encoded by this plasmid gene is capable of entering the mitochondrion and assembling into a functional holocytochrome c oxidase.     

Effects of a transition from normoxia to anoxia on yeast cytochrome c oxidase and the mitochondrial respiratory chain: implications for hypoxic gene induction

Previous studies have demonstrated that the mitochondrial respiratory chain and cytochrome c oxidase participate in oxygen sensing and the induction of some hypoxic nuclear genes in eukaryotes. In addition, it has been proposed that mitochondrially-generated reactive oxygen and nitrogen species function as signals in a signaling pathway for the induction of hypoxic genes. To gain insight concerning this pathway, we have looked at changes in the functionality of the yeast respiratory chain as cells experience a shift from normoxia to anoxia. These studies have revealed that yeast cells retain the ability to respire at normoxic levels for up to 4 h after a shift and that the mitochondrial cytochrome levels drop rapidly to 30--50% of their normoxic levels and the turnover rate of cytochrome c oxidase (COX) increases during this shift. The increase in COX turnover rate cannot be explained by replacing the aerobic isoform, Va, of cytochrome c oxidase subunit V with the more active hypoxic isoform, Vb. We have also found that mitochondria retain the ability to respire, albeit at reduced levels, in anoxic cells, indicating that yeast cells maintain a functional mitochondrial respiratory chain in the absence of oxygen. This raises the intriguing possibility that the mitochondrial respiratory chain has a previously unexplored role in anoxic cells and may function with an alternative electron acceptor when oxygen is unavailable.     

Mitochondrial membrane biogenesis: characterization and use of pet mutants to clone the nuclear gene coding for subunit V of yeast cytochrome c oxidase

A nuclear pet mutant of Saccharomyces cerevisiae that is defective in the structural gene for subunit V of cytochrome c oxidase has been identified and used to clone the subunit V gene (COX5) by complementation. This mutant, E4-238 [24], and its revertant, JM110, produce variant forms of subunit V. In comparison to the wild-type polypeptide (Mr = 12,500), the polypeptides from E4-238 and JM110 have apparent molecular weights of 9,500 and 13,500, respectively. These mutations directly alter the subunit V structural gene rather than a gene required for posttranslational processing or modification of subunit V because they are cis-acting in diploid cells; that is, both parental forms of subunit V are produced in heteroallelic diploids formed from crosses between the mutant, revertant, and wild type. Several plasmids containing the COX5 gene were isolated by transformation of JM28, a derivative of E4-238, with DNA from a yeast nuclear DNA library in the vector YEp13. One plasmid, YEp13-511, with a DNA insert of 4.8 kilobases, was characterized in detail. It restores respiratory competency and cytochrome oxidase activity in JM28, encodes a new form of subunit V that is functionally assembled into mitochondria, and is capable of selecting mRNA for subunit V. The availability of mutants altered in the structural gene for subunit V (COX5) and of the COX5 gene on a plasmid, together with the demonstration that plasmid-encoded subunit V is able to assemble into a functional holocytochrome c oxidase, enables molecular genetic studies of subunit V assembly into mitochondria and holocytochrome c oxidase.