Assembly of the mitochondrial membrane system. Characterization of COR1, the structural gene for the 44-kilodalton core protein of yeast coenzyme QH2-cytochrome c reductase

The respiratory deficiency of yeast strains previously assigned to complementation group G7 has been ascribed to the absence in the mutants of functional cytochrome b. Since G7 mutants are capable of synthesizing the apoprotein, the primary effect of the mutations is to prevent maturation of this electron carrier. The recombinant plasmid pG7/T1 with a 6.7-kilobase pairs (kb) insert of wild type yeast nuclear DNA has been selected from a genomic library by transformation of a G7 mutant to respiratory competency. The genetically active region of the pG7/T1 insert has been subcloned on a 3-kb fragment of DNA which has been shown to contain an open reading frame encoding a protein of 50,236 Mr. In situ disruption of the reading frame causes a deficiency in cytochrome b. The strain with the disrupted gene fails to complement G7 mutants thereby confirming the correct identification of the gene henceforth referred to as COR1. The carboxyl-terminal half of the COR1 gene has been fused to the amino-terminal half of the Escherichia coli trpE gene in the high expression vector pATH2. This plasmid construct promotes a high level of expression of the trpE/COR1 hybrid protein. Antibodies against the purified hybrid protein react with a 44 kDa protein subunit of yeast coenzyme QH2-cytochrome c reductase corresponding to the largest core subunit of the complex. These data indicate that the yeast nuclear gene COR1 codes for the 44-kDa core protein and that the latter is required for the conversion of apocytochrome b to mature cytochrome b.     

A mutation in yeast mitochondrial DNA results in a precise excision of the terminal intron of the cytochrome b gene

The yeast nuclear gene CBP2 was previously proposed to code for a protein necessary for processing of the terminal intron in the cytochrome b pre-mRNA (McGraw, P., and Tzagoloff, A. (1983) J. Biol. Chem. 258, 9459-9468). In the present study we describe a mitochondrial mutation capable of suppressing the respiratory deficiency of cbp2 mutants. The mitochondrial suppressor mutation has been shown to be the result of a precise excision of the last intervening sequence from the cytochrome b gene. Strains with the altered mitochondrial DNA have normal levels of mature cytochrome b mRNA and of cytochrome b and exhibit wild type growth on glycerol. These results confirm that CBP2 codes for a protein specifically required for splicing of the cytochrome b intron and further suggest that absence of the intervening sequence does not noticeably affect the expression of respiratory function in mitochondria.     

Assembly of the mitochondrial membrane system. Characterization of a yeast nuclear gene involved in the processing of the cytochrome b pre-mRNA

The cytochrome b gene of Saccharomyces cerevisiae D273-10B was previously shown to be composed of three exons and two introns (Nobrega, F.G., and Tzagoloff, A. (1980) J. Biol. Chem. 255, 9828-9837). In the present study nuclear respiratory deficient mutants of this strain have been screened for defects in processing of the cytochrome b pre-mRNA. Fifteen independently isolated mutants lacking cytochrome b have been assigned to a single genetic complementation group (G36). Members of this complementation group are blocked in the excision of the second intervening sequence of cytochrome b and consequently are unable to produce the mature mRNA. The wild type gene defined by this class of mutants has been named CBP2. A recombinant plasmid with the CBP2 gene has been selected from a library of wild type nuclear DNA and further subcloned by transformation of a cbp2 mutant to respiratory competency. The smallest plasmid (pG36/T5) capable of complementing cbp2 mutants and of restoring their ability to complete processing of the cytochrome b pre-mRNA has a nuclear DNA fragment of 2.6 kilobase pairs inserted at the BamHI site of the yeast vector YEp13. The sequence of the cloned DNA fragment has revealed an 1890-nucleotide-long reading frame encoding a basic protein with a molecular weight of 74,000. Deletion analysis confirms that the entire reading frame is required for complementation of cbp2 mutants. This reading frame is proposed to code for the CBP2 gene product.     

Characterization of a yeast nuclear gene (MST1) coding for the mitochondrial threonyl-tRNA1 synthetase

The wild-type yeast nuclear gene MST1 complements mutants defective in mitochondrial protein synthesis. The gene has been sequenced and shown to code for a protein of 54,030 kDa. The predicted product of MST1 is 36% identical over its 462 residues to the Escherichia coli threonyl-tRNA synthetase. Amino-acylation of wild-type mitochondrial tRNAs with a mitochondrial extract from mst1 mutants fail to acylate tRNAThr1 (anticodon: 3'-GAU-5') but show normal acylation of tRNAThr2 (anticodon: 3'-UGU-5'). These data suggest the presence of two separate threonyl-tRNA synthetases in yeast mitochondria. Antibodies were prepared against a trpE/MST1 fusion protein containing the 321 residues from the amino-terminal region of the E. coli anthranilate synthetase and 118 residues of the mitochondrial threonyl-tRNA synthetase. Antibodies to the fusion protein detect a 50-55-kDa protein in wild type yeast mitochondria but not in mitochondria of a strain in which the chromosomal MST1 gene was replaced by a copy of the same gene disrupted by insertion of the yeast LEU2 gene. The ability of the mutant with the inactive MST1 gene to charge tRNAThr2 argues strongly for the existence of a second threonyl-tRNA synthetase gene.     

ATP10, a yeast nuclear gene required for the assembly of the mitochondrial F1-F0 complex

A yeast nuclear gene (ATP10) is reported whose product is essential for the assembly of a functional mitochondrial ATPase complex. Mutations in ATP10 induce a loss of rutamycin sensitivity in the mitochondrial ATPase but do not affect respiratory enzymes. This phenotype has been correlated with a defect in the F0 sector of the ATPase. The wild type ATP10 gene has been cloned by transformation of an atp 10 mutant with a yeast genomic library. The gene codes for a protein of Mr = 30,293. The primary structure of the ATP10 product is not related to any known subunit of the yeast or mammalian mitochondrial ATPase complexes. To further clarify the role of this new protein in the assembly of the ATPase, an antibody was prepared against a hybrid protein expressed from a trpE/ATP 10 fusion gene. The antibody recognizes a 30-kDa protein present in wild type mitochondria. The protein is associated with the mitochondrial membrane but does not co-fractionate either with F1 or with the rutamycin-sensitive F1-F0 complex. These data suggest that the ATP10 product is not a subunit of the ATPase complex but rather is required for the assembly of the F0 sector of the complex.     

Mitochondrial translational-initiation and elongation factors in Saccharomyces cerevisiae

C155 and E252 are respiratory-defective mutants of Saccharomyces cerevisiae, previously assigned to complementation groups G37 and G142, respectively. The following evidence suggested that both mutants were likely to have lesions in components of the mitochondrial translational machinery: C155 and E252 display a pleiotropic deficiency in cytochromes a, a3 and b; both strains are severly limited in their ability to incorporate radioactive methionine into the mitochondrial translation products and, in addition, display a tendency to loose wild-type mitochondrial DNA. This set of characteristics is commonly found in strains affected in mitochondrial protein synthesis. To identify the biochemical lesions, each mutant was transformed with a wild-type yeast genomic library and clones complemented for the respiratory defect were selected for growth on a non-fermentable substrate. Analysis of the cloned genes revealed that C155 has a mutation in a protein which has high sequence similarity to bacterial elongation factor G and that E252 has a mutation in a protein homologous to bacterial initiation factor 2. Disruption of the chromosomal copy of each gene in a wild-type haploid yeast induced a phenotype analogous to that of the original mutants, but does not affect cell viability. These results indicate that both gene products function exclusively in mitochondrial protein synthesis. Subcloning of the IFM1 gene, coding for the mitochondrial initiation factor, indicates that the amino-terminal 423 residues of the protein are sufficient to promote peptide-chain initiation in vivo.     

Yeast cytochrome b2 gene: isolation with antibody probes

An efficient technique was used to clone the gene for yeast cytochrome b2, (a nuclear encoded mitochondrial protein) using the expression vector, lambda gt11 (lac 5 nin 5 c1857 S100). This enables the insertion of yeast DNA into the beta-galactosidase structural gene (lacZ) and promotes synthesis of hybrid proteins. Screening of antigen producing clones in the lambda gt11 recombinant genomic library was achieved using antiserum against cytochrome b2 according to Young and Davis (1983) Two recombinants containing part of the gene coding for cytochrome b2 were isolated and characterized as follows: by their expression in Escherichia coli cells, examined by immuno-blotting with antibodies to pure cytochrome b2. by DNA sequence analysis. One recombinant carries a 3 Kb yeast DNA insert which contains the whole nucleotide sequence encoding cytochrome b2 and a few amino acids of the amino terminal presequence.     

MSW, a yeast gene coding for mitochondrial tryptophanyl-tRNA synthetase

E569 and E606 are noncomplementing pet mutants of Saccharomyces cerevisiae. Both strains are defective in mitochondrial protein synthesis and as a result exhibit a pleiotropic deficiency in respiratory components that are translated on mitochondrial ribosomes. The wild type gene MSW capable of complementing the protein synthesis defect has been cloned by transformation of one of the mutants with a genomic library of wild type yeast nuclear DNA. The cloned gene has been sequenced and shown to code for a protein with a molecular weight of 42,414 which is 37 and 39% identical to the tryptophanyl-tRNA synthetases of Escherichia coli and Bacillus stearothermophilus, respectively. A strain containing an insertion in the chromosomal copy of MSW was constructed by in situ gene replacement. This mutant fails to charge mitochondrial tryptophanyl-tRNA providing further evidence that MSW is the structural gene for mitochondrial tryptophanyl tRNA synthetase. The existence of another gene coding for the cytoplasmic tryptophanyl-tRNA synthetase is inferred from the observation that mutations in MSW are not lethal but only result in a respiratory deficiency.     

Identification and characterization of genes for a second anthranilate synthase in Pseudomonas aeruginosa: interchangeability of the two anthranilate synthases and evolutionary implications.

Two anthranilate synthase gene pairs have been identified in Pseudomonas aeruginosa. They were cloned, sequenced, inactivated in vitro by insertion of an antibiotic resistance gene, and returned to P. aeruginosa, replacing the wild-type gene. One anthranilate synthase enzyme participates in tryptophan synthesis; its genes are designated trpE and trpG. The other anthranilate synthase enzyme, encoded by phnA and phnB, participates in the synthesis of pyocyanin, the characteristic phenazine pigment of the organism. trpE and trpG are independently transcribed; homologous genes have been cloned from Pseudomonas putida. The phenazine pathway genes phnA and phnB are cotranscribed. The cloned phnA phnB gene pair complements trpE and trpE(G) mutants of Escherichia coli. Homologous genes were not found in P. putida PPG1, a non-phenazine producer. Surprisingly, PhnA and PhnB are more closely related to E. coli TrpE and TrpG than to Pseudomonas TrpE and TrpG, whereas Pseudomonas TrpE and TrpG are more closely related to E. coli PabB and PabA than to E. coli TrpE and TrpG. We replaced the wild-type trpE on the P. aeruginosa chromosome with a mutant form having a considerable portion of its coding sequence deleted and replaced by a tetracycline resistance gene cassette. This resulted in tryptophan auxotrophy; however, spontaneous tryptophan-independent revertants appeared at a frequency of 10(-5) to 10(6). The anthranilate synthase of these revertants is not feedback inhibited by tryptophan, suggesting that it arises from PhnAB. phnA mutants retain a low level of pyocyanin production. Introduction of an inactivated trpE gene into a phnA mutant abolished residual pyocyanin production, suggesting that the trpE trpG gene products are capable of providing some anthranilate for pyocyanin synthesis.     

Cloning, sequencing, and mapping of the bacterioferritin gene (bfr) of Escherichia coli K-12.

The bacterioferritin (BFR) of Escherichia coli K-12 is an iron-storage hemoprotein, previously identified as cytochrome b1. The bacterioferritin gene (bfr) has been cloned, sequenced, and located in the E. coli linkage map. Initially a gene fusion encoding a BFR-lambda hybrid protein (Mr 21,000) was detected by immunoscreening a lambda gene bank containing Sau3A restriction fragments of E. coli DNA. The bfr gene was mapped to 73 min (the str-spc region) in the physical map of the E. coli chromosome by probing Southern blots of restriction digests of E. coli DNA with a fragment of the bfr gene. The intact bfr gene was then subcloned from the corresponding lambda phage from the gene library of Kohara et al. (Y. Kohara, K. Akiyama, and K. Isono, Cell 50:495-508, 1987). The bfr gene comprises 474 base pairs and 158 amino acid codons (including the start codon), and it encodes a polypeptide having essentially the same size (Mr 18,495) and N-terminal sequence as the purified protein. A potential promoter sequence was detected in the 5' noncoding region, but it was not associated with an "iron box" sequence (i.e., a binding site for the iron-dependent Fur repressor protein). BFR was amplified to 14% of the total protein in a bfr plasmid-containing strain. An additional unidentified gene (gen-64), encoding a relatively basic 64-residue polypeptide and having the same polarity as bfr, was detected upstream of the bfr gene.     

Isolation and characterization of the yeast 3-phosphoglycerokinase gene (PGK) by an immunological screening technique

An immunological screening technique has been used for the detection of a specific antigen-producing clone in a bank of bacterial colonies containing hybrid plasmids. This technique involves covalent attachment of antiserum to cyanogen bromide-activated paper discs, contact of this paper with lysed colonies on agar plates, and finally detection of the bound antigen with 125I-labeled antibody. Using this method, we have identified an Escherichia coli colony, containing a yeast DNA insert in plasmid ColE1, that produces antigen which combines with antibody directed against purified yeast 3-phosphoglycerate kinase. The hybrid plasmid (pYe57E2) obtained by this procedure has been shown by both biochemical and genetic methods to contain the structural gene PGK for yeast 3-phosphoglycerate kinase. The location of the PGK structural gene on pYe56E2 was determined by immunological screening of E. coli colonies bearing plasmids containing various reconstructions of the original yeast DNA insert. Examination of the expression of the cloned yeast PGK gene in both E. coli and yeast has shown that functional enzyme is synthesized from the cloned gene in yeast, but not in E. coli.     

Antibodies against a fused ''lacZ-yeast mitochondrial intron'' gene product allow identification of the mRNA maturase encoded by the fourth intron of the yeast cob-box gene.

Several missense or nonsense mutations have been localized in the fourth intron open reading frame (ORF) of the yeast mitochondrial cytochrome b gene. These results and the phenotypes of mutants strongly suggested that a mRNA maturase, controlling the expression of both cytochrome b and cytochrome oxidase subunit I (COXI) genes, is encoded in this ORF. To investigate more directly the biosynthesis of mRNA maturase we raised antibodies against a part of the putative ORF translation product. For that purpose we inserted a fragment of the ORF sequence, in phase, into the C-terminal EcoRI site of lacZ gene. The hybrid gene was then expressed in Escherichia coli under the control of either the wild-type lac promoter or the thermoregulated lambda system PR/cI857. The hybrid protein was partially purified and antibodies were raised against it. These antibodies recognized a mitochondrially coded protein, p27, in intron mutants, whereas no such protein was detected in the wild-type cell. These results demonstrate that the p27 protein, previously shown to be associated with the mRNA maturase activity, is actually translated from the intron ORF. The autoregulated mRNA maturase synthesis model is discussed in relation to these results.     

Isolation and characterization of the yeast gene coding for the alpha subunit of mitochondrial phenylalanyl-tRNA synthetase

The respiratory defect of pet mutants of Saccharomyces cerevisiae assigned to complementation group G120 has been ascribed to their inability to acylate the mitochondrial phenylalanyl tRNA. A fragment of wild type yeast genomic DNA capable of complementing the genetic lesion of G120 mutants has been cloned by transformation with a yeast genomic recombinant library of a representative mutant from this complementation group. The gene designated as MSF1 has been subcloned on a 2.2-kilobase pair fragment and its nucleotide sequence determined. The predicted protein product of MSF1 has a molecular weight of 55,314 and has several domains of high primary sequence homology to the alpha subunit of the Escherichia coli phenylalanyl-tRNA synthetase. Based on the phenotype of G120 mutants and the homology to the bacterial protein, MSF1 is proposed to code for the alpha subunit of yeast mitochondrial phenylalanyl-tRNA synthetase. Disruption of the chromosomal copy of MSF1 in the respiratory-competent haploid strain W303-1B induces a phenotype similar to G120 mutants but does not affect cell viability, indicating that the cytoplasmic phenylalanyl-tRNA synthetase of yeast is encoded by a separate gene. Although the E. coli and yeast mitochondrial aminoacyl-tRNA synthetases are sufficiently similar in their primary sequences to suggest a common evolutionary origin, they have undergone significant changes as evidenced by the low homology in some regions of the polypeptide chains and the presence in the mitochondrial enzyme of two domains that are lacking in the bacterial phenylalanyl-tRNA synthetase.     

TGATG vector: a new expression system for cloned foreign genes in Escherichia coli cells

A TGATG vector system was developed that allows for the construction of hybrid operons with partially overlapping genes, employing the effects of translational coupling to optimize expression of cloned cistrons in Escherichia coli. In this vector system (plasmid pPR-TGATG-1), the coding region of a foreign gene is attached to the ATG codon situated on the vector, to form the hybrid operon transcribed from the phage lambda PR promoter. The cloned gene is the distal cistron of this hybrid operon ('overlappon'). The efficiently translated cro'-cat'-'trpE hybrid cistron is proximal to the promoter. The coding region of this artificial fused cistron [the length of the corresponding open reading frame is about 120 amino acids (aa)] includes the following: the N-terminal portions of phage lambda Cro protein (20 aa), the CAT protein of E. coli (72 aa) and 3' C-terminal codons of the E. coli trpE gene product. At the 3'-end of the cro'-cat'-'trpE fused cistron there is a region for efficient translation reinitiation: a Shine-Dalgarno sequence of the E. coli trpD gene and the overlapping stop and start codons (TGATG). In this sequence, the last G is the first nucleotide of the unique SacI-recognition site (GAGCT decreases C) and so integration of the structural part of the foreign gene into the vector plasmid may be performed using blunt-end DNA linking after the treatment of pPR-TGATG-1 with SacI and E. coli DNA polymerase I or its Klenow fragment.(ABSTRACT TRUNCATED AT 250 WORDS)     

The novel function of the Saccharomyces cerevisiaeCBP2 gene as a splicing factor essential to excision of the Saccharomyces douglasiiLSU intron in vivo

In the yeast Saccharomyces cerevisiae, the product of the nuclear gene CBP2 is required exclusively for the splicing of the terminal intron of the mitochondrial cytochrome b gene. The homologous gene from the related yeast, Saccharomyces douglasii, has been shown to be essential for respiratory growth in the presence of a wild-type S. douglasii mitochondrial genome and dispensable in the presence of an intronless mitochondrial genome. The two CBP2 genes are functionally interchangeable although the target intron of the S. cerevisiaeCBP2 gene is absent from the S. douglasii mitochondrial genome. To determine the function of the CBP2 gene in S. douglasii mitochondrial pre-RNA processing we have constructed and analyzed interspecific hybrid strains between the nuclear genome of S. cerevisiae carrying an inactive CBP2 gene and S. douglasii mitochondrial genomes with different intron contents. We have demonstrated that inactivation of the S. cerevisiaeCBP2 gene affects the maturation of the S. douglasii LSU pre-RNA, leading to a respiratory-deficient phenotype in the hybrid strains. We have shown that the CBP2 gene is essential for excision of the S. douglasii LSU intron in vivo and that the gene is dispensable when this intron is deleted or replaced by the S. cerevisiae LSU intron.     

Beta-galactosidase fused to the hydrophobic domain of cytochrome b5 spontaneously associates with liposomes

Since liver microsomal cytochrome b5 spontaneously associates with liposomes and membranes by means of its C-terminal hydrophobic domain (HP), chimeric proteins containing HP prepared by genetic fusion might also spontaneously associate with liposomes or cellular membranes. Synthetic DNA corresponding to the hydrophobic domain of cytochrome b5 was enzymatically fused in-frame to cloned DNA corresponding to the C-terminus of the Escherichia coli enzyme, beta-galactosidase. This protein, LacZ:HP, synthesized in E. coli and purified from a crude E. coli membrane extract, was shown to spontaneously associated with liposomes, as does cytochrome b5. Association is rapid and stable in the presence of salt and high pH and the fusion protein behaves as an integral membrane protein. LacZ:HP can be readily and extensively purified from crude extracts by association with liposomes and this procedure may provide a convenient purification scheme for proteins not otherwise readily purified, for example polypeptides from cloned gene fragments to be used for antibody production. These hybrid proteins may represent a new potentially useful class of polypeptides capable of hydrophobic interactions with membranes.     

Nuclear genes coding the yeast mitochondrial adenosine triphosphatase complex. Isolation of ATP2 coding the F1-ATPase beta subunit

A yeast nuclear pet mutant of Saccharomyces cerevisiae lacking any detectable mitochondrial F1-ATPase activity was genetically complemented upon transformation with a pool of wild type genomic DNA fragments carried in the yeast Escherchia coli shuttle vector YEp 13. Plasmid-dependent complementation restored both growth of the pet mutant on a nonfermentable carbon source as well as functional mitochondrial ATPase activity. Characterization of the complementing plasmid by plasmid deletion analysis indicated that the complementing gene was contained on adjoining BamH1 fragments with a combined length of 3.05 kilobases. Gel analysis of the product of this DNA by in vitro translation in a rabbit reticulocyte lysate programmed with yeast mRNA hybrid selected by the plasmid revealed a product which could be immunoprecipitated by antisera against the beta subunit of the yeast mitochondrial ATPase complex. A comparison of the protein sequence derived from partial DNA sequence analysis indicated that the beta subunit of the yeast mitochondrial ATPase complex exhibits greater than 70% conservation of protein sequence when compared to the same subunit from the ATPase of E. coli, beef heart, and chloroplast. The gene coding the beta subunit (subunit 2) of yeast mitochondrial adenosine triphosphatase is designated ATP2. The utilization of cloned nuclear structural genes of mitochondrial proteins for the analysis of the post-translational targeting and import events in organelle assembly is discussed.