DNA sequence and transcription of a DNA minicircle isolated from male-fertile sugar beet mitochondria

High-fidelity (repeat) consensus sequences from short reads using combined read clustering and assembly

BACKGROUND

Despite the many cheap and fast ways to generate genomic data, good and exact genome assembly is still a problem, with especially the repeats being vastly underrepresented and often misassembled. As short reads in low coverage are already sufficient to represent the repeat landscape of any given genome, many read cluster algorithms were brought forward that provide repeat identification and classification. But how can trustworthy, reliable and representative repeat consensuses be derived from unassembled genomes?

RESULTS

Here, we combine methods from repeat identification and genome assembly to derive these robust consensuses. We test several use cases, such as (1) consensus building from clustered short reads of non-model genomes, (2) from genome-wide amplification setups, and (3) specific repeat-centred questions, such as the linked vs. unlinked arrangement of ribosomal genes. In all our use cases, the derived consensuses are robust and representative. To evaluate overall performance, we compare our high-fidelity repeat consensuses to RepeatExplorer2-derived contigs and check, if they represent real transposable elements as found in long reads. Our results demonstrate that it is possible to generate useful, reliable and trustworthy consensuses from short reads by a combination from read cluster and genome assembly methods in an automatable way.

CONCLUSION

We anticipate that our workflow opens the way towards more efficient and less manual repeat characterization and annotation, benefitting all genome studies, but especially those of non-model organisms.

ECCsplorer: a pipeline to detect extrachromosomal circular DNA (eccDNA) from next-generation sequencing data

Background

Extrachromosomal circular DNAs (eccDNAs) are ring-like DNA structures physically separated from the chromosomes with 100 bp to several megabasepairs in size. Apart from carrying tandemly repeated DNA, eccDNAs may also harbor extra copies of genes or recently activated transposable elements. As eccDNAs occur in all eukaryotes investigated so far and likely play roles in stress, cancer, and aging, they have been prime targets in recent research—with their investigation limited by the scarcity of computational tools.

Results

Here, we present the ECCsplorer, a bioinformatics pipeline to detect eccDNAs in any kind of organism or tissue using next-generation sequencing techniques. Following Illumina-sequencing of amplified circular DNA (circSeq), the ECCsplorer enables an easy and automated discovery of eccDNA candidates. The data analysis encompasses two major procedures: first, read mapping to the reference genome allows the detection of informative read distributions including high coverage, discordant mapping, and split reads. Second, reference-free comparison of read clusters from amplified eccDNA against control sample data reveals specifically enriched DNA circles. Both software parts can be run separately or jointly, depending on the individual aim or data availability. To illustrate the wide applicability of our approach, we analyzed semi-artificial and published circSeq data from the model organisms Homo sapiens and Arabidopsis thaliana, and generated circSeq reads from the non-model crop plant Beta vulgaris. We clearly identified eccDNA candidates from all datasets, with and without reference genomes. The ECCsplorer pipeline specifically detected mitochondrial mini-circles and retrotransposon activation, showcasing the ECCsplorer’s sensitivity and specificity.

Conclusion

The ECCsplorer (available online at https://github.com/crimBubble/ECCsplorer) is a bioinformatics pipeline to detect eccDNAs in any kind of organism or tissue using next-generation sequencing data. The derived eccDNA targets are valuable for a wide range of downstream investigations—from analysis of cancer-related eccDNAs over organelle genomics to identification of active transposable elements.

Supplementary Information

The online version contains supplementary material available at 10.1186/s12859-021-04545-2.

Mitochondrial plasmids of sugar beet amplified via rolling circle method detected during curtovirus screening

Crops of sugar beet have been considerably impaired by infection with Beet curly top virus (BCTV) during the past decades. Quick and reliable diagnostic techniques are therefore desirable to detect this circular single-stranded DNA-containing geminivirus. Techniques combining either tissue printing or blot hybridization, or rolling circle amplification (RCA) and restriction fragment length polymorphism (RFLP) were compared. Although they easily detected BCTV with certainty, both exhibited apparent false positive results which have been scrutinized in closer detail. Uninfected control plants revealed unspecific signals due to probe attachment on tissue blots, and dominant fragment patterns upon RCA/RFLP which did not hybridize with BCTV-specific probes. Cloning and sequencing of these DNA fragments showed that they were amplified from mitochondrial plasmids. Examination of their genome structure revealed no relationship with geminiviruses or their satellites.

The plant mitochondrial genome: homologous recombination as a mechanism for generating heterogeneity

The mitochondrial genomes of higher plants are among the largest and most complex organelle genomes described. They are generally multicircular or partly linear; in some species, extrachromosomal plasmids are present. It is proposed that inter- and intramolecular homologous recombination can account for the diversity of the observed genome organizations. The ability of mitochondria to fuse establishes a panmictic mitochondrial DNA population which is in recombinational equilibrium. It is suggested that this suppresses the base mutation rate, and unequal partitioning of the cytoplasm during cell division can lead to the rapid evolution of mitochondrial genome structure. This contrasts with the observed rates of base-sequence and genome evolution in chloroplasts. This difference can be accounted for solely by the inability of chloroplasts to fuse, thereby preventing chloroplast genome panmixis.

Preference of the recombination sites involved in the formation of extrachromosomal copies of the human alphoid Sau3A repeat family

The human alphoid Sau3A repetitive family DNA is one of the DNA species that are actively amplified to form extrachromosomal circular DNA in several cell lines. The circularization takes place between two of the five approximately 170 bp subunits with an average of 73.1% homology as well as between identical subunits. To investigate the nature of the recombination reaction, we cloned and analyzed the subunits containing recombination junctions. Analysis of a total of 68 junctions revealed that recombination had occurred preferentially at four positions 10-25 (A), 40-50 (B), 85-90 (C) and 135-160 (D) in the 170bp subunit structure. Two regions (B and C) were overlapped with the regions with higher homology between subunits, while other two regions (A and D) cannot be explained solely by the regional homology between the subunits. These regions were located at both junctions of the nucleosomal and the linker region, and overlapped with the binding motifs for alpha protein and CENP-B. Approximately 90% of the recombination occurred between the subunits located next but one (+/- 2 shift), although the frequency of recombination between the adjoining subunits (+/- 1 shift) was approximately 10%.

Characterization of two minicircular plasmid-like DNAs isolated from date-palm mitochondria

We report here the identification and characterization of two minicircular plasmid-like DNAs isolated from mitochondria of a moroccan date-palm variety. Both molecules were cloned and used as probes in Southern analyses of mitochondrial and total-cellular DNA. Evidence was obtained that these plasmid-like DNAs cross-hybridized but did not show any homology to nuclear, chloroplastic, or main mitochondrial genomes. Sequence analysis revealed that both minicircles, 1,346- and 1,160-bp long, share several stretches of homology, the most important consisting of three identical clusters of lengths 42, 47 and 38 bp. In contrast, no major homology was observed with the other higher-plant plasmid-like DNAs reported so far. Sequence analysis also revealed the presence, in the same strand of one of the minicircles, of two open reading frames potentially encoding proteins 89 and 86 amino acids in length. Interestingly, Northern analyses, using single strands of each minicircle as probes, showed the presence of two transcripts hybridizing only with the strand bearing these two open reading frames. However, computer-assisted comparison of the predicted polypeptide sequences with a protein-sequence library failed to detect any significant homology to known sequences.

The sugar beet mitochondrial gene for the ATPase alpha-subunit: sequence, transcription and rearrangements in cytoplasmic male-sterile plants

We have characterized the mitochondrial atpA (the alpha subunit of F1-ATPase) gene from male-fertile cytoplasm (cv TK81-0) of sugar beet. The gene is 1518-bp long and encodes a polypeptide of 506 amino acids. The atpA mRNA sequence is modified by three C-to-U RNA editing events, all of which alter the encoded protein sequences. In order to examine the genome organization of the atpA locus in cytoplasmic male-sterile (CMS) sugar beet, atpA-containing clones were isolated from Owen CMS (TK81-MS) and a different source of CMS [I-12CMS(2)] cytoplasm respectively. The sequences of the atpA coding region from TK81-MS and I-12CMS(2) are identical to each other and to the corresponding TK81-0 sequence. However, the TK81-0 and TK81-MS loci diverge completely 47 bp upstream of the initiation codon, resulting in different 5' transcript termini for the two genes. On the other hand, the point of divergence between the TK81-0 and I-12CMS(2) atpA genes was found to occur after 393 bp 3' to the TAA stop codon. Our results also show the 3'-flanking sequences of I-12CMS(2) atpA to be present elsewhere in the mitochondrial genomes of TK81-0, TK81-MS and I-12CMS(2), suggesting the possible involvement of these repeated DNA elements in the sequence rearrangements.

Rearrangements in sugar beet mitochondrial DNA induced by cell suspension, callus cultures and regeneration

Structural alterations in mitochondrial DNAs (mtDNAs) from a plant of a sterile sugar beet line, callus derived from it, suspension-cultured cells and plants regenerated from the callus were studied. BamHI restriction analysis revealed that structural alterations between the mtDNAs of the callus and the control plant had occurred. Multiple rearrangements were also demonstrated in the mtDNA from the suspension culture, of which some were similar to those appearing in the callus, and others had arisen de novo. Rearrangements were also identified by means of blot hybridization of BamHI-digested mtDNA from suspension-cultured cells with the genes encoding subunit II of cytochrome oxidase (cox II) and subunit 1 of NADH-dehydrogenase (Nd1). No alterations were observed in the mitochondrial genome of the callus and regenerants. The location of the genes for the α-subunit of F1-ATPase (atpA) and apocytochrome b (cob) in the mtDNA remained unchanged.Our salient finding was of a plant with an altered mitochondrial genome as judged by EcoRI and BamHI restriction analysis. This exceptional plant had retained the sterile phenotype like all of the other regenerants and the parent. The set of plasmid-like molecules of mtDNA remained the same as that in the control plant and in all of the regenerants, callus and suspension-cultured cells. The only type of plasmid-like molecule found in all of the DNAs was the 1.6-kbp minicircle, which is a feature of sterile cytoplasms. These structural changes in mtDNA were obviously a consequence of somaclonal variation during the in vitro cultivation of the sugar beet cells.

A novel method to study DNA replication in vivo in organelles

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Sugarbeet minicircular mitochondrial DNAs: high-resolution transcript mapping, transcript abundance and copy number determination

Three minicircular mitochondrial DNAs have been studied to address several aspects of transcription in sugarbeet mitochondria. High-resolution transcript mapping experiments have shown that sequences at the 5' termini of minicircle transcripts are highly homologous and resemble sequences at the 5' termini of sugarbeet mainband mitochondrial genes (atpA, atp6). In addition, they show homology to transcript termini of mitochondrial genes from other dicotyledonous plants, suggesting they may function as promoter sequences. Conserved sequences, which most probably act as RNA processing signals, were also identified at the 3' termini of minicircle transcripts. An oligonucleotide probe to a 14 base conserved sequence was used to determine the relative copy numbers of the three minicircle components in male-fertile mitochondria. Copy numbers were roughly equivalent, suggesting minicircles are replicated and/or transmitted with nearly equal efficiency, at least in sugarbeet taproots. Mc.a and Mc.c transcript levels are equivalent, consistent with their template copy number, however; Mc.d transcript levels were significantly lower than expected, implicating additional factors such as promoter strength and/or transcript stability in determining transcript levels in sugarbeet mitochondria, as recently demonstrated in maize.

Transkinetoplastidy--a novel phenomenon involving bulk alterations of mitochondrion-kinetoplast DNA of a trypanosomatid protozoan

Dramatic and consistent changes of mitochondria or kinetoplast DNA (kDNA) were observed in certain variants of Leishmania amazonensis (A variants) selected in vitro for arsenite-resistance. This was found initially by comparing different lots of wild-type cells and their respective A variants resistant to 30 microM arsenite. The kDNAs isolated from these two groups had different restriction patterns and hybridized poorly to each other, whereas those from different lots within each of the two groups were identical. Hybridization data showed an overall identity of less than 10(-3) between total kDNAs of the two groups. This difference was further examined in three independent series of variants, which were selected from three different clones for resistance to graded concentrations of arsenite (5-50 microM). In all three series, their kDNAs were found to change abruptly in an identical pattern at a late step of the selection process, i.e., A variants resistant to 15 microM or 30 microM arsenite. There was no apparent loss of kDNA in the process. Most of the changes observed appear to involve a shift in either the dominance or the copy number of different minicircle subclasses. Surprisingly, the kDNAs of tunicamycin-resistant variants (T variants) were also found to undergo similar changes. Genetic changes previously described in both A and T variants are limited to their nuclei. Namely, different chromosomal regions are amplified to produce large DNA circles which are responsible for the drug-resistant phenotypes. Interestingly, other arsenite-resistant clones without such chromosomal DNA amplification (A' variants) had kDNA of the wild-type pattern. The profound changes of kDNA observed are unprecedented. We propose the term "transkinetoplastidy" for this phenomenon to distinguish it from dyskinetoplastidy or the loss of kDNA described previously in trypanosomatid protozoa. This phenomenon is discussed with respect to the possible mechanisms of its generation, regulation and relation to the drug-resistant phenotypes.

Molecular characterization of mitochondrial DNA of different subtypes of male-sterile cytoplasms of the sugar beet Beta vulgaris L

Mitochondrial (mt) DNA from eight cytoplasmic male-sterile (cms) lines of sugar beet from different breeding stations was investigated by restriction fragment analysis and Southern hybridization. All cms lines showed similar but not identical restriction and hybridization signal patterns, readily distinguishable from those of fertile (N) cytoplasm. Digestion of the mtDNA with BamHI, EcoRI, SalI, and XhoI revealed distinct differences between the sterile lines, and six subtypes of the S cytoplasm could be distinguished. Differences between the sterile lines were confirmed by hybridization with a [Formula: see text] gene probe revealing minor, line-specific hybridization signals. The data presented provide evidence for the existence of considerable variation within the only commercially used source of cms in the sugar beet, the Owen's type of cytoplasm.

Nucleotide sequence and transcriptional analysis of a mitochondrial plasmid from a cytoplasmic male-sterile line of sunflower

A mitochondrial plasmid of 1,939 bp (P2) from a cytoplasmic male-sterile line of sunflower has been cloned and sequenced. It presents 437 bp of near-perfect homology to the 1.4-kb mitochondrial plasmid P1 from sunflower. Sequences homologous to P2 were found in nuclear DNA. P2 was transcribed into a major 980-nucleotide (nt) RNA molecule and two minor transcripts of 570 and 520 nt. They were all transcribed from the same strand and within the region nonhomologous to P1. A single 5' boundary and three 3' termini were determined for P2 transcripts. The 5' end is similar to a consensus sequence for plant mitochondrial genes. No evidence of translation products can be provided.

Rapid hybridization-based assays for identification by DNA probes of male-sterile and male-fertile cytoplasms of the sugar beet Beta vulgaris L

Methods are described whereby hybridization of mitochondrial (mt) DNA with different DNA probes can definitely distinguish male-fertile and and male-sterile (cms) cytoplasms of sugar beet Beta vulgaris L. We have developed two types of miniassays. (1) Comparative methods requiring the isolation and restriction of total cellular DNA, hybridization with cloned mtDNA fragments from either fertile or male-sterile cytoplasms, and comparison of the hybridization patterns to the fertile-and sterile-specific patterns of mtDNA of sugar beet for the given mtDNA probe. For these analyses, we routinely used 1 g of plant material to determine the type of cytoplasm. (2) Noncomparative ("plus-minus") methods requiring neither the isolation of pure DNA nor restriction, electrophoresis, or Southern blotting. Instead, alkaline-SDS plant extracts from as little as 50 mg of plant material were dot-blotted and hybridized with fertile-specific (mitochondrial minicircular DNA) and/or cms-specific probes (consisting of a 2.3-kb mtDNA sequence exclusively occurring in the cms cytoplasm). The assays are simple to perform, give definitive results, are nonde-structive to the plants, and may be used in mass screening of sugar beet populations for hybrid production or in in vitro culture processes.

Genomic organization and sequence analysis of the cytochrome oxidase subunit II gene from normal and male-sterile mitochondria in sugar beet

We have cloned and sequenced the cytochrome oxidase subunit II (coxII) gene from both normal and cytoplasmic male-sterile (CMS) sugar beet. The normal coxII (designated NcoxII) locus was found to be located 1491 bp upstream from the gene for cytochrome oxidase subunit I (coxI) on the same DNA strand and to have a 1463 bp intron which split the coding sequence into two exons (382 and 398 bp). The COXII protein contains 260 amino acid residues. We have also found two copies of the coxII gene (ScoxII-1 and ScoxII-2) to be present in the CMS genome. Our results suggest that the NcoxII gene diverges completely from the ScoxII-1 and ScoxII-2 genes 50 bp 5' to the ATG start codon. In addition, the ScoxII-1 and ScoxII-2 sequences could be readily discriminated from each other by the 3' end and the immediately adjacent flanking sequences of the gene: the 3' divergence results in a 101 codon extension of the ScoxII-2 ORF. Northern blot analysis demonstrates that the coxII gene exhibits altered transcript patterns in CMS compared with normal sugar beet. Different genomic arrangements of the coxII gene are considered to be the result of extensive intra- and inter-molecular recombination events involving the repeated DNA elements in the mitochondrial genome.

Rapid control of purity for the cytoplasm of male-sterile seed stocks by means of a dot hybridization assay

To produce hybrids, one member of the parental line is genetically made male-sterile. This male-sterile trait is encoded by mitochondria so that it is maternally inherited. Consequently, the progeny of a male-sterile plant is fully sterile. Nevertheless, during the handling of cytoplasmic male-sterile seed stocks, some mixture with seeds of the maintainer lines can occur. Up to the present time, the only way to check the homogeneity of the cytoplasmic male-sterile seed stock was to grow the plants until flowering time. We have developed a method which can be used immediately after the harvest, allowing us to check samples from both sunflower and sugar beet. We used the mitochondrial plasmid, present only in the maintainer lines, as a probe for the total nucleic acids prepared from the cytoplasmic male-sterile seed stocks which might be contaminated. The signals compared to those of samples artificially contaminated allow us to measure as few as one male-fertile seed in 1000 seeds in a rapid and accurate manner.

High-rate spontaneous reversion to cytoplasmic male sterility in sugar beet: a characterization of the mitochondrial genomes

Among the fertile sugar beet lines with nuclear sterility maintenance genes, rf, in a homozygous recessive state, sublines capable of reverting spontaneously at a high rate to sterility were identified. Of 24 related fertile sublines studied, 6 were found to spontaneously revert to sterility with a frequency of about 19%. Genetic analysis confirmed the cytoplasmic nature of spontaneously arising sterility. Reversion to sterility in these sublines was accompanied by alterations in the mitochondrial genome structure: loss of the autonomously replicating minicircle c (1.3 kb) and changes in the restriction patterns of high-molecular-weight mitochondrial DNA (mtDNA). Southern hybridixation analysis with cloned minicircle c as a probe revealed no integration of this DNA molecule into the main mitochondrial and nuclear genomes of the revertants. Comparative BamHI and EcoRI restriction analysis of the mtDNA from the sterile revertants and fertile parental subline showed that the spontaneous reversion is accompanied by extensive genomic rearrangement. Southern blot analysis with cloned α-subunit of F1-ATPase (atpA) and cytochrome c oxidase subunit II (COX II) genes as probes indicated that the changes in mtDNA accompanying spontaneous reversion to sterility involved these regions. The mitochondrial genomes of the spontaneous revertants and the sterile analogue were shown to be identical.

Characterization and sequence of lupin mitochondrial plasmid-like DNA

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 exhibits 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.

Comparison of the organization and expression of mtDNA of fertile and male-sterile sugar beet varieties (Beta vulgaris L.)

Analysis of minicircle occurrence in different samples of sugar beet mitochondrial (mt) DNA invalidates the postulated relationship between cytoplasmic male sterility (CMS) phenotype and the absence of minicircle c and d. In high molecular weight mt DNA, two types of restriction patterns are found for fertile genomes and only one type for the CMS; in spite of the multiplicity of crosses carried out by plant breeders, all the CMS varieties analyzed seem to have derived from the original cytoplasm discovered by Owen in 1945. Southern hybridizations with mitochondrial genes coding for cytochrome oxidase subunits II and III, ATPase subunits α, 6 and 9 and 26S ribosomal RNA indicate that gene organization is different between fertile and sterile genomes but similar in all fertile genomes. Transcription analysis with the same genes indicate several differences between fertile and sterile varieties but also within some fertile varieties. These results suggest that the mt genome found in male-sterile sugar beet may originate not from modifications of the fertile mitochondrial genome but from a particular source of cytoplasm, of which a possible origin is discussed.

Characterization of a conserved extrachromosomal element isolated from the avian malarial parasite Plasmodium gallinaceum

We have identified a conserved, repeated, and highly transcribed DNA element from the avian malarial parasite Plasmodium gallinaceum. The element produced multiple transcripts in both zygotes and asexual blood stages of this parasite. It was found to be highly conserved in all of five malarial species tested and hybridized at reduced stringency to other members of the phylum Apicomplexa, including the genera Babesia, Eimeria, Toxoplasma, and Theileria. The copy number of the element was about 15, and it had a circularly permuted restriction map with a repeat unit length of about 6.2 kilobases. It could be separated from the main genomic DNA by using sucrose gradients and agarose gels, and it migrated separately from the recognized Plasmodium chromosomes on pulse-field gels. In the accompanying paper (S. M. Aldritt, J. T. Joseph, and D. F. Wirth, Mol. Cell. Biol. 9:3614-3620, 1989), evidence is presented that element contains the mitochondrial genes for the protein cytochrome b and a fragment of the large rRNA. We postulate that this element is an episome in the mitochondria of the obligate parasites belonging to the phylum Apicomplexa.

Characterization of a conserved extrachromosomal element isolated from the avian malarial parasite Plasmodium gallinaceum

We have identified a conserved, repeated, and highly transcribed DNA element from the avian malarial parasite Plasmodium gallinaceum. The element produced multiple transcripts in both zygotes and asexual blood stages of this parasite. It was found to be highly conserved in all of five malarial species tested and hybridized at reduced stringency to other members of the phylum Apicomplexa, including the genera Babesia, Eimeria, Toxoplasma, and Theileria. The copy number of the element was about 15, and it had a circularly permuted restriction map with a repeat unit length of about 6.2 kilobases. It could be separated from the main genomic DNA by using sucrose gradients and agarose gels, and it migrated separately from the recognized Plasmodium chromosomes on pulse-field gels. In the accompanying paper (S. M. Aldritt, J. T. Joseph, and D. F. Wirth, Mol. Cell. Biol. 9:3614-3620, 1989), evidence is presented that element contains the mitochondrial genes for the protein cytochrome b and a fragment of the large rRNA. We postulate that this element is an episome in the mitochondria of the obligate parasites belonging to the phylum Apicomplexa.

A new cytoplasmic male sterile genotype in the sugar beet Beta vulgaris L.: a molecular analysis

Mitochondrial DNA (mtDNA) from fertile (N) and possibly new cytoplasmic male sterile (CMS) genotypes was studied in the sugar beet Beta vulgaris L. It was found by restriction endonuclease analysis that BMC-CMS, a cytoplasm that was derived from the wild beet Beta maritima, contained a unique type of mtDNA which is distinguishable from both the N and S-CMS, the only other CMS genotype that is currently availabe in B. vulgaris L. The organization of three genes: coxI, coxII and cob, was analyzed by hybridization with heterologous probes from maize. These genes have a similar structure in N and BMC-CMS that is different from S-CMS. It is concluded that BMC-CMS is a novel CMS genotype in the sugar beet.

Physical and biological characterization of linear DNA plasmids of the yeast Pichia inositovora

Three cryptic DNA plasmids have been identified in a strain of the yeast Pichia inositovora that are 18, 13, and 10 kbp in size. All are sensitive to digestion by DNase I, restriction endonucleases, and exonuclease III, but are resistant to the activities of RNase A and lambda exonuclease. These results indicate that each plasmid is a linear DNA molecule whose 5' ends are protected. A restriction map has been developed for each of the plasmids, demonstrating that each is unique and confirming their linear nature. The plasmids are a major constituent of DNA prepared from whole cells, but are absent from DNA preparations of purified mitochondria and nuclei, indicating that the plasmids are located in the cytoplasm. These plasmids share many of the physical characteristics described for the linear plasmids of the yeasts Kluyveromyces lactis and Saccharomycopsis crataegensis. Unlike the linear plasmids of K. lactis, however, they appear not to be capable of killer toxin production.

Properties and nucleotide sequence of a mitochondrial plasmid from sunflower

The 1.413 circular supercoiled mitochondrial DNA plasmid P1 from a fertile sunflower line was sequenced, and a series of 160 bp tandemly repeated sequences was observed. The P1 plasmid was detected in both fertile and cytoplasmic male-sterile (CMS) lines, but in different quantities. Two other circular plasmids, P2 and P3, each 1.8 kbp in length, were shown to share common sequences with P1. The mitochondrial plasmid P1 detected homologous sequences in the nuclear DNA of sunflower, but not in chloroplast DNA nor in main band mitochondrial DNA. RNA molecules of about 680 and 550 nucleotides were detected that were complementary to mt plasmid P1.

Minicircle variation in Beta mitochondrial DNA

Mitochondrial DNAs from nine male fertile and eight cytoplasmic male sterile (cms) accessions of wild and cultivated Beta beets were investigated for the presence of low molecular weight DNA molecules. Five different supercoiled DNA molecules were detected, varying in size from 1.33 to 1.63 kb. Southern hybridizations revealed multimeric forms and sequence homologies between the minicircles. The occurrence of the different minicircles among the 17 accessions was investigated by agarose gel electrophoresis and Southern hybridization using minicircle specific probes. The 1.33 and 1.63 kb minicircles were found in most accessions, the other three minicircles were found in one or two of the wild Beta beet accessions. The presence of a low number of small, more or less homologous, minicircles in all investigated plants makes these molecules a general characteristic of Beta mtDNA. No association is found between the presence or absence of specific minicircles and the expression of male sterility. Neither does the distribution of the different minicircles in Beta beets indicate any essential biological role of these minicircles.

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

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.

Nucleotide sequence and molecular characterization of a maize mitochondrial plasmid-like DNA

The mitochondrial genome of Black Mexican Sweet maize consists of the principal genome, a 2.3 kb minilinear DNA, a 1,913 bp (1.9 kb) and a 1,445 bp (1.4 kb) minicircular DNA. The three extrachromosomal DNAs exhibit characteristics of autonomous replication in cell suspension culture. The complete sequence of the 1.4 kb minicircle was determined. It has 61 bp of near perfect sequence homology to the 1.9 kb minicircle. Both minicircular DNAs are transcriptionally active; the longest open reading frame of the 1.4 kb minicircle was 231 bp. A putative origin of replication was identified as a high A + T sequence. These minicircles were present in some but not all of 20 maize lines surveyed. None of the lines examined carried the 1.4 kb minicircle without the 1.9 kb minicircle. Nuclear DNA of one line of the seven examined carried homology to both DNAs.

Mitochondrial plasmid DNAs of broad bean: nucleotide sequences, complex secondary structures, and transcription

Three circular plasmid DNA molecules of 1704, 1695 and 1476 nucleotide pairs from broad bean mitochondria (mt-plasmids 1-3) have been sequenced. Within a highly homologous segment of mt-plasmid 1 and 2 are found a series of six directly repeated, inverted repeat sequences, separated by unique sequences. Mt-plasmid 3 contains a series of four inverted repeat sequences, unrelated to the inverted repeat sequences of mt-plasmids 1 and 2. Two RNA molecules of about 440 and 320 nucleotides that are complementary to mt-plasmid 2 were detected. Mapping of 5' and 3' termini of these complementary RNA molecules indicated that all transcription from mt-plasmid 2 occurs within a 441 nucleotide region of the molecule. Evidence for transcription of mt-plasmids 1 and 3 was not found.

The nucleotide sequence and transcription of minicircular mitochondrial DNA's associated with male-fertile and cytoplasmic male-sterile lines of sugarbeet

Male-fertile (MF) and cytoplasmic male-sterile (CMS) lines of sugarbeet possess characteristic low molecular weight minicircular mitochondrial DNA's, and Southern hybridizations revealed sequence homologies between them. The complete nucleotide sequences of minicircle a present in MF and CMS lines, and minicircle d present in some MF lines have been determined and compared to minicircle c present in all MF lines. Computer analysis revealed sequences common to all three DNA's: these may be essential to their maintenance in sugarbeet mitochondria. Analysis of the extent and arrangement of homologous sequences in minicircle a and minicircle d suggests the latter may have arisen from an intramolecular recombination event in minicircle a. The G+C contents of the minicircles differ and their possible origins are discussed. All three DNA's are transcribed. Minicircle c and minicircle d transcripts are exclusive to MF mitochondria, but are unlikely to encode protein products. Two transcripts of sufficient size and the predicted polarity to encompass a short open reading frame on minicircle a are common to both MF and CMS mitochondria.

Heterogeneity of circular mitochondrial DNA molecules from sugar beet with normal and male sterile cytoplasms

Mitochondrial (mt) DNAs from normal (N) and male sterile (S) cytoplasms of sugar beet have been isolated and investigated by electron microscopy. The results showed that mtDNA was composed of a heterogeneous population of circular molecules. Their contour lengths varied from 0.28 to 51 micron, but unlike in the case of maize, a large difference was not observed in the distribution of molecular classes greater than 1.0 micron between N and S cytoplasms of sugar beet. On the other hand, N and S cytoplasms were shown to contain their own characteristic combinations of small circular mtDNA species with lengths between 0.28 micron and 0.6 micron. Mitochondrial DNAs from various sources of male-sterile cytoplasms were analyzed by agarose gel electrophoresis to determine the extent of cytoplasmic variation. Additional low molecular weight DNA bands appeared in all male-sterile lines examined, and as a result, three distinctive banding patterns were recognized. These data are in general agreement with those based upon restriction endonuclease digestion of mt and chloroplast DNAs and the genetic analysis of fertility restoration in test crosses.

Organelle genome diversity in sugar beet with normal and different sources of male sterile cytoplasms

Mitochondrial (mt) and chloroplast (ct) DNAs from sugar beet lines carrying normal and introduced sources of male sterile cytoplasms have been characterized and compared on the basis of restriction enzyme analysis. Normal cytoplasm was shown to contain mt and ctDNAs which differed from those of the male sterile cytoplasms examined in the present investigation. On the other hand, four groups of male sterile cytoplasms could be differentiated by their own characteristic mtDNA digest patterns, while two were separated by ctDNA comparisons. In addition, a greater degree of variability of the mitochondrial genome is suggested. Our results also imply strict maternal inheritance of mt and ctDNAs. Thus, the organelle DNA assay provides a positive and alternative means of identifying various male sterile cytoplasms.

Extrachromosomal DNA in eucaryotes

Eucaryotic extrachromosomal DNAs have been organized into four major classes: (1) Organelle DNAs, (2) plasmid DNAs, (3) amplified genes, and (4) intermediates and/or by-products of DNA transpositions and rearrangements. In this review some of the relatively well-characterized members of each class are described; it is suggested that many of them reflect the complexity and plasticity of eucaryotic genomes.

Circular plasmid DNAs from mitochondria of Sorghum bicolor

Agarose gel electrophoresis of mitochondrial DNA (mtDNA) from the IS1112C male-sterile cytoplasm of Sorghum bicolor (S. bicolor) revealed plasmid-like DNAs additional to the linear N1 and N2 molecules. Mitochondrial plasmids were separated from the principal mitochondrial genome and used in the construction of molecular clones. Clones with EcoRI inserts of 1.7 and 2.3 kb were recovered. Hybridization of these clones to Southern blots of unrestricted and EcoRI-digested IS1112C mitochondrial plasmids indicated the cloned inserts were complete or nearly-complete copies of minicircular DNA molecules. These clones were used to probe Southern blots of mitochondrial genomes from six cytoplasmic male-sterile (CMS) and five male-fertile (MF) lines of S. bicolor, as well as Southern blots of IS1112C chloroplast, kafir chloroplast, IS1112C nuclear, and kafir nuclear genomes. The 2.3 and 1.7 kb plasmids had a very limited distribution among the sorghum entries we examined. We found no evidence for integrated copies of these sequences in any of the mitochondrial, chloroplast, or nuclear genomes probed in this study. However, the 2.3 kb sorghum minicircle did hybridize to the 1.94 kb minicircle from maize mitochondria. Hybridization of the 1.7 and 2.3 kb clones to IS111L2C mitochondrial RNA reveal a transcript of 1.1 kb from the 1.7 kb minicircle and transcripts of 1.9 and 1.4 kb from the 2.3 kb molecule.

The nucleotide sequence of a mitochondrial replicon from maize

The 1913-bp maize mitochondrial (mt) plasmid was isolated from a suspension culture of a Black Mexican Sweet maize strain, cloned into M13mp vectors, and sequenced by a unidirectional progressive deletion method. The 1.9-kb extrachromosomal double-stranded circular DNA plasmid was found to contain regions of sequence which in other systems are known to be part of origins of replication (ori). This plasmid could be used as a carrier for chimeric genes and a molecular probe for replication.