A maturase-like subunit of the sequence-specific endonuclease endo.SceI from yeast mitochondria

Gut microbial diversity is associated with lower arterial stiffness in women

Aims

The gut microbiome influences metabolic syndrome (MetS) and inflammation and is therapeutically modifiable. Arterial stiffness is poorly correlated with most traditional risk factors. Our aim was to examine whether gut microbial composition is associated with arterial stiffness.

Methods and results

We assessed the correlation between carotid-femoral pulse wave velocity (PWV), a measure of arterial stiffness, and gut microbiome composition in 617 middle-aged women from the TwinsUK cohort with concurrent serum metabolomics data. Pulse wave velocity was negatively correlated with gut microbiome alpha diversity (Shannon index, Beta(SE)= -0.25(0.07), P = 1 × 10-4) after adjustment for covariates. We identified seven operational taxonomic units associated with PWV after adjusting for covariates and multiple testing-two belonging to the Ruminococcaceae family. Associations between microbe abundances, microbe diversity, and PWV remained significant after adjustment for levels of gut-derived metabolites (indolepropionate, trimethylamine oxide, and phenylacetylglutamine). We linearly combined the PWV-associated gut microbiome-derived variables and found that microbiome factors explained 8.3% (95% confidence interval 4.3-12.4%) of the variance in PWV. A formal mediation analysis revealed that only a small proportion (5.51%) of the total effect of the gut microbiome on PWV was mediated by insulin resistance and visceral fat, c-reactive protein, and cardiovascular risk factors after adjusting for age, body mass index, and mean arterial pressure.

Conclusions

Gut microbiome diversity is inversely associated with arterial stiffness in women. The effect of gut microbiome composition on PWV is only minimally mediated by MetS. This first human observation linking the gut microbiome to arterial stiffness suggests that targeting the microbiome may be a way to treat arterial ageing.

Assembly of F1F0-ATP synthases

F1F0-ATP synthases are multimeric protein complexes and common prerequisites for their correct assembly are (i) provision of subunits in appropriate relative amounts, (ii) coordination of membrane insertion and (iii) avoidance of assembly intermediates that uncouple the proton gradient or wastefully hydrolyse ATP. Accessory factors facilitate these goals and assembly occurs in a modular fashion. Subcomplexes common to bacteria and mitochondria, but in part still elusive in chloroplasts, include a soluble F1 intermediate, a membrane-intrinsic, oligomeric c-ring, and a membrane-embedded subcomplex composed of stator subunits and subunit a. The final assembly step is thought to involve association of the preformed F1-c10-14 with the ab2 module (or the ab8-stator module in mitochondria)--mediated by binding of subunit δ in bacteria or OSCP in mitochondria, respectively. Despite the common evolutionary origin of F1F0-ATP synthases, the set of auxiliary factors required for their assembly in bacteria, mitochondria and chloroplasts shows clear signs of evolutionary divergence. This article is part of a Special Issue entitled: Chloroplast Biogenesis.

Characterization of Gtf1p, the connector subunit of yeast mitochondrial tRNA-dependent amidotransferase

The bacterial GatCAB operon for tRNA-dependent amidotransferase (AdT) catalyzes the transamidation of mischarged glutamyl-tRNA(Gln) to glutaminyl-tRNA(Gln). Here we describe the phenotype of temperature-sensitive (ts) mutants of GTF1, a gene proposed to code for subunit F of mitochondrial AdT in Saccharomyces cerevisiae. The ts gtf1 mutants accumulate an electrophoretic variant of the mitochondrially encoded Cox2p subunit of cytochrome oxidase and an unstable form of the Atp8p subunit of the F(1)-F(0) ATP synthase that is degraded, thereby preventing assembly of the F(0) sector. Allotopic expression of recoded ATP8 and COX2 did not significantly improve growth of gtf1 mutants on respiratory substrates. However, ts gft1 mutants are partially rescued by overexpression of PET112 and HER2 that code for the yeast homologues of the catalytic subunits of bacterial AdT. Additionally, B66, a her2 point mutant has a phenotype similar to that of gtf1 mutants. These results provide genetic support for the essentiality, in vivo, of the GatF subunit of the heterotrimeric AdT that catalyzes formation of glutaminyl-tRNA(Gln) (Frechin, M., Senger, B., Brayé, M., Kern, D., Martin, R. P., and Becker, H. D. (2009) Genes Dev. 23, 1119-1130).

Maintenance and expression of the S. cerevisiae mitochondrial genome--from genetics to evolution and systems biology

As a legacy of their endosymbiotic eubacterial origin, mitochondria possess a residual genome, encoding only a few proteins and dependent on a variety of factors encoded by the nuclear genome for its maintenance and expression. As a facultative anaerobe with well understood genetics and molecular biology, Saccharomyces cerevisiae is the model system of choice for studying nucleo-mitochondrial genetic interactions. Maintenance of the mitochondrial genome is controlled by a set of nuclear-coded factors forming intricately interconnected circuits responsible for replication, recombination, repair and transmission to buds. Expression of the yeast mitochondrial genome is regulated mostly at the post-transcriptional level, and involves many general and gene-specific factors regulating splicing, RNA processing and stability and translation. A very interesting aspect of the yeast mitochondrial system is the relationship between genome maintenance and gene expression. Deletions of genes involved in many different aspects of mitochondrial gene expression, notably translation, result in an irreversible loss of functional mtDNA. The mitochondrial genetic system viewed from the systems biology perspective is therefore very fragile and lacks robustness compared to the remaining systems of the cell. This lack of robustness could be a legacy of the reductive evolution of the mitochondrial genome, but explanations involving selective advantages of increased evolvability have also been postulated.

F1-dependent translation of mitochondrially encoded Atp6p and Atp8p subunits of yeast ATP synthase

The ATP synthase of yeast mitochondria is composed of 17 different subunit polypeptides. We have screened a panel of ATP synthase mutants for impaired expression of Atp6p, Atp8p, and Atp9p, the only mitochondrially encoded subunits of ATP synthase. Our results show that translation of Atp6p and Atp8p is activated by F(1) ATPase (or assembly intermediates thereof). Mutants lacking the alpha or beta subunits of F(1), or the Atp11p and Atp12p chaperones that promote F(1) assembly, have normal levels of the bicistronic ATP8/ATP6 mRNAs but fail to synthesize Atp6p and Atp8p. F(1) mutants are also unable to express ARG8(m) when this normally nuclear gene is substituted for ATP6 or ATP8 in mitochondrial DNA. Translational activation by F(1) is also supported by the ability of ATP22, an Atp6p-specific translation factor, to restore Atp6p and to a lesser degree Atp8p synthesis in the absence of F(1). These results establish a mechanism by which expression of ATP6 and ATP8 is translationally regulated by F(1) to achieve a balanced output of two compartmentally separated sets of ATP synthase genes.

Assembly of F0 in Saccharomyces cerevisiae

Respiratory deficient mutants of Saccharomyces cerevisiae have been instrumental in identifying an increasing number of nuclear gene products that promote pre- and post-translational steps of the pathway responsible for biogenesis of the mitochondrial ATP synthase. In this article we have attempted to marshal current information about the functions of such accessory factors and the roles they play in expression and assembly of the mitochondrially encoded subunits of the ATP synthase. We also discuss evidence that the ATP synthase may be built up from three separate modules corresponding to the F1 ATPase, the stator and F0.

Yeast cells lacking the mitochondrial gene encoding the ATP synthase subunit 6 exhibit a selective loss of complex IV and unusual mitochondrial morphology

Atp6p is an essential subunit of the ATP synthase proton translocating domain, which is encoded by the mitochondrial DNA (mtDNA) in yeast. We have replaced the coding sequence of Atp6p gene with the non-respiratory genetic marker ARG8m. Due to the presence of ARG8m, accumulation of rho-/rho0 petites issued from large deletions in mtDNA could be restricted to 20-30% by growing the atp6 mutant in media lacking arginine. This moderate mtDNA instability created favorable conditions to investigate the consequences of a specific lack in Atp6p. Interestingly, in addition to the expected loss of ATP synthase activity, the cytochrome c oxidase respiratory enzyme steady-state level was found to be extremely low (<5%) in the atp6 mutant. We show that the cytochrome c oxidase-poor accumulation was caused by a failure in the synthesis of one of its mtDNA-encoded subunits, Cox1p, indicating that, in yeast mitochondria, Cox1p synthesis is a key target for cytochrome c oxidase abundance regulation in relation to the ATP synthase activity. We provide direct evidence showing that in the absence of Atp6p the remaining subunits of the ATP synthase can still assemble. Mitochondrial cristae were detected in the atp6 mutant, showing that neither Atp6p nor the ATP synthase activity is critical for their formation. However, the atp6 mutant exhibited unusual mitochondrial structure and distribution anomalies, presumably caused by a strong delay in inner membrane fusion.

The Saccharomyces cerevisiae ATP22 gene codes for the mitochondrial ATPase subunit 6-specific translation factor

Mutations in the Saccharomyces cerevisiae ATP22 gene were previously shown to block assembly of the F0 component of the mitochondrial proton-translocating ATPase. Further inquiries into the function of Atp22p have revealed that it is essential for translation of subunit 6 of the mitochondrial ATPase. The mutant phenotype can be partially rescued by the presence in the same cell of wild-type mitochondrial DNA and a rho- deletion genome in which the 5'-UTR, first exon, and first intron of COX1 are fused to the fourth codon of ATP6. The COX1/ATP6 gene is transcribed and processed to the mature mRNA by splicing of the COX1 intron from the precursor. The hybrid protein translated from the novel mRNA is proteolytically cleaved at the normal site between residues 10 and 11 of the subunit 6 precursor, causing the release of the polypeptide encoded by the COX1 exon. The ability of the rho- suppressor genome to express subunit 6 in an atp22 null mutant constitutes strong evidence that translation of subunit 6 depends on the interaction of Atp22p with the 5'-UTR of the ATP6 mRNA.

Aep3p stabilizes the mitochondrial bicistronic mRNA encoding subunits 6 and 8 of the H+-translocating ATP synthase of Saccharomyces cerevisiae

Subunits 6 and 8 of the mitochondrial ATPase in Saccharomyces cerevisiae are encoded by the mitochondrial genome and translated from bicistronic mRNAs containing both reading frames. The stability of the two major species of ATP8/6 mRNA, which differ in the length of the 5'-untranslated region, depends on the expression of several nuclear-encoded factors. In the present study, the product of the gene designated AEP3 (open reading frame YPL005W) is shown to be required for stabilization and/or processing of both ATP8/6 mRNA species. In an aep3-disruptant strain, the shorter ATP8/6 mRNA was undetectable, and the level of the longer mRNA was reduced to approximately 35% that of wild type. Localization of a hemagglutinin-tagged version of Aep3p showed that the protein is an extrinsic constituent of the mitochondrial inner membrane facing the matrix.

Association of HSP70 with endonucleases allows the expression of otherwise silent mutations

A subpopulation of the 70 kDa heat shock protein (HSP70) found within the mitochondria of Saccharomyces cerevisiae functions as a stable binding partner of the endonuclease SceI. We have previously found that the SceI endonuclease monomer recognizes and cleaves a unique, 26 bp sequence in vitro. Dimerization with HSP70 changes the specificity of SceI, allowing it to cleave at multiple sequences. This study shows that SuvI, an ortholog of SceI isolated from a different yeast strain, contains two amino acid substitutions, yet it shows the same uni-site specificity in its monomeric form. Binding of HSP70 to the SuvI monomer confers multi-site specificity that is different from that exhibited by the HSP70/SceI heterodimer. Mutation of single residues of SceI to the corresponding residue in SuvI provides enzymes with specificities intermediate between SceI and SuvI when complexed with HSP70. These results suggest that HSP70 interaction with certain endonucleases allows the expression of otherwise silent mutations in them, causing a change in enzyme cleavage specificity.

Cellular copper homeostasis, mitochondrial DNA instabilities, and lifespan control in the filamentous fungus Podospora anserina

In the fungal aging model Podospora anserina, lifespan is controlled by mitochondrial and nuclear genetic traits. Different nuclear genes are known to affect the integrity of the mitochondrial DNA (mtDNA). One gene of this type is Grisea encoding a copper-modulated transcription factor involved in the control of cellular copper homeostasis. The characterization of a long-lived mutant with a loss-of-function mutation in this gene revealed that the last step in the pathway, homologous recombination, leading to the characteristic age-related mtDNA reorganizations is copper-dependent. In growing parts of the culture, the stabilization of the mtDNA has an important impact on the biogenesis of functional mitochondria, on their capacity to remodel damaged respiratory chains and on longevity.

Stable association of 70-kDa heat shock protein induces latent multisite specificity of a unisite-specific endonuclease in yeast mitochondria

The multisite-specific endonuclease Endo.SceI of yeast mitochondria is unique among endonucleases because its 50-kDa subunit forms a stable dimer with the mitochondrial 70-kDa heat shock protein (mtHSP70), which otherwise fulfills a chaperone function by binding transiently to unfolded proteins. Here we show that the mtHSP70 subunit confers broader sequence specificity, greater stability, and higher activity on the 50-kDa subunit. The 50-kDa subunit alone displayed weaker activity and highly sequence-specific endonuclease activity. The 50-kDa protein exists as a heterodimer with mtHSP70 in vivo, allowing Endo.SceI to cleave specifically at multiple sites on mitochondrial DNA. Endo.SceI may have evolved from a highly specific endonuclease that gained broader sequence specificity after becoming a stable partner of mtHSP70.

The complete sequence of the mitochondrial genome of Saccharomyces cerevisiae

The currently available yeast mitochondrial DNA (mtDNA) sequence is incomplete, contains many errors and is derived from several polymorphic strains. Here, we report that the mtDNA sequence of the strain used for nuclear genome sequencing assembles into a circular map of 85,779 bp which includes 10 kb of new sequence. We give a list of seven small hypothetical open reading frames (ORFs). Hot spots of point mutations are found in exons near the insertion sites of optional mobile group I intron-related sequences. Our data suggest that shuffling of mobile elements plays an important role in the remodelling of the yeast mitochondrial genome.

Structure and activity of the mitochondrial intron-encoded endonuclease, I-SceIV

Starting with crude yeast mitochondria, the intron homing endonuclease, I-SecIV, was purified to near homogeneity. This highly purified enzyme differs from some other well-characterized yeast mitochondrial intron-encoded endonucleases in terms of its structure and DNA cleavage specificity. The enzyme is a heterodimer with a native molecular mass of 92 kDa. A small catalytic subunit (32 kDa) is probably encoded largely or entirely by intron 5 alpha of the cytochrome oxidase subunit I gene. A larger polypeptide subunit (60 kDa) may be a nuclear factor necessary for intron mobility. I-SceIV exhibits a low DNA sequence specificity as it cleaves a variety of DNA substrates. Analysis of kinetic parameters shows that the purified enzyme has a very high affinity for DNA and exhibits low turnover which may have implications for subsequent steps in the intron homing process.

Ho endonuclease cleaves MAT DNA in vitro by an inefficient stoichiometric reaction mechanism

Mating type switching in Saccharomyces cerevisiae initiates when Ho endonuclease makes a double-stranded DNA break at the yeast MAT locus. In this report, we characterize the fundamental biochemical properties of Ho. Using an assay that monitors cleavage of a MAT plasmid, we define an optimal in vitro reaction, showing in particular that the enzyme has a stringent requirement for zinc ions. This suggests that zinc finger motifs present in Ho are important for cleavage. The most unexpected feature of Ho, however, is its extreme inefficiency. Maximal cleavage occurs when Ho is present at a concentration of 1 molecule/3 base pairs of substrate DNA. Even under these conditions, complete digestion requires >2 h. This inefficiency results from two characteristics of Ho. First, Ho recycles slowly from cleaved product to new substrate, in part because the enzyme has an affinity for one end of its double strand break product. Second, high levels of cleavage in the in vitro reaction correlate with the appearance of large protein-DNA aggregates. At optimal Ho concentrations, these latter aggregates, referred to as "florettes," have an ordered structure consisting of a densely staining central region and loops of radiating DNA. These unusual properties may indicate that Ho plays a role in other aspects of mating type switching subsequent to double strand break formation.

Endo.SK1: an inducible site-specific endonuclease from yeast mitochondria

Site-specific endonucleases have been found in various eukaryotic organelles such as mitochondria, chloroplasts and nuclei. These endonucleases initiate site-specific or homologous gene conversion in mitochondrial and nuclear DNA. Here, we report a new site-specific endonuclease activity, Endo.SK1, identified in mitochondria of strain SK1, a homothallic diploid strain of Saccharomyces cerevisiae. Nucleotide sequences around the Endo.SK1-cleavage sites are different from those of known yeast site-specific endonucleases. The Endo.SK1 activity is, at least partly, specified by a gene in the SK1-derived mitochondria. A novel feature of the Endo.SK1 activity is its inducibility: the endonuclease activity was induced by ca. 40-fold by transfer of cells from a glucose medium into an acetate medium, and was then repressed. This transient induction was independent of the ploidy level of the cells, and coincided with induction of fumarase, a mitochondrial enzyme involved in the TCA cycle. Co-induction and co-repression of the mitochondrial site-specific endonuclease activity and a respiration-related enzyme indicate that the endonuclease activity in regulated in response to physiological conditions, and suggest a possible role for the endonuclease in mitochondrial DNA metabolism.

The mobile group I intron 3 alpha of the yeast mitochondrial COXI gene encodes a 35-kDa processed protein that is an endonuclease but not a maturase

Three mitochondrial mutants were characterized that block the splicing of aI3 alpha, a mobile group I intron of the COXI gene of yeast mtDNA. Mutant C1085 alters helical structures known to be important for splicing of group I introns. M44 and C1072 are point mutants in exon 3 that block correct splicing but allow some splicing at cryptic 5'-splice sites. M44 alters the P1 helix needed for 5'-splice site definition, while the mutation in C1072 is a new kind of mutation because it is located upstream of the exon sequence involved in the P1 helix. All three mutants accumulate novel proteins of 35 and 44 kDa (p35 and p44, respectively) detected both by labeling of mitochondrial translation products and by Western blotting. Partial protease digestions indicate that p44 and p35 are closely related, probably as precursor and processed protein. The level of the intron-encoded endonuclease activity, I-SceIII, is elevated approximately 10-fold in the mutants. Partial purification of I-SceIII from the mutants showed that most, if not all, of the activity is associated with p35. Finally, because aI3 alpha splices accurately in a petite mutant, we conclude that aI3 alpha splicing does not depend on a mtDNA-encoded maturase.

Nucleo-mitochondrial interactions in mitochondrial gene expression

All proteins encoded by mitochondrial DNA (mtDNA) are dependent on proteins encoded by nuclear genes for their synthesis and function. Recent developments in the identification of these genes and the elucidation of the roles their products play at various stages of mitochondrial gene expression are covered in this review, which focuses mainly on work with the yeast Saccharomyces cerevisiae. The high degree of evolutionary conservation of many cellular processes between this yeast and higher eukaryotes, the ease with which mitochondrial biogenesis can be manipulated both genetically and physiologically, and the fact that it will be the first organism for which a complete genomic sequence will be available within the next 2 to 3 years makes it the organism of choice for drawing up an inventory of all nuclear genes involved in mitochondrial biogenesis and for the identification of their counterparts in other organisms.

Genes of the linear mitochondrial DNA of Williopsis mrakii: coding sequences for a maturase-like protein, a ribosomal protein VAR1 homologue, cytochrome oxidase subunit 2 and methionyl tRNA

The mitochondrial DNA (mtDNA) in some yeasts has a linear structure with inverted terminal repeats closed by a single-stranded loop. These mtDNAs have generally a constant gene order, beginning with a small ribosomal RNA gene at the right end and terminating with a cytochrome oxidase subunit 2 gene (COX2) at the left end, independently of the wide variation in genome size. In the mtDNAs from several species of the genus Williopsis, we found an additional open reading frame, ORF1, which was homologous to the Saccharomyces cerevisiae RF1 gene encoding a group I intron maturase-like protein. ORF1 genes from W. mrakii and W. suaveolens were mapped and sequenced. Next to ORF1, COX2 and methionyl tRNA genes were present on the opposite strand. The same relative positions of genes in the mtDNAs so far examined suggests that the constancy of gene order is generally conserved also at the level of individual tRNA genes. We identified another open reading frame, ORF2, in W. mrakii mtDNA. It was mapped next to the cytochrome oxidase subunit 3 gene. Rich in adenine-thymine bases, ORF2 appears to be a homologue of the VAR1 gene which codes for a small ribosomal subunit protein in S. cerevisiae mitochondria. Nucleotide sequences data have been deposited in the EmBL data library under the following Accession Numbers: X66594 (Apocytochrome b and ORF2 genes of W. mrakii), X66595 (ORF1, tRNA-Met and COX2 genes of W. mrakii), X73415 (tRNA-Met and COX2 genes of W. suaveolens), X73416 (ORF1 gene of W. suaveolens) and X73414 (tRNA-Met and COX2 genes of P. jadinii).

Formation of the 3' end of yeast mitochondrial mRNAs occurs by site-specific cleavage two bases downstream of a conserved dodecamer sequence

Mitochondrial mRNAs in yeast arise by processing of polygenic primary transcripts at a conserved dodecamer sequence (5'-AAUAAPyAUUCUU-3'). Previous results indicated that processing at dodecamer sites interrupted the sequence implying that it functioned primarily as a signal for 3' end formation of mRNAs. We have determined the precise cleavage site for RNAs processed at the dodecamer sequences associated with the oli1 gene and the omega intron of the 21S rRNA gene. In both cases cleavage occurred two bases downstream of the site. Hydrolysis left the PO4 group attached to the 3' terminus of the cleavage products. These results demonstrate for the first time that mature mitochondrial mRNAs terminate with an intact dodecamer sequence. In light of the recent identification of a protein complex within mitochondria that binds to RNAs terminating with an intact dodecamer sequence, these results support the idea that the dodecamer sequence functions not only within pre-mRNAs as a processing site, but within mature mRNAs as well, possibly for the stabilization and/or translation.

The NAM1/MTF2 nuclear gene product is selectively required for the stability and/or processing of mitochondrial transcripts of the atp6 and of the mosaic, cox1 and cytb genes in Saccharomyces cerevisiae

The NAM1/MTF2 gene was firstly isolated as a multicopy suppressor of mitochondrial splicing deficiencies and independently as a gene of which a thermosensitive allele affects mitochondrial transcription in organello. To determine which step in mitochondrial RNA metabolism is controlled in vivo by the NAM1 gene, mitochondrial transcripts of seven transcription units from strains carrying an inactive nam1::URA3 gene disruption in various mitochondrial genetic backgrounds were analysed by Northern blot hybridisations. In a strain carrying an intron-containing mitochondrial genome, the inactivation of the NAM1 gene led to a strong decrease in (or total absence of) the mosaic cytb and cox1 mRNAs and in transcripts of the atp6-rf3/ens2 genes, which are co-transcribed with cox1. Neither the accumulation of unspliced cytb or cox1 pre-mRNAs, nor that of excised circular intron molecules of ai1 or ai2 were observed, but the abundance of the bi1 and ai7 lariats was comparable to that observed in the wild-type strain, thus demonstrating that transcription of the cytb and cox1 genes does occur. In strains carrying the intron-less mitochondrial genome with or without the rf3/ens2 sequence, wild-type amounts of cytb and cox1 mRNAs were detected while the amount of the atp6 mRNA was always strongly decreased. The abundance of transcripts from five other genes was either slightly (21S rRNA) or not at all (cox2, cox3, atp9 and 15S rRNA) affected by the nam1 inactivation.(ABSTRACT TRUNCATED AT 250 WORDS)

The single group-I intron in the chloroplast rrnL gene of Chlamydomonas humicola encodes a site-specific DNA endonuclease (I-ChuI)

The single group-I intron (ChLSU.1) in the chloroplast (cp) large subunit rRNA-encoding gene (rrnL) of the green alga Chlamydomonas humicola is located at a position at which no introns have previously been characterized in other systems. In the present study, the nucleotide (nt) sequence of this 1118-bp intron was found to contain an internal open reading frame (ORF) that potentially encodes a basic protein of 218 amino acid residues. The putative C. humicola protein features two copies of the LAGLI-DADG motif and is part of the family of intron-encoded proteins comprising the endonucleases (ENases), I-SceI, I-SceIV and I-CsmI. Expression of the ChLSU.1 intron ORF in vitro in the presence of a 260-bp DNA fragment containing the exon 1-2 junction of an intronless version of the C. humicola rrnL resulted in specific cleavage of the DNA fragment very close to the intron insertion site. This novel intron-encoded ENase, designated I-ChuI, was also shown to generate a staggered cut with 4-nt (CTCG) 3'-OH overhangs 2 bp downstream from the intron insertion site.

A sequence-specific endonuclease, Endo.SceI, can efficiently induce gene conversion in yeast mitochondria lacking a major exonuclease

Endo.SceI most likely initiates homologous recombination of yeast mitochondrial genome through sequence-specific double-strand scission of DNA. According to the double-strand break-repair model for the mechanism of homologous recombination, DNA ends created by sequence-specific endonucleases have to be processed by exonucleases. The major mitochondrial exonuclease (encoded by NUC1) has been shown to greatly affect the length of conversion tracts at the 21S rRNA locus when site-specific gene conversion is induced by omega endonuclease. In order to examine the role of the NUC1 nuclease in the Endo.SceI-induced recombination, recombination frequencies were measured after crossing of parental strains either in the presence or absence of NUC1 nuclease activity. The frequency of gene conversion in the oli2 locus induced by Endo.SceI was not reduced by disruption of the NUC1 gene. This result strongly implicates the presence of multiple exonucleases for the processing of the DNA ends created by sequence-specific endonucleases.

Genetic approaches to the study of mitochondrial biogenesis in yeast

In contrast to most other organisms, the yeast Saccharomyces cerevisiae can survive without functional mitochondria. This ability has been exploited in genetic approaches to the study of mitochondrial biogenesis. In the last two decades, mitochondrial genetics have made major contributions to the identification of genes on the mitochondrial genome, the mapping of these genes and the establishment of structure-function relationships in the products they encode. In parallel, more than 200 complementation groups, corresponding to as many nuclear genes necessary for mitochondrial function or biogenesis have been described. Many of the latter are required for post-transcriptional events in mitochondrial gene expression, including the processing of mitochondrial pre-RNAs, the translation of mitochondrial mRNAs, or the assembly of mitochondrial translation products into the membrane. The aim of this review is to describe the genetic approaches used to unravel the intricacies of mitochondrial biogenesis and to summarize recent insights gained from their application.

The yeast mitochondrial intron aI5 alpha: associated endonuclease activity and in vivo mobility

By analyzing crosses between yeast strains carrying different combinations of mitochondrial (mt) introns, we have shown that the aI5 alpha intron is mobile in vivo. Furthermore, we have observed that the mobility of intron aI5 alpha is affected by both the nuclear and mt genotypes. We have also detected a restriction endonuclease (ENase) activity that cleaves intronless mt genomes close to the aI5 alpha intron insertion site and thus might be involved in intron mobility. This is further supported by the fact that this ENase activity is only detected in a strain containing the aI5 alpha intron. Furthermore, similar to other ENases encoded by mobile mt introns of yeast, the ENase generates a cut with a four-base 3'-OH overhang. Thus, intron aI5 alpha represents a characteristic member of the family of mobile group-I introns.

The identification of 18 nuclear genes required for the expression of the yeast mitochondrial gene encoding cytochrome c oxidase subunit 1

Eighteen nuclear mutants of the yeast Saccharomyces cerevisae, each disturbed in the biosynthesis of the mitochondrially encoded cytochrome c oxidase subunit 1 (cox1) and each representing a distinct complementation group, have been examined to identify the level at which COX1 expression is affected. RNA blotting revealed that most have a defect in the processing of COX1 precursor-mRNA; only a few are defective in COX1 transcription and/or pre-mRNA stability. In most RNA-processing mutants, the absence of the COX1 messenger results from a defect in the splicing of one or more COX1 introns. In turn, this defect can be ascribed to a mutation in a nuclear gene which is either directly involved in splicing or else acts indirectly by impairing COX1 translation.

Sequence-specific complex formation of DNA and a eukaryotic sequence-specific endonuclease, SceI

Endo.SceI is a eukaryotic sequence-specific endonuclease of 120 kDa that causes sequence-specific double-stranded scission of DNA. Unlike results with restriction enzymes, we found a consensus sequence around the cleavage sites for Endo.SceI instead of a common sequence. We searched for conditions for studying the binding of Endo.SceI to DNA other than cutting. Under optimized conditions including gel mobility shift assay, Endo.SceI exhibited sequence-specific binding to a short double-stranded DNA (41 base pairs) containing a cleavage site and the DNA reisolated from the protein-DNA complex was not cleaved. The analysis of the complex of Endo.SceI and DNA isolated by the gel mobility shift experiments showed that the DNA-binding entity in the Endo.SceI preparation does have Endo.SceI activity and consists of an equal amount of 75-kDa and 50-kDa polypeptides. Based on this observation and those from previous studies, we conclude that Endo.SceI is a heterodimer of the 75-kDa and 50-kDa subunits. Under the present assay conditions, Endo.SceI did not show binding to single-stranded DNA having the same sequence of either plus or minus strand of the double-stranded DNA containing the cleavage site (the 41-bp DNA). Endo.SceI showed significantly higher affinity for the consensus sequence than the major cleavage site in pBR322 DNA. Unlike the cleavage of DNA by Endo.SceI which requires Mg2+, this sequence-specific binding is independent of but stimulated by Mg2+.