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     

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.     

Transfer RNA genes in the cap-oxil region of yeast mitochondrial DNA.

A cytoplasmic "petite" (rho-) clone of Saccharomyces cerevisiae has been isolated and found through DNA sequencing to contain the genes for cysteine, histidine, leucine, glutamine, lysine, arginine, and glycine tRNAs. This clone, designated DS502, has a tandemly repeated 3.5 kb segment of the wild type genome from 0.7 to 5.6 units. All the tRNA genes are transcribed from the same strand of DNA in the direction cap to oxil. The mitochondrial DNA segment of DS502 fills a sequence gap that existed between the histidine and lysine tRNAs. The new sequence data has made it possible to assign accurate map positions to all the tRNA genes in the cap-oxil span of the yeast mitochondrial genome. A detailed restriction map of the region from 0 to 17 map units along with the locations of 16 tRNA genes have been determined. The secondary structures of the leucine and glutamine tRNAs have been deduced from their gene sequences. The leucine tRNA exhibits 64% sequence homology to an E. coli leucine tRNA.     

Recombination in yeast mitochondrial DNA

When haploid yeast strains containing mitochondrial DNAs (mtDNAs) of different buoyant densities are mated, the resulting zygotes contain a mixed population of mitochondria and mitochondrial DNAs. During vegetative growth of diploid cells formed from such a cross between a petite strain with mtDNA of density 1.677 g cm^?3 and a respiratory competent strain with mtDNA of density 1.684 g cm^?3, mtDNAs with intermediate buoyant densities are obtained. Virtually all newly synthesized mtDNA in diploid ρ^? progeny has the intermediate buoyant density. Therefore, within 2 generations of growth of the diploid cells, the intermediate buoyant density species predominate. In crosses between a respiratory competent strain and other petite strains with different values of genetic suppressiveness, it was found that the amount of recombination yielding mtDNAs of intermediate buoyant densities roughly parallels the degree of suppressiveness. Individual clones of respiratory deficient cells from such crosses were also isolated to confirm that stable mtDNAs with intermediate buoyant densities were obtained. Thus, it is apparent that some form of recombination takes place within the mtDNAs of yeast cells that results in stable mtDNA species.     

The curious history of yeast mitochondrial DNA

Forty years ago, soon after yeast mitochondrial DNA (mtDNA) was recognized, some animal versions of mtDNA were shown to comprise circular molecules. Supporting an idea that mitochondria had evolved from bacteria, this finding generated a dogmatic belief that yeast mtDNA was also circular, and the endless linear molecules actually observed in yeast were regarded as broken circles. This concept persisted for 30 years and has distorted our understanding of the true nature of the molecule.     

The organization of ribosomal RNA genes in the mitochondrial DNA of Tetrahymena pyriformis strain ST.

1. We have constructed a physical map of the mtDNA of Tetrahymena pyriformis strain ST using the restriction endonucleases EcoRI, PstI, SacI, HindIII and HhaI. 2. Hybridization of mitochondrial 21 S and 14 S ribosomal RNA to restriction fragments of strain ST mtDNA shows that this DNA contains two 21-S and only one 14-S ribosomal RNA genes. By S1 nuclease treatment of briefly renatured single-stranded DNA the terminal duplication-inversion previously detected in this DNA (Arnberg et al. (1975) Biochim. Biophys. Acta 383, 359--369) has been isolated and shown to contain both 21-S ribosomal RNA genes. 14 S ribosomal RNA hybridizes to a region in the central part of the DNA, about 8000 nucleotides or 20% of the total DNA length apart from the nearest 21 S ribosomal RNA gene. 3. We have confirmed this position of the three ribosomal RNA genes by electron microscopical analysis of DNA . RNA hybrid molecules and R-loop molecules. 4. Hybridization of 21 S ribosomal RNA with duplex mtDNA digested either with phage lambda-induced exonuclease or exonuclease III of Escherichia coli, shows that the 21-S ribosomal RNA genes are located on the 5'-ends of each DNA strand. Electron microscopy of denaturated mtDNA hybridized with a mixture of 14-S and 21-S ribosomal RNAs show that the 14 S ribosomal RNA gene has the same polarity as the nearest 21 S ribosomal RNA gene. 5. Tetrahymena mtDNA is (after Saccharomyces mtDNA) the second mtDNA in which the two ribosomal RNA cistrons are far apart and the first mtDNA in which one of the ribosomal RNA cistrons is duplicated.     

Regulation of yeast mitochondrial DNA synthesis

Summary The expression and stability of Escherichia coli F-primes in Proteus mirabilis is examined. It is possible to consecutively introduce, and stably maintain, the DNA of several E. coli F-primes in P. mirabilis in the absence of selective pressure for all or some of the plasmids. Additionally, we can recover more than one F-prime from certain P. mirabilis recipient strains which carry DNA derived from several independent matings with E. coli F-prime donors.     

Regulation of yeast mitochondrial DNA synthesis

Summary A single recessive nuclear gene mutation has been isolated from strain 123.1 C of Saccharomyces cerevisiae which is conditionally deficient in mitochondrial DNA metabolism and has been termed tpi. Growth of this mutant strain in media containing galactose at 36°C causes a reduction of mitochondrial DNA synthesis as analyzed by incorporation of radioactive adenine into the mitochondrial DNA. These cells continue to grow and divide producing petite cells which are neutral and have been found to lack mitochondrial DNA as measured by radioactive incorporation of ³H-adenine into the mitochondrial DNA in the presence of cycloheximide at the permissive temperature. The rate of mitochondrial DNA synthesis of the mutant strain grown at the restrictive temperature in dextrose or glycerol containing media was found to be greatly reduced following two hours of exposure to the restrictive temperature. In addition, the action of this mutant gene has been found to be independent of the respiratory capacity of the mutant strain.     

The context organization of functional regions in yeast genes with high-level expression

With the example of yeast genes, context organization was compared for functional gene regions (promoter, 5'-UTR, 3'-UTR) and tested for association with the level of gene expression. Several parameters (nucleotide composition, dinucletoide content bias) proved to correlate with expression level, each functional region having its specific features. Context optimization of a functional region was assumed to be essential for highly efficient interaction with the expression system of the cell. Specific context features were considered as dispersed signals important for high-level gene expression.     

Replication of bromodeoxyuridylate-substituted mitochondrial DNA in yeast.

The DNA of several strains of Saccharomyces cerevisiae was labeled by growing the culture in medium supplemented with thymidylate and bromodeoxyuridylate. It was thus possible to follow the course of mitochondrial DNA replication in density shift experiments by determining the buoyant density distribution of unreplicated and replicated DNAs in analytical CsCl gradients. DNA replication was followed for three generations after transfer of cultures from light medium to heavy medium and heavy medium to light medium. Under both conditions, the density shifts observed for mitochondrial DNA were those expected for semiconservative, nondispersive replication. This was further confirmed by analysis of the buoyant density of alkali-denatured hybrid mitochondrial DNA. With this method, no significant recombination between replicated and unreplicated DNA was detected after three generations of growth.     

The ribosomal RNA genes of Drosophila mitochondrial DNA.

The nucleotide sequence of a segment of the mtDNA molecule of Drosophila yakuba which contains the A+T-rich region and the small and large rRNA genes separated by the tRNAval gene has been determined. The 5' end of the small rRNA gene was located by S1 protection analysis. In contrast to mammalian mtDNA, a tRNA gene was not found at the 5' end of the D. yakuba small rRNA gene. The small and large rRNA genes are 20.7% and 16.7% G+C and contain only 789 and 1326 nucleotides. The 5' regions of the small rRNA gene (371 nucleotides) and of the large rRNA gene (643 nucleotides) are extremely low in G+C (14.6% and 9.5%, respectively) and convincing sequence homologies between these regions and the corresponding regions of mouse mt-rRNA genes were found only for a few short segments. Nevertheless, the entire lengths of both of the D. yakuba mt-rRNA genes can be folded into secondary structures which are remarkably similar to secondary structures proposed for the rRNAs of mouse mtDNA. The replication origin-containing, A+T-rich region (1077 nucleotides; 92.8% A+T), which lies between the tRNAile gene and the small rRNA gene, lacks open reading frames greater than 123 nucleotides.