Restriction Fragment Length Polymorphisms of Mitochondrial and Nuclear DNAs among Korean Races of Magnaporthe grisea

Three KJ-races of Magnaporthe grisea (virulent to only japonica type rice cultivars) and seven KI-races (virulent to either indica or japonica type cultivars) isolated from various rice-growing areas of Korea were assayed for restriction fragment length polymorphisms (RFLPs) in mitochondrial and nuclear DNAs of the fungus. The size of mitochondrial DNA of M. grisea was estimated to be approximately 39. 8 kb. No RFLP in the mt DNA was detected among the 10 Korean races, indicating an extensive conservation in the gene composition of mt DNA without sequence variation. The identical restriction patterns of mt DNA also suggest that mt DNA of M. grisea may not be responsible for pathotypic diversity and variability. Southern blot analysis with five single-copy DNA probes showed considerable polymorphisms. Much diversity was detected in the three KI-races predominated during 1978–1985 in Korea. In contrast, no genetic variation was detected between other four KI-races and three KJ-races. RFLPs in nuclear DNA were correlated to some extent with the prevailing races in Korea. However, relationship between RFLPs in nuclear DNA and virulence of M. grisea races was inconclusive.     

Mitochondrial DNA haplogroups do not play a role in the variable phenotypic presentation of the A3243G mutation

Thirty-five mitochondrial (mt) DNAs from Spain that harbor the mutation A3243G in association with either MELAS (mitochondrial myopathy, encephalopathy, lactic acidosis, and strokelike episodes) syndrome or a wide array of disease phenotypes (ranging from diabetes and deafness to a mixture of chronic progressive external ophthalmoplegic symptoms and strokelike episodes) were studied by use of high-resolution restriction fragment length polymorphism analysis and control-region sequencing. A total of 34 different haplotypes were found, indicating that all instances of the A3243G mutation are probably due to independent mutational events. Haplotypes were distributed into 13 haplogroups whose frequencies were close to those of the general Spanish population. Moreover, there was no statistically significant difference in haplogroup distribution between patients with MELAS and those with disease phenotypes other than MELAS. Overall, these data indicate that the A3243G mutation harbors all the evolutionary features expected from a severely deleterious mtDNA mutation under strong negative selection, and they reveal that European mtDNA backgrounds do not play a substantial role in modulating the mutation's phenotypic expression.     

Restriction Fragment Length Polymorphism Analysis of the Mitochondrial DNA of Fusarium oxysporum f. sp. ciceris

Seven isolates of Fusarium oxysporum f. sp. ciceris, representing pathogenic races 1 , 2, 3, and 4 from India and 0, 5, and 6 from Spain, were assayed for restriction fragment length polymorphisms (RFLPs) in the mitochondrial DNA,(mt DNA). The mt DNA fraction of total fungal DNA was purified and digested with the restriction endonucleases Bam HI, Bgl II, Eco RI. Kpn I, Sac I, Sal I, Sma I, and Xho I. The mt DNA is a circular molecule of 40.5 kb. No RFLP in the mt DNA was detected among the seven races of F. o. ciceris. The identical restriction patterns of mt DNA indicates an extensive conservation in the gene composition of mt DNA without sequence variation, and suggests that mt DNA of F. o. ciceris may not be responsible for pathogenic diversity. The restriction map of mt DNA from the race 6 isolate Fo 8272 was constructed by digestion of the mt DNA with five restriction enzymes: Eco RI, Kpn I, Sac I, Sal I, and Xho I, either singly or in selected pairs.     

Direct selection of mutations in the human mitochondrial tRNAThr gene: reversion of an 'uncloneable' phenotype

Several regions of the human mitochondrial genome are refractory to cloning in plasmid and bacteriophage DNA vectors. For example, recovery of recombinant M13 clones containing a 462 basepair MboI-Kpn I restriction fragment that spans nucleotide positions 15591 to 16053 of HeLa cell mitochondrial DNA was as much as 100-fold lower than the recovery of M13 clones containing other regions of the human mitochondrial genome. All of 50 recombinant M13 clones containing this 'uncloneable' fragment had one or more changes in nucleotide sequence. Each clone contained at least one alteration in two nucleotide positions within the tRNAThr gene that encode portions of the anticodon loop and D-stem of the HeLa mitochondrial tRNAThr. These results imply that the HeLa mitochondrial tRNAThr gene is responsible for the 'uncloneable' phenotype of this region of human mitochondrial (mt) DNA. A total of 61 nucleotide sequence alterations were identified in 50 independent clones containing the HeLa mt tRNAThr gene. 56 mutations were single-base substitutions; 5 were deletions. Approximately 80% of the base substitution mutations were A:T----G:C transitions. A preference for A:T----G:C transition mutations also characterizes polymorphic base substitution variants in the mitochondrial DNA of unrelated individuals. This similarity suggests that human mitochondrial DNA sequence variation within and between individuals may have a common origin.     

Analysis of rice mitochondrial genome organization using pulsed-field gel electrophoresis

Most of the plant mitochondrial (mt) genomes that have been mapped are believed to be organized as master circle molecules from which sub-genomic molecules arise through homologous recombination. We have evidence to suggest that a major part of the rice mt genome is organized as independent, sub-genomic molecules or mt chromosomes, one of which has already been mapped. This study is aimed at the identification of the other molecular entities that comprise the genome. Pulsed-field gel electrophoresis of the native rice mt DNA and Southern analysis with different mt gene probes have shown that in addition to the 117 kb mt chromosome, at least four more such molecules of sizes 130 kb, 95 kb, 70 kb and 56 kb account for most of the rice mt genome. A majority of the rice mt genes that encode products involved in oxidative phosphorylation are distributed among these five chromosomes. Partial restriction map of the 95 kborf 25/cox 3 chromosome, indicating the sites for the enzymesBglII andHindIII has also been determined.     

Identification of three populations ofOphiostoma ulmi (aggressive subgroup) by mitochondrial DNA restriction-site mapping and nuclear DNA fingerprinting

Three genetically distinct populations of the Dutch elm pathogenOphistoma ulmi within the aggressive subgroup were defined by the hybridization of a human minisatellite DNA sequence (HVR 33.6) to polymorphic dispersed DNA sequences within theO. ulmi nuclear genomes. For the 10 isolates examined there was a close correlation between nuclear DNA fingerprints and mitochondrial (mt) DNA restriction patterns. A restriction-site map was constructed for the mitochondrial genomes for each of these populations. The three mt DNA maps corresponded to genome sizes of 49.1 (Type I), 49.9 (Type II), and 53.9 (Type III) kilobase pairs (kbp) of DNA. The Type I and Type II mt genomes differed from the Type III mt genome by discrete length mutations of 4.8 and 4.0 kbp, respectively. It is unknown whether these length mutations resulted from insertions into or deletions from a progenitor mitochondrial genome. There was no correlation between the mitochondrial or nuclear genotypes and the geographical source of the isolates.     

A new mitochondrial disease associated with mitochondrial DNA heteroplasmy.

A variable combination of developmental delay, retinitis pigmentosa, dementia, seizures, ataxia, proximal neurogenic muscle weakness, and sensory neuropathy occurred in four members of a family and was maternally transmitted. There was no histochemical evidence of mitochondrial myopathy. Blood and muscle from the patients contained two populations of mitochondrial DNA, one of which had a previously unreported restriction site for AvaI. Sequence analysis showed that this was due to a point mutation at nucleotide 8993, resulting in an amino acid change from a highly conserved leucine to arginine in subunit 6 of mitochondrial H(+)-ATPase. There was some correlation between clinical severity and the amount of mutant mitochondrial DNA in the patients; this was present in only small quantities in the blood of healthy elderly relatives in the same maternal line.     

Direct selection of mutations in the human mitochondrial tRNAThr gene: reversion of an ‘uncloneable’ phenotype

Several regions of the human mitochondrial genome are refractory to cloning in plasmid and bacteriophage DNA vectors. For example, recovery of recombinant M13 clones containing a 462 basepair MboI-Kpn I restriction fragment that spans nucleotide positions 15591 to 16053 of HeLa cell mitochondrial DNA was as much as 100-fold lower than the recovery of M13 clones containing other regions of the human mitochondrial genome. All of 50 recombinant M13 clones containing this ‘uncloneable’ fragment had one or more changes in nucleotide sequence. Each clone contained at least one alteration in two nucleotide positions within the tRNA^Thr gene that encode portions of the anticodon loop and D-stem of the HeLa mitochondrial tRNA^Thr. These results imply that the HeLa mitochondrial tRNA^Thr gene is responsible for the ‘uncloneable’ phenotype of this region of human mitochondrial (mt) DNA.A total of 61 nucleotide sequence alterations were identified in 50 independent clones containing the HeLa mt tRNA^Thr gene. 56 mutations were single-base substitutions; 5 were deletions. Approximately 80% of the base substitution mutations were A:T → G:C transitions. A preference for A:T → G:C transition mutations also characterizes polymorphic base substitution variants in the mitochondrial DNA of unrelated individuals. This similarity suggests that human mitochondrial DNA sequence variation within and between individuals may have a common origin.     

Fertility Restoration Is Associated with Loss of a Portion of the Mitochondrial Genome in Cytoplasmic Male-Sterile Common Bean

Restoration of pollen fertility to cytoplasmic male-sterile common bean by nuclear gene Fr is accompanied by mitochondrial (mt) DNA rearrangements within restored plants. These rearrangements are also observed upon spontaneous cytoplasmic reversion to fertility. An mtDNA fragment of at least 25 kilobases was lost from the genome upon restoration or reversion. This fragment contained DNA segments that were not repeated elsewhere in the genome and, therefore, were not detected within the genome upon fertility restoration. This result suggested that the particular mtDNA configuration absent from restored plants could not be maintained by a constant process of recombination but rather by autonomous replication. No evidence of excision of this region from the mt genome, in the form of a junction fragment associating flanking DNA regions, was detected in fertile restored plants. DNA gel blot hybridization of this mtDNA region, compared with hybridization to related regions of the mitochondrial genome that shared sequence homology, indicated that the mtDNA region associated with sterility was present in lower copy number. These observations, as well as the occurrence of similar or identical rearrangements upon spontaneous cytoplasmic reversion, indicate that the restoration of pollen fertility may be accompanied by loss of an independently replicating subgenomic DNA molecule from the mitochondrial genome.     

Quantitation of heteroplasmy in mitochondrial DNA mutations by primer extension using Vent(R)(exo-) DNA polymerase and RFLP analysis

In this report we describe a simple and rapid protocol for reliable quantitation of mitochondrial DNA (mtDNA) mutations, which is basically a modification of the traditional polymerase chain reaction (PCR)/restriction fragment length polymorphism (RFLP) analysis technique. Up to now, the PCR/RFLP method has been of limited use for the accurate determination of ratios of mutant and wild type molecules, largely owing to the formation of heteroduplex molecules by PCR and incompleteness of restriction digestion. In order to overcome this problem, we have introduced a single-step primer extension reaction using Vent(R)(exo-) DNA polymerase and a fluorescence-labeled primer to the standard assay. The labeled homoduplex molecules are then digested with a restriction endonuclease, and the nucleic acids fractionated on an automated DNA sequencer equipped with GENESCAN analysis software. The amount of mutant mtDNA is readily estimated from fluorescence intensities of the wild-type and mutant mtDNA fragments corrected for incomplete digestion as monitored by a homologous control fragment. The accuracy of the improved protocol was determined by constructing standard curves obtained from defined mixtures of genomic DNA containing homoplasmic wild-type and mutant mtDNA. The expected values were obtained, with an observed correlation coefficient of 0.997 and a typical variability of +/-5% between repeated measurements. Further validation of the protocol is provided by the screening of five patients and unaffected subjects carrying the guanine to adenine transition at the nucleotide 3460 of the mitochondrial genome responsible for the mitochondrial disorder of Leber's hereditary optic neuropathy.     

Mitochondrial DNA analysis distinguishes between British populations of the whitefish

The whitefish Coregonus lavaretus is confined to two Scottish lochs and four English and one Welsh lake in the British Isles. Restriction fragment length polymorphisms (RFLPs) in the mitochondrial (mt) DNA have been used to analyse variability within and between populations. The 14 restriction enzymes employed in this study examined approximately 3% of the mt genome and revealed 15 haplotypes among 156 fish. Haplotype diversity within populations was generally low except for the Welsh population where nine haplotypes were found among 30 fish examined. The haplotypes clustered into three distinct groups corresponding to Scottish, English and Welsh populations. No haplotypes were shared among the three groups. Possible alternative explanations for these findings are introgression from another species, stochastic lineage sorting from a polymorphic ancestral gene pool and/or separate colonizations following the last glaciation.     

A point mutation in the mitochondrial tRNA(Leu)(UUR) gene in MELAS (mitochondrial myopathy, encephalopathy, lactic acidosis and stroke-like episodes)

Mitochondrial myopathy, encephalopathy, lactic acidosis and strokelike episode (MELAS) is a major group of heterogeneous mitochondrial disorders. To identify the defective gene, mitochondrial DNA from a patient with MELAS was sequenced by using amplified DNA fragments as sequencing templates. In 14.1 kbp determined out of 16.6 kbp of the whole mitochondrial gene, at least 21 nucleotides were different from those of a control human mitochondrial DNA. One of the substitutions was a transition of A to G in the tRNA(Leu) (UUR) gene at Cambridge nucleotide number 3,243. This nucleotide is conserved not only in many mitochondrial tRNAs but in most cytosolic tRNA molecules. An Apa I restriction site was gained by the substitution of this nucleotide. The Apa I digestion of the amplified DNA fragment revealed that all independent 6 patients had G at nucleotide number 3,243 in their mitochondrial DNAs, but none of 11 control individuals had G at this position. This result strongly suggests that the mutation in the mitochondrial tRNALeu gene causes MELAS.     

MATERNAL INHERITANCE OF THE CHLOROPLAST AND MITOCHONDRIAL GENOMES IN CHEILANTHOID FERNS

Molecular data from the chloroplast genome are being used to reconstruct the phylogeny and revise the problematic taxonomy of the xerically adapted cheilanthoid ferns. Chloroplast DNA based phylogenies trace maternal, paternal, or biparental lineages, depending on the mode of inheritance of the chloroplast genome, and instances of all three modes of inheritance are known in the seed plants. Evidence for biparental and uniparental inheritance in ferns has been presented, but the distinction between maternal and paternal uniparental inheritance has not been rigorously made, and the mode of inheritance in cheilanthoid ferns is completely unknown. Based on a natural hybrid population in the cheilanthoid genus Pellaea in which the maternal and paternal derivations of the hybrid are unambiguously known, restriction fragment length polymorphisms of chloroplast DNA demonstrated simple maternal inheritance of the chloroplast genome. This hybrid complex was also examined for restriction fragment length polymorphisms of its mitochondrial DNA, providing the first direct evidence that the mitochondrial genome in ferns is maternally inherited.     

The nucleotide sequence of the large ribosomal RNA gene and the adjacent tRNA genes from rat mitochondria.

We have sequenced the Eco R(1) fragment D from rat mitochondrial DNA. It contains one third of the tRNA (Val) gene (the remaining part has been sequenced from the 3' end of the Eco R(1) fragment A) the complete gene for the large mt 16S rRNA, the tRNA (Leu) gene and the 5' end of an unidentified reading frame. The mt gene for the large rRNA from rat has been aligned with the homologous genes from mouse and human using graphic computer programs. Hypervariable regions at the center of the molecule and highly conserved regions toward the 3' end have been detected. The mt gene for tRNA Leu is of the conventional type and its primary structure is highly conserved among mammals. The mt gene for tRNA(Val) shows characteristics similar to those of other mt tRNA genes but the degree of homology is lower. Comparative studies confirm that AGA and AGG are read as stop codons in mammalian mitochondria.     

Selection of Daucus carota somatic hybrids using drug resistance markers and characterization of their mitochondrial genomes

Summary Protoplasts from different Daucus carota L. cell strains carrying resistance to glyphosate, 5-methyltryptophan, sodium selenate or selenocystine were fused in three combinations using dextran. Clones were selected for both of the resistances carried by the individual parental strains in medium with both inhibitors. No doubly resistant colonies formed from unfused controls or from protoplasts from each individual parental strain alone. Suspension cultures from the selected clones contained predominantly the additive chromosome numbers of the parental strains. Apparently the four resistances used are expressed dominantly in fusion hybrids. Analysis of mitochondrial DNA showed that recombination occurred in one fusion combination since the mitochondrial DNA in the hybrid cells was different from that of either parent as shown by restriction endonuclease fragment analysis. Mitochondrial DNA in the other two somatic hybrid combinations was parental. Thus, a dominant, nuclear resistance marker system has been developed to select efficiently for somatic hybrids in which mitochondrial DNA recombination can be studied.Abbreviations 2,4-D 2,4-dichlorophenoxyacetic acid - FW fresh weight - Glp Glyphosate - mt mitochondrial - MX Murashige and Skoog (1962) medium containing 0.4 mg/l 2,4-D - 5MT 5-methyltryptophan - MXG MX containing (5% Glucose) - SC selenocystine - SS sodium selenate     

Mitochondrial DNA mutations in diabetes mellitus patients in Chinese Han population

Background and objective

Mutations of mitochondrial DNA are associated with diabetes mellitus (DM). The present case–control study aimed to investigate the mutations of mitochondrial DNA in DM patients of Chinese Han ethnicity.

Methods and results

A total of 770 DM patients and 309 healthy control individuals were enrolled. The mitochondrial DNA was extracted from blood cells and analyzed by the polymerase chain reaction–restriction fragment length polymorphism assay. In the diabetes group, there were 13 (1.69%) individuals carrying the mt3243 A → G mutation while none of the healthy control had this mutation. Though the 14709, 3316, 3394, and 12026 mutation variants were identified in 9, 17, 18 and 28 in DM patients respectively, there were no significant differences compared with control group. And the 3256, 8296, 8344, 8363, 3426 and 12258 mutations were not detected in either group. In the diabetes group, two double mutations were identified: A3243G+T3394C and A3243G+A12026G.

Conclusion

Our data suggested that mitochondrial gene tRNA^Leu(UUR) 3243 A → G mutation may be one risk of prevalence of DM and associated with worse clinical status in Chinese Han population.     

Ageing-associated 5 kb deletion in human liver mitochondrial DNA

Using PCR technique and restriction mapping, we analyzed liver mitochondrial DNA (mtDNA) of 2 stillborn babies and 55 Chinese subjects from 27 to 86 years old and blood cell mtDNA from 20 subjects of various ages. An ageing-associated 4,977-bp deletion was detected between nucleotide position 8,469 and 13,447 (or between 8,482 and 13,460) in the liver mtDNA of older subjects. In the region containing the junction fragment, we observed a 13 bp repeat "ACCTCCCTCACCA". Moreover, the incidence of the deleted mtDNA of each of the study subjects was found to increase with age. The deletion was found in 5 out of 8 patients of the 31-40 age group and 9 out of 11 patients of the 41-50 age group, and in all the patients over 50 years old. The deletion was not observed in either the mtDNA of the liver of the stillbirth or the blood cells of subjects of all the age groups. These results support our previous contention that liver mitochondrial respiratory functions decline with age and the hypothesis that continuous accumulation of mitochondrial DNA mutation is an important contributor to ageing process.     

Mitochondrial DNA polymorphism induced by protoplast fusion in Cruciferae

Summary The mitochondrial genomes of five rapeseed somatic hybrid plants, which combine in a first experimentBrassica napus chloroplasts and a cytoplasmic male sterility trait coming fromRaphanus sativus, and in a second experiment chloroplasts of a triazine resistantB. compestris and a cytoplasmic male sterility trait fromR. sativus, were analyzed by restriction endonucleases. Restriction fragment patterns indicate that these genomes differ from each other and from both parents. The presence of new bands in the somatic hybrid mitochondrial DNA restriction patterns is evidence of mitochondrial recombination in somatic hybrid cells. In both parental and somatic hybrid plants large quantitative variations in a mitochondrial plasmid-like DNA have been observed. Our results suggest that the cytoplasmic support for male sterility is located in the chromosomal mitochondrial DNA instead of the plasmid-like DNA.     

Uniparental Mitochondrial Transmission in the Cultivated Button Mushroom, Agaricus bisporus

A uniparental mitochondrial (mt) transmission pattern has been previously observed in laboratory matings of the cultivated mushroom Agaricus bisporus on petri dishes. In this study, four sets of specific matings were further examined by taking mycelial plugs from the confluent zone of mated homokaryons and inoculating these plugs into rye grain for laboratory fruiting and for fruiting under industrial conditions. Examination of the mt genotype of each individual fruit body for mt-specific restriction fragment length polymorphisms further confirmed that the mt genome was inherited uniparentally. The vegetative radial growth and the fruiting activity of two pairs of intraspecific heterokaryons, each pair carrying the same combination of nuclear genomes but different mt genotypes, were compared. Our results suggested that the mt genotype did not appreciably affect radial growth or fruiting activity. The failure to recover both heterokaryons, each carrying either parental mt genotype in any given cross, therefore clearly indicated that in matings of A. bisporus, the mt genome from one of the parental homokaryons is either selectively excluded in the newly formed heterokaryon or selectively eliminated in the immediate heterokaryotic mitotic progeny of the newly formed heterokaryon.