Characterization and sequence of lupin mitochondrial plasmid-like DNA

Summary Two minicircular DNAs of 1.2 kb (K1) and 1.4 kb (K2) were found in mitochondria of fertile lupin (Lupinus albus). The plasmid-like DNA, K1, was cloned, labelled and hybridized with mitochondrial DNA from three different species of lupin. We have found no evidence for integrated copies of K1 in any of the mitochondrial genomes probed in this study. No sequence homology between plasmid K1 and K2, and no homology of either with chloroplast DNA, has been detected. The K1 DNA is two-fold more abundant than the K2 DNA and about seven-fold more abundant than a unique segment of the mtDNA. The entire nucleotide sequence of the K1 DNA has been determined. This sequence exibits a 340 base pair region with highly organized repeats. The sequence of K1 shows no substantial homology with sequence of other mitochondrial plasmids of higher plants.     

Differential changes in copy numbers of rice mitochondrial plasmid-like DNAs and main mitochondrial genomic DNAs that depend on temperature

The mitochondria of rice contain four kinds of circular plasmid-like DNAs, namely, B1, B2, B3 and B4, in addition to the main mitochondrial genomic DNAs. In order to examine the genetic stability of mitochondrial plasmid-like DNAs, changes in the amounts of plasmid-like DNAs and main mitochondrial genomic DNAs were analyzed in calli that had been cultured at various temperatures. The observed effect of temperature on the levels of plasmid-like DNAs was larger than that on the main mitochondrial genomic DNAs. A significant reduction in the copy number of plasmid-like DNAs was detected in calli cultured at 35 °C, as compared to 20 °C, 25 °C and 30 °C. The effect of temperature on DNA synthesis in isolated mitochondria was also analyzed. Synthesis of the main mitochondrial genomic DNAs occurred at all the temperatures examined, whereas synthesis of plasmid-like DNAs occurred only over a limited range of temperatures. The results of both in vivo and in vitro analyses suggest that plasmid-like DNAs are less stably maintained than the main mitochondrial genomic DNAs, which is consistent with the notion that the transmission of mitochondrial plasmid-like DNAs from one generation to the next may be unstable under unusual conditions. Received: 17 February 1997 / 24 April 1998     

Analysis of nuclear sequences homologous to the B4 plasmid-like DNA of rice mitochondria; evidence for sequence transfer from mitochondria to nuclei

Summary Nuclear sequences homologous to the plasmid-like DNA, B4, were analyzed in the Japonica rice variety, Fujiminori. Homologous sequences existed at several positions in the nuclear genome, but each contained only a portion of the B4 sequence. It was impossible to reconstruct the entire sequence of B4 even by collating all the homologous sequences. Overlaps between some of the B4 sequences present in the nuclear genome resulted in parts of the sequence being represented more than once. These features indicate that nuclear sequences homologous to B4 are not the origin of B4 and that they have been transferred from mitochondria and integrated into the nuclear genome. Five other foreign sequences originating in the chloroplast or mitochondrial genome were found within 1 kb of the B4-homologous sequences. Structural analysis is consistent with the hypothesis that the DNA sequences were transfered via RNA.     

Recombination of yeast mitochondrial DNA does not require mitochondrial protein synthesis

Summary Mitochondrial genes recombine extensively in yeast zygotes. In heteropolar crosses (⁺ × ^–) in which the ^– allele consists of an insertion, there is preferential recovery of ⁺ and markers closely linked to it. This polarity has been postulated to be a consequence of one-way gene conversion beginning at the locus (- to ⁺). We have shown that most or all mitochondrial recombination in homopolar and heteropolar crosses, and the phenomenon of polarity itself, does not require products of protein synthesis on mitochondrial ribosomes. (i) Yeast strains were grown and mated, and the zygotes plated and grown, on glucose medium with erythromycin to inhibit and dilute out the products of mitochondrial protein synthesis. Recombination frequencies and polarity at the cap1 and oli1 loci were normal compared to controls in some homopolar (⁺ × ^–) and heteropolar crosses. Apparent changes in recombination frequencies and polarity were seen in other crosses but are attributable to locus-specific petite induction by erythromycin. (ii) Homopolar (⁺ × ⁺) and heteropolar crosses between pairs of petite mutants retaining the cap1, ery1, and oli1 loci also showed nearly normal recombination at the cap1 and oli1 loci, as determined by test-crossing the petite progeny. The petite mutants and zygotes cannot do mitochondria) protein synthesis. These results support the recombinational model of polarity.     

Evolutionary changes in the structures of the cox2 and atp6 loci in the mitochondrial genome of soybean involving recombination across small interspersed sequences

Mitochondrial DNA (mtDNA) fragments that contained cox2 or atp6 loci were cloned from three accessions of wild soybean (Glycine soja) in order to understand the evolutionary changes of mitochondrial genomes in the genus Glycine subgenus Soja. Cox2 was cloned as a single configuration, while atp6 was cloned as either one or two configurations from each accession. Structural variations were detected in the 5′ upstream region of cox2 and in both the 5′ upstream and 3′ downstream regions of atp6. These variations appeared to be the results of recombination events. A comparison of the mtDNA fragments previously cloned from a cultivated soybean (G. max) and a wild soybean revealed various sites of recombination, as well as various combinations of the 5′ and 3′ regions, at the cox2 and atp6 loci. Some of the cloned fragments were found to contain a set of repeated sequences, namely 299-bp and 23-bp repeats in the 5′ region of cox2 or atp6, which were interspersed in the mitochondrial genome in the subgenus Soja. Recombination events involving the 299-bp or 23-bp repeated sequences were shown to account for the generation of structural variations in the 5′ regions of these loci. Received: 21 March / 4 August 1998     

Small interspersed sequences that serve as recombination sites at the cox2 and atp6 loci in the mitochondrial genome of soybean are widely distributed in higher plants

Mitochondrial DNA (mtDNA) fragments that contain cox2 and atp6 were cloned from a wild soybean (Glycine soja, accession `B09002') and from a cultivated soybean (G. max, `Harosoy'). Comparison of these DNAs revealed that two sets of repeated sequences, namely, 299 bp and 23 bp, were present in the 5′ regions of cox2 and atp6. The 299-bp and 23-bp repeats were present close to each other on the 5′ flanking region and the 5′ part of the coding region of cox2 in both `Harosoy' and `B09002', as well as on the 5′ flanking region of atp6 in `Harosoy', while these two repeats were separated by a 706-bp nucleotide sequence that contained a truncated sequence of nad3 at the 5′ flanking region of atp6 in `B09002'. The mtDNA configurations upstream from atp6 and cox2 found in `Harosoy' appeared to have been generated from configurations of cox2 and atp6 found in `B09002' via recombination across the 299-bp or 23-bp repeated sequences, or vice versa, in the mitochondrial genome of the hypothetical progenitor of these plants. The 299-bp sequence was found to be interspersed in the mitochondrial genome. Eight loci were identified that include mtDNA configurations that are inter-convertible with each other via recombination across this sequence in `B09002'. Various loci on the mitochondrial genomes of higher plants that harbor segments of the 299-bp repeats in Glycine were identified. Received: 16 August / 15 December 1997     

Interaction between mitochondrial DNA and mitochondrial plasmids in Claviceps purpurea: analysis of plasmid-homologous sequences upstream of the IrRNA-gene

Homology of two linear, mitochondrial (mt) Claviceps purpurea plasmids, pC1K1 and pClT5, to the upstream region of the large ribosomal RNA gene in the mtDNA of three strains (W3, T5 and K) has been investigated in detail to explore the widespread phenomenon of homology between mt plasmids and mtDNA in C. purpurea. Sequence comparison indicates that recombination between free plasmids and mtDNA is the cause of the observed homology. The process is similar to the integration of the structurally related adenoviruses into the mammalian genome. As in other fungi, palindromic sequences seem to be involved in this mitochondrial recombination process.     

Maize mitochondrial DNA rearrangements between the normal type,the Texas male sterile cytoplasm,and a fertile revertant cms-T regenerated plant

Summary The maize mitochondrial DNA (mtDNA) from the cytoplasmic male sterile type T (cms-T) contains a 6.6 kb XhoI fragment not found in the normal type (N) or the fertile revertant (V3). Analysis of the fragment in cms-T mtDNA and homologous regions in N and V3 mtDNAs reveals that a number of events are necessary to explain the formation of the 6.6 kb XhoI fragment in T mtDNA and its subsequent loss in V3 mtDNA. This includes the formation and the loss of a 4 kb repeat and various recombinational events. It is interesting to note that a recombinational event that has occurred in the fertile revertant genome reconstitutes a sequence arrangement identical to one found in the normal genome.     

Intramolecular cross-overs generate deleted mitochondrial DNA molecules in Podospora anserina

The unavoidable senescence process that limits the vegetative growth of Podospora anserina is always associated with an accumulation of various classes of circular, tandemly arranged, defective mitochondrial DNA molecules (senDNAs). The monomers of the senDNAs belonging to the so-called β class share a common core, but differ in both their length and termini. To understand the mechanism leading to their formation, we have determined the junction sequence of 36 senDNA β monomers present in various senescent cultures. In most cases, we observe that: (1) short direct repeats precisely bound the senDNA β termini and (2) one copy of the repeats is retained in the senDNA sequence. Moreover, PCR analysis of the mitochondrial DNA of some of the senescent cultures, has allowed us to detect another genome which is exactly lacking the sequence of the senDNA β found in the culture. These results demonstrate that an intramolecular unequal cross-over occurring between short direct repeats can generate deleted mtDNA molecules in P. anserina. In addition, the polymorphism displayed by one pair of repeats allows us to establish that this cross-over may be associated with a short conversion tract spanning a few (about 15) nucleotides. Received: 16 May / 11 November 1996     

Recombination of mitochondrial DNA without selection pressure among compatible strains of the Aspergillus niger species aggregate

Previous mitochondrial transmission experiments between oligomycin-resistant and oligomycin-sensitive incompatible strains of the A. niger aggregate bearing various mtDNA RFLP profiles resulted in a great variety of mitochondrial recombinants under selection pressure. Apart from the recombinant mtDNAs, resistant clones harbouring unchanged RFLP profiles of resistant donor mtDNAs with the recipient nuclear backgrounds were rarely isolated. These strains were anastomosed with nuclearly isogenic oligomycin-sensitive recipient partners and the mitochondria of the resulting progeny were examined under non-selective conditions. These experiments provide insights into events which are possibly similar to those occurring in nature. The heterokaryons obtained formed both oligomycin-resistant and -sensitive sectors, most of which were found to be homoplasmons. Progenies harbouring oligomycin-resistant and -sensitive mtDNAs may originate either from individual recombination events or be due to parental segregation. MtDNA recombination might take place in the heterokaryons without selection by oligomycin. The most frequent recombinant types of mtDNA RFLP profiles were indistinguishable from those recombinant mtDNAs which were frequently obtained under selection pressure from directed transfer experiments between incompatible strains. We present evidence that mixed mitochondrial populations may influence the compatibility reactions in the presence of an isogenic nuclear background, that recombination may take place without selection pressure, and that the process does not require specific nuclear sequences of both parental strains. Received: 20 October 1997 / 13 January 1998     

Heteroplasmy as a common state of mitochondrial genetic information in plants and animals

Plant and animal mitochondrial genomes, although quite distinct in size, structure, expression and evolutionary dynamics both may exhibit the state of heteroplasmy—the presence of more than one type of mitochondrial genome in an organism. This review is focused on heteroplasmy in plants, but we also highlight the most striking similarities and differences between plant and animal heteroplasmy. First we summarize the information on heteroplasmy generation and methods of its detection. Then we describe examples of quantitative changes in heteroplasmic populations of mitochondrial DNA (mtDNA) and consequences of such events. We also summarize the current knowledge about transmission and somatic segregation of heteroplasmy in plants and animals. Finally, factors which influence the stoichiometry of heteroplasmic mtDNA variants are discussed. Despite the apparent differences between the plant and animal heteroplasmy, the observed similarities allow one to conclude that this condition must play an important role in the mitochondrial biology of living organisms.     

High frequency transfer of species specific mitochondrial DNA sequences between members of the aspergillaceae

Summary The mitochondrial genome of Aspergillus nidulans var. echinulatus is approximately 20% larger than that of the closely related species Aspergillus nidulans (Eidam) Winter. Restriction enzyme mapping and electron microscopy has revealed that the size difference is due to the presence of six inserted sequences in the former. With the exception of a small number of species specific restriction sites and the six insertions/deletions, the two mitochondrial genomes appear identical. Protoplast fusion between the two species followed by selection of extranuclear drug resistance markers resulted in the isolation of recombinant mitochondrial genomes in an A. nid. var. echinulatus background. Restriction maps of the hybrid genomes indicated that three of the additional sequences found in A. nid. var. echinulatus could be transferred to the A. nidulans nuclear background without loss or detectable alteration. The nature of the additional mitochondrial DNA and high frequency transfer of certain species specific sequences is discussed with reference to studies in yeast and Neurospora crassa.     

Maintenance of chloroplast-derived sequences in the mitochondrial DNA of Gramineae

Evidence for the transfer of DNA from the chloroplast to the mitochondrion has been reported in many higher plants and, in most cases, the transferred chloroplast genes do not have the ability to encode functional products as a consequence of base substitutions and/or multiple rearrangements. We reported previously that the sequence of one end of a chloroplast-derived (ct-derived) fragment of DNA that contained the rps19 and trnH genes has been maintained in most gramineous plants and that its presence seems to be correlated with gene expression in this region. In the present study, we have investigated whether or not the ct-derived sequences in mitochondrial DNA (mtDNA) from some gramineous plants and species of Oryza are conserved, and whether or not such conservation is related to gene expression in these regions. We identified two junctions between ct-derived and mitochondrial sequences that were conserved among some gramineous plants. Around these regions, we found a ct-derived gene for tRNA and the promoter of a mitochondrial gene on the ct-derived sequences, respectively, and these regions were transcribed through the junctions. This result indicates that the junctions and/or regions that are transcribed and functional in mitochondria have been strongly conserved and maintained during their evolution. In Oryza, some junctions between ct-derived and mitochondrial sequences were conserved and other junctions were not. These variations seem to have been caused by deletions and/or rearrangements, and appear to be specific to the type of genome. In the case of Oryza, the timing of deletions and/or rearrangements of ct-derived sequences is likely to have coincided with the divergence of the various genome types. Received: 24 July / 13 August 1997     

Single-strand scissions of nuclear yeast DNA occur without meiotic recombination

Summary In meiotic cells of Saccharomyces cerevisiae, reduction in molecular weights of DNA in alkaline sucrose gradients is observed concomittantly with premeiotic DNA replication and with commitment to recombination. Following the completion of the latter processes, higher molecular weights are obtained. These single-stranded breaks are found in both old and newly synthesised strands. Similar scissions in DNA are also found in a temperature-sensitive mutant (cdc40/cdc40), which does not undergo commitment to recombination at the restrictive temperature, and in vegetative wild type cells that were previously exposed to sporulation medium. The suggestion that these scissions are the physical manifestation of commitment to recombination is therefore rejected.     

Properties of the circular plasmid-like DNA,B4, from mitochondria of cytoplasmic male-sterile rice

Summary The plasmid-like DNA, B4, consisting of 969 base pairs (bp), was isolated from mitochondria of the cytoplasmic male-sterile rice, A-58 CMS. Molecular clones containing the complete B4 sequence were constructed and used in Southern hybridization to probe mitochondrial and nuclear genomes. No evidence was found for the existence of integrated copies of B4 in the main mitochondrial genomes of either the male-sterile or fertile rice. Sequences homologous to B4, however, were found in the rice nuclear genome. The complete B4 nucleotide sequence was determined, and a sequence homologous to B4 was found in the 1.9 kbp plasmid-like DNA of maize.     

Partial mitochondrial DNA sequence of the crustaceanDaphnia pulex

A 3667-base pair (bp) fragment of the mitochondrial genome of the crustaceanDaphnia pulex has been sequenced and found to contain the complete genes for the small subunit ribosomal RNA, ND2, seven tRNAs and the control region. This organization is identical to that found inDrosophila yakuba mtDNA yetD. pulex mtDNA exhibits several unique features when compared to other mitochondrial sequences. The sequenced fragment is only 62.6% A+T which is much lower than that of any other arthropod mtDNA sequenced to date.D. pulex mtDNA also exhibits length conservation having shorter coding and non-coding regions. The putative control region is 689 bp in length and includes a sequence that has the potential to fold into a hairpin structure with a perfect 20-bp pair stem and a 22-base loop.