Recombination between parental mitochondrial DNA following protoplast fusion can occur in a region which normally does not undergo intragenomic recombination in parental plants

Summary A novel restriction fragment, which was not present in either parent's mitochondrial DNA, was cloned from the mitochondrial genome of a somatic hybrid Petunia line. This fragment resulted from interspecific recombination between homologous mitochondrial DNA regions of the parental plants, Petunia line 3704 and line 3688. Hybridization with a cloned Petunia atp9 gene revealed that the regions involved in recombination carry atp9 coding sequences. Intragenomic recombination within the parental mitochondrial genomes was not detected between the atp9 regions which recombined following protoplast fusion.     

Intergenomic recombination of mitochondrial genomes in a somatic hybrid plant

Summary Restriction site polymorphisms between two parental mitochondrial (mt) genomes were used to characterize the novel mt genome present in a somatic hybrid plant. A cosmid clone containing mtDNA restriction fragments characteristic of both parental plant lines was identified in a library constructed from mtDNA of progeny of a somatic hybrid plant. Restriction mapping revealed the location of several restriction fragments derived from each of the parental mt genomes on the same cloned region of somatic hybrid mtDNA. This result is direct evidence that intergenomic recombination at the molecular level occurs in homologous regions of two parental mt genomes combined in the same plant cell by protoplast fusion.     

Inheritance of mitochondrial DNA in sexual crosses and protoplast cell fusions in Lentinula edodes

By using mitochondrial DNA (mtDNA) restriction fragment length polymorphisms (RFLPs) as genetic markers, the modes of mitochondrial inheritance in sexual crosses and protoplast cell fusions of the higher basidiomycete Lentinula edodes were examined. All newly established dikaryons from reciprocal crosses between compatible monokaryons carrying different mtDNA RFLP phenotypes retained mtDNA genotypes from one of the monokaryons, suggesting that mitochondrial inheritance is principally uniparental. In contrast, it was shown that recombinant mtDNA genomes arose in some dikaryons obtained after protoplast cell fusion. Based on these results, a possible mechanism for mitochondrial inheritance in L. edodes is discussed.     

Several different mitochondrial DNA regions are involved in intergenomic recombination in Brassica napus cybrid plants

Summary An important mitochondrial (mt) DNA polymorphism was detected by SalI restriction enzyme analysis in five Brassica napus cybrids plants which combine B. napus chloroplasts and a cytoplasmic male sterility (cms) trait from Raphanus sativus. Novel restriction fragments observed in these cybrids were analysed. One of them was found to be constituted by fragments of both parent mt genomes. Sites involved in rut recombination in cybrids were compared by molecular hybridization to sites supposedly implicated in intragenomic mt recombination in B. oleracea The results indicate that mt recombination events arising through protoplast fusion involve several different rut DNA regions. Some of these regions appeared homologous to regions presumably involved in intragenomic mt recombination in B. oleracea.     

Randomly amplified polymorphic DNAs assess recombination following an induced parasexual cycle in Penicillium roqueforti

Random amplified polymorphic DNAs (RAPDs) were used as a genetic marker system to characterize recombinant strains following the parasexual cycle of Penicillium roqueforti. After protoplast fusion and haploidization of diploid hybrids, segregants characterized by a reassortment of the parental genetic markers displayed specific RAPD fingerprints. The appearance or the loss of RAPD fragments demonstrate that these markers provide an efficient method to analyze recombination and to characterize somatic hybrids.     

Novel mitochondrial genomes in Brassica napus somatic hybrids

Summary The mitochondrial genomes of nine male-fertile and two Ogura cytoplasmic male-sterile (cms) Brassica napus somatic hybrids were probed with 46 mitochondrial DNA fragments. The distribution of information obtained from each fusion partner was not random. Several regions, including the coxI gene and a major recombination repeat sequence, were always derived from the Brassica campestris fusion partner, and some regions were always derived from the Ogura mitochondrial genome. Novel fragments occurred in seven distinct regions. Some of the rearrangement breakpoints were located near the evolutionary breakpoints relating the mitochondrial genomes of the Brassica species. The sizes of the mitochondrial genomes in the somatic hybrids ranged from 224.8 to 285.3 kb. A direct correlation between a specific gene and the cms phenotype was not observed; however, a possible cms-associated region was identified. It corresponds to a region that was identified through analysis of fertile revertants from a cms B. napus cybrid.     

Cytoplasmic male sterility is associated with large deletions in the mitochondrial DNA of two Nicotiana sylvestris protoclones

Summary Two cytoplasmic male-sterile plants (CMSI and CMSII) were obtained by protoplast culture in Nicotiana sylvestris. Both plants showed large deletions (up to 50 kb) in their mitochondrial DNA. Restriction maps of the reorganized regions suggested that the deletions occurred via two homologous recombination events (rec. 1 and rec. 2) in the parental mitochondrial genome. With the exception of nad5, no mitochondrial DNA polymorphism could be detected between parental and CMS lines using different heterologous genes probes. A sequence homologous to the Oenothera nad5 mitochondrial gene was located close to the CMSI-specific rec. 2 region. Moreover, a cDNA probe corresponding to total mitochondrial RNA from the parent line was found to hybridize to mitochondrial DNA fragments involved in the rec. 1 event common to both CMS lines, suggesting that rec. 1 lies in a transcribed region. Cytoplasmic male sterility in the Nicotiana sylvestris CMS mutants could be due either to gene deletion or to a regulatory effect of such a deletion on mitochondrial gene expression, rather than to the presence of specific polypeptides as has been shown in the T cytoplasm of maize, or in CMS Petunia.     

The organization of mitochondrial atp6 gene region in male fertile and CMS lines of pepper (Capsicum annuum L.)

The mitochondrial atp6 gene in male fertile (N) and CMS (S) pepper has previously been compared and was found to be present in two copies (Kim et al. in J Kor Soc Hort Sci 42:121–127 2001). In the current study, these atp6 copies were amplified by an inverse PCR technique, and the coding region as well as the 5′ and 3′ flanking regions were sequenced. The atp6 copies in CMS pepper were detected as one intact gene and one pseudogene, truncated at the 3′ coding region. When the atp6 genes in pepper were compared to other plant species, pepper, potato, and petunia all possessed a sequence of 12 identical amino acids at the 3′ extended region, which was considered a hallmark of the Solanaceae family. Northern blot analysis showed differences in mRNA band patterns between CMS and restorer lines, indicating that atp6 gene is one of the candidates for CMS in pepper. GenBank accession number: DQ126682 (atp6-1 genomic sequence common to fertile and CMS pepper), DQ126681 (Fertile atp6-2 genomic sequence), DQ126680 (CMS pseudo-atp6-2 genomic sequence)     

Extensive mitochondrial DNA variation in somatic tissue cultures initiated from wheat immature embryos

Summary Wheat mitochondria) DNA has been isolated from callus cultures initiated from both immature embryos and the corresponding parental cultivar. A Sall restriction pattern study has shown that the organization of callus culture mitochondria) DNA underwent extensive change, characterized by either the disappearance or the decrease in the relative stoichiometry of several restriction bands. Hybridization of labelled mitochondrial fragments obtained from a recombinant cosmid library to Southern blots of callus and parental line restricted mitochondria) DNAs has shown that a fraction of the mitochondria) genome was lost in callus cultures. Data from a Sall + HindIII restriction map of a defined part of the wheat mitochondria) genome concerned with some of these variations strongly suggest that the observed variations correspond to the disappearance of at least one mitochondria) DNA subgenomic molecule in callus cultures.Abbreviations mtDNA mitochondrial DNA - cpDNA chloroplast DNA - rRNA ribosomal RNA - mRNA messenger RNA - kb kilobase - cv cultivar     

Mitochondrial genetics of Coprinus: Recombination of mitochondrial genomes

Summary The formation of the sexual mycelium or dikaryon in the basidiomycete Coprinus cinereus involves exchange and migration of nuclei without accompanying exchange of mitochondria. The dikaryotic growth which appears around the periphery of mated monokaryons has exclusively the mitochondrial genome of the recipient cells. Recombination of mitochondrial genomes is not, however, precluded during dikaryosis. Using monokaryons with different mitochondrial gene mutations, [acu-10] causing cytochrome aa ₃ deficiency and[cap-1.1] conferring resistance to chloramphenicol, it was shown that recombinant mitochondria arise in the zone of contact of mated monokaryons.     

The complete DNA sequence of the mitochondrial genome of the dermatophyte fungus Epidermophyton floccosum

We report here the complete nucleotide sequence of the 30.9-kb mitochondrial genome of the dermatophyte fungus Epidermophyton floccosum. All genes are encoded on the same DNA strand and include seven subunits of the reduced nicotinamide adenine dinucleotide ubiquinone oxireductase (nad1, nad2, nad3, nad4, nad4L, nad5, and nad6), three subunits of cytochrome oxidase (cox1, cox2, and cox3), apocytochrome b (cob), three subunits of ATP synthase (atp6, atp8, and atp9), the small and large ribosomal RNAs (rns and rnl), and 25 tRNAs. A ribosomal protein gene (rps5) is present as an intronic ORF in the large ribosomal subunit. The genes coding for cob and cox1 carry one intron and nad5 carries two introns with ORFs. The mtDNA of E. floccosum has the same gene order as Trichophyton rubrum mtDNA, with the exception of some tRNA genes. Maximum likelihood phylogenetic analysis confirms T. rubrum as a close relative of E. floccosum. This is the first complete mitochondrial sequence of a species of the order Onygenales. This sequence is available under GenBank accession number AY916130.     

Biased inheritance of optional insertions following mitochondrial genome recombination in the basidiomycete fungus Coprinus cinereuss

Summary Two mitochondrial genomes of Coprinus cinereus, H and J, were found to have alternative 1.23 kb insertions. Using the Neurospora crassa cytochrome oxidase-1 (co-1) gene as a probe, the J insertion site was shown to be located within the Coprinus co-1 gene, whereas the H insertion was some 2 kb distant. The insertions showed biased inheritance following mitochondrial genome recombination. Recombination between H and J genomes was detected using the mitochondrial gene mutations acu-10, which causes a cytochrome oxidase defect, and cap-1, which confers chloramphenicol resistance. Fourteen of fifteen independently derived recombinants for these two genes were shown to have both DNA insertions. In a second series of H x J crosses, intragenic recombination between different cap-1 alleles was detected. These mutations are assumed to be in the large ribosomal RNA gene some 6 kb distant from the nearest insertion site. Each of eight independently derived cap-1 ⁺ recombinants had both DNA insertions. Despite their similar size and similar behaviour following recombination the insertions do not share extensive sequence homology.     

A model for the rapid vegetative segregation of multiple chloroplast genomes in Chlamydomonas: Assumptions and predictions of the model

Summary Physical evidence indicates that the chloroplast DNA of Chlamydomonas reinhardtii is composed of approximately 75 copies of a small unique sequence. Genetic analysis of zygotes biparental for chloroplast genes shows rapid vegetative segregation of parental chloroplast alleles. Zygote clones composed entirely of homoplasmic progeny cells predominate within 10–20 post-mating generations. A model is proposed here which reconciles the high multiplicity of chloroplast genes with their rapid vegetative segregation rates. Clustering of genomes into a small number of discrete areas (nucleoids) within the chloroplast reduces the effective number of segregating units. A non-random distribution of nucleoids to daughter cells, dictated solely by the spatial arrangement of parental nucleoids with respect to the plane of chloroplast division, further increases the rate of segregation from heteroplasmic cells. Recombination between parental chloroplast genomes is viewed as an indication of nucleoid fusion, and can account for differences in the patterns and rates of segregation at different gene loci. Within such fused nucleoids, clustering of parental genomes and a non-random distribution, again based solely on physical positioning of the genomes, to daughter nucleoids, could act to promote rapid genetic purification of heteroplasmic nucleoids. The effects of biased parental nucleoid ratios, and of potentially unequal nucleoid distributions to daughter chloroplasts are also discussed with respect to observed rates and patterns of chloroplast gene segregation.     

A truncated recombination repeat in the mitochondrial genome of a Petunia CMS line

Repeated sequences known as recombination repeats are present in the majority of plant mitochondrial genomes. Two recombination repeat sequences from Petunia have been analyzed. The two repeats are virtually identical over 1.42 kb. One of the repeats is truncated and is likely to have arisen from a rare recombination event in the full-length repeat. Two sequence-blocks within the Petunia repeat are highly similar to sequences in the 5 flank of several plant mitochondrial genes. No sequence motifs are shared by the Petunia repeat and other sequenced plant mitochondrial recombination repeats, suggesting that the recombination occurs by an homologous, rather than a site-specific, mechanism.     

Preferential amplification of mitochondrial DNA fragments in somatic hybrids of the Gramineae

Summary Somatic hybrid cell lines of Pennisetum americanum + Panicum maximum, and of Pennisetum americanum + Saccharum officinarum display unique mitochondrial DNA (mtDNA) restriction patterns suggestive of mitochondrial fusion and recombination. Apparent recombinant fragments of the hybrids were recovered, cloned, and hybridized to parental and somatic hybrid mtDNAs. In each somatic hybrid, novel fragments were found to be present at low copy number in one or both of the parental mtDNAs, and amplified 15–30 times in the hybrids. In pearl millet-sugarcane somatic hybrid cells, the amplification does not appear to involve enhanced recombination. The presumably amplified restriction fragment of the pearl millet-Guinea grass somatic hybrids is a junction fragment of a repeat, present in low copy number in both parents, and in high copy number in the hybrids. Thus protoplast and probable mitochondrial fusion results in a marked shift in the direction of mtDNA recombination events. We conclude that amplification of parental mtDNA fragments is a common event in somatic hybrid cells of these Gramineae.     

Constitutive homologous recombination between mitochondrial DNA and a linear mitochondrial plasmid in Physarum polycephalum

Summary In one particular myxamoebal strain (NG7; mF⁺) of Physarum polycephalum, a linear mitochondrial plasmid (mF plasmid) which promotes mitochondrial fusion has been identified. A mating between mF^- strains, that do not carry the mF plasmid, resulted in uniparental inheritance of the mtDNA. In matings between mF⁺ and mF^- strains a recombination occurred between the mtDNA and the mF plasmid, and recombinant mtDNA was generated with the end of the mF plasmid as its ends. The DNA sequences of the recombination site in the mtDNA and the mF plasmid, and of the recombinant mtDNA, revealed that the mF plasmid had a 473-bp sequence that was identical to, but slightly shorter than, a 477-bp sequence of the mtDNA. This so-called identical sequence was found at the junction between unique sequences of the mF plasmid and the mtDNA in the recombinant mtDNA. Thus, the recombination between the mtDNA and the mF plasmid was due to reciprocal crossing-over at the identical sequence.