Regulatory interactions between mitochondrial genes: interactions between two mosaic genes

Cbp3-Cbp6 interacts with the yeast mitochondrial ribosomal tunnel exit and promotes cytochrome b synthesis and assembly

A complex specifically required for the biogenesis of the respiratory chain component cytochrome b binds to the tunnel exit of yeast mitochondrial ribosomes to coordinate protein synthesis and assembly.

Mitochondria contain their own genetic system to express a small number of hydrophobic polypeptides, including cytochrome b, an essential subunit of the bc₁ complex of the respiratory chain. In this paper, we show in yeast that Cbp3, a bc₁ complex assembly factor, and Cbp6, a regulator of cytochrome b translation, form a complex that associates with the polypeptide tunnel exit of mitochondrial ribosomes and that exhibits two important functions in the biogenesis of cytochrome b. On the one hand, the interaction of Cbp3 and Cbp6 with mitochondrial ribosomes is necessary for efficient translation of cytochrome b transcript. On the other hand, the Cbp3–Cbp6 complex interacts directly with newly synthesized cytochrome b in an assembly intermediate that is not ribosome bound and that contains the assembly factor Cbp4. Our results suggest that synthesis of cytochrome b occurs preferentially on those ribosomes that have the Cbp3–Cbp6 complex bound to their tunnel exit, an arrangement that may ensure tight coordination of cytochrome b synthesis and assembly.

The reverse transcriptase encoded by ai1 intron is active in trans in the retro-deletion of yeast mitochondrial introns

Genomic mitochondrial intron deletion occurs frequently during the reversion of mitochondrial intronic mutations in Saccharomyces cerevisiae. The multiplicity as well as the apparent polarity of intron deletion led us to propose the implication of reverse transcription in this process. The two first introns of the COX1 (cytochrome oxidase I) gene, ai1 and ai2, are known to be homologous to viral reverse transcriptase and to encode such activity. We have tested the involvement of these introns in the deletion process by constructing three isogenic strains. They contain the same reporter mutation in the second intron of the CYTb (cytochrome b) gene but differ from each other by the presence or the absence of the ai1 and/or ai2 introns in the other gene encoding the COX1 subunit. Only the strain lacking ai1 and ai2 introns is no more able to revert by intron deletion. The strain retaining only the ai1 intron was able to revert by intron deletion. We conclude that the reverse transcriptase activity, even when encoded by only ai1 intron, can act in trans in the intron deletion process, during the reversion of intronic mutations.

The bI4 group I intron binds directly to both its protein splicing partners, a tRNA synthetase and maturase, to facilitate RNA splicing activity

The imported mitochondrial leucyl-tRNA synthetase (NAM2p) and a mitochondrial-expressed intron-encoded maturase protein are required for splicing the fourth intron (bI4) of the yeast cob gene, which expresses an electron transfer protein that is essential to respiration. However, the role of the tRNA synthetase, as well as the function of the bI4 maturase, remain unclear. As a first step towards elucidating the mechanistic role of these protein splicing factors in this group I intron splicing reaction, we tested the hypothesis that both leucyl-tRNA synthetase and bI4 maturase interact directly with the bI4 intron. We developed a yeast three-hybrid system and determined that both the tRNA synthetase and bI4 maturase can bind directly and independently via RNA-protein interactions to the large bI4 group I intron. We also showed, using modified two-hybrid and three-hybrid assays, that the bI4 intron bridges interactions between the two protein splicing partners. In the presence of either the bI4 maturase or the Leu-tRNA synthetase, bI4 intron transcribed recombinantly with flanking exons in the yeast nucleus exhibited splicing activity. These data combined with previous genetic results are consistent with a novel model for a ternary splicing complex (two protein: one RNA) in which both protein splicing partners bind directly to the bI4 intron and facilitate its self-splicing activity.

The formation of respiratory chain complexes in mitochondria is under the proteolytic control of the m-AAA protease

Yta10p (Afg3p) and Yta12p (Rcal1p), members of the conserved AAA family of ATPases, are subunits of the mitochondrial m-AAA protease, an inner membrane ATP-dependent metallopeptidase. Deletion of YTA10 or YTA12 impairs degradation of non-assembled inner membrane proteins and assembly of respiratory chain complexes. Mutations of the proteolytic sites in either YTA10 or YTA12 have been shown to inhibit proteolysis of membrane-integrated polypeptides but not the respiratory competence of the cells, suggesting additional activities of Yta10p and Yta12p. Here we demonstrate essential proteolytic functions of the m-AAA protease in the biogenesis of the respiratory chain. Cells harbouring proteolytically inactive forms of both Yta10p and Yta12p are respiratory deficient and exhibit a pleiotropic phenotype similar to Deltayta10 and Deltayta12 cells. They show deficiencies in expression of the intron-containing mitochondrial genes COX1 and COB. Splicing of COX1 and COB transcripts is impaired in mitochondria lacking m-AAA protease, whilst transcription and translation can proceed in the absence of Yta10p or Yta12p. The function of the m-AAA protease appears to be confined to introns encoding mRNA maturases. Our results reveal an overlapping substrate specificity of the subunits of the m-AAA protease and explain the impaired assembly of respiratory chain complexes by defects in expression of intron-containing genes in mitochondria lacking m-AAA protease.

The ATP-dependent PIM1 protease is required for the expression of intron-containing genes in mitochondria

The ATP-dependent PIM1 protease, a Lon-like protease localized in the mitochondrial matrix, is required for mitochondrial genome integrity in yeast. Cells lacking PIM1 accumulate lesions in the mitochondrial DNA (mtDNA) and therefore lose respiratory competence. The identification of a multicopy suppressor, which stabilizes mtDNA in the absence of PIM1, enabled us to characterize novel functions of PIM1 protease during mitochondrial biogenesis. The synthesis of mitochondrially encoded cytochrome c oxidase subunit I (CoxI) and cytochrome b (Cob) is impaired in pim1 mutants containing mtDNA. PIM1-mediated proteolysis is required for the translation of mature COXI mRNA. Moreover, deficiencies in the splicing of COXI and COB transcripts, which appear to be restricted to introns encoding mRNA maturases, were observed in cells lacking the PIM1 gene. Transcripts of COXI and COB genes harboring multiple introns are degraded in the absence of PIM1. These results establish multiple, essential functions of the ATP-dependent PIM1 protease during mitochondrial gene expression.

Mobile group II introns of yeast mitochondrial DNA are novel site-specific retroelements

Group II introns aI1 and aI2 of the yeast mitochondrial COXI gene are mobile elements that encode an intron-specific reverse transcriptase (RT) activity. We show here that the introns of Saccharomyces cerevisiae ID41-6/161 insert site specifically into intronless alleles. The mobility is accompanied by efficient, but highly asymmetric, coconversion of nearby flanking exon sequences. Analysis of mutants shows that the aI2 protein is required for the mobility of both aI1 and aI2. Efficient mobility is dependent on both the RT activity of the aI2-encoded protein and a separate function, a putative DNA endonuclease, that is associated with the Zn2+ finger-like region of the intron reading frame. Surprisingly, there appear to be two mobility modes: the major one involves cDNAs reverse transcribed from unspliced precursor RNA; the minor one, observed in two mutants lacking detectable RT activity, appears to involve DNA level recombination. A cis-dominant splicing-defective mutant of aI2 continues to synthesize cDNAs containing the introns but is completely defective in both mobility modes, indicating that the splicing or the structure of the intron is required. Our results demonstrate that the yeast group II intron aI2 is a retroelement that uses novel mobility mechanisms.

The mitochondrial genome of Schizosaccharomyces pombe. Stimulation of intra-chromosomal recombination in Escherichia coli by the gene product of the first cox1 intron

The open reading frame of the first intron of the mitochondrial cox1 gene (cox1I1) was expressed in Escherichia coli. The putative intron-encoded protein stimulated the formation of intra-chromosomal lac(+)-recombinants about threefold. No stimulation was found when the reading frame was inserted in the opposite direction, or when it was interrupted by a deletion. The intronic open reading frame did not complement recA- or recB- mutants of E. coli. In S. pombe, elimination of this intron did not abolish homologous recombination in mitochondria. A possible role of the recombinase activity in yeast mitochondria will be discussed.

The yeast mitochondrial leucyl-tRNA synthetase is a splicing factor for the excision of several group I introns

The Saccharomyces cerevisiae nuclear gene NAM2 codes for mitochondrial leucyl-tRNA synthetase (mLRS). Herbert et al. (1988, EMBO J 7:473-483) proposed that this protein is involved in mitochondrial RNA splicing. Here we present the construction and analyses of nine mutations obtained by creating two-codon insertions within the NAM2 gene. Three of these prevent respiration while maintaining the mitochondrial genome. These three mutants: (1) display in vitro a mLRS activity ranging from 0%-50% that of the wild type: (2) allow in vivo the synthesis of several mitochondrially encoded proteins; (3) prevent the synthesis of the COXII protein but not of its mRNA; (4) abolish the splicing of the group I introns bI4 and aI4; and (5) affect significantly the excision of the group I introns bI2, bI3 and aI3. Importation of the bI4 maturase from the cytoplasm into mitochondria in a nam2- mutant strain does not restore the excision of the introns bI4 and aI4 implying that the splicing deficiency does not result from the absence of the bI4 maturase. We conclude that the mLRS is a splicing factor essential for the excision of the group I introns bI4 and aI4 and probably important for the excision of other group I introns.

Novel hybrid maturases in unstable pseudorevertants of maturaseless mutants of yeast mitochondrial DNA

Unstable pseudorevertants of mitochondrial mutants of Saccharomyces cerevisiae lacking the maturase function encoded by the fourth intron of the cytochrome b gene (bI4) were isolated. They were found to be heteroplasmic cells owing their regained ability to respire (and grow on glycerol medium) to the presence of a rearranged (rho-) mtDNA that contains an in-frame fusion of the reading frames of the group I introns bI4 and intron 4 alpha of the coxl gene encoding subunit I of cytochrome c oxidase (aI4 alpha). The products of those gene fusions suppress the bI4 maturase deficiency still present in those heteroplasmic cells. Similar heteroplasmic pseudorevertants of a group II maturaseless mutant of the first intron of the coxI gene were characterized; they result from partial deletion of the coxI gene that fuses the reading frames of introns 1 and 2. These heteroplasms provide independent support for the existence of RNA maturases encoded by group I and group II introns. Also, since the petite/mit- heteroplasms arise spontaneously at very high frequencies they provide a system that can be used to obtain mutants unable to form or maintain heteroplasmic cells.

Synthesis and function of the mitochondrial intron--encoded bI4 RNA maturase from Saccharomyces cerevisiae. Effects of upstream frame-shift mutations

We have analyzed the expression and function of the intron-encoded bI4 maturase when frame-shift mutations in the upstream exon alter the translational process. By constructing secondary cis-acting mutations within the bI4 intron, we observed (1) that the bI4 maturase is still translated in the presence of the upstream mutation, albeit in very low amounts, and (2) that the limited amounts of bI4 maturase made under these conditions is no longer able to promote the splicing process of the aI4 intron. These observations, which further strengthen the maturase model, strongly suggest that bI4 maturase acts sequentially on the bI4 intron and then on the aI4 intron.

Mutational analysis of the yeast coenzyme QH2-cytochrome c reductase complex

The synthesis of cytochrome b in yeast depends on the expression of both mitochondrial and nuclear gene products that act at the level of processing of the pre-mRNA, translation of the mRNA, and maturation of the apoprotein during its assembly with the nuclear-encoded subunits of coenzyme QH2-cytochrome c reductase. Previous studies indicated one of the nuclear genes (CBP2) to code for a protein that is needed for the excision of the terminal intervening sequence from the pre-mRNA. We show here that the intervening sequence can promote its own excision in the presence of high concentrations of magnesium ion (50 mM), but that at physiological concentrations of the divalent cation (5 mM), the splicing reaction requires the presence of the CBP2-encoded product. These results provide strong evidence for a direct participation of the protein in splicing, most likely in stabilizing a splicing competent structure in the RNA. The conversion of apocytochrome b to the functional cytochrome has been examined in mutants lacking one or multiple structural subunits of the coenzyme QH2-cytochrome c reductase complex. Based on the phenotypes of the different mutants studied, the following have been concluded. (i) The assembly of catalytically active enzyme requires the synthesis of all except the 17 kDa subunit. (ii) Membrane insertion of the individual subunits is not contingent on protein-protein interactions. (iii) Assembly of the subunits occurs in the lipid bilayer following their insertion. (iv) The attachment of haem to apocytochrome b is a late event in assembly after an intermediate complex of the structural subunits has been formed. This complex minimally is composed of apocytochrome b, the non haem iron protein and all the non-catalytic subunits except for the 17 kDa core 3 subunit.

Molecular basis of the 'box effect', A maturase deficiency leading to the absence of splicing of two introns located in two split genes of yeast mitochondrial DNA

In the mitochondrial DNA of Saccharomyces cerevisiae, the genes cob-box and oxi3, coding for apocytochrome b and cytochrome oxidase subunit I respectively, are split. Several mutations located in the introns of the cob-box gene prevent the synthesis of cytochrome b and cytochrome oxidase subunit I (this is known as the 'box effect').-We have elucidated the molecular basis of this phenomenon: these mutants are unable to excise the fourth intron of oxi3 from the cytochrome oxidase subunit I pre-mRNA; the absence of a functional bI4 mRNA maturase, a trans-acting factor encoded by the fourth intron of the cob-box gene explains this phenomenon. This maturase was already known to control the excision of the bI4 intron; consequently we have demonstrated that it is necessary for the processing of two introns located in two different genes. Mutations altering this maturase can be corrected, but only partially, by extragenic suppressors located in the mitochondrial (mim2) or in the nuclear (NAM2) genome. The gene product of these two suppressors should, therefore, control (directly or indirectly) the excision of the two introns as the bI4 mRNA maturase normally does.

Mitochondrial translation products during release from glucose repression in Saccharomyces cerevisiae

Mitochondrial protein synthesis was studied during release from glucose repression in Saccharomyces cerevisiae cells bearing different mitochondrial genomes. The increase in the rate of the synthesis of mitochondrial translation products was analyzed during respiratory induction. Different kinetic patterns were found for strains having a different structure of mitochondrial mosaic genes, even when the nuclear background was the same. A very limited response of the synthesis of the var1 ribosomal protein to inducing conditions was observed.

The cytochrome oxidase subunit I split gene in Saccharomyces cerevisiae: genetic and physical studies of the mtDNA segment encompassing the 'cytochrome b-homologous' intron

We have constructed a refined genetic and physical map of 38 oxi3 mutations. With the help of the rho- clones derived from 'short' and 'long' genes, pairwise crosses between mutants, estimations of their reversion frequencies and analyses of mitochondrially synthesized proteins, we have characterized and localized several mutants in the exon A4 and in the intron aI4. We present genetic and physical evidence that in the 'long' gene the exon A5 is split into at least three quite distinct exons, A5-1, A5-2 and A5-3 where numerous mutations are localized. We suggest that a novel 56 Kd polypeptide, which accumulates in some cis-dominant oxi3- mutants results from the translation of the upstream exons and the downstream aI4 intron.

Internal structure of a mitochondrial intron of Aspergillus nidulans

The intron of the mitochondrial apocytochrome b gene, cobA, of Aspergillus nidulans has been subjected to sequence analysis. It contains an open reading frame of 957 base pairs contiguous with the preceding exon. Regions of the translated open reading frames of cobA and the third intron of the cob gene in yeast show high amino acid homology. Comparison of the cobA intron with this and other yeast introns indicates that cobA codes for a maturase protein that splices out the intron encoding it and possibly other mitochondrial introns. Two very similar decamer peptides are found in the protein sequences of the cobA intron, four mitochondrial yeast introns, and the yeast mitochondrial sequence reading frame 1 (RF-1) and may be diagnostic of one class of maturase-coding introns. Four short DNA sequences, two of which are in the region defined by box9 and box2 mutations in the cob gene of yeast, are conserved in cobA and certain yeast introns. Comparison with three yeast introns strongly suggests that the first 200 base pairs of the open reading frame of the cobA intron do not code for any amino acids present in the putative maturase protein but are required for splicing or the control of splicing, or both.

Single base substitution in an intron of oxidase gene compensates splicing defects of the cytochrome b gene

An extragenic suppressor mutation, mim2-1, which compensates yeast mitochondrial mutants deficient in splicing of the cytochrome b gene, has been mapped and sequenced. The mutation is due to a single G leads to A transition in the long open reading frame of the fourth intron of the oxidase subunit one gene. It causes the replacement of a glutamic codon by a lysine codon and the expression of a novel mRNA maturase active in splicing. Evolution and regulatory connections between homologous introns of nonhomologous genes are discussed.

Long range control circuits within mitochondria and between nucleus and mitochondria. II. Genetic and biochemical analyses of suppressors which selectively alleviate the mitochondrial intron mutations

In the preceding paper of this series (Dujardin et al. 1980 a) we described general methods of selecting and genetically characterizing suppressor mutations that restore the respiratory capacity of mit- mitochondrial mutations. Two dominant nuclear (NAM1-1 and NAM2-1) and one mitochondrial (mim2-1) suppressors are more extensively studied in this paper. We have analysed the action spectrum of these suppressors on 433 mit- mutations located in various mitochondrial genes and found that they preferentially alleviate the effects of mutations located within intron open reading frames of the cob-box gene. We conclude that these suppressors permit the maturation of cytochrome b mRNA by restoring the synthesis of intron encoded protein(s) catalytically involved in splicing i.e. mRNA-maturase(s) (cf. Lazowska et al. 1980). NAM1-1 is allele specific and gene non-specific; it suppresses mutations located within different introns. NAM2-1 and mim2-1 are intron-specific: they suppress mutations all located in the same (box7) intron of the cob-box gene. Analyses of cytochrome absorption spectra and mitochondrial translation products of cells in which the suppressors are associated with various other mit- mutations show that the suppressors restore cytochrome b and/or cytochrome oxidase (cox I) synthesis, as expected from their growth phenotype. This suppression is, however, only partial: some new polypeptides characteristic of the mit- mutations can be still detected in the presence of suppressor. Interestingly enough when box7 specific suppressors NAM2-1 and mim2-1 are associated with a complete cob-box deletion (leading to a total deficiency of cytochrome b and oxidase) partial restoration of cox I synthesis is observed while cytochrome b is still totally absent. These results show that in strains carrying NAM2-1 or mim2-1 the presence of cytochrome b gene is no longer required for the expression of the oxi3 gene pointing out to the possibility of a mutational switch-on of silent genes, whether mitochondrial, mim2-1, or nuclear, NAM2-1. This switch-on would permit the synthesis of an active maturase acting as a substitute for the box7 maturase in order to splice the cytochrome b and oxidase mRNAs.

Mitochondrial genes at Cold Spring Harbor

The flowering dogwood trees and green lawns of Cold Spring Harbor provided the setting for a meeting devoted to Mitochondrial Genes from May 13-17th, 1981. Dedicated to the memory of Boris Ephrussi, who pioneered mitochondrial genetics at a time when the only kinds of genetics were nuclear or unclear, the meeting showed that the study of mtDNA has had impact on many areas of molecular biology including the genetic code and decoding, tRNA function, mechanisms of splicing and molecular evolution. Curiously, as Herschel Roman pointed out in his opening address, Ephrussi took great pains to avoid any mention of mitochondrial DNA in connection with his observations on cytoplasmic inheritance, preferring instead to refer to 'cytoplasmic particles, endowed with genetic continuity' (Ephrussi 1953). This reticence was not shared by participants at the meeting, as the following, brief report will show.