Physical mapping and genome organization of mitochondrial DNA from Candida maltosa

Summary Mitochondrial (mt) DNA of the ascomycetous yeast Candida maltosa was isolated and characterized. The mtDNA is circular and the size estimated from restriction analysis performed with 7 endonucleases was 52 kb pairs. A restriction map was constructed, using the cleavage data of four endonucleases. Using mt genes from Saccharomyces cerevisiae, six structural genes (large rRNA, apocytochrome b, cytochrome c oxidase subunit I and subunit 11, ATPase subunit 6 and subunit 9) were located on the C. maltosa chondriome by cross hybridization experiments. The comparison between the mt genomes of C. maltosa and six other yeasts showed differences in the overall genome organization.     

The mitochondrial genome of the aquatic phycomycete Allomyces macrogynus. Physical mapping and mitochondrial DNA instability

Summary A physical map of the mitochondrial genome of the aquatic phycomycete Allomyces macrogynus strain Burma 3–35 (35°C) has previously been published (Borkhardt and Delius 1983). This map has been extended in this study by locating 37 additional recognition sites for five new restriction enzymes in the mitochondrial genome. Homologous regions for the genes coding for cytochrome oxidase subunits 1, 2, and 3, apocytochrome b, ATPase subunits 6 and 9, the small and large ribosomal RNA, URF1, URF5, and perhaps urfa, a presumptive gene hitherto found only in the mitochondrial genome of the fission yeast Schizosaccharomyces pombe, were located in the mitochondrial genome of A. macrogynus by heterologous hybridizations with specific, mitochondria) gene probes from Saccharomyces cerevisiae, Aspergillus nidulans, Neurospora crassa, and S. pombe. The mitochondrial gene order in A. macrogynus was found to be identical to that of A. arbuscula; a gene order hitherto found only among members of the family Blastocladiaceae. Spontaneous insertion mutations have been found to occur quite frequently in the mitochondrial genome of A. macrogynus. In all mutated mitochondrial genomes so far studied, insertions have been located in a specific region located between the genes coding for the ATPase subunit 9 and the large ribosomal RNA. In two of the mutated mitochondrial genomes the insertional event(s) resulted in the presence of mitochondrial DNA molecules differing in size by multiples of approximately 70 base pairs.     

Isolation and characterization of mitochondrial DNA from the alkane yeast Saccharomycopsis lipolytica

Summary Mitochondrial (mt) DNA of the alkane yeast, Saccharomycopsis lipolytica, was isolated. Its buoyant density in CsCl was found to be of 1.687 g/cm³, indicating a GC content of 27.5% and its melting point T_m = 79.5 °C, indicating a GC content of 24.9%. The corresponding values for nuclear (n) DNA, are 1.709 g/cm³ (GC: 49.5%) and T_m = 90.5 (GC: 51.7%) respectively. Electron microscopy revealed that mtDNA has a circular structure with a contour length of about 14.5 µm corresponding to 45.5 kb per molecule. The size estimated from restriction analyses performed with 7 endonucleases was 48.35 kb/molecule. A restriction map was constructed, using the cleavage data of 4 endonucleases.     

Cloning by genetic complementation and restriction mapping of the yeast HEM1 gene coding for 5-aminolevulinate synthase

Summary We have cloned the structural gene HEM1 for 5-aminolevulinate (ALA) synthase from Saccharomyces cerevisiae by transformation and complementation of a yeast hem1–5 mutant which was previously shown to lack ALA synthase activity (Urban-Grimal and Labbe Bois 1981) and had no immunodetectable ALA synthase protein when tested with yeast ALA synthase antiserum. The gene was selected from a recombinant cosmid pool which contained wild-type yeast genomic DNA fragments of an average size of 40 kb. The cloned gene was identified by the restauration.of growth on a non fermentable carbon source without addition of exogenous ALA. Sub cloning of partial Sau3A digests and functional analysis by transformation allowed us to isolate three independent plasmids, each carrying a 6 kb yeast DNA fragment inserted in either orientation into the single BamHI site of the vector pHCG3 and able to complement hem1–5 mutation. Analysis of the three plasmids by restriction endonucleases showed that HEM1 is contained within a 2.9 kb fragment. The three corresponding yeast trans formants present a 1, 2.5 and 16 fold increase in ALA synthase activity as compared to the wild-type strain. The gene product immunodetected in the transformant yeast cells has identical size as the wild-type yeast ALA synthase and its amount correlates well with the increase in ALA synthase activity.     

Preparation of yeast mitochondrial DNA for direct sequence analysis

We describe two simple protocols for preparation of templates for direct sequencing of yeast mitochondrial DNA (mtDNA) by automatic DNA analyzers. The protocols work with a range of yeast species and yield a sufficient quantity and quality of the template DNA. In combination with primer-walking strategy, they can be used either as an alternative or a complementary approach to shot-gun sequencing of random fragment DNA libraries. We demonstrate that the templates are suitable for re-sequencing of the mtDNA for comparative analyses of intraspecific variability of yeast strains as well as for primary determination of the complete mitochondrial genome sequence.     

A rapid and simple method for extracting yeast mitochondrial DNA

Summary A rapid method for the extraction of yeast mitochondrial DNA (mtDNA) is described. In comparison with previous methods, it simplifies several steps, does not require either the isolation of mitochondria or phenol treatment and is less time consuming. This protocol gives a high yield of pure mtDNA (50–120 g from a 100-ml culture), which can be directly used in various molecular applications: restriction enzyme digestion, electrophoresis, blotting, labeling, cloning and sequencing.     

Genome organization of mitochondrial DNA from the non-saccharomycete yeast Arxula adeninivorans LS3

Mitochondrial (mt) DNA of the asexual ascomycetous yeast Arxula adeninivorans LS3 was isolated and characterized. The mtDNA has a GC content of 30.3 mol%. It is circular and its size, as estimated by restriction analysis performed with nine endonucleases, was 35.5 kbp. Using mt gene-probes from Saccharomyces cerevisiae six structural genes (cob, cox1, cox2, oli1, oli2, and 21S rRNA) were located on the mitochondrial genome of A. adeninivorans. The comparison between the mt genomes of A. adeninivorans and other yeasts showed differences in genome organization.     

MboI,ThaI and HinfI endonuclease cleavage maps of the yeast mitochondrial DNA

Summary MboI, HinfI and ThaI cleavage maps have been constructed for the region of the mitochondrial DNA from S. cerevisiae where transfer RNA genes are principally located. About 40 cleavage sites have been localized between the C and P genetic markers. The MboI map covers about 50% of the total mitochondrial genome. For constructing maps we have used a series of rho^– deletion mutants whose mitochondrial DNAs have a typical single deletion structure as judged by previous genetic and physical analyses. The mutant DNAs carry known transfer RNA genes and genetic markers and, therefore, the comparison between genetic and restriction maps has allowed us to localize individual transfer RNA genes within defined physical segments.Abbreviations bp base pairs - mtDNA mitochondrial DNA - tRNA transfer RNA - rRNA ribosomal RNA - ThaI formerly TacI     

Physical map of the COB region in mitochondrial DNA of Saccharomyces cerevisiae

Summary A physical map of the COB region in mtDNA of yeast has been established. This region harbours a split gene coding for apocytochrome b. It includes restriction sites of seven endonucleases (EcoRI, HindII, HindIII, HaeIII, HpaII, AluI and BamHI). Various mtDNA sequences of this region, retained in a series of genetically characterized rho^– clones have been allocated to this map. The combination of this physical map with a genetic map of the rho^– clones revealed that 1) cob^– mutational sites spread over 8,400 bp, 2) mutations in sequences coding for apocytochrome b map in five distinct segments which are separated by intervening sequences with minimum lengths from 350 to 1,900 bp.Abbreviations mtDNA mitochondrial DNA - b bases - bp basepairs     

Physical mapping of 4S RNA genes on chloroplast DNA of Spirodela oligorhiza

Summary We have determined the position of Spirodela oligorhiza chloroplast 4S RNA genes on the restriction fragment map of cp DNA, using purified in vitro[³²P]-labeled 4S RNA. The overall organization of these genes is very similar to the organization of tRNAs on spinach cp DNA (Driesel et al. 1979).Abbreviations cp chloroplast - (k)bp (kilo)base pairs - SSC 150 mM NaCl; 15 mM Na-citrate (pH 7.0)     

Physical mapping of the mitochondrial genome of the cultivated mushroom Agaricus brunnescens (= A. bisporus)

Summary Mitochondrial (mt) DNA from the commercial mushroom Agaricus brunnescens Peck [= A. bisporus (Lange) Imbach] was purified by cesium chloride/bisbenzimide gradient centrifugation. A physical map of the mtDNA fragments produced by BamHI, EcoRl, and PvuII digestion was generated by filter hybridizations with radiolabelled BamHI mtDNA probes. The A. brunnescens mtDNA was a circular molecule 136 kilo-basepairs (kbp) in length and contained an inverted repeat between 4.6 and 9.2 kbp in size. Orientational isomers of the mitochondrial genome were not detected. The positions of six genes were located on the A. brunnescens mtDNA map by heterologous hybridization. No coding function has yet been ascribed to the inverted repeat. The large rRNA gene was located on the smaller single copy region. The genes for cytochrome b, cytochrome oxidase (subunit III), ATPase (subunits 8 and 6) and the small rRNA were located on different regions of the larger single copy region.     

Physical mapping of genes for chloroplast DNA encoded subunit polypeptides of the ATPsynthase complex from Petunia hybrida

Summary Escherichia coli minicells harbouring the cloned restriction fragment Sall S9 from P. hybrida chloroplast DNA synthesize the beta and epsilon polypeptide subunits of the CF₁ component of the chloroplast ATPsynthase complex. The polypeptides were identified by molecular weight determination and immunoprecipitation. The position of the atpB and the atpE gene, encoding respectively the beta and epsilon subunit, on the Sall S9 fragment was determined in more detail by studying polypeptide synthesis directed by subclones of the S9 fragment in E. coli minicells. The atpB and atpE genes are located close to the rbcL gene, the distance between the rbcL gene and atpB gene being approximately 770 bp. Analysis of the expression of subclones of the S9 fragment in E. coli minicells also revealed that the atpE gene can be transcribed and translated independently of the expression of the atpB gene.The location of the genes coding for the alpha subunit (atpA gene) and the proteolipid subunit III of CF₀ (atpH) of the ATPsynthase complex on the physical map of P. hybrida cpDNA was determined by hybridization of restriction enzyme digests of petunia cpDNA with cloned cpDNA fragments from Spirodela and wheat, containing internal parts of respectively the atpA and the atpH gene. The two genes map close together within a region of 5.2 kbp on the physical map of P. hybrida cpDNA. The distance between the atpA gene and the atpB and atpE genes is approximately 42 kbp.Abbreviations cpDNA chloroplast DNA - rbcL gene coding for the large subunit of ribulose-1,5-bisphosphate carboxylase/oxygenase - CF₁ coupling factor, extrinsic part of the chloroplast ATPsynthase complex - kbp kilo base pairs     

The mitochondrial DNA of land plants: peculiarities in phylogenetic perspective

Land plants exhibit a significant evolutionary plasticity in their mitochondrial DNA (mtDNA), which contrasts with the more conservative evolution of their chloroplast genomes. Frequent genomic rearrangements, the incorporation of foreign DNA from the nuclear and chloroplast genomes, an ongoing transfer of genes to the nucleus in recent evolutionary times and the disruption of gene continuity in introns or exons are the hallmarks of plant mtDNA, at least in flowering plants. Peculiarities of gene expression, most notably RNA editing and trans-splicing, are significantly more pronounced in land plant mitochondria than in chloroplasts. At the same time, mtDNA is generally the most slowly evolving of the three plant cell genomes on the sequence level, with unique exceptions in only some plant lineages. The slow sequence evolution and a variable occurrence of introns in plant mtDNA provide an attractive reservoir of phylogenetic information to trace the phylogeny of older land plant clades, which is as yet not fully resolved. This review attempts to summarize the unique aspects of land plant mitochondrial evolution from a phylogenetic perspective.     

Molecular genetic properties of the yeast Torulaspora pretoriensis: Characterization of chromosomal DNA and genetic transformation by Saccharomyces cerevisiae-based plasmids

Chromosomal DNA banding patterns were obtained for three strains of Torulaspora pretoriensis by contour-clamped homogenous-electric-field gel electrophoresis. Chromosomes were resolved into six or seven bands in the range of 800 to 2000 kb, and a polymorphism of these lengths was observed. By Southern-blot analysis, the three strains were shown to lack the DNA sequences homologous to the URA3, LEU2, TRP1, and HO genes of Saccharomyces cerevisiae. A uracil auxotrophic mutant derived from T. pretoriensis was transformed with three plasmids (YEp24, YRpHI, and YCp50) carrying the URA3 gene of S. cerevisiae by the lithium acetate method.     

Physical mapping of the MEL gene family in Saccharomyces cerevisiae

Nine members, MEL2–MEL10, of the MEL gene family coding for -galactosidase were physically mapped to the ends of the chromosomes by chromosome fragmentation. Genetic mapping of the genes supported the location of all the MEL genes in the left arm of their resident chromosomes.     

Physical mapping of repetitive DNA sequences and 5S and 18S–26S rDNA in five wild species of the genusHordeum

The genetic relationships between several wild species and subspecies of the genusHordeum were assessed using fluorescencein situ hybridization (FISH). Plant material included natural populations of wild barley growing in Spain of the annual species,H. marinum ssp.marinum (2n=14) andgussoneanum (2n=14), andH. murinum ssp.murinum (2n=28), andleporinum (2n=28) and the perennial speciesH. bulbosum (2n=14) andH. secalinum (2n=28), plus the South American perennial speciesH. chilense (2n=14). FISH was used to locate the chromosomal sites of two rDNA multigene families 5S and 18S–26S (pTa71 and pTa794) and three repetitive DNA sequences (pSc119.2, pAs1 and pHch950) isolated from different species and genera. The seven chromosomes of the diploid species were readily distinguished by their external morphology and hybridization patterns to pTa71, pTa794, pSc119.2 and pAs1. These DNA probes were also useful for the identification of homologous chromosomes and in differentiating these from unidentified chromosomes in the tetraploid taxa. The use of the probe pHch950 permitted intergenomic differentiation in tetraploids and supports the diphyletic origin ofH. murinum andH. secalinum. Thein situ experiments yielded the following conclusions: (1) differences between the subspeciesmarinum andgussoneanum; (2) close relationships between the subspeciesmurinum andLeporinum; and (3) major differences in physical mapping betweenH. bulbosum and the remaining taxa. The genomic and phylogenetic relationships between taxa, as inferred from the results, are discussed.accepted by J.S. (Pat) Heslop-Harrison     

Distribution of mitochondrial r1-type introns and the associated open reading frame in the yeast genus Kluyveromyces

Summary We have sequenced the intron in the large subunit ribosomal RNA gene from the mitochondrion of Kluyveromyces lactis. It is a typical group I intron but, unlike the corresponding intron (r1) in Saccharomyces cerevisiae, it does not contain an open reading frame. This intron is widespread in the genus Kluyveromyces although intron-less strains were also found in some species of this genus. Sequences homologous to the open reading frame of the S. cerevisiae ribosomal intron were detected in some strains of K. waltii, K thermotolerans and K. africanus.     

Multiple correlation analysis of the redistribution of mitochondrial size in dependence on the dose and time after one-trial ionizing radiation

Translated fromByulleten' Eksperimental'noi Biologii i Meditsiny Vol. 115, N ^o 5, pp., 553–556, May, 1993