Excision sequences in the mitochondrial genome of yeast

We report an analysis of the sequences used in the excision of the mitochondrial genomes of 22 spontaneous and ten ethidium bromide (EtBr)-induced Saccharomyces cerevisiae petite mutants. In all cases, excision sequences were found to be perfect direct repeats, often flanked on one or both sides by regions of patchy homology. Sequences used in the excision of the genomes of spontaneous petites were always located in the AT spacers and GC clusters of intergenic regions of the genome; the GC clusters corresponded to ori and ori^s sequences, namely to canonical and surrogate origins of DNA replication, respectively. In the case of the ethidium bromide-induced petites, excision sequences were found not only in intergenic sequences, but also in the introns and exons of mitochondrial genes.     

The origins of replication of the mitochondrial genome of yeast

Recent investigations have provided information on the origin of replication of the mitochondrial genome of yeast and an explanation for the phenomenon of the suppressivity.     

Replication origins in yeast chromosomes

DNA replication initiates at many sites in eukaryotic chromosomes. It has been difficult to isolate such replication origins, but a family of sequences from the yeast genome have properties which suggest that they may serve this function. The identification of these sequences together with sophisticated methods of genetic analysis, make yeast a useful organism for the study of eukaryotic DNA replication.     

Transmission of the yeast mitochondrial genome to progeny: The impact of intergenic sequences

Summary In a previous publication it was shown that the output of yeast mitochondrial loci lacking nearby intergenic sequences (encompassing ori/rep elements) was reduced in crosses to strains with wild-type mtDNAs. In the present work, mitochondrial genomes carrying the intergenic deletions were marked at unlinked, loci by introducing specific antibiotic resistance mutations against erythromycin, oligomycin and paromomycin. These marked genomes were used to follow the output of unlinked regions of the genome from crosses between the intergenic deletion mutants and wild-type strains. Transmission of genetically unlinked markers in coding regions was substantially reduced when an intergenic deletion was present on the same genome. In general the transmission of the antibiotic markers was the same as or slightly higher than the corresponding intergenic marker. These results indicate that the presence of an intergenic deletion in the regions studied impairs the transmission to progeny of a mitochondrial genome as a whole. More specifically, the results suggest that ori/rep sequences, present in the regions that have been deleted, confer a competitive advantage over genomes lacking a full complement of such sequences. These results support the hypothesis that intergenic sequences, and specifically ori/rep elements, have a biological role in the mitochondrial genome. However, because of the exclusive presence of ori/rep sequences in the genus Saccharomyces, it may be that these sequences evolved in (or invaded) the mitochondrial genome relatively late in the evolution of the yeasts. Therefore, in a more general sense, variations in the amount and structure of intergenic sequences in various yeasts may reflect processes that have been of selective advantage in the metabolism of individual mitochondrial DNA in a particular environment and that have not drastically interrupted the respiratory phenotype.     

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.     

Tracing the dawn of Plasmodium falciparum with mitochondrial genome sequences

Until recently, little light had been shed on the murky origins of human malaria. Did Plasmodium falciparum, the most virulent malaria parasite, emerge as a common pathogen only in the past few thousand years, as suggested by some analyses of its nucleotide sequence diversity? Or, was it an ancient scourge of early humans >100 000 years ago, as suggested by others? A recent study, using complete mitochondrial DNA sequence polymorphism data and new analytical methods, points to an intermediate date of origin and expansion out of Africa. Subsequent population growth in each continent is less well resolved.     

Replication origins are attached to the nuclear skeleton.

DNA fragments containing replication origins (oriDNA) were isolated from a chicken erythroblast cell line by a modified procedure of Zannis-Hadjopoulos et al. and studied in the renaturation reaction driven by either total or nuclear matrix DNA (nmDNA) from the same cells or from mature erythrocytes. We found that the unique sequences of nmDNA from erythroblasts (5 kb long) represented a specific subset of sequences constituting about a quarter of total DNA unique sequences, while the erythrocyte nmDNA 5 kb fragments constitute only about one tenth of total unique DNA and all are recovered among erythroblast nmDNA. Virtually all oriDNA sequences are present in the fraction of erythrocyte nmDNA. Thereafter, the putative positions of replication origins within the alpha-globine gene domain have been mapped by hybridization experiments. They were found to coincide with the previously established positions of permanent sites of DNA attachment to the nuclear matrix.     

Structural properties of replication origins in yeast DNA sequences

Sequence-dependent DNA flexibility is an important structural property originating from the DNA 3D structure. In this paper, we investigate the DNA flexibility of the budding yeast (S. Cerevisiae) replication origins on a genome-wide scale using flexibility parameters from two different models, the trinucleotide and the tetranucleotide models. Based on analyzing average flexibility profiles of 270 replication origins, we find that yeast replication origins are significantly rigid compared with their surrounding genomic regions. To further understand the highly distinctive property of replication origins, we compare the flexibility patterns between yeast replication origins and promoters, and find that they both contain significantly rigid DNAs. Our results suggest that DNA flexibility is an important factor that helps proteins recognize and bind the target sites in order to initiate DNA replication. Inspired by the role of the rigid region in promoters, we speculate that the rigid replication origins may facilitate binding of proteins, including the origin recognition complex (ORC), Cdc6, Cdt1 and the MCM2-7 complex.