Fine structure of OXI1, the mitochondrial gene coding for subunit II of yeast cytochrome c oxidase

Role of yUbp8 in Mitochondria and Hypoxia Entangles the Finding of Human Ortholog Usp22 in the Glioblastoma Pseudo-Palisade Microlayer

KAT Gcn5 and DUB Ubp8 are required for respiration and mitochondria functions in budding yeast, and in this study we show that loss of respiratory activity is acquired over time. Interestingly, we show that absence of Ubp8 allows cells to grow in hypoxic conditions with altered mitophagy. Comparatively, the aggressive glioblastoma (GBM) multiforme tumor shows survival mechanisms able to overcome hypoxia in the brain. Starting from yeast and our findings on the role of Ubp8 in hypoxia, we extended our analysis to the human ortholog and signature cancer gene Usp22 in glioblastoma tumor specimens. Here we demonstrate that Usp22 is localized and overexpressed in the pseudo-palisade tissue around the necrotic area of the tumor. In addition, Usp22 colocalizes with the mitophagy marker Parkin, indicating a link with mitochondria function in GBM. Collectively, this evidence suggests that altered expression of Usp22 might provide a way for tumor cells to survive in hypoxic conditions, allowing the escape of cells from the necrotic area toward vascularized tissues. Collectively, our experimental data suggest a model for a possible mechanism of uncontrolled proliferation and invasion in glioblastoma.

Cytochrome c oxidase deficiency

Cytochrome c oxidase (COX) deficiency is characterized by a high degree of genetic and phenotypic heterogeneity, partly reflecting the extreme structural complexity, multiple post-translational modification, variable, tissue-specific composition, and the high number of and intricate connections among the assembly factors of this enzyme. In fact, decreased COX specific activity can manifest with different degrees of severity, affect the whole organism or specific tissues, and develop a wide spectrum of disease natural history, including disease onsets ranging from birth to late adulthood. More than 30 genes have been linked to COX deficiency, but the list is still incomplete and in fact constantly updated. We here discuss the current knowledge about COX in health and disease, focusing on genetic aetiology and link to clinical manifestations. In addition, information concerning either fundamental biological features of the enzymes or biochemical signatures of its defects have been provided by experimental in vivo models, including yeast, fly, mouse and fish, which expanded our knowledge on the functional features and the phenotypical consequences of different forms of COX deficiency.

Recombinational analysis of oxi2 mutants and preliminary analysis of their translation products in S. cerevisiae

Genetic and biochemical studies were performed with mutants allocated to the mitochondrial oxi2 gene.Recombinational analysis of 19 oxi2 mutants was performed using α and a mutant strains derived from the same genetic background. The frequencies of wild-type recombinants in oxi2 (-) × oxi2 (-) crosses varied from 0.002 to 17%. The map of oxi2 mutations constructed on the basis of these frequencies shows many internal inconsistencies. In the course of rho (-) deletion mapping five classes of oxi2 mutations were distinguished. The results of deletion analysis are in agreement with those of recombinational mapping.The analysis of mitochondrial translation products by SDS-polyacrylamide electrophoresis of 20 oxi2 mutants shows that 17 of them are connected with conspicuous changes of 22 kd polypeptide band corresponding to subunit III of cytochrome oxidase. At least four of them carried instead of subunit III clearly visible significantly shorter polypeptides (12.8 to 20.1 kd). These were, most likely, shorter fragments of subunit III resulting from chain termination mutations. Colinearity was observed between the lenght of new polypeptides and the positions of the respective mutations on the recombinational map. These data confirm hat oxi2 encodes subunit III of cytochrome oxidase and suggest that translation of the oxi2 gene is in the direction from V303 to V273.

The effect of amino acid substitutions in the conserved aromatic region of subunit II of cytochrome c oxidase in Saccharomyces cerevisiae

Mitochondrial encoded subunit II of cytochrome c oxidase carries the metal center, which acts as the initial acceptor of electrons from cytochrome c. Among the conserved features of this protein is a region in which five aromatic and three non-aromatic amino acids are conserved in a wide variety of organisms. This aromatic region has been postulated to be involved in transfer of electrons from the copper center in subunit II to the remaining metal centers of cytochrome oxidase in subunit I. To test the functional importance of two conserved, aromatic tryptophan residues and one conserved, non-aromatic glycine residue, yeast strains with alterations at these positions were characterized. The strains with altered codons were tested for their ability to carry out cellular respiration, for their growth rates on non-fermentable carbon sources, and for their cytochrome c oxidase activity. The results demonstrate that the aromatic character of the tryptophan residues appears necessary for subunit II function, while the conserved glycine can be replaced with other, small, uncharged residues.

A point mutation in the 5'-untranslated leader that affects translational activation of the mitochondrial COX3 mRNA

The 613-base 5'-untranslated leader (5'-UTL) of the Saccharomyces cerevisiae mitochondrial COX3 mRNA contains the target of an mRNA-specific translational activator complex composed of at least three nuclearly encoded proteins. We have genetically mapped a collection of cox3 point mutations, using a set of defined COX3 deletions, and found one to be located in the region coding the 5'-UTL. The strain carrying this allele was specifically defective in translation of the COX3 mRNA. Nucleotide-sequence analysis showed that the allele was in fact a double mutation comprised of a single-base insertion in the 5'-UTL (T inserted between bases -428 and -427 with respect to the start of translation) and a G to A substitution at +3 that changed the ATG initiation codon to ATA. Both mutations were required to block translation completely. The effects of the ATG to ATA mutation alone (cox3-1) had previously been analyzed in this laboratory: it reduces, but does not eliminate, translation, causing a slow respiratory growth phenotype. The T insertion in the 5'-UTL had no detectable respiratory growth phenotype as a single mutation. However, the 5'-UTL insertion mutation enhanced the respiratory defective phenotype of missense mutations in pet54, one of the COX3-specific translational-activator genes. This phenotypic enhancement suggests that the -400 region of the 5'-UTL, where the mutation is located, is important for Pet54p-COX3 mRNA interaction.

Mutation of a highly conserved base in the yeast mitochondrial 21S rRNA restricts ribosomal frameshifting

A mutation shown to cause resistance to chloramphenicol in Saccharomyces cerevisiae was mapped to the central loop in domain V of the yeast mitochondrial 21S rRNA. The mutant 21S rRNA has a base pair exchange from U2677 (corresponding to U2504 in Escherichia coli) to C2677, which significantly reduces rightward frameshifting at a UU UUU UCC A site in a +1 U mutant. There is evidence to suggest that this reduction also applies to leftward frameshifting at the same site in a -1 U mutant. The mutation did not increase the rate of misreading of a number of mitochondrial missense, nonsense or frameshift (of both signs) mutations, and did not adversely affect the synthesis of wild-type mitochondrial gene products. It is suggested here that ribosomes bearing either the C2677 mutation or its wild-type allele may behave identically during normal decoding and only differ at sites where a ribosomal stall, by permitting non-standard decoding, differentially affects the normal interaction of tRNAs with the chloramphenicol resistant domain V. Chloramphenicol-resistant mutations mapping at two other sites in domain V are described. These mutations had no effect on frameshifting.

Replacement of a conserved glycine residue in subunit II of cytochrome c oxidase interferes with protein function

In this paper we describe the isolation and characterization of a respiration-deficient yeast strain which is defective in the function of subunit II of cytochrome c oxidase. This strain, VC32, carries a mutation in the mitochondrial COX2 gene which converts a conserved glycine residue to arginine. The conserved glycine is in a region implicated as important for ligating the CuA redox center and for interaction with cytochrome c. We have also characterized five revertants of VC32 which have recovered respiratory function; all five were mapped to the mitochondrial genome. In three of the five revertants the wild-type glycine codon is restored, while in two of the five the mutant arginine codon is still present. These two strains are likely to possess alterations either in components of the mitochondrial translation machinery or in mitochondrially-encoded gene products that interact directly with subunit II to assemble an active oxidase complex.

A GC cluster repeat is a hotspot for mit- macro-deletions in yeast mitochondrial DNA

In a random collection of mit- mutations of the yeast strain 777-3A we find that deletions are exceptionally frequent in the OXI3 gene, a large mosaic gene coding for subunit I of cytochrome oxidase. About 10% of all oxi3-mutants carry the same macro-deletion, del-A, extending from the 5' non-translated leader of OXI3 to intron 5b of this gene. Determination of the respective wild-type sequences and of the del-A junction sequence revealed that the end-points of the deletion are in two GC clusters with 31 bp sequence identity which are located at a distance of 11.3 kb. We speculate that not only the sequence identity of the two GC clusters but also the palindromic structure of these putatively mobile elements of yeast mitochondrial DNA (mtDNA) plays a role in deletion formation.

Mitochondrial mutations restricting spontaneous translational frameshift suppression in the yeast Saccharomyces cerevisiae

The +1 frameshift mutation, M5631, which is located in the gene (oxi1) for cytochrome c oxidase II (COXII) of the yeast mitochondrial genome, is suppressed spontaneously to a remarkably high extent (20%-30%). The full-length wild-type COXII produced as a result of suppression allows the mutant strain to grow with a "leaky" phenotype on non-fermentable medium. In order to elucidate the factors and interactions involved in this translational suppression, the strain with the frameshift mutation was mutated by MnCl2 treatment and a large number of mutants showing restriction of the suppression were isolated. Of 20 mutants exhibiting a strong, restricted, respiration-deficient (RD) phenotype, 6 were identified as having mutations in the mitochondrial genome. Furthermore, genetic analyses mapped one mutation to the vicinity of the gene for tRNA(Pro) and two others to a region of the tRNA cluster where two-thirds of all mitochondrial tRNA genes are encoded. The degree of restriction of the spontaneous frameshift suppression was characterized at the translational level by in vivo 35S-labeling of the mitochondrial translational products and immunoblotting. These results showed that in some of these mutant strains the frameshift suppression product is synthesized to the same extent as in the leaky parent strain. It is suggested that more than one +1 frame-shifted product is made as a result of suppression in these strains: one is as functional as the wild-type COXII, the other(s) is (are) nonfunctional and prevent leaky growth on non-fermentable medium. A possible mechanism for this heterogenous frameshift suppression is discussed.

The paromomycin resistance mutation (parr-454) in the 15 S rRNA gene of the yeast Saccharomyces cerevisiae is involved in ribosomal frameshifting

The leaky expression of the yeast mitochondrial gene oxi1, containing a framshift mutation (+1), is caused by natural frameshift suppression, as shown previously (Fox and Weiss-Brummer 1980). A drastic decrease in the natural level of frameshifting is found in the presence of the parr-454 mutation, localized at the 3' end of the 15 S rRNA gene. This mutation causes resistance to the antibiotic paromomycin in the yeast strains D273-10B and KL14-4A (Li et al. 1982; Tabak et al. 1982). The results of this study imply that in the yeast strain 777-3A this mutation alone is sufficient for restriction of the level of natural frameshifting but is insufficient to confer resistance to paromomycin. A second mutation, arising spontaneously with a frequency of 10(-4) leads, in combination with the parr-454 mutation, to full paromomycin resistance in strain 777-3A.

A mitochondrial frameshift suppressor maps in the tRNASer-var1 region of the mitochondrial genome of the yeast S. cerevisiae

A polypeptide chain-terminating mutation (M5631) previously has been shown to be a +1T insertion in the yeast mitochondrial gene oxi1, coding for subunit II of the cytochrome c oxidase. A spontaneously arisen frameshift suppressor (mfs-1) that is mitochondrially inherited suppresses this mutation to a considerable extent. The suppressor mutation was mapped by genetic and molecular analyses in the mitochondrial tRNASer-var1 region of the mitochondrial genome of the yeast S. cerevisiae. Genetic analyses show that the suppressor mfs-1 does not suppress other known mitochondrial frameshift mutations, or missense and nonsense mutations.

Accumulation of the cytochrome c oxidase subunits I and II in yeast requires a mitochondrial membrane-associated protein, encoded by the nuclear SCO1 gene

The yeast nuclear SCO1 gene is required for accumulation of the mitochondrially synthesized cytochrome c oxidase subunits I and II (COXI and COXII). We cloned and characterized the SCO1 gene. It codes for a 0.9 kb transcript. DNA sequence analysis predicts a 33 kDa protein. As shown by in vitro transcription and translation experiments in combination with import studies on isolated mitochondria, this protein is matured into a 30 kDa polypeptide which is tightly associated with a mitochondrial membrane. The possible function of the SCO1 gene product in the assembly of cytochrome c oxidase is discussed.

Nuclear functions required for cytochrome c oxidase biogenesis in Saccharomyces cerevisiae: multiple trans-acting nuclear genes exert specific effects on expression of each of the cytochrome c oxidase subunits encoded on mitochondrial DNA

Fourteen nuclear complementation groups of mutants that specifically affect the three mitochondrially-encoded subunits of yeast cytochrome c oxidase have been characterized. Genes represented by these complementation groups are not required for mitochondrial transcription, transcript processing, or translation per se but are required for the expression of one of the three genes--COX1, COX2, or COX3--which encode the cytochrome c oxicase subunits I, II, or III, respectively. Five of these genes affect the biogenesis of cytochrome c oxidase subunit I, 3 affect the biogenesis of subunit II, 3 affect the biogenesis of subunit III and 3 affect the biogenesis of both cytochrome c oxidase subunit I and cytochrome b, the product of COB. Among the 5 complementation groups of mutants that affect the expression of COX1, 2 lack COX1 transcripts, 1 produces incompletely processed COX1 transcripts, and 2 contain normal levels of normal-sized COX1 transcripts. In contrast, all 3 complementation groups which affect the expression of COX2 and all 3 complementation groups which affect the expression of COX3 exhibit no, or little, detectable difference with respect to the wild type pattern of transcripts. The 3 complementation groups which affect the expression of both COX1 and COB all have aberrant COX1 and COB transcript patterns. These findings indicate that multiple trans-acting nuclear genes are required for specific expression of each COX gene encoded on mitochondrial DNA and suggest that their products act at different steps in the expression of these mitochondrial genes.

A mitochondrial frameshift-suppressor (+1) [corrected] of the yeast S. cerevisiae maps in the mitochondrial 15S rRNA locus

The first case of a +1 "extrageneic" frameshift suppressor (MF1), mapping in the yeast mitochondrial 15S rRNA gene is reported. The suppressor was identified by genetic analyses in a leaky mitochondrial oxil frameshift mutant and the respective wild-type strain 777-3A of the yeast S. cerevisiae. This is in accordance with the finding that all mitochondrial frameshift mutants isolated from this strain tend to be leaky to a variable degree. MF1 does not suppress known nonsense mutations created by a direct basepair exchange in strain 777-3A. These mutants exhibit a non-leaky phenotype (Weiss-Brummer et al. 1984).

Primary structure of wild-type and mutant alleles of the PET494 gene of Saccharomyces cerevisiae

The product of the yeast nuclear gene PET494 is required specifically for the translation of the mitochondrially encoded subunit III of cytochrome c oxidase. We have determined the DNA sequence of a 1.9 kb fragment carrying PET494. The sequence contains a single long open reading frame of 489 codons. This open reading frame encodes the PET494 protein since the DNA sequence of the corresponding fragment derived from a strain with a known pet494 amber mutation contained an in frame UAG codon. The results of S1 nuclease protection experiments demonstrated that this region is transcribed and that the 5' ends of the major transcripts lie 30 to 40 base-pairs upstream of the first AUG codon in the PET494 reading frame. The predicted PET494 protein has a highly basic amino-terminal domain of 66 amino acids followed by a stretch of 32 uncharged residues, half of which are hydrophobic. The remainder of the protein is not unusual in amino acid composition or distribution except that the carboxyterminal region is notably basic. The phenotype of mutations generated in vitro around codon 119 by exonuclease digestion and linker insertion indicated that this region is dispensable for function. A mutation caused by deletion of 101 bp of coding sequence behaved like a simple frameshift when inserted into the chromosome: it was partially suppressed by the recessive non-group specific frameshift suppressor suf13 and reverted to Pet+ phenotype by mutations linked to PET494.

Functional nuclear suppressor of mitochondrial oxi2 mutations in yeast

A semidominant nuclear suppressor, called nam6, of oxi2-V276 mitochondrial mutation has been isolated and characterized. The nuclear character of nam6 was proved by its retention in rho degree strains, lack of mitotic segregation in diploids and meiotic 2:2 segregation in tetrads. The specificity of nam6 was tested on 315 mit- mutations of four mitochondrial genes (oxi1, oxi2, oxi3, and cob-box). It suppresses clearly only three mutations in the oxi2 gene, restoring partially or completely cytochrome aa3 formation. The results suggest a functional character of the suppression.

Deletions in the cob gene of yeast mtDNA and their phenotypic effect

Two cob- deletion mutants are characterized. One of them, M9410, is deleted for 911 bp of the noncoding sequences only which separate tRNAGlu and cob exon 1; it thus lacks most of the sequence encoding the 957 bp long cob leader (Bonitz et al. 1982) and some 20 bp 5' to it. The end points of this deletion coincide with 31 bp long direct repeats in wild type mtDNA. The other mutant, M9391, is deleted for all cob coding sequences and most of the cob leader sequence but it retains the 5' terminal 261 bp of this leader. Northern analysis revealed that M9410 totally lacks cob mRNA or pre-mRNA. The large deletion M9391 in contrast accumulates a 13S RNA which probably results from transcription through the junction, which ligates sequences of the cob leader to sequences of the cob-oli1 intergenic spacer.

A nuclear mutation that post-transcriptionally blocks accumulation of a yeast mitochondrial gene product can be suppressed by a mitochondrial gene rearrangement

The nuclear amber mutation, pet494-1, specifically blocks the accumulation of the product of the mitochondrial gene oxi2, cytochrome oxidase subunit III. The pet494-1 mutation does not prevent transcription of the mitochondrial gene since RNA--gel blot hybridizations showed that mutant cells contain normal amounts of an oxi2 transcript, indistinguishable in size from wild-type. A mitochondrial mutation that partially suppresses the nuclear mutation was isolated. The "mitochondrial revertant" behaved as though it contained two different mitochondrial DNAs: one rho+, the other rho-. The suppressor mutation is carried on the rho- mitochondrial DNA and is apparently the result of a gene fusion between oxi2 and another mitochondrial gene, oxi3. This gene rearrangement replaced the normal 5'-non-translated sequence of oxi2 with a portion of the open reading frame of the second intron of oxi3. Novel transcripts of the rearranged gene, containing oxi3 sequences upstream from oxi2 were detected in the mitochondrial revertant. The strain accumulated an electrophoretically variant form of cytochrome oxidase subunit III, probably translated from a new initiation codon. The data are consistent with models in which the PET494 protein acts within the mitochondria to specifically promote the translation of the oxi2 messenger RNA.

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.

mit-Mutations in the structural gene of subunit III of cytochrome oxidase in Saccharomyces cerevisiae

Two-dimensional electrophoretic analysis of the mitochondrial translation products of four mit-mutants indicate that subunit III of cytochrome oxidase is the only mitochondrial translation product affected by mutations in the oxi2 region of the mtDNA. Mitochondria of two of these mutants synthesize new products which coprecipitate with an anticytochrome oxidase antiserum and produce proteolytic digests similar to those of subunit III of the enzyme complex. These data strongly support the suggestion that the oxi2 region of the yeast mtDNA contains the structural gene of subunit III of cytochrome oxidase.

Leaky +1 and -1 frameshift mutations at the same site in a yeast mitochondrial gene

Two mutations in a mitochondrial structural gene, which cause leaky premature polypeptide chain termination and leaky growth, are +1 and -1 frameshifts in the same run of five T residues. The partial restoration of reading frame is probably due to ribosomal frameshifting at this site, and may be promoted by the unique structure of the yeast mitochondrial t RNAPhe.