Mitochondrial and nuclear mutations that affect the biogenesis of the mitochondrial ribosomes of yeast. I. Genetics

Mitochondrial and nuclear mitoribosomal suppressors that enable misreading of ochre codons in yeast mitochondria : I. Isolation, localization and allelism of suppressors

A systematic search for suppressors of mutations which cause a deficiency in the splicing of mitochondrial RNA has been undertaken. These splicing mutations were localized in the mRNA-maturase coding sequence of the second intron of the cob-boxgene, i.e. in the box3locus. A total of 953 revertants (mostly spontaneous in origin) were isolated and their genetic nature (nuclear vs. mitochondrial) and phenotype characterized.Most revertants were mitochondrially determined and displayed a wild-type phenotype. A mitochondrial suppressor unlinked with the box3 (-)target mutation was uncovered among the revertants displaying a pseudo-wild phenotype: out of 26 revertants analyzed, derived from 7 different box3(-) mutants only one such suppressor mutation mim3-1 was found. It was localized by rho(-) deletion mapping in the region between the oxi2 and oxi3 gene, within (or in the vicinity) the gene specifying the 15S ribosomal RNA.Nuclear suppressors were isolated from seven different box3 (-)mutants. All were recessive and had a pseudo-wild phenotype. Three such suppressors nam3-1, nam3-2 and nam3-3 were investigated more extensively. Tetrad analysis has shown that they are alleles of the same nuclear locus NAM3 and mitotic analysis has shown that they do not segregate mitotically.

Novel DNA mismatch-repair activity involving YB-1 in human mitochondria

Maintenance of the mitochondrial genome (mtDNA) is essential for proper cellular function. The accumulation of damage and mutations in the mtDNA leads to diseases, cancer, and aging. Mammalian mitochondria have proficient base excision repair, but the existence of other DNA repair pathways is still unclear. Deficiencies in DNA mismatch repair (MMR), which corrects base mismatches and small loops, are associated with DNA microsatellite instability, accumulation of mutations, and cancer. MMR proteins have been identified in yeast and coral mitochondria; however, MMR proteins and function have not yet been detected in human mitochondria. Here we show that human mitochondria have a robust mismatch-repair activity, which is distinct from nuclear MMR. Key nuclear MMR factors were not detected in mitochondria, and similar mismatch-binding activity was observed in mitochondrial extracts from cells lacking MSH2, suggesting distinctive pathways for nuclear and mitochondrial MMR. We identified the repair factor YB-1 as a key candidate for a mitochondrial mismatch-binding protein. This protein localizes to mitochondria in human cells, and contributes significantly to the mismatch-binding and mismatch-repair activity detected in HeLa mitochondrial extracts, which are significantly decreased when the intracellular levels of YB-1 are diminished. Moreover, YB-1 depletion in cells increases mitochondrial DNA mutagenesis. Our results show that human mitochondria contain a functional MMR repair pathway in which YB-1 participates, likely in the mismatch-binding and recognition steps.

Identification of nuclear genes which participate to mitochondrial translation in Saccharomyces cerevisiae

The mitochondrial protein synthesis presents specific features and uses specific components different from their cytoplasmic counterparts. Since most genes which code for these components are localized in the chromosomes and only a small number are encoded by the mitochondrial DNA, it is important to identify and characterize the nuclear genes involved in this process. In order to do this, we have used a genetic screening which implies the selection and study of nuclear suppressors of mitochondrial mutations (or the reverse situation) which affect the mitochondrial protein synthesis. Three mutations have been used for this purpose. Two of them (ts 1398, cs 909) impair the mitochondrial ribosome; they were used to characterize new interacting components as well as two genes, MBR1 and MBR2, which control the assembly or the regulation of other genes involved in mitochondrial protein synthesis. The third mutation (ts 932), blocks the 3'-end maturation of the mitochondrial aspartyl tRNA. A nuclear suppressor has been obtained which presents all the characteristics of a mutation in the gene encoding the enzyme responsible for this process.

A single nucleotide substitution at the rib2 locus of the yeast mitochondrial gene for 21S rRNA confers resistance to erythromycin and cold-sensitive ribosome assembly

We have studied a mutation (cs23) in the mitochondrial gene for 21S rRNA that affects the peptidyl transferase center of the ribosome and conditionally blocks the assembly of the 54S ribosomal subunit. Strains carrying this mutation are resistant to erythromycin and cold-sensitive for growth on nonfermentable carbon sources (Singh et al. 1978) Mitochondria isolated from mutant cells grown on glucose at 20 degrees C, the nonpermissive temperature, were depleted of the 54S subunit and instead contained a novel 45S ribosomal particle. After mutant cells were shifted from 20 degrees C to 32 degrees C, 54S subunits were assembled, apparently from the 45S particles and pre-existing ribosomal proteins. DNA sequencing revealed that the mutant phenotype is a consequence of a C to A transversion at position 3993 of the 21S rRNA gene. Previously, C to U and C to G mutations have been identified at the same position in the 21S rRNA sequence. This position corresponds to C-2611 in the E. coli 23S RNA, a nucleotide that appears to be conserved in the large rRNA of all erythromycin-sensitive ribosomes.

Substitution of an invariant nucleotide at the base of the highly conserved '530-loop' of 15S rRNA causes suppression of yeast mitochondrial ochre mutations

We have determined the nucleotide sequence alteration in the 15S rRNA gene of a Saccharomyces cerevisiae strain carrying the previously described mitochondrial ochre suppressor, MSUI. The suppressor contains an A residue at position 633 of the yeast mitochondrial sequence, in place of the wild-type G. This position, located in the highly conserved region forming the stem of the '530-loop', corresponds to G517 of the Escherichia coli 16S rRNA and is occupied by G in all other known small rRNA sequences. This finding strongly supports the previous conclusions of others that the 530-loop region plays an important role in enhancing translational accuracy.

Mutational study of the rRNA in yeast mitochondria: functional importance of T1696 in the large rRNA gene

Four intragenic suppressors of a mitochondrial mutation in the 21S rRNA gene have been characterized in S. cerevisiae. The determination of the nature of the nucleotide changes in the suppressor strains showed that a T at position 1696 in the large rRNA gene is essential for correct function of the mitoribosome. The importance of this specific nucleotide and the fact that this mitochondrial mutation can also be suppressed by a mutation in a nuclear gene are in good agreement with a rRNA-r protein interaction in this part of domain IV, which functional importance is demonstrated in vivo by our results.

Nuclear and mitochondrial revertants of a yeast mitochondrial tRNA mutant

We isolated revertants capable of respiration from the respiratory deficient yeast mutant, FF1210-6C/170, which displays greatly decreased mitochondrial protein synthesis due to a single base substitution at the penultimate base of the tRNAAsp gene on mitochondrial (mt) DNA. Three classical types of revertant were identified: (1) same-site revertants; (2) intragenic revertants which restore the base pairing in the acceptor stem of the mitochondrial tRNAAsp; and (3) extragenic suppressors located in nuclear DNA. In addition a fourth type of revertant was identified in which the mutant tRNAAsp is amplified due to the maintenance of both the original mutant mtDNA and a modified form of the mutant mtDNA in which only a small region around the tRNAAsp gene is retained and amplified. The latter form resembles the mtDNA in vegetative petite (rho-) strains which normally segregates rapidly from the wild-type mtDNA. Each revertant type was characterized genetically and by both DNA sequence analysis of the mitochondrial tRNAAsp gene and analysis of the quantity and size of RNA containing the tRNAAsp sequence. These results indicate that the mitochondrial tRNAAsp of the mutant retains a low level of activity and that the presence of the terminal base pair in tRNAAsp is a determinant of both tRNAAsp function and the maintenance of wild-type levels of tRNAAsp.

In vivo and in vitro evidence for a proton leakage through the inner mitochondrial membrane in a mutant of Saccharomyces cerevisiae

Mutants of Saccharomyces cerevisiae were isolated which supported three mutations: two unlinked chromosomic mutations conferring thermosensitivity and cold sensitivity respectively, and a mitochondrial mutation conferring paromomycin sensitivity. When studied on isolated mitochondria, these mutants exhibited low phosphorylation efficiency and great proton permeability of their inner mitochondrial membrane. Experiments were carried out on whole cells: determination of growth rates, cellular yields and cellular respiration, either in the presence of triethyltin, an ATP synthase inhibitor, or in the presence of uncoupler, demonstrating that the proton leakage is actually a physiological phenomenon linked to the cold-sensitive phenotype. Experiments performed on isolated mitochondria confirmed the existence of such a proton leakage.

A poliovirus temperature-sensitive RNA synthesis mutant located in a noncoding region of the genome

We have constructed an 8-base-pair insertion mutation in the 3' noncoding region of an infectious poliovirus cDNA clone that gives rise to a temperature-sensitive RNA synthesis mutant upon transfection into mammalian cells. The mutated cDNA was used to establish a cell line that releases the mutant poliovirus in a temperature-dependent fashion, representing a unique persistent viral infection. A poliovirus mutant mapping in the noncapsid region of the viral genome can be complemented in this cell line, implying that the cell line expresses viral proteins at the nonpermissive temperature.

A mitochondrial ribosomal RNA mutation and its nuclear suppressors

We have isolated cold-resistant revertants from a mitochondrial cold-sensitive mutation, cs909, localized in the 21S ribosomal RNA gene. Two types of revertants have been isolated: (1) strong revertants which were shown to be due to a single, nuclear, dominant suppressor; (2) weak revertants which are all due to the presence of a single, nuclear, recessive suppressor. The recessive suppressor, when separated from the mitochondrial mutation, itself confers a cold-sensitive phenotype, that is, there is a mutual suppression between the mitochondrial cold-sensitive mutation and the nuclear cold-sensitive mutation. The suppressor by itself produces modified ribosomes and therefore probably codes for an element of the mitochondrial ribosome such as a ribosomal protein.

Mitochondrial ribosomal RNA genes of yeast: their mutations and a common nuclear suppressor

Due to the absence of repetition of the rRNA genes in S. cerevisiae mitochondria, isolation of ribosomal mutants at the level of the rRNA genes is relatively easy in this system. We describe here a novel thermosensitive mutation, ts1297, localized by rho- deletion mapping in (or very close to) the sequence corresponding to the small ribosomal RNA (15S) gene. Defective mutations of the small rRNA have not been reported so far. In the mutant, the amount of 15S rRNA and of the small ribosomal subunit, 37S, is reduced. The quantity of the large ribosomal RNA (21S), directly extracted from mitochondria, appears normal. However, the large ribosomal subunit, 50S, seems to be fragile and could be recovered only in the presence of Ca2+ in place of Mg2+. The 50S particles seem to be completely degraded under normal conditions of extraction with Mg2+. The thermosensitive phenotype of the ts1297 mutant is suppressed by a nuclear mutation SU101. The SU101 mutation had been originally isolated as a suppressor of another mitochondrial mutation, ts902, which is located within the 21S rRNA gene. These results suggest that the mitochondrial mutations ts1297 and ts902 are both involved in the interaction of the large and small ribosomal subunits.

Genetics of mitochondrial ribosomes of yeast: mitochondrial lethality of a double mutant carrying two mutations of the 21S ribosomal RNA gene

Among the mitochondrial conditional mutations localized in the gene coding for the 21S ribosomal RNA, one--ts 902--produces severely reduced amounts of 21S RNA and 50S subunit. We investigated its physiological properties and found that this thermosensitive mutation was associated with highly pleiotropic effects. The mutant phenotype is associated with cell death in certain conditions, and with a massive accumulation of rho- mutants at non-permissive temperature. Furthermore, interactions with the sites of action of erythromycin and chloramphenicol, both localized within the 21S rRNA, were detected. The mutant is hypersensitive to erythromycin and has a cis-incompatibility with the chloramphenicol-resistant mutation CR321. Ts 902 thus appears to have a dual effect, not only at the ribosomal level but also at a cellular level.

Identification of two erythromycin resistance mutations in the mitochondrial gene coding for the large ribosomal RNA in yeast

Two independent erythromycin resistance mutations, ER514 and ER221, have been identified in the mitochondrial gene coding for the 21S ribosomal RNA. The two mutations were found to be identical, corresponding to a A to G transition at the nucleotide position 1951 of the ribosomal RNA gene. In the secondary structure model of the ribosomal RNA, the ER resistance site is found at the proximity of the chloramphenicol resistance sites located about 500 bases downstream.

Nature of an inserted sequence in the mitochondrial gene coding for the 15S ribosomal RNA of yeast

The small ribosomal RNA, or 15S RNA, or yeast mitochondria is coded by a mitochondrial gene. In the central part of the gene, there is a guanine-cytosine (GC) rich sequence of 40 base-pairs, flanked by adenine-thymine sequences. The GC-rich sequence is (5') TAGTTCCGGGGCCCGGCCACGGAGCCGAACCCGAAAGGAG (3'). We have found that this sequence is absent in the 15S rRNA gene of some strains of yeast. When present, it is transcribed into the mature 15S rRNA to produce a longer variant of the RNA. Sequences identical or closely related to this GC-rich sequence are present in many regions of the mitochondrial genome of Saccharomyces cerevisiae. The 5' and 3' terminal structures of all these sequences are highly constant.

Genetic interactions in the control of mitochondrial function in Paramecium. II. Interactions between nuclear and mitochondrial genomes

In an attempt to understand the genetic interactions between nuclear and mitochondrial genomes leading to mitochondrial biogenesis, different combinations of known nuclear and mitochondrial mutations have been constructed by microinjection. Eleven different tetrazolium resistant mutant strains, many clearly affecting mitochondrial function, were injected with mitochondria from four different erythromycin resistant mitochondrial mutants. Cases were found in which mutant mitochondria were unable to replicate in tetrazolium resistant mutants. The successful mitochondrial transfers were characterized for growth rate, temperature and cold sensitivity. Several selected combinations were characterised also for cytochrome spectra and cyanide resistance. Many different phenotypes were produced by the interaction of the different nuclear and mitochondrial mutations. These ranged from a positive interaction in which mutant mitochondria were selected by a nuclear mutant in preference to wild-type, through apparent absence of interaction, to negative interaction in which the mitochondrial-nuclear combination was temperature sensitive even though both 'parents' were thermoresistant. The possible molecular basis of these interactions is discussed.

Mitochondrial and nuclear mutations that affect the biogenesis of the mitochondrial ribosomes of yeast. II. Biochemistry

1. Several nuclear mutants have been isolated which showed thermo- or cryo-sensitive growth on non-fermentable media. Although the original strain carried mitochondrial drug resistance mutations (CR, ER, OR and PR), the resistance to one or several drugs was suppressed in these mutants. Two of them showed a much reduced amount of the mitochondrial small ribosomal subunit (37S) and of the corresponding 16S ribosomal RNA. Two dimensional electrophoretic analysis did not reveal any change in the position of any of the mitochondrial ribosomal proteins. However one of the mitochondrial ribosomal proteins. However one of the mutants showed a striking decrease in the amounts of three ribosomal proteins S3, S4 and S15. 2. Four temperature-sensitive mitochondrial mutations have been localized in the region of the gene coding for the large mitochondrial ribosomal RNA (23S). These mutants all showed a marked anomaly in the mitochondrial large ribosomal subunit (50S) and/or the corresponding 23S ribosomal RNA.