Structure and transcription of the gene coding for subunit 3 of cytochrome oxidase in wheat mitochondria

Mapping of wheat mitochondrial mRNA termini and comparison with breakpoints in DNA homology among plants

Mitochondrial DNA rearrangements occur very frequently in flowering plants and when close to genes there must be concomitant acquisition of new regulatory cis-elements. To explore whether there might be limits to such DNA shuffling, we have mapped the termini of mitochondrial mRNAs in wheat, a monocot, and compared them to the known positions for counterpart genes in the eudicot Arabidopsis. Nine genes share homologous 3' UTRs over their full-length and for six of them, the termini map very close to the site of wheat/Arabidopsis DNA rearrangements. Only one such case was seen for comparisons of 5' UTRs, and the 5' ends of mRNAs are typically more heterogeneous than 3' termini. Approximately half of the thirty-one wheat mitochondrial transcriptional units are preceded by CRTA promoter-like motifs, and of the potential stem-loop or tRNA-like structures identified as candidate RNA processing/stability signals near the 5' or 3' ends, several are shared with Arabidopsis. Comparison of the mitochondrial gene flanking sequences from normal fertile wheat (Triticum aestivum) with those of Aegilops kotschyi which is the source of mitochondria present in K-type cytoplasmic male sterile wheat, revealed six cases where mRNAs are precluded from sharing full-length homologous UTRs because of genomic reorganization events, and the presence of short repeats located at the sites of discontinuity points to a reciprocal recombination-mediated mode of rearrangement.

Transfer of RPS14 and RPL5 from the mitochondrion to the nucleus in grasses

Gene transfer from the mitochondrion to the nucleus, a process of outstanding importance to the evolution of the eukaryotic cell, is an on-going phenomenon in higher plants. After transfer, the mitochondrial gene has to be adapted to the nuclear context by acquiring a new promoter and targeting information to direct the protein back to the organelle. To better understand the strategies developed by higher plants to transfer organellar genes during evolution, we investigated the fate of the mitochondrial RPL5-RPS14 locus in grasses. While maize mitochondrial genome does not contain RPS14 and RPL5 genes, wheat mitochondrial DNA contains an intact RPL5 gene and a nonfunctional RPS14 pseudogene. RPL5 and PsiRPS14 are co-transcribed and their transcripts are edited. In wheat, the functional RPS14 gene is located in the nucleus, within the intron of the respiratory complex II iron-sulfur subunit gene (SDH2). Its organization and expression mechanisms are similar to those previously described in maize and rice, allowing us to conclude that RPS14 transfer and nuclear activation occurred before divergence of these grasses. Unexpectedly, we found evidence for a more recent RPL5 transfer to the nucleus in wheat. This nuclear wheat RPL5 acquired its targeting information by duplication of an existing targeting presequence for another mitochondrial protein, ribosomal protein L4. Thus, mitochondrial and nuclear functional RPL5 genes appear to be maintained in wheat, supporting the hypothesis that in an intermediate stage of the transfer process, both nuclear and mitochondrial functional genes coexist. Finally, we show that RPL5 has been independently transferred to the nucleus in the maize lineage and has acquired regulatory elements for its expression and a mitochondrial targeting peptide from an unknown source.

Marchantia polymorpha mitochondrial orf identifies transcribed sequence in angiosperm mitochondrial genome

Heterologous hybridizations performed using nine Marchantia polymorpha mitochondrial orfs and the sdh4 gene against angiosperm mtDNA suggested that three of them and the sdh4 gene have been conserved in the mitochondrial genome of different angiosperm species. Solanum tuberosum mtDNA fragments, which hybridized to M. polymorpha orf207 and sdh4 gene, were cloned, sequenced, and their expressions evaluated by Northern and RT-PCR. Hybridizing fragments to sdh4 gene and orf207 from potato mtDNA were shown to be transcribed, but only in the case of sdh4 gene was there homology between the protein encoded by the DNA sequence from M. polymorpha and the potato mitochondrial genome. M. polymorpha orf207 showed little similarity to an open reading frame from potato mtDNA, named here orf78. The putative proteins encoded by both orf207 and orf78 were not related, indicating that these orfs do not constitute homologous sequences.

The steady-state level of mRNA from the Ogura cytoplasmic male sterility locus in Brassica cybrids is determined post-transcriptionally by its 3' region

We have investigated the control of the expression of three different configurations of the mitochondrial gene orf138, whose expression is correlated with Ogura cytoplasmic male-sterility in rapeseed cybrids. These configurations, termed Nco2.5/13S, Nco2.7/13F and Bam4.8/18S, specific to the 13S (sterile), 13F (fertile) and 18S (sterile) cybrids respectively, have the same 5' regions but different 3' regions. The orf138 transcript from Bam4.8/18S is 10-fold more abundant than the one from Nco2.5/13S, while no orf138 transcript from Nco2.7/13F accumulates. However, transcriptional activity measurements show that the rate of transcription is equivalent for the three configurations. These results strongly suggest that the steady-state level of mRNA from the orf138 locus is determined post-transcriptionally, most likely by its 3' region. To determine the role of these 3' regions, we have established an in vitro decay and processing system. In the presence of rapeseed mitochondrial lysate, synthetic RNAs corresponding to the 3' region of the Nco2.7/13F transcript are, as expected, less stable than RNAs corresponding to the 3' regions of the Nco2.5/13S and Bam4.8/18S transcripts. We have also observed in vitro processing of synthetic RNAs at the sites corresponding to the 3' ends of the natural mRNAs from Nco2.5/13S and Bam4.8/18S. Further analysis of the role of these 3' regions in in vitro RNA stability should help us to better understand post-transcriptional control in plant mitochondria.

Polymerase chain reaction-single strand conformational polymorphism analysis of intra- and interspecific variations in organellar DNA regions of Aegilops mutica and related species

In order to study the phylogeny of Aegilops mutica in the genera of Triticum and Aegilops, variations in chloroplast and mitochondrial DNA regions were investigated by polymerase chain reaction-single strand conformational polymorphism (PCR-SSCP) analysis. Nine lines, each of Ae. mutica and Ae. speltoides, were studied together with nine other Triticum and Aegilops species, including T. aestivum. By analyzing 9.7-kb chloroplast and 13.1-kb mitochondrial DNA regions, a total of 268 bands were detected, of which 176 (65.7%) showed variation within and/or between species. The level of intraspecific variation of Ae. mutica was lower than that of Ae. speltoides. The low level of the intraspecific variation of Ae. mutica was contrary to the expectation from previous studies on morphological and cytolo-gical characters. In the phylogenetic trees based on SSCP, Ae. mutica, Ae. speltoides and the other four species of the section Sitopsis (the subsection Emarginata) were separated into three different clusters. In addition, T. aestivum was included in the cluster of Ae. speltoides in the phylogenetic trees. This result suggests that Ae. speltoides is the cytoplasmic donor of common wheat.

A gene proposed to encode a transmembrane domain of an ABC transporter is expressed in wheat mitochondria

In a study of transcribed regions of the wheat mitochondrial genome, we identified an open reading frame of 720 bp, which was consequently designated orf240. The amino acid sequence deduced from orf240 shows a high level of similarity with HelC, a protein essential for c-type cytochrome biogenesis in the photosynthetic purple bacterium Rhodobacter capsulatus. HelC is part of a putative heme ABC transporter. An open reading frame homologous to orf240 is present in the mitochondrial genome of Marchantia polymorpha. The wheat gene is expressed as an mRNA of 2.8 kb, which is further processed to smaller transcripts. The transcript is highly edited, with 36 C to U modifications found in the coding region of all cDNAs sequenced. RNA editing is responsible for changes in 14% of the amino acids specified by the transcript.

Higher plant mitochondria encode an homologue of the nuclear-encoded 30-kDa subunit of bovine mitochondrial complex I

We describe the structure and expression of a wheat mitochondrial gene, which codes for a subunit of mitochondrial NADH dehydrogenase. The deduced protein sequence has 70% similarity to the 30-kDa subunit of bovine mitochondrial complex I and 65% similarity to the 31-kDa subunit of Neurospora crassa complex I, components of the iron-sulfur-protein fraction, both nuclear-encoded proteins. We named this wheat mitochondrial gene as nad9. The wheat nad9 gene is transcribed in a single mRNA of 0.9 kb that is edited (C-to-U conversions) in 14 positions. Transcript mapping revealed that the first ATG codon is just 20 nucleotides downstream of the mRNA 5' end and that the 3' end is just 23 nucleotides downstream of the nad9 stop codon. The expression of the nad9 gene in plant mitochondria was studied. Polyclonal antibodies prepared against a wheat NAD9 fusion protein specifically recognise the 30-kDa subunit of bovine mitochondrial complex I and a 27.5-kDa protein in the membrane fractions of wheat, maize and common bean mitochondria, whereas the same serum recognizes a 30-kDa protein in the mitochondria of pea, chickpea and lentil.

An rps14 pseudogene is transcribed and edited in Arabidopsis mitochondria

Sequence analysis of the region upstream of the apocytochrome b (cob) gene in the Arabidopsis mitochondrial genome identifies an open reading frame with homology to ribosomal protein L5, (rpl5), and a pseudogene with similarity to ribosomal protein S14 (rps14) genes. Both cob and rpl5 genes have intact reading frames, but the rps14 homology is disrupted by a stop codon and a deleted nucleotide. The rpl5 gene, the rps14 pseudogene, and the cob gene are separated by one nucleotide and a 1604-nucleotide-long spacer respectively. A plastid-like tRNA(Ser) is encoded downstream from the cob gene. The entire region is transcribed into a 5-kb transcript, containing the rps14 pseudogene and the cob gene. Cob and rpl5 mRNAs are edited in several positions with different frequencies. The rps14 pseudogene is transcribed and edited in one position in common with other plants. Since no intact rps14 gene is found in the mitochondrial genome of Arabidopsis, the functional gene is presumably encoded in the nucleus.

Mitochondrial DNA of cytoplasmic male-sterile Triticum timopheevi: rearrangement of upstream sequences of the atp6 and orf25 genes

The organization of mitochondrial DNA (mtDNA) and transcript patterns of the atp6 and orf25 genes were examined in cytoplasmic male-sterile (CMS) and fertile Triticum lines. Major differences are observed between CMS T. timopheevi and fertile T. aestivum for both mitochondrial genes. The T. aestivum mt genome carries two atp6 gene copies, whereas only a single copy of the atp6 gene is present in T. timopheevi mtDNA. Sequence data suggest that identical sequences upstream of the atp6 gene and the orf25 gene are involved in homologous recombination in both cytoplasms. The differences in the upstream sequences of the atp6 or the orf25 genes affect transcript sizes in both cytoplasms. Transcription initiation may occur at conserved promoter elements located at variable distances upstream of the aminoacid coding sequences. The correlation between the gene rearrangements and the CMS phenomenon in T. timopheevi is discussed.

RNA editing in plant mitochondria and chloroplasts

In the mitochondria and chloroplasts of flowering plants (angiosperms), transcripts of protein-coding genes are altered after synthesis so that their final primary nucleotide sequence differs from that of the corresponding DNA sequence. This posttranscriptional mRNA editing consists almost exclusively of C-to-U substitutions. Editing occurs predominantly within coding regions, mostly at isolated C residues, and usually at first or second positions of codons, thereby almost always changing the amino acid from that specified by the unedited codon. Editing may also create initiation and termination codons. The net effect of C-to-U RNA editing in plants is to make proteins encoded by plant organelles more similar in sequence to their nonplant homologs. In a few cases, a strong argument can be made that specific C-to-U editing events are essential for the production of functional plant mitochondrial proteins. Although the phenomenon of RNA editing in plants is now well documented, fundamental questions remain to be answered: What determines the specificity of editing? What is the biochemical mechanism (deamination, base exchange, or nucleotide replacement)? How did the system evolve? RNA editing in plants, as in other organisms, challenges our traditional notions of genetic information transfer.

Structure and expression of the rice mitochondrial apocytochrome b gene (cob-1) and pseudogene (cob-2)

Rice mitochondrial DNA contains an intact copy and a pseudogene copy of a apocytochrome b gene (cob-1 and cob-2, respectively). Using primer extension and capping analyses, the transcriptional start site has been mapped; an 11-base motif at the transcription start site closely matches the consensus promoter motifs proposed for maize, wheat and soybean mitochondrial genes. Although both copies are identical in the 5' upstream region and through most of the coding region, only cob-1-specific mRNA is detected on RNA gel-blots. Run-on transcription analysis indicates, however, that both cob-1 and cob-2 mRNAs are synthesized in vivo but less cob-2 is accumulated. At its mapped 3' terminus the cob-1 transcript possesses a sequence that could fold into a double stem-loop structure. The possible roles of a double stem-loop structure in mitochondrial gene expression are discussed.

The first analysed archegoniate mitochondrial gene (COX3) exhibits extraordinary features

The first mitochondrial-encoded gene of an archegoniate has been identified, cloned and sequenced. The cytochrome oxidase III gene (cox3) of the moss Physcomitrella patens consists of a 618 bp open reading frame with high homology (around 72%) to known cox3 sequences of higher plants. Nevertheless, it is a quarter shorter than these. The cox3 gene of P. patens contains no introns and reveals a G + C-content of 41.3%. The region containing the cox3 gene exists as a single copy in the mitochondrial genome as shown by restriction mapping. In the 5' flanking sequence a putative ribosome binding site and a putative secondary structure were found. Two main transcripts of 2.4 kb and 2.6 kb were detected indicating a complex mitochondrial transcription pattern possibly due to co-transcription. Additional open reading frames were found downstream from, as well as upstream of, the cox3 gene. In Western blots a polyclonal cox3 antibody from yeast detected one single band with an apparent molecular weight of 22 kDa.

Sequence analysis of wheat mitochondrial transcripts capped in vitro: definitive identification of transcription initiation sites

To identify transcription initiation sites in wheat mitochondria, the nascent 5'-ends of transcripts were specifically labeled by incubation of wheat mitochondrial RNA with [alpha-32P]GTP in the presence of the enzyme guanylyltransferase. After separation of the resulting capped transcripts by electrophoresis in polyacrylamide gels, individual RNAs were recovered and directly sequenced. Four RNA sequences obtained in this way were localized upstream of the protein-coding genes atpA, coxII, coxIII and orf25. Comparison of mRNA and gene sequences allowed precise positioning of transcription initiation sites for these four genes. Sequence similarities immediately upstream of these sites define a conserved motif that we suggest as a candidate regulatory element in wheat mtDNA. The relationship between this motif and putative mitochondrial promoters in other plant species is discussed.

The cytochrome oxidase subunit III gene in sunflower mitochondria is cotranscribed with an open reading frame conserved in higher plants

The gene encoding subunit III of cytochrome oxidase (COXIII) has been identified in the sunflower mitochondrial genome. The COXIII coding region is located 570 bp downstream of a 477 bp open reading frame (ORFB). Sequence comparisons and hybridization experiments show that ORFB sequences are conserved in other plant mitochondrial genomes. Nucleotide and amino acid sequence comparisons suggest that RNA editing is required in sunflower mitochondria to synthesize a functional COXIII polypeptide.

Editing of the wheat coxIII transcript: evidence for twelve C to U and one U to C conversions and for sequence similarities around editing sites

The complete cDNA sequence corresponding to the wheat coxIII gene transcript (coding for subunit 3 of cytochrome oxidase) has been determined by a method involving cDNA synthesis using specific oligonucleotides as primers followed by PCR amplification, cloning and sequencing of the amplification products. In 12 different clones, the same 13 nucleotide modifications have been found as compared to the genomic mitochondrial DNA sequence. Among these modifications, 12 are C----U conversions which change codons identities, thereby increasing the homology between the wheat COXIII protein and the corresponding protein of non-plant organisms. The 13th modification is a silent U----C conversion which seems to be an unfrequent editing eventin plant mitochondria. Homologies can be found between sequences surrounding editing sites in the coxIII transcript and in other wheat mitochondrial transcripts. The presence of such homology suggests that these sequences could base-pair with a common RNA molecule which might be involved in editing site recognition.