Transfer RNA genes in mitochondrial DNA of grande (wild-type) yeast

We have used transfer RNA-DNA hybridization to show that seven tRNAs, i.e. tyrosyl, glutamyl, aspartyl, prolyl, lysyl, histidyl and seryl, hybridize with grande yeast mitochondrial DNA. These tRNA species are in addition to the seven which we previously showed to be gene products of mitochondrial DNA. Escherichia coli aminoacyl-synthetase preparations also were shown to catalyze specific acylation of yeast mitochondrial leucyl and tyrosyl-tRNA, but not of the isoaccepting tRNAs localized in the cell supernatant. Cytoplasmic tRNAs were found to be present in our purified mitochondrial preparations.     

A novel mitochondrial DEAD box protein (Mrh4) required for maintenance of mtDNA in Saccharomyces cerevisiae

In a screen of nuclear genes that assist splicing of mitochondrial localized group II introns in yeast we isolated low-copy number suppressors of splicing and respiratory-deficient point mutants of intron aI5gamma, the last intron of the gene encoding cytochrome c oxidase subunit I. One of the genes found contains the open reading frame (ORF) YGL064c that has previously been proposed to encode a putative RNA helicase of the DEAD box family. Deletion of the ORF gives rise to 100% cytoplasmic petites, indicating that the protein plays an essential role in the mitochondrial RNA metabolism. Overexpression of YGL064c-GFP fusions clearly revealed a mitochondrial localization of the protein. The gene encodes the fourth putative RNA helicase of Saccharomyces cerevisiae implicated in a mitochondrial function and was therefore termed MRH4 (for mitochondrial RNA helicase).     

Phylogeny of the Colubroidea (Serpentes): new evidence from mitochondrial and nuclear genes

The Colubroidea contains over 85% of all the extant species of snakes and is recognized as monophyletic based on morphological and molecular data. Using DNA sequences (cyt b, c-mos) from 100 species we inferred the phylogeny of colubroids with special reference to the largest family, the Colubridae. Tree inference was obtained using Bayesian, likelihood, and parsimony methods. All analyses produced five major groups, the Pareatidae, Viperidae, Homalopsidae, the Elapidae, and the Colubridae. The specific content of the latter two groups has been altered to accommodate evolutionary history and to yield a more stable taxonomy. We propose an updated classification based on the reallocation of species as indicated by our inferred phylogeny.     

The organization of genes in yeast mitochondrial DNA

Summary We have fractionated fragments of yeast mtDNA, obtained with restriction endonucleases, on poly(U)-Sephadex columns using the procedure of Flavell and Van den Berg (FEBS Letters (1975) 58, 90–93). The poly(U) forms a triple helix with (dA·dT) clusters in duplex DNA and fractionates DNA fragments on the basis of the length and number of clusters contained in them.mtDNA fragments obtained with endonucleases PstI, BamHI, HindII, HindII+III, EcoRI, HapII and HhaI were separated by poly(U)-Sephadex in three groups: fragments not retained by the column in 2M LiCl, fragments partially retained and fragments (nearly) completely bound in 2 M LiCl and only eluted by 0.1 M LiCl. The separation obtained is adequate for analytical fractionation of fragments and it can be used for the preparative isolation of firmly-bound fragments.In mtDNA digests made with endonuclease HapII, which gives about 70 separable fragments under our conditions, only about 10% of the fragments were firmly bound to poly(U)-Sephadex. This shows that the number of (dA·dT) clusters long enough to result in binding is limited in yeast mtDNA and its suggests that large fragments are bound by only one or a few clusters.Corresponding segments of the physical map of the mtDNAs from Saccharomyces carlsbergensis and Saccharomyces cerevisiae strains JS1-3D and KL14-4A were bound to the column, showing that the (dA·dT) clusters responsible for binding are conserved in the evolution of mtDNA. However, one 3,000 bp insert, only present on KL14-4A mtDNA, causes the loss of a binding site, another long insert introduces a new binding site.Fragments firmly bound to the columns are clustered in one quadrant of the physical map of these three mtDNAs. This quadrant also contains the large insertions present in KL14-4A mtDNA and absent from S. carlsbergensis mtDNA. The possible relation between (dA·dT) clusters and insertions is discussed.Abbreviation bp base pairs     

Snake phylogeny: evidence from nuclear and mitochondrial genes

We constructed phylogenies of snakes from the c-mos and cytochrome b genes using conventional phylogenetic methods as well as the relatively new method of Bayesian inference. For all methods, there was excellent congruence between the c-mos and cytochrome b genes, implying a high level of support for the shared clades. Our results agree with previous studies in two important respects: first, that the scolecophidians and alethinophidians are monophyletic sister clades; and second, that the Colubroidea is a monophyletic group with the Acrochordidae as its sister clade. However, our results differ from previous studies in the finding that Loxocemus and Xenopeltis cluster with pythons. An additional noteworthy result from our data is that the genera Exiliboa and Ungaliophis, often placed with Tropidophis (and Trachyboa, not included in the present study) in the Tropidophiidae, are in reality boids.     

Distinct nuclear genes for yeast mitochondrial and cytoplasmic methionyl-tRNA synthetases.

Total methionine-tRNA synthetases from wild type $\text{Saccharomyces}\text{cerevisiae}$ can be fractionated on hydroxylapatite into two peaks: Peak I is the mitochondrial, peak II the cytoplasmic isoenzyme. The specificity towards various tRNAs and the antigenic determinants are not identical. A mutant strain, known for its altered cytoplasmic enzyme, contains a mitochondrial species with the same properties as the wild type mitochondrial enzyme, as well as a cytoplasmic isoenzyme with a K_M for methionine about 300 times higher than the corresponding wild type enzyme. Another strain, obtained by back-crossing the mutant with a wild type strain, retains the enzyme pattern found in the mutant. The results are in favor of two distinct nuclear genes for yeast mitochondrial and cytoplasmic methionyl-tRNA synthetases.     

A screen for nigericin-resistant yeast mutants revealed genes controlling mitochondrial volume and mitochondrial cation homeostasis

Little is known about the regulation of ion transport across the inner mitochondrial membrane in Saccharomyces cerevisiae. To approach this problem, we devised a screening procedure for facilitating the identification of proteins involved in mitochondrial ion homeostasis. Taking advantage of the growth inhibition of yeast cells by electroneutral K(+)/H(+) ionophore nigericin, we screened for genetic mutations that would render cells tolerant to this drug when grown on a nonfermentable carbon source and identified several candidate genes including MDM31, MDM32, NDI1, YMR088C (VBA1), CSR2, RSA1, YLR024C, and YNL136W (EAF7). Direct examination of intact cells by electron microscopy indicated that mutants lacking MDM31 and/or MDM32 genes contain dramatically enlarged, spherical mitochondria and that these morphological abnormalities can be alleviated by nigericin. Mitochondria isolated from the Deltamdm31 and Deltamdm32 mutants exhibited limited swelling in an isotonic solution of potassium acetate even in the presence of an exogenous K(+)/H(+) antiport. In addition, growth of the mutants was inhibited on ethanol-containing media in the presence of high concentrations of salts (KCl, NaCl, or MgSO(4)) and their mitochondria exhibited two- (Deltamdm31 and Deltamdm32) to threefold (Deltamdm31Deltamdm32) elevation in magnesium content. Taken together, these data indicate that Mdm31p and Mdm32p control mitochondrial morphology through regulation of mitochondrial cation homeostasis and the maintenance of proper matrix osmolarity.     

Phylogenetic evidence for role-reversals of gender-associated mitochondrial DNA in Mytilus (Bivalvia: Mytilidae)

Distinct gender-associated mitochondrial DNA (mtDNA) lineages (i.e., lineages which are transmitted either through males or through females) have been demonstrated in two families of bivalves, the Mytilidae (marine mussels) and the Unionidae (freshwater mussels), which have been separated for more than 400 Myr. The mode of transmission of these M (for male-transmitted) and F (for female-transmitted) molecules has been referred to as doubly uniparental inheritance (DUI), in contrast to standard maternal inheritance (SMI), which is the norm in animals. A previous study suggested that at least three origins of DUI are required to explain the phylogenetic pattern of M and F lineages in freshwater and marine mussels. Here we present phylogenetic evidence based on partial sequences of the cytochrome c oxidase subunit I gene and the 16S RNA gene that indicates the DUI is a dynamic phenomenon. Specifically, we demonstrate that F lineages in three species of Mytilus mussels, M. edulis, M. trossulus, and M. californianus, have spawned separate lineages which are now associated only with males. This process is referred to as "masculinization" of F mtDNA. By extension, we propose that DUI may be a primitive bivalve character and that periodic masculinization events combined with extinction of previously existing M types effectively reset the time of divergence between conspecific gender-associated mtDNA lineages.      

O(2) uptake in the light in chlamydomonas: evidence for persistent mitochondrial respiration

The nature of the process responsible for the stationary O₂ uptake occurring in the light under saturating CO₂ concentration in Chlamydomonas reinhardii has been investigated. For this purpose, a mass spectrometer with a membrane inlet system was used to measure O₂ uptake and evolution in the algal suspension. First, we observed that the O₂ uptake rate was constant (about 0.5 micromoles of O₂ per milligram chlorophyll per minute) during a light to dark transition and was not affected by 3-(3,4-dichlorophenyl)-1,1-dimethylurea. Salicylhydroxamic acid had no effect on O₂ uptake in the dark or in the light, but was found to have the same inhibitory effect either in the dark or in the light when added to cyanide-treated algae. The stimulation of the O₂ uptake rate due to the uncoupling effect of carbonyl cyanide m-chlorophenylhydrazone was about the same in the dark or in the light. From these results, we conclude that mitochondrial respiration is maintained during illumination and therefore is not inhibited by high ATP levels. Another conclusion is that in conditions where photorespiration is absent, no other light-dependent O₂ uptake process occurs. If Mehler reactions are involved, in Chlamydomonas, under conditions where both photosynthetic carbon oxidation and reduction cycles cannot operate (as in cyanide-treated algae), their occurrence in photosynthesizing algae either under saturating CO₂ concentration or at the CO₂ compensation point appears very unlikely. The comparison with the situation previously reported in Scenedesmus (R. J. Radmer and B. Kok 1976 Plant Physiol 58: 336-340) suggests that different O₂ uptake processes might be present in these two algal species.     

Genome-wide screening of yeast metal homeostasis genes involved in mitochondrial functions

Metal ions are essential for mitochondria to execute their roles. Yeast mutants that are sensitive to metals (either excess or deficiency) on non-fermentable media but not on fermentable media may carry mutations in genes that participate in metal homeostasis involving mitochondrial functions. A collection of approximately 4,800 haploid yeast deletion mutants was screened for metal ion homeostasis genes linked to mitochondrial respiration. In addition to several well-characterized metal homeostasis genes, 45 new mutants, impaired in various molecular functions, were identified on non-fermentable media that were sensitive to adscititious metals or metal deficiency. While 35 of these mutants displayed metal-sensitivity only on non-fermentable media, the remaining 10 also exhibited metal sensitivity on fermentable media, suggesting metal-sensitivity of the latter is not due to mitochondrial dysfunction. Inductively coupled plasma optical emission spectrometry (ICP-OES) was conducted for 12 mutants that were sensitive to metal excess to analyze their metal contents. Among these 12 mutants 7 were sensitive to metal excess on non-fermentable but not on fermentable media. All the seven respiration-dependent mutants displayed abnormal levels of metal ions inside mitochondria, indicative of disrupted mitochondrial metal homeostasis. This study therefore effectively identified multiple new genes involved in metal homeostasis pathways possibly pertinent to mitochondrial functions, and should be helpful for future studies to further understand their molecular roles.     

Temperature-sensitive mutation in yeast mitochondrial ribosome recycling factor (RRF)

The yeast protein Rrf1p encoded by the FIL1 nuclear gene bears significant sequence similarity to Escherichia coli ribosome recycling factor (RRF). Here, we call FIL1 Ribosome Recycling Factor of yeast, RRF1. Its gene product, Rrf1p, was localized in mitochondria. Deletion of RRF1 leads to a respiratory incompetent phenotype and to instability of the mitochondrial genome (conversion to rho^–/rho⁰ cytoplasmic petites). Yeast with intact mitochondria and with deleted genomic RRF1 that harbors a plasmid carrying RRF1 was prepared from spores of heterozygous diploid yeast. Such yeast with a mutated allele of RRF1, rrf1-L209P, grew on a non-fermentable carbon source at 30 but not at 36°C, where mitochondrial but not total protein synthesis was 90% inhibited. We propose that Rrf1p is essential for mitochondrial protein synthesis and acts as a RRF in mitochondria.     

Cloning and analysis of the nuclear genes for two mitochondrial ribosomal proteins in yeast

Summary Two mitochondrial ribosomal proteins of yeast (Saccharomyces cerevisiae) were purified and their N-terminal amino acid sequences determined. The sequence data were used for the synthesis of oligonucleotide probes to clone the corresponding genes. Thus, the genes for two proteins, termed YMR-31 and YMR-44, were cloned and their nucleotide sequences determined. From the nucleotide sequence data, the coding region of the gene for protein YMR-31 was found to be composed of 369 nucleotide pairs. Comparison of the amino acid sequence of protein YMR-31 and the one deduced from the nucleotide sequence of its gene suggests that it contains an octapeptide leader sequence. The calculated molecular weight of protein YMR-31 without the leader sequence is 12792 dalton. The gene for protein YMR-44 was found to contain a 147 bp intron which contains two sequences conserved among yeast introns. The length of the two exons flanking the intron totals 294 nucleotide pairs which can encode a protein with a calculated molecular weight of 11476 dalton. The gene for protein YMR-31 is located on chromosome VI, while the gene for protein YMR-44 is located on either chromosome XIII or XVI.     

Two isoaccepting seryl tRNAs coded by separate mitochondrial genes in yeast

Summary In S. cerevisiae four isoacceptor mitochondrial tRNAs for serine have been separated by reversed phase chromatography. At least two of these species are products of different genes. In this work the deletion mapping technique has been used to locate two genes for tRNA^ser. The gene for tRNA^ser previously localized in the oli I region of the mitochondrial genome has been found to code for tRNA _ser ² , and another gene coding for tRNA _ser ¹ has been detected in the region where most of other tRNA genes are found. Results of fine mapping experiments allowed to localize this gene in the proximity of the gene for tRNA^arg.     

Interaction between ubiquinone and ATPase in mitochondrial membranes

The extraction of ubiquinone from mitochondrial membranes produces alterations of ATPase activity including a reversible loss of oligomycin sensitivity which is restored by long-chain Q-homologs. Short-chain ubiquinones like Q₃ produce a loss of oligomycin and dicyclohexylcarbodiimide (DCCD) sensitivity in submitochondrial particles. The effect shows uncompetitive or noncompetitive kinetics with respect to oligomycin or DCCD respectively. Long-chain ubiquinones have a competitive effect with Q₃, thus restoring oligomycin sensitivity; they behave, however, in about the same way as Q₃ in lowering the DCCD sensitivity in submitochondrial particles. On the basis of these observations we suggest that ubiquinone may be a physiological modulator of ATPase activity in the mitochondrial membrane.Abbreviations used: BHM, beef heart mitochondria; DCCD, dicyclohexylcarbodiimide; ETP, electron transfer particles (submitochondrial particles); Q, ubiquinone.