Size and structure of mitochondrial DNA from Physarum polycephalum

Electron microscopic investigation of mitochondrial DNA from Chenopodium album (L.)

DNA molecules from mitochondria of whole plants and a suspension culture of Chenopodium album were prepared, by a gentle method, for analysis by electron microscopy. Mitochondrial (mt) DNA preparations from both sources contained mostly linear molecules of variable sizes (with the majority of molecules ranging from 40 to 160 kb). Open circular molecules with contour lengths corresponding to 0. 3-183 kb represented 23-26% of all mtDNA molecules in the preparations from the suspension culture and 13-15% in the preparations from whole plants. More than 90% of the circular DNA was smaller than 30 kb. Virtually no size classes of the mtDNA molecules could be identified, and circular or linear molecules of the genome size (about 270 kb) were not observed. In contrast, plastid (pt) DNA preparations from the suspension culture contained linear and circular molecules falling into size classes corresponding to monomers, dimers and trimers of the chromosome. About 23% of the ptDNA molecules were circular. DNA preparations from mitochondria contained a higher percentage of more complex molecules (rosette-like structures, catenate-like molecules) than preparations of ptDNA. Sigma-like molecules (putative intermediates of rolling-circle replication) were observed in mtDNA preparations from the suspension culture (18% of the circles), and in much lower amount (1%) in preparations from whole plants. The results are compared with data obtained previously by pulsed-field gel electrophoresis and discussed in relation to the structural organization and replication of the mt genome of higher plants.

Reaching for the ring: the study of mitochondrial genome structure

The linear molecules that comprise most of the mitochondrial DNA (mtDNA) isolated from most organisms result from the artifactual degradation of circular genomes that exist within mitochondria. This view has been adopted by most investigators and is based on DNA fragment mapping data as well as analogy to the genome-sized circular mtDNA molecules obtained in high yield from animals. The alternative view that linear molecules actually represent the major form of DNA within mitochondria is supported by two observations; (1) over a 1000-fold range of genome size among fungi and plants we find the same size distribution of linear mtDNA molecules, and (2) linear mtDNA molecules much larger than genome size can be found for some fungi and plants. The circles that represent only a small fraction of the mtDNA obtained from most eukaryotes could be optional sequence forms unimportant for mitochondrial function; they may also participate in mtDNA replication. The circles might result from incidental recombination events between directly repeated sequences within or between tandemly arrayed genome units on linear mtDNA molecules.

Cloning and characterization of the Chlamydomonas moewusii mitochondrial genome

We report that the mitochondrial genome of Chlamydomonas moewusii has a 22 kb circular map and thus contrasts with the mitochondrial genome of Chlamydomonas reinhardtii, which is linear and about 6 kb shorter. Overlapping restriction fragments spanning over 90% of the C. moewusii mitochondrial DNA (mtDNA) were identified in a clone bank constructed using a Sau3AI partial digest of a C. moewusii DNA fraction enriched for mtDNA by preparative CsCl density gradient centrifugation. Overlapping Sau3AI clones were identified by a chromosome walk initiated with a clone of C. moewusii mtDNA. The mtDNA map was completed by Southern blot analysis of the C. moewusii mtDNA fraction using isolated mtDNA clones. Regions that hybridized to C. reinhardtii or wheat mitochondrial gene probes for subunit I of cytochrome oxidase (cox1), apocytochrome b (cob), three subunits of NADH dehydrogenase (nad1, nad2 and nad5) and the small and the large ribosomal RNAs (rrnS and rrnL, respectively) were localized on the C. moewusii mtDNA map by Southern blot analysis. The results show that the order of genes in the mitochondrial genome of C. moewusii is completely rearranged relative to that of C. reinhardtii.

Rapid disappearance of one parental mitochondrial genotype after isogamous mating in the myxomycete Physarum polycephalum

Five haploid amoebal strains of the myxomycete Physarum polycephalum, each with a distinct mitochondrial genotype, were crossed in all pairwise combinations. The mitochondrial genotype in the diploid plasmodia resulting from these isogamous matings were found to be transmitted uniparentally. This uniparental inheritance could be arranged in a dominant hierarchical order. Time-course analysis of the presence of mitochondrial genotypes in the zygotes and young developing plasmodia show that elimination of one parental mitochondrial genotype is virtually completed during the first two nuclear cycles in the zygote/differentiating plasmodium. To our knowledge this is the first report indicating an active mechanism involving the degradation of mitochondrial genomes in sexual crosses.

Mitochondrial DNA of Physarum polycephalum: physical mapping, cloning and transcription mapping

Mitochondrial DNA (mtDNA) has been isolated from four strains of Physarum polycephalum and a restriction site map has been determined using nine restriction enzymes. The restriction site maps of the four strains are similar but each strain is distinguished by insertions, deletions and restriction enzyme site polymorphisms. The sum of the restriction fragments gives mitochondrial genome sizes which vary from about 56 kb to 62 kb. In all four strains the composite map of the restriction enzyme sites for the mtDNA is circular. Knowledge of the restriction enzyme map has enabled cloning of mtDNA fragments representing the entire mtDNA of strain M3. The cloned fragments have been used to create a transcription map of the mtDNA.

Thymidylate synthetase during synchronous nuclear division cycle and differentiation of Physarum polycephalum

Thymidylate synthetase and thymidine kinase activities in wild type strain M3b and in thymidine kinase-deficient mutant TU63 of Physarum polycephalum are studied. Whenever nuclear division occurs in macroplasmodia of wild type, thymidine kinase and thymidylate synthetase activities sharply increase, although the increase of thymidylate synthetase activity is less pronounced than thymidine kinase activity. This is also true for other investigated nuclear divisions during the life cycle of P. polycephalum. It is shown for the first time that thymidylate synthetase is a periodically fluctuating enzyme during the naturally synchronous nuclear division cycle of P. polycephalum with a peak of specific activity in the S phase. In macroplasmodia, as well as after germination of microsclerotia of M3b, thymidine kinase is the dominant enzyme, whereas at the time of the precleavage mitosis in sporulating macroplasmodia thymidylate synthetase is the predominant enzyme. This study describes and compares both dTMP-synthesizing enzymes during proliferation and differentiation of the same organism.

Structural homogeneity of mitochondrial DNA in the mitochondrial nucleoid of Physarum polycephalum

Mitochondrial DNA (mtDNA) of Physarum polycephalum was isolated gently by CsCl centrifugation. The mtDNA was linear with molecular weights ranging from 25 . 10(6) to 45 . 10(6) and heterogeneous in size. Nevertheless, thermal transition profiles of the mtDNA suggested that this DNA fraction was more homogeneous than nuclear DNA. Exhaustive digestions of this DNA with restriction endonucleases yielded unique fragments, and then the total of their molecular weights of each digest was around 45 . 10(6). This value is equivalent to the maximum molecular weight estimated using electron microscopy and electrophoresis. Moreover, EcoRI digests of the mtDNA fractionated by the sucrose gradient showed unequimolar quantities of large fragments and a high background between bands. These results suggest that the mtDNA of Physarum has a homogeneous base sequence, and that the size heterogeneity of the mtDNA is attributable to degradation of the DNA under isolation procedures. The mtDNA was cleaved by EcoRI and XhoI to yield 16 and 7 fragments, respectively. A physical map of these fragments was constructed using the routine mapping procedures. The physical map showed that the mitochondrial genome of Physarum was linear with molecular weight of 45 . 10(6). We concluded therefore that the mitochondrial nucleoid is a structure in which the homogeneous mtDNA is highly amplified.

Mitochondrial DNA from Podospora anserina. I. Isolation and characterization

Mitochondrial (Mt) DNA from Podospora anserina was isolated and characterized with respect to density in CsCl, contour length and endonuclease restriction enzymes. The density of Mt DNA for four races examined was 1.694 g/cm3, compared with 1.712 g/cm3 for nuclear DNA. Extraction in the presence of a nuclease inhibitor, aurintricarboxylic acid and isolation in DAPI CsCl gradients allowed us to isolate high molecular weight DNA. Mt DNA isolated by total DNA extraction contained ca. 1% of circular molecules, 31 micron in contour length; Mt DNA isolated from purified mitochondria contained 2--4% of these 31 micron circles. Analysis with Eco RI restriction endonuclease revealed that each of the four races examined, s, A, T and E had a characteristic fragment pattern. Races s and A Mt DNA differed by only one fragment after Eco RI enzymatic digestion; similarly, these two DNA differed by only one or two fragments after Hae III digestion.