Evolution of plant mitochondrial genomes via substoichiometric intermediates

Polymorphism for ribosomal RNA gene arrangement in the mitochondrial genome of fall rye (Secale cereale L.)

A restriction-fragment-length polymorphism (RFLP) in mitochondrial DNA (mtDNA) was detected between varieties of fall rye (Secale cereale L.) by Southern hybridization with rrn18, the gene encoding the mitochondrial 18S ribosomal RNA. Restriction mapping showed that the RFLP is based on differing numbers of genomic contexts (one vs three) for a recombining-repeat element (the "18S/5S repeat"). From examination of other Secale species, we conclude that the one-context state arose relatively recently, putatively by deletion of two of an ancestral set of three distinct genomic loci containing the mitochondrial 18S/5S repeat. This is consistent with our earlier conclusion that the 18S/5S repeat has probably existed in at least two genomic copies throughout much of the history of the grass family (at least 40 million years). Interestingly, the intervarietal difference in the number of distinct rrn18 loci is not accompanied by a major difference in the number of rrn18 copies per unit mass of mtDNA. This suggests the existence of a mechanism that can compensate rather precisely for differences in mitochondrial gene dosage, perhaps by over-replication or stabilization of specific subgenomic molecules.

Mitochondrial DMA variation in somatic embryogenic cultures ofLarix

outhern hybridization analysis using wheat mitochondrial gene-specific probes indicates that changes in mitochondrial genomic organization and the relative representation of certain genomic regions occur during in vitro somatic embryogenic cell culture ofLarix species. We observed differences in the mitochondrial (mt)DNA hybridization patterns between somatic embryogenic cell cultures and trees grown from seed forLarix leptolepis,L. decidua, and the reciprocal hybrids of these twoLarix species. This is the first study to describe the correlation of molecular changes in a gymnosperm mitochondrial genome with in vitro somatic embryogenic cell culture. Quantitative differences in mtDNA hybridization signals were also observed among a 4-year-old somatic embryogenic cell culture ofLarix ×eurolepis trees regenerated from this culture, and the seed source tree from which the somatic embryogenic cell cultures were initiated.

Mitochondrial DNA variability detected in a single wheat regenerant involves a rare recombination event across a short repeat

The mitochondrial genome of the selfed progeny of a plant regenerated from long-term somatic tissue culture displays specific structural rearrangements characterized by the appearance of novel restriction fragments. A mitochondrial DNA library was constructed from this selfed progeny in the SalI site of cosmid pHC79 and the novel fragments were subsequently studied. They were shown to arise from reciprocal recombination events involving DNA sequences present in the parental plant. The regions of recombination were sequenced and the nucleotide sequences were aligned with those of the presumptive parental fragments. We characterized an imperfect short repeated DNA sequence, 242 bp long, within which a 7-bp DNA repeat could act as a region of recombination. The use of PCR technology allowed us to show that these fragments were present in both parental plants and tissue cultures as low-abundance sequence arrangements.

Intron loss from the NADH dehydrogenase subunit 4 gene of lettuce mitochondrial DNA: evidence for homologous recombination of a cDNA intermediate

The mitochondrial gene coding for subunit 4 of the NADH dehydrogenase complex I (nad4) has been isolated and characterized from lettuce, Lactuca sativa. Analysis of nad4 genes in a number of plants by Southern hybridization had previously suggested that the intron content varied between species. Characterization of the lettuce gene confirms this observation. Lettuce nad4 contains two exons and one group IIA intron, whereas previously sequenced nad4 genes from turnip and wheat contain three group IIA introns. Northern analysis identified a transcript of 1600 nucleotides, which represents the mature nad4 mRNA and a primary transcript of 3200 nucleotides. Sequence analysis of lettuce and turnip nad4 cDNAs was used to confirm the intron/exon border sequences and to examine RNA editing patterns. Editing is observed at the 5' and 3' ends of the lettuce transcript, but is absent from sequences that correspond to exons two, three and the 5' end of exon four in turnip and wheat. In contrast, turnip transcripts are highly edited in this region, suggesting that homologous recombination of an edited and spliced cDNA intermediate was involved in the loss of introns two and three from an ancestral lettuce nad4 gene.

Variant mitochondrial plasmids of broad bean arose by recombination and are controlled by the nuclear genome

Various cytoplasms of broad bean contain three mitochondrial plasmids (mtp1, 2 and 3), previously described. In cytoplasm 350 we have observed several additional mitochondrial plasmids, varying in number and in identity according to the nuclear background. Replacement of the nucleus by backcrossing led to the appearance or disappearance of additional plasmids, indicating that the nuclear genome controls either the creation or the copy level of mitochondrial plasmids. Analysis of eight variant additional plasmids (mtp4-11) suggests that they all result from a double recombination event between mtp1 and mtp2. In all cases, one recombination point was located within a 276-bp sequence, identical in both plasmids. For 7 plasmids, the region in which the second recombination event occurred could be narrowed down to a short stretch containing imperfect tandem repeats of a 31-bp motif. The largest sequence shared by the recombination regions was hexanucleotide GCGACG.

Cytoplasmic male sterility (CMS) in Lolium perenne L.: 1. Development of a diagnostic probe for the male-sterile cytoplasm

Analysis of reciprocal crosses between nonrestoring fertile genotypes and restored male-sterile genotypes of Lolium perenne confirmed the cytoplasmic nature of the sterility trait. This prompted a search for a molecular probe that could be used to distinguish between fertile and cytoplasmic male-sterile (CMS) cytoplasms. We describe the identification and cloning of a 4.5-kb BamHI-HindIII restriction fragment from the mtDNA of the CMS line. The cloned fragment (pCMS45) failed to hybridise to sequences in the mtDNA of fertile lines and was thus capable of unambiguously distinguishing between fertile and CMS cytoplasms. The use of pCMS45 as a diagnostic probe provided a simple test for positive identification of young non-flowering plants carrying the CMS cytoplasm and also permitted confirmation at the molecular level of the maternal transmission of the CMS trait suggested by the genetic data.

Organizational differences between cytoplasmic male sterile and male fertile Brassica mitochondrial genomes are confined to a single transposed locus

Comparison of the physical maps of male fertile (cam) and male sterile (pol) mitochondrial genomes of Brassica napus indicates that structural differences between the two mtDNAs are confined to a region immediately upstream of the atp6 gene. Relative to cam mtDNA, pol mtDNA possesses a 4.5 kb segment at this locus that includes a chimeric gene that is cotranscribed with atp6 and lacks an approximately 1kb region located upstream of the cam atp6 gene. The 4.5 kb pol segment is present and similarly organized in the mitochondrial genome of the common nap B.napus cytoplasm; however, the nap and pol DNA regions flanking this segment are different and the nap sequences are not expressed. The 4.5 kb CMS-associated pol segment has thus apparently undergone transposition during the evolution of the nap and pol cytoplasms and has been lost in the cam genome subsequent to the pol-cam divergence. This 4.5 kb segment comprises the single DNA region that is expressed differently in fertile, pol CMS and fertility restored pol cytoplasm plants. The finding that this locus is part of the single mtDNA region organized differently in the fertile and male sterile mitochondrial genomes provides strong support for the view that it specifies the pol CMS trait.

Mitochondrial DNA and genetic disease

Since the human mitochondrial genome was characterised and sequenced in 1981, it has been viewed as the likely site of genetic diseases showing a maternal inheritance pattern and associated with defects of the respiratory chain, such as the mitochondrial myopathies (MMs). The properties that make it a candidate for the source of such conditions are that it encodes polypeptides involved in electron transport and that it is maternally inherited. However, several of the mtDNA diseases only fulfill one or other of these criteria: the first group of mtDNA diseases showed only sporadic deletions, and the first point mutation in Leber's Hereditary Optic Neuropathy (LHON) is not associated with a clear biochemical defect. Furthermore, it is now clear that both autosomal dominant and probably recessive nuclear genes can cause abnormalities of mtDNA. Each of these major groups will be considered in turn.

Alteration of mitochondrial genomes containing atpA genes in the sexual progeny of cybrids between Raphanus sativus cms line and Brassica napus cv. Westar

We have investigated the fate of the mitochondrial genomes of cybrids derived from "donor-recipient" protoplast fusion between X-irradiated Raphanus sativus (cms line) and iodoacetamide-treated Brassica napus cv. Westar. Two out of ten fusion products were male-sterile with the diploid chromosome number of B. napus. The mitochondrial (mt) genomes of the cybrids and their progeny were further analyzed by DNA-DNA hybridizaion using the pea mitochondrial ATPase subunit gene (atpA) as a probe. One cybrid, 18-3, had a 3.0 kb fragment characteristic of B. napus and a 2.0 kb non-parental fragment when the BamHI-digested DNA was hybridized with the probe. In the first-backcrossed progeny of this cybrid, the hybridization pattern was not stably inherited. A 4.0 kb radish fragment, not detectable in the cybrid, appeared in one of the BC1 generation siblings, and the 2.0 kb non-parental fragment was lost in another. The hybridization patterns in BC1 progeny siblings of cybrid 12-9 were also varied. The alteration of mtDNA in the cybrid progeny continued to the BC2 generation. There was no clear evidence of a heteroplasmic state or of sub-stoichiometric molecules in the mt genome of cybrid 18-3. A possible cause of the observed alteration in the mt genome is discussed.

Organization of ATPA coding and 3' flanking sequences associated with cytoplasmic male sterility in Phaseolus vulgaris L

A region of the mitochondrial genome associated with cytoplasmic male sterility (CMS) in Phaseolus vulgaris was flanked by two different repeated sequences designated x and y. The DNA sequence of the CMS-unique region and a portion of each flanking repeat was determined. Repeat x contained a complete coding copy of the F1 ATPase subunit A (atpA) gene, as well as an open reading frame (orf) predicting a protein of 209 amino acids. The TGA termination codon of the atpA gene and the ATG initiation codon of orf209 were overlapping. These reading frames were oriented with their 3' ends proximal to the CMS-unique region. The CMS-unique region of 3736 nucleotides contained numerous orfs. The longest of these predicted proteins being of 239, 98 and 97 amino acids. The 3' coding and 3' flanking regions of orf98 were derived from an internal region of the higher plant chloroplast tRNA alanine intron. The region of repeat y immediately adjacent to the CMS-unique region contained the 111 carboxy-terminal coding residues of the apocytochrome b (cob) gene. This segment was oriented with its 5' end proximal to the CMS-unique region, but cob gene sequences were not fused to an initiation codon within the unique region.

Amplification of substoichiometric recombinant mitochondrial DNA sequences in a nuclear, male sterile mutant regenerated from protoplast culture in Nicotiana sylvestris

A Nicotiana sylvestris plant regenerated from protoplast culture was found to be mutated in both the mitochondrial (mt) and nuclear genomes. The novel mt DNA organization, called U, is due to the amplification of recombinant substoichiometric DNA sequences that preexist in the parent line. The recombination event involves two 404 bp repeats, which hybridize to a 2.1 kb transcript. Although the sequence of both repeats was not altered by the recombination, an additional transcript of 2.5 kb was detected in U mitochondria. In addition to this mitochondrial reorganization, the protoclone carried a recessive nuclear mutation conferring male sterility (ms4). A possible role of ms4 in the appearance of the U mt DNA organization was investigated by introducing this gene into normal N. sylvestris cytoplasm. No mt DNA change could be found in homozygous ms4/ms4 plants of the F2 generation.

Unique patterns of mitochondrial genes, transcripts and proteins in different male-sterile cytoplasms of Daucus carota

Restriction fragment analysis of mitochondrial and chloroplast DNAs from a brown anther and a petaloid cytoplasmic male-sterile (cms) line revealed unique patterns for each cms line distinct from those of normal fertile cytoplasms, but identical restriction fragments for all chloroplast DNAs. The restauration of fertility through the introduction of nuclear restorer genes had no effect on the overall mitochondrial DNA (mtDNA) structure. The genomic environment and transcription patterns of several mitochondrial genes differ between cms and normal cytoplasms, while no difference has so far been detected between cms and the corresponding fertility-restored lines in mitochondrial DNAs and mRNAs. Mitochondrial translation products analysed by in-organello synthesized proteins revealed a number of polypeptides unique to each cytoplasm. Most prominent is a 17-kDa polypeptide that is present in the brown anther cms line but not in fertile mitochondria. Synthesis of this protein was not visibly affected by fertility restauration. The different cms phenotypes in carrot are thus associated with extensive and unique mtDNA rearrangements and distinct alterations in transcription and translation patterns.

Mitochondrial genome structure of rice suspension culture from cytoplasmic male-sterile line (A-58CMS): reappraisal of the master circle

The mitochondrial DNA (mtDNA) from the cultured cells of a cytoplasmic male-sterile line (A-58CMS) of rice (Oryza sativa) was cloned and its physical map was constructed. There was structural alteration on the mitochondrial genome during the cell culture. Detailed restriction analysis of cosmid clones having mtDNA fragments suggested either that the master genome has a 100-kb duplication (the genome size becomes 450 kb) or that a master circle is not present in the genome (the net structural complexity becomes 350 kb). The physical map of plant mitochondrial genomes thus far reported is illustrated in a single circle, namely a master circle. However, no circular DNA molecule corresponding to a master circle has yet been proved. In the present report, representation of plant mitochondrial genomes and a possibility for mitochondrial genome without a master circle are discussed.

Duplications of mitochondrial DNA: implications for pathogenesis

This paper describes the mapping data obtained on two patients in whom there was clear evidence for a rearrangement of mitochondrial DNA, using restriction enzyme analysis of DNA from whole blood and of polymerase chain reaction products. This suggested that a direct tandem duplication was present, and this was confirmed by sequence analysis of the junction fragment between duplicated segments. In each case the gene for cytochrome oxidase subunit I (MTCOX1) was interrupted, creating reading frames which, if transcribed and translated, would result in truncated versions of this peptide. Heteroplasmy and mosaicism for the abnormal mtDNA population were apparent. Preliminary data also suggest that high-molecular-weight rearrangements of the duplicated region are present in all tissues. The hypothesis that these duplicated genomes caused the phenotype was investigated by examining the distribution of duplicated genomes in various tissues using Southern hybridization and by RNA analysis. This included Northern blotting and cDNA sequencing. In order to investigate the origins of the duplicated mtDNAs, their distribution in different cells within a tissue was documented using the polymerase chain reaction.

RNA editing makes mistakes in plant mitochondria: editing loses sense in transcripts of a rps19 pseudogene and in creating stop codons in coxI and rps3 mRNAs of Oenothera

An intact gene for the ribosomal protein S19 (rps19) is absent from Oenothera mitochondria. The conserved rps19 reading frame found in the mitochondrial genome is interrupted by a termination codon. This rps19 pseudogene is cotranscribed with the downstream rps3 gene and is edited on both sides of the translational stop. Editing, however, changes the amino acid sequence at positions that were well conserved before editing. Other strange editings create translational stops in open reading frames coding for functional proteins. In coxI and rps3 mRNAs CGA codons are edited to UGA stop codons only five and three codons, respectively, downstream to the initiation codon. These aberrant editings in essential open reading frames and in the rps19 pseudogene appear to have been shifted to these positions from other editing sites. These observations suggest a requirement for a continuous evolutionary constraint on the editing specificities in plant mitochondria.

The wheat mitochondrial gene for subunit I of the NADH dehydrogenase complex: a trans-splicing model for this gene-in-pieces

The nad1 gene encoding subunit I of the respiratory chain NADH dehydrogenase is fragmented into five unique-copy coding segments that are scattered over at least 40 kb and interspersed with other genes in the wheat mitochondrial genome. The nad1 segments are flanked by sequences with group II intron features, and transcript analysis demonstrates the presence of correctly spliced mRNAs. RNA editing occurs at sites asymmetrically distributed along the wheat nad1 coding region, and the initiation codon is created by RNA editing. The unusual organization of the wheat nad1 gene is attributed to mitochondrial DNA rearrangements within introns, and a trans-splicing model involving secondary structural interactions between group II-like intron pieces is proposed for its expression.

Plastid DNA diversity in natural populations of Beta maritima showing additional variation in sexual phenotype and mitochondrial DNA

Plants of two natural populations of Beta maritima, characterized by high percentages of male-sterile plants, have been investigated for organelle DNA polymorphism. We confirm the two classes of mitochondrial DNA variation previously described: (i) mitochondrial DNA (mtDNA) type N is associated with male fertility, whereas mtDNA type S can cause cytoplasmic male sterility (CMS); (ii) the 10.4-kb linear plasmid is observed in both types of mitochondria and is not correlated with the cytoplasmic male sterility occurring in this plant material. A third polymorphism is now described for chloroplast DNA (ctDNA). This polymorphism occurs within single populations of Beta maritima. Three different ctDNA types have been identified by HindIII restriction analysis. Among the plants studied, ctDNA type 1 is associated with N mitochondria and type 2 with S mitochondria. Chloroplast DNA type 3 has been found both in a fertile N plant and in a sterile S plant. This finding suggests that the chloroplast DNA polymorphism reported is not involved in the expression of male sterility. A comparison with Beta vulgaris indicates that ctDNA type 3 of Beta maritima corresponds to the ctDNA of fertile sugar beet maintainer lines. The three types of Beta maritima ctDNA described in this study differ from the ctDNA of male-sterile sugar beet.

Transcriptional and posttranscriptional regulation of maize mitochondrial gene expression

Lysed maize mitochondria synthesize RNA in the presence of radioactive nucleoside triphosphates, and this assay was utilized to compare the rates of transcription of seven genes. The rates of incorporation varied over a 14-fold range, with the following rank order: 18S rRNA greater than 26S rRNA greater than atp1 greater than atp6 greater than atp9 greater than cob greater than cox3. The products of run-on transcription hybridized specifically to known transcribed regions and selectively to the antisense DNA strand; thus, the isolated run-on transcription system appears to be an accurate representation of endogenous transcription. Although there were small differences in gene copy abundance, these differences cannot account for the differences in apparent transcription rates; we conclude that promoter strength is the main determinant. Among the protein coding genes, incorporation was greatest for atp1. The most active transcription initiation site of this gene was characterized by hybridization with in vitro-capped RNA and by primer extension analyses. The DNA sequences at this and other transcription initiation sites that we have previously mapped were analyzed with respect to the apparent promoter strengths. We propose that two short sequence elements just upstream of initiation sites form at least a portion of the sequence requirements for a maize mitochondrial promoter. In addition to modulation at the level of transcription, steady-state abundance of protein-coding mRNAs varied over a 20-fold range and did not correlate with transcriptional activity. These observations suggest that posttranscriptional processes are important in the modulation of mRNA abundance.

Have malaria parasites three genomes?

Recent efforts to define the mitochondrial genome of malaria parasites have uncovered an unexpected complexity: there are two almost totally dissimilar organellar DNA molecules. lain Wilson, Malcolm Gardner, Jean Feagin and Donald Williamson discuss the surprising possibility that Plasmodium may have, in addition to the nuclear genome, two unrelated organellar genomes, one evidently mitochondrial and the other of unknown function.

Transcriptional and posttranscriptional regulation of maize mitochondrial gene expression

Lysed maize mitochondria synthesize RNA in the presence of radioactive nucleoside triphosphates, and this assay was utilized to compare the rates of transcription of seven genes. The rates of incorporation varied over a 14-fold range, with the following rank order: 18S rRNA greater than 26S rRNA greater than atp1 greater than atp6 greater than atp9 greater than cob greater than cox3. The products of run-on transcription hybridized specifically to known transcribed regions and selectively to the antisense DNA strand; thus, the isolated run-on transcription system appears to be an accurate representation of endogenous transcription. Although there were small differences in gene copy abundance, these differences cannot account for the differences in apparent transcription rates; we conclude that promoter strength is the main determinant. Among the protein coding genes, incorporation was greatest for atp1. The most active transcription initiation site of this gene was characterized by hybridization with in vitro-capped RNA and by primer extension analyses. The DNA sequences at this and other transcription initiation sites that we have previously mapped were analyzed with respect to the apparent promoter strengths. We propose that two short sequence elements just upstream of initiation sites form at least a portion of the sequence requirements for a maize mitochondrial promoter. In addition to modulation at the level of transcription, steady-state abundance of protein-coding mRNAs varied over a 20-fold range and did not correlate with transcriptional activity. These observations suggest that posttranscriptional processes are important in the modulation of mRNA abundance.

The Texas Cytoplasm of Maize: Cytoplasmic Male Sterility and Disease Susceptibility

The Texas cytoplasm of maize carries two cytoplasmically inherited traits, male sterility and disease susceptibility, which have been of great interest both for basic research and plant breeding. The two traits are inseparable and are associated with an unusual mitochondrial gene, T-urf13, which encodes a 13-kilodalton polypeptide (URF13). An interaction between fungal toxins and URF13, which results in permeabilization of the inner mitochondrial membrane, accounts for the specific susceptibility to the fungal pathogens.

A mitochondrial DNA rearrangement and three new mitochondrial plasmids from long-lived strains of Podospora anserina

The excision-junction sites of a mtDNA rearrangement of a long-lived strain of Podospora anserina, Mn19, were cloned and sequenced. Analysis of sequence and hybridization data lead to the conclusion that the Mn19 mtDNA consists of two nonoverlapping circular molecules. Three plasmids, LMt-2, LMt-3, and LMt-4, cloned from long-lived progeny of crosses between the Mn19 strain and wild type were cloned and sequenced. These plasmids share features and excision-junction sites with previously described longevity and senescence plasmids. The Mn19 mtDNA rearrangement and plasmids LMt-2, LMt-3, and LMt-4 are described. The possible significance of similarities to previously described plasmids is discussed.

Contrasting modes and tempos of genome evolution in land plant organelles

Despite inhabiting the same cell lineage for roughly a billion years and being dependent on the same nucleus for most of their gene products and genetic control, the two organelle genomes of land plants exhibit remarkably different tempos and patterns of evolutionary change. With a few notable exceptions, chloroplast genomes are highly conserved in size and gene arrangement, whereas mitochondrial genomes vary enormously in size and organization. Conversely, nucleotide substitution rates are on average several times higher in chloroplast DNA than in mitochondrial DNA. Mechanistic and selective forces underlying these differences are only poorly understood.

Physical organization of the 18S and 5S ribosomal RNA genes in the mitochondrial genome of rye (Secale cereale L.)

The mitochondrial 18S and 5S ribosomal RNA (rRNA) genes of rye, plus a total of about 90 kilobase pairs of flanking DNA, have been cloned and maps of restriction enzyme cleavage sites have been constructed. Like their homologs from hexaploid wheat, the rye genes are closely linked and are part of a three-copy family of recombining repeats (the "18S/5S repeat"). The rye repeat probably also contains a mitochondrial tRNA(fMet) gene, which the wheat repeat is known to carry. However, despite the overall organizational similarity between the wheat and rye 18S/5S repeats in the immediate vicinity of their coding regions, extensive rearrangement of flanking sequences has taken place during evolutionary divergence of the two species. Our data provide additional support for an emerging picture of plant mitochondrial genomes as evolving much more rapidly in structure than in sequence.