Immunologically related proteins in cytoplasmic and mitochondrial ribosomes of yeast Saccharomyces cerevisiae

Summary Ribosomal proteins from the cytoplasm and mitochondria of the yeast Saccharomyces cerevisiae were compared by immunoblotting techniques. Antibodies raised against cytoplasmic ribosomal proteins cross-react with five mitochondrial ribosomal proteins, four of which are located in the large and one in the small mitochondrial subunits. The possible existence of common ribosomal proteins for cytoplasmic and mitochondrial ribosomes is discussed.Abbreviations cyto cytoplasmic - mito mitochondrial     

Altered mitochondrial ribosomes in a cold-sensitive mutant of Saccharomyces cerevisiae

A mutation at a new locus denotedtsr1 which lies very close to theery1 locus and 21S rRNA gene in mitochondrial DNA ofSaccharomyces cerevisiae, confers conditional respiratory deficiency on cells grown at low temperature, namely 18°. Studies on mitochondria isolated from a strain carrying the mutatedtsr1 locus demonstrate that the rate of mitochondrial protein synthesis is cold-sensitive at 18°. The large subunit of the mitochondrial ribosomes isolated from the mutant strain is unstable during extraction and the isolated ribosomes are shown to be defective in catalyzing the poly U-directed synthesis of polyphenylalanine. It is concluded that thetsr1 locus is involved in the determination of the properties of the large subunit of the mitochondrial ribosome.     

Nucleo-cytoplasmic interactions in the petite negative yeast Schizosaccharomyces pombe

Summary In the petite positive yeast, Saccharomyces cerevisiae, cycloheximide selectively inhibits protein synthesis on cytoplasmic ribosomes, and, as a consequence, nuclear DNA synthesis. Mitochondrial DNA, however, is synthesized for 4–6 h after cessation of protein synthesis. In this paper we show that in contrast to Saccharomyces cerevisiae, synthesis of mitochondrial and nuclear DNA is tightly coordinated in the petite negative yeast Schizosaccharomyces pombe, since inhibition of cytoplasmic protein synthesis leads immediately to cessation of both nuclear and mitochondrial DNA synthesis.Dedicated to Prof. Dr. F. Kaudewitz on occasion of his 60th birthday     

A cold-sensitive cytoplasmic mutation of Saccharomyces cerevisiae affecting assembly of the mitochondrial 50S ribosomal subunit.

Summary A cytoplasmic mutant of Saccharomyces cerevisiae (E23-1) has been isolated that is resistant to erythromycin and cold sensitive for growth on nonfermentable carbon sources at 18°. Genetic analysis has shown that both of these properties probably result from a single mutation at the rib2 locus which maps close to or within the gene for the 21S rRNA of the mitochondrial 50S ribosomal subunit. Electrophoresis of total RNA extracted from purified mitochondria demonstrated that the 21S and 14S rRNA species from both mutant and wild-type cells were present in roughly equimolar quantities regardless of growth temperature. The mutant is therefore not defective in the synthesis of the 21S rRNA. Sucrose gradient analysis of the mitochondrial ribosomes in Mg²⁺-containing buffers revealed that approximate values for the ratio of 50S to 37S subunits were 1:1 for wild-type cells grown at either 18° or 32°, 0.5:1 for the mutant grown at 32° and 0.2:1 for the mutant grown at 18°. The subunit ratios were approximately 1:1 when Ca²⁺-containing buffers were used, however, In alls cases, 50S particles from the mutant grown at 18° lacked or contained markedly reduced amounts of two distinctive protein components that were present in the mutant at 32° and in the wild-type at both temperatures. In addition, no intact 21S RNA could be recovered from the mitochondrial ribosomes of the mutant grown at the restrictive temperature, even in the presence of Ca²⁺. These findings indicate that mitochondrial 50S ribosomal subunits produced by the mutant at 18° are structurally defective and raise the possibility that the defect results from an alteration in the gene for 21S rRNA.A preliminary report of this work was presented at the meeting on The Molecular Biology of Yeast, Cold Spring Harbor Laboratory, August 18–22, 1977     

Comparison of amino acid compositions of mitochondrial and cytoplasmic ribosomal proteins of Saccharomyces cerevisiae.

Summary The amino-acid compositions of the mitochondrial ribosomal subunits of Saccharomyces cerevisiae have been determined and compared to those of cytoplasmic ribosomal subunits. For the large subunits, the mitochondrial and cytoplasmic ribosomes showed major differences in the proportions of arginine, alanine and methionine. For the small subunits, arginine, aspartic acid, alanine, valine and methionine showed marked differences.We have compared these amino-acid compositions with those already published of bacterial and eukaryotic ribosomes by a statistical method of data analysis. It appeared clearly that the yeast mitoribosomes are more distant from bacterial ribosomes than from eukaryotic cytoribosomes.Abbreviations r-proteins ribosomal proteins     

Ribosomal recessive suppressors cause a respiratory deficiency in yeast Saccharomyces cerevisiae

Summary Recessive suppressor mutations in yeast Saccharomyces cerevisiae alter a component of the cytoplasmic ribosomes, relaxing the control of translational fidelity. As a consequence ribosomes can misread nonsense codons as amino acids (Surguchov et al. 1980a).The suppressor mutants are often respiratory deficient, being unable to grow on non-fermentable substrates. The study of the cytochrome spectra has revealed that the cytochrome b and aa₃ contents were lower in the mutants than in the parent strains. Furthermore, the suppresor mutations often cause hypersensitivity to paromomycin and neomycin on media with a non-fermentable source of carbon. Some of the suppressor mutants exhibited both erythromycin and chloramphenicol-dependent growth on media containing ethanol or glycerol as a sole carbon source.These results suggest that the mutations altering cytoplasmic ribosomes may simultaneously impair the mitochondrial translation. A coupling of cytoplasmic and mitochondrial protein synthesis in yeast cells is proposed. The existence of a common protein component participating both in mitochondrial and cytoplasmic protein synthesis apparatus is discussed.     

The Mode of Action of Pederin,a Drug Inhibiting Protein Synthesis in Eucaryotic Organisms

Abstract

Pederin, a toxic substance isolated from the insect Paederus fuscipes, inhibits growth of Saccharomyces cerevisiae and EUE cells but not of Bacillus subtilis. Protein synthesis in vitro appears to be inhibited by the drug in preparations obtained from organisms containing 80 S ribosomes (yeast, EUE cells and rat liver) but not in those from organisms endowed with 70 S ribosomes (E. coli and B. subtilis). Pederin inhibits protein synthesis at a stage subsequent to the formation of the ternary complex between ribosomes, aminoacyl-tRNA and messenger RNA. Resistance or susceptibility to the drug appears to be a characteristic of ribosomes.     

Mitochondrial and cytoplasmic ribosomes. Distinguishing characteristics and a requirement for the homologous ribosomal saltextractable fraction for protein synthesis

1. Mitochondrial and cytoplasmic ribosomes of Euglena gracilis differ in their total RNA and protein content. 2. Mitochondrial ribosomes dissociate to subunits at higher Mg(2+) concentrations than do cytoplasmic ribosomes. 3. A separable 5S RNA is obtained from cytoplasmic and chloroplast ribosomes, but not from mitochondrial ribosomes. 4. For protein-synthesizing activity with a natural mRNA, mitochondrial ribosomes use tRNA from any cell compartment and are partly active with supernatant enzymes from cytoplasm. Cytoplasmic ribosomes are partly active with enzymes and tRNA from mitochondria or chloroplasts. 5. Both mitochondrial and cytoplasmic ribosomes show high specificity for the homologous salt-extractable ribosomal fraction for protein-synthesizing activity.     

Evidence for a functional association of DNA synthesis with the membrane in mitochondria of Saccharomyces cerevisiae

We have studied the effect of membrane fatty acid composition on replicative DNA synthetic activity in mitochondria isolated from Saccharomyces cerevisiae. Cells containing different levels of membrane unsaturated fatty acids were obtained by growth of a fatty acid desaturase mutant of Saccharomyces cerevisiae in glucose-limited chemostat cultures supplemented with various concentrations of Tween 80. Arrhenius plots of DNA synthetic activity in isolated mitochondria show a discrete discontinuity at specific temperature which are dependent on the membrane unsaturated fatty acid content of the mitochondria. This indicates a functional association of DNA replication with the mitochondrial membrane in Saccharomyces cerevisiae.     

MEMBRANOUS STRUCTURES IN YEASTS

1. Most yeast cells carrying out active respiration have spherical or ellipsoidal mitochondria, with plate-like cristae. 2. Cytoplasmic petite strains of Saccharomyces cerevisiae have aberrant mitochondria, often containing whorled membranes. Mutants with deficiencies in the tricarboxylic acid cycle have mitochondria which appear normal when the cells are grown in low levels of glucose. 3. Cells of normal and petite S. cerevisiae grown strictly anaerobically show no recognizable mitochondrial profiles. 4. Carbon substrates which can only be respired promote the development of well-defined mitochondria. In certain facultatively anaerobic yeasts respiration is suppressed by glucose and the mitochondria under these conditions are large, pleomorphic and few in number. Other fermentable carbohydrates do not give this repression. 5. A number of antibacterial antibiotics, which inhibit mitochondrial protein synthesis, cause a disorganization of the mitochondrial cristae. 6. In yeast cells adapting from anaerobic to aerobic conditions mitochondria appear to develop from proliferations of the endoplasmic reticulum, which become progressively more organized. 7. Vacuoles often contain granular material, but in S. cerevisiae the vacuole, which has been described as a lysosome, frequently contains myelin-like lipid inclusions. The material in these inclusions is apparently derived from spherosomes. 8. Endoplasmic reticulum, orientated parallel to the plasmalemma, may be associated with fermentative ability in certain facultatively anaerobic yeasts. Endoplasmic reticulum is also actively involved in the budding process. 9. Normally the yeast-cell plasmalemma shows only minor convolutions, but in chloramphenicol-grown Rhodotorula glutinis the plasmalemma produces vesicular structures termed ‘paramural bodies’. 10. The yeast nuclear membrane has about 200 pores occupying 6–8 % of the total surface area. The nuclear membrane remains intact during mitotic division in yeasts until the daughter nuclei separate.     

The morphological site of synthesis of cytochrome c in mammalian cells (Krebs cells)

In Krebs ascites-tumour cells, cytochrome c is segregated in the mitochondria and the level in microsomes could not be measured. At 22° in glucose–buffer Krebs cells synthesized a spectrum of proteins including cytochrome c. Mild osmotic shock in the presence of ribonuclease had little effect on incorporation of [¹⁴C]-leucine or [¹⁴C]valine into mixed mitochondrial protein but strongly inhibited synthesis of non-mitochondrial cytoplasmic proteins. Under these conditions, labelling of cytochrome c was also strongly inhibited. After pulse labelling of Krebs cells at 22° for 10min. the cytcchrome radioactivity found in mitochondria was higher than in microsomes. After addition of unlabelled amino acid as `chase' there was 137% increase in radioactivity of cytochrome c but only a 3% increase in radioactivity of whole-cell protein. It is concluded that the peptide chain of cytochome c is synthesized on cytoplasmic ribosomes. Mitochondria therefore do not have the character of self-replicating entities, but are formed by the cooperative function of messenger RNA of cytoplasmic ribosomes and, possibly, of intramitochondrial messenger derived from the mitochondrial DNA.     

Higher-plant mitochondrial ribosomes contain a 5S ribosomal ribonucleic acid component.

Ribosomes from higher-plant mitochondria contain 5S rRNA, in contrast with the mitochondrial ribosomes of animals and fungi, in which such a component has not been detected. In common with the ribosomes of prokaryotes and chloroplasts, higher-plant mitochondrial ribosomes do not appear to contain an RNA equivalent to the 5.8 S rRNA that is found in eukaryoytes hydrogen-bonded to the largest of the cytoplasmic rRNA species.     

Selective transfer of fungal cytoplasmic genetic elements by protoplast fusion

An anucleate small-protoplast fraction was prepared from a respiratory-competentSaccharomyces cerevisiae strain carrying mitochondrially inherited resistance to erythromycin, and used to transfer mitochondria selectively. Polyethylene glycol and Ca²⁺ were applied to induce fusion between these small protoplasts and nucleus-containing protoplasts of a respiratory-deficient ρ° mutant derived from an adenine-requiring strain of the same species. The majority of fusion products were haploid and erythromycin resistant, containing the nucleus of the recipient adenine-requiring strain and the mitochondrial genome from the respiratory-competent donor cells. Selective transfer of mitochondria and other cytoplasmic genetic elements also seems possible in a wide variety of fungal and other cells.     

Glucose repression and autolysis ofSaccharomyces cerevisiae cells: alterations in the cytochemical localization of acid phosphatase

Summary Allerations in the localization of acid phosphatase inSaccharomyces cerevisiae during glucose repression and during autolysis have been studied. Cell morphology becomes distinctly changed after only 2 h in the presence of high glucose concentration while after 3 h of glucose repression the majority of the mitochondirial structures resemble promitochondria. Yeast cells repressed for 6 h contain almost completely degraded mitochondrial structures and numerous lipid droplets in the central vacuole and cytoplasm. Destruction of mitochondria is accompanied by the accumulation of acid phosphatase in these organelles and in the cytoplasm whereas its activity in the central vacuole is lowered, most probably because of the leakage of the enzyme into the cytoplasm.No preferential breakdown of mitochondria is observed during autolysis. On the contrary, mitochondria are apparently the last to be degraded. Digestion of cytoplasmic regions and membranous elements occurs intravacuolarly after sequestration by protrusions of the central vacuole which are formed at the initial stages of autolysis. Acid phosphatase is not released from the central vacuole, suggesting indirectly that vacuole enzymes do not migrate into the cytoplasm during autolysis.     

Ionophores and intact cells II. Oleficin acts on mitochondria and induces disintegration of the mitochondrial genome in yeast Saccharomyces cerevisiae

The non-macrolid polyene antibiotic oleficin, which has been shown to function as an ionophore of Mg²⁺ in isolated rat liver mitochondria, preferentially inhibited growth of the yeast Saccharomyces cerevisiae on non-fermentable substrates. It uncoupled and inhibited respiration of intact cells and converted both growing and resting cells into respiration-deficient mutants. The mutants arose as a result of fragmentation of the mitochondrial genome. Another antibiotic known to be an ionophore of divalent cations, A23187, also selectively inhibited growth of the yeast on non-fermentable substrates, but did not produce the respiration-deficient mutants, neither antibiotic inhibited the energy-dependent uptake of divalent cations by yeast cells nor opened the plasma membrane for these cations. The results indicate that in Saccharomyces cerevisiae both oleficin and A23187 preferentially affected the mitochondrial membrane without acting as ionophores in the plasma membrane.     

Mitochondrial–nuclear co‐evolution leads to hybrid incompatibility through pentatricopeptide repeat proteins

Mitochondrial–nuclear incompatibility has a major role in reproductive isolation between species. However, the underlying mechanism and driving force of mitochondrial–nuclear incompatibility remain elusive. Here, we report a pentatricopeptide repeat‐containing (PPR) protein, Ccm1, and its interacting partner, 15S rRNA, to be involved in hybrid incompatibility between two yeast species, Saccharomyces cerevisiae and Saccharomyces bayanus. S. bayanus‐Ccm1 has reduced binding affinity for S. cerevisiae‐15S rRNA, leading to respiratory defects in hybrid cells. This incompatibility can be rescued by single mutations on several individual PPR motifs, demonstrating the highly evolvable nature of PPR proteins. When we examined other PPR proteins in the closely related Saccharomyces sensu stricto yeasts, about two‐thirds of them showed detectable incompatibility. Our results suggest that fast co‐evolution between flexible PPR proteins and their mitochondrial RNA substrates may be a common driving force in the development of mitochondrial–nuclear hybrid incompatibility.     

Identification of the Saccharomyces cerevisiae RNA:pseudouridine synthase responsible for formation of psi(2819) in 21S mitochondrial ribosomal RNA

So far, four RNA:pseudouridine (Ψ)-synthases have been identified in yeast Saccharomyces cerevisiae. Together, they act on cytoplasmic and mitochondrial tRNAs, U2 snRNA and rRNAs from cytoplasmic ribosomes. However, RNA:Ψ-synthases responsible for several U→Ψ conversions in tRNAs and UsnRNAs remained to be identified. Based on conserved amino-acid motifs in already characterised RNA:Ψ-synthases, four additional open reading frames (ORFs) encoding putative RNA:Ψ-synthases were identified in S.cerevisiae. Upon disruption of one of them, the YLR165c ORF, we found that the unique Ψ residue normally present in the fully matured mitochondrial rRNAs (Ψ₂₈₁₉ in 21S rRNA) was missing, while Ψ residues at all the tested pseudouridylation sites in cytoplasmic and mitochondrial tRNAs and in nuclear UsnRNAs were retained. The selective U→Ψ conversion at position 2819 in mitochondrial 21S rRNA was restored when the deleted yeast strain was transformed by a plasmid expressing the wild-type YLR165c ORF. Complementation was lost after point mutation (D71→A) in the postulated active site of the YLR165c-encoded protein, indicating the direct role of the YLR165c protein in Ψ₂₈₁₉ synthesis in mitochondrial 21S rRNA. Hence, for nomenclature homogeneity the YLR165c ORF was renamed PUS5 and the corresponding RNA:Ψ-synthase Pus5p. As already noticed for other mitochondrial RNA modification enzymes, no canonical mitochondrial targeting signal was identified in Pus5p. Our results also show that Ψ₂₈₁₉ in mitochondrial 21S rRNA is not essential for cell viability.     

pet 18: A chromosomal gene required for cell growth and for the maintenance of mitochondrial DNA and the killer plasmid of yeast

Summary Mutations in the pet18 gene of Saccharomyces cerevisiae (formerly denoted pets) confer three phenotypes on mutant strains: (i) inability to respire (petite), (ii) inability to maintain the double-stranded RNA killer plasmid (sensitive), and (iii) temperature sensitivity for growth. We find that pet18 mutants lack mitochondrial DNA. However, despite their inability to maintain the killer RNA plasmid and mitochondrial DNA, pet18 mutants still can carry the other yeast plasmids, [URE3-1], [PSI], and 2-micron DNA. The temperature sensitivity of the pet18 mutants is not expressed as a selective defect in total DNA, RNA, or protein synthesis.